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Reduction in natural speech
(2009)
Natural (conversational) speech, compared to cannonical speech, is earmarked by the tremendous amount of variation that often leads to a massive change in pronunciation. Despite many attempts to explain and theorize the variability in conversational speech, its unique characteristics have not played a significant role in linguistic modeling. One of the reasons for variation in natural speech lies in a tendency of speakers to reduce speech, which may drastically alter the phonetic shape of words. Despite the massive loss of information due to reduction, listeners are often able to understand conversational speech even in the presence of background noise. This dissertation investigates two reduction processes, namely regressive place assimilation across word boundaries, and massive reduction and provides novel data from the analyses of speech corpora combined with experimental results from perception studies to reach a better understanding of how humans handle natural speech. The successes and failures of two models dealing with data from natural speech are presented: The FUL-model (Featurally Underspecified Lexicon, Lahiri & Reetz, 2002), and X-MOD (an episodic model, Johnson, 1997). Based on different assumptions, both models make different predictions for the two types of reduction processes under investigation. This dissertation explores the nature and dynamics of these processes in speech production and discusses its consequences for speech perception. More specifically, data from analyses of running speech are presented investigating the amount of reduction that occurs in naturally spoken German. Concerning production, the corpus analysis of regressive place assimilation reveals that it is not an obligatory process. At the same time, there emerges a clear asymmetry: With only very few exceptions, only [coronal] segments undergo assimilation, [labial] and [dorsal] segments usually do not. Furthermore, there seem to be cases of complete neutralization where the underlying Place of Articulation feature has undergone complete assimilation to the Place of Articulation feature of the upcoming segment. Phonetic analyses further underpin these findings. Concerning deletions and massive reductions, the results clearly indicate that phonological rules in the classical generative tradition are not able to explain the reduction patterns attested in conversational speech. Overall, the analyses of deletion and massive reduction in natural speech did not exhibit clear-cut patterns. For a more in-depth examination of reduction factors, the case of final /t/ deletion is examined by means of a new corpus constructed for this purpose. The analysis of this corpus indicates that although phonological context plays an important role on the deletion of segments (i.e. /t/), this arises in the form of tendencies, not absolute conditions. This is true for other deletion processes, too. Concerning speech perception, a crucial part for both models under investigation (X-MOD and FUL) is how listeners handle reduced speech. Five experiments investigate the way reduced speech is perceived by human listeners. Results from two experiments show that regressive place assimilations can be treated as instances of complete neutralizations by German listeners. Concerning massively reduced words, the outcome of transcription and priming experiments suggest that such words are not acceptable candidates of the intended lexical items for listeners in the absence of their proper phrasal context. Overall, the abstractionist FUL-model is found to be superior in explaining the data. While at first sight, X-MOD deals with the production data more readily, FUL provides a better fit for the perception results. Another important finding concerns the role of phonology and phonetics in general. The results presented in this dissertation make a strong case for models, such as FUL, where phonology and phonetics operate at different levels of the mental lexicon, rather than being integrated into one. The findings suggest that phonetic variation is not part of the representation in the mental lexicon.
The transporter associated with antigen processing-like (TAPL) acts as a lysosomal ATP-dependent polypeptide transporter with broad length selectivity. To characterize in detail its substrate specificity, a procedure for solubilization, purification and functional reconstitution of human TAPL was developed. TAPL was expressed in Sf9 insect cells with the baculovirus expression system and solubilized from crude membranes. By intensive screening of detergents, the mild non-ionic detergents digitonin and dodecylmaltoside were found to be ideal for solubilization with respect to efficiency, long term stability, and functionality of TAPL. TAPL was isolated in a two-step procedure with a yield of 500 micro g/L cell culture and, subsequently, reconstituted into proteoliposomes. The KM(pep) for the peptide RRYCfKSTEL (f refers to fluorescence label) and KM(ATP) were determined to be 10.5 ± 2.3 micro M and 97.6 ± 27.5 micro M, respectively, which are in the same range as the Michaelis-Menten constants determined in the membranes. The peptide transport activity of the reconstituted TAPL strongly depends on the lipid composition. Interestingly, the E. coli lipids are prefered over other tested natural lipids extracts. Moreover, phosphatidylcholine, the most abundant phospholipid in eukaryotic cells influenced TAPL activity in a dose dependent manner. In addition, some negatively charged lipids like DOPA and DOPS increased peptide transport activity with preference for DOPS. However, DOPE or egg PG which are also negatively charged had no effect. It seems not only the charge but also the specific head group of phospholipids that has impact on the function of TAPL. With the help of combinatorial peptide libraries containing D-amino acid residues at defined positions as well as bulky fluorescein labeled peptides, the key positions of the peptides were localized to the N- and C-terminal residues with respect to peptide transport. The C-terminal position has the strongest selectivity since modification at this position shows strongest impact on peptide transport. Additionally, positions 2 and 3 of the peptide also have weak influence on peptide selectivity. Subsequently, the residue preferences at the key positions were systematically investigated by combinatorial peptide libraries with defined residues at certain positions. At both ends, TAPL favors positively charged, aromatic, or hydrophobic residues and disfavors negatively charged residues as well as asparagine and methionine. The residue preferences at the key positions are valid for peptide substrates with different length, indicating a general rule for TAPL selectivity. Besides specific interactions of both terminal residues, electrostatic interactions are important, since peptides with positive net charge are more efficiently transported than negatively charged ones. By size exclusion chromatography (SEC) and blue native PAGE, TAPL purified in the presence of digitonin or dodecylmaltoside had an apparent molecular weight of 200 kDa which is close to the theoretical molecular mass of the TAPL homodimer (172 kDa). The purified and reconstituted TAPL showed specific ATP hydrolysis activity which can be inhibited by orthovanadate. TAPL in proteoliposomes showed 6-fold higher ATP hydrolysis than digitonin solubilized protein, indicating the phospholipids impact on TAPL function. However, no peptide substrate stimulated ATPase activity was observed. For site-specific labeling of TAPL, eight cysteines in each half transporter were replaced by alanine or valine. The TAPL cys-less mutant showed the same peptide transport activity as TAPL wt. Based on the functional TAPL cys-less mutant, seven single cysteine mutants were introduced into strategic positions. All single cysteine mutants in the TMD did not influence peptide transport, whereas the mutant L701C, which is close to the conserved H-loop motif, displayed impaired transport. TAPL orthologs Haf-4 and Haf-9 from Caenorhabditis elegans possess around 40% sequence identities with TAPL and 50% with each other. Both proteins are putative half transporters and reported to be involved in the intestinal granule formation (Bauer, 2006; Kawai et al., 2009). To further understand the physiological functions of these two proteins, they were expressed in Sf9 insect cells. Haf-4 and Haf-9 showed weak but specific ATP- and peptide-dependent peptide transport activity for the given peptide RRYCfKSTEL. Therefore, it was proposed that the physiological roles for Haf-4 and Haf-9 might be related to their peptide transport activity. Besides forming functional homodimeric complex as estimated by the peptide transport activities, both half transporter could also form heteromers which was confirmed by coimmunoprecipitation. However, the heteromers showed decreased transport activity.
Trace elemental concentrations of bivalve shells content a wealthy of environmental and climatic information of the past, and therefore the studies of trace elemental distributions in bivalve shells gained increasing interest lately. However, after more than half century of research, most of the trace elemental variations are still not well understood and trace elemental proxies are far from being routinely applicable. This dissertation focuses on a better understanding of the trace elemental chemistry of Arctica islandica shells from Iceland, and paving the way for the application of the trace elemental proxies to reconstruct the environmental and climatic changes. Traits of trace elemental concentrations on A. islandica shells were explored and evaluated. Then based the geochemical traits of the shells, four non-environmental/climatic controlling is indentified. (1) Trace elemental concentrations of bivalve shells are effected by early diagenesis by the leach or exchange of elemental ions, especially in shell tip part, even with the protection of periostrucum; (2) The analytical methods also affect the results of trace elemental concentrations, especially for the element, such as Mg, which is highly enriched in organic matrices; (3) Shell organic matrices are found play a dominating role on the concentration of trace elements on A. islandica shells. Most trace elements only occurred in insoluble organic matrices (IOM), although others are only found in the carbonate fraction. IOM of A. islandica shells is significantly enriched in Mg, while Li and Na are more deplete in IOM, but enriched in shell carbonate. Ba is more or less even contented in IOM and shell carbonate. The concentrations of certain elements vary between primary layer and secondary layer; (4) The vital /physiological controlling on trace elemental distributions of bivalve shells is also confirmed. Six elemental (B, Na, Mg, Mn, Sr, and Ba) concentrations show significant correlation (exponential functions) with ontogenetic age and shell grow rates (logarithmic equations). It is worthy to remark that B, Mg, Sr and Ba concentrations are negatively correlated with shell growth rate, positive with ontogenetic age, while the concentrations of Na and Mn show the opposite trends. At last, all the controlling described above can be taken into account and corrected to extract the environmental and climatic signal by a kind of standardization. The derived six exponential functions of the high correlations between six trace elemental concentrations and ontogenetic year are applied to make the standardization of these element-Ca ratios. The gotten standardized indices are compared with the variations of environmental and climatic parameters in this region, and many correlations are found. Standardized indices of Sr/Ca ratios are strongly related to the sun spot number, autumn NAO, autumn Europe surface air temperature (SAT) and Arctic sea surface temperature anomaly (TA), and those of Mg/Ca ratios are strongly associated with Arctic TA, Europe SAT and Solar variation (irradiance). The variations of autumn Europe SAT demonstrated more similarity with standardized indices of B/Ca than other parameters. Except for the SAT index of Arctic, the standardized indices of Na/Ca showed no distinct relation to temperature. European precipitation and the Arctic sea level pressure index compared well the Na/Ca ratios of the shells, and so did the autumn NAO. Standardized indices of Mn/Ca were correlated with the number of hurricanes in the North Atlantic, Northern Europe SAT and sun spot number.
Energy and environment are two major concerns in the 21st century. At present, the energy required for the daily life still mainly relies on the traditional fossil fuel resources, but the caused air pollution problem and greenhouse effect have seriously threatened the sustainable development of mankind. Another adopted energy source which can provide a large fraction of electricity for the world is the nuclear fission reaction. However, the increasing high-radioactive spent nuclear fuels, which half-lives are usually >1 million years, are becoming the hidden perils to the earth. A great advance in accelerator physics and technology opens an opportunity to solve this dilemma between man and nature, because powerful accelerator-based neutron sources can play important roles for clean nuclear power production, for example: - The Accelerator-Driven System (ADS) can serve as an easy control of a sub-critical fission reactor so that the nuclear fuels will be burnt more completely and safely. - The EUROTRANS project launched by EU is investigating another application of the ADS technology to reduce the radiotoxicity and the volume of the existing nuclear waste greatly and quickly in a transmutation way. - The developing international IFMIF plant will be used to test and qualify reactor materials for future fusion power stations, which can produce much cleaner nuclear electricity more efficiently than the fission ones. Therefore, the R&D of high-power driver linacs (HPDL) is of a worldwide importance. As the proverb said, "everything is hard at the beginning", the front end is the most difficult part for realizing an HPDL machine. Based on the RFQ and H-type DTL structures, this dissertation is dedicated to study the beam dynamics in the presence of significantly strong space-charge effects while accelerating intense hardon beams in the low- and medium-beta-region. Besides the 5mA/30mA, 17MeV proton injector (RFQ+DTL) and the 125mA, 40MeV deuteron DTL of the above-mentioned EUROTRANS and IFMIF facilities, a 200mA, 700keV proton RFQ has been also intensively studied for a small-scale but ultra-intense neutron source FRANZ planned at Frankfurt University. The most remarkable properties of the FRANZ RFQ and the IFMIF DTL are the design beam intensities, 200mA and 125mA, which are the record values for the proton and deuteron linacs, respectively. Though the design intensities for the two development stages, XT-ADS (5mA) and EFIT (30mA), of the EUROTRANS injector are well within the capability of the modern RF linac technology, the special design concept for an easy upgrade from XT-ADS to EFIT brings unusual challenges to realize a linac layout which allows flexible operation with different beam intensities. To design the 200mA FRANZ RFQ and the two-intensity EUROTRANS RFQ, the classic LANL (Los Alamos National Laboratory) Four-Section Procedure, which was developed by neglecting the space-charge forces, is not sufficient anymore. Abandoning the unreasonable constant- B (constant-transverse-focusing-strength) law and the resulting inefficient evolution manners of dynamics parameters adopted by the LANL method, a new design approach so-called "BABBLE", which can provide a "Balanced and Accelerated Beam Bunching at Low Energy", has been developed for intense beams. Being consistent with the beam-development process including space-charge effects, the main features of the "BABBLE" strategy (see Pages 55-58) are: 1) At the entrance, the synchronous phase is kept at = phi s = -90° while a gradual increase in the electrode modulation is started so that the input beam can firstly get a symmetrical and soft bunching within a full-360° phase acceptance. 2) In the following main bunching section, B is increasing to balance the stronger and stronger transverse defocusing effects induced by the decreasing bunch size so that the bunching speed can be fast and safely increased. 3) When the real acceleration starts, the quickly increased beam velocity will naturally weaken the transverse defocusing effects, so B is accordingly falling down to avoid longitudinal emittance growths and to allow larger bore apertures. Taking advantage of the gentle initial bunching and the accelerated main bunching under balanced forces enabled by the "BABBLE" strategy, a 2m-long RFQ with beam transmission in excess of 98% and low emittance growths has been designed for FRANZ, and a 4.3m-long RFQ with almost no beam losses and flat emittance evolutions at both 5mA and 30mA has been designed for EUROTRANS. All design results have proven that the "BABBLE" strategy is a general design approach leading to an efficient and robust RFQ with good beam quality in a wide intensity-range from 0mA to 200mA (even higher). To design the IFMIF DTL and the injector DTL part of the EUROTRANS driver linac, which have been foreseen as the first real applications of the novel superconducting CH-DTL structure, intensive attempts have been made to fulfill the design goals under the new conditions, e.g. long drift spaces, SC transverse focusing elements and high accelerating gradients. For the IFMIF DTL, the preliminary IAP design has been considerably improved with respect to the linac layout as well as the beam dynamics. By reserving sufficient drift spaces for the cryosystem, diagnostic devices, tuner and steerer, introducing SC solenoid lenses and adjusting the Linac Design for Intense Hadron Beams accelerating gradients and accordingly other configurations of the cavities (see Pages 78-80), a more realistic, reliable and efficient linac system has been designed. On the other hand, the specifications and positions of the transverse focusing elements (see Pages 81-82) as well as the phase- and energy-differences between the bunch-center particle and the synchronous particle at the beginning of the phi s=0° sections have been totally redesigned (see Pages 83-84) resulting in good beam performances in both radial and longitudinal planes. For the EUROTRANS injector DTL, in addition to the above-mentioned procedures, extra optimization concepts to coordinate the beam dynamics between two intensities, such as employing short adjustable rebunching cavities with phi s = -90° (see Page 116), have been applied. ...
In this work, we extend the Hegselmann and Krause (HK) model, presented in [16] to an arbitrary metric space. We also present some theoretical analysis and some numerical results of the condensing of particles in finite and continuous metric spaces. For simulations in a finite metric space, we introduce the notion "random metric" using the split metrics studies by Dress and al. [2, 11, 12].
1. Fab co-complexes of proton pumping NADH:ubiquinone oxidoreductase (complex I) Fab fragments suitable for co-crystallization with complex I were generated using an immobilized papainbased protocol. The binding of the antibody fragments to complex I was verified using Surface Plasmon Resonance and size exclusion chromatography. The binding constants of the antibodies and their respective Fab fragments were found to be in the nanomolar range. This work presents the first report on successful crystallization of complex I (proton pumping NADH:ubiquinone oxidoreductase) from Yarrowia lipolytica with proteolytic Fab fragments. The quality of the crystals was significantly improved when compared to the initial experiments and the best crystals diffracted X-rays to a resolution of ~7 Å. The activity of complex I remained uninfluenced by antibody fragment binding. The initial diffraction data suggest that the complex I/Fab co-complex crystals represent a space group different to the one observed for the native protein. Ongoing experiments are aimed at further enhancements of the diffraction quality of the crystals. Providing a different space group the CI/Fab co-complexes may become a very useful approach for structure determination of the enzyme. Moreover, the bound Fab offers an additional possibility to generate phase information. The antibody-mediated crystallization represents a valuable tool in structural characterization of the NADH:oxidoreductase subcomplexes or even single subunits. 2. UDP-glucose pyrophosphorylase UDP-glucose pyrophosphorylase from Yarrowia lipolytica displays affinity towards Ni2+ NTA and was first detected in a contaminated sample of complex I. Following, separation from complex I, Ugp1p was purified using anion exchange chromatography. Sequence similarity studies revealed high identity to other known pyrophosphorylases. As indicated by laser-based mass spectrometry method (LILBID) Ugp1p from Y. lipolytica builds octamers similarly to the enzyme from Saccharomyces cerevisiae. The initial crystals grew as thin needles favorably in sitting drop setups. The size of the crystals was increased by employment of a micro batch technique. The improved crystals diffracted X-rays to a resolution of 3.2 Å at the synchrotron beamline. Structural characterization is under way using a molecular replacement approach based on the published structure of baker’s yeast UGPase.
Photo-initiated processes, like photo-excitation and -deexcitation, internal conversion, excitation energy transfer and electron transfer, are of importance in many areas of physics, chemistry and biology. For the understanding of such processes, detailed knowledge of excitation energies, potential energy surfaces and excited state properties of the involved molecules is an essential prerequisite. To obtain these informations, quantum chemical calculations are required. Several quantum chemical methods exist which allow for the calculation of excited states. Most of these methods are computationally costly what makes them only applicable to small molecules. However, many biological systems where photo-processes are of interest like light-harvesting complexes in photosynthesis or the reception of light in the human eye by rhodopsin are quite large. For large systems, however, only few theoretical methods remain applicable. The currently most widely used method is time-dependent density functional theory (TD-DFT), which can treat systems of up to 200–300 atoms with the excitation energies of some excited states exhibiting errors of less than 0.5 eV. Yet, TD-DFT has several drawbacks. The most severe failure of TD-DFT is the false description of charge transfer states which is particularly problematic in case of larger systems where it yields a multitude of artificially low-lying charge transfer states. But also Rydberg states and states with large double excitation character are not described correctly. Still, if these deficiencies are kept in mind during the interpretation of results, TD-DFT is a useful tool for the calculation of excited states. In my thesis, TD-DFT is applied in investigations of excitation energy and electron transfer processes in light-harvesting complexes. Since light-harvesting complexes, which consist of thousands of atoms, are by far too large to be calculated, model complexes for the processes of interest are constructed from available crystal structures. The model complexes are used to calculate potential energy curves along meaningful reaction coordinates. Artificial charge transfer states are corrected with the help of the so-called ∆DFT method. The resulting potential energy curves are then interpreted by comparison with experimental results. For the light-harvesting complex LH2 from purple bacteria the experimentally observed formation of carotenoid radical cations is studied. It is shown that the carotenoid radical cation is formed most likely via the optically forbidden S1 state of the carotenoid. In light-harvesting complex LHC-II of green plants the fast component of the so-called non-photochemical quenching (NPQ) is investigated. Two of several different hypotheses on the mechanism of NPQ, which have been proposed recently, are studied in detail. The first one suggests that NPQ proceeds via simple replacement of violaxanthin by zeaxanthin in the binding pocket in LHC-II. However, the calculated potential energy curves exhibit no difference between violaxanthin and zeaxanthin in the binding pocket. In combination with experimental results it is thus shown that simple replacement alone does not mediate NPQ in LHC-II. The second hypothesis proposes conformational changes of LHC-II that lead to quenching at the central lutein and chlorophyll molecules during NPQ. My TD-DFT calculations demonstrate that if this mechanism is operative, only the lutein 1 which is one of two central luteins present in LHC-II can take part in the quenching process. This is corroborated by recent experiments. Though several conclusions can be drawn from the investigations using TD-DFT, the interpretability of the results is limited due to the deficiencies of the method and of the models. To overcome the methodological deficiencies, more accurate methods have to be employed. Therefore, the so-called algebraic diagrammatic construction scheme (ADC) is implemented. ADC is a widely overlooked ab initio method for the calculation of excited states, which is based on propagator theory. Its theoretical derivation proceeds via perturbation expansion of the polarization propagator, which describes electronic excitations. This yields separate schemes for every order of perturbation theory. The second order scheme ADC(2), which is employed here, is the equivalent to the Møller-Plesset ground state method MP(2), but for excited states. It represents the computationally cheapest excited state method which can correctly describe doubly excited states, as well as Rydberg and charge transfer states. The quality of ADC(2) results is demonstrated in calculations on linear polyenes which serve as model systems for the larger carotenoid molecules. The calculations show that ADC(2) describes the three lowest excited states of polyenes sufficiently well, particularly the optically forbidden S1 state which is known to possess large double excitation character. Yet, the applicability of the method is limited compared to TD-DFT due to the much larger computational requirements. To facilitate the calculation of larger systems with ADC(2) a new variant of the method is developed and implemented. The variant employs the short-range behavior of electron correlation to reduce the computational effort. As a first step, the working equations of ADC(2) are transformed into a basis of local orbitals. In this basis negligible contributions of the equations which are due to electron correlation can be identified based on the distances of local orbitals. A so-called “bumping” scheme is implemented which removes the negligible parts during a calculation. This way, the computation times as well as the disk space requirements can be reduced. With the “bumping” scheme several new parameters are introduced that regulate the amount of “bumping” and thereby the speed and the accuracy of computations. To determine useful values for the parameters an evaluation is performed using the linear polyene octatetraene as test molecule. From the evaluation an optimal set of parameter values is obtained, so that the computation times become minimal, while the errors in the excitation energies due to the “bumping” do not exceed 0.15 eV. With further calculations on various molecules of different sizes it is tested if these parameter values are universal, i.e. if they can be used for all molecules. The test calculations show that the errors in the excitation energies are below 0.15 eV for all test systems. Additionally, no trend is visible for the errors that their magnitude might depend on the system. In contrast, the amount of disregarded contributions in the calculations increases drastically with growing system size. Thus, the local variant of ADC(2) can be used in future to reliably calculate excited states of systems which are not accessible with conventional ADC(2).
This study analyses five British translations of Bertolt Brecht's 'Mutter Courage und ihre Kinder'. Two of these translations were written by speakers of German, and three by well-known British playwrights with no knowledge of the source text language. Four have been produced in mainstream British theatres in the past twenty-five years. The study applies translation studies methodology to a textual analysis which focuses on the translation of techniques of linguistic "Verfremdung", as well as linguistic expression of the comedy and of the political dimension in the work. It thus closes the gap in current Brecht research in examining the importance of his idiosyncratic use of language to the translation and reception of his work in the UK. The study assesses the ways in which the translator and director are influenced by Brecht's legacy in the UK and in turn, what image of Brecht they mediate through the production on stage. To this end, the study throws light on the formation of Brecht's problematic reputation in the UK, and it also highlights the social and political circumstances in early twentieth century Germany which prompted Brecht to develop his theory of an epic theatre. The focus on a linguistic examination allows the translator's contribution to the production process to be isolated. Together with an investigation of the reception of each performance text, this in turn facilitates a more accurate assessment of the translator and director's respective influence in the process of transforming a foreign-language text onto a local stage. The analysis also sheds light on the different approaches taken by speakers of German, and playwrights creating an English version from a literal translation. It pinpoints losses in translation and adaptation, and suggests how future versions may avoid these.
Macrophages show a remarkable functional plasticity, which enables them to change their phenotype in response to environmental signals. They are key players during infection by initiating inflammation through the release of proinflammatory mediators. Furthermore, macrophages contribute to the resolution of inflammation by phagocytosis of apoptotic granulocytes. Phagocytosis of apoptotic cells (AC) induces an anti-inflammatory phenotype in macrophages and protects them against apoptosis. However, mechanistic details provoking these phenotype alterations are incompletely understood. Therefore, the aim of my Ph.D. thesis was to investigate the molecular basis of anti-inflammatory macrophage polarization. In the first part of my studies, I investigated the expression of heme oxygenase (HO)-1 in macrophages following treatment with supernatants from AC. HO-1 catalyzes the first and rate-limiting step of heme degradation and potentially bears anti-inflammatory as well as anti-apoptotic potential. I was able to show biphasic upregulation of HO-1 by AC supernatants. The first phase of HO-1 induction at 6 h required activation of p38 MAPK and was accomplished by the bioactive lipid sphingosine-1-phosphate (S1P) engaging S1P receptor 1 (S1P1). However, the second wave of HO-1 induction at 24 h was attributed to autocrine signaling of vascular endothelial growth factor (VEGF) A, whose expression was facilitated by S1P. The release of VEGFA from macrophages was STAT1-dependent, whereas VEGFA itself acted on the macrophage HO-1 promoter via STAT1/STAT3 heterodimer binding. Knockdown of HO-1 revealed its relevance in promoting enhanced expression of the anti-apoptotic proteins B cell leukemia/lymphoma-2 (Bcl-2) and B cell leukaemia/lymphoma-x long (Bcl-XL), as well as the anti-inflammatory adenosine receptor A2A. MHC II and indoleamine 2,3-dioxygenase expression were also affected by ACsupernanatants, but were not HO-1 dependent. Unexpectedly, S1P1 was also upregulated following treatment with AC supernatants. Thus, I considered whether S1P1 induction could specifically be mediated by alternative macrophage activating factors. The expression of S1P1 was enhanced in the presence of the alternative activation stimuli IL-4 as well as IL-10, whereas it was unchanged following incubations with LPS, interferon-g or S1P. My next aim was to investigate the expression of the different S1P receptor isoforms in macrophages following treatment with supernatants form AC. While the expressions of S1P1 as well as S1P3 were induced by exposure to supernatants from AC, S1P2 expression was unaffected. As S1P1/3 and S1P2 are conflictively involved in the regulation of cell migration, I asked for a correlation between increased S1P receptor expression and enhanced migration rate. Indeed, macrophages showed enhanced motility following treatment with supernatants form AC, which was inhibited in S1P1 knockout macrophages. In summary, my findings indicate that HO-1, which is induced by AC-derived S1P, is critically involved in macrophage polarization towards an alternatively activated macrophage phenotype. S1P1 seems to represent a central checkpoint during macrophage activation. On the one hand, S1P1 is induced by supernatants form AC and promotes migration of macrophages. On the other hand, it mediates the induction of HO-1, which is accompanied by antiinflammatory as well as anti-apoptotic signaling. Furthermore, my studies provide evidence that upregulation of HO-1 and S1P1 in macrophages may contribute to the resolution of inflammation by establishing an anti-inflammatory macrophage phenotype and provoking macrophage migration along the vascular S1P gradient out of an inflammatory environment into the lymph.
The transcription factor p63 is part of the p53 protein family, which consists of three members, p53, p63 and p73. P63 shares structural similarity with all family members, but is associated to different biological functions than p53 or p73. While p53 is mainly linked to tumor suppression and p73 is connected with neuronal development, p63 has been connected to critical biological roles within ectodermal development and skin stem cell biology as well as supervision of the genetic stability of oocytes. Due to its gene structure p63 is expressed as at least six different isoforms, three of them containing a N-terminal transactivation domain. The isoforms that are of biological relevance both have a C-terminal inhibitory domain that negatively regulates the transcriptional activity. This inhibitory domain is supposed to contain two individual components of which one is internally binding and masking the transactivation domain while the other one can be sumoylated. To further investigate this domain a mutational analysis with the help of transactivation assays in SAOS2 cells was carried out to identify the critical amino acids within the inhibitory domain and the impact on transcriptional activity of TAp63alpha, the p63-isoform which is essential for the integrity of the female germline. The results of these experiments show that a stretch of approximately 13 amino acids seems to be important for the regulation of transcriptional activity in TAp63alpha, due to the increased transcriptional activity occurring in this region after mutation. Additional experiments showed that this mechanism is distinct from sumoylation, which seems to have only implications for the intracellular level of TAp63alpha. As a conclusion, the C-terminus of the Tap63alpha is essential for two different mechanisms, which control the transcriptional activity of the protein. Both regulatory elements are independent from each other and can now be restricted to certain amino acids. Activation of the wild type protein might take place in the identified region via post-translational modification. Furthermore an inhibition assay was carried out to test if the same region might have implications on the second biological relevant isoform deltaNp63alpha. The results show that the same amino acids which show an impact on transcriptional activity in Tap63alpha lead to a significant change in functional behaviour of deltaNp63alpha. There is a possibility that both proteins are regulated with opposite effects via the same mechanisms, based at the C-terminus of the p63alpha-isoforms. In both cases a modification of these residues could lead to a more opened conformation of the protein with consequences on promoter binding, which can be even important for deltaNp63alpha with respect to promoter squelching. Both alpha-isoforms seem to be regulated via the C-terminus and to elucidate if that is also the case for TAp63gamma a deletion analysis was carried out. The results show that there are also amino acids within the C-terminus of TAp63gamma, which have implications on the transcriptional activity of the protein. Therefore the C-terminus seems to play a major role for regulation of diverse p63 isoforms.
Photosystem (PS) I is a huge membrane protein complex which coordinates around 200 co-factors. Upon light excitation a charge separation at the PS I reaction centre is induced which leads to an electron transport across the thylakoid membrane and the generation of redox equivalents needed for several biochemical reactions, e.g. the synthesis of sugars. For higher plants and cyanobacteria the crystal structure of PS I complexes were resolved to resolutions of 4.4 Å and 2.5 Å. Furthermore, supramolecular structures of PS I of eukaryotic algae, mainly of the green line, were obtained recently. However, up to now, no structure of diatoms is available yet. Diatoms are key players in global primary production and derived from a secondary endosymbiosis event. Their chloroplasts are surrounded by four envelope membranes and their thylakoids are evenly arranged in bands of three, i.e. no separation in grana and stroma regions is apparent. In this thesis a protocol was developed to isolate a functional PS I complex of diatoms which can be used for structural analysis by transmissional electron microscopy (TEM). A photosystem I-fucoxanthin chlorophyll protein (PS I-FCP) complex was isolated from the pennate diatom Phaeodactylum tricornutum by ion exchange chromatography. Spectroscopic analysis proved that bound Fcp polypeptides function as a light-harvesting complex. An active light energy transfer from Fcp associated pigments, Chl c and fucoxanthin, towards the PS I core was proven by fluorescence spectroscopy. Oxidised minus reduced difference spectroscopy evidenced the activity of the PS I reaction centre P700 and yielded a chlorophyll a/P700 ratio of approximately 200:1. These data indicate that the isolated PS I-FCP complex exceeds the PS I cores from cyanobacteria and higher plants in the numbers of chlorophyll a molecules. Because of the strict conservation of PS I cores among organisms the additional 100 chlorophyll a molecules must either be coordinated by Fcps or function as linker molecules between the Fcp antenna and the PS I core as shown for the PS I-LHC I complex of higher plants. To tell something about the structural organisation, the PS I-FCP complex was compared with its cyanobacterial and higher plant counterparts. Whereas cyanobacterial PS I cores aggregate to trimers, usually without associated antennae, higher plant PS I is a monomer and binds additionally two LHC I heterodimers. BN-PAGE and gel filtration experiments showed that also diatoms contain PS I monomers associated with Fcps as light-harvesting antenna. First TEM studies evidenced these observations. Negatively stained PS I-FCP particles had an increased size compared to PS I cores of other organisms. No PS I trimers or higher oligomers have been found. The calculated diameter and shape of the particles correspond to PS I-LHC I particles obtained from green algae, which also comprise of a higher number of LHC I polypeptides compared to the higher plant x-ray structure. Additionally, the analysis of polypeptides indicates that the PS I associated Fcps differ from the free Fcp pool and also from Fcps of a PS II enriched fraction. The assumption that diatoms harbour just one Fcp antenna that serve both Photosystems equally seems to be wrong. To further study the association of Fcps with the two Photosystems, both complexes plus the free FCP complexes were isolated from the centric diatom Cyclotella meneghiniana. Because of the availability of antibodies directed against specific Fcp polypeptides of Cyclotella the PS I-FCP complex of Phaeodactylum could not be used. A trimeric FCP complex, FCPa, and a higher FCP oligomer, FCPb, have already been described for C. meneghiniana. The latter is assumed to be composed of only Fcp5, whereas the FCPa contains Fcp2 and Fcp6. Biochemical and spectroscopical evidences revealed a different subset of associated Fcp polypeptides within the isolated photosystem complexes. Whereas the PS II associated Fcp antenna resembles FCPa, at least three different Fcp polypeptides are associated with PS I. By re-solubilisation of the PS I complex and a further purification step Fcp polypeptides were partially removed from PS I and both fractions were analysed again by biochemical and spectroscopical means, as well as by HPLC. Thereby Fcp4 and a so far undescribed 17 kDa Fcp were found to be strongly coupled to PS I, whereas another Fcp, presumably Fcp5, is only loosely bound to the PS I core. Thus an association of FCPb and PS I is assumed.
This study addresses the situation of the Sorbs, an indigenous minority living in Lusatia, Germany. Under the overarching rubric of ethnic and nationalist projects, women are usually symbolized as the guardians of culture and language. Women’s experiences as subjects in everyday life and in multi-facetted social practices therefore become veiled. The main concern in this book is to discuss how the women who identify themselves as/with Sorbs studied here construct their identities in the modern world, how they approach a sense of self and how they position themselves in their everyday lives, what kind of processes they undergo in their identity construction, and which factors are implicated in the formation of these identities. Investigating the Sorbian minority as the research subject and focusing on the female gender primarily involves intersections of ethnicity and gender, which are the points of departure for this study. As the research progresses, women’s gradual active construction of gender and ethnicity while living their everyday lives reveals a construction of multifarious and complex identifications across differences of gender, ethnicity, culture, religion and class. The results of research create Sorbian culture anew, craft Sorbian identity afresh and render the notion of Sorbian women in new terms. New meanings encased in these conceptions actually contain an active and transformative impetus. This thrust forces these ideas to undergo a process of redefinition. It is the life experiences people have in everyday practices that impel us to envisage identity construction as a dynamic, never-ending and open-ended articulation of one’s positionings.
Sepsis is caused by infection and often followed by an overwhelming inflammatory response. This can lead to shock, organ failure and even death. Each year approximately 60,000 people die in Germany due to sepsis. There is good evidence that sepsis is associated with failure of the hypothalamic-pituitary-adrenal-axis. In patients with sepsis, glucocorticoids (e.g. corticosterone, cortisol) released from adrenal glands play an essential role in preventing an excessive pro-inflammatory response. Adrenal insufficiency occurs in a large number of patients with septic shock and is associated with an increased mortality. In the innate immune system, Toll-like receptors (TLRs) play a crucial role in its onset by recognizing pathogenassociated molecules. It is well known that there are interactions between the immune and endocrine stress systems; glucocorticoids and TLRs regulate each other in a bi-directional way. Therefore, a coordinated response of the adrenal and immune system is of vital importance for survival during severe inflammation. This experimental study focuses on the role of TLR-2, TLR-4 and TLR-9 during adrenal stress. The results show that in mice, the absence of TLR-2 and TLR-4, but not TLR-9 leads to altered adrenal morphology, relating to size and cellular structure. However, this alteration does not appear to compromise the phenotype of TLR knock-out mice. Mice deficient of TLR-2, 4 and 9 are not able to respond adequately to inflammatory stress induced by their potential ligands lipopolysaccharide (LPS), lipoteichoic acid (LTA) or cytidine phosphate guanosine-oligodeoxynucleotides (CpG-ODN). This impaired adrenal stress response appears to be associated with a decrease in systemic and intra-adrenal cytokine expressions. Taken together, these results suggest that TLR-2, 4 and 9 are key players in the immuno-endocrine response during inflammation and SIRS. In conclusion, TLRs play a crucial role in the immune-adrenal crosstalk. This close functional relationship needs to be considered in the treatment of inflammatory diseases where an intact adrenal stress response is required. Furthermore, TLR polymorphisms could contribute to the underlying mechanisms of impaired adrenal stress response in patients with bacterial sepsis
The NADH:ubiquinone oxidoreductase (complex I) is a large membrane bound protein complex coupling the redox reaction of NADH oxidation and quinone reduction to vectorial proton translocation across bioenergetic membranes. The mechanism of proton pumping is still unknown; it seems however that the reduction of quinone induces conformational changes which drive proton uptake from one side and release at the other side of the membrane. In this study the proposed quinone and inhibitor binding pocket located at the interface of the 49-kDa and PSST subunits was explored by a large number of point mutations introduced into complex I from the strictly aerobic yeast Yarrowia lipolytica. Point mutations were systematically chosen based on the crystal structure of the hydrophilic domain of complex I from Thermus thermophilus. In total, the properties of 94 mutants at 39 positions which completely cover the lining of the large putative quinone and inhibitor binding cavity are described and discussed here. A structure/function analysis allowed the identification of functional domains within the large putative quinone binding cavity. A possible quinone access path ranging from the N-terminal beta-sheet of the 49-kDa subunit into the pocket to tyrosine 144 could be defined, since all exchanges introduced here, caused an almost complete loss of complex I activity. A region located deeper in the proposed quinone binding pocket is apparently not important for complex I activity. In contrast, all exchanges of tyrosine 144, even the very conservative mutant Y144F, essentially abolished dNADH:DBQ oxidoreductase activity of complex I. However, with higher concentrations of Q1 or Q2 the dNADH:Q oxidoreductase activity was largely restored in the mutants with the more conservative exchanges. Proton pumping experiments showed that this activity was also coupled to proton translocation, indicating that these quinones were reduced at the physiological site. However, the apparent Km values for Q1 or Q2 were drastically increased, clearly demonstrating that tyrosine 144 is central for quinone binding and reduction. These results further prove that the enzymatically relevant quinone binding site of complex I is located at the interface of the 49-kDa and PSST subunits. The quinone binding pocket is thought to comprise the binding sites for a plethora of specific complex I inhibitors that are usually grouped into three classes. The large array of mutants targeting the quinone binding cavity was examined with a representative of each inhibitor class. Many mutants conferring resistance were identified which, depending on the inhibitor tested, clustered in well defined and partially overlapping regions of the large putative quinone and inhibitor binding cavity. Mutants with effects on type A (DQA) and type B (rotenone) inhibitors were found in a subdomain corresponding to the former [NiFe] site in homologous hydrogenases, whereby the type A inhibitor DQA seems to bind deeper in this domain. Mutants with effects on the type C inhibitor (C12E8) were found in a narrow crevice. Exchanging more exposed residues at the border of these well defined domains affected all three inhibitor types. Therefore, the results as a whole provide further support for the concept that different inhibitor classes bind to different but partially overlapping binding sites within a single large quinone binding pocket. In addition, they also indicate the approximate location of the binding sites within the structure of the large quinone and inhibitor binding cavity at the interface of the 49 kDa and the PSST subunit. It has been proposed earlier that the highly conserved HRGXE-motif in the 49-kDa subunit forms a part of the quinone binding site of complex I. Mutagenesis of the HRGXE-motif, revealed that these residues are rather critical for complex I assembly and seem to have an important structural role. The question why iron-sulfur cluster N1a is not detectable by EPR in many models organisms is not solved yet. Introducing polar and positively charged amino acid residues close to this cluster in order to increase its midpoint potential did not result in the appearance of the cluster N1a EPR signal in mitochondrial membranes from the mutants. Clearly, further research will be necessary to gain insights to the function of this iron-sulfur cluster in complex I. In an additional project, a new and simple in vivo screen for complex I deficiency in Y. lipolytica was developed and optimized. This assay probes for defects in complex I assembly and stability, oxidoreductase activity and also proton pumping activity by complex I. Most importantly, this assay is applicable to all Y. lipolytica strains and could be used to identify loss-of-function mutants, gain-of-functions mutants (i.e. resistance towards complex I inhibitors) and revertants due to mutations in both nuclear and mitochondrially encoded genes of complex I subunits.
In this thesis we have studied the physics of different ultracold Bose-Fermi mixtures in optical lattices, as well as spin 1=2 fermions in a harmonic trap. To study these systems we generalized dynamical mean-field theory for a mixture of fermions and bosons, as well as for an inhomogeneous environment. Generalized dynamical mean-field theory (GDMFT) is a method that describes a mixture of fermions and bosons. This method consists of Gutzwiller mean-field for the bosons, and dynamical mean-field theory for the fermions, which are coupled on-site by the Bose-Fermi density-density interaction and possibly a Feshbach term which converts a pair of up and down fermions into a molecule, i.e. a boson. We derived the self-consistency equations and showed that this method is well-controlled in the limit of high lattice coordination number z. We develop real-space dynamical mean-field theory for studying systems in an inhomogeneous environment, e.g. in a harmonic trap. The crucial difference compared to standard DMFT is that we are taking into account that different sites are not equivalent to each other and thus take into account the inhomogeneity of the system. Different sites are coupled by the real-space Dyson equation. ...
Induced charge computation
(2009)
One of the main aspects of statistical mechanics is that the properties of a thermodynamics state point do not depend on the choice of the statistical ensemble. It breaks down for small systems e.g. single molecules. Hence, the choice of the statistical ensemble is crucial for the interpretation of single molecule experiments, where the outcome of measurements depends on which variables or control parameters, are held fixed and which ones are allowed to fluctuate. Following this principle, this thesis investigates the thermodynamics of a single polymer pulling experiments within two different statistical ensembles. The scaling of the conjugate chain ensembles, the fixed end-to-end vector (Helmholtz) and the fixed applied force (Gibbs), are studied in depth. This thesis further investigates the ensemble equivalence for different force regimes and polymer-chain contour lengths. Using coarse-grained molecular dynamic simulations, i.e. Langevin dynamics, the simulations were found to complement the theoretical predictions for the scaling of ensemble difference of Gaussian chains in different force-regimes, giving special attention to the zero force regime. After constructing Helmholtz and Gibbs conjugate ensembles for a Gaussian chain, two different data sets of thermodynamic states on the force-extension plane, i.e. force-extension curves, were generated. The ensemble difference is computed for different polymer-chain lengths by using force-extension curves. The scaling of the ensemble difference versus relative polymer-chain length under different force regimes has been derived from the simulation data and compared to theoretical predictions. The results demonstrate that the Gaussian chain in the zero force limit generates nonequivalent ensembles, regardless of its equilibrium bond length and polymer-chain contour length. Moreover, if polymers are charged in confinement, coarse-graining is problematic, owing to dielectric interfaces. Hence, the effect of dielectric interfaces must be taken into account when describing physical systems such as ionic channels or biopolymers inside nanopores. It is shown that the effect of dielectrics is crucial for the dynamics of a biopolymer or an ion inside a nanopore. In the simulations, the feasibility of an efficient and accurate computation of electrostatic interactions in the presence of an arbitrarily shaped dielectric domain is challenging. Several solutions for this problem have been previously proposed in the literature such as a density functional approach, or transforming problem at hand into an algebraic problem ( Induced Charge Computation (ICC) ) and boundary element methods. Even though the essential concept is the same, which is to replace the dielectric interface with a polarization charge density, these approaches have been analyzed and the ICC algorithm has been implemented. A new superior boundary element method has been devised utilizing the force computation via the Particle-Particle Particle-Mesh (P3M) method for periodic geometries (ICCP3M). This method has been compared to the ICC algorithm, the algebraic solutions, and to density functional approaches. Extensive numerical tests against analytically tractable geometries have confirmed the correctness and applicability of developed and implemented algorithms, demonstrating that the ICCP3M is the fastest and the most versatile algorithm. Further optimization issues are also discussed in obtaining accurate induced charge densities. The potential of mean force (PMF) of DNA modelled on a coarsed-grain level inside a nanopore is investigated with and without the inclusion of dielectric effects. Despite the simplicity of the model, the dramatic effect of dielectric inclusions is clearly seen in the observed force profile.
Central America is one of the world’s most herpetological diverse areas in relation to its size. Nicaragua is the largest country in this region and separates Nuclear from Lower Central America. It is one of the least herpetological explored countries in Central America and few studies dealing with the herpetofauna of a potion or the entire country have been published. I here update the checklist of the Nicaraguan herpetofauna, present taxonomic revisions of some difficult species complexes, compare the similarities of the composition of the herpetofaunal communities in the major forest formations present in the country within a zoogeographical context, and identify those species with a greater vulnerability risk in Nicaragua. Taxonomy The herpetofauna of Nicaragua currently consists of 244 species representing 134 genera and 42 families with 78 amphibian species representing 35 genera and 15 families, and 166 reptile species representing 99 genera and 27 families, which includes six marine species. Sixteen species (12 amphibians and four reptiles) are endemic to the country. Of the 12 endemic amphibian species, three are here described. In addition, five genera (Anotheca, Cerrophidion, Duellmanohyla, Isthmohyla, and Rhinobothryum) and two species (Rhadinea godmani and Urotheca decipiens) are known to occur both north and south of Nicaragua although there are no voucher specimens of these taxa to confirm their presence in country. I complete a bibliographic research updating the nomenclature changes and provide a brief herpetological history of Nicaragua, a recompilation of all species described upon Nicaraguan material and their current synonymy, the first time each species was recorded from the country, and a list of all recognized subspecies occurring in Nicaragua. I discuss the taxonomic uncertainties among the Nicaraguan populations of amphibians and reptiles and take further detailed taxonomic revisions on selected Nicaraguan species groups from the genera Anolis, Bolitoglossa, and Craugastor along their known distributional range. I describe five new species of herpetofauna (three of which are based on Nicaraguan material), redescribe five species of Anolis (three of which occur in Nicaragua), and provide voucher specimens of five other species for the first time in Nicaragua. In detail: • I studied the pholidosis, morphometrics as well as hemipenis and dewlap morphology in Anolis wermuthi, an anole endemic to the highlands of northern Nicaragua. I examine patterns of geographic variation using discriminant function analysis and discuss the characters that vary both individually and among populations. The results indicate that A. wermuthi is a single species with several disjunct, slightly divergent populations. I provide a standardized description, illustrations of the everted hemipenis of an adult topotype, the male and female dewlap, and a distribution map. I also provide brief descriptions of the localities where this species occurs and some ecological notes. • I studied the pholidosis, morphometrics as well as hemipenis morphology in the Central American anole species Anolis humilis, A. quaggulus, and A. uniformis. The three taxa are distinct in hemipenis morphology. However, very little differentiation in pholidotic and morphometric characters is documented. I document interspecific variation in several characters but with overlap of the documented ranges. A discriminant function analysis based on five pholidotic characters yielded a scatter diagram that showed large overlap between the clusters of the three taxa. I provide head scalation illustrations, an identification key, a distribution map, and standardized descriptions of the commonly distributed in Nicaragua A. quaggulus as well as of the other two species. • I describe two new species of anoles (genus Anolis) from Panama formerly referred to as Anolis limifrons. The two new species, Anolis apletophallus and Anolis cryptolimifrons, differ from A. limifrons by having a large bilobed hemipenis (small and unilobed in A. limifrons). The new species differ from each other in male dewlap size and coloration. I provide illustrations of the head scalation, everted hemipenis, and dewlap, an identification key, a distribution map, and standardized descriptions of the commonly distributed in Nicaragua A. limifrons and the two new species described herein. • I describe two new species of salamanders of Bolitoglossa from southern Nicaragua. Bolitoglossa indio is known from Río Indio in the lowlands of the Río San Juan area and Bolitoglossa insularis from the premontane slopes of Volcán Maderas on Ometepe Island. The two new species are of unknown affinities but both differ from their congeners in coloration. Bolitoglossa indio is most similar to B. mexicana and B. odonnelli from which differ by having both broad dorsolateral pale brown stripes not clearly delimited in outline. Bolitoglossa insularis is most similar to B. mombachoensis and B. striatula from which differ by the absence of dark or light defined stripes on dorsum and venter. • I describe a new species of frog of the genus Craugastor from Río San Juan, Nicaragua. The new species, Craugastor chingopetaca, is assigned to the fitzingeri group and differs from most Central American species of that group by the absence of a midgular pale stripe. Within the fitzingeri group it is most similar to C. crassidigitus and C. talamancae from which it differs in several morphological characteristics such as more extensive webbing, retuse disk covers on some digits, and relative toe length. • I provide voucher specimens of Cochranella spinosa, Kinosternon angustipons, Mesaspis moreletii, Cnemidophorus lemniscatus and Adelphicos quadrivirgatum for the first time in Nicaragua. I include descriptions, illustrations, and brief ecological notes for the five new country records. Zoogeography Based on the concept of ecological formations proposed by HOLDRIDGE (1967), nine forest formations are found in Nicaragua. Of the total number of terrestrial species of herpetofauna found in Nicaragua, 131 species (55.0%) occur in Lowland Wet Forest, 21 of which (8.8%) are restricted to this forest formation, 168 species (70.6%) occur in Lowland Moist Forest, 15 of which (6.3%) are restricted to this forest formation, 84 species (35.3%) occur in Lowland Dry Forest, four of which (1.7%) are restricted to this forest formation, 47 species (19.7%) occur in Lowland Arid Forest, with no species restricted to this forest formation, 59 species (24.8%) occur in Premontane Wet Forest, three of which (1.3%) are restricted to this forest formation, 116 species (48.7%) occur in Premontane Moist Forest, 10 of which (4.2%) are restricted to this forest formation, 51 (21.4%) species occur in Premontane Dry Forest, with no species restricted to this forest formation, 13 species (5.5%) occur in Lower Montane Wet Forest, two of which (0.8%) are restricted to this forest formation, and 50 species (21.0%) occur Lower Montane Moist Forest, seven of which (2.9%) are restricted to this forest formation. The Coefficient of Biogeographic Resemblance algorithm show a distinct composition of the herpetofauna from the isolated highlands of northeastern Nicaragua, which is characterized by a high proportion of endemic species. Two other clusters are evident when analyzing the herpetofaunal similarities among Nicaragua, the Pacific versant and the central mountains and the Atlantic lowlands. In addition, the Pacific lowlands are characterized by a relatively homogeneous composition of the herpetofauna. In contrast, many species have their northern limit of distribution in the Atlantic lowlands with the ranges of most of these species ending in southern Nicaragua. The central mountains constitute the southern limit of distribution of several highland species. In general, there is a greater contribution of reptile than amphibian species to the total herpetofauna present in each forest formation. This unbalance is slightly higher in the dry than in the moist parts of the country. The similarities in the composition of the reptiles between the different forests formations seem to be relatively distinct on an elevation factor, whereas in amphibians similarities might be better explained in correlation with humidity. The total amount of amphibian and reptile species in Nicaragua has a Middle American Element dominance and varies between amphibians and reptiles, with and a greater South American Element influence in anurans and a greater Old Northern Element influence in reptiles. In general, there is a greater percentage of species with a South American Element in extreme southeastern Nicaragua with a decreasing tendency towards northern Nicaragua. Taking in account the geography and geologic history of Nicaragua as well as the known Central American dispersal routes, I identify species of probable occurrence in Nicaragua as well as those places with a greater potential to hold undescribed endemic species. Conservation In Nicaragua, no amphibian or reptile populations are entirely free from anthropogenic impact. I determine the endangerment level of all Nicaraguan amphibian and reptile species using the IUCN categorizations and the Environmental Vulnerability Scores. Seventy-six species (31.9%) of Nicaraguan amphibians and terrestrial reptiles have high vulnerability, 118 (49.6%) medium vulnerability, and 44 (18.5%) low vulnerability. Eighteen species (7.4% of the total herpetofauna) are unknown from protected areas, including 13 high vulnerability species (three are endemic), four medium vulnerability species, and one low vulnerability species. To preserve the future of Nicaragua’s amphibians and reptiles, every species should reside in at least one protected area, the protected areas must be guarded, and monitoring programs are needed to detect changes in amphibian and reptile populations, prioritizing highly vulnerable species.
Mitochondria are dynamic organelles indispensible for viability of eukaryotic cells. Diffusion of proteins in mitochondrial membranes is a prerequisite for the correct functionality of the organelles. However, its study is made complicated due to the nontrivial geometry, small size and positional instability of the organelle, restricting the usability of regular experimental methods and theoretical understanding of acquired data. Therefore, here the molecular transport along the main mitochondrial axis was investigated using highly accurate computational methods combining them with traditional experimental approaches. Using recently reported electron microscopic tomography data concerning the constitution of mitochondria [Fre02], a lattice model of the inner mitochondrial membrane (IM) reproducing its structure in great details was built up. With Monte Carlo (MC) simulations of particle dynamics on this model, it was found that the membrane geometry induces nonlinear effects in the motion of molecules along the mitochondrial axis, which in turn lead to a transient violation of the 2nd Fick?s equation. We show that mere curvature of the IM resulting from the presence of cristae is sufficient for the emergence of transient anomalous diffusion (TAD) in the membrane. The MC calculations have enabled an accurate estimation of regularities in the extent of deviations from the normal regime, therefore allowing us to propose non-homogenous power law as a suitable generalization of the current approach to the analysis of experimental data for the transient dynamics. The general cause of TAD resulting from the membrane curvature alone, without any involvement of specific inter-particle interactions prompted us to predict the similar dynamical effect also for other curved cellular membranes, be it diffusion in endoplasmic reticulum or in plasma membrane of cells possessing dense microvilli. The data indicate that the geometry-induced anomalous diffusion should be easily detectable with current experimental methods, but only in the restricted range of time scales corresponding to high temporal resolution. Until now, experimental measurements of molecular diffusion in biological membranes indiscriminately assumed either pure normal or pure anomalous diffusion schemes for the analysis of data acquired in very wide range of temporal resolutions, which often lead to ambiguities in the interpretation of diffusion parameters. The MC calculations have clearly illustrated the necessity for a more subtle treatment of experimental conditions: the assumption of pure Gaussian diffusion model is justified only if the applied temporal resolution is sufficiently low (as is often the case when using scanning techniques exemplified further); otherwise, the transient regime should be tested for by means of the non-homogenous power function. In the second part of the study the Fluorescence Recovery after Photobleaching (FRAP) with the laser scanning microscope is introduced as a method of choice for studying protein mobility within mitochondrial membranes. The conventional FRAP methodology [Axe76] was extended to enable its application for the determination of confined diffusion with conventional laser scanning microscopes which allowed us to communicate for the first time the direct measurement of protein diffusion in mitochondrial membranes of living cells. This is achieved through adaptation of FRAP data analysis to account for the spatial dimensions of the organelle and the spatiotemporal pattern of light pulses induced by the microscope. The experimental circumstances existing during the particular measurement session are computationally recreated and this way the best suited values of diffusion parameters are found. The method is validated experimentally for four FP-tagged mitochondrial membrane proteins: the IM OxPhos complexes F1F0 ATPase and cytochrome c oxidase and for Tom7 and hFis1 - components of the mitochondrial protein import and fission machineries respectively localized in the outer membrane. We find that for all proteins simple normal diffusion is not a sufficient description. In the inner membrane, diffusion coefficient of F1F0 ATPase expressed in HeLa cell line is found to be 0.2 ?m2/s, with more than 1/3 of the protein molecules being immobilized, while cytochrome c oxidase (in CEF primary cells) demonstrated a similar diffusivity pattern (0.4 ?m2/s, 30% immobile). In the outer membrane, the D (0.7 ?m2/s) and immobile fraction (7-8%) of GFP-Tom7 and GFP-hFis1 (both in HeLa cells) are identical, which designates a substantial difference in comparison to the IM protein mobility. Diffusion coefficients of mitochondrial membrane proteins studied here lay in the intermediate region between those measured in artificial bilayers and in plasma membranes. Protein crowding and intermolecular interactions will be among the major causes responsible for the detected slowdown of diffusion.
The physiology of our most complex organ, the brain, is still not comprehensively understood. The brain basically serves the processing, storing and binding of external and internal information, and thereby generates amazing phenomena like the understanding of oneself as an individual entitiy. How exactly information is encoded and represented, how individual neurons or networks of neurons actually interact, is a gigantic puzzle, whose pieces were collected since many decades. Subject of scientific discussions are the basic spatiotemporal structures of neuronal representations. Suggestions and observations reach hereby from simple rate coding of individual neurons to synchronous activity of larger ensembles. To approach answers to these questions, our working group has used a combination of different recording techniques that allowed for the comparison of neuronal interactions on different spatial scales. We focused on prefrontal neuronal interactions during visual short-term memory. Herefore two rhesus monkeys had been trained to perform a visual short-term memory task. We measured and recorded their neuronal activity by means of a microelectrode matrix that could be inserted into the cortex via a closable chamber, which had been previously implanted above prefrontal cortex. The acquired signal was separated into two components: a high-frequency component, that represents the spiking output activity of few neurons in the vicinity of each electrode tip (multi-unit activity), and a low-frequency component, that results from dendritic input activity of larger neuronal assemblies (local field potential). From one of the experimental animals we also recorded mass signals of even larger neuronal populations by means of small silverball electrodes, that had been implated into the skull above prefrontal cortex (skull EEG) in the context of a pilot project. In the first subproject, we analyzed the selectivity of output signals with respect to the memorized stimulus and task performance. We compared selectivities of local recording sites (multi-unit activity) with the selectivities of patterns created by the combined activity of all recording sites, thus representing the activity of large and distributed ensembles. Local neuronal activity correlated with the course of the visual short-term memory task, but was not highly discriminative with respect to different visual stimuli. We could show that the population activity was significantly more specific. Concerning task performance, we obtained the same result, albeit less pronounced. Further analyses revealed that the patterns of distributed ensemble activity were only partly based on realtime coordination of neuronal activity, and in addition, did not remain stable across the time course of the short-term memory task. In the second subproject, we focused on the oscillatory behavior of the local field potential. After a time-frequency analysis, we studied different frequency bands concerning stimulus selectivity and task performance of the monkey. We hereby found significant modulations of oscillations in the beta- and gamma-frequency range, that correlated with different periods of the task. Especially for oscillations in beta- and low-gamma-range, we observed phase-locking of oscillations between different recording sites, which could play an important role as internal clock to coordinate spatially separate activity. Local high-gamma oscillations themselves seemed to be important for the maintenance of information. These results could be partly confirmed by mass signals of EEG. In sum, our results support the hypothesis that information is represented in the brain by means of concerted activity of spatially distributed neuronal ensembles. This activity again appears to be coordinated by oscillatory activity in beta- and low-gamma-frequency ranges. A deeper understanding of central nervous information processing could contribute to better treatment of diseases like Parkinson’s, Alzheimer’s as well as epilepsy, and neuropsychiatric disorders like schizophrenia.
Mixed volumes, mixed Ehrhart theory and applications to tropical geometry and linkage configurations
(2009)
The aim of this thesis is the discussion of mixed volumes, their interplay with algebraic geometry, discrete geometry and tropical geometry and their use in applications such as linkage configuration problems. Namely we present new technical tools for mixed volume computation, a novel approach to Ehrhart theory that links mixed volumes with counting integer points in Minkowski sums, new expressions in terms of mixed volumes of combinatorial quantities in tropical geometry and furthermore we employ mixed volume techniques to obtain bounds in certain graph embedding problems.
Orthopoxviruses are large DNA viruses that replicate within the cytoplasm of infected cells encoding over a hundred different proteins. The orthopoxviral 68k ankyrin‐like protein (68k‐ank) is highly conserved among orthopoxviruses, and this study aimed at elucidating the function of 68k‐ank. The 68k‐ank protein is composed of four ankyrin repeats (ANK) and an F‐box‐like domain; both motifs are known proteinprotein interaction domains. The F‐box is found in cellular F‐box proteins (FBP), crucial components of cellular E3 ubiquitin (Ub) ligases. With yeast‐two‐hybrid screens and subsequent co‐immunoprecipitation analyses, it was possible to identify S‐phase kinase‐associated protein 1a (Skp1a) as a cellular counterpart of 68k‐ank via binding to the F‐box‐like domain. Additionally, Cullin‐1 was co‐precipitated, suggesting the formation of a viral‐cellular SCF E3 Ub ligase complex. Modified Vaccinia virus Ankara (MVA) ‐ being attenuated and unable to replicate in most mammalian cell lines due to a block in morphogenesis – nevertheless, expresses its complete genetic information attributing to its properties as promising vector vaccine. Conservation of 68k‐ank as the only ANK protein encoded by MVA implied a substantial role of this viral factor. Hence, its function in the viral life cycle was assessed by studying a 68k‐ank knock‐out MVA. A mutant phenotype manifested in nonpermissive mammalian cells characterized by a block succeeding viral early gene expression and by a reduced ability of the virus to shutoff host protein synthesis. Studies with MVA encoding a 68k‐ank F‐box‐like domain truncated protein revealed that viral‐cellular SCF complex formation and maintenance of viral gene expression are two distinct, unrelated functions fulfilled by 68k‐ank. Moreover, K1, a well‐described VACV host range factor of the ANK protein family, is able to complement 68k‐ank function. This suggests that gene expression of MVA putatively depends on the ANKs encoded in 68k‐ank. In addition to the important findings in vitro, first virulence studies with the mouse pox agent, ectromelia virus (ECTV) deleted of the 68k‐ank ortholog (C11) suggested that this factor contributes to ECTV virulence in vivo.
The physics of interacting bosons in the phase with broken symmetry is determined by the presence of the condensate and is very different from the physics in the symmetric phase. The Functional Renormalization Group (FRG) represents a powerful investigation method which allows the description of symmetry breaking with high efficiency. In the present thesis we apply FRG for studying the physics of two different models in the broken symmetry phase. In the first part of this thesis we consider the classical O(1)-model close to the critical point of the second order phase transition. Employing a truncation scheme based on the relevance of coupling parameters we study the behavior of the RG-flow which is shown to be influenced by competition between two characteristic lengths of the system. We also calculate the momentum dependent self-energy and study its dependence on both length scales. In the second part we apply the FRG-formalism to systems of interacting bosons in the phase with spontaneously broken U(1)-symmetry in arbitrary spatial dimensions at zero temperature. We use a truncation scheme based on a new non-local potential approximation which satisfy both exact relations postulated by Hugenholtz and Pines, and Nepomnyashchy and Nepomnyashchy. We study the RG-flow of the model, discuss different scaling regimes, calculate the single-particle spectral density function of interacting bosons and extract both damping of quasi-particles and spectrum of elementary excitations from the latter.
The present PhD-thesis was prepared within subproject B8 of the DFG-Sonderforschungsbereich (SFB) 641 “The Tropospheric Ice Phase”. The subproject B8 was entitled “Interactions of volatile organic compounds with airborne ice crystals”. Results of previous studies have shown that various volatile organic compounds (VOC) and semivolatile organic compounds (SVOC) are incorporated into the atmospheric ice phase and several uptake mechanisms are discussed in the literature. The aim of this study was to identify the dominating VOC and SVOC in airborne snow collected at Jungfraujoch in the Swiss Alps (3580 m asl) and to study in laboratory experiments the uptake mechanism of organic compounds into snow and ice. For this purpose an analytical method to analyse freshly fallen snow samples was developed and evaluated in a first step. The method consists of headspace (HS) solid phase dynamic extraction (SPDE) followed by gas chromatography combined with mass spectrometry (GC/MS). During the extraction process a new cooling device was successfully integrated into the HS-SPDE-GC/MS method to enhance the extraction yield. Extraction and desorption parameters such as the number of extraction cycles, extraction temperature, desorption volume and desorption flow rate have been optimized. Detection limits for benzene, toluene, ethylbenzene, m-, p-, o- xylene (BTEX) ranged from 19 ng L-1 (benzene) to 30 ng L-1 (m/p-xylene), while those for C6-C10 n-aldehydes ranged from 21 ng L-1 (n-heptanal) to 63 ng L-1 (n-hexanal). Furthermore, freshly fallen snow samples were collected at the High Altitude Research Station Jungfraujoch (3580 m asl, Switzerland) during the field campaigns “Cloud and aerosol characterization experiment” (CLACE) 4 and 5 in February and March 2005 and 2006, respectively. Freshly fallen snow samples collected directly in-cloud on a high altitude remote location were used as approximation of airborne ice crystals since sampling of airborne ice crystals in quantities sufficient for analysis of individual organic compounds is not yet possible. In the collected snow samples a wide range of organic compounds were identified, namely BTEX, n-aldehydes (C6-C10), terpenes, chlorinated hydrocarbons and alkylated monoaromatics. The most abundant organic compounds in snow samples from Jungfaujoch during CLACE 4 and 5 were n-hexanal with a median concentration of 1.324 μg L-1 (CLACE 5) followed by n-nonanal (CLACE 5) with a median concentration of 1.239 μg L-1. High concentration variations of the analytes in snow samples collected at the same time at the same place argue for a heterogeneous composition of snow and ice. Several indicators were found that the origin of the n-aldehydes in the snow can be attributed to direct biogenic emissions from vegetation and indirect biogenic emissions through photochemical oxidation of fatty acids and alkenes. In a second step laboratory experiments were carried out to clarify the uptake mechanism of volatile and semivolatile organic compounds into snow/ice. Organic compounds can be incorporated into the atmospheric ice phase either by the process of gas scavenging, liquid scavenging (riming) or particle scavenging. Gas scavenging (incorporation of the organic compounds from the gas phase during growing of ice crystals) revealed to be ineffective based on previous laboratory experiments in which ice crystals were growing in the presence of aromatic hydrocarbons (BTEX) in the gas phase. In the present study the process of liquid scavenging (riming) was investigated in the laboratory using aqueous standard solutions containing BTEX, naldehydes (C6-C10), methyl tert-butyl ether (MTBE) and ethyl tert-butyl ether (ETBE). The headspace above the standard solution was sampled after adjusting the aqueous solutions to definite temperatures by use of a thermostat. Measurement were carried out at 25°C, 15°C and 5°C (water), -5°C and -15°C (supercooled water) and -25°C (ice). Results have shown that the known trend of lower gas phase concentrations over water concomitant with lower temperatures (Henry’s Law) is only valid for temperatures above 0°C. At temperature below 0°C, increasing concentrations of the analytes (BTEX, MTBE, ETBE and n-aldehydes) were determined in the gas phase together with decreasing temperatures. Dimensionless Henry’s law coefficients (KAW) were calculated from the concentrations of the organic compounds in the headspace above the standard solutions at temperatures between 25°C and -25°C. The observed inversion of Henry’s law coefficients of volatile and semivolatile organic compounds at a water temperature of approximately 0°C is explained by the formation of ordered zones of H2O molecules in supercooled water called “ice-like-clusters”. Together with decreasing temperatures the degree of formation of ordered zones increases which results in the removal of the organic molecules from the liquid phase and transfer into the gas phase. At a temperature of -25°C the supercooled water is converted into ice and a further significant increase of the gas phase concentrations of hydrophobic compounds such as BTEX is observed. In comparison, less hydrophobic compounds such as MTBE, ETBE and n-aldehydes are detected in lower amounts in the gas phase above the water/ice phase due to the higher water solubility and lower Henry coefficients compared to BTEX. The results show that in the absence of particles the uptake of BTEX MTBE, ETBE and C6-C10-naldehydes into ice not enhanced during freezing of a supercooled liquid, since at -25°C for these analytes the concentrations in the gas phase are higher at -25°C (ice) compared with -15°C (supercooled liquid). The heterogeneous distribution of BTEX and n-aldehydes concentrations in snow samples collected during the CLACE field campaigns suggests that adsorption of the organic compounds to particles followed by incorporation of the particles into the snow and ice might play a major role in the uptake process of organic compounds into snow and ice. To increase the knowledge about uptake processes of organic compounds into snow and ice further experiments are required with should include aerosol particles in the experimental setup to evaluate the influence of particle scavenging in the uptake processes.
Zusammenfassung Die Alzheimersche Krankheit (AD) ist mit 60% die am häufigsten auftretende Art der Demenz. Weltweit sind ca. 24 Mio. Menschen von der neurodegenerativen Krankheit betroffen, welche sich durch den Verlust der kognitiven Fähigkeiten auszeichnet. Es gibt zwei Ausprägungen der Demenz, zum einen die sporadische Verlaufsform, die bei Menschen in einem Alter ab 65 Jahren auftritt und zum anderen die familiäre Alzheimersche Krankheit (FAD), die schon weitaus jüngere Menschen betrifft und auf genetische Mutationen zurück zu führen ist. Beide Formen der Demenz zeigen den gleichen neuropathologische Phänotyp, der zur Ausbildung von extrazellulären Plaques und intrazellulären Neurofibrillen führt. Durch die Entstehung der Plaques und der Neurofibrillen werden die Verbindungen zwischen den einzelnen Neuronen verringert und die Neuronen sterben ab. Für das Auftreten der FAD sind Mutationen in den Genen des Amyloid Vorläufer Proteins (APP, Substrat) sowie der Aspartatprotease Einheit des γ-Sekretase Komplexes, Presenilin 1 (PS1) oder Presenilin 2 (PS2), verantwortlich. Die γ-Sekretase ist ein membranständiger Komplex bestehend aus den vier Untereinheiten PS1 oder PS2, Nicastrin (Nct), Aph-1 und Pen-2. Um ausreichende Informationen über den γ-Sekretase Komplex bezüglich seiner Interaktionsflächen, seines Katalysemechanismus und seiner Substraterkennung zu erhalten, wäre es hilfreich seine 3 Dimensionale Struktur aufzuklären, wozu große Mengen der sauberen und homogenen Proteine benötigt werden. Die Herstellung von ausreichenden Proteinmengen stellt derzeit aber einen Engpass für die strukturelle und funktionelle Charakterisierung des γ-Sekretase Komplexes in-vitro dar. Alzheimer’s disease (AD) is the most common cause of dementia, which affects 24 million people worldwide. It is a neurodegenerative disorder, which occurs either in its most common form in people over 65 years or in the rare early-onset familial AD (FAD). Responsible for the autosomal dominant FAD are mutations in the genes encoding for the β-amyloid precursor protein (APP) and the two homologues integral membrane proteins Presenilin 1 (PS1) and Presenilin 2 (PS2). The two PSs are major but alternative components of the intramembrane aspartyl protease γ-secretase. Further components are the membrane proteins Nicastrin (Nct), Aph-1 and Pen-2. Production of sufficient amounts of protein samples is still the major bottleneck for the detailed functional and structural in-vitro characterization of the γ-secretase complex. Due to toxicity, stability and targeting problems, the overproduction of MPs in conventional in-vivo systems often has only limited success. Therefore, efficient expression protocols using the cell-free (CF) system were established in this work. After optimization, I was able to produce up to milligram amounts of the single proteins PS1 and PS2, the cleavage products PS1-NTF and PS1-CTF, and Pen-2. The in-vitro produced γ-secretase subunits were further characterized, concerning their purity, secondary fold, thermal stability and homogeneity. Highest purities with over 90% after affinity chromatography could be achieved for PS1-CTF and Pen-2. Reconstitution of PS1, PS1-NTF, PS1-CTF and Pen-2 into E. coli liposomes results in a homogeneously distribution, which gives evidence for a structural folding. This was confirmed by CD spectroscopy of PS1-CTF and Pen-2. The thermal stability of Pen-2 shows a transition at 68°C, whereas PS1-CTF is stable up to 95°C. Both proteins show in addition homogeneous elution profiles investigated by analytical SEC and exhibit a monomeric (Pen-2) or dimeric (PS1-CTF) character analyzed by blue native PAGE. Different methods were performed to get evidence about the assembly of the complex, like pull-down experiments, immunoprecipitation, co-expression of radioactive labeled subunits and titration assays by liquid-state NMR. First hints for an interaction of the CF synthesized proteins could be observed by co-expression. Supplemental, Pen-2 and CTF could be purified in sufficient amounts and to apparent homogeneity that allow structural approaches by X-ray crystallography and liquid-state NMR spectroscopy. First conditions for protein crystals were achieved for Pen-2 and structural investigations of PS1-CTF by liquid-state NMR could be performed after optimization of the expression-, purification- and detergent conditions.
Misregulated receptor tyrosine kinases (RTKs), i.e. the epidermal growth factor receptor EGFR or the insulin-like growth factor receptor 1 (IGF-1R), can be involved in the development of cancer. Monoclonal antibodies specifically inhibit the RTKs in cancer therapy. The scope of this thesis is to investigate the molecular basis of the inhibition through the therapeutic antibodies matuzumab (EMD72000) against EGFR and EMD1159476 against IGF-1R. The 3D crystal structure of matuzumab in complex with the EGFR domain III shows an eptiope connected with a novel inhibition mechanism: a non-competitive, sterical inhibition of receptor acitivation. The anti-IGF-1R targeted monoclonal antibody EMD1159476 shows a reduced binding capacity to the receptor in the presence of ligand indicating a competitive inhibition mechanism. The epitope of EMD1159476 is within domain II of the receptor. The results of these molecular interaction studies are important for the clinical therapies with these monoclonal antibodies. The matuzumab-EGFR complex crystal structure shows that a simultaneous binding of matuzumab and cetuximab (Erbitux) is possible. The latter antibody is already in clinical use. A combination of several therapeutic antibodies in cancer treatment might show synergistic effects and benefits for the patients.
‘The whole is more than the sum of its parts.’ This idea has been brought forward by psychologists such as Max Wertheimer who formulated Gestalt laws that describe our perception. One law is that of collinearity: elements that correspond in their local orientation to their global axis of alignment form a collinear line, compared to a noncollinear line where local and global orientations are orthogonal. Psychophysical studies revealed a perceptual advantage for collinear over non-collinear stimulus context. It was suggested that this behavioral finding could be related to underlying neuronal mechanisms already in the primary visual cortex (V1). Studies have shown that neurons in V1 are linked according to a common fate: cells responding to collinearly aligned contours are predominantly interconnected by anisotropic long-range lateral connections. In the cat, the same holds true for visual interhemispheric connections. In the present study we aimed to test how the perceptual advantage of a collinear line is reflected in the anatomical properties within or between the two primary visual cortices. We applied two neurophysiological methods, electrode and optical recording, and reversibly deactivated the topographically corresponding contralateral region by cooling in eight anesthetized cats. In electrophysiology experiments our results revealed that influences by stimulus context significantly depend on a unit’s orientation preference. Vertical preferring units had on average a higher spike rate for collinear over non-collinear context. Horizontal preferring units showed the opposite result. Optical imaging experiments confirmed these findings for cortical areas assigned to vertical orientation preference. Further, when deactivating the contralateral region the spike rate for horizontal preferring units in the intact hemisphere significantly decreased in response to a collinear stimulus context. Most of the optical imaging experiments revealed a decrease in cortical activity in response to either stimulus context crossing the vertical midline. In conclusion, our results support the notion that modulating influences from stimulus context can be quite variable. We suggest that the kind of influence may depend on a cell’s orientation preference. The perceptual advantage of a collinear line as one of the Gestalt laws proposes is not uniformly represented in the activity of individual cells in V1. However, it is likely that the combined activity of many V1 neurons serves to activate neurons further up the processing stream which eventually leads to the perceptual phenomenon.
"The whole is more than the sum of its parts." This idea has been brought forward by psychologists such as Max Wertheimer who formulated Gestalt laws that describe our perception. One law is that of collinearity: elements that correspond in their local orientation to their global axis of alignment form a collinear line, compared to a noncollinear line where local and global orientations are orthogonal. Psychophysical studies revealed a perceptual advantage for collinear over non-collinear stimulus context. It was suggested that this behavioral finding could be related to underlying neuronal mechanisms already in the primary visual cortex (V1). Studies have shown that neurons in V1 are linked according to a common fate: cells responding to collinearly aligned contours are predominantly interconnected by anisotropic long-range lateral connections. In the cat, the same holds true for visual interhemispheric connections. In the present study we aimed to test how the perceptual advantage of a collinear line is reflected in the anatomical properties within or between the two primary visual cortices. We applied two neurophysiological methods, electrode and optical recording, and reversibly deactivated the topographically corresponding contralateral region by cooling in eight anesthetized cats. In electrophysiology experiments our results revealed that influences by stimulus context significantly depend on a unit’s orientation preference. Vertical preferring units had on average a higher spike rate for collinear over non-collinear context. Horizontal preferring units showed the opposite result. Optical imaging experiments confirmed these findings for cortical areas assigned to vertical orientation preference. Further, when deactivating the contralateral region the spike rate for horizontal preferring units in the intact hemisphere significantly decreased in response to a collinear stimulus context. Most of the optical imaging experiments revealed a decrease in cortical activity in response to either stimulus context crossing the vertical midline. In conclusion, our results support the notion that modulating influences from stimulus context can be quite variable. We suggest that the kind of influence may depend on a cell’s orientation preference. The perceptual advantage of a collinear line as one of the Gestalt laws proposes is not uniformly represented in the activity of individual cells in V1. However, it is likely that the combined activity of many V1 neurons serves to activate neurons further up the processing stream which eventually leads to the perceptual phenomenon.
Delthyridoid spiriferids are characterized by a global abundance and fast evolution during Silurian and Devonian, and, therefore, are used as important biostratigraphical and palaeobiogeographical tools. In this work, delthyridoid brachiopod faunas from different regions of today’s world, resp., of different palaeobiogeographical units, are compared side-by-side to investigate their phylogenetic relationships and to improve, in a second step, the palaeobiogeography from Late Silurian to Early Eifelian time. A new systematics of Delthyridoidae is established which is more complicated than hitherto assumed. The results of this study are mainly based on direct comparison of articulated and isolated brachiopod shells, external and internal moulds, as well as latex casts and serial sections. The computer supported cladistic analyses have turned out not to be useful due to different kinds of preservation resulting in an incomplete matrix which is insufficient for reliable cladograms. A further problem in terms of cladistical analyses are various convergences during the evolution of spiriferids. Many characters evolved independently from each other at different times in each lineage so that autapomorphies are hardly or not at all recognizable. As a result, families and genera are only definable by a combination of characters rather than by a single or a few autapomorphies. As a new method, 3D reconstruction from serial sections is introduced which made it possible for the first time to compare directly mouldic and shelly material. Preliminary results are presented herein. Statistical analyses of measurements taken from new taxa are made but regarded as a descriptive argument rather than a deciding factor for taxonmy due to incomplete preservation and/or tectonic deformation. Brachiopods, especially type material, from collections of different institutions and museums are studied as well as personal material, whenever possible collected from topotype outcrops. Emended diagnoses, if necessary, from family to species level are given. During this work several new taxa have been erected: 7 new families: Australospiriferidae, Murchisonispiriferidae, Orientospiriferidae, Otospiriferidae, Patriaspiriferidae, Rostrospiriferidae, and Trigonospiriferidae; 6 new genera, 1 of these in open nomenclature: Cyclopterospirifer, Hallispirifer, Parlinispirifer, Murchisonispirifer, Shujiapingensispirifer, and gen. nov. B; and 3 new species: Patriaspirifer merriami, Patriaspirifer johnsoni, and Murchisonispirifer feldmani; 1 taxon is defined as nomen novum: Orientospirifer nakaolingensis wani. In the framework of this project, 2 families: Filispiriferidae and Multispiriferidae; 1 subfamily: Multiplicatispiriferinae, 6 genera, 1 of them in open nomenclature: Frequentispirifer, Leonispirifer, Multiplicatispirifer, Ovetensispirifer, Turcispirifer, and Gen. A; and 9 new species, 3 of them in open nomenclature: Filispirifer hamadae, Leonispirifer leonensis, Multiplicatispirifer foumzguidensis, Oventensispirifer novascotianus, Quiringites arensentiae, Turcispirifer turciae, Multiplicatispirifer cf. foumzguidensis, Quiringites cf. arensentiae, and ?Turcispirifer sp. A which have already been established are also described in this work. The brachiopod faunas studied consist of externally very similar spiriferids which have been identified as same genera, species, or even subspecies in earlier times. These forms are considered as 6 distinct morphotypes Howellella-, Arduspirifer-, Acrospirifer-, Euryspirifer-, Paraspirifer-, and Multiplicatispirifer-like morphotypes, which are briefly introduced. The new systematics is characterized by different clades, the European/North African delthyridoid spiriferid clade, the North American delthyridoid spiriferid clade, the Asian delthyridoid spiriferid clade, the Malvinokaffric delthyridoid spiriferid clade, and the delthyridoid multiplicated spiriferid clade. Each of them is described in a cladistic and in a phylogenetic way. Their phylogenetic relationship sheds new light on palaeobiogeographical interpretations for the different stages from Late Silurian to early Middle Devonian time. A tendency for increasing endemicity is seen until the end of the Early Emsian, which is interrupted by short term regional faunal exchange within a province or within a realm, followed by a loss of endemicity resulting in global distribution of brachiopod genera until the end of Givetian time. The Old World Realm is re-defined due to the lack of phylogenetic relationship between its faunas and subdivided into the European Realm, consisting of the Gondwanan and Avalonian provinces, and the Asian Realm, consisting of the Siberian, Sino, and Mongolian provinces. A reconstruction of Lower Devonian palaeobiographical map is introduced.
Vasculogenesis as well as angiogenesis are important for postnatal development of blood vessels. Peripheral blood or bone marrow-derived endothelial precursor cells are used in clinical trials for therapeutic enhancement of postnatal neovascularization in patients suffering from coronary artery diseases. The vasculogenic potential of the precursor cell population depends on the appropriate retention of the infused cells to the ischemic tissue. However, cell-autonomous mechanisms regulating the attraction and retention of circulating cells in inflammatory tissue are not well understood. Caspases belong to a family of pro-apoptotic enzymes. Beyond cell death signals, caspase proteases additionally regulate non-apoptotic processes like cell morphology and migration in many cell types. The isoform Caspase-8 is essential for embryonal vasculogenesis in conditional knockout mice. In this study, we identified a novel apoptosis-unrelated role of Caspase-8 in circulating and bone marrow-derived cells for vascular repair. Caspase-8-specific inhibition abrogated the ex vivo formation of EPC from human peripheral blood. Moreover, Caspase-8 inhibition disables EPC migration and adhesion to different matrices and decreases the cell surface expression of the fibronectin receptor subunit integrin alpha 5 and the chemokine receptor CXCR4. In vitro and in vivo studies using bone marrow mononuclear cells derived from inducible Caspase-8- deficient mice revealed an essential role of Caspase-8 for EPC formation and neovascularization enhancing capacities of progenitor cells. Caspase-8 activity appears to be required for maintaining responses to matrix interaction and chemoattractants of EPC. Additional studies showed that the E3 ubiquitin ligase Cbl-b, a negative regulator of cell adhesion molecules including integrin alpha 5, is present in EPC at low protein levels under basal conditions, but markedly increases upon Caspase-8 inhibition. In vitro assays and overexpression studies in intact cells confirmed Caspase-8-dependent degradation of Cbl-b, providing a potential requirement for Caspase-8-regulated adhesion. Indeed, neovascularization of matrigel plugs was enhanced in mice lacking Cbl-b. Moreover, Cbl-b degradation in the presence of active Caspase-8 prevents the down-regulation of integrin alpha 5 and is associated with an enhanced vasculogenic activity of progenitor cells in hind limb ischemia. The identified upstream regulation of caspase-8 by cytokine IL-6 is only one possibility for fine-tuning the non-apoptotic enzymatic activity. In summary, this study shows a novel essential role of Caspase-8 for proper EPC adhesion-related signaling. Caspase-8 is involved in the function of adhesion molecules by regulation the E3 ubiquitin ligase Cbl-b. Strategies to improve survival of therapeutic injected progenitor cells by using caspase inhibitors should be addressed with caution. Because of the broad spectrum of activity of caspase-8, downstream targets of this caspase isoform and Cbl-b should be in more focus for therapeutic pretreatment to improve neovascularization of myocardial and ischemic tissue.
The characterization of microscopic properties in correlated low-dimensional materials is a challenging problem due to the effects of dimensionality and the interplay between the many different lattice and electronic degrees of freedom. Competition between these factors gives rise to interesting and exotic magnetic phenomena. An understanding of how these phenomena are driven by these degrees of freedom can be used for rational design of new materials, to control and manipulate these degrees of freedom in order to obtain desired properties. In this work, we study these effects in materials with small exchange interaction between the magnetic ions such as metal-organic and inorganic dilute compounds. We overcome the dfficulties in studying these kind of materials by combining classical and quantum mechanical ab initio methods and many-body theory methods in an effective theoretical approach. To treat metal-organic compounds we elaborate a novel two-step methodology which allows one to include quantum effects while reducing the computational cost. We show that our approach is an effective procedure, leading at each step, to additional insights into the essential features of the phenomena and materials under study. Our investigation is divided into two parts, the first one concerning the exploration of the fundamental physical properties of novel Cu(II) hydroquinone-based compounds. We have studied two representatives of this family, a polymeric system Cu(II)-2,5-bis(pyrazol-1-yl)-1,4-dihydroxybenzene (CuCCP) and a coupled system Cu2S2F6N8O12 (TK91). The second part concerns the study of magnetic phenomena associated with the interplay between different energy scales and dimensionality in zero-, one- and two-dimensional compounds. In the zero-dimensional case, we have performed a comprehensive study of Cu4OCl6L4 with L=diallylcyanamide=NC-N-(CH2-CH=CH2)2 (Cu4OCl6daca4). Interpretations of the magnetic properties for this tetrameric compound have been controversial and inconsistent. From our studies, we conclude that the common models usually applied to this and other representatives in the same family of cluster systems fail to provide a consistent description of their low temperature magnetic properties and we thus postulate that in such systems it is necessary to take into account quantum fluctuations due to possible frustrated behavior. In the one-dimensional case, we studied polymeric Fe(II)-triazole compounds, which are of special relevance due to the possibility of inducing a spin transition between low and high spin state by applying a external perturbation. A long standing problem has been a satisfactory microscopic explanation of this large cooperative phenomenon. A lack of X-ray data has been one mitigating reason for the absence of microscopic studies. In this work, we present a novel approach to the understanding of the microscopic mechanism of spin crossover in such systems and show that in these kind of compounds magnetic exchange between high spin Fe(II) centers plays an important role. The correct description of the underlying physics in many materials is often hindered by the presence of anisotropies. To illustrate this difficulty, we have studied a two dimensional dilute compound K2V3O8 which exhibits an unusual spin reorientation effect when applying magnetic fields. While this effect can be understood when considering anisotropies in the system, it is not sufficient to reproduce experimental observations. Based on our studies of the electronic and magnetic properties in this system, we predict an extra exchange interaction and the presence of an additional magnetic moment at the non-magnetic V site. This sheds a new light into the controversial recent experimental data for the magnetic properties of this material.
The bulk viscosity of several quark matter phases is calculated. It is found that the effect of color superconductivity is not trivial, it may suppress, or enhance the bulk viscosity depending on the critical temperature and the temperature at which the bulk viscosity is calculated. Also, is it found that the effect of neutrino-emitting Urca processes cannot be neglected in the consideration of the bulk viscosity of strange quark matter. The results for the bulk viscosity of strange quark matter are used to calculate the r-mode instability window of quark stars with several possible phases. It is shown that each possible phase has a different structure for the r-mode instability window.
We investigate the utility of modern kernel-based machine learning methods for ligand-based virtual screening. In particular, we introduce a new graph kernel based on iterative graph similarity and optimal assignments, apply kernel principle component analysis to projection error-based novelty detection, and discover a new selective agonist of the peroxisome proliferator-activated receptor gamma using Gaussian process regression. Virtual screening, the computational ranking of compounds with respect to a predicted property, is a cheminformatics problem relevant to the hit generation phase of drug development. Its ligand-based variant relies on the similarity principle, which states that (structurally) similar compounds tend to have similar properties. We describe the kernel-based machine learning approach to ligand-based virtual screening; in this, we stress the role of molecular representations, including the (dis)similarity measures defined on them, investigate effects in high-dimensional chemical descriptor spaces and their consequences for similarity-based approaches, review literature recommendations on retrospective virtual screening, and present an example workflow. Graph kernels are formal similarity measures that are defined directly on graphs, such as the annotated molecular structure graph, and correspond to inner products. We review graph kernels, in particular those based on random walks, subgraphs, and optimal vertex assignments. Combining the latter with an iterative graph similarity scheme, we develop the iterative similarity optimal assignment graph kernel, give an iterative algorithm for its computation, prove convergence of the algorithm and the uniqueness of the solution, and provide an upper bound on the number of iterations necessary to achieve a desired precision. In a retrospective virtual screening study, our kernel consistently improved performance over chemical descriptors as well as other optimal assignment graph kernels. Chemical data sets often lie on manifolds of lower dimensionality than the embedding chemical descriptor space. Dimensionality reduction methods try to identify these manifolds, effectively providing descriptive models of the data. For spectral methods based on kernel principle component analysis, the projection error is a quantitative measure of how well new samples are described by such models. This can be used for the identification of compounds structurally dissimilar to the training samples, leading to projection error-based novelty detection for virtual screening using only positive samples. We provide proof of principle by using principle component analysis to learn the concept of fatty acids. The peroxisome proliferator-activated receptor (PPAR) is a nuclear transcription factor that regulates lipid and glucose metabolism, playing a crucial role in the development of type 2 diabetes and dyslipidemia. We establish a Gaussian process regression model for PPAR gamma agonists using a combination of chemical descriptors and the iterative similarity optimal assignment kernel via multiple kernel learning. Screening of a vendor library and subsequent testing of 15 selected compounds in a cell-based transactivation assay resulted in 4 active compounds. One compound, a natural product with cyclobutane scaffold, is a full selective PPAR gamma agonist (EC50 = 10 +/- 0.2 muM, inactive on PPAR alpha and PPAR beta/delta at 10 muM). The study delivered a novel PPAR gamma agonist, de-orphanized a natural bioactive product, and, hints at the natural product origins of pharmacophore patterns in synthetic ligands.
The goal of this research is to develop an understanding of what causes organizations and information systems to be “good” with regard to communication and coordination. This study (1) gives a theoretical explanation of how the processes of organizational adaptation work and (2) what is required for establishing and measuring the goodness of an organization with regard to communication and coordination. By leveraging concepts from cybernetics and philosophy of language, particularly the theoretical conceptualization of information systems as social systems and language communities, this research arrives at new insights. After discussing related work from systems theory, organization theory, cybernetics, and philosophy of language, a theoretical conceptualization of information systems as language communities is adopted. This provides the foundation for two exploratory field studies. Then a formal theory for explaining the adaptation of organizations via language and communication is presented. This includes measures for the goodness of organizations with regard to communication and coordination. Finally, propositions stemming from the theoretical model are tested using multiple case studies in six information system development projects in the financial services industry.
Dendritic cells are the sentinels between the innate and the adaptive immunity. They are professionals that capture invading pathogens, recognize specific microbial structures and induce naïve T lymphocytes to polarize into a specific T cell subset. To initiate the T cell polarization DCs secrete cytokines which are induced upon Toll-like receptor activation by microbial structures. The recognition of these structures and the discrimination between non-self and self structures by TLRs is fine tuned, but under defined circumstances deregulation of immune responses appears. Consequently, this can result in immune disorders such as autoimmunity, chronic inflammatory diseases or cancer. In this thesis the investigations are focused on the regulation of the IL-12 family members IL-12p70 and IL-23 in DCs. The objective was to investigate three different endogenous and exogenous factors that regulate IL-12p70 or IL-23. In the first part Selenium, an essential trace element and important factor in several metabolic pathways including the cellular redox status and reactive oxygen species (ROS) dependent signaling was applied as supplement in immature Langerhans cell culture. Because Selenium also plays a role in the immune system the TLR-induced IL-23 production of the DCs upon Selenium treatment was analyzed. In the immature Langerhans cell line XS-52 the strongest inducer of IL-23 was TLR4 ligand LPS. Furthermore increased levels of TLR4-induced IL-23 in cells treated with Selenium were detected in a concentration dependent manner. Whereas the IL-23 subunit p40 was upregulated upon Selenium treatment the second subunit p19 was completely unaffected. This effect was detected on mRNA and protein level. In addition, as expected, IFN-gamma inhibited the TLR4-induced IL-23 secretion of both, Selenium treated and untreated cells. In the second part of this thesis p47phox, an organizing protein of the NADPH oxidase was analyzed regarding its potential to regulate IL-12p70 and/or IL-23 secreted by different DC subtypes. Since it was demonstrated that p47phox deficiency is associated with enhanced autoimmunity and chronic inflammation we wanted to prove whether it has a function in addition to that within the NADPH oxidase. We found some hints that p47phox may be interact with proteins of the TLR signaling pathway and thus we hypothesized that p47phox may have a function for the regulation of TLR-mediated cytokine production in DCs. In several experiments with DCs from the spleen of different p47phox deficient mice we detected an increased production of TLR9-induced IL-12p70 compared to wild type cells. In contrast TLR4 stimulation with LPS displayed no significant differences between p47phox deficient and wild type cells. In spleen cells IL-23 was not detected. Confirming the results of this new negative feedback by p47phox on IL-12p70 rats, with a single nucleotide polymorphism in the p47phox gene, were investigated. Interestingly this polymorphism is located in the phosphorylation site of IRAK4, an important kinase in the TLR pathway. In rats with a methionine residue at this position in the p47phox protein enhanced IL-12p70 level were found, compared to the rats with threonine, which can be phosphorylated by IRAK4. All analyzed mice and rats have defects in the NADPH oxidase function due to a non functional p47phox protein which results in a defective ROS production. To determine whether the observed negative feedback mechanism is connected to the lack of ROS production experiments with gp91phox deficient mice, which also have a defective NADPH oxidase function, were performed. In several experiments the enhanced IL-12p70 production in cells from p47phox deficient mice could be confirmed, but no differences between gp91phox deficient and wild type mice have been observed. In further studies was found that the inhibition of the NADPH oxidase function did not alter the negative feedback on TLR9-induced IL-12p70 secretion by p47phox. Interestingly upon treatment with the inhibitor a feedback mechanism in wild type cells also after TLR4 stimulation was observed. Hence, blocking a ROS-dependent TLR4 pathway by the inhibitor uncovered the LPS induced ROS-independent pathway of the TLR4 signaling. These findings strongly approve a NADPH oxidase/ROS-independent function of p47phox in DCs. Because splenic DCs do not secrete IL-23, in vitro differentiated DCs from the bone marrow were investigated regarding the negative feedback mechanism. In DCs from p47phox deficient mice, differentiated with GM-CSF, the upregulation of IL-12p70 was confirmed, whereas Flt3-L cultured DCs did not display the negative feedback. In contrast to IL-12p70 no difference for the IL-23 production between wild type and p47phox deficient cells has been detected. Thus, we concluded that IL-23 production is not regulated by p47phox. IL-12p70 is the major cytokine in the Th1 polarization whereas IL-23 is important for the maintenance and survival of Th17 cells. To prove whether the regulation of IL-12p70 influences the T cell response immunization experiments closely resembling the classical DTH-like protocols were performed. Groups of p47phox deficient and wild type mice received either PBS, OVA alone or mixed with TLR9 ligand CpG2216 in IFA s.c. to activate and polarize naïve T cells towards Th1 or Th17 cells. After ten days isolated lymph node cells were incubated in an ELISA spot assay with or without OVA and the frequency of IFN-gamma and IL-17 producing T cells was quantified. In vitro recall of OVA immunization of wild type and p47phox deficient mice resulted in an increased IFN-gamma and IL-17 frequency in the p47phox deficient cells. The combination with CpG2216 as adjuvant and inducer of the 3rd signal enhanced the frequency of IFN-gamma and IL-17 producing T cells in wild type mice significantly. However, in p47phox deficient cells the IFN-gamma and IL-17 response, being already detectable without in vitro OVA re-stimulation, was strongly augmented upon OVA restimulation. These findings confirmed our in vitro data for IL-12p70. Hence, the data supports our hypothesis that the p47phox dependent regulation of IL-12p70 and the consequences for the T cell response is an important mechanism to prevent uncontrolled immune responses. In the last part of this thesis the immunomodulatory property of vitamin D3 on the IL-12p70 production of DCs was examined. Since it was shown that VD3 influences the differentiation and maturation of monocytes and DCs, splenic DCs from C57BL/6 and BALB/c mice were investigated regarding their IL-12p70 production after VD3 treatment. Spleen cells, stimulated with LPS or CpG2216, exhibited a decreased IL-12p70 production when treated with VD3 before stimulation phase. In contrast treatment with VD3 only during TLR stimulation had no influence on the IL-12p70 production. Since it was demonstrated that VD3 stimulates the expression of p47phox mRNA cells from p47phox deficient mice were also treated with VD3. In initial experiments only a slight inhibition of IL-12p70 has been detected in p47phox deficient cells compared to the wild type. In summary the thesis displays three different possibilities to influence the TLR-induced cytokine secretion of DCs, although with different intensities and specificities.
X-ray structure of the Na+-coupled Glycine-Betaine symporter BetP from Corynebacterium glutamicum
(2009)
Cellular membranes are important sites of interaction between cells and their environment. Among the multitude of macromolecular complexes embedded in these membranes, transporters play a particularly important role. These integral membrane proteins perform a number of vital functions that enable cell adaptation to changing environmental conditions. Osmotic stress is a major external stimulus for cells. Bacteria are frequently exposed to either hyperosmotic or hypoosmotic stress. Typical conditions for soil bacteria, such as Corynebacterium glutamicum, vary between dryness and sudden rainfall. Physical stimuli caused by osmotic stress have to be sensed and used to activate appropriate response mechanisms. Hypoosmotic stress causes immediate and uncontrolled influx of water. Cells counteract by instantly opening mechanosensitive channels, which act as emergency valves leading to fast efflux of small solutes out of the cell, therebydiminishing the osmotic gradient across the cell membrane. Hyperosmotic stress, on the other hand, results in water efflux. This is counterbalanced by an accumulation of small, osmotically active solutes in the cytoplasm, the so-called compatible solutes. They comprise a large variety of substances, including amino acids (proline), amino acid derivatives (betaine, ectoine), oligosaccharides (trehalose), and heterosides (glucosylglycerol). Osmoregulated transporters sense intracellular osmotic pressure and respond to hyperosmotic stress by facilitating the inward translocation of compatible solutes across the cell membrane, to restore normal hydration levels. This work presents the first X-ray structure of a member of the Betaine-Choline-Carnitine-Transporter (BCCT) family, BetP. This Na+-coupled symporter from Corynebacterium glutamicum is a highly effective osmoregulated and specific uptake system for glycine-betaine. X-ray structure determination was achieved using single wavelength anomalous dispersion (SAD) of selenium atoms. Selenium was incorporated into the protein during its expression in methione auxotrophic E. coli cells, grown in media supplemented with selenomethionine. SAD data with anomalous signal up to 5 Å led to the detection of 39 selenium sites, which were used to calculate the initial electron density map of the protein. Medium resolution and high data anisotropy made the structure determination of BetP a challenging task. A specific strategy for data anisotropy correction and a combination of various crystallographic programs were necessary to obtain an interpretable electron density map suitable for model building. The crystal structure of BetP shows a trimer with glycine-betaine bound in a three-fold cation-pi interaction built by conserved tryptophan residues. The bound substrate is occluded from both sides of the membrane and aromatic side chains line its transport pathway. Very interestingly, the structure reveals that the alpha-helical C-terminal domain, for which a chemo- and osmosensory function was elucidated by biochemical methods, interacts with cytoplasmic loops of an adjacent monomer. These unexpected monomer-monomer interactions are thought to be crucial for the activation mechanism of BetP, and a new atomic model combing biochemical results with the crystal structure is proposed. BetP is shown to have the same overall fold as three unrelated Na+-coupled symporters. While these were crystallised in either the outward- or inward-facing conformation, BetP reveals a unique intermediate state, opening new perspectives on the alternating access mechanism of transport.
Manual development of deep linguistic resources is time-consuming and costly and therefore often described as a bottleneck for traditional rule-based NLP. In my PhD thesis I present a treebank-based method for the automatic acquisition of LFG resources for German. The method automatically creates deep and rich linguistic presentations from labelled data (treebanks) and can be applied to large data sets. My research is based on and substantially extends previous work on automatically acquiring wide-coverage, deep, constraint-based grammatical resources from the English Penn-II treebank (Cahill et al.,2002; Burke et al., 2004; Cahill, 2004). Best results for English show a dependency f-score of 82.73% (Cahill et al., 2008) against the PARC 700 dependency bank, outperforming the best hand-crafted grammar of Kaplan et al. (2004). Preliminary work has been carried out to test the approach on languages other than English, providing proof of concept for the applicability of the method (Cahill et al., 2003; Cahill, 2004; Cahill et al., 2005). While first results have been promising, a number of important research questions have been raised. The original approach presented first in Cahill et al. (2002) is strongly tailored to English and the datastructures provided by the Penn-II treebank (Marcus et al., 1993). English is configurational and rather poor in inflectional forms. German, by contrast, features semi-free word order and a much richer morphology. Furthermore, treebanks for German differ considerably from the Penn-II treebank as regards data structures and encoding schemes underlying the grammar acquisition task. In my thesis I examine the impact of language-specific properties of German as well as linguistically motivated treebank design decisions on PCFG parsing and LFG grammar acquisition. I present experiments investigating the influence of treebank design on PCFG parsing and show which type of representations are useful for the PCFG and LFG grammar acquisition tasks. Furthermore, I present a novel approach to cross-treebank comparison, measuring the effect of controlled error insertion on treebank trees and parser output from different treebanks. I complement the cross-treebank comparison by providing a human evaluation using TePaCoC, a new testsuite for testing parser performance on complex grammatical constructions. Manual evaluation on TePaCoC data provides new insights on the impact of flat vs. hierarchical annotation schemes on data-driven parsing. I present treebank-based LFG acquisition methodologies for two German treebanks. An extensive evaluation along different dimensions complements the investigation and provides valuable insights for the future development of treebanks.
The various OPE mixtures were also tested on sSOI material which consists of a thin strained silicon layer on top of an insulator like silicon dioxide. The OPE A, B and F are able to reveal threading dislocations (TD) in the strained silicon film (chapter 5.11). The TD densities determined for the OPE A correspond very well with those obtained with the Secco diluted reference. The tested OPE mixtures are not able to delineate other crystal defects like stacking faults, pile ups or twins, which also appear in the strained silicon. Some Organic Peracid Etches were also tested on wafers with an epitaxial silicon layer and on silicon substrates. Epitaxially produced silicon layers are nearly defect-free. Etching times were chosen such that only a part of the epitaxial layer was removed. Nevertheless, after very long etching times (> 16 h) isolated pits were found, with defect densities ranging from 104/cm3 to 106/cm3 depending on the etching solution used. No etch pits were found in the remaining epitaxial layer when OPE F was used. Longer etching times appear to favour the formation of artefects. These artefacts could be caused by the formation of gas bubbles, particles or micro scratches at the crystal surface. The OPE C and D are able to reveal vacancy agglomerates (D-defects) in silicon substrates (see under 5.5, 5.6 and 5.11in chapter 5). Due to their low removal rates and the long etching times which favour the formation of artifacts, these solutions are less suited to the delineation of defects in silicon substrates. In the second part of this study the different etch formulations have been compared with each other in respect of their physical properties like removal rates, activation energies, standard potentials and selectivities (chapter 6). The selectivity was determined at etch pits caused by dislocations. The depth of the etch pits, determined by atomic force microscopy (AFM), should be dependent on the selectivity of the corresponding etching solution used. The higher the selectivity of the solution the deeper the etch pit should be. It was assumed that a low removal rate and a high activation energy for the etching process should correspond to a high selectivity. However, the experimental results have shown that it is not possible to predict the selectivity of an etching solution from experimental parameters like removal rate or activation energy. One must bear in mind that selectivity was only determined on one particular type of crystal defect, namely on dislocations. Values for selectivity in the etching solutions can differ for other defect types. Besides the etching solutions used in this study differ considerably from each other in respect of their chemical and physical roperties. They can be divided into three completely different etching systems. The original Secco solution and the diluted variations thereof are hydrofluoric acid-dichromate mixtures with the Cr6+ species as the oxidizing agent. The Jeita and MEMC solutions contain nitric acid, hydrofluoric acid and, as diluents, acetic acid and water. Here the oxidizing agents are various N(III) species which are formed autocatalytically during the etching process. The concentration of acetic acid also plays an important role as it lowers the degree of dissociation of HF and of HNO3. This has an influence on the pH and the standard potential of the etching solution. The Organic Peracid Etches are mixtures of hydrogen peroxide and a short-chain alkanoic acid like acetic acid. Such systems are strictly speaking not aqueous solutions, the reactive species is the peracid formed.Within each system, however, a certain relationship is perceived between the selectivity of the etching solution on the one hand, and the and the activation energy or the removal rate on the other. The decreased activation energy for the etching process of silicon at a dislocation can be calculated from experimental data by using the Arrhenius equation (chapter 6.3). It was found that the strain inside the crystal lattice caused by a dislocation loop leads to an increase of the potential energy of ~ 5 % and, hence, a decrease of the activation energy of ~ 5 % and an increase in the removal rate of ~ 100 %.
In this thesis the first fully integrated Boltzmann+hydrodynamics approach to relativistic heavy ion reactions has been developed. After a short introduction that motivates the study of heavy ion reactions as the tool to get insights about the QCD phase diagram, the most important theoretical approaches to describe the system are reviewed. To model the dynamical evolution of the collective system assuming local thermal equilibrium ideal hydrodynamics seems to be a good tool. Nowadays, the development of either viscous hydrodynamic codes or hybrid approaches is favoured. For the microscopic description of the hadronic as well as the partonic stage of the evolution transport approaches have beeen successfully applied, since they generate the full phse-space dynamics of all the particles. The hadron-string transport approach that this work is based on is the Ultra-relativistic Quantum Molecular Dynamics (UrQMD) approach. It constitutes an effective solution of the relativistic Boltzmann equation and is restricted to binary collisions of the propagated hadrons. Therefore, the Boltzmann equation and the basic assumptions of this model are introduced. Furthermore, predictions for the charged particle multiplicities at LHC energies are made. The next step is the development of a new framework to calculate the baryon number density in a transport approach. Time evolutions of the net baryon number and the quark density have been calculated at AGS, SPS and RHIC energies and the new approach leads to reasonable results over the whole energy range. Studies of phase diagram trajectories using hydrodynamics are performed as a first move into the direction of the development of the hybrid approach. The hybrid approach that has been developed as the main part of this thesis is based on the UrQMD transport approach with an intermediate hydrodynamical evolution for the hot and dense stage of the collision. The initial energy and baryon number density distributions are not smooth and not symmetric in any direction and the initial velocity profiles are non-trivial since they are generated by the non-equilibrium transport approach. The fulll (3+1) dimensional ideal relativistic one fluid dynamics evolution is solved using the SHASTA algorithm. For the present work, three different equations of state have been used, namely a hadron gas equation of state without a QGP phase transition, a chiral EoS and a bag model EoS including a strong first order phase transition. For the freeze-out transition from hydrodynamics to the cascade calculation two different set-ups are employed. Either an in the computational frame isochronous freeze-out or an gradual freeze-out that mimics an iso-eigentime criterion. The particle vectors are generated by Monte Carlo methods according to the Cooper-Frye formula and UrQMD takes care of the final decoupling procedure of the particles. The parameter dependences of the model are investigated and the time evolution of different quantities is explored. The final pion and proton multiplicities are lower in the hybrid model calculation due to the isentropic hydrodynamic expansion while the yields for strange particles are enhanced due to the local equilibrium in the hydrodynamic evolution. The elliptic flow values at SPS energies are shown to be in line with an ideal hydrodynamic evolution if a proper initial state is used and the final freeze-out proceeds gradually. The hybrid model calculation is able to reproduce the experimentally measured integrated as well as transverse momentum dependent $v_2$ values for charged particles. The multiplicity and mean transverse mass excitation function is calculated for pions, protons and kaons in the energy range from $E_{\rm lab}=2-160A~$GeV. It is observed that the different freeze-out procedures have almost as much influence on the mean transverse mass excitation function as the equation of state. The experimentally observed step-like behaviour of the mean transverse mass excitation function is only reproduced, if a first order phase transition with a large latent heat is applied or the EoS is effectively softened due to non-equilibrium effects in the hadronic transport calculation. The HBT correlation of the negatively charged pion source created in central Pb+Pb collisions at SPS energies are investigated with the hybrid model. It has been found that the latent heat influences the emission of particles visibly and hence the HBT radii of the pion source. The final hadronic interactions after the hydrodynamic freeze-out are very important for the HBT correlation since a large amount of collisions and decays still takes place during this period.
The mTOR kinase inhibitor rapamycin (sirolimus) is a drug with potent immunosuppressive and antiproliferative properties. We found that rapamycin induces the TGF/Smad signaling cascade in rat mesangial cells (MC) as depicted by the nuclear translocation of phospho-Smads 2, -3 and Smad-4, respectively. Concomitantly rapamycin increases the nuclear DNA binding of receptor (R)- and co-Smad proteins to a cognate Smad-binding element (SBE) which in turn causes an increase in profibrotic gene expression as exemplified by the connective tissue growth factor (CTGF) and plasminogen activator inhibitor 1 (PAI-1). Using small interfering (si)RNA we demonstrate that Smad 2/3 activation by rapamycin depends on its endogenous receptor FK-binding protein 12 (FKBP12). Mechanistically, Smad induction by rapamycin is initiated by an increase in active TGF1 as shown by ELISA and by the inhibitory effects of a neutralizing TGF antibody. Using an activin receptor-like kinase (ALK)-5 inhibitor and by siRNA against the TGF type II receptor TGF-RII) we furthermore demonstrate a functional involvement of both types of TGF receptors. However, rapamycin did not compete with TGFfor TGF-receptor binding as found in radioligand-binding assay. Besides SB203580, a specific inhibitor of the p38 MAPK, the reactive oxygen species (ROS) scavenger N-acetyl-cysteine (NAC) and a cell-permeable superoxide dismutase (SOD) mimetic strongly abrogated the stimulatory effects of rapamycin on Smad 2 and 3 phosphorylation. Furthermore, the rapid increase in Dichlorofluorescein (DCF) formation implies that rapamycin mainly acts through ROS. In conclusion, activation of the profibrotic TGFSmad signaling cascade accompanies the immunosuppressive and antiproliferative actions of rapamycin. Keywords: FK506 binding protein; p38 MAP kinase; rapamycin; renal fibrosis; Smads; TGFβ
In mitochondrial respiration, the soluble protein cytochrome c accepts an electron from the membrane bound cytochrome bc1. The interaction between cytochrome bc1 and cytochrome c is highly transient in nature, enabling turnover numbers greater than 160 s-1. Yeast cytochrome bc1 has been successfully crystallised with bound cytochrome c with the help of an antibody fragment (Lange and Hunte 2002; Solmaz and Hunte 2008). In all crystal structures of the complex, the homodimeric cytochrome bc1 binds only one cytochrome c, with the binding site located on subunit cytochrome c1. Univalent cytochrome c binding is correlated with conformational changes of the Rieske protein head domain and subunit QCR6p. The interface of the complex is small. The haem moieties are centrally located in a mainly non-polar contact site that includes a cation–! interaction and is surrounded by complementary charged residues. The crystal structure is in agreement with the general architecture of the interfaces of transient redox complexes and also reveals several interesting features unique to the cytochrome bc1. On the basis of the crystal structures, an extensive thermodynamic and kinetic characterisation of the interaction was carried out in this work to challenge the static snapshot of the bound proteins in the crystal structure as the relevant physiological electron transfer. The thermodynamic parameters of the interaction between the redox partners were determined using isothermal titration calorimetry (ITC). The association constant for cytochrome bc1 and cytochrome c in oxidised state under physiological ionic strength of 120 mM at 25 °C, was determined to be 5 " 103 M-1 by direct ITC titration. So, the partners interact with an affinity of 200 #M. In spite of the low affinity the complex has a life time ($ = 1/koff) of 5 #second, sufficiently long to enable the theoretically calculated electron transfer rates of 1.0 " 106 to 2.6 " 107 s%1 with a lifetime ($ = 1/rate) of 1-0.04 μseconds and experimentally determined rate of 7.7 " 104 s%1 with a lifetime of 13 μseconds. The low affinity makes it difficult to ascertain the stoichiometry of binding. The enthalpy of the interaction is endothermic, which is consistent with the nature of an interface where hydrophobic interactions are dominant. The enthalpy and entropy is 3.6 kJmol-1 and 83 kJmol-1K-1, respectively. The importance of key interface residues was also investigated. The role of the interface residue G89 of cytochrome c which might have a role in the dissociation of the complex has been probed by site-directed mutagenesis. The interface contains a cation-! interaction between F230 of cytochrome bc1 and R19 of cytochrome c, which is thought to provide the specificity to the interaction between the otherwise promiscuous partners. To analyse the role of this interaction pair in electron transfer, F230L and F230W mutants were used to measure direct electron transfer rates by flash photolysis and steady state kinetics. The findings indicate that another ! system can work as functional substitution of F230, while deleting the ! system has a deleterious effect on the complex formation. The inability of F230L to achieve the transient and steady state turnover rates as wild type protein indicates a scenario where the variant achieves an altered bound state with inefficient electron transfer pathways and higher edge-to-edge distance. The role of supernumerary subunit QCR6p in complex formation was investigated by steady state kinetics measurements. Subunit QCR6p does not interact directly with cytochrome c but is positioned in such a way that it could electrostatically steer cytochrome c in a reactive ensemble. The highly acidic and disordered N-terminus of QCR6p could interact with a patch of conserved lysine residues on cytochrome c. The role of subunit QCR6p has been assessed using QCR6p deleted cytochrome bc1 and a lysine variant of cytochrome c. The results show that QCR6p not only affects the kinetics of the interaction but is also important for the stability of cytochrome bc1. The kinetic and thermodynamic data obtained during this study provide evidence for the functional importance of non-catalytic cytochrome bc1 subunit QCR6p, show that the entropy driven interaction is indeed of low affinity and highly transient in nature and indicate that the interface is well suited to ensure the high turnover of the electron transfer chain where cytochrome c interacts with multiple partners using overlapping interfaces. The suggested role of the cation-! interaction as a highly specific interaction has been validated.
In over 100 genera of tropical angiosperms, one or more species possess specialised structures for housing ants. The longevity and intimacy of these associations has often facilitated an increasing specialisation of both the ants and the plants, leading to a number of highly specific and obligate symbioses. Early literature contained only few anecdotal reports of the ant genus Cladomyrma WHEELER inhabiting (unidentified) plants. This work presents the new findings on Cladomyrma and its host plants that accumulated over the last two decades. My studies of Cladomyrma reveal that there is a largely overlooked community of south-east Asian plant-ants and their associated plants. Currently the genus consists of at least 12 species. Cladomyrma has been thought to be restricted to the ever-wet part of the West Malesian floristic region, comprising the Malay Peninsula, Borneo, and Sumatra, but recent collections from Thailand and Vietnam indicate that species of the genus penetrate the seasonal tropical forests of Continental Asia. Cladomyrma inhabits 24 plant species belonging to a surprisingly extensive range of plant taxa: Callerya, Saraca, Spatholobus (Fabaceae), Crypteronia (Crypteroniaceae), Drypetes (Putranjivaceae), Ryparosa (Achariaceae), Strychnos (Loganiaceae), Neonauclea (Rubiaceae), Luvunga (Rutaceae) and Sphenodesme (Verbenaceae). In terms of taxonomic diversity on the genus and family level the range of hosts utilised by Cladomyrma is one of the broadest ever recorded for any live stem-nesting plant-ant lineage worldwide. This work provides a species-level overview of all Cladomyrma host plants known from Borneo, the Malay Peninsula and Sumatra, including descriptions of ant-housing structures (domatia), ant inhabitant identity, onset of colonisation during plant ontogeny, nest structure, occupancy rate, and considerations of results obtained from herbarium specimens. Both the regularity of ant association and the degree of morphological specialisation toward myrmecophytism are assessed. The behavioural traits of Cladomyrma are compatible with traits exhibited by other protective plant-ants. This work demonstrates that all species of Cladomyrma investigated (dianeae, maschwitzi, yongi, petalae) confer antiherbivore protection to young leaves of its host. The ants also attack and repell or kill herbivorous insect larvae encountered on young foliage. Cleaning behaviour appears to be a trait shared by all members of the genus, and the two species tested (maschwitzi, petalae) successfully removed termite eggs experimentally placed onto young leaves. Another trait common to all known species of the genus is that the ants preferentially patrol young shoots and leaves ('neophily'). These behavioural traits of Cladomyrma likely reduce stem damage and pathogenic infection of their host. The ants prune encroaching vegetation (tested in dianeae maschwitzi, petalae, yongi, observed in crypteroniae) and attack paper tape used to mark host plants (observed in andrei, dianeae, hobbyi, nudidorsalis, maschwitzi, yongi, petalae). If these traits combined translate into a better reproductive success of the hosts has yet to be verified. Evidence for lifetime fitness benefits is particularly difficult to quantify for the long-lived woody host plants of Cladomyrma. The predominant food source of Cladomyrma appears to be the honeydew of scale insects (Coccidae and Pseudococcidae) which the ants tend inside their nest cavities. Observations on scale insect acquisition by Cladomyrma foundress queens show that hemipteran trophobionts are not transported by the queens on their nuptial flight but they nevertheless arrive on the host plant independently of the ants. Entry into nest chambers is facilitated by small holes kept open by the foundress queen. Most Cladomyrma species have been recorded from only one or two (three) host plant species (andrei, crypteroniae, hobbyi, maschwitzi, nudidorsalis, scopulosa, yongi), but two species, Cladomyrma petalae and C. dianeae, are more catholic in their host usage; the first being a 'generalist' plant-ant colonising hosts across a broad taxonomic range, the second inhabiting several members of the genus Neonauclea. First results of host-choice experiments with C. petalae are presented and the potential mechanisms promoting host specificity are discussed. My studies of the Cladomyrma/plant associations indicate that codiversification and host shifts or host expansions, rather than cospeciation, shape the pattern of species interactions in this system. Finally, I propose a scenario in which three key traits of Cladomyrma –access to live stems, utilisation of indirect food rewards via trophobionts and 'neophily'– are hypothesised to favour niche differentiation and the acquisition of new hosts over evolutionary time.
Drought and salt stress are the major constraint to increase yield in chickpea (Cicer arietinum). Improving drought and high-salinity tolerance is therefore of outmost importance for breeding. However, the complexity of these traits allowed only marginal progress. A solution to the current stagnation is expected from innovative molecular tools such as transcriptome analyses providing insight into stress-related gene activity, which combined with molecular markers and expression (e)QTL mapping, may accelerate knowledge-based breeding. SuperSAGE, an improved version of the serial analysis of gene expression (SAGE) technique, generating genome-wide, high-quality transcription profiles from any eukaryote, has been employed in the present study. The method produces 26bp long fragments (26bp tags) from defined positions in cDNAs, providing sufficient sequence information to unambiguously characterize the mRNAs. Further, SuperSAGE tags may be immediately used to produce microarrays and probes for real-time-PCR, thereby overcoming the lack of genomic tools in non-model organisms.
Höhere Eukaryoten stellen ein Ensemble von Zellen dar, die in Kompartimente unterteilt sind. Somit sind intra- und interzelluläre Transportprozesse entscheidend für das Überleben dieser Zellverbände. In meiner Arbeit habe ich Evolution und Struktur von Translokationskomplexen untersucht, um einige Aspekte dieser komplexen Systeme zu untersuchen. Eingangs befassten wir uns mit Rezeptorsystemen am Beispiel des Proteintransports. Mittels phylogenetischer Analysen fanden wir heraus, dass Pex5 nicht der Urahn der anderen untersuchten 3-TPR-Domänen ist, obwohl Pex5 in allen eukaryotischen Organismen vorkommt. Ein Vergleich der 3-TPR-Domänen mit der restlichen Sequenz des Rezeptorproteins ergab, dass die 3-TPR-Domänen eine langsamere Evolutionsgeschwindigkeit aufweisen, was für eine Evolutionseinschränkung durch Interaktionspartner spricht. Sec72 ist möglicherweise aus einer TPR1 (Hop) Domäne entstanden und eine Funktion als Hsp70-erkennende Komponente des Sec-Komplexes für den post-translationalen Import kann daraus abgeleitet werden. „Recycling“ von 3-TPR-Domänen anderer Proteine konnten wir durch unsere phylogenetische Analyse auch für die zweite 3-TPR-Domäne von Tom34 nachweisen, die mit CYP40/FKBP51/52 clustert. Darüber hinaus war es uns möglich, die plastidär bzw. mitochondriell lokalisierten Formen von Toc64 phylogenetisch zu unterscheiden. Durch Erzeugung von Homologiemodellen konnten organellspezifische Aminosäuren strukturell eingeordnet werden. Dabei stellten wir fest, dass sich fast alle Positionen, die sich in der Aminosäurekomposition unterscheiden, auf der konvexen Seite der 3-TPR-Domäne befinden. Molekulardynamische Simulationen zeigten zudem deutliche Veränderung der Hauptbewegungen der 3-TPR-Domänen nach Komplexierung mit dem Hsp90-C-Terminus. Bei Bindung des Liganden werden intramolekulare Wasserstoffbrücken sowohl auf der konvexen als auch konkaven Seite der 3-TPR-Domäne „umgeschaltet“. Diese Erkenntnisse führen zu zwei Hypothesen: 1.) die Organellspezifität der Rezeptoren wird durch die Interaktion mit anderen Komplexpartnern garantiert und 2.) die Änderungen des Wasserstoffbrückennetzwerkes auf der konvexen Seite nach Hsp90-Bindung führen zur Ausbildung der Bindungsstelle für die andere Komplexkomponente. Beide Hypothesen erklären die experimentellen Beobachtungen bezüglich der Rezeptoren und warum keine phylogenetischen Hinweise für die Existenz von Vorstufenprotein-spezifischen Hsp70/90-Proteinen gefunden werden konnten. Nach dem Rezeptor haben wir uns mit dem Translokationsprozess befasst. Wir konnten phylogenetisch zeigen, dass sich Omp85 aus Proteobakterien im Vergleich zu Cyanobakterien und Eukaryoten insbesondere durch andersartige POTRA Domänen auszeichnet und fanden zwei konservierte Motive in der Porenregion. Zudem konnten wir im Heterokontophyten P. tricornutum ein vollständiges Omp85 identifizieren (bipartite Signalsequenz, 2 POTRAs, Pore mit langen Schleifen). Die Aminosäuresequenz weicht teils deutlich von den bekannten Omp85-Proteinen ab, was die Entdeckung erschwerte. Wir haben damit geklärt, dass auch im Translokationsapparat von komplexen Plastiden ein b-Fassprotein der Omp85 Familie die Kerneinheit bildet. Ebenfalls zu den Protein-transportierenden b-Fassproteinen gehört TolC, das aber im Gegensatz zu Omp85 auch andere Substanzen, wie zum Beispiel Siderophore transportiert. Alr2887 ist das einzige TolC-ähnliche Protein aus Anabaena sp. PCC7120. Vergleichende Phänotypuntersuchungen weisen auf eine Interaktion eines ABC-Transporters (DevBCA Operon) mit Alr2887 hin. Die Distanz zwischen äußerer Membran und Plasmamembran ist in Anabaena doppelt so groß wie in E. coli. Entsprechend fanden wir im Adapterprotein DevB eine stark verlängerte dimere Doppelwendel, die das von TolC gebildete a-Fass im Periplasma bis hin zum ABC-Transporter in der Plasmamembran theoretisch fortsetzen kann. Da verschiedenste in Anabaena existierende ABC-Transporter TolC als Abflusskanal benötigen, nehmen wir an, dass Alr2887 ein Rundumtalent in Bezug auf die zu transportierenden Substrate darstellt. Dieses ist auch aufgrund der basalen Einordnung im phylogenetischen Baum zu vermuten; es könnte somit auch in den „Multi-Drug-Efflux“ involviert sein. Nicht nur ABC-Transporter, auch TonB-abhängige Transporter stehen in funktionellem Zusammenhang mit TolC. Wir haben Aminosäuresequenzen von ~4600 TBDTs aus Gram-negativen Bakterien und Cyanobakterien zusammengetragen und nach ihrer paarweisen Ähnlichkeit geclustert. Anhand experimentell charakterisierter TBDTs mit bekannten Substraten und TBDTs mit vorhergesagten Substraten konnten wir sehr vielen Clustern ein Substrat zuordnen, das die in ihnen zusammengefassten TBDTs aller Wahrscheinlichkeit nach importieren. Wir konnten ferner feststellen, dass es noch eine Menge weiterer Cluster mit unbekannten Substratspezifitäten gibt und unsere Analysen stimulieren somit die Arbeiten an diesem System im Allgemeinen und in Cyanobakterien im Besonderen.
In Philadelphia Chromosome (Ph) positive ALL and CML the fusion between BCR and ABL leads to the BCR/ABL fusion proteins, which induces the leukemic phenotype because of the constitutive activation of multiple signaling pathways down-stream to the aberrant BCR/ABL fusion tyrosine kinase. Targeted inhibition of BCR/ABL by ABL-kinase inhibitors induces apoptosis in BCR/ABL transformed cells and leads to complete remission in Ph positive leukemia patients. However, a large portion of patients with advanced Ph+ leukemia relapse and acquire resistance. Kinase domain (KD) mutations interfering with inhibitor binding represent the major mechanism of acquired resistance in patients with Ph+ leukemia. Tetramerization of BCR/ABL through the N-terminal coiled-coil region (CC) of BCR is essential for the ABL-kinase activation. Targeting the CC-domain forces BCR/ABL into a monomeric conformation, reduces its kinase activity and increases the sensitivity for Imatinib. Here we show that i.) targeting the tetramerization by a peptide representing the Helix-2 of the CC efficiently reduced the autophosphorylation of both WT BCR/ABL and its mutants; ii.) Helix-2 inhibited the transformation potential of BCR/ABL independently of the presence of mutations; iii.) Helix-2 efficiently cooperated with Imatinib as revealed by their effects on the transformation potential and the factor-independence related to BCR/ABL with the exception of mutant T315I. These findings suggest that BCR/ABL harboring the T315I mutation have a transformation potential which is at least partially independent from its kinase activity. Targeted inhibition of BCR/ABL by small molecule inhibitors reverses the transformation potential of BCR/ABL. We definitively proved that targeting the tetramerization of BCR/ABL mediated by the N-terminal coiled-coil domain (CC) using competitive peptides, representing the Helix-2 of the CC, represents a valid therapeutic approach for treating Ph+ leukemia. To further develop competitive peptides for targeting BCR/ABL, we created a membrane permeable Helix-2 peptide (MPH-2) by fusing the Helix-2 peptide with a peptide transduction tag. In this study, we report that the MPH-2: (i) interacted with BCR/ABL in vivo; (ii) efficiently inhibited the autophosphorylation of BCR/ABL; (iii) suppressed the growth and viability of Ph+ leukemic cells; and (iv) was efficiently transduced into mononuclear cells (MNC) in an in vivo mouse model. The T315I mutation confers resistance against all actually approved ABL-kinase inhibitors and competitive peptides. It seems not only to decrease affinity for kinase inhibitors but to confer additional features to the leukemogenic potential of BCR/ABL. To determine the role of T315I in resistance to the inhibition of oligomerization and in the leukemogenic potential of BCR/ABL, we investigated its influence on loss-of-function mutants with regard to the capacity to mediate factor-independence. Thus we studied the effects of T315I on BCR/ABL mutants lacking functional domains in the BCR portion indispensable for the oncogenic activity of BCR/ABL such as the N-terminal coiled coil (CC), the tyrosine phosphorylation site Y177 and the serine/threonine kinase domain (ST), as well as on the ABL portion of BCR/ABL (#ABL-T315I) with or without the inhibitory SH3 (delta SH3-ABL) domain. Here we report that i.) T315I restored the capacity to mediate factor independence of oligomerization_deficient p185BCR/ABL; ii.) resistance of p185-T315I against inhibition of the oligomerization depends on the phosphorylation at Y177; iii.) autophosphorylation at Y177 is not affected by the oligomerization inhibition, but phosphorylation at Y177 of endogenous BCR parallels the effects of T315I; iv.) the effects of T315I are associated with an intact ABL_kinase activity; v.) the presence of T315I is associated with an increased ABL_kinase activity also in mutants unable to induce Y177 phosphorylation of endogenous BCR; vi.) there is no direct relationship between the ABL-kinase activity and the capacity to mediate factor_independence induced by T315I as revealed by the #ABL-T315I mutant, which was unable to induce Y177 phosphorylation of BCR only in the presence of the SH3 domain. In contrast to its physiological counterpart c-ABL, the BCR/ABL kinase is constitutively activated, inducing the leukemic phenotype. The N-terminus of c-ABL (Cap region) contributes to the regulation of its kinase function. It is myristoylated, and the myristate residue binds to a hydrophobic pocket in the kinase domain known as the myristoyl binding pocket in a process called “capping”, which results in an auto-inhibited conformation. Because the cap region is replaced by the N-terminus of BCR, BCR/ABL “escapes” this auto-inhibition. Allosteric inhibition by myristate “mimics”, such as GNF-2, is able to inhibit unmutated BCR/ABL, but not the BCR/ABL that harbors the “gatekeeper” mutation T315I. Here we investigated the possibility of increasing the efficacy of allosteric inhibition by blocking BCR/ABL oligomerization. We demonstrate that inhibition of oligomerization was able not only to increase the efficacy of GNF-2 on unmutated BCR/ABL, but also to overcome the resistance of BCR/ABL-T315I to allosteric inhibition. These results strongly suggest that the response to allosteric inhibition by GNF-2 is inversely related to the degree of oligomerization of BCR/ABL. Taken together these data suggest that the inhibition of tetramerization inhibits BCR/ABL-mediated transformation and can contribute to overcome Imatinib-resistance. The study provides the first evidence that an efficient peptide transduction system facilitates the employ-ment of competitive peptides to target the oligomerization interface of BCR/ABL in vivo. Further the data show that T315I confers additional leukemogenic activity to BCR/ABL, which might explain the clinical behavior of patients with BCR/ABL -T315I-positive blasts. In summary, our observations establish a new approach for the molecular targeting of BCR/ABL and its resistant mutants represented by the combination of oligomerization and allosteric inhibitors.
The aim of the study was to investigate the role of the CX3C chemokine FKN in the role of platelet adhesion. The presence of the FKN receptor CX3CR1 in platelets is demonstrated and G-protein dependent activation of platelets with soluble FKN results in the increased adhesion of platelets to collagen and fibrinogen under flow 228 and adhesion of leucocytes to firmly attached platelets 231. Whether membrane-bound FKN is capable to promote the direct adhesion of platelets in flowing blood analogue to leucocytes was completely unknown. The adhesion mechanisms of FKN in mediating the adhesion of leucocytes under flow are well characterised and represent a novel unique mechanism of leucocyte capture and firm adhesion: FKN is responsible for immediate arrest of flowing CX3CR1 expressing leucocytes without the participation of additional adhesion receptors and ligands. This is in contrast to the classical leucocyte adhesion pathways, which are multistep processes involving leucocyte arrest, rolling and subsequent cell activation prior to firm arrest. In leucocytes, the FKN – CX3CR1 axis is sufficient to allow rapid arrest of leucocytes at low shear flow conditions 67, 101, 115, 122, 261. The set of data from this study demonstrates that immobilised FKN was capable to mediate the adhesion of platelets under low shear conditions, whereas there was no interaction in the absence of shear flow. In the presence of vWf in the adhesion matrix, FKN mediated the potent increased adhesion of platelets. This was in parts due to the activation of flowing platelets via CX3CR1 and the augmented translocation of platelets on FKN via the vWf receptor GPIbα. With respect to platelet activation, the function of endothelial FKN was comparable to leucocytes: in both cell types, the FKN dependent activation is mediated by its cognate receptor CX3CR1. This is in contrast to the adhesive capacity: in leucocytes, FKN dependent adhesion is mediated by CX3CR1, whereas in platelets, the adhesive capacity was mostly mediated by the vWf receptor GPIbα with only minor contribution from CX3CR1. In platelets, activation and adhesion by FKN were mediated by two distinct receptors, whereas in leucocytes, CX3CR1 is solely responsible for FKN dependent activation and adhesion. The presented results point out to a role of platelets in early stage of atherosclerosis. The in vivo expression of both, FKN and vWf is regulated by TNF-α, which is released in early stages of inflammation. The presence of vWf and FKN in the endothelial lining of blood vessels during these conditions is sufficient to initiate the capturing and translocation of platelets on the tunica interna. The rolling of platelets on the endothelium can induce endothelial damage and inflammation of the vessel, which might advance to the generation of clinically significant atherosclerotic plaques and fibrous atheroma.
Amphibians of Malawi : an analysis of their richness and community diversity in a changing landscape
(2009)
This study summarizes the state of the knowledge of the amphibian diversity in Malawi highlighting the possible threats impending on this fauna correlated with human encroachment and land use change. New data about diversity, distribution and ecology have been gathered, whereas the old ones have been summarised, reviewed and commented. In order to put in context the responses of the amphibian communities to land use change, the main environmental characteristics of the country at a broad space and time scale have been explored. Furthermore, the original habitats and vegetation have been described, and their status in the present day Malawi discussed. In the same way, an overview of the actual state of the knowledge about the Malawian amphibians has been provided, and their ability to act as surrogate of environmental integrity in Sub-Saharan Africa commented on the basis of the available studies. Afterwards, the results of the study of the selected areas and samples have been analysed within this newly generated context. Different field and laboratory methods were applied for the quantitative analysis of the richness and diversity of the communities. Opportunistic search was used to detect species richness, whereas the visual encounter survey was applied to detect the relative abundance of species. Several indices of diversity and similarity, and extrapolations by means of true richness estimators were used for the analysis of the alpha and beta diversities. Additional information were gathered by means of pitfall traps with drift fence, and by the recording of the advertisement calls. Supplementary methods were applied for the analysis of the taxonomic composition of the collected material. In Malawi 84 amphibian species are recorded, two of which still undescribed (Leptopelis sp. and Phrynobatrachus sp.). Three further species need to be confirmed and might be possibly present too: Amietia viridireticulata, Hemisus guineensis, and Hyperolius minutissimus. Additionally, other unrecognised cryptic species — at least one — are present within the Hyperolius nasutus complex. Most of the species belong to the order Anura (82 species; 97.6%), whereas only two species belong to the Gymnophiona (2.4%). Anurans are divided into 12 families and 23 genera, whereas the two caecilians species into one family (Caecilidae) and two genera. The more diverse family is the Hyperoliidae (21 species, 25%) followed by the families Ptychadenidae (13 species, 15%), Arthroleptidae (11 species, 13%), Phrynobatrachidae (10 species, 12%), and Bufonidae and Pyxicephalidae (9 species, 11% respectively). The remaining high family diversity (seven families, Caecilidae included) is contrasted by a low number of species (11 species in total, 14%). Based on the available distribution data, the value of species richness of the anuran communities in Malawi is comprised between 5‒45 species. In average 16.8 ± 9.0 species (N=80) are to be found, 75% of the sites have less than 21 species, and only two sites have more than 25 species. Four hot spots of amphibian diversity were identified: the Nyika Plateau (24 species), Mangochi-Malombe (25 species), Zomba Plateau (32 species) and the Mulanje Massif (45 species). In the studied areas a mean of 14.7 ± 1.6 species was observed and extrapolations by means of the true richness estimators were in good agreement with this result. Among the studied areas the richest was Palm Forest Reserve (17 species), followed by Kaningina Forest Reserve (16 species) and Vinthukutu F. R., and Vwaza W. R (15 species). The poorest area was the Misuku Mountains with 12 species only and a slightly different ranking was generated by the true richness estimators. The mean of the species present in the samples was 4.8 ± 2.1 species, considerably less than the true species richness detected in the respective areas. Basing on the ranking generated by the K-dominance plot the most diverse samples were Palm F. R. and Misuku, whereas the less diverse were Kaningina F. R. and Fort Lister, confirmed by the values of the diversity indices. The main finding of this study was the observation of the lack of a clear match between environmental degradation and amphibian diversity, and the crucial importance of temporary water bodies for the preservation of the amphibian diversity. In fact, despite most of the original habitat formerly present in Malawi have been destroyed and replaced by cultivations, the amphibian communities of different areas showed a comparable diversity at both family and species richness level, and no evident match between environmental degradation and amphibian diversity was recognisable. Differences in species richness could mostly be explained by natural factors such the elevation gradient and the presence of temporary water bodies. However, it was not possible to exclude that the communities have changed during historical time and the shift in species composition already occurred together with the modification of their relative frequencies. Most of the species showed a remarkable ecological plasticity and several species were found in a variety of both natural and altered habitats. The classification of the Malawian amphibians on the basis of ecological guilds based on the available natural history data showed the preponderance (76%) of generalist pond breeders. As a consequence, most of these amphibians possessed a scarce capacity to act as surrogates of habitat integrity. Based on the result of this study the farm bush landscape with traditional agriculture practices bears a great potential to support amphibian diversity in terms of species richness, representing a compromise between local economic development and conservation. Furthermore, the results of this study indicate the outstanding importance of the southern-east region of Malawi for the conservation of the country’s amphibians.
If we want to develop a semantic analysis for explicit performatives such as I promise you to free Willy, we are faced with the following puzzle: In order to account for the speech act expressed by the performative verb, one can assume that the so-called performative clause is purely performative and provides the illocutionary force of the speech act whose content is given by the semantic object denoted by the complement clause. Yet under this perspective, the performative clause that is, next to the performative verb, the indexicals I and you that refer to the speaker and to the addressee of the utterance context is semantically invisible and does not contribute compositionally its meaning to the meaning of the entire explicit performative sentence. Conversely, if we account for the truth conditional contribution of the performative clause and deny that the meaning of the performative verb is purely performative, then we have to find a way to account for the speech act expressed by the performative verb. Of course, there is already the widely accepted and very appealing indirectness account for explicit performative utterances developed by Bach & Harnish (1979). Roughly, Bach and Harnish solve this puzzle in deriving the performativity by means of a pragmatic inference process. According to them, the important speech act performed by means of the utterance of the explicit performative sentence is a kind of the conventionalized indirect speech act. However, the boundary between semantics and pragmatics can be drawn in many various ways. Therefore, I think there could be other perspectives regarding the interface between the truth-functional treatment of the declarative explicit performative sentences and the speech acts performed with their utterances and which are expressed by the performative verbs. Hence, this thesis consists in the experiment to develop a further analysis and to check out its consequences with respect to the semantics and pragmatics of explicit performative utterances and the new interface emerged. Briefly, the experiment runs as follows: First, I develop an analysis for explicit performative sentences framed by parenthetical structures such as in (1)(a). In a second step, this parenthetical analysis is applied to the proper Austinian explicit performative sentences in (1)(b). (1) a. Tomorrow, I promise you this, I will teach them Tyrolean songs. b. I promise you that I will teach them Tyrolean songs. To analyze at first explicit performatives framed by parenthetical structures bears the convenience that we are faced with two utterances of two main clauses. In (1)(a) there is the utterance of the host sentence Tomorrow I will teach them Tyrolean songs, and the utterance of the explicit parenthetical I promise you this, where the demonstrative this refers to the utterance of Tomorrow I will teach them Tyrolean songs. Since speakers perform speech acts with utterances of main clauses, I assume that the meaning of the explicit parenthetical I promise you this specifies that the actual illocutionary force of the utterance of Tomorrow I will teach them Tyrolean songs is the illocutionary force of a promise. Hence, instead of deriving an indirect illocutionary force by means of a pragmatic inference schema, we can deal with an ordinary direct speech act that is performed with the utterance of the host sentence. This kind of analysis stresses the particular discourse function of explicit performative utterances. Performative verbs are used whenever the contextual information is not sufficient to determine the illocutionary force of the corresponding implicit speech act. The resulting consequences of the parenthetical analysis are interesting since they cast a different light on performative verbs. Surprisingly, the performative verbs are not performative at all. They do not constitute the execution of a speech act, but are execution supporting. Instead of constituting the particular illocutionary force, they merely specify the illocutionary force of the utterance of the host sentence. For instance, the speaker utters the explicit parenthetical I promise you this for specifying what he is simultaneously doing. Hence the speaker does not succeed in performing the promise simply because he is uttering I promise you this. Rather, by means of the information conveyed by the utterance of I promise you this, the potential illocutionary forces of the utterance of the host sentence are disambiguated. Thus, it is not the case that explicit parentheticals are trivially true when uttered. Their function is more complex. Their self-verifying property (‘saying so makes it so’) is explained by means of disambiguation. Furthermore, according to the parenthetical analysis, instead of being purely performative, the performative verbs contribute compositionally their meanings to the truth conditions of the entire explicit performative sentence. Together with its consequences, this analysis is applied to the proper Austinian performatives, which display subordination. I assume that regardless of their structure, explicit performatives always semantically and pragmatically behave as the parenthetical analysis predicts.
The pictorial art of the Church, as a spiritual product of the Christian civilisation, has continually received great influences from its ecclesiastical tradition and it was defined by its formal aesthetical standards and its iconographic preferences. A more nuanced reading of the parallels can be attained by placing the images in their visual context, which would allow a better appreciation of the meanings within. The biblical story of Adam and Eve, which is the theme of the following thesis, reflects the differentiation between the Eastern and the Western understanding of the events of the history of the holy Oikonomia, a point, which is the major ground for the development of the relative pictorial motifs. The protoplasts are the protagonists from their creation and life in paradise, the fall and expulsion until their resurrection through Christ. Their story is visualised in a number of scenes and episodes, having thus their original sin and resurrection for specific reasons centralised. This doctoral thesis attempts to collect as many parallels of the scenes is possible, trying to collate the Eastern with the Western visual approach in a deductive way, in order to reach our constructive conclusions and make available the combination of the art, theology and liturgy in the scenes of Adam and Eve in Genesis and in Resurrection (Anastasis). The reading we tried to perform was based upon the specific iconographical elements, which were worth to be commented. Our aim was to detect the direct bond between the production of art and the relevant patristic and apocryphal writings or even the theological theories, by quoting texts from the ecclesiastical literature, as well as the liturgical praxis.
Das libor Markt Modell (LMM) ist seit seiner Entwicklung in den Veröffentlichungen von Brace, Gatarek, Musiela (1997), einerseits, und unabhängig von diesen von Miltersen, Sandmann, Sondermann (1997), andererseits, zu dem anerkanntesten Instrument zur Modellierung der Zinsstruktur und der damit verbundenen Preisfindung für relevante Finanzderivate geworden. libor steht dabei für London Inter-Bank Offered Rate, ein täglich in London fixierter Referenz-Zins für kurzfristige Anlagen. Drei- oder sechsmonatige Laufzeiten sind in Verbindung mit dem LMM üblich. Die Forschung zur Verbesserung dieses Modells hat in den letzten Jahren an Zuwachs gewonnen. Beim Versuch den Fehler der Anpassung an die täglich beobachteten Preise von Zinsoptionen wie Caps und Swaptions zu verringern, erhält man in der Folge auch genauere Bewertungen für andere, exotischere, Derivate. Die zugrunde liegende und zentrale Idee des LMM besteht darin, die Forward (Termin) Zinsen direkt als primären (Vektor) Prozess mehrerer libor Sätze zu betrachten und diese simultan zu modellieren, anstatt sie nur herzuleiten aus einem übergeordneten, unendlich dimensionalen Forward Zinsprozess, wie im zeitlich früher entwickelten Heath-Jarrow-Morton Modell. Das überzeugendste Argument für diese Diskretisierung ist, dass die libor Sätze direkt im Markt beobachtbar sind und ihre Volatilitäten auf eine natürliche Weise in Beziehung gebracht werden können zu bereits liquide gehandelten Produkten, eben jenen Caps und Swaptions. Dennoch beinhaltet das Modell eine gravierende Insuffizienz, indem es keine Krümmung der Volatilitätsoberfläche, im Hinblick auf Optionen mit verschiedenen Basiszinsen, abbildet. Wie im einfachen eindimensionalen Black-Scholes Modell prägen sich auch hier die Ungenauigkeiten der Verteilung in fehlenden heavy tails deutlich aus. Smile und Skew Effekte sind erkennbar. Im klassischen liborMarkt Modell wird in Richtung der Basiszinsdimension nur eine affine Struktur erzeugt, welche bestenfalls als Approximation für die erwünschte Oberfläche dienen kann. Die beobachteten Verzerrungen führen naturgemäss zu einer ungenauen Abbildung der Realität und fehlerhaften Reproduktion der Preise in Regionen, die ein wenig entfernt vom Bereich am Geld liegen. Derartig ungewollte Dissonanzen in Gewinn und Verlustzahlen führten z.B. in 1998 zu gravierenden Verlusten im Zinsderivateportfolio der heutigen Royal Bank of Scotland. ...
Signal-dependent regulation of actin dynamics is essential for many cellular processes, including directional cell migration. In particular, cell migration is initiated by lamellipodia, actin-based protrusions of the plasma membrane. The formation of these protruding structures require incessant assembly and disassembly of actin filaments. The Arp2/3 complex and WAVE proteins are essential for both lamellipodium formation and its dynamics. WAVEs mediate the activation of the Arp2/3 complex downstream of the small GTPase Rac, thus being critical for Rac- and RTK-induced actin polymerization and cell migration. The WAVE-family proteins are always found associated with multiprotein complexes. The most abundant WAVE-based complex is referred to as the WANP (WAVE2-Abi-1-Nap1-PIR121) complex. IQGAP1 is a huge scaffolding protein with multiple protein-interacting domains. IQGAP1 participates in many fundamental activities, including regulation of the actin cytoskeleton, mitogenic, adhesive and migratory responses, as well as in cell polarity and cellular trafficking. IQGAP1 binds to N-WASP, thus raising the possibility that it might control actin nucleation by the Arp2/3 complex. In this study, IQGAP1 was found co-immunoprecipitated not only with WAVE, but also with the endogenous WANP-complex subunits. Correspondingly, IQGAP1 associated to both anti-WAVE and anti-Abi-1 immuno-complexes. Pull-down experiments proved that IQGAP1 binds directly to the WANP-complex subunits. Physical interaction between IQGAP1 and the reconstituted WANP complex could also be demonstrated. Together, these data indicate that IQGAP1 is an accessory component of the WANP complex. Interestingly, the IQGAP-WANP complex disassembled after either EGF stimulation or transfection with constitutively active Cdc42 and Rac1. HeLa cells devoid of IQGAP1 showed diminished and less persistent ruffling upon EGF, but not HGF, stimulation in comparison with the control. This phenotype was accompanied by a strong reduction in chemotaxis towards both growth factors, which was as dramatic as in WANP-complex knockdown (KD) cells. Moreover, GM130 and Giantin showed a polarized and flat ribbon-like pattern in control cells, as it is expected for cis- and cis/medial-Golgi markers. Conversely, small and dispersed vesicular structures were found in both IQGAP1 KD and WANP-complex KD cells. Importantly, Arp2/3-complex silencing resulted in the same phenotypes. Consistently, Brefeldin A-induced disassembly of the Golgi strongly inhibited the IQGAP1-WANP-complex interaction and chemotaxis towards EGF in wild-type cells. The re-expression of an RNAi-resistant wild-type IQGAP1 in IQGAP1 KD cells fully rescued both the ruffling abilities and Golgi structure. A constitutively active mutant, unable to bind to neither Rac1 /Cdc42 nor the WANP complex, could reconstitute only the former defect. Hence, this study shows that actin dynamics regulated by the IQGAP1-WANP complex controls Golgi-apparatus architecture and its contribution to cell chemotaxis. The working model here proposes that at the Golgi apparatus, recruitment of the WANP complex by IQGAP1 leads to the assembly of actin filaments required to maintain the appropriated Golgi morphology. The dissociation of the complex may be required to allow the remodeling of the Golgi membranes in order to respond following a chemoattractant gradient.
In this work we investigate phenomenological aspects of an anisotropic quark-gluon plasma. In the first part of this thesis, we formulate phenomenologicalmodels that take into account the momentumspace anisotropy of the system developed during the expansion of the fireball at early-times. By including the proper-time dependence of the parton hard momentum scale, phard(), and the plasma anisotropy parameter, Xi, the proposed models allow us to interpolate from 0+1 pre-equilibrated expansion at early-times to 0+1 ideal hydrodynamics at late times. We study dilepton production as a valuable observable to experimentally determine the isotropization time of the system as well as the degree of anisotropy developed at early-times. We generalize our interpolating models to include the rapidity dependence of phard and consider its impact on forward dileptons. Next, we discuss how to constrain the onset of hydrodynamics by demanding two requirements of the solutions to the equations of motion of viscous hydrodynamics. We show this explicitly for 0+1 dimensional 2nd-order conformal viscous hydrodynamics and find that the initial conditions are non-trivially constrained. Finally, we demonstrate how to match the initial conditions for 0+1 dimensional viscous hydrodynamics from pre-equilibrated expansion. We analyze the dependence of the entropy production on the pre-equilibrium phase and discuss limitations of the standard definitions of the non-equilibrium entropy in kinetic theory.
This thesis demonstrates the advancement of PELDOR spectroscopy beyond its original design of distance measurements in order to disentangle a maximum amount of information additionally encoded in the PELDOR data. In particular, the successful synthesis of novel polynitroxide radicals is described as well as the extraction of the relative orientation of spin labels, conformational flexibility and the separation of dipolar and exchange coupling via orientation selective PELDOR measurements in combination with PESIM based simulations. Moreover, the method of PELDOR "Spin Counting" was experimentally validated.
Despite the well-known importance of ribonucleic acids (RNA) in cell biology, it is astounding to realize the pace at which new fundamental functions of RNAs have been discovered. One of the fundamental reasons for the multitude of functions of RNA is the property of RNA to adopt different conformations or folds. The primary sequence of RNA, a linear polymer built from four different repetition units, can fold into alternate secondary structure motifs which in turn form alternate long-range interactions in complex tertiary structures. Ligands such as metal ions or small molecular weight metabolites and also proteins or peptides can bind to RNA and induce the changes in tertiary conformation. For example, in the cell, RNA participates in gene regulation in the form of riboswitches. Riboswitches are found in untranslated regions of messenger RNA (mRNA) and adopt alternate conformations depending on the presence or absence of specific metabolites. If a metabolite is present above a specific concentration, it induces a conformational change in the respective riboswitch by binding and thereby alters gene expression. Another example is the RNA thermometer which participates in the cell translational mechanism by a similar strategy. Translation initiation requires the binding of RNA thermometers to the ribosome. The ribosome binding region is located in the 5’ untranslated region of mRNA. At low temperatures this region is prevented from binding to the ribosome by forming basepairs. At higher temperatures, these basepairs dissociate allowing ribosome binding and subsequent translation. Therefore, the characterization and delineation of the kinetics and pathway of RNA folding is important to understand the function of RNA and is an important contribution to fundamentally understand RNA’s role in the cell. RNA conformational transitions occur over a wide range of timescales. Depending on the timescale, various biophysical techniques are used to study RNA conformational transitions. In these biophysical studies, achieving good structural and temporal resolution constitute frequently encountered challenges or limitations. For example, single molecule FRET spectroscopy provides high temporal resolution in the milliseconds at high sensitivity but lacks atomic resolution. Recent advances in the field of Nuclear Magnetic Resonance (NMR) spectroscopy have enabled the elucidation of tertiary folding events to be characterized with atomic resolution. This thesis involves the use of NMR spectroscopy to characterize the folding of RNA molecules. Kinetics experiments require rapid initiation of the kinetics followed by monitoring of the reaction. In this thesis, two different folding initiation techniques have been applied and coupled to the subsequent detection of RNA folding using NMR spectroscopy, namely, photocaging and rapid mixing. The method of photocaging is well established (Kuhn and Schwalbe, 2000) and builds on the following principle: A photolabile moiety is attached to a molecule that prevents a specific interaction. Upon irradiation of the molecule with the photolabile group using laser light at a specific wave length, at which the molecule of interest is not absorbing, the protecting group is released. In our group, together with the group of S. Pitsch, ETH Lausanne, we could "cage" RNA at its equilibrium state by a photolabile molecule (similar work has been carried out in the group of A. Heckel). Rapid and traceless release of the photolabile precursor compound by a laser pulse releases the RNA to fold into its native state; the build-up of the native state of the RNA is monitored by NMR signals that are uniquely characteristic for the native state of the RNA. By optically coupling a laser source to an NMR magnet, the above procedure can take place in situ and the kinetics recorded by NMR. Several different molecules can be caged: The photocage can be attached to RNA. Then, a modified photolabile nucleotide can be placed at strategic positions of a target RNA whose folding properties is to be studied. The photocage can also be attached to a ligand: if folding is dependent on ligand binding then the ligand can be modified to carry a photosensitive unit whose degradation allows binding to RNA. In this thesis, an alternative method for photocaging is introduced. Here, metal ions essential for folding of the RNA are photocaged using the photolabile chelating agent Dimethyl-nitrophen (DMN). Photolysis of DMNr releases the metal ion, thereby RNA folding is initiated. In the rapid-mixing technique, one of (several) components required for proper folding of the RNA is rapidly injected into an NMR sample in situ by the use of a pneumatic injection device. ...
This thesis is devoted to the developement of a classical model for the study of the energetics and stability of carbon nanotubes. The motivation behind such a model stems from the fact that production of nanotubes in a well-controlled manner requires a detailed understanding of their energetics. In order to study this different theoretical approaches are possible, ranging from the computationally expensive quantum mechanical first principle methods to the relatively simple classical models. A wisely developed classical model has the advantage that it could be used for systems of any possible size while still producing reasonable results. The model developed in this thesis is based on the well-known liquid drop model without the volume term and hence we call it liquid surface model. Based on the assumption that the energy of a nanotube can be expressed in terms of its geometrical parameters like surface area, curvature and shape of the edge, liquid surface model is able to predict the binding energy of nanotubes of any chirality once the total energy and the chiral indices of it are known. The model is suggested for open end and capped nanotubes and it is shown that the energy of capped nanotubes is determined by five physical parameters, while for the open end nanotubes three parameters are sufficient. The parameters of the liquid surface model are determined from the calculations performed with the use of empirical Tersoff and Brenner potentials and the accuracy of the model is analysed. It is shown that the liquid surface model can predict the binding energy per atom for capped nanotubes with relative error below 0.3% from that calculated using Brenner potential, corresponding to the absolute energy difference being less than 0.01 eV. The influence of the catalytic nanoparticle on top of which a nanotube grows, on the nanotube energetics is also discussed. It is demonstrated that the presence of catalytic nanoparticle changes the binding energy per atom in such a way that if the interaction of a nanotube with the catalytic nanoparticle is weak then attachment of an additional atom to a nanotube is an energetically favourable process, while if the catalytic nanoparticle nanotube interaction is strong , it becomes energetically more favourable for the nanotube to collapse. The suggested model gives important insights in the energetics and stability of nanotubes of different chiralities and is an important step towards the understanding of nanotube growth process. Young modulus and curvature constant are calculated for single-wall carbon nanotubes from the paremeters of the liquid surface model and demonstrated that the obtained values are in agreement with the values reported earlier both theoretically and experimentally. The calculated Young modulus and the curvature constant were used to conclude about the accuracy of the Tersoff and Brenner potentials. Since the parameters of the liquid surface model are obtained from the Tersoff and Brenner potential calculations, the agreement of elastic properties derived from these parameters corresponds to the fact that both potentials are capable of describing the elastic properties of nanotubes. Finally, the thesis discuss the possible extension of the model to various systems of interest.
New industries are recognized as new impetus to national wealth. At the same time, they are increasingly becoming geographically concentrated in some well defined areas. But current studies on the emergence of industrial clusters tend to analyze favorable driving factors. This dissertation takes the example of a Chinese endogenous industrial cluster, the traditional Chinese medicine (TCM) cluster at Tonghua, a small peripheral city in Northeastern China, to contribute to the theoretical understanding of the emergence of industrial cluster as a co-evolutionary process of organizations, institutions and firms, or, to put it more broadly, as economic evolution embedded in complex socio-economic contexts. The recent advance in evolutionary and co-evolutionary economics which considers the economy and economic landscape as dynamic process instead of equilibrium can be regarded as a part of broader and more intellectual turn of quest for history in social sciences. Although the principle of "history matters" is widely acknowledged, it tends to be reduced to a quite simple concept of "path dependence". However, path dependence cannot offer space for new path creation, except from an external shock. Accordingly, the role of human conscious action or Schumpeterian innovation should be added to path analysis through the concept of path creation. Furthermore, and more importantly, history should be understood as context, and historical context can be explored through the understanding of multi-paths and interaction among them over time. So path inter-dependence (co-evolution between paths) would be useful to better understand the complexity of real history. Since the industrial cluster is composed of interconnected firms and is also subject to changes in institution and technology, I will focus on the multi-way causal relationship between firm, institution and technology. The theorizing is not entirely new, but most of the theoretical and empirical discussions are at the national or industrial level, not regional or local one. A competitive cluster can be regarded as a co-evolutionary hotspot in which multiple populations actively interact and are interconnected. Co-evolution itself is a dynamic and evolutionary process. So I will adopt a dynamic and evolutionary view to examine co-evolutionary degree or co-evolutionary effects in the Tonghua pharmaceutical cluster through time. After a brief introduction which deals with the national institutional changes that are highly associated with new venture creation, entrepreneurship, and innovation, with registrations on drug and healthcare system, and with changes in market demand of China’s pharmaceutical industry and geographical distribution, I will collect evidences from three aspects based upon field survey and second hand data, i.e., the history of the enterprises, the origin of entrepreneurship, and the knowledge of evolution, linking their respective generative relationships through the genealogical method. In this volume, the evolution of the Tonghua pharmaceutical firm organization, the formation of local entrepreneurship, historical accumulation of knowledge, and particular knowledge of transfer among generations of firms will be discussed, then I will probe into co-adaption and co-evolution between local formal and informal institutions and organizations in Tonghua’s TCM industry. In addition, I will try to understand the co-evolutionary process at different geographical levels (namely, national and local). In summary, my main findings include the following several points. Firstly, in the course of the emergence of Tonghua’s pharmaceutical industry, local social networks and the traditional alliance between enterprises and government have played important roles. Secondly, the most important factor that influences the evolution of endogenous industrial clusters such as the Tonghua pharmaceutical industry in transitional countries is not the change in technology, but the change in fundamental national institutions. Thirdly, the success of the Tonghua pharmaceutical industry can be ascribed to the creation of multiple paths largely based on initial conditions, which implies that economic policy should have historical consciousness, namely, new economic innovation should make full use of both historical legacies and existing assets. Finally, it is co-adaption and co-selection of firm organization, institution, and technology that have jointly made Tonghua’s pharmaceutical industry become highly competitive, which means that whether one region can grasp new opportunities partially depends on its capabilities to coordinate a varity of development agents.
Understanding the dynamics of recurrent neural networks is crucial for explaining how the brain processes information. In the neocortex, a range of different plasticity mechanisms are shaping recurrent networks into effective information processing circuits that learn appropriate representations for time-varying sensory stimuli. However, it has been difficult to mimic these abilities in artificial neural models. In the present thesis, we introduce several recurrent network models of threshold units that combine spike timing dependent plasticity with homeostatic plasticity mechanisms like intrinsic plasticity or synaptic normalization. We investigate how these different forms of plasticity shape the dynamics and computational properties of recurrent networks. The networks receive input sequences composed of different symbols and learn the structure embedded in these sequences in an unsupervised manner. Information is encoded in the form of trajectories through a high-dimensional state space reminiscent of recent biological findings on cortical coding. We find that these self-organizing plastic networks are able to represent and "understand" the spatio-temporal patterns in their inputs while maintaining their dynamics in a healthy regime suitable for learning. The emergent properties are not easily predictable on the basis of the individual plasticity mechanisms at work. Our results underscore the importance of studying the interaction of different forms of plasticity on network behavior.
Large amplitude intramolecular motions in non-rigid molecules are a fundamental issue in chemistry and biology. The conventional approaches for study these motions by far-infrared and microwave spectroscopy are not applicable when the molecule is non-polar. Therefore, in the current thesis an alternative approach for the investigation of large amplitude intramolecular motions was developed and tested. This new method is based on femtosecond rotational degenerate four-wave mixing spectroscopy (fs DFWM), which is a particular implementation of rotational coherence spectroscopy. The method was successfully applied for the investigation of pseudorotation in pyrrolidine and the ring-puckering vibration in cyclopentene. Another important subject is the photophysics of molecules and molecular clusters which have an ultrashort lifetime of their electronically excited state (photoreactivity). These ultrashort lifetimes often represent a protective mechanism causing photostability. The photoreactivity is usually the manifestation either of an “elementary” reaction, such as proton or electron transfer, which occurs in the excited state or of a fast non-radiative deactivation processes, such as internal conversion via conical intersection of the electronically excited and ground state. Due to a short-lived excited state, the conventional vibrational spectroscopic methods, such as IR depletion detected by resonance two-photon ionization spectroscopy (IR/R2PI), are not applicable for the structural investigation of these systems. Therefore, new approach, termed IR depletion detected by multiphoton ionization with femtosecond laser pulses (IR/fsMPI), was developed for studying the structure of photoreactive microsolvated molecules. The IR/fsMPI technique was applied for investigating the clusters of 1H-pyrrolo[3,2-h]quinoline with water/methanol as well as adenine- and 9-methyl-adenine-hydrates. In addition, the excited state dynamics of bifunctional azaaromatic molecule 7-(2'-pyridyl)indole (7PyIn) was studied by femtosecond pump-probe resonance excitation multiphoton ionization technique (fs REMPI). Under electronic excitation of this molecule a fast proton transfer (phototautomerization) takes place, which is followed by radiationless excited state deactivation process. The fs REMPI spectra lead to the conclusion that the phototautomerization in 7PyIn is coupled with a twisting of the molecule, and that the twisting provides an efficient channel for ultrafast radiationless excited state deactivation. This pattern of excited-state tautomerization/deactivation might be quite general.
This thesis presents a 5.9 Å map of yeast FAS obtained by cryo-electron microscopy using single particle analysis (SPA). The EM-map has been analyzed both by quantitative and qualitative analysis to aid in understanding of the structure and dynamics of yeast FAS. This study approaches the factors limiting the resolution in EM (>20 Å) and further discusses the possibilities of achieving higher-resolutions (<10 Å) in cryo-EM by single particle analysis. Here, SPA is highlighted as a powerful tool for understanding the structure and dynamics of macro-molecular complexes at near native conditions. Though SPA has been used over the last four decades, the low-resolution range (20-30 Å) of the method has limited its use in structural biology. Over the last decade, sub nanometer resolution (<10 Å) structures solved by SPA have been reported --both in studies involving symmetric particles, such as GroEL (D7) and asymmetric particles, such as ribosomes (C1). Recently, near-atomic resolution in the range of 3.8-4.2 Å has been achieved in cases of highly symmetric icosahedral viral capsid structures as well. The yeast FAS structure (D3) presented here is one of two low symmetry structures submitted to the EM-database in a resolution range of 5-6 Å; the other being GroEL (D7). Fatty acid synthase (FAS) is the key enzyme for the biosynthesis of fatty acids in living organisms. There are two types of FAS, namely the type II FAS system in prokaryotes, consisting of a set of individual enzymes, and type I FAS found in eukaryotes as a multienzyme complex. Yeast fatty acid synthase (FAS) is a 2.6 MDa barrel-shaped multienzyme complex, which carries out cyclic synthesis of fatty acids. By electron cryomicroscopy of single particles we obtained a 3D map of yeast FAS at 5.9 Å resolution. Compared to the crystal structures of fungal FAS, the EM map reveals major differences and new features that indicate a considerably different arrangement of the complex in solution, as well as a high degree of variance inside the barrel. Distinct density regions in the reaction chambers next to each of the catalytic domains fit well with the substratebinding acyl carrier protein (ACP) domain. In each case, this resulted in the expected distance of ~18 Å from the ACP substrate binding site to the active site of the catalytic domains. The multiple, partially occupied positions of the ACP within the reaction chamber provide direct insight into the proposed substrate-shuttling mechanism of fatty acid synthesis in this large cellular machine.
TeaABC from the halophilic bacterium Halomonas elongata belongs to the family of tripartite ATP-independent periplasmic (TRAP) transporters. It facilitates the uptake of the compatible solutes ectoine and hydroxyectoine which protect the cell from dehydration by accumulating in the cytoplasm during hyperosmotic stress. It is the only known TRAP transporter activated by osmotic stress. Ectoine and hydroxyectoine accumulation in H. elongata is regulated by the cytoplasmic universal stress protein TeaD. The gene encoding TeaD is located in the same operon as the TeaABC gene. TeaD regulates the cellular homeostasis of ectoine possibly by interacting directly or indirectly with TeaABC. All subunits of TeaABC and TeaD were expressed in E. coli and purified. With TeaD and the solute binding protein (SBP) TeaA high levels of expression suitable for crystallization could be obtained and their 3D structures solved. The small transmembrane protein TeaB and the transporter TeaC showed only moderate and low levels of expression respectively. Functional analysis on TeaA was performed using Isothermal Titration Calorimetry. The measurements demonstrate that TeaA is a high affinity ectoine-binding protein (Kd = 0.19 _M) that also has a significant affinity for hydroxyectoine (Kd = 3.8 _M). The structure of TeaA was solved using ab initio phase determination by MAD (multiple anomalous dispersion). TeaA structures were determined in three conformations: TeaA alone, TeaA in complex with ectoine and TeaA in complex with hydroxyectoine. The resolutions of the structures were 2.2, 1.55 and 1.80 Å, respectively. These represent the first structures of an osmolyte SBP associated to a TRAP transporter. The structures reveal similar ligand binding compared to osmolyte SBPs of ABC transporter pointing to coevolution of the ligand binding modes. Moreover, unique features such as the solvent-mediated specific binding of the ligands ectoine and hydroxyectoine could be observed for TeaA. The structure of TeaD in complex with its cofactor ATP was solved by molecular replacement at a resolution of 1.9 Å. Comparison with other structures of universal stress proteins shows striking oligomerization and ATP binding in TeaD. In conclusion, this work presents the first detailed analysis of the molecular mechanisms underlying ligand recognition of an osmoregulated transporter from the TRAP-transporter family.
This study addresses the structure-function relationships of three essential membrane proteins: Porin from Paracoccus denitrificans, Porin OmpG from Eschericia coli and BetP from Corynobacterium glutamicum using Fourier transform infrared (FT-IR) spectroscopy and Attenuated Total Reflection (ATR) techniques. The structure of porin from P. denitrificans is known for more than a decade; however, the mechanism for loss of functionality together with the monomerization was not clear. In this study we have addressed the role of lipids for the functionality of porin using FT-IR. OmpF porin was found to interact with the lipid molecules via the aromatic girdles surrounding the protein for functionality. In this study, molecular bonds and groups of the lipids were established as reporter groups probing at different depths of the bilayer in order to understand the interaction partner of the aromatic girdles of porins. Monomerization of the trimeric assembly of OmpF porin reconstituted in lipids is induced by increasing the temperature. Porin (OmpF) was found to be extremely stable: The secondary structure of the protein was unaltered up to the temperature-induced main transition, around 80-90 °C, above which it is denatured. However, the interaction of the aromatic girdle with the lipid molecules exhibited distinct changes at much lower temperature values (40 - 50°) where, according to the previous functional studies, monomerization and the loss of function occurs. The results are compared with OmpG porin from E.coli, for which the functional unit is a monomer. The aromatic girdle-lipid interaction was monitored by the tyrosine aromatic ring C=C vibrational mode, a universal marker for the protein stability and interaction. We have also found that the aromatic girdles of porins are interacting with the interfacial region of the lipid bilayer instead of lipid headgroups. Lipid-protein interaction was found to be not only essential for the structural stability, but also for the functionality of OmpF porin. We have also studied the structural properties of OmpG from E.coli. The structure of OmpG at two pH values has been resolved using X-ray crystallography and the channel has been proposed to attain different states at different pH values as closed (pH < 5.5) and open (pH >7.5). This study, using IR spectroscopy, revealed that the pH-induced opening and closing of the channel is reflected by the frequency shifts of the ? sheet structure. OmpG has more rigid ? barrel properties upon opening of the channel. IR spectral analysis revealed multiple ? sheet signals with different hydrogen bond strengths. This enabled us to monitor the formation of hydrogen bridges between the extracellular loops upon opening of the channel. The conclusion that OmpG porin having two states at different pH values was also confirmed by the three mutants where the role of the histidine pair (H231 & H261) and loop 6 has been addressed. Temperature-profiling of the wild type (WT) protein and the mutants did not show pH dependent structural stability differences in detergent solution. However, the WT protein was found to be more stable in the open form in 2D crystals than the closed form. Reconstitution into lipids has increased the transition temperature value by ~20 °C in the closed state and ~25 °C in the open state. Therefore we conclude that the open and closed state of OmpG has structural stability differences that are only revealed in the lipid environment. A comparison of the transition temperature values of OmpG WT and the mutants suggested that the hydrogen bond network among S218-H231-H261-D267, together with the formation of 12 residue-long ?-sheet contributes to the structural stability of the open channel. In the process of closing and opening of the channel, the globular structure of the protein remains mainly unchanged, while there are changes in the side chain moieties. In addition to the role of the histidine pair and the loop L6, in situ opening/closing experiments showed that the negatively charged amino acids, i.e. Asp and Glu, and Arg residues also play an active role; possibly by interacting with each other inside the pore lumen. Therefore it could be concluded that the closure of the channel at acidic pH values is not only via closing the channel entrance by loop 6, but also via changing the electric potential inside the lumen due to the different states of charged amino acids in order to effectively block the gateway. BetP from C.glutamicum attains an active and inactive state in order to adjust its glycine betaine uptake rate to the osmotic conditions that the cell encounters. The structure of BetP is not yet available. The WT protein exhibited structural differences in the presence of excess K+, which is one of the activation conditions. In 2D crystals, increasing the ionic strength to 700 mM K+ was shown to induce changes in the ?-helical moiety with contributions from the ester groups and one Tyr residue using ATR-FTIR. An increase in ionic strength to 220 mM K+ was found to be the threshold value of potassium concentration ([K+]) where the protein exhibits structural alterations in detergent solution. The determined [K+] values are in good agreement with the previous functional studies. However, there are differences in the activation profile of BetP in 2D crystals and in detergent solution, which points out that the lipids are involved in the conformational transition from the inactive to the active state and their absence can lead to different structural properties. BetP WT was found to have ~65% alpha-helix, ~25% random coil and ~10% turn structure in detergent solution. In the presence of excess K+, the WT protein is found to adapt more unordered structure. Secondary structure analysis of the mutants revealed that both the N- and C-terminus are in ?-helical conformation. Reconstitution of WT protein in 2D crystals increased the main transition (denaturation) temperature value from ~62 °C to ~85 °C, a clear indication that the protein is more stable in lipid environment. Temperature-profiling of the two forms of the WT protein revealed that the structural breakdown is preceeded by monomerization of the trimeric assembly. Comparing the two forms of the WT protein and the mutant BetA, we conclude that the oligomeric status is stabilized via the interactions among hydrophilic regions involving the N terminus. H/D exchange and activation with excess K+ in D2O-buffer revealed that activation of the protein involves the interaction of Arg and Asp/Glu residues in the cytoplasmic region of the protein. BetP WT and the two mutants tested, i.e. BetA and BetP?C45, showed differences in protein packing upon activation. The WT protein and BetP?C45 mutant also show changes in the hydrogen bonding properties of turns. Since BetA does not show such a property in activation, we conclude that the N-terminus interacts with the loops in the inactive state via the interaction of charged amino acids for the WT protein and that this interaction is altered during the activation. It could be argued that the protein packing is affected via the changes in turns upon activation. We also have found experimental evidence that one Tyr residue has different orientations in the active and inactive state of BetP. Based on the previous functional studies, it could be one of the five Tyr residues in the cytoplasmic region of the protein (in loop 3, 6, 7 or C-terminus). The mutant BetP?C45, on the other hand, showed fewer differences between the active and inactive state conditions and based on the H/D exchange rates, the mutant shows the properties of an active WT protein, proving that the C-terminal truncation impairs the conformational transition between the active and inactive states.
The current thesis is devoted to a systematic study of fluctuations and correlations in heavy-ion collisions, which might be considered as probes for the phase transition and the critical point in the phase diagram, within the Hadron-String- Dynamics (HSD) microscopic transport approach. This is a powerful tool to study nucleus-nucleus collisions and allows to completely simulate experimental collisions on an event-by-event basis. Thus, the transport model has been used to study fluctuations and correlations including the influence of experimental acceptance as well as centrality, system size and collision energy. The comparison to experimental data can separate the effects induced by a phase transition since there is no phase transition in the HSD version used here. Firstly the centrality dependence of multiplicity fluctuations has been studied. Different centrality selections have been performed in the analysis in correspondence to the experimental situation. For the fixed target experiment NA49 events with fixed numbers of the projectile participants have been studied while in the collider experiment PHENIX centrality classes of events have been defined by the multiplicity in certain phase space region. A decrease of participant number fluctuations (and thus volume fluctuations) in more central collisions for both experiments has been obtained. Another area of this work addresses to transport model calculations of multiplicity fluctuations in nucleus-nucleus collisions as a function of colliding energy and system size. This study is in full correspondence to the experimental program of the NA61 Collaboration at the SPS. Central C+C, S+S, In+In, and Pb+Pb nuclear collisions at Elab = 10, 20, 30, 40, 80, 158 AGeV have been investigated. The expected enhanced fluctuations - attributed to the critical point and phase transition - can be observed experimentally on top of a monotonic and smooth ‘hadronic background’. These findings should be helpful for the optimal choice of collision systems and collision energies for the experimental search of the QCD critical point. Other observables are fluctuations of ratios of hadrons (e.g. pions, kaons, protons, etc.) which are not so much affected by volume fluctuations. In particular HSD results for the kaon-to-pion ratio fluctuations, which has been regarded as promising observable for a long time, are presented from low SPS energies up to high energies at RHIC. In addition to the HSD calculations statistical model is also used in terms of microcanonical, canonical and grand canonical ensembles. Further a study of the system size event-by-event fluctuations causing rapidity forward-backward correlations in relativistic heavy-ion collisions is presented. The HSD simulations reveal strong forward-backward correlations and reproduce the main qualitative features of the STAR data in A+A collisions at RHIC energies. It has been shown that strong forward-backward correlations arise due to an averaging over many different events that belong to one centrality bin. An optimization of the experimental selection of centrality classes is presented, which is relevant for the program of the NA61 collaboration at CERN, the low-energy program at RHIC, as well as future experiments at FAIR.
Ein wesentliches Ziel der Physik mit schweren Ionen ist die Untersuchung der Zustände von Kernmaterie bei hohen Dichten bzw. Temperaturen. Solche Zustände lassen sich durch Kollisionen von hochenergetischen schweren Ionen in Teilchenbeschleunigern wie dem Super Proton Synchrotron SPS am Europäischen Kernforschungszentrum CERN in Genf erzeugen und untersuchen. Die vorliegende Arbeit beschäftigt sich mit der Analyse des Einflusses des in einer solchen Kollision erzeugten Mediums auf hochenergetische Teilchen, welche dieses Medium durchqueren. Hierzu werden Korrelationen zwischen Teilchen mit hohem Transversalimpuls pt als Funktion der Zentralität der Kollisionen und der Ladung der beteiligten Teilchen untersucht. Ziel ist es, hierdurch eine experimentelle Grundlage für die theoretische Beschreibung der Eigenschaften des Mediums in solchen Kollisionen bereitzustellen. ...
SIVsmmPBj-derived lentiviral vectors are capable of efficient primary human monocyte transduction, a capacity which is linked to the viral accessory protein Vpx. To enable novel gene therapy approaches targeting monocytes, in this thesis it was aimed to generate enhanced lentiviral vectors that meet the required standards for clinical applications with respect to gene transfer efficiency and safety. The vectors were tested for their suitability in a relevant therapeutic gene transfer approach. At first, it was investigated whether vectors derived from another Vpx-carrying lentivirus reveal the same capacity for monocyte transduction as SIVsmmPBj-derived vectors. A transduction experiment using HIV-2-derived vectors in comparison to PBj-derived vectors revealed a comparable transduction capacity, thus disproving the assumed uniqueness of the PBj vectors. The further generation and analysis of expression constructs for the vpx genes of HIV-2 and SIVmac demonstrated a similar functionality in monocyte transduction as the Vpx of PBj. As VpxPBj, both Vpx proteins facilitated monocyte transduction of a vpx-deficient PBj-derived vector system. For the generation of enhanced SIVsmmPBj and HIV-2 vector systems, only the transfer vectors were optimized, since the packaging vectors available already meet current standards. At first, several modifications were introduced into an available preliminary PBj-derived transfer vector by conventional cloning. The modifications included insertions of cPPT/CTS and WPRE as well as the deletions of the remaining pol sequence, the second exons of tat end rev, and the U3-region within the 3’LTR to generate a SIN vector. Thus, beside safety enhancement, the vector titers were also increased from 9.1x105 TU/ml achieved after concentration with the initial transfer vector up to 1.1x107 TU/ml with the final transfer vector. The PBj vector retained its capability of monocyte transduction when supplemented with Vpx. This conventional method of vector enhancement is time-consuming and may result in only sub-optimal vectors, since it depends on the presence of restriction sites which may not allow deletion of all needless sequences. Moreover, mutations may accumulate during the high number of cloning and amplification steps. Therefore, a new and easier method for lentiviral transfer vector generation was conceived. Three essential segments of the viral genome (5‘ LTR, RRE, ΔU3-3’ LTR) are amplified on the template of the lentiviral wild-type genome and fused by Fusion-PCR. Further necessary elements namely the cPPT/CTS-element, MCS, and PPT are included into the resulting vector by extension of the nucleotide primers used for the PCRs. The amplified and fused vector-scaffold can easily be integrated into a plasmid backbone, followed by insertion of the expression cassette of choice. By applying this approach, two novel lentiviral transfer vectors, based on the non-human SIVsmmPBj and the human HIV-2, were derived. Vector titers achieved for PBj and HIV-2 vectors supplemented with Vpx reached up to 4.0x108 TU/ml and 5.4x108 TU/ml, respectively. The capacity for monocyte transduction was maintained. Thus, safe and efficient, state of the art HIV-2- and PBj-derived vector systems are now available for future gene therapy strategies. Finally, the new vectors were used to set up an approach for gene correction of gp91phox-deficient monocytes for the treatment of X-linked chronic granulomatous disease (xCGD). The administration of autologous, gene-corrected monocytes to counteract systemic and acute infections could lead to a decreased infection load, dissolve granulomas and therefore improve the survival rate of hematopoietic stem cell transplantation (HSCT) which is the current treatment of choice for this disease. First, methods for analysis of gp91phox function were established. Next, they were employed to demonstrate the capacity of monocytes, obtained from healthy humans or mice, for phagocytosis, oxidative burst, and Staphylococcus aureus killing. The in vivo half-life of murine monocytes in the bloodstream and their distribution to specific tissues was determined. Lastly, HIV-1 vectors were used to transfer the gp91phox gene into monocytes from gp91phox-deficient mice. This resulted in the successful restoration of the oxidative burst ability in the cells. In summary, the general suitability of the new vectors for treatment of CGD by monocyte transduction was demonstrated. The results of the mouse experiments provide the foundation for future challenge experiments to evaluate the capability of gene-corrected monocytes to kill off microbes in vivo.
Die anaerobe Atmung mit Nitrat und Nitrit als terminalen Elektronenakzeptoren bildet einen wichtigen Teil des biologischen Stickstoff-Zyklus. Beispiele sind Denitrifikation und respiratorische Nitrat-Ammonifikation, wobei in beiden Fällen in einem ersten Schritt Nitrat zu Nitrit reduziert wird. In der Denitrifikation entstehen dann verschiedene gasförmige Produkte (NO, N2O, N2), wogegen Nitrit in der Ammonifikation ohne die Freisetzung weiterer Zwischenprodukte direkt zu Ammonium reduziert wird. Während die terminalen Reduktasen dieser Atmungsketten gut untersucht sind, ist das Wissen über die Zusammensetzung kompletter Elektronentransportketten sowie die Interaktion einzelner Proteine als auch zwischen den Proteinen und Chinonen in der Membran begrenzt. Ziel dieser Arbeit war die Charakterisierung der membranständigen Chinol-Dehydrogenasen NapGH und NrfH in der respiratorischen Nitrat-Ammonifikation von Wolinella succinogenes. Dieses Epsilonproteobakterium ist ein etablierter Modellorganismus der anaeroben Atmung und wächst durch respiratorische Nitrat-Ammonifikation mit Formiat oder H2 als Elektronendonoren. Als terminale Reduktasen werden dabei die periplasmatische Nitratreduktase NapA und die Cytochom c-Nitritreduktase NrfA benötigt. Die Genomsequenz weist keine weiteren typischen Nitrat- und Nitritreduktasen auf, und napA- und nrfA-defiziente Mutanten sind nicht in der Lage durch Nitrat- bzw. Nitritatmung wachsen. Das Operon des Nap-Systems (napAGHBFLD) von W. succinogenes kodiert Proteine, die an der Nitrat-Reduktion durch Menachinol beteiligt sind (NapA, -B, -G und -H) und Proteine, die für die Reifung und Prozessierung von NapA benötigt werden (NapF, -L und –D). Im Gegensatz zu vielen anderen Bakterien läuft die Nitrat-Atmung unabhängig von einem NapC-ähnlichen Protein ab, das als membrangebundenes Tetrahäm-Cytochrom c für die Chinol-Oxidation zuständig ist und Elektronen über den Elektronenüberträger NapB an die terminale Reduktase NapA liefert. Zwar sind im Genom zwei NapC-Homologe kodiert (FccC und NrfH), doch die Deletion beider Gene hatte keinen Einfluss auf die Nitrat-Atmung. Es wurde vermutet, dass die Funktion von NapC in W. succinogenes stattdessen durch die beiden Fe/S-Cluster Proteine NapG und NapH übernommen wird. Die Reduktion von Nitrit zu Ammonium wird durch den NrfHA-Komplex katalysiert. Das Pentahäm-Cytochrom c NrfA bildet dabei die katalytische Untereinheit, die über das membranständige Tetrahäm-Cytochrom c auf der periplasmatischen Seite der Membran gebunden ist. NrfH gehört zur NapC/NirT-Familie und überträgt Elektronen von Menachinol auf NrfA. Mittels gerichteter Mutagenese von nrfH wurden in früheren Arbeiten bereits Aminosäure-Reste identifiziert, die essentiell für die Elektronentransportaktivität von Formiat zu Nitrit sind.
In this work the preparation of organic donor-acceptor thin films was studied. A chamber for organic molecular beam deposition was designed and integrated into an existing deposition system for metallic thin films. Furthermore, the deposition system was extended by a load-lock with integrated bake-out function, a chamber for the deposition of metallic contacts via stencil mask technique and a sputtering chamber. For the sublimation of the organic compounds several effusion cells were designed. The evaporation characteristic and the temperature profile within the cells was studied. Additionally, a simulation program was developed, which calculates the evaporation characteristics of different cell types. The following processes were integrated: evaporation of particles, migration on the cell walls and collisions in the gas phase. It is also possible to consider a temperature gradient within the cell. All processes can be studied separately and their relative strength can be varied. To verify the simulation results several evaporation experiments with different cell types were employed. The thickness profile of the prepared thin films was measured position-dependently. The results are in good agreement with the simulation. Furthermore, the simulation program was extended to the field of electron beam induced deposition (EBID). The second part of this work deals with the preparation and characterization of organic thin films. The focus hereby lies on the charge transfer salt (BEDT-TTF)(TCNQ), which has three known structure variants. Thin films were prepared by different methods of co-evaporation and were studied with optical microscopy, X-ray diffraction and energy dispersive X-ray spectroscopy (EDX).The formation of the monoclinic phase of (BEDT-TTF)(TCNQ) could be shown. As a last part tunnel structures were prepared as first thin film devices and measured in a He4 cryostat.
Based on the commonly used and well-established state-of-the-art DNA sequencing method, i. e. Sanger sequencing, the major target of future research is to develop a fast, cost-effective and gelelectrophoresis-free sequencing method. The aim of the new sequencing technologies is to detect DNA mutations faster and more accurate in order to develop individual therapies for patients (personalized medicine). For this purpose, a lot of novel sequencing techniques like pyrosequencing, mass-spectrometry-assisted sequencing, sequencing by hybridization etc. have been put into practice and already led to commercialized sequencers. The sequencing technology we were mostly interested in is the so-called sequencing-by-synthesis method (SBS). This PhD thesis covers the synthesis of modified nucleosides – the so-called reversible terminators – and their evaluation as reversible terminators. These 3′-modified and dye-labeled nucleotides are incorporated by the polymerase into the DNA-template, then the DNA-synthesis is stopped. After detection of the fluorescent signal, the reversible terminator has to be cleavable in a way (i. e. the polymerase-blocking modification) that the DNA-synthesis can continue. As a result of the polymerase-acceptance tests that have been carried out with the two triphosphates cyanoethoxymethyl(CEM)-dTTP and cyanoethyl(CE)-dTTP as substrates it became clear that the latter one was better incorporated than the first one. Based on this knowledge all four key compounds for the whole reversible terminators possessing the cyanoethyl (CE) group where synthesized within this PhD thesis. Additionally to the synthesis of the modified key compounds, the cleavability of the cyanoethyl function had to be evaluated which is an essential requirement of a reversible terminator for SBS. For addressing this issue, three different CE- and CEM modified monophosphates were created. For each of these three monophosphates an individual synthetic strategy has been developed within this PhD work, each of these strategies and subsequent phosphorylation led to the desired modification. These previously unknown model compounds mimicking the solubility of short oligonucleotides were employed the for qualitative cleavage experiments after their purification and spectroscopical characterization. With these three monophosphates suitable cleavage conditions for a quantitative removal of the CE and the CEM group were examined. In case of the CE function we selectively improved the cleavage conditions while varying the solvent, the reaction temperature as well as the amount of cleaving agent used, in order to make the conditions applicable for an SBS experiment. Due to the fact that the CE function was the most important modification for our SBS experiment, we could even optimize the cleavage efficiency by employing co-solvents like DMSO or DMF. An additional cleavage experiment was carried out by using a short CE-modified oligomer which led to further results that were comparable to the ones obtained from the cleavage experiments of the monomers. One big difference is the required amount of TBAF as cleaving agent for the quantitative removal of the CE-modification from the oligomer. In this case, 7500 equivalents of TBAF are needed for complete CE cleavage at 45 °C compared to the amount of 40 to 80 equivalents TBAF for the monomer (monophosphate). As a conclusion of this result we assume that the amount of cleaving agent and the solubility of the oligomer plays an important role in the CE cleavage efficiency. This assumption was already supported by Saneyoshi et al. who demonstrated for CE-modified RNA oligonucleotides that the CE-cleavage rate is strongly lowered with the increasing of the oligomer length. Thus we could demonstrate that the CE function is quantitatively removable from an oligomer without destroying it. With these results in hands we could prove that the CEM and the CE group are quantitatively cleavable and therefore applicable as blocking groups for reversible terminators. The conditions for the CE cleavage are used for the ArraySBS-“proof-of-principle” which is currently under investigation.
5-lipoxygenase (5-LO) is the key enzyme in the formation of inflammatory leukotrienes, which are mediators of inflammation and allergy. The 5-LO catalyses the oxidation of arachidonic acid to 5-HPETE and subsequently to LTA4. The leukotrienes are involved in the development and maintenance of inflammatory diseases, like asthma and allergic rhinitis. Additionally, 5-LO is overexpressed in some cancer types, although its relevance is still not fully understood. 5-LO expressing cells are B- lymphocytes and cells of myeloid origin like monocytes, macrophages and granulocytes. The 5-LO promoter lacks a TATA or CCAT box and covers two CpG islands. These are characteristics of a housekeeping gene, but as the 5-LO is not expressed ubiquitiously, the expression of the 5-LO is tightly regulated. Epigenetic mechanisms were known to be involved in the control of the 5-LO expression. The HDAC inhibitor TsA significantly induced the transcriptional activity of the 5-LO promoter in reporter gene assays as well as on 5-LO mRNA transcript level in MM6 cells. The GC-boxes GC4 and GC5 in the proximal 5-LO promoter were identified to be essential for the TsA effect, as deletion of these element led to an attenuated TsA effect in reporter gene assay. Recruitment of the transcription factors Sp1 and Sp3 and the RNA polymerase II to the 5-LO promoter was detectable after TsA treatment in MM6 cells by chromatin immunoprecipitation assays (ChIP), while the acetylation status of histone H4 remained unchanged. Likewise it is known that DNA methylation leads to silencing of 5-LO expression in-vitro and in-vivo. The 5-LO promoter is densely methylated in the cell line U937, but unmethylated in HL-60 cells and - elucidated in this study - also in MM6 cells. Reporter gene assays with in-vitro methylated 5-LO promoter containing plasmids revealed that the frequency of methylated CpGs is directly proportional to reduction of 5-LO promoter activity. Incubation of U937 cells with 5-AdC, an inhibitor of DNA methyltransferases, was able to reactivate 5-LO transcription and to demethylate CpG dinucleotides. In the first part of this study the mechanism of TsA induced promoter activation was further investigated. I elucidated the mechanism of Sp1 and Sp3 recruitment to the 5-LO promoter after TsA treatment. Immnoprecipitation assay was used to detect a transcription factor complex containing Sp1 or Sp3 interacting with HDAC proteins, which might change its composition after TsA treatment. Besides the posttranslational modifications of the transcription factors Sp1 and Sp3 after TsA treatment were investigated, potentially causing an increased interaction of the proteins with the 5-LO promoter. Both aspects and their response in HDAC inhibition have been described. TsA did not affect the composition of the Sp1/HDAC1/HDAC2 complex. Sp3 was not located in a complex with the HDAC enzymes. Acetylation of Sp1 and Sp3 was detectable, but no change occurred after TsA treatment. Since neither release of the transcription factors off a complex, nor alterations in posttranslational modifications of Sp1 and Sp3 are the reason for the increased Sp1 and Sp3 binding to the 5-LO promoter, I elucidated alterations in the chromatin structure. The acetylation status of the histone proteins H3 and H4, as well as the chromatin marks H3K4me3, representing active chromatin, and H3K9me, representative for repressive state, were investigated. Additionally, the time course of the TsA effect was determined on 5-LO mRNA level using real-time PCR. The acetylation status of the histone proteins on the 5-LO core promoter correlated with the basal 5-LO mRNA transcript expression in MM6, HL-60 and U937 cells. The highest 5-LO mRNA level was detectable in MM6 cells, followed by HL-60 cells. The lowest 5-LO mRNA level was detected in 5-LO promoter methylated U937 cells. The order of the basal 5-LO mRNA expression of the three cell lines correlates with the basal acetylation status of histone proteins H3 and H4. In MM6 cells the highest basal levels in acH3 and acH4 were detected, followed by HL-60 and U937 cells. Moreover, the data obtained in U937 cells revealed that the correlation between DNA methylation and histone hypoacetylation is alike on the 5-LO promoter. TsA treatment induced the 5-LO mRNA level in the three cell lines with different intensity: 5-LO mRNA level in MM6 cells was induced 11-fold, in HL-60 cells 6- fold and in U937 cells 4- fold. The histone acetylation and methylation levels on the 5-LO promoter after TsA incubation were investigated. No increase in acH3 and acH4, but in H3K4me3 was detectable in MM6 cells by ChIP assay. HL-60 cells showed an increase in acH3 and acH4 as well as in H3K4me3. H3K9me was only detectable in untreated U937 cells, but disappeared after TsA treatment, while acH3, acH4 and H3K4me3 increased constantly after TsA treatme nt. A strong correlation between the histone modifications and the time course of the mRNA expression was detectable in all three cell lines. The combination of the posttranslational modifications acH3, acH4 and H3K4me3 led to a fast effect in transcriptional activation and the maxima of acH3 and acH4 were usually associated with the maximum in 5-LO mRNA transcript level. An increase in H3K4me3 alone, as detected in MM6 cells, led to continuous increase in the 5-LO mRNA expression with a late maximum. Additionally, we detected a slight overall decrease in 5-LO promoter methylation in U937 cells after TsA treatment. This fact taken together with the observed histone modifications could explain the 4- fold response in 5-LO mRNA level to TsA treatment of the methylated cell line U937. Another aim of the present study was to identify the specific HDAC enzymes involved in the 5-LO promoter regulation. Reporter gene assays and real-time PCR with selective HDAC inhibitors revealed that HDACs of class I are involved in 5-LO promoter regulation, namely HDAC 1, 2 and 3. The influence of each of the enzymes seemed to depend on the cell type, as inhibition of HDACs 2, 3 strongly induced 5-LO promoter activity in reporter gene assay in HeLa cells, whereas in MM6 cells HDACs 1 and 2, 3 seemed to be responsible for the 5-LO promoter regulation, measured as 5-LO mRNA level. The HDACs of class IIa and class III are not involved in the regulation of 5-LO mRNA expression. The second part of this study investigated the influence of MBD proteins on the methylated 5-LO promoter and the 5-LO mRNA expression. ChIP assays revealed MBD1, 2 and MeCP2 protein binding to the proximal 5-LO promoter in U937 cells. MBD1 was detectable on the 5-LO promoter in unmethylated HL-60 cells, while no MBD protein was located on the 5-LO promoter in MM6 cells. To elucidate the functional role of the MBD proteins, stable knocked down of MBD proteins was established in U937 cells. 5-LO mRNA transcript level was determined in the knock down clones by real-time PCR. The 5-LO transcript level was increased in all knock down samples. MBD2 knock down clones showed the highest effect in activating 5-LO with a 3- and 4.4-fold increase in the 5-LO mRNA level, followed by MBD1 (3.5- fold) and MeCP2 (2.5-fold) knock down clones. A combined participation of these three enzymes in the corepression of the methylated 5-LO promoter is indicated. Taken together, the data reveal that epigenetic mechanisms are strongly involved in the regulation of 5-LO transcription and might function as a crucial control mechanism of 5-LO expression.
Solid state NMR is a emerging method for the study of membrane proteins, which has received much interest in recent years. Limiting the study of many pharmacologically relevant targets, are the often long measuring times, required to obtain especially higher dimensional solid state NMR spectra of good quality. To address this problem, multiple methods where developed in this work, which can be categorized into two groups. The first set of methods aims at the quality of certain spectra, by implementing a spectral filter, which increases the fidelity of the measured data. The second set of methods, addresses the problem of long measuring times directly, by increasing the sensitivity per unit time, as could be shown, for example, on homo- and heteronuclear singlequantum-singlequantum correlation experiments. The gains in measuring time for the latter group of methods are typically in the order of 2-3, but some experiments allow multiple methods to be employed simultaneously, which can lead to a decrease in measuring time of a factor of up to 8. It is important to mention, that none of the methods introduced in this work require any equipment in addition to the conventional setup present in most sold state NMR laboratories and no changes or addition to the samples under study are required. Therefore the gains reported in this work come at no extra cost and require only minimal implementation effort on the side of the user.
A framework for the analysis and visualization of multielectrode spike trains / von Ovidiu F. Jurjut
(2009)
The brain is a highly distributed system of constantly interacting neurons. Understanding how it gives rise to our subjective experiences and perceptions depends largely on understanding the neuronal mechanisms of information processing. These mechanisms are still poorly understood and a matter of ongoing debate remains the timescale on which the coding process evolves. Recently, multielectrode recordings of neuronal activity have begun to contribute substantially to elucidating how information coding is implemented in brain circuits. Unfortunately, analysis and interpretation of multielectrode data is often difficult because of their complexity and large volume. Here we propose a framework that enables the efficient analysis and visualization of multielectrode spiking data. First, using self-organizing maps, we identified reoccurring multi-neuronal spike patterns that evolve on various timescales. Second, we developed a color-based visualization technique for these patterns. They were mapped onto a three-dimensional color space based on their reciprocal similarities, i.e., similar patterns were assigned similar colors. This innovative representation enables a quick and comprehensive inspection of spiking data and provides a qualitative description of pattern distribution across entire datasets. Third, we quantified the observed pattern expression motifs and we investigated their contribution to the encoding of stimulus-related information. An emphasis was on the timescale on which patterns evolve, covering the temporal scales from synchrony up to mean firing rate. Using our multi-neuronal analysis framework, we investigated data recorded from the primary visual cortex of anesthetized cats. We found that cortical responses to dynamic stimuli are best described as successions of multi-neuronal activation patterns, i.e., trajectories in a multidimensional pattern space. Patterns that encode stimulus-specific information are not confined to a single timescale but can span a broad range of timescales, which are tightly related to the temporal dynamics of the stimuli. Therefore, the strict separation between synchrony and mean firing rate is somewhat artificial as these two represent only extreme cases of a continuum of timescales that are expressed in cortical dynamics. Results also indicate that timescales consistent with the time constants of neuronal membranes and fast synaptic transmission (~10-20 ms) appear to play a particularly salient role in coding, as patterns evolving on these timescales seem to be involved in the representation of stimuli with both slow and fast temporal dynamics.
In the framework of this thesis the intense low energy ion beam transport was investigated. Especially, the beam transport in toroidal magnetic field configurations was discussed, as it may allow the accumulation of high intensive beams in the future. One of the specific tasks is to design an injection system that can be used for the proposed low energy accumulator ring. This thesis regarding beam transport investigations is related to the larger research fields, storage rings used in accelerator physics and non-neutral plasmas. The proposal of building a storage ring with longitudinal guiding magnetic fields was made. Due to natural transversal focussing in magnetic fields it is possible to accumulate very intense charged particle beams, a subject of interest within the physics community. A simulation code (TBT) was written to describe the particle motion in curved segments. Particle in Cell techniques were utilized to simulate a multi particle dynamics. This code allows the user to generate different particle distributions as input parameter. A possibility of reading an external data file was made available so that a measured distribution can be used to compare simulation results with measured ones. A second order cloud in cell method was used to calculate charge density and in turn to solve Poisson’s equation. The circular toroidal coordinate system was used. The drift motion and gyrating motion was proved to be consistent with analytical values. Further simulations were performed to study the self field effects on beam transport. The experiments with single toroidal segments find niche in the work. The experiments were performed to compare the simulation results and gain practical experience. The toroidal segment has similar dimensions (major axis R = 1:3 m, minor axis r = 0:1 m, arc angle 30°) as for a full scale ring design. The main difference lies in the magnetic field strength. The available segments can be operated at room temperature producing 0:6T on axis maximum magnetic field, while for the storage ring design this value is in the range of 5T. The preparatory experiments consisted of building and characterization of the ion source in a first step. Along with the momentum spectrometer and emittance scanner the beam properties were studied. Low mass ion beams He+ and mixed p, H2+, H3+ beams were analyzed. The proton beam consisting of a 48% H+ fraction was extracted regularly and used for further experiments. A moderate beam energy of 10 keV was chosen as operational energy for which 3.08 mA proton beam current was measured. In the second stage, beams were transported through a solenoid and the phase space distribution was measured as a function of the magnetic field for different beam energies. The phase-space as distributions measured in a first stage were simulated backward and then again forward transported through the solenoid. The simulated results were then compared with the measured distribution. The LINTRA transport program was used. The phase-space distribution was further simulated for transport experiments in a toroidal magnetic field. The experiments with a single toroidal segment give basic results necessary to compare the results between transport code (TBT) and measurements. The optical diagnostic provides measurements which can be well compared with the simulated results. A digital camera with a magnetic shield was used to record images in jpeg file format. A subroutine was written to analyze an image file to give the intensity distribution of a given image file. The integrated profile in vertical and horizontal direction was used to calculate the vertical drift and the beam size. The simulated values were in good agreement with the measured ones. The injection system needs most care. The transport program that was used to simulate the beam in the toroid was also used to design the injection system. The injection system with its special field configurations was designed to perform experiments with room temperature segments. The main point to tackle was to smoothly bring the charged particles generated outside the trap into the acceptance of the ring. The designed system consists of two sources, one representing a ring beam and the other one the injection beam. While simulations showed a clear way, how to inject the particle beam via a well positioned solenoid and in combination with a transverse electric field element causing an ExB drift into the main ring acceptance. After construction of these injection elements it will be very important to measure the robustness of such a system with respect to the beam stability- especially of the injection channel.
The peroxisome proliferator activated receptor gamma (PPARgamma) plays an eminent role during alternative activation of macrophages and resolution of inflammation. As an antiinflammatory signaling molecule, it seems likely that it is tightly regulated dependent on the state of the immune response. There is growing evidence that PPARgamma expression is reduced during inflammation, whereas molecular mechanisms are illdefined. Even though, its role in immunosuppression is getting more definite. Apoptotic cells (AC) provoke an active repression of pro-inflammatory responses inter alia by the inhibition of pro-inflammatory cytokine expression or attenuated generation of reactive oxygen species (ROS). The reduced formation of ROS was attributed to PPARgamma activation, while mechanisms behind the reduced cytokine expression remained unclear. Therefore, my Ph.D. thesis addressed the role of PPARgamma during inhibited cytokine synthesis in response to AC and the regulation of PPARgamma expression during an inflammatory response, which was initiated by lipopolysaccharide (LPS) exposure. In the first part of the thesis, I investigated the role of PPARgamma in coordinating the attenuation of pro-inflammatory cytokine expression in response to AC. Exposing murine RAW264.7 macrophages to AC prior to LPS-stimulation, reduced NFKB transactivation and lowered target gene expression of e.g. TNFalpha and IL-6 compared to controls. In macrophages over-expressing a dominant negative (d/n) mutant of PPARgamma, NFKB transactivation in response to LPS was restored, while using macrophages from myeloid lineage-specific conditional PPARgamma knock-out mice proved that PPARgamma transmitted the anti-inflammatory response delivered by AC. Domain analysis revealed that amino acids 32-250 are essential for inhibition of NFKB. Mutation of a SUMOylation (SUMO: small-ubiquitin related modifier) site in this region (K77R) and interfering SUMOylation by silencing the SUMO E3 ligase PIAS1 (protein inhibitor of activated Stat1) eliminated AC-provoked NFKB inhibition and concomitant TNFalpha expression. Chromatin-immunoprecipitation assays demonstrated that AC prevented the LPS-induced removal of nuclear receptor co-repressor (NCoR) from the KB response element within the TNFalpha promoter. I concluded that AC induce PPARgamma SUMOylation to attenuate the removal of NCoR, thereby blocking transactivation of NFKB. This contributes to an anti-inflammatory phenotype shift in macrophages in response to AC, by lowering pro-inflammatory cytokine production. The second part addressed molecular mechanisms responsible for reduced PPARgamma expression upon LPS exposure. PPARgamma gained considerable interest as a therapeutic target during chronic inflammatory diseases. Remarkably, the pathogenesis of diseases such as multiple sclerosis or Alzheimer’s disease is associated with impaired PPARgamma expression. Initiation of an inflammatory response by exposing primary human macrophages to LPS revealed a rapid decline of PPARgamma1 expression. PPARgamma1 mRNA decrease was prevented by inhibition of NFKB and also after pre-treatment with the PPARgamma agonist rosiglitazone, suggesting a NFKB-dependent pathway, because activated PPARgamma is known to inhibit NFKB transactivation. Since promoter activities were not affected by LPS, I focused on mRNA stability and noticed a decreased PPARgamma1 mRNA half-life. RNA stability is often regulated via 3’ untranslated regions (UTRs). Therefore, I analyzed the impact of the PPARgamma-3’UTR by luciferase assays. LPS significantly reduced luciferase activity of pGL3-PPARgamma-3’UTR, suggesting that PPARgamma1 mRNA is destabilized. Deletion of a potential miR-27a/b binding site within the 3’UTR completely restored luciferase activity. Moreover, inhibition of miR-27b, which was induced upon LPS-exposure, partially reversed PPARgamma1 mRNA decay, whereas the mature miR-27 mimicked the effect of LPS. MiR-27b was at least partially induced by NFKB, thus correlating with NFKB-dependent PPARgamma1 mRNA decrease. Since deletion of the miR-27 site also containing an AU-rich element (ARE) completely abrogated LPS-induced reduction but inhibition of miR-27b only partially restored PPARgamma1 mRNA expression, I suggested an additional implication of an ARE-binding protein. I provide evidence that LPS induces miR-27b, which in turn destabilizes PPARgamma1 mRNA. Understanding the molecular mechanism of PPARgamma mRNA destabilization, might help to rationalize inflammatory diseases associated with impaired PPARgamma expression. Even though, further experiments are needed to clarify the potential involvement of ARE-binding proteins.
The documentation of life on Earth, that is, the inventorization of nature and the naming and classification of organisms found therein, is a major task for biologists today and a fundamental precondition for nature conservation efforts. This study aimed at contributing to the inventory of amphibians and reptiles in selected, previously understudied ecoregions of Bolivia. I strove to document diversity patterns and seek possible ecological and historical reasons for these patterns. Special attention was paid to the Chiquitano Region situated in the eastern lowlands of Bolivia in a climatic transition zone between the humid evergreen Amazon Forests and the deciduous thorn-scrub vegetation of the Gran Chaco. In congruence with its location in the transition zone, the Chiquitano Region displays a mosaic of habitats: The vegetation is dominated by the endemic Chiquitano Dry Forest, which is probably the largest extant patch of Seasonal Dry Tropical Forest, with enclaves of savanna, the western outliers of the Cerrado biome of central Brazil. Taxonomic revisions: The taxonomic data in this study are used as a tool to measure biodiversity, to assess biogeographic relationships, and to evaluate conservation needs. Since all is predicated on the taxonomic decisions made, an adequate taxonomy is essential, and taxonomy can be regarded as the foundation of this study. The methodology encompassed a variety of herpetological field techniques, such as different survey methods, preparation and documentation of voucher specimens, recording of frog calls, and herpetological laboratory techniques, such as morphology, molecular procedures with mtDNA, phylogenetic analyses, and bioacoustic analysis and descriptions of frog calls. A total of 1251 specimens belonging to 200 species were obtained during this study, including 87 amphibian and 123 reptile species. This constitutes about 36% of the herpetofauna currently known for Bolivia, about 34% of the amphibians currently known for Bolivia and about 40% of the reptiles, respectively. In the course of this study, a new species of frog was described from the study site Caparu in the eastern lowlands of Bolivia; this species, Hydrolaetare caparu Jansen, Gonzales & G. Köhler 2007, differs from the other two congeners in external morphology (e.g., lateral fringes and relative length of fingers, size of palmar tubercle, webbing of toes, and colouration) and advertisement call. Two new colubrid snake species were also described from the study site San Sebastián. Thus far, both are known only from the Chiquitano Region, Provincia Ñuflo de Chávez. Phalotris sansebastiani Jansen & G. Köhler 2008 differs from all the other species in the genus in having a triangular projection of the red snout colouration reaching onto the parietals. Xenopholis werdingorum Jansen, Gonzales & G. Köhler 2009 can be identified as a member of the genus Xenopholis by its vertebral morphology. It differs from the other two species of Xenopholis in having a unique uniform dorsal colour pattern, and from X. scalaris in having two prefrontals and a narrow septum within the neural spine and perpendicular to its long axis as evident in the x-ray images. A review of a small collection of pitvipers from different lowland localities and from the Inter-Andean dry valleys of the region of Pampagrande revealed one new species of Bothrops and one of Bothrocophias (both to be formally described elsewhere). The two pitviper species differ morphologically and genetically from their congeners. The results of a brief review of a small collection of frogs of the genus Scinax (Anura: Hylidae) from different localities in the lowlands, together with analyses of their bioacoustics, suggest an unknown cryptic diversity in Bolivian species of Scinax cf. fuscomarginatus and allies. However, further studies are necessary to clarify the taxonomic status of these populations. In addition, this study provides new data on the morphology (e.g., pholidosis) of snakes, many of them previously known only from few museum specimens. Keys to the Bolivian lizard species of Cercosaura and the Bolivian snake species of Chironius, Clelia, Liophis, Lystrophis, Phalotris, and Xenodon are presented here for the first time. New information on distribution includes many range extensions of amphibian and reptile species, such as five new country records (one frog species, four snake species) and six new departmental records (two frog species, four snake species). Observations on ecology and natural history: Several observations on ecology and natural history were made during field work. Visual signaling, an aspect of territorial behavior that was already known for several species of the genus Phyllomedusa, could be described for the first time for Phyllomedusa boliviana (Jansen & J. Köhler 2007). Furthermore, during audio surveys of an anuran community at the study site San Sebastián from 2005 to 2007, a decline of certain amphibian populations was observed in the rainy season 2006/2007 (Jansen et al., in press). This is possibly related to an extreme drought in the dry season of 2006 where 158 consecutive days without rainfall were recorded. In addition, a new method for measuring intensity of anuran choruses by means of a continuous sound pressure metre was developed (Jansen 2009). The method was suitable to detect calling phenology (during one night), as well as differences in calling activity (between two nights). Biodiversity and biogeographical relationships: Species lists were compiled at the six study sites Pampagrande, Los Volcanes, San Sebastián, Caparú, El Espinal und El Corbalan. The total amphibian and reptile species numbers observed ranged from 37 to 101 with the highest species numbers in San Sebastián (101) and Caparú (89) and the lowest in Los Volcanes (37) and El Espinal (41). A preliminary species list of the herpetofauna of the Chiquitano Region was presented, including 60 amphibian and 84 reptile species. The majority of the amphibians of the Chiquitano Region are classified predominantly as inhabitants of open formations (41 species, 68.3%). Interestingly, even the majority of species recorded from the Chiquitano Dry Forest (32 species) are usually associated with open formations (22 species, 66.7%), followed by the number of species associated with open and forest formations (8 species, 24.4%). Only two of the observed species (6.0%) are predominant forest dwellers. The amphibian assemblage of the Chiquitano Region is most similar in composition to that of the Cerrado biome: 46 species (76.7%) occur in the Cerrado as well, and three species are regarded as Cerrado endemics (5.0%). The Chiquitano Region shares considerably fewer amphibian species with the other biomes (Amazon: 22 species, 36.7%; Gran Chaco: 13 species, 21.7%; Caatinga: 16 species, 26.7%). The reptile assemblage also has significant affinities to the Cerrado, which can be seen in the high proportion of reptile species distributed in that biome (68 species; 81.0%). Affinities to the other biomes are as follows: Amazon (48 species, 57.1%), Chaco (37 species, 40.1%), and Caatinga (30 species, 35.7%). When arranged in mutually exclusive biome categories, reptiles and amphibians showed similar patterns so that the majority of both amphibians and reptiles of the Chiquitano Region can be regarded as widespread. The high proportion of reptile species probably endemic to this region (5 species, 6.0%) is remarkable (i.e. Tropidurus xanthochilus, Apostolepis phillipsi, Phalotris sansebastiani, Xenopholis werdingorum, and Micrurus diana). In an analysis of the biodiversity patterns and biogeographical relationships of the herpetofauna of the study sites, these sites were compared with literature data from 37 localities and included in a presence/absence matrix with a total of 657 amphibian and reptile species in the surrounding South American biomes Amazon, Cerrado and Gran Chaco. The biogeographic relationships between these sites were evaluated using the Coefficient of Biogeographic Resemblance (CBR), cluster analysis, and multidimensional scaling (MDS) of sites. The analyses were first conducted on amphibians and reptiles combined, and than group-specific each for amphibians, reptiles, lizards, and snakes, separately. A “bias-reduced analysis” was developed for a better understanding of the affinities of the amphibians. In this analysis, e.g., the distinct habitat types of the Chiquitano Region, the Chiquitano Dry Forest and the Cerrado were taken into account. Analyses of the biodiversity patterns revealed that the sites in the Amazon comprise highest species numbers, as expected, followed successively by the sites in the Cerrado biome and sites in-between the two biomes. Within the eastern lowlands of Bolivia, the Chiquitano Region is the most rich in species. Comparing it with the other South American sites, the Chiquitano Region has a surprisingly high alpha diversity, especially in amphibians. The microgeographic variation in species composition (beta diversity) in the Chiquitano Region is also remarkably high and obviously related to the mosaic character of the vegetation and habitats. However, the bias-reduced analysis revealed that the amphibian fauna of the open areas and savannas at Hacienda San Sebastián (with 36 species in the Cerrado and pastureland) was one of the most species-rich savanna sites known for amphibians in South America. Considering that the Hacienda San Sebastián site is only ca. 3300 ha (= 1.29 amphibian species per km2), this outcome is particularly suprising. The results of the analyses of the biogeographical relationships suggest that the herpetofauna of Bolivia’s lowlands, including the Beni, the Pantanal and the Chiquitano Region, is as distinct from the herpetofauna of the Gran Chaco, Amazon, and Cerrado as these biomes are from each other. The Chiquitano herpetofauna in particular represents a unique and well-defined herpetofaunal assemblage when compared to all surrounding localities and biomes. This is supported by high CBR-values, findings from the cluster analysis, as well as a clear separation of the Chiquitano sites in the MDS. Biogeographic relations exist in all the surrounding biomes, but are strongest to Cerrado, followed by the Amazon. This study strongly suggests that the Chiquitano herpetofauna is composite and has multiple affinities. This is congruent with a well-defined Chiquitano flora, avifauna and mammalian fauna, suggesting a similar history. The bias-reduced analysis revealed a more detailed picture of the biogeographic relations of the Chiquitano Region, especially the Chiquitano Dry Forest. I argue here that the Chiquitano Dry Forest herpetofauna is a “young”, and “former savanna herpetofauna”. Whereas the Chiquitano Dry Forest is rather poor in amphibian and reptile species, and endemics are lacking from this forest type, the isolated Cerrado enclaves are especially diverse in species and probably contain locally endemic species, such as Phalotris sansebastiani and Xenopholis werdingorum. The colonization of the young Chiquitano Dry Forest may have taken place from savannas by mainly open area species, and only briefly through the Amazon. The results emphasise the importance of bias-reduction in studies of biogeography, e.g., by using group-specific analyses or by taking into account criterias as area size and heterogeneity of compared sites. The different biogeographic patterns of reptiles and amphibians of the Andean valleys indicate a different history of these two groups. In regard to reptiles, dispersals and withdrawals into the valleys in warm humid and dry cool periods in the Pleistocene seem likely, supported by a relation between the valleys and the dry lowland (e.g., Chaco). However, it is more plausible that, during these climatic fluctuations, amphibians migrated to adjacent, more humid regions, such as Yungas. The study verified the known patterns of sister-species pairs in the Inter-Andean Dry Forest and the lowlands. Additionally, pairs of populations with slight differences in morphology were found in the valleys and in the lowlands (Cercosaura parkeri and Xenodon rhapdocephalus). Further studies must test the taxonomic status of these populations. The discovery of new species of Bothrops and Bothrocophias from the Andean valleys has several implications, and possible reasons for the high endemism in the dry valleys are discussed. Conservation and outlook: The high local alpha and beta diversity of the Chiquitano herpetofauna shows that this is a region of complex faunal interaction, which reflects the present heterogeneity of the region, but which is possibly also related to a complex geological and environmental history. The Chiquitano Region can be assessed as a region of distinct regional herpetofaunal diversity charaterised by small scale diversity patterns. It therefore merits recognition as a unique ecoregion, and conservation effort should be increased. Further research is necessary to solve the taxonomic problems addressed in this study. Moreover, future work should be directed towards the development and institution of longterm monitoring programs to evaluate the effects of climate change and changes in land-use on biodiversity, especially that of the Chiquitano Region.
In this study, I investigate the crustal and upper mantle velocity structure beneath the Rwenzori Mountains in western Uganda. This mountain range is situated within the western branch of the East African Rift and reaches altitudes of more than 5000 m. I use four different approaches that belong to the travel-time tomography method. The first approach is based on the isotropic tomographic inversion of local data, which contain information about 2053 earthquakes recorded by a network of up to 35 stations covering an area of 140×90 km2. The LOTOS-09 algorithm described here is used to realize this approach. The second approach is based on the anisotropic tomographic inversion of the same local dataset. This method employs the tomographic code ANITA, developed with my participation, which provides 3D anisotropic P and isotropic S velocity distributions based on P and S travel-times from local seismicity. For the P anisotropic model, four parameters for each parameterization cell are determined. This represents an orthorhombic anisotropy with one vertically-oriented predefined direction. Three of the parameters describe slowness variations along three horizontal orientations with azimuths of 0°, 60° and 120°, and one is a perturbation along the vertical axis. The third approach is based on tomographic inversion of the teleseismic data, which contain information about the traveltimes of P-waves coming from 284 teleseismic events recorded by the seismic network stations. The TELELOTOS code, which is my own modification of the LOTOS-09 algorithm, is used in this approach. The TELELOTOS code is designed to iteratively invert the local and/or teleseismic datasets. Finally, I present the results of the new tomographic approach, which is based on the simultaneous inversion of the joint local and teleseismic data. The simultaneous use of these datasets for the tomographic inversion has several advantages. In this case, the velocity structure in the study area can be resolved as deep as in the teleseismic approach. At the same time, in the upper part of the study volume, the resolution of the obtained models is as good as in the local tomography. The TELELOTOS algorithm is used to perform the joint tomographic inversion. Special attention is paid in this work to synthetic testing. A number of different synthetic and real data tests are performed to estimate the resolution ability and robustness of the obtained models. In particular, synthetic tests have shown that the results of the anisotropic tomographic inversion of the local data have to be considered as unsatisfactory. For all approaches used in this study, I present synthetic models that reproduce the same pattern of anomalies as that obtained by inverting the real data. These models are used to interpret the results and estimate the real amplitudes of the obtained anomalies. The obtained models exhibit a relatively strong negative P anomaly (up to -10%) beneath the Rwenzori Mountains. Low velocities are found in the northeastern part of the array at shallower depths and are most likely related to sedimentary deposits, while higher velocities are found beneath the eastern rift shoulder and are thought to be related to old cratonic crust. The presence of low velocities in the northwestern part of the array may be caused by a magmatic intrusion beneath the Buranga hot springs. Relatively low velocities were observed within the lower crust and upper mantle in the western and southern parts of the study area (beneath the rift valley and the entire length of the Rwenzori range). The higher amplitude of the low-velocity anomaly in the south can be related to the thinner lithosphere in the southern part of the Albertine rift. In the center of the study area, a small negative anomaly is observed, with the intensity increasing with depth. This anomaly is presumably related to a fluids rising up from a plume branch in the deeper part of the mantle. According to the interpretation of the local earthquake distribution, the Rwenzori Mountains are located between two rift valleys with flanks marked by normal faults. The Rwenzori block is bounded by thrust faults that are probably due to compression.
Enantioselective carbon-carbon bond-forming reactions, particularly, using organocatalysts represent one of the most important areas in modern synthetic chemistry. New concepts and methods in organocatalysis are emerging continuously, allowing more selective, economically more appealing and environmentally friendlier transformations. Chiral Brønsted-acid catalysts have recently emerged as a new class of organocatalysts for a number of enantioselective carbon-carbon bond-forming reactions. The first part of this thesis focused on the new development of new Brønsted acid-catalyzed enantioselective Nazarov cyclizations. The Nazarov reaction belongs to the group of electrocyclic reactions and is one of the most versatile methods for the synthesis of five-membered rings, which are the key structural elements of numerous natural products. In general, the Nazarov cyclization can be catalyzed by Brønsted or Lewis acids. However, only a few asymmetric variations have been described, of which most require the use of large amounts of chiral metal complexes. The reactivities of Nazarov cyclizations are also depending on the substituents of the divinyl ketone substrates as described in the first chapter. The substrates to study Brønsted acid-catalyzed enantioselective Nazarov cyclization were prepared following the known procedures. The dihydropyran was treated with tBuLi in THF at –78 oC and then the α,β-unsaturated aldehydes 1 were added to the reaction mixture to afford the corresponding alcohols 2 in moderate to good yields. The alcohols 2 were oxidized to divinyl ketones 3 employing Dess-Martin periodinane/pyridine (DMP/py) in CH2Cl2 at room temperature to obtain the divinyl ketones 3 in moderate to good yields (Scheme 1). Scheme 1. Preparation of substrates in order to study Brønsted acid-catalyzed enantioselective Nazarov cyclization and subsequent transformations. At the starting point, an evaluation of suitable Brønsted acid catalysts for the enantioselective Nazarov cyclization of divinyl ketone 3a was performed. The initial reactions conducted with various BINOL-phosphoric acids 4a-4e in toluene at 60 oC provided the mixture of cis and trans cyclopentenones 5a with enantioselectivities of up to 82% ee (Table 1, entries 1-5). Eventually, improved reactivity could be achieved by using the corresponding N-triflylphosphoramides 4f and 4g, which even at 0 oC gave complete conversion after ten minutes. Additionally, it was shown that the use of these catalysts significantly enhanced both the diastereoselectivity (cis/trans ratio up to 7:1) and the enantioselectivity (up to 96% ee; Table 1, entries 6 and 7). Table 1. Evaluation of Brønsted acids 4a-4g in the enantioselective Nazarov cyclization. The scope of the Brønsted acid-catalyzed enantioselective Nazarov cyclization of various divinyl ketones 3 was explored under an optimized reaction condition (Scheme 2). Treatment of divinyl ketones 3 in CHCl3 in the presence of 2 mol% chiral BINOL-Ntriflylphosphoramide 4g at 0 oC for 1-6 h provided the corresponding cyclopentenone 5 in good yields (45-92%) with excellent enantioselectivities (up to 93% ee) (Scheme 2). Furthermore, the isomerization of cis-cyclopentenone under basic condition led to the corresponding trans-cyclopentenone without loss of enantiomeric purity. This efficient method introduced here was not only the first example of an organocatalytic electrocyclic reaction but also represented the first enantioselective activation of a carbonyl group catalyzed by a chiral BINOL phosphoric acid. Compared to the metal-catalyzed reaction, special features of this new Brønsted acid-catalyzed electrocyclization are the lower catalyst loadings (2 mol%), higher enantioselectivities, accessibility to all possible stereoisomers, as well as the mild conditions. ....
Der zentrale Aspekt der vorliegenden Arbeit ist die Untersuchung psychophysiologischer Konsequenzen von Emotionsregulationsanforderungen und deren Beeinflussung durch individuelle Differenzen. Hierbei wurden in Studie 1 subjektive, verhaltensbezogene und physiologische Konsequenzen von Emotionsregulation und deren Beeinflussung durch individuelle Differenzen untersucht. Die Studien 2, 3 und 4 fokussieren auf Emotionsregulation in einem Service-Kontext (Emotionsarbeit). Während in der Emotionsregulationsforschung der Einfluss individueller Differenzen bisher wenig untersucht wurde, existieren insbesondere in der Emotionsarbeitsforschung kaum experimentelle Studien, die kausale Rückschlüsse auf den Zusammenhang von emotionalen Regulationsanforderungen mit subjektiven, verhaltensbezogenen und physiologischen Reaktionen erlauben. Hierbei fanden insbesondere physiologische Parameter und individuelle Differenzen keine bzw. wenig Berücksichtigung. Studie 1 zeigte, dass individuelle Differenzen eine moderierende Wirkung auf den Zusammenhang von Emotionsregulationsinstruktionen und verhaltensbezogenen sowie physiologischen Reaktionen aufweisen. In den Studien 2 und 3 konnte gezeigt werden, dass die Vorgabe, emotionale Zustände darzustellen, die nicht in der Arbeitssituation empfunden werden (emotionale Dissonanz), in einer simulierten Interaktion mit einem unzufriedenen Kunden mit mehr Emotionsregulation und mit einer verstärkten physiologischen Belastung des Service-Angestellten einherging. Ebenso waren in den Studien 2, 3 und 4 Versuchsteilnehmer mit einer geringen negativen Affektivität (hier: Trait-Ärger bzw. Neurotizismus) durch geringere psychophysiologische Belastungsreaktionen gekennzeichnet, sofern starke Regulationsanforderungen an sie gestellt wurden. Zudem zeigte sich in Studie 4, dass die Vorgabe, positive emotionale Zustände 40 darzustellen, zu einer organisational vorteilhafteren Expressionsleistung gegenüber der Vorgabe negative emotionale Zustände nicht zu zeigen, führte. Zusammenfassend sprechen diese Ergebnisse dafür, dass häufige Konfrontationen mit starken Regulationsanforderungen die Belastung von Service-Angestellten erhöhen und die Entwicklung von kardiovaskulären Erkrankungen begünstigen können. Die vorliegenden Moderatoreffekte implizieren, dass Personen mit geringer negativer Affektivität weniger vulnerabel gegenüber den negativen Konsequenzen starker emotionaler Regulationsanforderungen in unangenehmen Kundeninteraktionen sind.
Breaking tolerance to the natural human liver autoantigen cytochrome P450 2D6 by virus infection
(2009)
Autoimmune hepatitis (AIH) is a chronic liver disease of unknown etiology, characterized by a loss of tolerance against hepatocytes leading to the progressive destruction of hepatic parenchyma and cirrhosis. Clinical signs for AIH are interface hepatitis and portal plasma cell infiltration, hypergammaglobulinemia, and autoantibodies. Based on serological markers AIH is defined in subtypes. The hallmark of AIH type 2 are type 1 liver/kidney microsomal autoantibodies (LKM-1), whereas AIH type 1 is characterized by the presence of anti-nuclear (ANA) and/or anti-smooth muscular (SMA) autoantibodies. The major autoantigen recognized specifically by LKM-1 autoantibodies was identified as the 2D6 isoform of the cytochrome P450 enzyme family (CYP2D6). Not much is known about the etiology and pathogenic mechanisms of AIH so far and most animal models available result in only transient hepatic liver damage after a rather complex initiation method. It was the aim of my project to generate a novel animal model for AIH that reflects the chronic and progressive destruction of the liver characteristic for the human disease while using a defined and feasible initiating event to further analyze the pathogenic mechanisms leading to the autoimmune-mediated destruction of the liver. Therefore, mice transgenically expressing the human CYP2D6 in the liver and wild-type mice were infected with a liver-tropic adenovirus expressing the human CYP2D6 (Ad-2D6). Selftolerance to CYP2D6 was broken in Ad-2D6-infected mice, resulting in persistent autoimmune liver damage, apparent by cellular infiltration, hepatic fibrosis and necrosis. Similar to type 2 AIH patients, Ad-2D6-infected mice generated LKM-1-like antibodies recognizing the same immunodominant epitope of CYP2D6. Taken together, we could introduce a new animal model that reflects the persistent autoimmune-mediated liver damage as well as the serological marker characteristic for AIH type 2 and we could demonstrate that chronic autoimmune diseases targeting the liver can be triggered by molecular mimicry occurring in the context of a hepatotropic viral infection.
Plant parasitic species of Asterinaceae and Microthyriaceae (Dothideomycetes, Ascomycota, Fungi) are inconspicuous foliicolous fungi with a mainly tropical distribution. They form black colonies on the surface of living leaves. Members of Asterinaceae and Microthyriaceae are characterized by shield-shaped, flat ascomata (thyriothecia) which grow completely superficially on the leaf cuticle. Microthyriaceae, Asterinaceae and other families of thyriothecia-forming ascomycetes belong to the class Dothideomycetes due to the presence of bitunicate asci. However, until today no consistent taxonomic concept nor molecular phylogenetic studies exist for the families of thyriothecioid ascomycetes. In the present thesis, 42 species belonging to 13 different anamorphic and teleomorphic genera of Asterinaceae, Microthyriaceae and ‘Pycnothyriales’ recently collected in Western Panama, are identified, described in detail and illustrated with drawings, transmission and scanning electron microscopical photographs. Among the 42 species, 37 species belong to the Asterinaceae, four species to the Microthyriaceae and one species to the from group ‘Pycnothyriales’. Two species of Asterinaceae are new to sience: Asterina gaiadendricola with an Asterostomella anamorph and Asterina schlegeliae with a Mahanteshamyces anamorph. Among the remaining species of Asterinaceae, 28 species represent new records for Panama: Asterina cestricola, A. ciferriana, A. consobrina, A. corallopoda, A. davillae with anamorph, A. diplocarpa, A. diplopoda, A. ekmanii, A. fuchsiae, A. manihotis, A. phenacis, A. radiofissilis with anamorph, A. siphocampyli, A. sponiae, A. stipitipodia with anamorph, A. styracina, A. tonduzii with anamorph, A. weinmanniae, A. zanthoxyli, Asterostomella dilleniicola, Asterolibertia licaniicola, Asterolibertia nodulosa, Cirsosia splendida with its Homalopeltis chrysobalani anamorph and Prillieuxina winteriana with its Leprieurina winteriana anamorph. The remaining 11 species of Asterinaceae probably respresent new species: Asterina spp. 1-8, Asterolibertia sp., Halbanina sp. and Mahanteshamyces sp. The four species of Microthyriaceae are new records for Panama: Maublanica uleana, Platypeltella irregularis, Platypeltella smilacis and Xenostomella tovarensis. The species Hemisphaeropsis magnoliae in the form group ‘Pycnothyriales’ is a new record for Panama. During this study, voucher material of 44 additional species of plant parasitic thyriothecioid ascomycetes was examined. Thereby, the number of species of Asterinaceae known for Panama since 2006 raises from four to 30, for Microthyriaceae respectively from zero to four and for ‘Pycnothyriales’ from zero to one. 21 of the presented species are new records for Central America and two species are new records for the American Continent. The presented 42 species parasitize 47 host plant species in 39 genera belonging to 28 plant families. For 23 fungal species, new host plant species are discovered. From those, seven belong to host plant genera not reported before to be parasitized by a member of Asterinaceae and Microthyriaceae: Burmeistera (Campanulaceae), Curatella and Davilla (Dilleniaceae), Greigia (Bromeliaceae), Hirtella (Chrysobalanaceae), Oxandra and Xylopia (Annonaceae). In this study, the first molecular phylogenetic approach in Asterinaceae is provided. For the first time, DNA was isolated from fresh material of Asterina spp. and their respective anamorphic stages on leaves in Panama. The hypothesis derived from SSU and LSU rDNA neighbour-joining analysis supports the monophyly of the Asterinaceae and suggests a close relationship to Venturiaceae within the class Dothideomycetes. The data obtained from the ppMP project (plant parasitic microfungi of Panama) indicate a constant but low abundance of plant parasitic thyriothecioid ascomycetes in natural plant communities in Panama, with Asterinaceae as the most species-rich and diverse family. Further collection activities in tropical regions worldwide will certainly increase our knowledge about species diversity and ecology of tropical plant parasitic thyriothecioid ascomycetes.
Tropical geometry is the geometry of the tropical semiring \[\mathbb{T}:=(\mathbb{R}\cup\{\infty\},\min,+).\] Classical algebraic structures correspond to tropical structures. If $I\lhd K[x_1,\ldots,x_n]$ is an ideal in a polynomial ring over a field $K$ with valuation $v$, then the classical algebraic variety correspond to the tropical variety $T(I)$. It is the set of all points $w$, such that the minimum $\min\{v(c_\alpha)+w\cdot\alpha\}$ is achieved twice for all $f=\sum_\alpha c_\alpha x^\alpha\in I$. So tropical geometry relates algebraic geometric problems with discrete geometric problems. In this thesis we obtain a tropical version of the Eisenbud-Evans Theorem which states that every algebraic variety in $\mathbb{R}^n$ is the intersection of $n$ hypersurfaces. We find out that in the tropical setting every tropical variety $T(I)$ can be written as an intersection of only $(n+1)$ tropical hypersurfaces. So we get a finite generating system of $I$ such that the corresponding tropical hypersurfaces intersect to the tropical variety, a so-called tropical basis. Let $I \lhd K[x_1,\ldots,x_n]$ be a prime ideal generated by the polynomials $f_1, \ldots, f_r$. Then there exist $g_0,\ldots,g_{n} \in I$ such that \[ T(I) \ = \ \bigcap_{i=0}^{n}T(g_i)\] and thus $\mathcal{G} := \{f_1, \ldots, f_r, g_0, \ldots, g_{n}\}$ is a tropical basis for $I$ of cardinality $r+n+1$. Tropical bases are discussed by Bogart, Jensen, Speyer, Sturmfels and Thomas where it is shown that tropical bases of linear polynomials of a linear ideal have to be very large. We do not restrict the tropical basis to consist of linear polynomials and therefore we get a shorter tropical basis. But the degrees of our polynomials can be very large. The main ingredient to get a short tropical basis is the use of projections, in particular geometrically regular projections. Together with the fact that preimages of projections of tropical varieties are themselves tropical varieties of a certain elimination ideal we get the desired result. Let $I \lhd K[x_1, \ldots, x_n]$ be an $m$-dimensional prime ideal and $\pi : \mathbb{R}^n \to \mathbb{R}^{m+1}$ be a rational projection. Then $\pi^{-1}(\pi(T(I)))$ is a tropical variety, namely \[ \pi^{-1}(\pi(T(I))) \ = \ T(J \cap K[x_1, \ldots, x_n]) \,\] Here $J$ is an ideal in $K[x_1,\ldots,x_n,\lambda_1,\ldots,\lambda_{n-m-1}]$ derived from the ideal $I$. We show that this elimination ideal is a principal ideal which yields a polynomial in our tropical basis. The advantage of our method is that we find our polynomials by projections and therefore we can use the results of Gelfand, Kapranov and Zelevinsky , of Esterov and Khovanskii , and of Sturmfels, Tevelev and Yu. With mixed fiber polytopes we get the structure and combinatorics of the image of a tropical variety and therefore the structure of the polynomials in our tropical basis. Let $I=\lhd K[x_1,\ldots,x_n]$ an $m$-dimensional ideal, generated by generic polynomials $f_1,\ldots, f_{n-m}$, $\pi:\mathbb{R}^n\to\mathbb{R}^{m+1}$ a projection and $\psi$ a projection presented by a matrix with a rowspace equal to the kernel of $\pi$. Then up to affine isomorphisms, the cells of the dual subdivision of $\pi^{-1} \pi T(I)$ are of the form \[ \sum_{i=1}^p \Sigma_{\psi} (C_{i1}^{\vee}, \ldots, C_{i{k}}^{\vee}) \] for some $p\in\mathbb{N}$ and faces $F_1, \ldots, F_p$ of $T(f_1)\cap\ldots\cap T(f_k)$ and the dual cell of $F_i\subseteq U = T(f_1)\cup\ldots\cup T(f_k)$ is given by $F_i^\vee=C_{i1}^{\vee}+ \ldots+ C_{ik}^{\vee}$ with faces $C_{i1}, \ldots, C_{i k}$ of $T(f_1), \ldots, T(f_{k})$. In case that we project a tropical curve we want to find the number of $(n-1)$-cells of the above form with $p>1$, i.e. the cells which are dual to vertices of $\pi(T(I))$ which are the intersection of the images of two non-adjacent $1$-cells of $T(I)$. Vertices of this type are called selfintersection points. We show that there exist a tropcal line $L_n\subset\mathbb{R}^n$ and a projection $\pi:\mathbb{R}^n\to\mathbb{R}^2$, such that $L_n$ has $\sum_{i=1}^{n-2}i$ selfintersection points. Furthermore we find tropical curves $\mathcal{C}\subset\mathbb{R}^n$, which are transversal intersections of $n-1$ tropical hypersurfaces of degrees $d_1,\ldots,d_{n-1}$ and a projection $\pi:\mathbb{R}^n\to\mathbb{R}^2$, such that $\mathcal{C}$ has at least $(d_1\cdot\ldots\cdot d_{n-1})^2\cdot \sum_{i=1}^{n-2}i) $ selfintersection points. A caterpillar is a certain simple type of a tropical line and for this type we show that it can have at most $\sum_{i=1}^{n-2}i$ selfintersection points.
An eclogite barometer has profound importance in the study of upper mantle processes and potential application to diamond prospecting. Studies on the partitioning of Li between clinopyroxene (cpx) and garnet (grt) in natural samples have shown that this particular element is very sensitive to changes in pressure and could be calibrated as the barometer demanded for bimineralic eclogites. Experiments were performed from 4 to 13 GPa and 1100 to 1400°C in the CMAS (CaO, MgO, Al2O3, SiO2) system with Li added as Li3PO4 to quantify this pressure dependence into a barometer expressed in the following equation: P= (0.00255*T-lnKd)/0.2351 where P is in GPa, T is in °C and Kd is defined as the partition coefficient of Li (in ppm) between clinopyroxene and garnet. The experimental pressures are reproduced to ± 0.38 GPa (1σ) by this equation. This barometer is strictly applicable only to CMAS. Experiments at 1300°C, 8-12 GPa showed that Henry’s Law is fulfilled for Li partitioning between cpx and grt in the concentration range of approximately 0.01 – 1 wt% Li. Direct application of the equation to experiments in natural systems performed at 1300°C from 4 GPa to 13 GPa consistently overestimates pressures by approximately 2 GPa. Our previous experiments in the system CaO-MgO-Al2O3-SiO2 + Li3PO4 showed that the partitioning of Li between garnet and clinopyroxene is pressure dependent in eclogitic bulk compositions. This supports experimentally the hypothesis of Seitz et al. (2003), based on the analysis of Li in eclogitic xenoliths and inclusions in diamond, that the partitioning of this particular element between clinopyroxene and garnet is very sensitive to changes in pressure and could be calibrated as a barometer for bimineralic eclogites. In order to calibrate this pressure dependence into a barometer, experiments were performed in natural systems using starting materials sourced from a well preserved eclogitic xenolith from the Roberts Victor kimberlite pipe (South Africa) to extrapolate our findings in CMAS to natural systems. Sixteen multianvil experiments were performed from 4-13 GPa and 1100-1500°C. Our findings reinforced the general trend we observed in the CMAS system, that KdLi cpx-grt for Li decreases with increasing P, and that at P ≥ 12 GPa, garnet is able to incorporate more Li than clinopyroxene. Multiple linear regression was applied to our experimental results to create the barometer: P = (0.000963*T – ln KdLi cpx-grt + 1.581) / 0.252 Where P is pressure in GPa, T is temperature in °C and KdLi cpx-grt is defined as the partitioning coefficient of Li obtained by dividing the concentration of Li in cpx by the concentration of Li in garnet. This barometer reproduces the experimental conditions to ± 0.2 GPa. It is applicable to eclogitic xenoliths, to garnet pyroxenites and to peridotitic and eclogitic inclusions in diamond. Application of the barometer to diamond bearing xenoliths results in pressures in the diamond stability field. Clinopyroxene is easily corrupted in xenoliths and also preferentially takes in Li during short lived metasomatic processes. Care must be taken therefore to analyse primary, unaltered clinopyroxene. Our preliminary application to natural samples shows that the barometer can be applied beyond the experimental range to pressures down to 3 GPa. Seventeen eclogitic xenoliths were chosen from a sample set of greater than 200 for their fresh microscopic and macroscopic appearance and were analyzed for Li content in coexisting garnet (grt) and clinopyroxene (cpx). These samples can be subdivided into two groups on the basis of Mg in cpx (cpfu: cations per formula unit, based on 6 oxygens): Group 1 with Mg > 0.75, and Group 2 with Mg < 0.75. Group 1 xenoliths show lower Li contents in both grt and cpx compared to Group 2. The Li barom ter calibrated in Hanrahan et al. (2009b)/Chapter 3 was applied to these samples as well as available literature data to obtain pressures of provenance - Group 2 xenoliths often provide pressures that appear unrealistic for eclogitic xenoliths. In light of observed crystal chemical relations in the natural samples, a new fitting procedure was applied to the experimental data presented in Chapter 3. This new fit appears to be more realistic than the previous fit, although a strong relationship with Mg# remains present, suggesting that Li-barometry is, at present, only applicable to Mg-rich eclogites. Inclusions in diamond, with the exception of eclogitic inclusions of coexisting majorite and cpx, often yield pressures that are inconsistent with the pressures required for diamond formation. Although an interesting observation when comparing all of the data is that inclusions in diamond have significantly higher average Li concentrations compared to xenoliths, which suggests that Li is highly present in the fluids from which diamonds form in the mantle, an observation which was previously made for the deep mantle as a result of high Li in ferropericlase inclusions in diamond (Seitz et al. 2003).
In this thesis we report on the high pressure synthesis, crystal growth, structural characterisation and magnetic properties of the cubic vanadate pyrochlores A2V2O7 (with A = Y, Er and Dy). We have found that high pressure is requisite for the stabilization of the selected compounds. For this purpose, a multianvil high pressure apparatus was built in our laboratory and a new multianvil inset (i.e., a ceramic pressure medium and the interior parts) was developed. The multianvil press is based on a hydraulic press with a maximum force of 7.73 MN (corresponds to 788 tons), a Walker type module and a specially designed hydraulic and electric control. Pressure calibration of the multianvil setup was performed by high pressure fixed points (i.e. solid-solid transformation of Bi I-II (2.55 GPa) and Bi II-III (3.15 GPa)). A maximum pressure of 6 GPa was attained using hardened metal anvils (tungsten carbide) with truncation edge length (TEL) of 14 mm and a sample volume of ~ 70 mm3. Heating of the sample in our current multianvil setup (TEL = 14 mm) was achieved by resistive heating of a graphite furnace. Temperatures up to 1500 °C could be obtained at pressures up to 6 GPa. By systematic variation of the synthesis conditions (for instance the operation temperature or the choice of the crucible material) under high pressure and taking into account the well known ternary compounds, when accessing the phase diagram, the cubic vanadate pyrochlores A2V2O7 (with A = Y, Er and Dy) were synthesized successfully. It was found that the oxygen partial pressure is crucial for the formation of the desired pyrochlore phase. Gas-tight platinum crucibles were used as container material for the synthesis of the vanadate pyrochlores. We have investigated, that pressures of the order of 5.0 GPa and temperatures of approximately 1200 °C are necessary for the stabilization of the monophasic samples of the vanadate pyrochlores. Lu2V2O7 could be synthesized under ambient pressure conditions and is used in our studies for comparison purposes. A special graphite furnace was developed for the high pressure crystal growth of the vanadate pyrochlores. For the first time, A2V2O7 (with A = Y, Er and Dy) single crystals with a maximum size of 0.4 mm were grown by using the grain growth method at high pressure and high temperature conditions. The samples (i.e., powders and single crystals) were characterised by single crystal Xray diffraction, X-ray powder diffraction method, Laue method and scanning electron microscopy (SEM). Complementary to the X-ray diffraction methods, infrared absorsoption spectroscopy was used to distinguish between the fluorite and pyrochlore structure. It has been shown that all samples crystallize in a well-ordered cubic structure with the space group F d 3m. The vanadium (+4) content in the samples was determined by oxidative weight gain in air using a thermogravimetric (TG) balance. A structural phase transformation of cubic to tetragonal was observed by differential thermal analysis (DTA) in conjunction with high temperature diffractometry. The magnetic characterisation of the vanadate pyrochlores A2V2O7 (Y, Lu, Er and Dy) was performed by Katarina Removic-Langer in the laboratory of Prof. Dr. M. Lang. All materials studied are ferromagnetic. The ferromagnetic critical temperatures are between 70 and 73 K. In case of Er2V2O7 and Dy2V2O7 an additional increase in the magnetization was observed below 20 K. The increase in the magnetization below 20 K exhibited by Er2V2O7 and Dy2V2O7 originates from the interactions between the two magnetic sublattices (i.e., the rare earth- and the vanadium sublattice).
In this work we study the properties of quarkonium states in a quark-gluon plasma which, due to expansion and non-zero viscosity, exhibits a local anisotropy in momentum space. We determine the hard-loop resummed gluon propagator in an anisotropic QCD plasma in general linear gauges and define a potential between heavy quarks from the Fourier transform of its static limit. This potential which arises due to one-gluon exchange describes the force between a quark and anti-quark at short distances. It is closer to the vacuum potential as compared to the isotropic Debye screened potential which indicates the reduced screening in an anisotropic QCD plasma. In addition, angular dependence appears in the potential; we find that there is stronger attraction on distance scales on the order of the inverse Debye mass for quark pairs aligned along the direction of anisotropy than for transverse alignment. The potential at long distances, however, is non-perturbative and modeled as a QCD string which is screened at the same scale as the Coulomb field. At asymptotic separation the potential energy is non-zero and inversely proportional to the temperature. With a phenomenological potential model which incorporates the different behaviors at short and long distances, we solve the three-dimensional Schrödinger equation. Our numerical results show that quarkonium binding is stronger at non-vanishing viscosity and expansion rate, and that the anisotropy leads to polarization of the P-wave states. Furthermore, we determine viscosity corrections to the imaginary part of the heavyquark potential in the weak-coupling hard-loop approximation. The imaginary part is found to be smaller (in magnitude) than at vanishing viscosity. This implies a smaller decay width of quarkonium bound states in an anisotropic plasma.
In the production of integrated circuits (ICs), photolithography plays a key role in wafer structuring. The basic principle of photolithography is the selective processing of areas (etching, implantation, metallisation etc.) while the others are covered and therefore protected by the resist. After each process step the resist, now modified, has to be removed. In the history of semiconductor manufacturing this has been accomplished with a mixture of H2SO4 and H2O2, H2SO4 and O3 or a plasma etch. As the structure sizes decreased they reached a stage where they had to be exposed to light of shorter wavelengths for the photolithography, going from i-line (365 nm) to DUV (248 nm and 193 nm). This change in wavelength now requires new resists and therewith new stripping methods. Beside the changes in the resist the finer structures are also more sensitive to damages caused by the resist strip. Along with this the demand for cost reduction and environment-friendliness poses a big challenge for modern resist stripping. In this study ozone in deionised water (DI/O3) was the basic chemistry investigated as it is cost efficient in production and disposal as well as environment friendly. Furthermore it is a chemistry known to cause no damage to the wafers. DI/O3 has been successfully applied to strip i-line resists. The challenge now is to find ways and means to make DI/O3 strip even highly implanted DUV resists which currently can only be removed by a plasma etch. To achieve this a detailed understanding of the behaviour of ozone in DI water and the influence of factors both chemical and physical on the stripping efficiency at the different stages in the process is necessary. Along with this, methods which enable the elucidation of resist structures and the changes they undergo during the process of photolithography as well as during the ozone strip have to be developed. This will enable us to understand the mechanisms involved and hence, ideally, develop ozone-based stripping solutions customized for each resist and process step. For this purpose the ozone decomposition in DI water with and without additives was studied via UV-Vis spectroscopy. Radicals generated within the ozone decomposition were trapped and quantified, the resists were studied directly on the wafer with IR and Raman spectroscopy and stripped with DI/O3-mixtures and different setups to find optimum conditions for a complete and damage free resist strip. UV-Vis spectroscopy at 260 nm was used to study ozone decomposition and the factors, both chemical and physical, which influence it. These factors are pH, different additives at the same pH, temperature and mixing of the solution. For the radical determination trapping reactions with MeOH and DMSO both forming CH2O which is further converted to DDL as the detectable species were compared with a variation of the classical iodometric titration acting as an absolute method without the need of calibration. IR spectroscopy proved to be a suitable method for the structural characterisation of the resists and the tracking of the changes undergone during the various processing steps as well as the ozone based stripping. For the stripping with DI/O3 IR spectroscopy delivered well-defined spectra. These displayed significant peak changes which support the assumption of classical ozonolysis as the decomposition mechanism for the unimplanted resist. For the study of the resist crust originating from ion implantation IR was fundamentally unsuitable and was replaced by Raman spectroscopy and microscopy. Raman spectra showed the crust to be of a highly carbon containing structure. Regrettably, the peak assignable to the crust was too broad for the exact composition of the crust to be determined. The wavelength region of the peak corresponds to that of peaks of glassy carbon and highly ordered and conventional graphite. Such a broad peak suggests that the structure of the crust is not uniform but contains more than one carbon modification. As the purpose of all these studies is to enable or improve DI/O3 based resist stripping on unimplanted as well as high-dose implanted resists the removal efficiency of DI/O3 spiked with different additives that alter the pH was studied. For these unimplanted resists the maximum efficiency could be achieved at pH = 5 – 7. Lowering or increasing the pH beyond this range gave poor results. The stripping of highly implanted resists could be achieved only at harsh conditions with a high pH-level of 12 - 13 with a narrow process window showing no stripping at lower pHs and severe damages at higher levels. The principle application of DI/O3 stripping chemistry could be proved but the currently required process time unfortunatelly is too long for commercial application and needs further optimisation.
This thesis contributes to the field of soft matter research and studies the importance of hydrodynamic interactions during free-solution electrophoresis of linear polyelectrolytes by means of coarse-grained molecular dynamics simulations including full electro-hydrodynamic interactions. The center of attention is the specific role of hydrodynamic interactions on the electrophoretic behaviour of charged macromolecules. Points of interest are the dependence of hydrodynamic interactions on the chain length, the chain flexibility and the surrounding counterions, and their combined influence on important observables such as the static chain conformations and the dynamic transport coefficients, i.e., the diffusion and the electrophoretic mobility. These problems are addressed by extensive computer simulations that are quantitatively matched with experimental results. Existing theoretical predictions are carefully examined and are augmented by the observations in this thesis.
Na+/H+ antiporters are ubiquitous membrane proteins involved in ion homeostasis and pH sensing. The amino acid sequence of one such antiporter, MjNhaP1, from Methanococcus jannaschii, shows a significant homology to eukaryotic sodium proton exchangers like NHE1 from Homo sapiens and SOS1 of Arabidopsis thaliana than to the well-characterized Escherichia coli NhaA or NhaB. MjNhaP1 shows activity at acidic pH unlike NhaA, which is active at basic pH. 13 transmembrane helices have been predicted to be present in NhaP1. A projection map, calculated by Cryo-EM of 2D crystals of MjNhaP1 grown at pH 4, showed it to be a dimer containing elongated densities in the centre of the dimer and a cluster of density peaks on either side of the dimer core (Vinothkumar et al., 2005). Incubation of 2D crystals at pH 8 on the EM grid resulted in well-defined conformational changes, clearly evident in a difference map as a major change in density distribution within the helix bundle (Vinothkumar et al., 2005). The aim of this dissertation is to understand the working mechanism of MjNhaP1 by determining its three-dimensional structure. The aim was initially approached by structure determination by X-ray crystallography. The limitation for this method was the low expression yield, which was 0.5–0.7mg/ml (Vinothkumar et al., 2005). After various optimization trials, the expression yield of the recombinant protein could be elevated to 2-2.5mg of pure protein per litre of culture by the method of autoinduction (Studier et al., 2005). To obtain well diffracting 3D crystals, purification conditions (Vinothkumar et al., 2005) were modified. 3D crystals were obtained under various conditions, which has so far not diffracted X-Ray beyond 8Å. Parallely, optimization of parameters (Vinothkumar et al., 2005) for 2D crystals formation was carried out. A combination of 1% DDM used for lipid solubilization, and 1% OG in the buffer of the purified protein produced 1-2 μm wide tubular 2D crystals of NhaP1. This batch of crystal proved to be the optimal for data collection at higher tilt angle with the electron microscope. A 3D map showed p22121 symmetry and revealed a tight dimer with an oval shape. The region in the central part of the dimer is composed of several tilted helices forming an interface between both monomers. On either side of the dimer interface, a group of six tightly packed helices form a bundle. This bundle contains three straight helices in the centre of the monomer and three helices in the periphery. Comparison of the structures of E.coli NhaA and M. jannaschii NhaP1 show substantial differences in length and slope of corresponding helices between both antiporters. A 3D model of NhaP1 based on the 3D map revealed 13 helices, which has been named as A-M to distinguish it from the NhaA helices. Overlaying the X-ray structure onto the 3D map revealed that the disrupted helices IV and XI of NhaA superimpose two central helices at similar position in the 3D map of NhaP1. The disrupted helices IV and XI in the X-ray structure of NhaA have been proposed as the putative ion-binding and translocation site (Hunte C et al, 2005; Arkin IT et al, 2007; Screpanti & Hunte (2007). This motif appears to be present also in NhaP1, as suggested by the close fit of NhaA helices IV and XI on the putative helices E and L of the NhaP1 model. These two putative helices E and L in NhaP1 contain the highly conserved TDP and GPRVVP motif, which are crucial for antiporter activity (Hellmer et al., 2002, Hellmer et al., 2003). In the overlay, helix V of NhaA containing the two essential, conserved aspartates D163 and D164 fits the density of the putative helix F of NhaP1, which contains the conserved motif FNDP. The homologous D161 in the FNDP motif of NhaP1 is essential for transport activity as show by mutagenesis (Hellmer at al., 2003). Significant differences are visible in the region of the dimer interface of the 3D map of NhaP1 occupied by helices VI, VII, and VIII in NhaA. This region shows an extra helical density (A) in the 3D map of NhaP1. By alignment of MjNhaP1 sequence with the amino acid sequences of several Na+/H+ exchangers, it was evident that the additional helix (A) is located in the N terminus of NhaP1. In our sequence alignment, a putative hydrophobic segment corresponding to this additional helix A is present in other archaeal and eukaryotic antiporters but not in any of the bacterial ones. The N-terminus of the human Na+/H+ exchanger NHE1 has been predicted to contain a highly hydrophobic signal peptide. This indicates the probability of the N-terminal helix A of NhaP1 to be an uncleaved signal peptide. Besides being a signal sequence targeting NhaP1 to the membrane, the map suggests that this helix might be involved in the formation of dimer contacts between both monomers. A gene duplication event is evident in the 3D map of NhaP1, as not only the helices D, E, F and K, L, M are related by an inverted repeat but also the helices B, C and I, J are related. We present here the three-dimensional architecture of a Na+/H+ antiporter from archaea. The presence of the 13th helix suggests the location of the N-terminus to be located in the cytosol and the C-terminus in the periplasm. This would orient NhaP1 in an inverted manner in the membrane in comparison to NhaA. Further structural information at higher resolution and biochemical and biophysical investigations are required to confirm the topology.
Through the use of information about the biological target structure, the optimization of potential drugs can be improved. In this work I have developed a procedure that uses the quantitative change in the chemical perturbations (CSP) in the protein from NMR experiments for driving protein-ligand docking. The approach is based on a hybrid scoring function (QCSPScore) which combines traditional DrugScore potentials, which describe the interaction between protein and ligand, with Kendall’s rank correlation coefficient, which evaluates docking poses in terms of their agreement with experimental CSP. Prediction of the CSP for a specific ligand pose is done efficiently with an empirical model, taking into account only ring current effects. QCSPScore has been implemented in the AutoDock software package. Compared to previous methods, this approach shows that the use of rank correlation coefficient is robust to outliers. In addition, the prediction of native-like complex geometries improved because the CSP are already being used during the docking process, and not only in a post-filtering setting for generated docking poses. Since the experimental information is guaranteed to be quantitatively used, CSP effectively contribute to align the ligand in the binding pocket. The first step in the development of QCSPScore was the analysis of 70 protein-ligand complexes for which reference CSP were computed. The success rate in the docking increased from 71% without involvement of CSP to 100% if CSP were considered at the highest weighting scheme. In a second step QCSPScore was used in re-docking three test cases, for which reference experimental CSP data was available. Without CSP, i.e. in the use of conventional DrugScore potentials, none of the three test cases could be successfully re-docked. The integration of CSP with the same weighting factor as described above resulted in all three cases successfully re-docked. For two of the three complexes, native-like solutions were only produced if CSP were considered.Conformational changes in the binding pockets of up to 2 Å RMSD did not affect the success of the docking. QCSPScore will be particularly interesting in difficult protein-ligand complexes. They are in particular those cases in which the shape of the binding pocket does not provide sufficient steric restraints such as in flat protein-protein interfaces and in the virtual screening of small chemical fragments.
A solid-supported membrane (SSM) is an alkanethiol/lipid hybrid membrane with comparable lipid mobility, conductivity, and capacitance than a black lipid membrane (BLM). However, mechanical perturbations, which usually destroy a BLM, do not influence the life-time of a SSM, which is mechanically so stable that solutions may be rapidly exchanged at its surface. This key property has been utilized in this thesis to characterize electrophysiologically two bacterial secondary active transporters (MelB and LacY) as well as to investigate the specific interactions between ions and lipid membranes. These three different projects are summarized below: (1) The properties of lipid membranes, which represent the most important biological interface between intracellular and extracellular compartments, are essentially modulated by the ionic composition of the surrounding aqueous medium. To investigate specific interactions between ions and lipid membranes, solutions of different ionic composition were exchanged at the surface of a SSM through a flow system. This solution exchange resulted in charge translocations that were interpreted in terms of binding of the ions to the lipid headgroups at the SSM surface. We found that chaotropic anions and kosmotropic cations are attracted to the membrane independent of the membrane composition. In particular, the same behaviour was found for lipid headgroups bearing no charge like monoolein. This general trend is modulated by the electrostatic interaction of the ions with the lipid headgroup charge. Our experimental results are in agreement with recent molecular dynamic simulations of PC membranes. (2) Rapid solution exchange on a solid-supported membrane (SSM) is investigated using fluidic structures and a solid-supported membrane in a wall jet geometry. The flow was analyzed with a new technique based on specific ion interactions with the surface combined with an electrical measurement. The critical parameters affecting the time course of the solution exchange and the transfer function describing the time resolution of the SSM system were determined. The experimental data indicate that the solution transport follows a plug flow geometry while the rise of the surface concentration can be approximated by Hagen Poiseuille flow with ideal mixing at the surface of the SSM. Using an improved cuvette design a solution exchange as fast as 2 ms was achieved at the surface of a solid supported membrane. As an application of the technique the rate constant of a fast electrogenic reaction in the melibiose permease MelB, a bacterial (Escherichia coli) sugar transporter, is determined. For comparison, the kinetics of a conformational transition of the same transporter was measured using stopped-flow tryptophan fluorescence spectroscopy. The relaxation time constant obtained for the charge displacement agrees with that determined in the stopped-flow experiments. This supports the previous proposition that upon sugar binding MelB undergoes an electrogenic conformational transition with a rate constant of k ~ 250 s-1. (3) Electrogenic events due to activity of wild-type lactose permease from Escherichia coli (LacY) were investigated with proteoliposomes containing purified LacY adsorbed on a solid-supported membrane electrode. Downhill sugar/H+ symport into the proteoliposomes generates transient currents. Studies at different lipid to protein ratios and at different pH values, as well as inactivation by N-ethylmaleimide, show that the currents are due specifically to the activity of LacY. From analysis of the currents under different conditions and comparison with biochemical data, it is apparent that the predominant electrogenic event in downhill sugar/H+ symport is H+ release. In contrast, LacY mutants E325A and C154G, which bind ligand normally but are severely defective with respect to lactose/H+ symport, exhibit a minor electrogenic event upon addition of LacY-specific substrates, representing only 6% of the total charge displacement of the wild-type. This activity is due either to substrate binding per se or to a conformational transition following substrate binding. We propose that turnover of LacY involves at least two electrogenic reactions: (i) a minor reaction that occurs upon sugar binding and is due to a conformational transition in LacY; and (ii) a major reaction due to cytoplasmic release of H+ during downhill sugar/H+ symport, which is the limiting step for this mode of transport.
The study of the electromagnetic structure of hadrons plays an important role in understanding the nature of matter. In particular the emission of lepton pairs out of the hot and dense collision zone in heavy-ion reactions is a promising probe to investigate in-medium properties of hadrons and in general the properties of matter under such extreme conditions. The first experimental observation of an enhanced di-electron yield in the invariant-mass region 0:3 - 0:7 GeV/c2 in p+Be collisions at 4:9 GeV/u beam energy [2] was announced by the DLS collaboration [1]. Recent results of the HADES collaboration show a moderate enhancement above n Dalitz decay contributions for 12C+12C at 1 and 2 GeV/u [3, 4] confirming the DLS results. There are several theoretical explanations of this observation, most of them focusing on possible in-medium modifications of the properties of vector mesons. At low beam energies the question whether the observed excess is related to any in-medium effects remains open because of uncertainties in the description of elementary di-electron sources. In this work the di-electron production in p+p and d+p reactions at a kinetic beam energy of 1:25 GeV/u measured by the HADES spectrometer is discussed. At Ekin = 1:25 GeV/u, i.e. below the n meson production threshold in proton-proton reactions, the delta Dalitz decay is expected to be the most abundant source above the pi 0 Dalitz decay region. The observed large difference in di-electron production in p+p and d+p collisions suggests that di-electron production in the d+p system is dominated by the n+p interaction. In order to separate delta Dalitz decays and np bremsstrahlung the di-electron yield observed in p+p and n+p reactions, both measured at the same beam energy, has been compared. The main interest here is the investigation of iso-spin effects in baryonic resonance excitations and the off-shell production of vector mesons [5]. We indeed observe a large difference in di-electron production in p+p and n+p reactions. Results of these studies will be compared to recent calculations. We will also present our experimentally defined cocktail for heavy-ion data. At much higher beam energies experimental results of the CERES [6] and NA60 [7] collaborations also show an enhancement in the invariant mass region 0:3 - 0:7 GeV/c2, in principle similar to the situation in DLS. A strong excess of lepton pairs observed by recent high energy heavy-ion dilepton experiments hint to a strong influence of baryons, however no data exist at highly compressed baryonic matter, achievable in heavy-ion collisions from 8 - 45 GeV/u beam energy. These conditions would allow to study the expected restoration of chiral symmetry by measuring in-medium modifications of hadronic properties, an experimental program which is foreseen by the future CBM experiment at FAIR. The experimental challenge is to suppress the large physical background on the one hand and to provide a clean identification of electrons on the other hand. In this work, strategies to reduce the combinatorial background in electron pair measurements with the CBM detector are discussed. The main goal is to study the feasibility of effectively reducing combinatorial background with the currently foreseen experimental setup, which does not provide electron identification in front of the magnetic field.
Lentiviral vectors mediate gene transfer into dividing and most non-dividing cells. Thereby, they stably integrate the transgene into the host cell genome. For this reason, lentiviral vectors are a promising tool for gene therapy. However, safety and efficiency of lentiviral mediated gene transfer still needs to be optimised. Ideally, cell entry should be restricted to the cell population relevant for a particular therapeutic application. Furthermore, lentiviral vectors able to transduce quiescent lymphocytes are desirable. Although many approaches were followed to engineer retroviral envelope proteins, an effective and universally applicable system for retargeting of lentiviral cell entry is still not available. Just before the experimental work of this thesis was started, retargeting of measles virus (MV) cell entry was achieved. This virus has two types of envelope glycoproteins, the hemagglutinin (H) protein responsible for receptor recognition and the fusion (F) protein mediating membrane fusion. For retargeting, the H protein was mutated in its interaction sites for the native MV receptors and a ligand or a single-chain antibody (scAb) was fused to its ectodomain. It was hypothesised that the retargeting system of MV can be transferred to lentiviral vectors by pseudotyping human immunodeficiency virus-1 (HIV-1) derived vector particles with the MV glycoproteins. As the unmodified MV glycoproteins did not pseudotype HIV vectors, two F and 15 H protein variants carrying stepwise truncations or amino acid (aa) exchanges in their cytoplasmic tails were screened for their ability to form MV-HIV pseudotypes. The combinations Hcd18/Fcd30, Hcd19/Fcd30 and Hcd24+4A/Fcd30 led to most efficient pseudotype formation with titers above 10exp6 transducing units /ml, using concentrated particles. The F cytoplasmic tail was truncated by 30 aa and the H cytoplasmic tail was truncated by 18, 19 or 24 residues with four added alanines after the start methionine in the latter case. Western blot analysis indicated that particle incorporation of the MV glycoproteins was enhanced upon truncation of their cytoplasmic tails. With the MV-HIV vectors high titers on different cell lines expressing one or both MV receptors were obtained, whereas MV receptor-negative cells remained untransduced. Titers were enhanced using an optimal H to F plasmid ratio (1:7) during vector particle production. Based on the described pseudotyping with the MV glycoprotein variants, HIV vectors retargeted to the epidermal growth factor receptor (EGFR) or the B cell surface marker CD20 were generated. For the production of the retargeted vectors MVaEGFR-HIV and MVaCD20-HIV, Fcd30 together with a native receptor blind Hcd18 protein, displaying at its ectodomain either the ligand EGF or a scAb directed against CD20 were used. With these vectors, gene transfer into target receptor-positive cells was several orders of magnitude more efficient than into control cells. The almost complete absence of background transduction of non-target cells was e.g. demonstrated in mixed cell populations, where the CD20-targeting vector selectively eliminated CD20-positive cells upon suicide gene transfer. Remarkably, transduction of activated primary human CD20-positive B cells was much more efficient with the MVaCD20-HIV vector than with the standard pseudotype vector VSV-G-HIV. Even more surprisingly, MVaCD20-HIV vectors were able to transduce quiescent primary human B cells, which until then had been resistant towards lentiviral gene transfer. The most critical step during the production of MV-HIV pseudotypes was the identification of H cytoplasmic tail mutants that allowed pseudotyping while retaining the fusion helper function. In contrast to previously inefficient targeting strategies, the reason for the success of this novel targeting system must be based on the separation of the receptor recognition and fusion functions onto two different proteins. Furthermore, with the CD20-targeting vector transduction of quiescent B cells was demonstrated for the first time. Own data and literature data suggest that CD20 binding and hyper-cross-linking by the vector particles results in calcium influx and thus activation of quiescent B cells. Alternatively this feature may be based on a residual binding activity of the MV glycoproteins to the native MV receptors that is insufficient for entry but induces cytoskeleton rearrangements dissolving the post-entry block of HIV vectors. Hence, in this thesis efficient retargeting of lentiviral vectors and transduction of quiescent cells was combined. This novel targeting strategy should be easily adaptable to many other target molecules by extending the modified MV H protein with appropriate specific domains or scAbs. It should now be possible to tailor lentiviral vectors for highly selective gene transfer into any desired target cell population with an unprecedented degree of efficiency.
Very little is known about the occlusal wear pattern in the Neanderthal posterior dentition. Usually dental wear is closely related to the physical properties of the ingested food, and consequently can be used to obtain information about diet. Neanderthal dietary reconstructions have been mostly based on the analysis of accompanying faunal remains and isotopic signatures of bones and tooth enamel, suggesting that they exploited larger portions of animal proteins from large and medium-sized herbivores. Probably these studies may do not reflect the bulk diet, tending to underestimate plant consumption and to overestimate meat consumption. In the present work the occlusal wear pattern of maxillary molars of Homo neanderthalensis (N=19) and early Homo sapiens (N=12)have been analyzed, applying non-destructive methods based on virtual three-dimensional polygonal models generated from surface scanning of dental casts. The sample groups occupied different geographical areas at different chronological times. The 3D digital tooth models were analyzed using the “Occlusal Fingerprint Analysis” (OFA) method (Kullmer et al. 2009), describing and quantifying the occlusal wear pattern derived from two wear facet angles (dip and dip direction), wear facet area and occlusal relief index (ORI). The OFA method provides information about the dynamics of the occlusal relationships and their function, permitting the reconstruction of the mandibular movements responsible for the contacts created during the chewing cycle. Since jaw movements and diet are closely related, the results obtained, can be used to interpret the diet of the two Pleistocene hominin species. In order to evaluate how dietary differences influence the occlusal wear pattern, upper molars of modern hunter-gatherers (N=42) with known diet and different dietary habits, have been included in the sample and compared with those of Neanderthals and early Homo sapiens. Results show that within the modern hunter-gatherers sample, the occlusal wear pattern of carnivorous populations differs from those who relied on a mixed-diet. In particular, the study of relative facet areas clearly distinguish meat-eaters from mixed-diet hunter-gatherers, while ORI results and wear facet inclinations (dip angle) seem to reflect directly the abrasiveness of the diet, including the influence of exogenous materials during food preparation. The Neanderthal occlusal wear pattern is characterized by an ecogeographic variation, suggesting the exploitation of different food resources. In particular Neanderthals who inhabited relatively warm environments of southern Europe and the Near East exhibit an occlusal wear pattern different from those of meat-eaters hunter-gatherers from tempered and cooler regions, displaying some features similar to those of Bushmen. These results suggest the exploitation of a broad variety of food sources. The analysis of the occlusal wear pattern in Neanderthals and early Homo sapiens who inhabited Europe during the cooler Oxygen Isotope Stage 3 (OIS3) shows many similarities between the two hominid species. These results indicate the exploitation of similar and low-diversified food sources, based mostly on the consumption of animal proteins, as suggested through the clear similarities with the wear patterns found in modern meat-eaters hunter-gatherers. In both studied groups, Neanderthals and early Homo sapiens the occlusal wear pattern is characterized by high ORI and dip angle values, suggesting the intake of a low-abrasive diet, probably due to the absence of sophisticated food preparation techniques introducing external silica grains, e.g. from soil (grinding of seeds) or plant cells, as those, seen in modern hunter-gatherer populations. The analysis of the occlusal fingerprints in Neanderthal and early European Homo sapiens upper molars suggests that both species followed very similar adaptive dietary strategies, based on a distinctive versatility and flexibility in the daily diet, depending on availability of resources according to environmental circumstances.
This thesis describes the structural characterization of interactions between biological relevant ribonucleic acid biomacromolecules (RNAs) and selected ligands to optimize the methodologies for the design of pharmacological lead compounds. To achieve this aim, not only the structures of the RNA, the ligand and their complexes need to be known, but also information about the inherent dynamics, especially of the target RNA, are necessary. To determine the structure and dynamics of these molecules and their complexes, liquid state nuclear magnetic resonance spectroscopy (NMR) is a suitable and powerful method. The necessity for these investigations arises from the lack of knowledge in RNA-ligand interactions, e.g. for the development of new medicinal drugs targeting crucial RNA sequences. In the first chapters of this thesis (Chapters II to IV), an introduction into RNA research is given with a focus on RNA structural features (Chapter II), into the interacting molecules, the biology of the specific RNA targets and the further development of their ligands (Chapter III) and into the NMR theory and methodologies used within this thesis (Chapter IV). Chapter II begins with a description of RNA characteristics and functions, placing the focus on the increasing attention that these biomacromolecules have attracted in recent years due to their diverse biological functionalities. This is followed by a detailed description of general structural features of RNA molecules. The biological functions of the RNAs investigated in this thesis (Human immunodeficiency virus PSI- and TAR-RNA and Coxsackievirus B3 Stemloop D in the 5’-cloverleaf element), together with their known structural characteristics are introduced in Chapter III. Furthermore, a description of the investigated ligands is given, focusing on the methods how their affinity and specificity were determined. The introduction is completed in Chapter IV, where the relevant NMR theory and methodologies are explained. First, kinetics and thermodynamics of ligand binding are summarized from an NMR point of view. Subsequently, a detailed description of the resonance assignment procedures for RNAs and peptidic ligands is given. This procedure mainly concentrates on the assignment of the proton resonances, which are essential for the later structure calculation from NMR restraints. The procedure for NMR structure calculation of RNA and its complexes follows with a short introduction into the programs ARIA and HADDOCK. The final part of this chapter explains the relaxation theory and the methodology to extract dynamic information from autocorrelated relaxation rates via the model-free formalism. In the Chapters V to VII of this thesis, the original publications are included and grouped into three topics. Chapter V comprehends the publications on the investigations of HIV PSI-RNA and its hexapeptidic ligand. These three publications[1-3] focus on the characterization of the ligand and its binding properties, its structure and the optimization of its composition aiming to improve its usage for further spectroscopic investigations.
In this thesis, we studied the single impurity Anderson model and developed a new and fast impurity solver for the dynamical mean field theory (DMFT). Using this new impurity solver, we studied the Hubbard model and periodic Anderson model for various parameters. This work is motivated by the fact that the dynamical mean field theory is widely used for the studies of strongly correlated systems, and the most frequently used methods, e.g. the quantum Monte-Carlo method (QMC), and the exact digonalization method are much CPU time consuming and usually limited by the available computers. Therefore, a fast and reliable impurity solver is needed. This new impurity solver was explored based on the equation-of-motion method (also called Green's function and decoupling method in some literature). Using the retarded Green's function, we first derived the equations of motion of Green's functions. Then, we employed a decoupling scheme to close the equations. By solving self-consistently the obtained closed set of integral equations, we obtained the single particle Green's function for the single impurity Anderson model. After that, the single impurity Anderson model was solved along with self-consistency conditions within the framework of DMFT. In this work, we studied and compared two decoupling schemes. Moreover, we also derived possible higher order approximations which will be tested in future work. Besides the theoretical work, we tested the method in numerical calculations. The integral equations are first solved by iterative methods with linear mixing and Broyden mixing, respectively. However, these two methods are not sufficient for finding the self-consistent solutions of the DMFT equations because converged results are difficult to obtain. Moreover, the computing speed of the two methods is also not satisfactory. Especially the iterative method with linear mixing costs always a lot of CPU time due to the required small mixing. Hence, we developed a new method, which is a combination of genetic algorithm and iterative method. This new method converges very fast and removes artifacts appearing in the results from the iterative method with linear and Broyden mixing. It can directly operate on the real axis, where no numerical error from the high frequency tail corrections and the analytical continuation is introduced. In addition, our new technique strongly improves the precision of the numerical results by removing the broadening. With this newly developed impurity solver and numerical technique, we studied the single impurity Anderson model, the single band Hubbard model and the periodic Anderson model with arbitrary spin and orbital degeneracy N on the real axis. For the single impurity Anderson model, the spectral functions are calculated for the infinite and finite Coulomb interaction strength. We also studied the spectral functions in dependence of the parameters of impurity position and hybridization. For the Hubbard model, we studied the bandwidth control and filling control Mott metal-insulator transition for spin and orbital degeneracy N = 2. It gives qualitatively the critical value of Coulomb interaction strength for the Mott metal-insulator transition, and the spectral functions which are comparable to those obtained in QMC and numerical renormalization group methods. We also studied the quasiparticle weight and the self-energy in metallic states. The latter shows almost Fermi liquid behavior. At last we calculated the densities of states for the Hubbard model with arbitrary spin and orbital degeneracy N. The periodic Anderson model (PAM) is also studied as another important lattice model. It was solved for various combinations of parameters: the Coulomb interaction strength, the impurity position, the center position of the conduction band, the hybridization, the spin and orbital degeneracy. The PAM results represents the physics of impurities in a metal. In short, our method works for the Hubbard model and the periodic Anderson model in a large range of parameters, and gives good results. Therefore, our impurity solver could be very useful in calculations within LDA+DMFT. Finally, we also made a preliminary investigation of the multi-band system based on the success in single band case. We first studied the two-band system in a simplified treatment by neglecting the interaction between the two bands through the bath. This has given promising numerical results for the two-band Hubbard model. Moreover, we have studied theoretically the two-band system with mean field approximation and Hubbard-I approximation in dealing with the higher order cross Green's functions which are related to both the two bands. In the mean field approximation, we even generalized the two-band system to arbitrary M=N/2 band system. Potential improvement can be carried out on the basis of this work.
Information sent to and received by cells is essential for a homeostatic development of tissues and organs. These same signals are responsible for the good functioning of lymphatic organs and therefore govern the immune response. Dysfunctioning of the signaling networks is related to pathological situations, among which one can find cancer and auto-immune diseases. Intercellular communication involves the synthesis and the adjustment of signals by the secreting/emitting cell in order to reach the needed threshold. Diffusion of the signal to the target cell in addition to its interpretation lead to functional changes like cell migration and aggregation. Individual cells such as bacteria find food or increase their virulence through taxis (directional stimulus) and/or kinesis (speed stimulus). Immune cells appear to use the same processes to find bacteria and cellular debris, as well as to perform the cellular dance observed in germinal centers. This behavior is a result of an up or down regulation of specific signals that suggest to B and T-cells the paths to follow. Furthermore, cell segregation in the white pulp of the spleen, was also shown to be a result of a tight adjustment of T-cell kinesis. Restriction to cellular tracks and other experimentally provided measurements does not ensure a full comprehension of the observed cellular behavior. Thus, the study of patterns opens new gates to our understanding of the immune system. With the help of the agent-based modeling technique, cellular migration and aggregation are investigated in response to various cell-cell interactions. This work aims to explore different mechanisms that lead to cellular migration and aggregation, by defining the emergent properties of interest and that will help distinguish between interactions, starting by a simple look at the emergent patterns, followed by an analysis of their size, their degree of aggregation and the effective communication distances. Finally, the results obtained from the in silico experiments provided a guideline to differentiate between many cell-cell interactions under specific circumstances. Chemotaxis and phototaxis with and without diffusive cellular motion were shown to be distinguishable through an analysis of the emerging aggregation profiles.
Kaon and pion production in centrality selected minimum bias Pb+Pb collisions at 40 and 158A GeV
(2009)
Results on charged kaon and negatively charged pion production and spectra for centrality selected Pb+Pb mininimum bias events at 40 and 158A GeV have been presented in this thesis. All analysis are based on data taken by the NA49 experiment at the accelerator Super Proton Synchrotron (SPS) at the European Organization for Nuclear Research (CERN) in Geneva, Switzerland. The kaon results are based on an analysis of the mean energy loss <dE/dx> of the charged particles traversing the detector gas of the time projection chambers (TPCs). The pion results are from an analysis of all negatively charged particles h- corrected for contributions from particle decays and secondary interactions. For the dE/dx analysis of charged kaons, main TPC tracks with a total momentum between 4 and 50 GeV have been analyzed in logarithmic momentum log(p) and transverse momentum pt bins. The resulting dE/dx spectra have been fitted by the sum of 5 Gaussians, one for each main particle type (electrons, pions, kaons, protons, deuterons). The amplitude of the Gaussian used for the kaon part of the spectra has been corrected for efficiency and acceptance and the binning has been transformed to rapidity y and transverse momentum pt bins. The multiplicity dN/dy of the single rapidity bins has been derived by summing the measured range of the transverse momentum spectra and an extrapolation to full coverage with a single exponential function fitted to the measured range. The results have been combined with the mid-rapidity measurements from the time-of-flight detectors and a double Gaussian fit to the dN/dy spectra has been used for extrapolation to rapidity outside of the acceptance of the dE/dx analysis. For the h- analysis of negatively charged pions, all negatively charged tracks have been analyzed. The background from secondary reactions, particle decays, and gamma-conversions has been corrected with the VENUS event generator. The results were also corrected for efficiency and acceptance and the pt spectra were analyzed and extrapolated where necessary to derive the mean yield per rapidity bin dN/dy. The mean multiplicity <pi-> has been derived by summing up the measured dN/dy and extrapolating the rapidity spectrum with a double Gaussian fit to 4pi coverage. The results have been discussed in detail and compared to various model calculations. Microscopical models like URQMD and HSD do not describe the full complexity of Pb+Pb collisions. Especially the production of the positively charged kaons, which carry the major part of strange quarks, cannot be consistently reproduced by the model calculations. Centrality selected minimum bias Pb+Pb collisions can be described as a mixture of a high-density region of multiply colliding nucleons (core) and practically independent nucleon-nucleon collisions (corona). This leads to a smooth evolution from peripheral to central collisions. A more detailed approach derives the ensemble volume from a percolation of elementary clusters. In the percolation model all clusters are formed from coalescing strings that are assumed to decay statistically with the volume dependence of canonical strangeness suppression. The percolation model describes the measured data for top SPS and RHIC energies. At 40A GeV, the system size dependence of the relative strangeness production starts to evolve from the saturation seen at higher energies from peripheral events onwards towards a linear dependence at SIS and AGS. This change of the dependence on system size occurs in the energy region of the observed maximum of the K+ to pi ratio for central Pb+Pb collisions. Future measurements with heavy ion beam energies around this maximum at RHIC and FAIR as well as the upgraded NA49 successor experiment NA61 will further improve our understanding of quark matter and its reflection in modern heavy ion physics and theories.
Many questions regarding gastropod phylogeny have not yet been answered like the molecular confirmation of the Heterobranchia concept based on morphological studies from Haszprunar (1985a; 1988). This taxon contains the “Lower Heterobranchia” with several “primitive” or “basal” members) and the Euthyneura (with the Opisthobranchia and Pulmonata). Phylogenetic relationships of subgroups within the Heterobranchia have not been satisfactorily resolved and monophyly of some taxa within the Heterobranchia (e.g. Opisthobranchia) is questionable. Moreover, most of the “Lower Heterobranchia” have not been included in former molecular studies. In order to resolve phylogenetic relationships within the Heterobranchia, I pursued a molecular systematic approach by sequencing and analysing a variety of genetic markers (including nuclear 28S rDNA + 18S rDNA and mitochondrial 16S rDNA + COI sequences). Maximum likelihood as well as Bayesian inference methods were used for phylogenetic reconstruction. The data were investigated a priori to tree reconstruction in order to find the most appropriate dataset for reconstructing heterobranch phylogeny. A variety of statistical tests (like Chi-Square-Test or Relative-Rate-Test) were applied and the substitution saturation was measured. The Relative-Rate-Test revealed the highest evolution rates within the “Lower Heterobranchia” (Omalogyra sp., Omalogyra fusca, Murchisonella sp., Ebala sp. and Architectonica perspectiva) and Opisthobranchia (Hyalocylis striata). Furthermore, many of the nucleotide positions show a high degree of substitution saturation. Additionally, bipartitions (splits) in the alignment were examined and visualized by split network analyses to estimate data quality. A high level of conflict indicated by many parallel edges of the same lengths could be observed in the neighbournet graphs. Moreover, several taxa with long terminal branches could be identified in all three datasets belonging to the Vetigastropoda, Caenogastropoda, “Lower Heterobranchia” or Opisthobranchia (Nudipleura). All phylogenetic analyses revealed a monophyletic Heterobranchia. Within the Heterobranchia several well supported clades could be resolved. However, the traditional classification based on morphological data could not be confirmed due to paraphyletic Euthyneura (because of the inclusion of the Pyramidellidae and Glacidorboidea) as well as paraphyletic Pulmonata and polyphyletic Opisthobranchia. Based on the phylogenetic inferred evolutionary trends regarding habitat colonisation or character complexes could be deduced. A case study was conducted in order to estimate divergence ages using a “relaxed” molecular clock approach with fossils as minimum age constraints. However, due to large 95% confidence intervals a precise dating of the nodes was not possible. Hence, the results are considered as preliminary. To test the plausibility of the newly obtained hypotheses, the results were evaluated a posteriori using a hypothesis test and secondary structures of the complete 18S rRNA and 28S rRNA. Secondary structure motifs were found within domain 43 and E23 2 &5 of the 18S rRNA as well as within domain E11 and G5_1 of the 28S rRNA, which contain phylogenetic signals to support various groups within the Heterobranchia. In addition, taxon specific motifs were found separating the Vetigastropoda from the Caenogastropoda and Heterobranchia, indicating a possible application of the secondary structure of 18S rRNA and 28S rRNA to reveal phylogenetic relationships at higher taxonomic levels such as Gastropoda or even Mollusca. The utility of the newly invented software RNAsalsa for the reconstruction of secondary structures was tested. The obtained structures were used to adjust evolutionary models specific to rRNA stem (paired basepairs) and loop (unpaired basepairs) regions with the intention of improving phylogenetic results. This approach proved unsuccessful. This molecular phylogenetic investigation provides the most comprehensive molecular study of Heterobranchia relationships to date. Substantial insights into the evolution and phylogeny of this enigmatic taxon have been gained.
The purpose of this thesis was to investigate different aspects of the promotion of selfregulated learning in primary and secondary school education by focussing on its effectiveness, and on its assessment from different perspectives. Theoretically, the thesis is based on contemporary social-cognitive and constructivist theories of self-regulated learning. Two meta-analyses were conducted, an observation instrument was developed which was tested and employed in two observation studies, and a multi-method study was conducted to investigate different perspectives on the topic. Common to all studies is the evaluation of different aspects of the promotion of self-regulated learning among students. The results of this investigation are reported in four research articles (Studies 1-4), which have been accepted for publication (Study 1 and 2) or submitted to scientific peer reviewed journals (Study 3 and 4). The data are analyzed by applying a multi-method approach, using several sources of data (primary studies, self-reports, video data, interviews) and diverse methods (meta-analysis, observation analysis, survey analysis). The present data generally indicate that self-regulated learning can be enhanced both at primary and secondary school. The results of the first and the second study showed that primary and secondary school students partly benefit from different training characteristics. However, there were also common aspects of effective training characteristics that hold for both school levels. Moreover, the third study revealed that it was possible to develop an instrument to observe teachers’ promotion of self-regulated learning in a reliable way, which can be applied in several contexts. The results indicated that the stability of teachers’ promotion of selfregulated learning varies among the school subjects. Furthermore, the results showed that only little instruction of self-regulated learning takes place in primary and secondary school mathematics lessons. Yet, secondary school teachers showed more promotion of cognitive strategies than primary school teachers did, although the former included more constructivist characteristics in the learning environment. The observation studies produced a rich pool of data, serving as pilot studies for future studies with a larger sample sizes that are needed to further strengthen the results. As the fourth study indicated, teacher ratings differ significantly from video-based observations in perceiving their promotion of self-regulated learning. However, for some aspects they agree with their students’ perception. Finally, it was found that students’ perception on their teachers’ promotion of self-regulated learning had the highest impact on their self-regulation competence. In the future, it will be crucial to include the instruction of self-regulated learning from a theoretical and a practical perspective in the teacher training curriculum. Moreover, in future research the implementation of the promotion of self-regulated learning should be investigated, and in experimental settings different ways of supporting such an implementation should be examined. A close collaboration with teachers would be helpful to get deeper insights into teachers’ behaviour and attitudes. The promotion of self-regulated learning should start as early as in primary school as students are already able to learn it then and as it takes many years to develop it fully. In addition, when investigating teachers’ promotion of self-regulated learning, the school subject should be taken into account during assessment. Long-term measurements could acknowledge such a potential instability. Moreover, in further studies, observation data of a large sample of teachers should be gathered in order to get a representative overview of teachers’ promotion of self-regulated learning. Furthermore, research on the promotion of self-regulated learning should account for the impact of students’ perspectives referring on this.
Neutron stars are very dense objects. One teaspoon of their material would have a mass of five billion tons. Their gravitational force is so strong that if an object were to fall from just one meter high it would hit the surface of the respective neutron star at two thousand kilometers per second. In such dense bodies, different particles from the ones present in atomic nuclei, the nucleons, can exist. These particles can be hyperons, that contain non-zero strangeness, or broader resonances. There can also be different states of matter inside neutron stars, such as meson condensates and if the density is height enough to deconfine the nucleons, quark matter. As new degrees of freedom appear in the system, different aspects of matter have to be taken into account. The most important of them being the restoration of the chiral symmetry. This symmetry is spontaneously broken, which is a fact related to the presence of a condensate of scalar quark-antiquark pairs, that for this reason is called chiral condensate. This condensate is present at low densities and even in vacuum. It is important to remember at this point that the modern concept of vacuum is far away from emptiness. It is full of virtual particles that are constantly created and annihilated, being their existence allowed by the uncertainty principle. At very high temperature/density, when the composite particles are dissolved into constituents, the chiral consensate vanishes and the chiral symmetry is restored. To explain how and when chiral symmetry is restored in neutron stars we use a model called non-linear sigma model. This is an effective quantum relativistic model that was developed in order to describe systems of hadrons interacting via meson exchange. The model was constructed from symmetry relations, which allow it to be chiral invariant. The first consequence of this invariance is that there are no bare mass terms in the lagrangian density, causing all, or most of the particles masses to come from the interactions with the medium. There are still other interesting features in neutron stars that cannot be found anywhere else in nature. One of them is the high isospin asymmetry. In a normal nucleus, the amount of protons and neutrons is more or less the same. In a neutron star the amount of neutrons is much higher than the protons. The resulting extra energy (called Fermi energy) increases the energy of the system, allowing the star to support more mass against gravitational collapse. As a consequence of that in early stages of the neutron star evolution, when there are still many trapped neutrinos, the proton fraction is higher than in later stages and consequently the maximum mass that the star can support against gravity is smaller. This, between many other features, shows how the microscopic phenomena of the star can reflect into the macroscopic properties. Another important property of neutron stars is charge neutrality. It is a required assumption for stability in neutron stars, but there are others. One example is chemical equilibrium. It means that the number of particles from each kind is not conserved, but they are created and annihilated through specific reactions that happen at the same rate in both directions. Although to calculate microscopic physics of neutron stars the space-time of special relativity, the Minkowski space, can be used, this is not true for the global properties of the star. In this case general relativity has to be used. The solution of Einstein's equations simplified to static, spherical and isotropic stars correspond to the configurations in which the star is in hydrostatic equilibrium. That means that the internal pressure, coming mainly from the Fermi energy of the neutrons, balances the gravity avoiding the collapse. When rotation is included the star becomes more stable, and consequently, can be more massive. The movement also makes it non-spherical, what requires the metric of the star to also be a function of the polar coordinate. Another important feature that has to be taken into account is the dragging of the local inertial frame. It generates centrifugal forces that are not originated in interactions with other bodies, but from the non-rotation of the frame of reference within which observations are made. These modifications are introduced through the Hartle's approximation that solves the problem by applying perturbation theory. In the mean field approximation, the couplings as well as the parameters of the non-linear sigma model are calibrated to reproduce massive neutron stars. The introduction of new degrees of freedom decreases the maximum mass allowed for the neutron star, as they soften the equation of state. In practice, the only baryons present in the star besides the nucleons are the Lambda and Sigma-, in the case in which the baryon octet is included, and Lambda and Delta-,0,+,++, in the case in which the baryon decuplet is included. The leptons are included to ensure charge neutrality. We choose to proceed our calculations including the baryon octet but not the decuplet, in order to avoid uncertainties in the couplings. The couplings of the hyperons were fitted to the depth of their potentials in nuclei. In this case the chiral symmetry restoration can be observed through the behavior of the related order parameter. The symmetry begins to be restored inside neutron stars and the transition is a smooth crossover. Different stages of the neutron star cooling are reproduced taking into account trapped neutrinos, finite temperature and entropy. Finite-temperature calculations include the heat bath of hadronic quasiparticles within the grand canonical potential of the system. Different schemes are considered, with constant temperature, metric dependent temperature and constant entropy. The neutrino chemical potential is introduced by fixing the lepton number in the system, that also controls the amount of electrons and protons (for charge neutrality). The balance between these two features is delicate and influenced mainly by the baryon number conservation. Isolated stars have a fixed number of baryons, which creates a link between different stages of the cooling. The maximum masses allowed in each stage of the cooling process, the one with high entropy and trapped neutrinos, the deleptonized one with high entropy, and the cold one in beta equilibrium. The cooling process is also influenced by constraints related to the rotation of the star. When rotation is included the star becomes more stable, and consequently, can be more massive. The movement also deforms it, requiring the metric of the star to include modifications that are introduced through the use of perturbation theory. The analysis of the first stages of the neutron star, when it is called proto-neutron star, gives certain constraints on the possible rotation frequencies in the colder stages. Instability windows are calculated in which the star can be stable during certain stages but collapses into black holes during the cooling process. In the last part of the work the hadronic SU(3) model is extended to include quark degrees of freedom. A new effective potential to the order parameter for deconfinement, the Polyakov loop, makes the connection between the physics at low chemical potential and hight temperature of the QCD phase diagram with the height chemical potential and low temperature part. This is done through the introduction of a chemical potential dependency on the already temperature dependent potential. Analyzing the effect of both order parameters, the chiral condensate and the Polyakov loop, we can drawn a phase diagram for symmetric as well as for star matter. The diagram contains a crossover region as well as a first order phase transition line. The new couplings and parameters of the model are chosen mainly to fit lattice QCD, including the position of the critical point. Finally, this matter containing different degrees of freedom (depending on which phase of the diagram we are) is used to calculate hybrid star properties.
This study focuses on structural features of a particular GPCR type, the family C GPCRs. Structure- and ligand-based approaches were adopted for prediction of novel mGluR5 binding ligand and their binding modes. The objectives of this study were: 1. An analysis of function and structural implication of amino acids in the TM region of family C GPCRs. 2. The prediction of the TM domain structure of mGluR5. 3. The discovery of novel selective allosteric modulators of mGluR5 by virtual screening. 4. The prediction of a ligand binding mode for the allosteric binding site in mGluR5. GPCRs are a super-family of structurally related proteins although their primary amino acid sequence can be diverse. Using sequence information a conservation analysis of family C GPCRs should be applied to reveal characteristic differences and similarities with respect function, folding and ligand binding. Using experimental data and conservation analysis the allosteric binding site of mGluR5 should be characterized regarding NAM and PAM and selective ligand binding. For further evaluation experimental knowledge about family A GPCRs as well as conservation between vertebrate rhodopsins was planned to be compared to results obtained for family C GPCRs (Section 4.1 Conservation analysis of family C GPCRs). Since no receptor structure is available for any family C GPCR, discussion of conserved sequence positions between family A and C GPCRs requires the prediction of a receptor structure for mGluR5 using a family A receptor as template. In order to predict the mGluR5 structure a sequence alignment to a GPCR template protein will have to be proposed and GPCR specific features considered in structure calculation (Section 4.1.4 Structure prediction of mGluR5). The obtained structure was intended to be involved in ligand binding mode prediction of newly discovered active molecules. For discovery of novel selective mGluR modulators several ligand-based virtual screening protocols were adapted and evaluated. Prediction models were derived for selection of possibly active molecules using a diverse collection of known mGluR binding ligands. For that purpose a data collection of known mGluR binding ligands should be established and this reference collection analyzed with respect to different ligand activity classes, NAM or PAM and selective modulators. The prediction of novel NAMs and PAMs using several combinations of 2D-, 3D-, pharmacophore or molecule shape encoding methods with machine learning techniques and similarity determining methods should be tested in a prospective manner (Section 4.2 Virtual screening for novel mGluR modulators). In collaboration with Merz Pharmaceuticals (Merz GmbH & Co. KGaA, Frankfurt am Main, Germany) the modulating effect of a few hundred molecules should be approved in a functional cell-based assay. With the objective to predict a binding mode of the discovered active molecules, molecule docking should be applied using the allosteric binding site of the modeled mGluR5 structure (Section 4.2.4 Modeling of binding modes). Predicted ligand binding modes are to be correlated to conservation profiles that had resulted from the sequence-based entropy analysis and information from mutation experiments, and shall be compared to known ligand binding poses from crystal structures of family A GPCRs.