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In the present study the cryo-immunogold technique was used and optimized for investigating the ultrastructure and immunolabeling of synaptic proteins. It is evidently a suitable method for the localization of membrane proteins since the antigens are not treated with any chemical denaturation before immunolabeling except for the fixation and since the antigens are directly exposed to the surface of the cryo-ultrasections. The v-SNARE VAMP II and the vesicle-associated proteins SV2 and Rab3A were detected extensively at small vesicles in the mossy fiber terminals. The t-SNARE SNAP-25, and N-type and P/Q type Ca2+ channels were allocated to the plasma membrane both at the active zone and outside the active zone. SNAP-25 and N-type Ca2+ channels appeared also at synaptic vesicles. A significantly increased immunolabeling of VAMP II, SV2, Rab3A, SNAP-25 and N-type Ca2+ channels was found at the active zones of fast synapses, indicating a concentration of these proteins at sites of exocytosis. The widespread distribution of the t-SNARE SNAP-25 at the axonal plasma membrane reveals that membrane-targeting specificity cannot be determined solely by v/t-SNARE interactions. Additional control components are required to assure the docking and exocytosis of the synaptic vesicles at active zones. The novel protein Bassoon was only found at active zones of central synapses and showed the highest specific labeling among all proteins investigated. Its labeling pattern implies an association of Bassoon with the presynaptic dense projections, the structural guide for vesicle exocytosis. The involvement of Bassoon in the organization of the neurotransmitter release site suggests that Bassoon may play an important role in determining the specificity of vesicle docking and fusion. In the neurosecretory endings of neurohypophysis the synaptic proteins VAMP II, SNAP- 25, SV2, Rab3A, and the N-type Ca2+ channels showed a preferential labeling over microvesicles. Moreover, the immunolabeling intensity of these proteins over microvesicles corresponded closely to that over synaptic vesicles. This suggests that these synaptic proteins share an identical association with synaptic vesicle and microvesicles. A significant labeling of SNAP-25, the N-type Ca2+ channels and VAMP II was also detected at the plasma membrane near the clustered microvesicles, indicating the competence of microvesicles for docking and exocytosis along the plasma membrane in the absence of active zones. No significant labeling of VAMP II, SNAP-25, SV2 and N-type Ca2+ channel was observed at the membrane of neurosecretory granules. This is in agreement with the notion that synaptic vesicles and microvesicles possess regulatory mechanisms for exocytosis different from those of granules. In contrast, a/ß-SNAP and NSF were found on the granules, and Rab3A and the P/Q-type Ca2+ channels on granules in a subset of terminals. Rab3A is associated specifically with the oxytocin-containing granule population. Interestingly, some plasma membrane proteins, such as SNAP-25 and even N-type Ca2+ channels and P/Q-type Ca2+ channels, were observed not only at the plasma membrane but also at the vesicular organelles. This suggests that these vesicular organelles may be involved in transporting newly synthesized proteins from the soma to the plasma membrane of the terminal. Furthermore, the vesicular pool of the Ca2+ channels may serve in the stimulationinduced translocation into the plasma membrane when required. Using the conventional preembedding method with Epon and the post-embedding method with LR Gold, VAMP II was localized at vesicular organelles of varying size and on horseradish peroxidase filled endocytic organelles in cultured astrocytes, with and without stimulation in the presence of the horseradish peroxidase. This indicates that VAMP II is involved in the cycle of vesicular exocytosis and endocytosis in astrocytes. U373 cells are capable of expressing all three members of the synaptic SNARE complex (v-SNARE VAMP II, t-SNARE syntaxin I and SNAP25). This indicates the competence of U373 to carry out regulated exocytosis by means of the classical SNARE mechanism. In addition, the ubiquitous v-SNARE cellubrevin and the endosome-associated small GTPbinding protein Rab5 could be expressed in U373 cells. All recombinant synaptic proteins investigated in U373 cells revealed a punctuate cellular distribution under the fluorescence microscope, suggesting that they are mainly associated with intracellular compartments. The cryo-electron microscopy provided direct evidence for the association of all expressed proteins with electron-lucent vesicular organelles. It further supports the potential of U373 MG cells to release low molecular weight messengers by a regulated exocytosis mechanism. In addition, myc-VAMP II was found on dispersed granules. Probably, VAMP II also participates in the exocytosis event of granules in U373 cells. Gold labeling for the two presumptive t-SNAREs syntaxin I and SNAP-25 in U373 cells was confined to the vesicular organelles. At the ultrastructural level no significant labeling was identified at the plasma membrane. The high level of colocalization of the two SNARE proteins VAMP II and syntaxin I in the cell body and in cell processes suggests that the two proteins are mostly sorted into identical vesicular organelles. A partial colocalization of VAMP II and cellubrevin as well as of VAMP II and Rab5 was observed under the fluorescence microscope. At the ultrastructural level, a colocalization of VAMP II and cellubrevin as well as of VAMP II and Rab5 was found on some clustered vesicles. The partial colocalization of VAMP II and cellubrevin implies that they similarly function as v-SNAREs. The partial colocalization of Rab5 with VAMP II in U373 cells suggests that the endosomal protein Rab5 is associated with VAMP II-containing organelles during some stages of their life cycle.
The cytochrome bc1 complex or ubiquinol:cytochrome c oxidoreductase (QCR) catalyses electron transfer from ubiquinol to cytochrome c in respiration and photosynthesis coupled to a vectorial proton transport across the membrane, in which the enzyme resides. In both bacteria and eukaryotic organisms, QCR participates in supramolecular assembly of membrane proteins that comprise the respiratory or photosynthetic chain. In the present work, proton transfer pathways, substrate binding and the supramolecular assembly of the respiratory chain in yeast were probed by structure-based site-directed mutagenesis and characterization of the variants. Both active sites centre P, the place of quinol oxidation, and centre N, where quinone reduction takes place, lack direct access to the bulk solvent necessary for proton release and uptake. Based on the X-ray structure, proton transfer pathways were postulated. Analysis at centre P showed, that E272 and Y132 of cytochrome b are important for QCR catalysis as indicated by increased superoxide production and lowered Cyc1p reductase activity in these variants. Pre-steady state heme reduction kinetics in combination with stigmatellin resistance indicated that charge and length of the side chain at position 272 are crucial for efficient docking of the ISP to form the enzyme substrate complex and for electron bifurcation at centre P. Variants of Y312 and F129, both residues of cytochrome b, showed an increased Km indicating participation of these residues in coordination of ubiquinol or the possible intermediate semiquinone anion radical. F129 proved to be crucial for a functional Q-cycle as indicated by respiratory negative growth phenotype and a lowered H+/e- stoichiometry of F129 variants. At centre N, the postulated CL/K and E/R proton transfer pathways are located at opposite sites of the bound ubiquinone. Variants in the surface residues R218 (cytochrome b) and E52 (Qcr7) of the E/R pathway and E82 (Qcr7) of the CL/K pathway showed instability upon purification indicating an important role of these residues for QCR integrity. The slowed down centre N reduction kinetics in H85 (CL/K), R218 and N208 (both E/R) variant was attributed to a destabilised semiquinone anion consistent with the observed decreased sensitivity towards the site-specific inhibitor antimycin and an increased Km. Variants of residues of both pathway, E82Q and R218M, exhibited a decreased H+/e- stoichiometry indicating a crucial role of both residue for maintaining a working Q-cycle and supporting the proposed protonation of the substrate via the Cl/K and the E/R pathway. Long-range interaction between centre N and centre P were observed by altered reduction kinetics of the high potential chain and increased superoxide production in the centre N variants. The role of the cation-pi-interaction between F230 of Cyt1p and R19 of cytochrome c in binding of the redox carrier to QCR was analysed. In F230L hydrophobic interaction were partially lost as was deduced from the ionic strength dependence of Cyc1p reductase activity and Cycp1 binding, as detected by ionic strength sensitive Kd and Km for Cyc1p. The decreased enzymatic rate of F230W could be explained by a disturbed binding of Cyc1p to the variant enzyme. F230 may influence the heme mid point potential and thereby the electron transfer rate to Cyc1p. Reduction of Cobp via both centre P and centre N was disturbed suggesting an interaction between high and low potential chain. Supramolecular association between QCR and cytochrome c oxidase (COX) in yeast mitochondria was probed by affinity chromatography of a his-tagged QCR in the presence of the mild detergent digitonin. In comparison to purification with laurylmaltoside, the presence of both QCR and COX subunits was detected in the elution fractions by SDS-PAGE, Cyc1p reductase and TMPD oxidase activity assays and immunoblot analysis. The CL-dependent formation of the supercomplex between QCR and COX was analysed by replacement variants in the CL-binding site of QCR in CL containing and CL free environment. With an increasing number of replacements of the three lysines the CL-binding pocket supercomplex formation was not abolished, when CL is present as shown by BN-PAGE analysis. This was supported by the synergetic decrease in enzyme activity for both enzymes upon increased number of replacements. In the CL-free environment, no supracomplex formation was observed for a wildtype CL binding site. By replacements of two lysines in the CL-binding pocket, supercomplex formation could be recovered as revealed by BN-PAGE. This indicates, that CL may serve as a charge neutralizer for the lysines near the presumed interaction domain between complex III and complex IV. The obtained results for centre P provide new information of residues critical for stabilisation of ubiquinol and controlling electron short circuit reactions. The observations for centre N variants clearly support the proposed two proton transfer pathways and the role of the bound phospholipids in centre N kinetics. Variants in the Cyc1p binding site suggest a role for F230 both in Cyc1p binding and electron transfer. Clear interaction between the high and low potential chain in both Cyt1p and centre N variants strongly support long-range interactions in the complex. Studies on the supramolecular association of complex III and complex IV indicate a new role of Cl in stabilising a supracomplex.
Im Rahmen dieser Dissertation wurde die Photophysik und die elektronische Struktur einer Klasse neuartiger Donator-Akzeptor-Ladungstransfer-Komplexe untersucht. Im Wesentlichen bestehen diese Verbindungen aus einem Ferrocen-Donator (Fc) und organischen Akzeptoren, die über B-N-Bindungen verbrückt sind, welche sich bei dieser Art von makromolekularen Systemen spontan bilden. Zentraler Gegenstand dieser Arbeit war die spektroskopische Untersuchung des Metall-zu-Ligand-Ladungstransfers (engl. Abkürzung: MLCT) im elektronischen Anregungszustand dieser kationischen Komplexverbindungen, die im Weiteren als „Fc-B-bpy“-Verbindungen bezeichnet werden. Die vorliegende Arbeit analysiert eine Vielzahl miteinander verwandter Fc-B-bpy-Derivate. Die Arbeit ist gegliedert in 1.) die Analyse der Absorptionsspektren vom UV- bis zum nahen Infrarot-Spektralbereich (250-1000 nm) von Lösungen, dotierten Polymer-Dünnfilmen und Einkristallen, 2.) die zeitaufgelöste optische Spektroskopie des angeregten Zustands auf der Pikosekunden-Zeitskala, 3.) die Analyse elektrochemischer Messungen an Lösungen, und 4.) die Auswertung quantenchemischer Berechnungen. Für die zeitaufgelösten Messungen wurde ein komplexes optisches Spektroskopie-System mit breitbandigen Femtosekunden-Pulsen sowie den entsprechenden zeitaufgelösten Detektionsmethoden (spektral gefilterte Weißlicht-Detektion) aufgebaut. Die Ergebnisse dieser Arbeit beweisen die Existenz eines MLCT-Übergangs mit fast vollständigem Übergang eines Fc-Donator-Elektrons zum B-bpy-Akzeptor bei optischer Anregung. Die vergleichenden Untersuchungen der spektroskopischen Eigenschaften verschiedener Derivate liefern wichtige Information für die Entwicklung neuartiger Derivate, einschließlich verwandter Polymere, mit verbesserten spektroskopischen Eigenschaften. Es wurden transiente Absorptionsmessungen bestimmter Fc-B-bpy-Derivate in Lösung nach gepulster Anregung der MLCT-Bande (bei 500 nm) über einen Zeitbereich von 0,1-1000 ps und einen Wellenlängenbereich von 460-760 nm vorgenommen. Aus den Messergebnissen geht hervor, dass die Relaxation aus dem angeregten MLCT-Zustand in den Grundzustand auf verschiedenen Zeitskalen geschehen kann, welche im Bereich zwischen ~18 und 900 ps liegen. Ein Vergleich verschiedener Derivate mit unterschiedlicher Flexibilität in der Konformation zeigt, dass die Starrheit der Bindungen zwischen Donatoren und Akzeptoren ein wesentlicher Faktor für die Lebensdauer des angeregten Zustands ist. Wenn die Akzeptorgruppen relativ frei rotieren können, ist es der Verbindung möglich, eine Geometrie einzunehmen, von der aus ein effizienter, strahlungsfreier Übergang in den Grundzustand erfolgen kann. Dieser Befund zeigt einen Weg auf, wie neuartige, verwandte Verbindungen mit größerer Lebensdauer das angeregten Zustands synthetisiert werden können, indem darauf geachtet wird, daß eine starre molekulare Architektur zwischen Donator und Akzeptor verwirklicht wird.
Stability, unfolding and refolding of the outer membrane protein porin from Paracoccus denitrificans was investigated using genetic and spectroscopic methods. Structural and functional activity studies on wild type and mutant porins: The site-directed mutants were constructed based on conserved residues and evidences on the role of certain amino acids from previous studies with OmpF. Secondary structure analysis of wild type and mutants E81Q, W74C, E81Q/D148N, E81Q/D148N/W74C by FTIR and CD spectroscopy are in line with the fact that porins are predominantly ß-sheet structure. The functional activity studies by black lipid bilayer techniques showed that the wild type and mutants W74C, E81Q/D148N, E81Q/D148N/W74C have a conductance of 3.25 nS. For mutant E81Q conductance of 1.25nS was more predominant over 3.25 nS. The activity of the mutants was observed to be far less than the wild type. This indicates that structural similarities does not implies similar functional activity. Thermal stability analysis of porin in detergent micelles and reconstituted into liposomes: Thermal stability analysis of wild type and mutants in detergent micelles showed changes in secondary and quaternary structure. It was found that wild type porin unfolds into aggregated structure with a high transition temperature of 86.2 °C. For mutants E81Q, W74C, E81Q/D148N the transition temperature was found to be 84.2 °C, 80.3 °C and 80.2 °C respectively. Functional activity assays at high temperatures revealed that the protein tends to loose its activity on heating up to 50 °C. This shows that structural stability does not imply functionality in the case of porins. Thermal stability analysis of porin reconstituted into liposomes showed that there was no change in the secondary and quaternary structure of the protein up to 100 °C, revealing that the protein becomes more thermostable when it is reconstituted into liposomes. Refolding of aggregated porin: This study shows that disaggregation of ß-sheet membrane protein porin is possible by changing its chemical and thermodynamic parameters. An increase of the solution pH to 12 or above results in opening up of the aggregated protein into unordered structure, as observed by FTIR and CD spectroscopy. This unordered structure could be refolded into native-like structure forming trimers. The secondary structure of the refolded protein deviated slightly from the native one. The thermal stability analysis of the native-like refolded proteins showed that the unfolding pattern is entirely different when compared to the native porins. pH dependent unfolding of porin: Thermal stability of porin at different pH values showed that the protein is stable in a pH range of 1-11. At pH 12 and above the protein unfolds into unordered structure instead of aggregating. The high pH unfolding of porin is a reversible process. The secondary structure of the refolded protein varied slightly from the native-one. Whereas thermal stability was entirely different. This shows that even though the unfolding of porin at high pH is reversible, it results in changes in local interaction between the amino acids resulting in a difference in stability. Unfolding in presence of urea and guanidinium hydrochloride (GuHCl): Denaturation of porin in the presence of chemical denaturants like urea and GuHCl showed that porin unfold into unordered structure. The unfolding is a reversible process. Unfolded protein was refolded into detergent micelles and liposomes. Refolding into detergent micelles was faster compared to refolding into liposomes, as seen by kinetic gel shift assays. The refolding into liposomes showed the presence of intermediates similar to those reported for OmpF. This study shows the difference in thermal stability of the outer membrane protein porin from Paracoccus denitrificans in detergent micelles and native-like liposomes. It suggests various unfolding pathways, which can be further investigated for unfolding and refolding kinetics. This report also suggests that it is possible to refold a heat-aggregated protein.
Transmembrane proteins play crucial roles in biological systems as active or passive channels and receptors. Experimentally only few structures could be determined so far. Gaining structural insights enables besides a general understanding of biological mechanisms also further processing such as in drug design. Due to the lack of experimental data, reliable theoretical predictions would be of high value. However, for the same reason, missing data, the knowledge-based class of prediction methods that is well established for soluble proteins can not be applied. The goal of predicting transmembrane protein structures with ab initio methods demands locating the free energy minimum. Main difficulties here are, first, the computational costs of explicitly calculating all involved interactions and, second, providing an algorithm that is capable of finding the minimum within an extremely complex and rugged energy landscape. We have developed promising energy functions that describe the interactions of amino acids on a residue level, reducing computational costs while still containing most information on the atomistic level. We have also found a way to describe the interaction of the residues with its surrounding in a realistic manner by distinguishing residues exposed to the environment from those buried within helices using a sphere algorithm. The sphere algorithm can also be applied for a different purpose: one can measure how densely sidechains are packed for certain helical conformations, and thereby get an estimate of the sidechain entropy. In addition, overcrowding effects can be identified which are not well-described by the energy functions due to the pairwise calculation. To determine the absolute free energy minimum, we assume the helices to be located on an equidistance grid with slightly larger distances than to be expected. Optimizing the helices on the grid provides a starting point that should enable common minimizing algorithms, gradient-based or not, to find the absolute minimum beyond the grid. To simulate the dynamics of the helices on large time scales, we split them into rigid body dynamics and internal dynamics in terms of the dihedrals. The former one is well-known with its inherent problem of numerical drift and plenty of approaches to it, among which we have chosen the quaternions to represent the rotation of the rigid bodies. The latter one requires a detailed analysis of the torque size exerted on the dihedrals caused by the forces acting on the residues.
Safety concerns associated with the use of viral vectors in gene therapy applications have attracted considerable attention towards the development of nonviral vectors as alternatives for DNA delivery. While nonviral vectors are commonly not associated with safety problems, they are still very inefficient compared to viral vectors, and require significant improvements to approach the efficiency of their viral counterparts. Meanwhile ligands or single-chain antibody fragments that bind to cell surface receptors for increased and/or specific cellular uptake, endosome escape activities, and nuclear localization sequences (NLSs) to enhance transport of plasmid DNA into the nucleus, have become available that can be incorporated into nonviral vectors to improve their efficacy. However, as gene delivery is a multistep process, the challenge is to incorporate multiple of these functional elements into a single nonviral vector system, while retaining their specific activities. A promising method to attach such entities to plasmid DNA is the use of multifunctional fusion proteins that bind to DNA through a DNA-binding domain. In principle, two types of DNA-binding domains/proteins can be used to anchor additional functional domains or peptides to a plasmid, namely sequence-specific DNA-binding domains, described in the first part of this thesis, or those that bind DNA independent of its sequence, exemplified in the second part of this work by a derivative of the human HMGB2 protein. The first fusion protein constructed and analyzed contained the E. coli LexA repressor as a sequence-specific DNA-binding domain. In addition, this DNA-carrier protein, termed TEL, included a bacterial translocation domain as an integrated endosome escape activity, and human TGF-a for specific targeting to the EGF-receptor (EGFR). TEL was expressed in E. coli and purified under both native and denaturing conditions. Purified, denatured TEL was refolded and subsequently shown to bind specifically to EGFR-expressing cells. However, inclusion of TEL in complexes of plasmid DNA and poly-L-lysine (pL) did not lead to increased gene delivery into EGFR-expressing COS-1 cells. Most likely this was due to the absence of DNA-binding activity of the LexA moiety in TEL. In contrast, native TEL was able to interact specifically with DNA. Nevertheless, since this interaction was rather weak, and refolding of denatured TEL had not resulted in functional activity of all of its protein domains, it seemed unlikely that fusion proteins containing LexA would exhibit gene transfer capabilities superior to those of similar DNA-carrier proteins previously constructed in our group. Further work therefore focused on the use of the E2C-Sp1C protein as an alternative sequencespecific DNA-binding domain. This artificial zinc-finger protein was fused to the single-chain antibody fragment scFv(FRP5), directed against the human ErbB2 growth factor receptor. The resulting 5-E2C fusion protein was expressed in E. coli and purified under native and denaturing conditions. Refolded and native 5-E2C were found to bind specifically to ErbB2-expressing cells, indicating that scFv(FRP5) in 5-E2C was functional in both preparations. In contrast, whereas refolded 5-E2C bound DNA only weakly, significant DNA binding was observed for native 5-E2C. In addition, it could not only be shown that the interaction of native 5-E2C with DNA containing its recognition sequence was specific, but also that this protein was able to bind DNA and recombinant ErbB2 simultaneously, demonstrating the functionality of both domains in native 5-E2C. Despite these encouraging results, the inclusion of native 5-E2C in pL- or polyethyleneimine (PEI)-DNA complexes did not lead to an (5-E2C-specific) enhancement of gene transfer efficiency, irrespective of the presence of the endosome-disruptive reagent chloroquine during transfection. In the second part of this thesis an alternative approach for the development of DNA-carrier proteins for nonviral gene delivery is described, based on human HMGB2, a DNA-binding protein without sequence specificity. HMGB2 contains an acidic C-terminus that has been found to decrease the affinity of the protein for DNA. Therefore, this C-terminal tail was deleted, resulting in an HMGB2-variant consisting of amino acids 1-186. HMGB2186, purified under native conditions from E. coli lysates, was able to interact with DNA and bound to the surface of different cell lines. Importantly, after binding to plasmid DNA HMGB2186 mediated gene delivery into COS-7 cells with higher efficiency than pL. In addition, HMGB2186-mediated gene transfer was strongly enhanced in the presence of chloroquine, indicating that the endocytic pathway was involved in cellular uptake. To improve internalization and intracellular routing of HMGB2186 as a DNA-carrier, a derivative containing the TAT47-57 cell-penetrating peptide (CPP), reported to facilitate cell entry independent of endocytosis, was constructed. Since this peptide also contains an NLS, in addition an HGMB2186-variant containing the SV40-NLS was constructed to investigate the effect of a peptide that has only nuclear localizing properties. Interestingly, the resulting TAT-HMGB2186 and SV40-HMGB2186 fusion proteins displayed DNA-binding activities similar to HMGB2186, but mediated gene delivery into different cell lines clearly more efficiently than the parental molecule. Furthermore, the efficacy of both fusion proteins was enhanced markedly in the presence of chloroquine, an indication that endocytosis was involved in the transfection process mediated by these proteins. This suggests that the increased transfection efficiency observed for TAT-HMGB2186 was more likely due to the NLS function present in the TAT47-57 peptide, rather than to its ‘cell penetrating properties’. Finally, the incorporation of functional peptides derived from human proteins into HMGB2186 was investigated. An uncharged CPP originating from Kaposi-FGF, reported to facilitate efficient cellular uptake of fused protein domains in an endocytosis-independent manner, was fused to HMGB2186 together with the SV40-NLS. Interestingly, the resulting KSV40-HMGB2186 fusion protein bound DNA similarly as previously tested DNA-carrier proteins, but did not mediate enhanced transfection compared to HMGB2186. In addition, the importin-b-binding (IBB) domain derived from human importin-a2 was investigated as a component of a DNA-carrier protein. Since the IBB domain can function as an NLS, it was fused to HMGB2186 resulting in the DNA-carrier protein IBBHMGB2186. Although IBB-HMGB2186 bound DNA in a similar manner as the other HMGB2186-derivatives, gene delivery mediated by IBB-HMGB2186 was only as effective as HMGB2186 mediated transfection, suggesting no significant role of the IBB domain. However, addition of chloroquine resulted in a remarkable enhancement of IBB-HMGB2186-mediated gene transfer, which was now more efficient than with any other HMGB2186-variant tested, and not much lower than gene transfer mediated by PEI, one of the most efficient transfection reagents available to date. To enhance nonviral gene delivery even further, the HMGB2186-based DNA-carrier proteins described in this thesis might now serve as building blocks for novel fusion proteins that include additional complementing activities. In this respect it seems particularly promising that, under conditions of effective end some escape, IBB-HMGB2186, which consists entirely of protein domains of human origin, was the most efficient of all proteins tested in this work.
Die 5 Lipoxygenase (5 LO) ist das Schlüsselenzym in der Synthese von Leukotrienen. Sie wird auf transkriptioneller und posttranskriptioneller Ebene reguliert. Die Differenzierung myeloider Zelllinien mit 1,25-Dihydroxyvitamin D3 (1,25(OH)2D3) und transformierendem Wachstumsfaktor beta (TGFbeta) führt zu einer Erhöhung der 5 LO mRNA-, Protein-Bildung und der zellulären Enzymaktivität. Hier wurde gezeigt, dass dabei reife, nicht jedoch prä-mRNA der 5 LO im Zytosol und im Zellkern stark angereichert wird und dass beide Agentien in die mRNA-Prozessierung eigreifen. Obwohl die Bindung von VDR-Retinoid-X-Rezeptor (RXR)-Heterodimeren an Bindungsstellen im 5 LO-Promotor mittels DNAseI-Footprinting und EMSAs nachgewiesen wurde, konnten Reportergene unter der Kontrolle des 5 LO-Promotors in transienten und stabilen Transfektionen durch 1,25(OH)2D3/TGFbeta nicht stimuliert werden. Offensichtlich wird die Induktion der Expression der 5 LO durch 1,25(OH)2D3/TGFbeta durch Elemente außerhalb des Promotors vermittelt. In transienten Transfektionen führte der Einbau der kodierenden Sequenz der 5 LO in Luziferase-Plasmide bei Cotransfektion von VDR/RXR zu einer 5 fachen Induktion der Reportergen-Aktivität durch 1,25(OH)2D3/TGFbeta, was durch zusätzlichen Einbau der letzten vier Introns auf eine 13-fache Erhöhung gesteigert wurde. Der VDR zeigte einen Ligand-unabhängigen Effekt. Diese Reportergen-Effekte waren promotorunabhängig und von der kodierenden Sequenz gesteuert. RT-PCR-Analyse wies auf eine Deletion von Teilen der kodierenden Sequenz im Laufe der mRNA-Prozessierung hin, was durch 1,25(OH)2D3/TGFbeta verhindert wird. Auch Cotransfektion der TGFbeta-Effektoren Smads 3/4 führte in Abhängigkeit von der kodierenden Sequenz und in geringerem Maße von der 3'-UTR und den Introns J M, aber unabhängig vom Promotor, zu einer starken Erhöhung der Reportergenaktivität. Die 5 LO-Expression wird in den untersuchten Zellen vermutlich durch posttranskriptionelle Prozesse (Splicing, mRNA-Reifung) herunterreguliert, während 1,25(OH)2D3/TGFbeta die Expression der 5 LO durch eine Gegenregulation zu erhöhen, an der Komplexe beteiligt sind, die vermutlich Smads, VDR-RXR-Dimere, andere Transkriptionsfaktoren, Coaktivatoren, RNA-Polymerase II und Splicing-Faktoren enthalten. Hyperacetylierung des 5 LO-Promoters durch Inkubation mit mit dem Histondeacetylase-Inhibitor TsA führte zu einer transkriptionellen Aktivierung. Die kodierende Sequenz (und die Introns) wirkt diesem Effekt vermutlich durch die Rekrutierung von HDACs an VDR oder Smads, die direkt oder indirekt an die kodierende Region binden, entgegen.
RcsB is a central transcriptional regulator in enteric bacteria involved in exopolysaccharide (EPS) biosynthesis, in cell division, in the expression of osmoregulated genes, and regulates at least 20 other genes and operons. It is a member of a phosphorelay system and signal transfer is mediated by phosphorylation through the RcsC/YojN phosphorelay. RcsB proteins modified with the phosphorylation mimic BeF3- as shown by its conformational changes and DNA binding properties and resulted phosphorylated RcsB derivatives with sufficient stability. Both, the wild type RcsB protein and the mutant RcsBD11A could be modified with BeF3-. Non-phosphorylated RcsB has been shown to bind as a heterodimer with the coinducer RcsA at the conserved RcsAB box in Rcs regulated promoters. In this study, it has been shown that the modification of RcsB by BeF3 - (I) has a negative effect on its homodimerization, (II) abolishes the complex formation of RcsAB with the RcsAB box as shown by the EMSA and SPR technique. All the effects were found to be reversible by increasing the NaF concentration in the assays presumably leading to the formation of the inactive BeF4 2- salt. This hypothesis of RcsB being modified by BeF3- was also supported by other phosphodonors like ATP and acetyl phosphate, both of them showed the same negative effect on DNA binding by RcsAB heterodimer giving evidence that BeF3- could be used as a phosphorylation mimic. In addition, the phosphorylation mimic BeF3- was found to be a better phosphorylating agent than ATP and acetyl phosphate. This is the first evidence that phosphorylation of RcsB might have a negative effect on the activation of RcsAB regulated operons. Autophosphorylation of RcsB proves that it has the ability to take up phosphoryl groups and the mutant protein also become autophosphorylated with less efficiency or stability than the wild type protein. RcsB probably takes up phosphoryl groups through RcsC -> YojN -> RcsB phosphorelay pathway. To study the interaction among the proteins in this pathway, fluorescence spectroscopy, NMR spectroscopy, and an in vivo ß galactosidase assay were performed by using two domains of RcsC (T-RcsC and R-RcsC), HPt domain of the protein YojN, and RcsB. The interactions between R-RcsC/YojN-HPt and YojN-HPt/RcsB supports the proposed pathway of phosphorylating RcsB. RcsB might also be phosphorylated by YojN-HPt that is phosphorylated by other sensor kinase other than RcsC in a cross-talk mechanism. The phosphorylation of RcsB by YojN-HPt probably has the same negative effect on cps induction as obtained with BeF3 - effect on DNA binding by RcsAB heterodimer.
The transcriptional regulator RcsB controls the expression of a minimum of 20 different genes having diverse functionalities and biosynthetic operons in the family of Enterobacteriaceae. While in the heterodimeric complex with the co activator RcsA, the RcsAB box consensus is recognized, DNA binding sites for RcsB without RcsA have also been identified. The conformation of RcsB might therefore be modulated upon interaction with various co activators, resulting in recognition of different DNA targets. In this study the interaction of RcsB with some of these DNA targets have been analysed by a diverse array of techniques including gel shift assay and SPR. The solution structure of the C-terminal DNA-binding domain of RcsB from Erwinia amylovora spanning amino acid residues 129-215 has been solved in this study by heteronuclear NMR spectroscopy. The C-terminal domain is composed of four α-helices where the two central helices of the H-T-H motif are similar to the structures of the regulatory proteins GerE, NarL and TraR. The DNA-binding activity of the C-terminal domain alone is established for the first time in this study and was specified by fluorescence spectroscopy, SPR and NMR titration experiments. The molecular interaction between the individual RcsB domains was analysed by cross-linking experiments and heteronuclear NMR spectroscopy and the amino acid residues of the C-terminal domain involved in this interaction were identified precisely. Another important part of this project was the cell-free production of different Trp analogue labelled RcsB protein. RcsB protein was produced in quite a good yield with different Trp analogue having spectrally enhanced properties. The isolated RcsB alloproteins proved to be ideal for protein interaction studies by fluorescence spectroscopy and the very first evidence of an oligomerization of RcsB due to molecular association has been put forth from these studies. The phosphorylated state of the RcsB protein was mimicked by a beryllofluoride complex in order to study its role in transcriptional regulation. It was found that RcsB alone could bind to DNA targets upon this modification by the beryllofluoride complex. Thus the phosphorylation of the protein that involves the Asp 56 residue induces a structural change of the protein followed probably by a domain movement also, so that the C-terminal domain having the H-T-H DNA binding motif that was previously eclipsed by the N-terminal domain is relieved of this constraint.
The hypothesis that oxidative stress plays a role in the pathogenesis of Alzheimer’s disease (AD) was tested by studying oxidative damage, acitvities of antioxidant enzymes and levels of reactive oxygen species (ROS) in several models. To this end, mouse models transgenic for mutant presenilin (PS1M146L) as well as mutant amyloid precursor protein (APP) and human post mortem brain tissue from sporadic AD patients and age-matched controls were studied. Aging leads to an upregulation of antioxidant enzyme activities of Cu/Zn-superoxide dismutase (Cu/Zn-SOD), glutathione peroxidase (GPx) and glutathione reductase (GR) in brains from C57BL/6J mice. Simultaneously, levels of lipid peroxidation products malondialdehyde MDA and 4-hydroxynonenal HNE were reduced. Additionally, pronounced gender effects were observed, as female mice display better protection against oxidative damage due to higher activity of GPx. Hence, antioxidant enzymes provide an important contribution to the protection against oxidative damage. In PS1M146L transgenic mice oxidative damage was only detectable in 19-22 months old mice, arguing for an additive effect of aging and the PS1 mutation. Both HNE levels in brain tissue as well as mitochondrial and cytosolic levels of ROS in splenic lymphocytes were increased in PS1M146L mice. Antioxidant defences were unaltered. In PDGF-APP and PDGF-APP/PS1 trangenic mice no changes in any of the parameters studied were observed in any age group. In contrast, Thy1-APP transgenic mice display oxidative damage as assessed by increased HNE levels. Reduced activity of Cu/Zn-SOD may explain this observation. Additionally, gender modified this effect, as female APP transgenic mice display higher b-secretase cleavage of APP and simultaneously increased HNE levels and reduced Cu/Zn-SOD activity earlier than male mice, i.e. from an age of 3 months and before the formation of Ab plaques. Reduced Cu/Zn-SOD activity was also found in another APP transgenic mouse model, in APP23 mice. In post mortem brain tissue from sporadic AD patients activities of Cu/Zn-SOD and GPx were however increased, and changes were most pronounced in temporal cortex. Simultaneously, levels of HNE but not MDA were elevated. Additionally, in vitro stimulation of lipid peroxidation led to increased MDA formation in samples from AD patients, indicating that increased activity of Cu/Zn-SOD and GPx are insufficient to protect against oxidative damage. Furthermore, the observed changes were subject to a gender effect, as samples from female AD patients showed increased activities of Cu/Zn-SOD and GPx as well as increased HNE levels, indicating that brain tissue from females is more sensitive towards oxidative damage. Levels of soluble Ab1-40 were positively correlated with with MDA levels and activities of Cu/Zn-SOD and GPx. Additionally, levels of lipid peroxidation products MDA and HNE are gene-dose-dependently modulated by the Apolipoprotein E4 allele, the most important genetic risk factor for AD known so far. While MDA levels were negatively correlated with MMSE scores, a measure for cognitive function, HNE levels were highest in AD patients with moderate cognitive impairment. Hence, increased HNE levels may play an important role in neurodegenerative events at an early disease stage. In summary, oxidative damage, as assessed by increased HNE levels, could be detected in sporadic AD patients and in different transgenic mouse models. The results of this thesis therefore support the further research of pharmacological targets aiming at augmentation of antioxidant defences for therapy or prophylaxis of Alzheimer’s disease.
Hinreichend kalte und dichte Quarkmaterie ist ein Farbsupraleiter. Ähnlich wie Elektronen in einem gewöhnlichen Supraleiter bilden Quarks Cooper-Paare. Während bei Elektronen der Austausch von Phononen zu einer Anziehung führt, ist im Falle von Quarks der Antitriplett-Kanal der starken Wechselwirkung attraktiv. Arbeiten in den letzten Jahren haben verschiedene Phasen von farbsupraleitender Quarkmaterie untersucht und sich dabei vor allem auf Phasen konzentriert, m denen der Gesamtspin eines Cooper-Paares verschwindet. In der vorliegenden Dissertation habe ich hauptsächlich Farbsupraleiter diskutiert, deren Cooper-Paare im Spin-Triplett-Kanal kondensieren, d.h. die Cooper-Paare haben den Gesamtspin 1. Diese Art von Supraleiter ist möglicherweise relevant für Systeme in der Natur, wie z.B. das Innere von Neutronensternen. Denn bei der Spin-0-Farbsupraleitung wird vorausgesetzt, dass die Fermi-Impulse zweier Quark-Flavor gleich ist oder zumindest hinreichend klein, was für realistische Systeme, also für nicht zu große Dichten, fragwürdig ist. Diese Einschränkung gibt es im Falle von Spin-1-Farbsupraleitern nicht, da hier Quarks des gleichen Flavors Cooper-Paare bilden. Ich habe in meiner Dissertation die verschiedenen möglichen Phasen eines Spin-1-Farbsupraleiters systematisch klassifiziert. Dies wurde mit Hilfe von gruppen-theoretischen Methoden durchgeführt, basierend auf der Tatsache, dass die Farbsupraleitung durch das theoretische Konzept der spontanen Symmetriebrechung beschrieben werden kann. Ähnlich wie bei supraflüssigem Helium-3 gibt es eine Vielzahl theoretisch möglicher Phasen. Ich habe die physikalischen Eigenschaften von vier dieser Phasen untersucht, nämlich der polaren und planaren Phasen sowie der A- und CSL-(color-spin-locked)Phasen. Mit Hilfe der QCD-Lückengleichung wurde die Energielücke sowie die kritische Temperatur bestimmt. Es stellt sich heraus, dass die Energielücke eines Spin-1-Farbsupraleiters um 2-3 Größenordnungen kleiner ist als die eines Spin-0-Farbsupraleiters, d.h. sie liegt im Bereich von 10 - 100 keV. Zwei besondere Eigenschaften der Energielücke werden diskutiert, nämlich eine 2-Lücken-Struktur, die in zwei der untersuchten Fälle auftritt, sowie mögliche Anisotropien, insbesondere Nullstellen der Lückenfunktion. Die Berechnung der kritischen Temperatur zeigt, dass es durchaus farbsupraleitende Materie in einer Spin-1-Phase im Innern von Neutronensternen geben kann, da die Temperatur von alten Neutronensternen im Bereich von einigen keV oder sogar darunter liegt. Darüber hinaus wurde die Frage untersucht, ob ein Farbsupraleiter auch ein gewöhnlicher Supraleiter ist. In diesem Zusammenhang ist die Frage von Interesse, ob ein Spin-1-Farbsupraleiter gewöhnliche Magnetfelder aus seinem Innern verdrängt, was sicherlich Auswirkungen auf die Observablen eines Neutronensterns hätte. Tatsächlich stellt sich heraus, dass ein Spin-1-Farbsupraleiter, im Gegensatz zu einem Spin-0-Farbsupraleiter, einen elektronmagnetischen Meissner-Effekt aufweist. Dieses Ergebnis wurde mit Hilfe von gruppentheoretischen Überlegungen vorausgesagt und mit Hilfe einer detaillierten Berechnung der Photon-Meissner-Massen bestätigt.
Taphonomy and palaeoecology of Laetoli as well as Makuyuni, Arusha region in northern Tanzania
(2004)
This thesis is the result of the Hominid Corridor research Project in Tanzania since 1993 to 1995 that include Pliocene and Pleistocene localities. The localities under study include Laetoli and Manyara area in Arusha Region, northern Tanzania. The thesis has the following specific objectives: firstly, to identify taxa recovered from the studied assemblages; secondly, to underpin taphonomic history of the assemblages under study; thirdly, to elucidate further palaeoecological reconstruction of the assemblages; and finally, to examine surface fossil fauna modifications including agents of modifications either hominids or carnivores.
The Upper Laetolil Beds are dated at 3.5 million years ago (Ma) and the Ndolanya Beds are bracketed in age between 3.5 and 2.41 Ma. The Naibadad Beds, also from Laetoli area, are date to be between 2.2 to 2.1 Ma. The Naibadad Beds are correlated with the base of Bed I at Olduvai Gorge. There are so far no absolute dates for Manyara assemblages. Based on biostratigraphic correlation, the younger overlying unit, the Upper Manyara Beds are estimated to belong to Later Pleistocene and the Lower Manyara Beds are estimated to belong to Early Pleistocene. The Upper Manyara Beds are correlated to the age of Bed III at Olduvai Gorge, while the Lower Manyara Beds are interpreted to span the same contemporaneity with the upper part of Bed II at Olduvai Gorge.
At Laetoli localities, terrestrial mammals while localities from Manyara besides terrestrial mammals dominate fauna; they include aquatic species such as fish, crocodiles and hippopotamus. The main families recovered from Upper Laetolil Beds complement those already recovered from former research works by other workers. This is also true for the younger overlying stratigraphic horizon, the Upper Ndolanya Beds. Thus, mammalian families recovered from Upper Laetolil Beds include Bovidae, Carnivora, Elephantidae, Equidae, Lagomorpha, Suidae, Rodentia, Hominoidea and Rhenocerotidae. Remains of an invertebrate, Gastropoda were also recovered. For Upper Ndolanya Beds include almost the same families recovered from Upper Laetolil Beds, but based on former recovery of fossil fauna, these Beds outnumber greatly the Upper Laetolil Beds in bovid composition by 20 per cent. Such a change in species composition is noticed also from South African localities and East African localities such as the East Turkana. This is interpreted to be due to climatic change drier environments that included species adapted to such palaeoclimates.
For the first time, our team has been able to retrieve specimens identifiable to taxa, a pattern that not possible from previous workers who claimed to have recovered too sparse specimens to be identifiable to any taxon.
The Upper Manyara Beds as well as Lower Manyara taxonomic composition include aquatic species besides the large terrestrial mammalian fauna retrieved from there. In due regard, the former horizon is attributed to have affinity with Olduvai Bed III components and the latter, older horizon, is attributed to have affinity with upper parts of Bed II times at Olduvai Gorge. The Lower Manyara Beds can be said to have, in relative terms, affinity to species recovered from site RC 11 of the Chiwondo Beds, Malema region in northern Malawi, although the former site may be equable to the terminal age of the latter locality.
Fossil hominid remains; attributable to genus Homo and possibly species Homo erectus have been recovered from two localities, Mk 2 and Mk, along Lower Manyara Beds. On the other hand, stone tools, identified to belong to the Acheulian industrial technocomplex, were recovered from site Mk 4.
All of fossil fauna from Laetoli sites were mostly exfoliated and there shows to be little effect in terms of hydrodynamic sorting of the fossil bones. However, intense carnivore activity is witnessed due to the almost one to one ratio of proximal to distal ends. This is also true for the Lower Manyara Beds locality. Through examination of surface modifications of the fossil fauna, it has been established that there was carnivore consumption of ungulates. There is no evidence of hominid involvement that has to be testified by stone tools.
The cytochrome bc1 complex is a cornerstone in bioenergetic electron transfer chains, where it carries out tasks as diverse as respiration, photosynthesis, and nitrogen fixation. This homodimeric multisubunit membrane protein has been studied extensively for several decades and the enzyme mechanism is described with the modified protonmotive Q cycle. Still, the molecular and kinetic description of the catalytic cycle is not complete and questions remain regarding the bifurcation of electron transfer at the quinol oxidation (Qo) site, substrate occupancy, pathways of proton conduction, and the nature of the Rieske protein domain movement. We used competitive inhibitors to study the molecular architecture at the Qo site with X-ray crystallography. The structure of the enzyme with the substrate analog 5-n-heptyl-6-hydroxy-4,7-dioxobenzothiazole (HHDBT) bound at the Qo site was determined at 2.5 Å resolution. Spectroscopic studies showed that HHDBT is negatively charged when bound at the active site. Mechanistic interpretations from inhibitor binding are in line with single occupancy model for quinol oxidation and structural analysis supports the proposed proton transfer pathway. For functional insight into the enzyme mechanism, redox-sensitive protonation changes were studied by Fourier transform infrared spectroscopy. The protein purification procedure was optimized for less delipidation and the isolated enzyme was more active. Furthermore, two new phospholipids were identified in the X-ray structures, including a cardiolipin. Strikingly, conserved lipid binding cavities were observed in structural comparison with homologous enzymes. The functional role of tightly bound phospholipids will be discussed. Finally, the Qo site is a target for various compounds of agricultural and pharmaceutical importance. Importantly, the X-ray structures permit detailed analysis of the molecular reasons for acquired resistance to and treatment failure of Qo site inhibitors, such as atovaquone, that is used to treat malaria and pneumonia, as discussed herein.
Nitric oxide (NO) is a potent mediator with pleiotropic functions such as inhibition of platelet aggregation, smooth muscle relaxation and regulation of neuronal transmission. These effects are mostly mediated by intracellular NO-sensitive guanylyl cyclases (GCs) which convert GTP into the second messenger, cGMP. This messenger in turn activates multiple downstream effectors such as cGMP-dependent protein kinases, cGMP-regulated ion channels and cGMPdependent phosphodiesterases. Mammalian NO-sensitive GCs are obligate heterodimers of an α and β subunit each. Given that these enzymes play a key role in cGMP-mediated pathways, one may anticipate that mechanisms other than allosteric activation via NO may exist to regulate the production and turnover of cGMP. In this thesis, novel aspects of the regulation of the most abundantly expressed GC heterodimer α1β1 are presented.
A possible mechanism of regulation that was tested here, is tyrosine phosphorylation. Using anti-phosphotyrosine antibodies, the phosphorylation of the β1 subunit was detected after incubation of β1-overexpressing COS-1 cells with protein tyrosine phosphatase (PTP) inhibitors such as pervanadate and bpV(phen). β1 phosphorylation on tyrosines was also observed in PC-12 cells which endogenously express GC and in rat aorta after inhibition of PTPs. Furthermore, hydrogen peroxide was found to be a physiological stimulus for the induction of reversible β1 tyrosine phosphorylation in intact cells. Using phenylalanine mutants of different tyrosines, residue 192 (Y192) of β1 was identified as the major phosphorylation site. Consistent with this finding, sequence analyses showed that Y192 forms part of a motif that resembles a preferential target site for Src-like kinases. When tyrosine-phosphorylated, this motif exposes a typical SH2 docking site for members of the Src kinase family.
Experiments with inhibitors of Src kinases, PP1 and PP2, clearly showed that phosphorylation of Y192 is Src-dependent. Preincubation of β1-expressing cells with these inhibitors significantly reduced the level of phosphorylated β1 after bpV(phen) treatment. Furthermore, co-expression of β1 with Src led to a strong phosphorylation of this subunit. Co-precipitation experiments showed that Src interacts with GC. Interestingly, kinases of the Src family are recruited to β1 via the SH2 domain upon phosphorylation of Y192. Together, these results indicate that Src kinases phosphorylate tyrosine 192 thereby creating a docking site for their own SH2 domains. Kinase bound to GC may then catalyze phosphorylation of GC or other downstream effectors. Inhibition of PTPs altered GC activity in two ways: it increased both the basal activity and the YC-1- and BAY 41-2272-stimulated activity two-fold, and it reduced the sensitivity of the enzyme towards NO. The detailed mechanism of action is still unknown, but experiments using the mutant β1[Y192F] demonstrated that residue 192 is not responsible for these effects.
Another major focus of this thesis was the identification of novel GC binding proteins. Using the yeast two-hybrid approach, the carboxy-terminal portion of a protein named AGAP1 (amino acid (aa) 399-804) was found to interact with the catalytic domain of α1 (aa 466-690) and with the regulatory domain of β1 (aa 1-348). Human AGAP1 is a multidomain protein of 804 amino acids with a calculated molecular mass of 89,1 kDa comprising an Arf-GAP (GAP:GTPase activating protein), a putative GTPase domain, two Ankyrin repeats and a PHdomain. Co-precipitation experiments using lysates from mammalian cells overexpressing both binding partners confirmed the interaction of AGAP1 with the GC subunits. Immunofluorescence analyses demonstrated that AGAP1 co-localizes with GC in the cytoplasm of COS-1 cells.
In Northern blots, AGAP1 mRNA was detected in various human and murine tissues showing a comparable expression pattern described for the mRNA of α1 and β1. Using an AGAP1-specific antibody, endogenous protein was precipitated from lysates of HEK-293 cells derived from human embryonic kidney. The same antibody efficiently cross-reacted with the rat homologue (rAGAP1) and immunoprecipitated endogenous rAGAP1 from lysates of PC-12 cells, aorta and heart. The molecular mass of rAGAP1 is larger than that of the human protein, possibly due to an additional exon present in the rat genome. Like β1, AGAP1 is a substrate for tyrosine kinases. Phosphorylation of AGAP1 was detected after inhibition of PTPs or by coexpression of Src. Furthermore, the kinase inhibitor PP2 strongly impaired phosphorylation of AGAP1 after pervanadate treatment suggesting that tyrosine kinases of the Src family are involved. Measurements of cGMP production showed that AGAP1 has no influence on the activity of NO-sensitive GC. Interestingly, inhibition of PTPs potently increased the complex formation between AGAP1 and GC indicating that the interaction between these two proteins is modulated by reversible tyrosine phosphorylation. Whether this effect is due to the phosphorylation of AGAP1 or GC is still unknown. AGAP1 associates with endosomes and exposes Arf-GAP activity towards Arf1 and Arf5 which are involved in vesicular transport. Thus, one may hypothesize that binding of α1β1 to AGAP1 targets GC to distinct subcellular compartments in close proximity to cGMP-dependent effectors, thereby optimizing cGMP generation and fostering cGMP-driven actions.
Taken together, these results demonstrate that beside the modulation of GC by NO the enzyme is regulated by tyrosine phosphorylation and interaction with AGAP1.
Partial melting of crustal and mantle rocks under pressure from impedance spectroscopy measurements
(2004)
The purpose of this work is to achieve a better understanding of the physical properties of rocks during partial melting processes. The electrical conductivity of some crustal and upper mantle rocks was measured prior and above the melting under pressure. The variations of the electrical conductivity were compared with the distribution of melt in partially molten rock samples. The electrical conductivity was estimated from the impedance spectroscopy at temperatures between 800 and 1450˚C and at pressures between 0.3 and 2 GPa. These measurements were performed in a piston cylinder apparatus. At temperatures above the melting, samples were equilibrated during a long time and subsequently quenched. Thin sections were prepared and topology, volume fraction and chemical composition of melt was analyzed by using a microprobe. Above the solidus temperature, the electrical conductivity increases for about 1 to 2 orders of magnitude in comparison with non-melted rocks. The "melt effect" seems to reflect the formation of an interconnected network of melt. When a complete melt connectivity is established, the charge transport follows the network of the formed melt films at grain boundaries. Usually, it takes a long time in order to reach a steady state of the electrical resistance in partially molten rocks. Only when a steady state of the electrical resistance is achieved, the bulk conductivity of a sample can be measured properly. The time-independent electrical conductivity were found only after 200 h of annealing time at a desired temperature.
Usually, the measurements of a dihedral angle on grain-liquid interfaces in rocks show that the wetting of grain faces start to develop at temperatures slightly above the solidus temperature. The development of these faces should lead to a continuous melt network even at small melt fractions of few wt.%. This result is not confirmed by our electrical conductivity measurements. The complete interconnection of the melt phase, which was mark by an increase of the electrical conductivity, corresponds to a temperature significantly above the solidus temperature, for at least 30-50˚C. The development of these faces stimulate a significant increase of the electrical conductivity, and corresponds to the occurence of at least 5 wt.% of a melt fraction. This result could be explained by deviations from the textural equilibrium of a melt phase topology in partially molten samples due to heterogeneous grain size distribution, misorientation of grains and anisotropy of the superficial energy of adjacent grain boundaries.
Some mixing models that allow to calculate the electrical conductivity of a composite as a function of a melt fraction were examined and the results of these calculations are discussed.
The experimental results were compared to the conductivity data obtained from magnetotelluric and electromagnetic measurements in the Northern part of mid-Atlantic ridge where a series of magma chambers are presumably located. There is a good agreement between our conductivity values for a melt fraction of 10-13 the conductivity estimated in the Reykjanes ridge zone.
A new experimental setup, for pump-probe fs DFWM measurements, which is based on a femtosecond laser system, has been constructed. It allows for the investigation of molecular species in the gas phase at different temperatures, from ~30 K in a seeded supersonic jet up to ~500 K in a heat-pipe oven. In comparison to other RCS methods the employed fs DFWM technique is less complicated and gives much higher signal-to-noise ratio [BFZ86, FeZ95a, CKS89, CCH90, HCF91, WRM02, Rie02]. A general computer code for the simulation of fs DFWM spectra of nonrigid asymmetric top molecules has been developed. This new DFWM code in combination with a non-linear fitting routine allows one to determine rotational and centrifugal distortion constants and obtain information on the polarizability tensor components from the experimental spectra. Fs DFWM spectroscopy was successfully applied to the medium-sized molecules benzene and benzene-d6 in a gas cell and in a supersonic jet. The spectrum from a seeded expansion has been measured up to delay time of 3.9 ns (restricted by the length of the delay stage) with excellent signal-to-noise ratio (102-103). In that way 87 and 72 J-type transients have been recorded for benzene and benzene-d6, correspondingly. A relative accuracy on the order of 10-5 has been achieved for the rotational constant. From the room temperature experiments, precise values of centrifugal distortion constants DJ and DJK have been extracted. The literature data for cyclohexane have been revised and a new precise rotational constant B0 has been obtained, which is (+5.5 MHz) shifted from the one reported in the former Raman investigation by Peters et al. [PWW73]. Additionally, high-level ab initio calculations of cyclohexane have been carried out using a large number of basis sets at several levels of theory. In particular, the vibrational averaging effects have been examined in order to critically compare the experimentally determined and theoretically evaluated rotational constants. The contribution of highly symmetric vibrational modes to vibrational averaging effects was clarified. More structural information could be obtained from fs DFWM measurements of asymmetric top species, since different type of rotational recurrences can appear, and all three rotational constants (A, B, C) can be extracted. On the other hand the analysis of the asymmetric top spectra is no longer trivial. In fact the simple formula for rotational recurrence periods of symmetric top species (Tab. 2.1) can not be applied to asymmetric top molecules. Thus, in order to extract high-resolution data for asymmetric species, a complete fitting of the experimental spectra is necessary. The fs DFWM and (1+2') PPI method have been applied to the asymmetric top molecules pyridine in the ground (S0) and pDFB in the S0 and electronically excited (S1) states. By fitting the measured fs DFWM spectra the rotational and centrifugal distortion constants have been extracted with good precision and the value of the parametrized polarizability angle of pDFB was obtained. In this work, the first application of fs DFWM spectroscopy to a molecular cluster has been reported. Also, the chemical equilibrium between monomeric and dimeric species was studied. In particular formic and acetic acid have been investigated in a gas cell and in a supersonic expansion. Many spectral features have been observed and analized in the fs DFWM spectrum of formic acid vapor in a gas cell at room temperature. Most of them were attributed to rotational recurrences of the formic acid monomer, but also spectral feature originating from the formic acid dimer of O-H×××O/O×××H-O type have been detected and analyzed. From the fitted simulation, the rotational and centrifugal distortion constants, and parametrized polarizability angle were extracted for the dimeric structure of O-H×××O/O×××HO type. With the assumption of unperturbed monomers a center-of-mass distance of R = 2.990 ± 0.001 Å for the monomers within the dimer has been calculated from the spectroscopic results. This distance is 0.028 Å smaller than that reported from electron diffraction [ABM69]. Thus, the centers-of-mass distance was assigned as the main point of disagreement between results of fs DFWM and electron diffraction experiments. In contrast to formic acid, acetic acid shows strong recurrences from dimeric species even in the fs DFWM spectra at room temperature. This is explained in terms of different symmetry of the moments-of-inertia tensor, which modulates the intensity of RRs (the fs DFWM signal is in general stronger from symmetric species). Due to the symmetric nature of the acetic acid dimer, only the sum (B+C) of the rotational constants has been extracted. The changes of geometrical parameters upon dimer formation have been analyzed for, both, formic and acetic acid. A heat-pipe oven has been used in order to overcome the main drawback of fs DFWM spectroscopy – the square dependence of the signal intensity on the sample number density. Two-ring molecules (cyclohexylbenzene, para-cyclohexylaniline and nicotine) with low vapor pressure (<0.1 mbar) at room temperature have been investigated. From the analysis of the experimental and ab-initio results for CHB and pCHA a nearly perpendicular conformation of the aromatic vs. cyclohexane ring for both system is inferred. The enlargement of the benzene ring of CHB in the electronically excited state (S1) has been found to cause the smaller rotational constants in S1. This conclusion has been drawn from the comparison of the ground and electronically excited state experimental rotational constants in combination with ab-initio calculations. The extraction of precise structural information for nicotine was not possible due to it weak fs DFWM signal. However, the fact that fs DFWM technique can be applied to conformational analysis of molecular species in an equilibrium mixture opens other applications for this kind of spectroscopy. In general the results obtained in this work show that the fs DFWM technique, being an experimental implementation of RCS, provides one with an important tool for structural analysis of molecular species in the gas phase in particular for the species to which microwave spectroscopy can not be applied. It gives spectra with excellent signal-to-noise ratio even at low number density samples expanded in a seeded supersonic jet. It provides an alternative and innovative approach towards rotational Raman spectroscopy of large polyatomic molecules applicable under various experimental conditions (broad temperature and pressure range). With the introduction of femtosecond (10-15s) laser pulses (usually picosecond (10-12s) laser pulses were used in RCS) an improvement in time-resolution and therefore in precision for the rotational constants by more than one order of magnitude has been achieved. Molecular systems in the ground electronic state without permanent dipole moment and chromophore can be studied with high precision, providing thereby molecular benchmark systems for the electronic structure theory. As has been shown, the study of molecular clusters by fs DFWM spectroscopy is possible, but its potential are restricted by the square dependence of the fs DFWM signal from the sample number density, which is even more important for supersonic jet expansions. Here, the application of near-resonant and resonant FWM schemes should help in order to compensate for the low sample concentration. With the introduction of the heat pipe oven for fs DFWM experiments, the investigation of large nonvolatile molecules under equilibrium conditions is possible now. In our laboratory the first results on the structural analysis of different conformers of pyrrolidine in the gas phase have been obtained [MaR04]. This method can have even more prospects for the structural investigations of large molecular species in combination with new non-thermal gas phase sources for nonvolatile molecules, like laser desorption [CTL89], laser oblation [MHL83], electrospray [FMM90], laser induced liquid beam ion desorption [KAB96, Sob00] etc. A very recent application of the fs DFWM technique is the investigation of the influence of strong laser fields on molecular gas phase sample, which could range from active alignment [PPB03] over molecular deformation to field ionization [CSD03]. In regards to future development in fs DFWM spectroscopy for more complex molecules one has to take into account, how large amplitude motions such as the van der Waals vibrations or internal rotation (see section 6.4.2) affect the rotational coherences. In any case, femtosecond Degenerate Four-Wave Mixing as experimental implementation of Rotational Coherence Spectroscopy can be considered as an innovative, developing, and powerful method for the structural investigation of the molecular species, which are hard to study by classical frequency-resolved spectroscopy [FeZ95a, Dan01, Rie02].
Calcium-activated potassium channels are fundamental regulators of neuron excitability. SK channels are activated by an intracellular increase of Ca++ (such as occurs during an action potential). They have a small single channel conductance (less than 20pS) and show no voltage dependence of activation. To date, there are only a few examples of high-resolution structures of eukaryotic membrane proteins. All of them were purified from natural sources. Since no abundant natural sources of eukaryotic K+ channels are available we overexpressed rSK2 in order to produce the quantities necessary for structural analysis. Unfortunately the Pichia pastoris expression system did not yield sufficient amount of pure protein, mainly because most of the protein was retained by in the ER and was only partially soluble. Subsequently, two constructs were expressed: SK2-FCYENE (containing a specific sequence that promotes surface expression), and SK2-q-CaM a concatamer of SK2 and calmodulin. Although these proved an improvement in terms of solubilisation, little improvement was found in terms of amounts of purified material obtained. For this reason we tested the Semliki Forest virus expression system, since the protein is expressed in a mammalian system where we hoped that it would be trafficked in the same way as in vivo. Using this system it was possible to express rSK2 and solubilise it with several detergents and to achieve much better purification. However, the levels were still not sufficient for high-resolution structural studies, although sufficient for single particle electron microscopy analysis.
This dissertation explores the language of three German grammar books and accompanying exercise books which are produced in Germany for international students of German. It examines how the examples and exercises presented in these books constitute ‘colony texts’ which convey different representations of human activity to the reader. Analysis of the language used in the German grammar books centres on the Linguistics of Representation and borrows techniques used normally in Corpus Linguistics. By using WordSmith Tools this study shows how particular terms (nouns, verbs, adverbs and adjectives) occur with greater frequency than others in the books under analysis thereby representing certain human activities more strongly than others. The activity of ‘work*, in particular, emerges in the grammar books as a key human activity and consequently provides the main focus for analysis in this study. Concordances relating to ‘work’ are grouped and analysed in terms of what they reveal about popular professions, workplace hierarchy and attitudes and approaches to work. Findings are considered from three perspectives: what they reveal to the researcher and learners of German about the representation of ‘work’ in the chosen context, how they compare to findings from comparative analyses of German textbooks and how they can contribute to our overall understanding of ‘text*. Grammar book examples and exercises emerge as ‘texts’ which have significant potential to reflect cultural norms and attitudes despite being considered generally as a source of innocuous and unremarkable language.