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We solved the crystal structure of a novel type of c-ring isolated from Bacillus pseudofirmus OF4 at 2.5 Å, revealing a cylinder with a tridecameric stoichiometry, a central pore, and an overall shape that is distinct from those reported thus far. Within the groove of two neighboring c-subunits, the conserved glutamate of the outer helix shares the proton with a bound water molecule which itself is coordinated by three other amino acids of outer helices. Although none of the inner helices contributes to ion binding and the glutamate has no other hydrogen bonding partner than the water oxygen, the site remains in a stable, ion-locked conformation that represents the functional state present at the c-ring/membrane interface during rotation. This structure reveals a new, third type of ion coordination in ATP synthases. It appears in the ion binding site of an alkaliphile in which it represents a finely tuned adaptation of the proton affinity during the reaction cycle. Formal Correction: This article has been formally corrected to address the following errors. 1. The images for Figures S2 and S3 were incorrectly switched. The image that appears as Figure S2 should be Figure S3, and the image that appears as Figure S3 should be Figure S2. The figure legends appear in the correct order. Please view the correct... (read formal correction) 2. The images for Figures S2 and S3 were incorrectly switched. The image that appears as Figure S2 should be Figure S3, and the image that appears as Figure S3 should be Figure S2. The figure legends appear in the correct order. Please view the correct... (read formal correction)
One of the key functions of blood vessels is to transport nutrients and oxygen to distant tissues and organs in the body. When blood supply is insufficient, new vessels form to meet the metabolic tissue demands and to re-establish cellular homeostasis. Expansion of the vascular network through sprouting angiogenesis requires the specification of ECs into leading (sprouting) tip and following (non-sprouting) stalk cells. Attracted by guidance cues tip cells dynamically extend and retract filopodia to navigate the nascent vessel sprout, whereas trailing stalk cells proliferate to form the extending vascular tube. All of these processes are under the control of environmental signals (e.g. hypoxia, metabolism) and numerous cytokines and peptide growth factors. The Dll4/Notch pathway coordinates several critical steps of angiogenic blood vessel growth. Even subtle alterations in Notch activity can profoundly influence endothelial cell behavior and blood vessel formation, yet little is known about the intrinsic regulation and dynamics of Notch signaling in endothelial cells. In addition, it remains an open question, how different growth factor signals impinging on sprouting ECs are coordinated with local environmental cues originating from nutrient-deprived, hypoxic tissue to achieve a balanced endothelial cell response. Acetylation of lysines is a critical posttranslational modification of histones, which acts as an important regulatory mechanism to control chromatin structure and gene transcription. In addition to histones, several non-histone proteins are targeted for acetylation reversible acetylation is emerging as a fundamental regulatory mechanism to control protein function, interaction and stability. Previous studies from our group identified the NAD+-dependent deacetylase SIRT1 as a key regulator of blood vessel growth controlling endothelial angiogenic responses. These studies revealed that SIRT1 is highly expressed in the vascular endothelium during blood vessel development, where it controls the angiogenic activity of endothelial cells. Moreover, in this work SIRT1 has been shown to control the activity of key regulators of cardiovascular homeostasis such as eNOS, Foxo1 and p53. The present study describes that SIRT1 antagonizes Notch signaling by deacetylating the Notch intracellular domain (NICD). We showed that loss of SIRT1 enhances DLL4-induced endothelial Notch responses as assessed by different luciferase responsive elements as well as transcriptional analysis of Notch endogenous target genes activation. Conversely, SIRT1 gain of function by overexpression of pharmacological activation decreases induction of Notch targets in response to DLL4 stimulation. We also showed that the NICD can be directly acetylated by PC AF and p300 and that SIRT1 promotes deacetylation of NICD. We have identified 14 lysines that are targeted for acetylation and their mutation abolishes the effects of SIRT1 of Notch responses. Furthermore, over-expression or activation of SIRT1 significantly reduces the levels of NICD protein. Moreover, SIRT1-mediated NICD degradation can be reversed by blockade of the proteasome suggesting a mechanism resulting from ubiquitin-mediated proteolysis. Indeed, we have shown that SIRT1 knockdown or pharmacological inhibition decreased NICD ubiquitination. We propose a novel molecular mechanism of modulation of the amplitude and duration of Notch responses in which acetylation increases NICD stability and therefore permanence at the promoters, while SIRT1, by inducing NICD degradation through its deacetylation, shortens Notch responses. In order to evaluate the physiological relevance of our findings we used different models in which the Notch functions during blood vessel formation have been extensively characterized. First, retinal angiogenesis in mice lacking SIRT1 activity shows decreased branching and reduced endothelial proliferation, similar to what happens after Notch gain of function mutations. ECs from these mice exhibit increased expression of Notch target genes. Second, these results were reproducible during intersomitic vessel growth in sirt1-deficient zebrafish. In both models, the defects could be partially rescued by inhibition of Notch activation. Third, we used an in vitro model of vessel sprouting from differentiating embryonic bodies in response to VEGF in a collagen matrix. Our results showed that Sirt1-deficient cells shows impaired sprouting which correlated with increased NICD levels. In addition, when in competition with wild-type cells in this assay, Sirt1-deficient cells are more prone to occupy the stalk cell position. Taken together, our study identifies reversible acetylation of NICD as a novel molecular mechanism to adapt the dynamics of Notch signaling and suggest that SIRT1 acts as a rheostat to fine-tune endothelial Notch responses. The NAD+-dependent feature of SIRT1 activity possibly links endothelial Notch responses to environmental cues and metabolic changes during nutrient deprivation in ischemic environments or upon other cellular stresses.
In the adult mammalian central nervous system, two defined neurogenic regions retain the capacity to generate new neurons throughout adulthood, namely the subependymal zone (SEZ) at the lateral ventricles and the subgranular layer of the hippocampus (SGL). Adult neurogenesis consists of a whole set of events including proliferation, fate specification, migration, survival and finally synaptic integration of newly born neurons. Each of these events is controlled by the interplay of numerous factors. In this study two signalling systems were analysed with regard to their functional role in adult neurogenesis in vivo, namely the purinergic system and the growth factor EGF. Neither short- nor long-term application of the P2Y receptor agonists UTP and ADPβS and the P2Y receptor antagonist suramin into the lateral ventricle of adult mice altered cell responses as compared to vehicle controls in vivo. In contrast, analysis of the expansion rates of cultured neural stem cells (NSCs) from knockout mice revealed a strong increase in the number of NSCs from NTPDase2-/- mice, whereas cell numbers of NSCs from P2Y1-/- and P2Y2-/- mice were significantly reduced in comparison to wildtype levels. Notably, in vivo proliferation rates were potently elevated in the SGL and the SEZ of NTPDase2-deficient mice. However, in vivo proliferation in both neurogenic niches of the single receptor knockout mice P2Y1-/- and P2Y2-/- and P2Y1-/- P2Y2-/-double-knockout mice did not differ significantly from the wildtype. In mice lacking the P2Y2 receptor the survival of newly born neurons in the hippocampal granule cell layer was significantly increased. These data provide the first line of evidence that purinergic signalling is involved in the control of neural stem cells behaviour not only in vitro but also in vivo. In order to further characterise the role of epidermal growth factor (EGF) in adult neurogenesis, transit amplifying precursors (TAPs) and type B astrocytes were identified as EGF-responsive cell populations following ventricular EGF injection, whereas ependymal cells, neuroblasts and NG2-positive cells did not or only to a minor extent respond to EGF injection. These EGF-responsive cell populations were found on both, the septal as well as striatal lateral ventricle walls. Long-term ventricular EGF infusion for 6d, 1. increased cell proliferation of both ventricle walls revealing a gradient along the rostro-caudal axis, 2. altered the balance between neuronal and macroglial cell fates to generate oligodendrocyte precursors and 3. lead to an entire remodelling of the classical architecture of the SEZ.
Fas Ligand (FasL; CD95L; CD178; TNSF6) is a 40 kDa glycosylated type II transmembrane protein with 279 aa in mice and 281 aa in humans that belongs to the tumor necrosis factor (TNF) family. The extracellular domain (ECD) harbors a TNF homology domain, the receptor binding site, a motif for self assembly and trimerization, and several putative N-glycosylation and a metalloprotease cleavage site/s. The cytoplasmic tail of FasL is the longest of all TNFL family members and contains several conserved signaling motifs, such as a putative tandem Casein kinase I phosphorylation site, a unique proline-rich domain (PRD) and phosphorylatable tyrosine residues (Y7 in mice; Y7, Y9, Y13 in human). The FasL/Fas system is renowned for the potent induction of apoptosis in the receptor-bearing cell and is especially important for immune system functions. It is involved in the killing of target cells by natural killer (NK) and cytotoxic T cells, in the (self) elimination of effector cells following the proliferative phase of an immune response (activation-induced cell death; AICD), in the maintenance of immuneprivileged sites and in the induction and maintenance of peripheral tolerance. Owing to its potent pro-apoptotic signaling capacity and important functions, FasL expression and activity are tightly regulated at transcriptional and posttranscriptional levels and restricted to few cell types, such as immune effector cells and cells of immune-privileged sites. In contrast, Fas is expressed in a variety of tissues including lymphoid tissues, liver, heart, kidney, pancreas, brain and ovary. In addition to its pro-apoptotic function, the FasL/Fas system can also elicit nonapoptotic signals in the receptor-expressing cell. Among others, Fas-signaling exerts co-stimulatory functions in the immune system, e.g. by promoting survival, activation and proliferation of T cells. Besides the capacity to deliver a signal into receptor-bearing cells (‘forward signal’), FasL can receive and transmit signals into the ligand-expressing cell. This phenomenon has been described for several TNF family ligands and is known as ‘reverse signaling’. The first evidence for the existence of reverse signaling into FasL-bearing cells stems from two studies that demonstrated either co-stimulation of murine CD8+ T cell lines by FasL cross-linking or inhibition of activation-induced proliferation of murine CD4+ T cells. In both cases, the observed changes of proliferative behaviour critically depended on the presence of a signaling-competent FasL. Almost certainly, the FasL ICD is functionally involved in signal-transmission: (i) The ICD is highly conserved across species and harbors several signaling motifs, most notably a unique PRD. (ii) Numerous proteins have been identified which interact with the FasL PRD via their SH3 or WW domains and regulate various aspects of FasL biology, such as FasL sorting, storage, cell surface expression and the linkage of FasL to intracellular signaling pathways. (iii) Post-translational modifications of the ICD have been implicated in the sorting of FasL to vesicles and the FasL-dependent activation of Nuclear factor of activated T cells (NFAT). (iv) Proteolytic processing of FasL liberates the ICD and allows its translocation into the nucleus where it might influence gene transcription. (v) It could be shown that overexpression of the FasL ICD is sufficient to initiate reverse signaling upon concomitant T cell receptor (TCR) stimulation and ICD cross-linking. Conflicting data on the consequences of FasL reverse signaling exist, and costimulatory as well as inhibitory functions have been reported. These discrepancies probably reflect the use of artificial experimental systems. Neither the precise molecular mechanism underlying FasL reverse signaling, nor its physiological relevance have been addressed at the endogenous protein level in vivo. Therefore, a ‘knockout/knockin’ mouse model in which wildtype FasL was replaced with a deletion mutant lacking the intracellular portion (FasL Delta Intra) was established in the group of PD Dr. Martin Zörnig. In the present study, FasL Delta Intra mice were phenotypically characterized and were employed to investigate the physiological consequences of FasL reverse signaling at the molecular and cellular level. To ensure that FasL Delta Intra mice represent a suitable model to study the consequences of FasL reverse signaling, we demonstrated that activated lymphocytes from homozygous FasL Delta Intra or wildtype mice express comparable amounts of (truncated) FasL at the cell surface. The truncated protein retains the capacity to induce apoptosis in Fas receptor-positive target cells, as co-culture assays with FasL-expressing activated lymphocytes and Fas-sensitive target cells showed. Additionally, systematic screening of unchallenged mice did not reveal any phenotypic abnormalities. Notably, signs of a lymphoproliferative autoimmune disease associated with FasL-deficiency could not be detected. As several reports have implicated FasL reverse signaling in the regulation of T cell expansion and activation, proliferation of lymphocytes isolated from FasL Delta Intra and wildtype mice in response to antigen receptor stimulation was investigated. Using CFSE dilution assays it could be demonstrated that the proliferative response of CD4+ T cells, CD8+ T cells and of B cells was enhanced in the absence of the FasL ICD. Interestingly, this effect was most pronounced in B cells and could only be detected in CD4+ T cells after depletion of CD4+CD25+ regulatory T cells. To our Summary knowledge, this is the first time that FasL reverse signaling has been demonstrated in B cells. In a series of experiments, the activation of several pathways that are known to play important roles in signal-transmission initiated upon antigen receptor triggering was assessed. As a molecular correlate for the observed enhancement of activation-induced proliferation, Extracellular signal regulated kinase (ERK1/2) phosphorylation was significantly increased in FasL Delta Intra mice following antigen receptor crosslinking. Surprisingly, B cell stimulation lead to a comparable extent of activating phosphorylations on S38 in c-Raf and S218/S222 in MEK1/2 in cells isolated from wildtype and FasL Delta Intra mice, indicating that Mitogen activated protein kinases (MAPKs) upstream of ERK1/2 (Raf-1 and MEK1/2) apparently do not contribute to the differential regulation of ERK1/2. Experiments in which activation-induced Akt phosphorylation (S473) was quantified also did not suggest a participation of Phosphoinositol specific kinase 3 (PI3K)/Akt signals in this process. Instead, further characterization of the upstream pathway revealed an involvement of Phospholipase C gamma (PLC gamma) and Protein kinase C (PKC) signals in FasL-dependent ERK1/2- regulation. Previous studies in our group revealed a Notch-like processing of FasL, resulting in the transcriptional regulation of a reporter gene. Furthermore, an interaction of the FasL ICD with the transcription factor Lymphoid-enhancer binding factor-1 (Lef-1) that affected Lef-1-dependent reporter gene transcription could be demonstrated. Therefore, a molecular analysis of activated lymphocytes was performed to identify FasL reverse signaling target genes. The differential expression of promising candidates was verified by quantitative real-time PCR (qRT-PCR), which showed that the transcription of genes associated with lymphocyte proliferation and activation was increased in FasL Delta Intra mice compared to wildtype mice. Interestingly, an extensive regulation of Lef-1-dependent Wnt/beta-Catenin signalingrelated genes was found. Lef-1 mRNA (RT-PCR) and protein (intracellular FACS staining) could be detected in mature B cells, suggesting the possibility of FasL ICD-mediated inhibition of Lef-1-dependent gene expression in these cells, initiated by Notch-like processing of FasL. To investigate the consequences of FasL reverse signaling in vivo, a potential participation of the FasL ICD in the regulation of immune responses upon various challenges was analyzed. In experiments in which thymocyte proliferation or the expansion of antigen-specific T cells following a challenge with the superantigen Staphylococcus enterotoxin B (SEB), with Lymphocytic choriomeningitis virus (LCMV) or with Listeria monocytogenes were investigated, comparable results were obtained with wildtype and FasL Delta Intra mice. Likewise, the recruitment of neutrophils in a thioglycollate-induced model of peritonitis was not affected by deletion of the FasL ICD. These findings might reflect regulatory mechanisms operating in vivo, such as control exerted by regulatory T cells. Along these lines, proliferative differences in CD4+ T cells could only be detected ex vivo after depletion of CD4+CD25+ regulatory T cells. Furthermore, several in vitro studies indicate that retrograde FasL signals can be observed under conditions of suboptimal lymphocyte stimulation, but not when the TCR is optimally stimulated. Therefore, the potent initiation of antigen receptor signaling by stimuli like SEB or LCMV might have masked inhibitory FasL reverse signaling in these experiments. In agreement with the observed hyperactivation of lymphocytes in the absence of the ICD ex vivo, the increase in germinal center B cells (GCs) following immunization with the hapten 3-hydroxy 4-nitrophenylacetyl (NP) and the number of antibody-secreting PCs was significantly higher in FasL Delta Intra mice. The larger quantity of PCs correlated with increased titers of NP-binding, i.e. antigen-specific, IgM and IgG1 antibodies in the serum of FasL Delta Intra mice after immunization. These data suggest that FasL reverse signaling exerts immunmodulatory functions. Supporting this notion, a model of Ovalbumin-induced allergic airway inflammation revealed an involvement of retrograde FasL-signals in the recruitment of immune effector cells into the lung and in the activation of T cells following exposure of mice to Ovalbumin. Together, our ex vivo and in vivo findings based on endogenous FasL protein levels demonstrate that FasL ICD-mediated reverse signaling is a negative modulator of certain immune responses. It is tempting to speculate that FasL reverse signaling might be a fine-tuning mechanism to prevent autoimmune diseases, a theory which will be tested in adequate mouse models in the future.
The TATA Box Binding Protein (TBP) is a 20 kD protein that is essential and universally conserved in eucarya and archaea. Especially among archaea, organisms can be found that live below 0°C as well as organisms that grow above 100°C. The archaeal TBPs show a high sequence identity and a similar structure consisting of α-helices and β-sheets that are arranged in a saddle-shape 2-symmetric fold. In previous studies, we have characterized the thermal stability of thermophilic and mesophilic archaeal TBPs by infrared spectroscopy and showed the correlation between the transition temperature (Tm) and the optimal growth temperature (OGT) of the respective donor organism. In this study, a “new” mutant TBP has been constructed, produced, purified and analyzed for a deeper understanding of the molecular mechanisms of thermoadaptation. The β-sheet part of the mutant consists of the TBP from Methanothermobacter thermoautotrophicus (OGT 65°C, MtTBP65) whose α-helices have been exchanged by those of Methanosarcina mazei (OGT 37°C, MmTBP37). The Hybrid-TBP irreversibly aggregates after thermal unfolding just like MmTBP37 and MtTBP65, but the Tm lies between that of MmTBP37 and MtTBP65 indicating that the interaction between the α-helical and β-sheet part of the TBP is crucial for the thermal stability. The temperature stability is probably encoded in the variable α-helices that interact with the highly conserved and DNA binding β-sheets.
The Opisthobranchia comprise highly specialized marine gastropods and have therefore been subject to diverse investigations covering various biological disciplines. However, a robust phylogeny of these gastropods is still lacking and several subclades have only been rarely studied. Furthermore, crucial aspects for the evolution of Opisthobranchia have not been comparatively analysed. Therefore, the aim of the present thesis is to gain new insights into the phylogeny of the Opisthobranchia with special focus on certain critical groups (Pleurobranchomorpha, Acteonoidea) and to assess several crucial features of the evolution of the investigated clades. The combination of four different gene markers (18S rDNA, 28S rDNA, 16S rDNA and CO1) and modern molecular systematic analysis tools were used to construct phylogenetic hypotheses focussing on Opisthobranchia as a whole as well as Pleurobranchomorpha and Acteonoidea in more detail. Intriguing new aspects of phylogeny and evolution of Opisthobranchia were revealed. First of all, monophyly of Opisthobranchia is definitely rejected based on the present data, while monophyly of Euthyneura (comprising Opisthobranchia and Pulmonata) is supported. Monophyly of opisthobranch subclades is confirmed for Nudipleura (as well as its constituting groups Nudibranchia and Pleurobranchomorpha), Umbraculida, Pteropoda (as well as subclades Thecosomata and Gymnosomata) and Acochlidiacea, for Cephalaspidea (if Runcinacea is regarded as a separate clade) and for Sacoglossa (if Cylindrobulla is accepted as an Oxynoacea). Aplysiomorpha are rendered paraphyletic due to the position of Akera bullata, but this result needs further investigation and should be considered with caution. The Nudipleura are found as the first single offshoot of the Euthyneura implying an early evolutionary separation of the last common ancestor of this clade. The remaining taxa form two main clades, one comprising the opisthobranch subgroups Umbraculida, Cephalaspidea, Aplysiomorpha and Pteropoda, while the other contains the pulmonate taxa and the opisthobranch Sacoglossa and Acochlidiacea. The interrelationships within these clades remain largely unresolved due to low statistical support values. However, a possible sister group relationship of Acochlidiacea and Eupulmonata receives statistical support. Opisthobranchia display various highly specific adaptations to diverse food sources. However, evolution of these specialized traits has never been assessed at an analytical level. The current thesis reconstructs the evolution of dietary preferences with novel methodologies based on the newly proposed phylogenetic hypothesis. Reconstruction of dietary evolution revealed herbivory as the ancestral condition in Euthyneura implying that carnivory evolved at least five times independently in the diverse lineages. The first comprehensive molecular phylogenetic hypothesis of the Pleurobranchomorpha could not reveal monophyly of the two main subclades Pleurobranchaeidae and Pleurobranchidae. This is due to the position of a single taxon (Euselenops luniceps) which is assigned to the Pleurobranchaeidae based on morphology but clusters within Pleurobranchidae in the current hypothesis. Furthermore, the tribe Berthellini and the genus Berthella are rendered paraphyletic by the current analyses. The results of molecular systematic analyses were used to reconstruct historical biogeography of Pleurobranchomorpha. Four different methodological approaches were applied yielding ambiguous results for Pleurobranchomorpha. However, the Pleurobranchidae comprising about 80% of the extant Pleurobranchomorpha most probably derived from an Antarctic origin. Dating of the phylogenetic tree via molecular clock methods yielded divergence of Pleurobranchidae into the Antarctic Tomthompsonia antarctica and the remaining species in Early Oligocene. Afterwards the latter underwent rapid radiation during Oligocene and Early Miocene. This divergence event coincides with two major geological events in the Antarctic region. On the one hand, the onset of glaciation and on the other hand the opening of the Drake Passage with concurrent formation of an Antarctic circumpolar current (ACC). I suppose that these sudden and dramatic changes in climate and palaeogeography probably accounted for migration of the last common ancestor of Pleurobranchidae (besides Tomthompsonia) into warmer regions via the Drake Passage to the Western Atlantic and Eastern Pacific and via the South Tasman Rise to the Indo-West Pacific. Furthermore, the ACC may have triggered larval dispersal to the Eastern Atlantic. The phylogenetic position of Acteonoidea has been a matter of debate for decades and they have long been considered as basal opisthobranchs. Results of the present thesis rather support placement in “Lower Heterobranchia” as sister group of Rissoelloidea. The current division of Acteonoidea into three families has never been investigated by means of phylogenetic methods. Thus, this thesis provides the first comprehensive investigation of this clade challenging present division into three families. The results rather support division into two main clades with the monogeneric Bullinidae clustering within Aplustridae doubting its separate status. Additionally, Rictaxis punctocaelatus which has been assigned to Acteonidae clusters basal to Aplustridae rendering Acteonidae paraphyletic. Since information on morphology of R. punctocaelatus was lacking until now, I conducted the first detailed investigation on morphology and histology of this species in order to reassess the unexpected molecular systematic placement. Character tracing analyses revealed similarities with both acteonoidean families implying an intermediate position of this species which might be assigned to a separate family in the future. Furthermore, the common features of Acteonidae and Rictaxis (massive shell, small foot, anterior mantle cavity opening, and absence of oral gland) are possibly plesiomorphic for the whole Acteonoidea. In summary, the results of the present thesis provide valuable novel insights into the phylogeny and evolution of the Opisthobranchia by employing state-of-the-art approaches of molecular systematics and evolutionary reconstruction. Thus, diverse hypotheses on opisthobranch phylogeny and evolution were either supported or rejected as well as novel hypotheses proposed which offer the basis for further research on these extraordinary gastropods.
The magnetic field sensors enabling birds to extract orientational information from the Earth’s magnetic field have remained enigmatic. Our previously published results from homing pigeons have made us suggest that the iron containing sensory dendrites in the inner dermal lining of the upper beak are a candidate structure for such an avian magnetometer system. Here we show that similar structures occur in two species of migratory birds (garden warbler, Sylvia borin and European robin, Erithacus rubecula) and a non-migratory bird, the domestic chicken (Gallus gallus). In all these bird species, histological data have revealed dendrites of similar shape and size, all containing iron minerals within distinct subcellular compartments of nervous terminals of the median branch of the Nervus ophthalmicus. We also used microscopic X-ray absorption spectroscopy analyses to identify the involved iron minerals to be almost completely Fe III-oxides. Magnetite (Fe II/III) may also occur in these structures, but not as a major Fe constituent. Our data suggest that this complex dendritic system in the beak is a common feature of birds, and that it may form an essential sensory basis for the evolution of at least certain types of magnetic field guided behavior.
With the help of miniaturized GPS recorders I recorded 167 tracks of 48 individual pigeons during their flight from 6 different sites around Frankfurt. The experiments consisted of two main series of repeated releases from two sites 30 km north and south from the pigeons' home loft. From the site in the south the pigeons homed 12 times and from the site in the north 16 times. After the final release from these sites, the pigeons were released at 60 km distance from home. These additional sites were selected so that the pigeons would presumably fly over the previous release site with which they were highly familiar. After conclusion of the main series two additional releases were performed, one within the magnetic anomaly of the Vogelsberg and one in a magnetically quiet region. To make these releases comparable, both release sites were selected so that the distance from the home loft was 40 km. All data obtained during these experiments were subjected to a threefold analysis, mostly based on methods that I had developed by myself or adapted for this specific study. In the first step, data were analyzed traditionally, evaluating variables similar to those that can be found in current literature. I therefore calculated values that correspond to those obtained by visual observation, like virtual vanishing bearings and intervals after one minute and after 2.5 km. Additionally I calculated the efficiency of the flights and efficiencies for specific portions of each flight, to derive variables that describe the behavior after vanishing. In the second step, which served also as a preparation for the mathematical analysis, the flight of the pigeons was separated into distinctive phases of the flight by the so-called points of decision. The flight of the pigeon can usually be separated into an initial phase of flying about, a departure and/or final homing phase. In more complex cases, however, several points of decision and a multitude of intermediary phases can be defined. Yet, the initial phase, the departure phase and the final homing phase can be defined for all tracks and therefore have been selected as appropriate candidates for a thorough analysis. In the last step I employed the so-called method of time lag embedding to reconstruct the underlying navigational process of the pigeons' homing flight. This method is based on the principles of chaos theory and is regularly employed for the analysis of dynamic systems. Its application allows the reconstruction of the underlying processes from experimentally recorded data without any a priori knowledge of the underlying system itself. For these reconstructed systems I calculated characteristic properties which are unique for each system. These are the so-called correlation dimension, describing the complexity of the system, and the so-called largest Lyapunov exponent, describing its predictability. Based on the knowledge gathered from these reconstructions, I used a variation of the previous methods to identify navigational phases, by calculating the correlation dimension as a sliding mean over the complete track. From these data I then derived further characteristics of the underlying process, such as its precision and differences in complexity depending on the pigeon's current position. ...
Fucoxanthin chlorophyll proteins (Fcps), the light-harvesting antennas of heterokont algae, are encoded by a multigene family and are highly similar with respect to their molecular masses as well as to their pigmentation, making it difficult to purify single Fcps. In this study, a hexa-histidine tag was genetically added to the C-terminus of the FcpA protein of the pennate diatom Phaeodactylum tricornutum. A transgenic strain expressing the recombinant His-tagged FcpA protein in addition to the endogenous wild type Fcps was created. This strategy allowed, for the first time, the purification of a specific, stable trimeric Fcp complex. In addition, a pool of various trimeric Fcps was also purified from the wild-type cells using sucrose density gradient ultracentrifugation and gel filtration. In both the His-tagged and the wild-type Fcps, excitation energy coupling between fucoxanthin and chlorophyll a was intact and the existence of a chlorophyll a/fucoxanthin excitonic dimer was demonstrated using circular dichroism spectroscopy. Mass spectrometric analyses of the trimeric His-tagged complex indicated that it is composed of FcpA and FcpE polypeptides. It is confirmed here that a trimer is the basic organizational unit of Fcps in P. tricornutum. From circular dichroism spectra, it is proposed that the organization of the pigments on the polypeptide backbone of Fcps is a conserved feature in the case of chlorophyll a/c containing algae.