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Global warming is expected to be associated with diverse changes in freshwater habitats in north-western Europe. Increasing evaporation, lower oxygen concentration due to increased water temperature and changes in precipitation pattern are likely to affect the survival ratio and reproduction rate of freshwater gastropods (Pulmonata, Basommatophora). This work is a comprehensive analyse of the climatic factors influencing their ranges both in the past and in the near future. A macroecological approach showed that for a great proportion of genera the ranges were projected to contract by 2080, even if unlimited dispersal was assumed. The forecasted warming in the cooler northern ranges predicted the emergence of new suitable areas, but also reduced drastically the available habitat in the southern part of the studied region. In order to better understand the ranges dynamics in the past and the post glacial colonisation patterns, an approach combining ecological niche modelling and phylogeography was used for two model species, Radix balthica and Ancylus fluviatilis. Phylogeographic model selection on a COI mtDNA dataset confirmed that R. balthica most likely spread from two central European disjunct refuges after the last glacial maximum. The phylogeographic analysis of A. fluviatilis, using 16S and COI mtDNA datasets, also inferred central European refugia. The absence of niche conservatism (adaptive potential) inferred for A. fluviatilis puts a cautionary note on the use of climate envelope models to predict the future ranges of this species. However, the other model species exhibited strong niche conservatism, which allow putting confidence into such predictions. A profound faunal shift will take place in Central Europe within the next century, either permitting the establishment of species currently living south of the studied region or the proliferation of organisms relying on the same food resources. This study points out the need for further investigations on the dispersal modes of freshwaters snails, since the future range size of the species depend on their ability to establish in newly available habitats. Likewise, the mixed mating system of these organisms gives them the possibility to fund a new population from a single individual. It will probably affect the colonisation success and needs further investigation.
This study focuses on structural features of a particular GPCR type, the family C GPCRs. Structure- and ligand-based approaches were adopted for prediction of novel mGluR5 binding ligand and their binding modes. The objectives of this study were: 1. An analysis of function and structural implication of amino acids in the TM region of family C GPCRs. 2. The prediction of the TM domain structure of mGluR5. 3. The discovery of novel selective allosteric modulators of mGluR5 by virtual screening. 4. The prediction of a ligand binding mode for the allosteric binding site in mGluR5. GPCRs are a super-family of structurally related proteins although their primary amino acid sequence can be diverse. Using sequence information a conservation analysis of family C GPCRs should be applied to reveal characteristic differences and similarities with respect function, folding and ligand binding. Using experimental data and conservation analysis the allosteric binding site of mGluR5 should be characterized regarding NAM and PAM and selective ligand binding. For further evaluation experimental knowledge about family A GPCRs as well as conservation between vertebrate rhodopsins was planned to be compared to results obtained for family C GPCRs (Section 4.1 Conservation analysis of family C GPCRs). Since no receptor structure is available for any family C GPCR, discussion of conserved sequence positions between family A and C GPCRs requires the prediction of a receptor structure for mGluR5 using a family A receptor as template. In order to predict the mGluR5 structure a sequence alignment to a GPCR template protein will have to be proposed and GPCR specific features considered in structure calculation (Section 4.1.4 Structure prediction of mGluR5). The obtained structure was intended to be involved in ligand binding mode prediction of newly discovered active molecules. For discovery of novel selective mGluR modulators several ligand-based virtual screening protocols were adapted and evaluated. Prediction models were derived for selection of possibly active molecules using a diverse collection of known mGluR binding ligands. For that purpose a data collection of known mGluR binding ligands should be established and this reference collection analyzed with respect to different ligand activity classes, NAM or PAM and selective modulators. The prediction of novel NAMs and PAMs using several combinations of 2D-, 3D-, pharmacophore or molecule shape encoding methods with machine learning techniques and similarity determining methods should be tested in a prospective manner (Section 4.2 Virtual screening for novel mGluR modulators). In collaboration with Merz Pharmaceuticals (Merz GmbH & Co. KGaA, Frankfurt am Main, Germany) the modulating effect of a few hundred molecules should be approved in a functional cell-based assay. With the objective to predict a binding mode of the discovered active molecules, molecule docking should be applied using the allosteric binding site of the modeled mGluR5 structure (Section 4.2.4 Modeling of binding modes). Predicted ligand binding modes are to be correlated to conservation profiles that had resulted from the sequence-based entropy analysis and information from mutation experiments, and shall be compared to known ligand binding poses from crystal structures of family A GPCRs.
Many questions regarding gastropod phylogeny have not yet been answered like the molecular confirmation of the Heterobranchia concept based on morphological studies from Haszprunar (1985a; 1988). This taxon contains the “Lower Heterobranchia” with several “primitive” or “basal” members) and the Euthyneura (with the Opisthobranchia and Pulmonata). Phylogenetic relationships of subgroups within the Heterobranchia have not been satisfactorily resolved and monophyly of some taxa within the Heterobranchia (e.g. Opisthobranchia) is questionable. Moreover, most of the “Lower Heterobranchia” have not been included in former molecular studies. In order to resolve phylogenetic relationships within the Heterobranchia, I pursued a molecular systematic approach by sequencing and analysing a variety of genetic markers (including nuclear 28S rDNA + 18S rDNA and mitochondrial 16S rDNA + COI sequences). Maximum likelihood as well as Bayesian inference methods were used for phylogenetic reconstruction. The data were investigated a priori to tree reconstruction in order to find the most appropriate dataset for reconstructing heterobranch phylogeny. A variety of statistical tests (like Chi-Square-Test or Relative-Rate-Test) were applied and the substitution saturation was measured. The Relative-Rate-Test revealed the highest evolution rates within the “Lower Heterobranchia” (Omalogyra sp., Omalogyra fusca, Murchisonella sp., Ebala sp. and Architectonica perspectiva) and Opisthobranchia (Hyalocylis striata). Furthermore, many of the nucleotide positions show a high degree of substitution saturation. Additionally, bipartitions (splits) in the alignment were examined and visualized by split network analyses to estimate data quality. A high level of conflict indicated by many parallel edges of the same lengths could be observed in the neighbournet graphs. Moreover, several taxa with long terminal branches could be identified in all three datasets belonging to the Vetigastropoda, Caenogastropoda, “Lower Heterobranchia” or Opisthobranchia (Nudipleura). All phylogenetic analyses revealed a monophyletic Heterobranchia. Within the Heterobranchia several well supported clades could be resolved. However, the traditional classification based on morphological data could not be confirmed due to paraphyletic Euthyneura (because of the inclusion of the Pyramidellidae and Glacidorboidea) as well as paraphyletic Pulmonata and polyphyletic Opisthobranchia. Based on the phylogenetic inferred evolutionary trends regarding habitat colonisation or character complexes could be deduced. A case study was conducted in order to estimate divergence ages using a “relaxed” molecular clock approach with fossils as minimum age constraints. However, due to large 95% confidence intervals a precise dating of the nodes was not possible. Hence, the results are considered as preliminary. To test the plausibility of the newly obtained hypotheses, the results were evaluated a posteriori using a hypothesis test and secondary structures of the complete 18S rRNA and 28S rRNA. Secondary structure motifs were found within domain 43 and E23 2 &5 of the 18S rRNA as well as within domain E11 and G5_1 of the 28S rRNA, which contain phylogenetic signals to support various groups within the Heterobranchia. In addition, taxon specific motifs were found separating the Vetigastropoda from the Caenogastropoda and Heterobranchia, indicating a possible application of the secondary structure of 18S rRNA and 28S rRNA to reveal phylogenetic relationships at higher taxonomic levels such as Gastropoda or even Mollusca. The utility of the newly invented software RNAsalsa for the reconstruction of secondary structures was tested. The obtained structures were used to adjust evolutionary models specific to rRNA stem (paired basepairs) and loop (unpaired basepairs) regions with the intention of improving phylogenetic results. This approach proved unsuccessful. This molecular phylogenetic investigation provides the most comprehensive molecular study of Heterobranchia relationships to date. Substantial insights into the evolution and phylogeny of this enigmatic taxon have been gained.
Very little is known about the occlusal wear pattern in the Neanderthal posterior dentition. Usually dental wear is closely related to the physical properties of the ingested food, and consequently can be used to obtain information about diet. Neanderthal dietary reconstructions have been mostly based on the analysis of accompanying faunal remains and isotopic signatures of bones and tooth enamel, suggesting that they exploited larger portions of animal proteins from large and medium-sized herbivores. Probably these studies may do not reflect the bulk diet, tending to underestimate plant consumption and to overestimate meat consumption. In the present work the occlusal wear pattern of maxillary molars of Homo neanderthalensis (N=19) and early Homo sapiens (N=12)have been analyzed, applying non-destructive methods based on virtual three-dimensional polygonal models generated from surface scanning of dental casts. The sample groups occupied different geographical areas at different chronological times. The 3D digital tooth models were analyzed using the “Occlusal Fingerprint Analysis” (OFA) method (Kullmer et al. 2009), describing and quantifying the occlusal wear pattern derived from two wear facet angles (dip and dip direction), wear facet area and occlusal relief index (ORI). The OFA method provides information about the dynamics of the occlusal relationships and their function, permitting the reconstruction of the mandibular movements responsible for the contacts created during the chewing cycle. Since jaw movements and diet are closely related, the results obtained, can be used to interpret the diet of the two Pleistocene hominin species. In order to evaluate how dietary differences influence the occlusal wear pattern, upper molars of modern hunter-gatherers (N=42) with known diet and different dietary habits, have been included in the sample and compared with those of Neanderthals and early Homo sapiens. Results show that within the modern hunter-gatherers sample, the occlusal wear pattern of carnivorous populations differs from those who relied on a mixed-diet. In particular, the study of relative facet areas clearly distinguish meat-eaters from mixed-diet hunter-gatherers, while ORI results and wear facet inclinations (dip angle) seem to reflect directly the abrasiveness of the diet, including the influence of exogenous materials during food preparation. The Neanderthal occlusal wear pattern is characterized by an ecogeographic variation, suggesting the exploitation of different food resources. In particular Neanderthals who inhabited relatively warm environments of southern Europe and the Near East exhibit an occlusal wear pattern different from those of meat-eaters hunter-gatherers from tempered and cooler regions, displaying some features similar to those of Bushmen. These results suggest the exploitation of a broad variety of food sources. The analysis of the occlusal wear pattern in Neanderthals and early Homo sapiens who inhabited Europe during the cooler Oxygen Isotope Stage 3 (OIS3) shows many similarities between the two hominid species. These results indicate the exploitation of similar and low-diversified food sources, based mostly on the consumption of animal proteins, as suggested through the clear similarities with the wear patterns found in modern meat-eaters hunter-gatherers. In both studied groups, Neanderthals and early Homo sapiens the occlusal wear pattern is characterized by high ORI and dip angle values, suggesting the intake of a low-abrasive diet, probably due to the absence of sophisticated food preparation techniques introducing external silica grains, e.g. from soil (grinding of seeds) or plant cells, as those, seen in modern hunter-gatherer populations. The analysis of the occlusal fingerprints in Neanderthal and early European Homo sapiens upper molars suggests that both species followed very similar adaptive dietary strategies, based on a distinctive versatility and flexibility in the daily diet, depending on availability of resources according to environmental circumstances.
Through the use of information about the biological target structure, the optimization of potential drugs can be improved. In this work I have developed a procedure that uses the quantitative change in the chemical perturbations (CSP) in the protein from NMR experiments for driving protein-ligand docking. The approach is based on a hybrid scoring function (QCSPScore) which combines traditional DrugScore potentials, which describe the interaction between protein and ligand, with Kendall’s rank correlation coefficient, which evaluates docking poses in terms of their agreement with experimental CSP. Prediction of the CSP for a specific ligand pose is done efficiently with an empirical model, taking into account only ring current effects. QCSPScore has been implemented in the AutoDock software package. Compared to previous methods, this approach shows that the use of rank correlation coefficient is robust to outliers. In addition, the prediction of native-like complex geometries improved because the CSP are already being used during the docking process, and not only in a post-filtering setting for generated docking poses. Since the experimental information is guaranteed to be quantitatively used, CSP effectively contribute to align the ligand in the binding pocket. The first step in the development of QCSPScore was the analysis of 70 protein-ligand complexes for which reference CSP were computed. The success rate in the docking increased from 71% without involvement of CSP to 100% if CSP were considered at the highest weighting scheme. In a second step QCSPScore was used in re-docking three test cases, for which reference experimental CSP data was available. Without CSP, i.e. in the use of conventional DrugScore potentials, none of the three test cases could be successfully re-docked. The integration of CSP with the same weighting factor as described above resulted in all three cases successfully re-docked. For two of the three complexes, native-like solutions were only produced if CSP were considered.Conformational changes in the binding pockets of up to 2 Å RMSD did not affect the success of the docking. QCSPScore will be particularly interesting in difficult protein-ligand complexes. They are in particular those cases in which the shape of the binding pocket does not provide sufficient steric restraints such as in flat protein-protein interfaces and in the virtual screening of small chemical fragments.
Plant parasitic species of Asterinaceae and Microthyriaceae (Dothideomycetes, Ascomycota, Fungi) are inconspicuous foliicolous fungi with a mainly tropical distribution. They form black colonies on the surface of living leaves. Members of Asterinaceae and Microthyriaceae are characterized by shield-shaped, flat ascomata (thyriothecia) which grow completely superficially on the leaf cuticle. Microthyriaceae, Asterinaceae and other families of thyriothecia-forming ascomycetes belong to the class Dothideomycetes due to the presence of bitunicate asci. However, until today no consistent taxonomic concept nor molecular phylogenetic studies exist for the families of thyriothecioid ascomycetes. In the present thesis, 42 species belonging to 13 different anamorphic and teleomorphic genera of Asterinaceae, Microthyriaceae and ‘Pycnothyriales’ recently collected in Western Panama, are identified, described in detail and illustrated with drawings, transmission and scanning electron microscopical photographs. Among the 42 species, 37 species belong to the Asterinaceae, four species to the Microthyriaceae and one species to the from group ‘Pycnothyriales’. Two species of Asterinaceae are new to sience: Asterina gaiadendricola with an Asterostomella anamorph and Asterina schlegeliae with a Mahanteshamyces anamorph. Among the remaining species of Asterinaceae, 28 species represent new records for Panama: Asterina cestricola, A. ciferriana, A. consobrina, A. corallopoda, A. davillae with anamorph, A. diplocarpa, A. diplopoda, A. ekmanii, A. fuchsiae, A. manihotis, A. phenacis, A. radiofissilis with anamorph, A. siphocampyli, A. sponiae, A. stipitipodia with anamorph, A. styracina, A. tonduzii with anamorph, A. weinmanniae, A. zanthoxyli, Asterostomella dilleniicola, Asterolibertia licaniicola, Asterolibertia nodulosa, Cirsosia splendida with its Homalopeltis chrysobalani anamorph and Prillieuxina winteriana with its Leprieurina winteriana anamorph. The remaining 11 species of Asterinaceae probably respresent new species: Asterina spp. 1-8, Asterolibertia sp., Halbanina sp. and Mahanteshamyces sp. The four species of Microthyriaceae are new records for Panama: Maublanica uleana, Platypeltella irregularis, Platypeltella smilacis and Xenostomella tovarensis. The species Hemisphaeropsis magnoliae in the form group ‘Pycnothyriales’ is a new record for Panama. During this study, voucher material of 44 additional species of plant parasitic thyriothecioid ascomycetes was examined. Thereby, the number of species of Asterinaceae known for Panama since 2006 raises from four to 30, for Microthyriaceae respectively from zero to four and for ‘Pycnothyriales’ from zero to one. 21 of the presented species are new records for Central America and two species are new records for the American Continent. The presented 42 species parasitize 47 host plant species in 39 genera belonging to 28 plant families. For 23 fungal species, new host plant species are discovered. From those, seven belong to host plant genera not reported before to be parasitized by a member of Asterinaceae and Microthyriaceae: Burmeistera (Campanulaceae), Curatella and Davilla (Dilleniaceae), Greigia (Bromeliaceae), Hirtella (Chrysobalanaceae), Oxandra and Xylopia (Annonaceae). In this study, the first molecular phylogenetic approach in Asterinaceae is provided. For the first time, DNA was isolated from fresh material of Asterina spp. and their respective anamorphic stages on leaves in Panama. The hypothesis derived from SSU and LSU rDNA neighbour-joining analysis supports the monophyly of the Asterinaceae and suggests a close relationship to Venturiaceae within the class Dothideomycetes. The data obtained from the ppMP project (plant parasitic microfungi of Panama) indicate a constant but low abundance of plant parasitic thyriothecioid ascomycetes in natural plant communities in Panama, with Asterinaceae as the most species-rich and diverse family. Further collection activities in tropical regions worldwide will certainly increase our knowledge about species diversity and ecology of tropical plant parasitic thyriothecioid ascomycetes.
The documentation of life on Earth, that is, the inventorization of nature and the naming and classification of organisms found therein, is a major task for biologists today and a fundamental precondition for nature conservation efforts. This study aimed at contributing to the inventory of amphibians and reptiles in selected, previously understudied ecoregions of Bolivia. I strove to document diversity patterns and seek possible ecological and historical reasons for these patterns. Special attention was paid to the Chiquitano Region situated in the eastern lowlands of Bolivia in a climatic transition zone between the humid evergreen Amazon Forests and the deciduous thorn-scrub vegetation of the Gran Chaco. In congruence with its location in the transition zone, the Chiquitano Region displays a mosaic of habitats: The vegetation is dominated by the endemic Chiquitano Dry Forest, which is probably the largest extant patch of Seasonal Dry Tropical Forest, with enclaves of savanna, the western outliers of the Cerrado biome of central Brazil. Taxonomic revisions: The taxonomic data in this study are used as a tool to measure biodiversity, to assess biogeographic relationships, and to evaluate conservation needs. Since all is predicated on the taxonomic decisions made, an adequate taxonomy is essential, and taxonomy can be regarded as the foundation of this study. The methodology encompassed a variety of herpetological field techniques, such as different survey methods, preparation and documentation of voucher specimens, recording of frog calls, and herpetological laboratory techniques, such as morphology, molecular procedures with mtDNA, phylogenetic analyses, and bioacoustic analysis and descriptions of frog calls. A total of 1251 specimens belonging to 200 species were obtained during this study, including 87 amphibian and 123 reptile species. This constitutes about 36% of the herpetofauna currently known for Bolivia, about 34% of the amphibians currently known for Bolivia and about 40% of the reptiles, respectively. In the course of this study, a new species of frog was described from the study site Caparu in the eastern lowlands of Bolivia; this species, Hydrolaetare caparu Jansen, Gonzales & G. Köhler 2007, differs from the other two congeners in external morphology (e.g., lateral fringes and relative length of fingers, size of palmar tubercle, webbing of toes, and colouration) and advertisement call. Two new colubrid snake species were also described from the study site San Sebastián. Thus far, both are known only from the Chiquitano Region, Provincia Ñuflo de Chávez. Phalotris sansebastiani Jansen & G. Köhler 2008 differs from all the other species in the genus in having a triangular projection of the red snout colouration reaching onto the parietals. Xenopholis werdingorum Jansen, Gonzales & G. Köhler 2009 can be identified as a member of the genus Xenopholis by its vertebral morphology. It differs from the other two species of Xenopholis in having a unique uniform dorsal colour pattern, and from X. scalaris in having two prefrontals and a narrow septum within the neural spine and perpendicular to its long axis as evident in the x-ray images. A review of a small collection of pitvipers from different lowland localities and from the Inter-Andean dry valleys of the region of Pampagrande revealed one new species of Bothrops and one of Bothrocophias (both to be formally described elsewhere). The two pitviper species differ morphologically and genetically from their congeners. The results of a brief review of a small collection of frogs of the genus Scinax (Anura: Hylidae) from different localities in the lowlands, together with analyses of their bioacoustics, suggest an unknown cryptic diversity in Bolivian species of Scinax cf. fuscomarginatus and allies. However, further studies are necessary to clarify the taxonomic status of these populations. In addition, this study provides new data on the morphology (e.g., pholidosis) of snakes, many of them previously known only from few museum specimens. Keys to the Bolivian lizard species of Cercosaura and the Bolivian snake species of Chironius, Clelia, Liophis, Lystrophis, Phalotris, and Xenodon are presented here for the first time. New information on distribution includes many range extensions of amphibian and reptile species, such as five new country records (one frog species, four snake species) and six new departmental records (two frog species, four snake species). Observations on ecology and natural history: Several observations on ecology and natural history were made during field work. Visual signaling, an aspect of territorial behavior that was already known for several species of the genus Phyllomedusa, could be described for the first time for Phyllomedusa boliviana (Jansen & J. Köhler 2007). Furthermore, during audio surveys of an anuran community at the study site San Sebastián from 2005 to 2007, a decline of certain amphibian populations was observed in the rainy season 2006/2007 (Jansen et al., in press). This is possibly related to an extreme drought in the dry season of 2006 where 158 consecutive days without rainfall were recorded. In addition, a new method for measuring intensity of anuran choruses by means of a continuous sound pressure metre was developed (Jansen 2009). The method was suitable to detect calling phenology (during one night), as well as differences in calling activity (between two nights). Biodiversity and biogeographical relationships: Species lists were compiled at the six study sites Pampagrande, Los Volcanes, San Sebastián, Caparú, El Espinal und El Corbalan. The total amphibian and reptile species numbers observed ranged from 37 to 101 with the highest species numbers in San Sebastián (101) and Caparú (89) and the lowest in Los Volcanes (37) and El Espinal (41). A preliminary species list of the herpetofauna of the Chiquitano Region was presented, including 60 amphibian and 84 reptile species. The majority of the amphibians of the Chiquitano Region are classified predominantly as inhabitants of open formations (41 species, 68.3%). Interestingly, even the majority of species recorded from the Chiquitano Dry Forest (32 species) are usually associated with open formations (22 species, 66.7%), followed by the number of species associated with open and forest formations (8 species, 24.4%). Only two of the observed species (6.0%) are predominant forest dwellers. The amphibian assemblage of the Chiquitano Region is most similar in composition to that of the Cerrado biome: 46 species (76.7%) occur in the Cerrado as well, and three species are regarded as Cerrado endemics (5.0%). The Chiquitano Region shares considerably fewer amphibian species with the other biomes (Amazon: 22 species, 36.7%; Gran Chaco: 13 species, 21.7%; Caatinga: 16 species, 26.7%). The reptile assemblage also has significant affinities to the Cerrado, which can be seen in the high proportion of reptile species distributed in that biome (68 species; 81.0%). Affinities to the other biomes are as follows: Amazon (48 species, 57.1%), Chaco (37 species, 40.1%), and Caatinga (30 species, 35.7%). When arranged in mutually exclusive biome categories, reptiles and amphibians showed similar patterns so that the majority of both amphibians and reptiles of the Chiquitano Region can be regarded as widespread. The high proportion of reptile species probably endemic to this region (5 species, 6.0%) is remarkable (i.e. Tropidurus xanthochilus, Apostolepis phillipsi, Phalotris sansebastiani, Xenopholis werdingorum, and Micrurus diana). In an analysis of the biodiversity patterns and biogeographical relationships of the herpetofauna of the study sites, these sites were compared with literature data from 37 localities and included in a presence/absence matrix with a total of 657 amphibian and reptile species in the surrounding South American biomes Amazon, Cerrado and Gran Chaco. The biogeographic relationships between these sites were evaluated using the Coefficient of Biogeographic Resemblance (CBR), cluster analysis, and multidimensional scaling (MDS) of sites. The analyses were first conducted on amphibians and reptiles combined, and than group-specific each for amphibians, reptiles, lizards, and snakes, separately. A “bias-reduced analysis” was developed for a better understanding of the affinities of the amphibians. In this analysis, e.g., the distinct habitat types of the Chiquitano Region, the Chiquitano Dry Forest and the Cerrado were taken into account. Analyses of the biodiversity patterns revealed that the sites in the Amazon comprise highest species numbers, as expected, followed successively by the sites in the Cerrado biome and sites in-between the two biomes. Within the eastern lowlands of Bolivia, the Chiquitano Region is the most rich in species. Comparing it with the other South American sites, the Chiquitano Region has a surprisingly high alpha diversity, especially in amphibians. The microgeographic variation in species composition (beta diversity) in the Chiquitano Region is also remarkably high and obviously related to the mosaic character of the vegetation and habitats. However, the bias-reduced analysis revealed that the amphibian fauna of the open areas and savannas at Hacienda San Sebastián (with 36 species in the Cerrado and pastureland) was one of the most species-rich savanna sites known for amphibians in South America. Considering that the Hacienda San Sebastián site is only ca. 3300 ha (= 1.29 amphibian species per km2), this outcome is particularly suprising. The results of the analyses of the biogeographical relationships suggest that the herpetofauna of Bolivia’s lowlands, including the Beni, the Pantanal and the Chiquitano Region, is as distinct from the herpetofauna of the Gran Chaco, Amazon, and Cerrado as these biomes are from each other. The Chiquitano herpetofauna in particular represents a unique and well-defined herpetofaunal assemblage when compared to all surrounding localities and biomes. This is supported by high CBR-values, findings from the cluster analysis, as well as a clear separation of the Chiquitano sites in the MDS. Biogeographic relations exist in all the surrounding biomes, but are strongest to Cerrado, followed by the Amazon. This study strongly suggests that the Chiquitano herpetofauna is composite and has multiple affinities. This is congruent with a well-defined Chiquitano flora, avifauna and mammalian fauna, suggesting a similar history. The bias-reduced analysis revealed a more detailed picture of the biogeographic relations of the Chiquitano Region, especially the Chiquitano Dry Forest. I argue here that the Chiquitano Dry Forest herpetofauna is a “young”, and “former savanna herpetofauna”. Whereas the Chiquitano Dry Forest is rather poor in amphibian and reptile species, and endemics are lacking from this forest type, the isolated Cerrado enclaves are especially diverse in species and probably contain locally endemic species, such as Phalotris sansebastiani and Xenopholis werdingorum. The colonization of the young Chiquitano Dry Forest may have taken place from savannas by mainly open area species, and only briefly through the Amazon. The results emphasise the importance of bias-reduction in studies of biogeography, e.g., by using group-specific analyses or by taking into account criterias as area size and heterogeneity of compared sites. The different biogeographic patterns of reptiles and amphibians of the Andean valleys indicate a different history of these two groups. In regard to reptiles, dispersals and withdrawals into the valleys in warm humid and dry cool periods in the Pleistocene seem likely, supported by a relation between the valleys and the dry lowland (e.g., Chaco). However, it is more plausible that, during these climatic fluctuations, amphibians migrated to adjacent, more humid regions, such as Yungas. The study verified the known patterns of sister-species pairs in the Inter-Andean Dry Forest and the lowlands. Additionally, pairs of populations with slight differences in morphology were found in the valleys and in the lowlands (Cercosaura parkeri and Xenodon rhapdocephalus). Further studies must test the taxonomic status of these populations. The discovery of new species of Bothrops and Bothrocophias from the Andean valleys has several implications, and possible reasons for the high endemism in the dry valleys are discussed. Conservation and outlook: The high local alpha and beta diversity of the Chiquitano herpetofauna shows that this is a region of complex faunal interaction, which reflects the present heterogeneity of the region, but which is possibly also related to a complex geological and environmental history. The Chiquitano Region can be assessed as a region of distinct regional herpetofaunal diversity charaterised by small scale diversity patterns. It therefore merits recognition as a unique ecoregion, and conservation effort should be increased. Further research is necessary to solve the taxonomic problems addressed in this study. Moreover, future work should be directed towards the development and institution of longterm monitoring programs to evaluate the effects of climate change and changes in land-use on biodiversity, especially that of the Chiquitano Region.
Die anaerobe Atmung mit Nitrat und Nitrit als terminalen Elektronenakzeptoren bildet einen wichtigen Teil des biologischen Stickstoff-Zyklus. Beispiele sind Denitrifikation und respiratorische Nitrat-Ammonifikation, wobei in beiden Fällen in einem ersten Schritt Nitrat zu Nitrit reduziert wird. In der Denitrifikation entstehen dann verschiedene gasförmige Produkte (NO, N2O, N2), wogegen Nitrit in der Ammonifikation ohne die Freisetzung weiterer Zwischenprodukte direkt zu Ammonium reduziert wird. Während die terminalen Reduktasen dieser Atmungsketten gut untersucht sind, ist das Wissen über die Zusammensetzung kompletter Elektronentransportketten sowie die Interaktion einzelner Proteine als auch zwischen den Proteinen und Chinonen in der Membran begrenzt. Ziel dieser Arbeit war die Charakterisierung der membranständigen Chinol-Dehydrogenasen NapGH und NrfH in der respiratorischen Nitrat-Ammonifikation von Wolinella succinogenes. Dieses Epsilonproteobakterium ist ein etablierter Modellorganismus der anaeroben Atmung und wächst durch respiratorische Nitrat-Ammonifikation mit Formiat oder H2 als Elektronendonoren. Als terminale Reduktasen werden dabei die periplasmatische Nitratreduktase NapA und die Cytochom c-Nitritreduktase NrfA benötigt. Die Genomsequenz weist keine weiteren typischen Nitrat- und Nitritreduktasen auf, und napA- und nrfA-defiziente Mutanten sind nicht in der Lage durch Nitrat- bzw. Nitritatmung wachsen. Das Operon des Nap-Systems (napAGHBFLD) von W. succinogenes kodiert Proteine, die an der Nitrat-Reduktion durch Menachinol beteiligt sind (NapA, -B, -G und -H) und Proteine, die für die Reifung und Prozessierung von NapA benötigt werden (NapF, -L und –D). Im Gegensatz zu vielen anderen Bakterien läuft die Nitrat-Atmung unabhängig von einem NapC-ähnlichen Protein ab, das als membrangebundenes Tetrahäm-Cytochrom c für die Chinol-Oxidation zuständig ist und Elektronen über den Elektronenüberträger NapB an die terminale Reduktase NapA liefert. Zwar sind im Genom zwei NapC-Homologe kodiert (FccC und NrfH), doch die Deletion beider Gene hatte keinen Einfluss auf die Nitrat-Atmung. Es wurde vermutet, dass die Funktion von NapC in W. succinogenes stattdessen durch die beiden Fe/S-Cluster Proteine NapG und NapH übernommen wird. Die Reduktion von Nitrit zu Ammonium wird durch den NrfHA-Komplex katalysiert. Das Pentahäm-Cytochrom c NrfA bildet dabei die katalytische Untereinheit, die über das membranständige Tetrahäm-Cytochrom c auf der periplasmatischen Seite der Membran gebunden ist. NrfH gehört zur NapC/NirT-Familie und überträgt Elektronen von Menachinol auf NrfA. Mittels gerichteter Mutagenese von nrfH wurden in früheren Arbeiten bereits Aminosäure-Reste identifiziert, die essentiell für die Elektronentransportaktivität von Formiat zu Nitrit sind.
TeaABC from the halophilic bacterium Halomonas elongata belongs to the family of tripartite ATP-independent periplasmic (TRAP) transporters. It facilitates the uptake of the compatible solutes ectoine and hydroxyectoine which protect the cell from dehydration by accumulating in the cytoplasm during hyperosmotic stress. It is the only known TRAP transporter activated by osmotic stress. Ectoine and hydroxyectoine accumulation in H. elongata is regulated by the cytoplasmic universal stress protein TeaD. The gene encoding TeaD is located in the same operon as the TeaABC gene. TeaD regulates the cellular homeostasis of ectoine possibly by interacting directly or indirectly with TeaABC. All subunits of TeaABC and TeaD were expressed in E. coli and purified. With TeaD and the solute binding protein (SBP) TeaA high levels of expression suitable for crystallization could be obtained and their 3D structures solved. The small transmembrane protein TeaB and the transporter TeaC showed only moderate and low levels of expression respectively. Functional analysis on TeaA was performed using Isothermal Titration Calorimetry. The measurements demonstrate that TeaA is a high affinity ectoine-binding protein (Kd = 0.19 _M) that also has a significant affinity for hydroxyectoine (Kd = 3.8 _M). The structure of TeaA was solved using ab initio phase determination by MAD (multiple anomalous dispersion). TeaA structures were determined in three conformations: TeaA alone, TeaA in complex with ectoine and TeaA in complex with hydroxyectoine. The resolutions of the structures were 2.2, 1.55 and 1.80 Å, respectively. These represent the first structures of an osmolyte SBP associated to a TRAP transporter. The structures reveal similar ligand binding compared to osmolyte SBPs of ABC transporter pointing to coevolution of the ligand binding modes. Moreover, unique features such as the solvent-mediated specific binding of the ligands ectoine and hydroxyectoine could be observed for TeaA. The structure of TeaD in complex with its cofactor ATP was solved by molecular replacement at a resolution of 1.9 Å. Comparison with other structures of universal stress proteins shows striking oligomerization and ATP binding in TeaD. In conclusion, this work presents the first detailed analysis of the molecular mechanisms underlying ligand recognition of an osmoregulated transporter from the TRAP-transporter family.
Signal-dependent regulation of actin dynamics is essential for many cellular processes, including directional cell migration. In particular, cell migration is initiated by lamellipodia, actin-based protrusions of the plasma membrane. The formation of these protruding structures require incessant assembly and disassembly of actin filaments. The Arp2/3 complex and WAVE proteins are essential for both lamellipodium formation and its dynamics. WAVEs mediate the activation of the Arp2/3 complex downstream of the small GTPase Rac, thus being critical for Rac- and RTK-induced actin polymerization and cell migration. The WAVE-family proteins are always found associated with multiprotein complexes. The most abundant WAVE-based complex is referred to as the WANP (WAVE2-Abi-1-Nap1-PIR121) complex. IQGAP1 is a huge scaffolding protein with multiple protein-interacting domains. IQGAP1 participates in many fundamental activities, including regulation of the actin cytoskeleton, mitogenic, adhesive and migratory responses, as well as in cell polarity and cellular trafficking. IQGAP1 binds to N-WASP, thus raising the possibility that it might control actin nucleation by the Arp2/3 complex. In this study, IQGAP1 was found co-immunoprecipitated not only with WAVE, but also with the endogenous WANP-complex subunits. Correspondingly, IQGAP1 associated to both anti-WAVE and anti-Abi-1 immuno-complexes. Pull-down experiments proved that IQGAP1 binds directly to the WANP-complex subunits. Physical interaction between IQGAP1 and the reconstituted WANP complex could also be demonstrated. Together, these data indicate that IQGAP1 is an accessory component of the WANP complex. Interestingly, the IQGAP-WANP complex disassembled after either EGF stimulation or transfection with constitutively active Cdc42 and Rac1. HeLa cells devoid of IQGAP1 showed diminished and less persistent ruffling upon EGF, but not HGF, stimulation in comparison with the control. This phenotype was accompanied by a strong reduction in chemotaxis towards both growth factors, which was as dramatic as in WANP-complex knockdown (KD) cells. Moreover, GM130 and Giantin showed a polarized and flat ribbon-like pattern in control cells, as it is expected for cis- and cis/medial-Golgi markers. Conversely, small and dispersed vesicular structures were found in both IQGAP1 KD and WANP-complex KD cells. Importantly, Arp2/3-complex silencing resulted in the same phenotypes. Consistently, Brefeldin A-induced disassembly of the Golgi strongly inhibited the IQGAP1-WANP-complex interaction and chemotaxis towards EGF in wild-type cells. The re-expression of an RNAi-resistant wild-type IQGAP1 in IQGAP1 KD cells fully rescued both the ruffling abilities and Golgi structure. A constitutively active mutant, unable to bind to neither Rac1 /Cdc42 nor the WANP complex, could reconstitute only the former defect. Hence, this study shows that actin dynamics regulated by the IQGAP1-WANP complex controls Golgi-apparatus architecture and its contribution to cell chemotaxis. The working model here proposes that at the Golgi apparatus, recruitment of the WANP complex by IQGAP1 leads to the assembly of actin filaments required to maintain the appropriated Golgi morphology. The dissociation of the complex may be required to allow the remodeling of the Golgi membranes in order to respond following a chemoattractant gradient.