Biologische Hochschulschriften (Goethe-Universität)
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The mammalian family of bears (Ursidae) comprises eight extant species, occurring on four different continents. Among them are the iconic and well-known brown and polar bears, both widely distributed across the Northern hemisphere. Their intraspecific genetic structuring has been extensively investigated, albeit with a focus on genetic markers from maternally inherited parts of their genomes (mitochondrial DNA). The evolutionary relationship and divergence time between brown and polar bears have recently triggered an extensive debate, while less focus has been put on to other parts of the ursid phylogeny, particularly to a clade of three Asian bear species. To date, whole genomes of more than 100 bear individuals from four different species have been sequenced. Yet, one fundamental part of the genome has been largely omitted from specific analyses, in bears as well as in most other mammals: the Y chromosome.
The mammalian Y chromosome provides a unique perspective on the evolutionary history of organisms due to its distinct features, and specifically reflects the patriline because of its male-specific inheritance. The characteristics of this chromosome make it well suited to complement and contrast evolutionary inferences based on other genetic markers, and to uncover processes like sex-biased gene flow and hybridization. The unique insights that can be gained from analyses of Y-linked genetic variation made me utilize this part of the genome to investigate the evolution of male lineages in bears. Studying the patriline is particularly promising in this taxonomic group because of male-biased dispersal and a complex and fast radiation of bears. The analysis of Y-chromosomal genetic markers is thus the common theme of this dissertation: I present the identification of large amounts of Y-chromosomal sequence, the development of male-specific markers from such sequences, and the application of these markers to trace the evolution of male lineages of different bear species.
Specifically, I developed a molecular sex determination system based on the detection of two Y-linked fragments that allows to reliably discriminate between females and males from seven different bear species (Bidon et al. 2013). The approach is highly sensitive, bear-specific, and can be applied in standard molecular laboratories. This makes it valuable in conservation genetics and forensic applications, e.g. to analyze non-invasively collected samples.
Furthermore, I used Y-linked markers in a comprehensive and range-wide sample of brown and polar bears, and show that male-biased gene flow plays an important role in distributing genetic material throughout the ranges of both species (Bidon et al. 2014). In brown bears, I detected a lack of paternal population structuring which is in strong contrast to the detailed structuring of the matriline.
Analyzing Y-chromosomal sequences from all eight bear species, I present a phylogeny of the patriline that largely resembles the topology from other nuclear markers but is different from the topology of the mitochondrial gene tree (Kutschera et al. 2014). This discordance among loci generates interesting hypotheses about inter-species gene flow, particularly among American and Asiatic black bears.
With the identification of almost two million basepairs of Y-chromosomal sequence and the analysis of an unprecedented large male-specific dataset in polar bears, a high-resolution view on the distribution of their intraspecific variation was obtained (Bidon et al. 2015). In particular, two clades that are divergent but do not show pronounced phylogeographic structure were detected, confirming the great dispersal capacity of males of this high arctic species.
This dissertation thus represents a comprehensive investigation of Y-linked genetic variation on the intra- and interspecific level in a non-model organism. With my research, I contribute to an increased understanding of the complex evolutionary history of bears. In particular, I show that male-biased gene flow strongly influences the distribution of nuclear genetic variation, and that the contrast between phylogenies of differentially inherited markers can help to understand interspecific hybridization between closely related species. Moreover, my findings demonstrate the potential of Y-chromosomal markers to uncover unknown evolutionary patterns and processes. This applies not only to bears but to many species, even such that are generally well known and well described.
Photosynthese zwischen Überfluss und Mangel : wie Kieselalgen sich Lichtintensitäten anpassen
(2015)
Kieselalgen können auf hocheffiziente Weise Energie aus dem Sonnenlicht gewinnen. So überleben sie selbst lange Dunkelphasen im Meer. Doch wie schützen sie sich vor zu viel Strahlung, wenn Wind und Strömung sie in seichtes Wasser oder an die Oberfläche treiben? Dahinter steckt ein cleverer Regulations-Mechanismus.
Der unscheinbare Fadenwurm "C. elegans" ist einer der ersten und bis heute wichtigsten Modellorganismen der Optogenetik. Zwei Frankfurter Arbeitsgruppen gelang es vor zehn Jahren erstmals, das Tier genetisch mit lichtaktivierbaren Ionenkanälen auszustatten und seine Bewegungen mit Licht zu steuern. Inzwischen studieren Forscher an dem durchsichtigen Wurm auch Prozesse, die für die medizinische Forschung bedeutsam sind – etwa die Entstehung und Behandlung genetisch bedingter Herz-Rhythmus-Störungen.
The metabolome of any live cell consists of several hundred, if not thousands of different molecules at any given moment, be it a relatively small bacterial cell or a whole multicellular organism. Although there are continuous attempts to differentiate between primary and secondary metabolites, the borders often blur in the eye of almost perfect interconvertability of all such matter. With chemistry and physics dominating this domain of biology it is an interdisciplinary endeavor to tackle the questions surrounding the workings of the metabolic pathways involved, searching for answers that ultimately help us to better understand life and find solutions to problems that affect us humans. One area of biochemistry that serves as a formidable example of the intertwined primary and secondary metabolic pathways are fatty acids, essential components of bacterial membranes, sources of energy and carbon but also important building blocks of several natural products. The second area to be mentioned is the metabolism of amino acids, the basic components of proteins and enzymes, which also serve as precursors to a diverse set of metabolites with many biological purposes.
This work focuses on these two areas of biochemistry, as several intermediates of their metabolism serve as building blocks for complex secondary metabolites whence many interesting and bioactive natural products are derived. The powerful and relatively novel tool of click-chemistry is employed to track azide-labeled precursors of primary and secondary metabolism in various bacterial strains to observe biochemistry at work and adds to the knowledge gained through other methods. The methods presented in this work serve the observation of fatty acid biosynthesis, degradation, modification and transport through direct ligation of azido fatty acids with cyclooctynes on one hand, leading to a revision of fatty acid transport in general. On the other hand a cleavable azide-reactive resin is devised to generally track the fate of azidated compounds through the myriads of metabolic pathways offered by entomopathogenic bacteria possessing a rich secondary metabolism. The resulting findings led to the identification of several antimicrobial peptides, amides and other compounds of which many had remained so far undetected in the strains that underwent investigation, underlining the worth of this method for future metabolomic research and beyond.
Termites are important ecosystem engineers of the savanna biome, with the large mounds of fungus-cultivating termites being sources of habitat heterogeneity and structural complexity in African savanna landscapes. Studies from different localities throughout Africa have shown that termite mounds have a strong influence of diversity and composition of plant communities. However, most research has been conducted only at the local scale, and integrating knowledge across Africa is hampered by different methodology of studies and differing environmental context. Little is known about the variation in vegetation composition on termite mounds compared to the surrounding savanna at the regional scale and at the landscape scale, and the main determinants of plant communities on mounds are yet to be ascertained.
This thesis aimes at better understanding the influence of termite mounds on vegetation compared to the surrounding savanna across spatial scales. Three research projects analyse vegetation data and soil data from paired mound and savanna plots in West Africa. The first project examines the influence of termite-induced heterogeneity on plant diversity and vegetation composition at a regional scale, following a bioclimatic gradient from the Sahel of Burkina Faso to the Sudanian vegetation zone in North Benin. The second Project analysed variation of vegetation on and off mounds at the landscape scale in Pendjari National Park, North Benin. The third is a monitoring study over the course of two years, exploring dynamics of juvenile woody plant communities on mounds and in the surrounding savanna at a local scale. The thesis thus provides the first comparative quantitative analysis across scales of mound and savanna vegetation and the drivers of the mound–savanna difference in vegetation.
Synthesizing across scales, its results confirm that termite mounds strongly contribute to savanna plant diversity, even though mounds are not generally more species rich than the surrounding savanna. Variation in mound vegetation is much higher along climatic and soil gradients than previously acknowledged. Mound vegetation differs from the surrounding savanna in the whole study area and in each sampled savanna type, with the strongest differences occurring at the most humid study sites. A large proportion of the differences between mound and savanna vegetation is explained by clay enrichment and related soil factors, such as cation concentrations. Plants on mounds thus benefit from favourable soil conditions, including higher fertility and higher water availability, which is also mirrored by the higher abundance and basal area of juvenile woody plants found on mounds. The variation in mound vegetation between study sites across scales results in part from local differences in soil composition and from climatic differences that influence the regional distribution of species. Different sets of characteristic mound species are identified in each project. Specific plant families and traits like succulency, lianescence, and adaptations to zoochory are found to be overrepresented in mound communities.
In addition to the findings in this thesis, remaining parts of the variation in mound vegetation between study sites could likely be explained by investigating further factors. Specifically, mound vegetation depends on habitat context, which includes available species pools, spatial distribution of mounds, biotic interactions with dispersers and herbivores, fire, and also anthropogenic influence. The high proportion of species with adaptations to zoochory found on mounds, for example, indicates that animal dispersers should be of particular importance for vegetation on termite mounds. Herbivory and fire regime, which are known to contribute to the diversity and community composition of the mound–savanna system, also show strong local variation, not least because of anthropogenic influence.
In conclusion, termite mounds play a crucial role in maintaining heterogeneity and plant diversity in the savanna across scales. Ecosystem services provided by termites, especially considering long-term effects on soil fertility and ecosystem resilience, are most likely undervalued. Mounds should be considered in management plans from local to regional, transnational scales as a matter of course, accompanied by further research on the role of termite mounds in savanna ecology on a longer temporal scale. The research presented here thus provides a basis for future studies on termite mound vegetation that should specifically consider the biotic and abiotic context of the mound–savanna system.
Background. There is growing public and scientific concern about the occurrence of anthropogenic chemicals in the aquatic environment. Surface and groundwater serve as main drinking water resource. Especially in metropolitan areas these water reservoirs are impacted by organic pollutants predominantly originating from wastewater treatment plant (WWTP) effluents. The impact of wastewater derived anthropogenic chemicals is therefore related to environmental and human health concerns. In order to lower the potential environmental and human health risk from wastewater associated pollutants, strategies for enhanced pollutant removal are applicable in a medium-term perspective. Ozonation and powdered activated carbon treatment are the two advanced wastewater treatment technologies, which are technically mature as well as economically feasible for the application in large-scale wastewater treatment plants. While powdered activated carbon removes substances by adsorption, ozonation degrades a parent compound into oxidation products. Most of the available research has been done at lab-scale while onsite ecotoxicity tests and chemical analyses are rare.
Objectives. For a comparative evaluation of advanced wastewater treatments' potential to alter toxicity, a broad spectrum of ecotoxicological data need to be collected. The focus has been set on three major objectives: A) Evaluation of the endocrine activity; B) Evaluation of the unspecific toxicity; C) Evaluation of genotoxicity and mutagenicity.
Methods. The advanced treatment methods, ozonation and powdered activated carbon treatment of secondary wastewater effluents, – each equipped with subsequent sand filtration as additional post treatment step – were ecotoxico-logically characterized at a pilot-scale WWTP. For process control the elimination of 35 selected pharmaceuticals was identified by chemical analyses using HPLC-MS/MS.
The endocrine activity ((anti-)estrogenic, (anti-)androgenic, dioxin-like activity)) was characterized by yeast-based in vitro bioassays and cytotoxicity by cell based assays. Genotoxicity and mutagenicity was assessed using umuC'assay and Ames assay, respectively. All in vitro assays were performed using extracts of the wastewater samples. In vivo toxicity was assessed with the fish early life stage test with rainbow trout (Oncorhynchus mykiss). Ozonation was additionally assessed at a full-scale WWTP with in-vitro tests on endocrine activity and cytotoxicity and in vivo toxicity tests using five aquatic model organisms: Lemna minor, Daphnia magna, Chironomus riparius, Lumbriculus variegatus, Potamopyrgus antipodarum.
Results. In conventional activated sludge treated effluents the residual estrogenicity, antiandrogenicity, aryl hydrocarbon receptor agonistic activity and cytotoxicity were considerably reduced while antiestrogenicity was increased by both advanced treatment technologies. Ozonation led to an increase in genotoxic effects detected with Ames assay and with single cell gel electrophoresis of rainbow trout erythrocytes. Furthermore, mortality of rainbow trout was increased and reproduction of L. variegatus was decreased. Sand filtration lessened the genotoxic effects and adjusted reproduction of L. variegatus and mortality of rainbow trout to a similar level as conventional treatment.
Conclusions. This work demonstrates that conventional activated sludge treatment induces in vitro and in vivo toxicity. Advanced wastewater treatment combined with subsequent sand filtration can reduce in vitro and in vivo toxicity. An observed increase of endocrine activity after advanced wastewater treatment is an indication for different removal efficiencies of chemicals causing agonistic or antagonistic activity, respectively. Ozonation of wastewater generates ecotoxicity, which is largely removed by subsequent sand filtration. After a comprehensive investigation and after assurance of the removal of adverse effects, advanced treatment technologies could have beneficial effects on the ecological quality of the receiving water.
Die Endometriose ist eine gynäkologische Erkrankung, bei der epitheliale und stromale Zellen des Endometriums Läsionen außerhalb des Uterus bilden, die in ihrem Aufbau dem Endometrium gleichen. Diese Läsionen, sowie deren zyklische Proliferation, führen zu Schmerzen bei betroffenen Frauen. In isolierten, invasiven Epithelzellen (EEC145T) einer Endometriose-Läsion konnte die Expression von Shrew-1 gezeigt werden. Auch in anderen zellulären Zusammenhängen fördert die Expression von Shrew-1 den invasiven Phänotyp. Shrew-1 ist ein Transmembranprotein, das in Epithelzellen mit den Adhärenzverbindungen assoziiert ist und Interaktionen mit β-Catenin und E-Cadherin eingeht. In MCF7-Zellen fördert die Expression von Shrew-1 die EGF-induzierte Internalisierung von E-Cadherin, welche zur Verminderung der Zell-Zell-Adhäsion führt. In 12Z- und HT1080-Zellen konnte eine Interaktion mit CD147 gezeigt werden. CD147 fördert die Aktivität von MMPs und in Shrew-1-überexprimierenden HT1080-Zellen konnte eine erhöhte Aktivität der MMP9 gezeigt werden. Shrew-1 wirkt somit auf die Invasivität von Zellen und ist gleichzeitig Teil der Adhärenzverbindung. Aus diesem Grund wird Shrew-1 eine modulatorische Rolle in diesem Kontext zugeschrieben.
In immunhistologischen Färbungen von Shrew-1 und E-Cadherin konnte in Adenomyose-Läsionen eine inverse Expression der beiden Proteine in einigen epithelialen Zellen gezeigt werden, die im Endometrium nicht detektiert werden konnten. In den epithelialen Endometriose-Zelllinien 12Z und 49Z, die kein E-Cadherin exprimieren und äquivalent zu der Zelllinie EEC145T sind, führte die Herunterregulation von Shrew-1 (Shrew-1 KD) zur Reexpression von E-Cadherin. E-Cadherin ist in den 12Z Shrew-1 KD-Zellen an der Plasmamembran lokalisiert und interagiert mit β-Catenin, wodurch seine Assoziation mit den Adhärenzverbindungen wahrscheinlich ist. Die Herunterregulation von Shrew-1 führt zu einer verminderten Motilität und Invasivität der 12Z-Zellen, wobei die reduzierte Invasivität nicht alleine auf die Reexpression von E-Cadherin zurückgeführt werden kann. Es ist zu vermuten, dass das verminderte invasive Verhalten mit der ausbleibenden Interaktion von Shrew-1 mit CD147 zusammenhängt, welches die Aktivität von MMPs fördert.
Da Shrew-1 eine direkte Interaktion mit β-Catenin eingehen kann, ist es möglich, dass die Herunterregulation von Shrew-1 zu Veränderungen in der Lokalisation von β-Catenin und weiteren Proteinen, die mit den Adhärenzverbindungen assoziiert sind (p120 Catenin und Aktin), führen. Dies konnte jedoch nicht beobachtet werden. Eine verstärkte Lokalisation von Vinculin an den Enden von Aktin-Stressfasern sowohl in Zellausstülpungen als auch an Zell-Zell-Kontakten konnte in 12Z-Zellen nach der Herunterregulation von Shrew-1 beobachtet werden. Dies könnte eine Folge der E-Cadherin-Reexpression oder entscheidend für die Lokalisation von E-Cadherin an der Membran sein.
Die Reexpression von E-Cadherin, die in den 12Z Shrew-1 KD-Zellen auf mRNA- und Protein-Ebene nachgewiesen werden kann, erfolgt in den 12Z-Zellen vermutlich hauptsächlich über Veränderungen von Histon-Acetylierungen, da die Behandlung mit dem HDAC-Inhibitor TSA die Expression von E-Cadherin in den 12Z-Zellen induziert. Eine verstärkte H3K9-Acetylierung am CDH1-Promotor konnte in ChIP-Analysen in den 12Z Shrew-1 KD-Zellen gezeigt werden. Die gesteigerte Acetylierung resultiert vermutlich aus der verminderten Assoziation von HDAC1 und HDAC2 mit dem CDH1-Promotor in diesen Zellen. Eine Beteiligung der Repressoren Snail, Slug, Twist und ZEB1 an der Reexpression von E-Cadherin in den 12Z Shrew-1 KD-Zellen konnte nicht gezeigt werden. Ebenso scheinen Veränderungen am Methylierungsstatus des CDH1-Promotors nach der Herunterregulation von Shrew-1 nicht zu erfolgen.
TSA induziert auch in weiteren epithelialen Endometriose-Zelllinien (10Z und 49Z) die Expression von E-Cadherin. In stromalen Zellen führt hingegen weder TSA noch die Herunterregulation von Shrew-1 zur Expression von E-Cadherin (17B, 18B und 22B). Dies weist darauf hin, dass die Herunterregulation von Shrew-1 über die Veränderungen von Histon-Acetylierungen wirkt und dass dieser Mechanismus in epithelialen Endometriose-Zellen entscheidend ist. In den stromalen Zellen muss die Expression von E-Cadherin über einen anderen und/oder weitere Mechanismen blockiert sein.
Auch der Wnt-Signalweg scheint an der Reexpression von E-Cadherin in 12Z-Zellen beteiligt zu sein. Die Inhibierung der GSK3β (LiCl und SB216763) führt zur Expression von geringen Mengen an E-Cadherin. In 12Z Shrew-1 KD-Zellen führt die Stabilisierung von Axin (XAV939) zur verminderten Expression von E-Cadherin. Dies lässt darauf schließen, dass Shrew-1 auch einen Einfluss auf den Wnt-Signalweg hat, was vor allem durch dessen Interaktion mit β-Catenin wahrscheinlich ist.
Terrestrische Säugetiere werden von unterschiedlichen Parasiten als Wirte genutzt. Dabei kann ihre Parasitenfauna je nach Art, Lebensweise, Verbreitung, Gesundheitszustand und Reproduktionsstatus des Wirts abweichen. Ein weiterer bestimmender Faktor, ist der Einfluss des Menschen in Form von Regulierungsmaßnahmen und Schaffung urbaner Lebensräume. Domestizierte Haustiere bzw. Nutztiere weisen daher in der Regel andere Parasiten auf als ihre wildlebenden Artgenossen. Gleichzeitig können sich sowohl Wildtiere als auch domestizierte Tiere und Menschen gegenseitig Parasitenarten teilen und wechselseitig aufeinander übertragen. Daraus resultierende Krankheiten werden als Zoonosen bezeichnet.
Insbesondere Fledermäuse (Unterordnung Microchiroptera) zeigen weltweit eine enorme Parasitendiversität, die noch weitgehend unerforscht ist. Ebenfalls Forschungsbedarf besteht für die Sandfloh-Gattung Tunga in Süd- und Mittelamerika in Hinblick auf ihr Wirtsspektrum, welches auch Menschen einschließt. Die Art Tunga penetrans und zahlreiche weitere Parasitenarten, parasitieren gleichzeitig auch bei Hunden. Daher stellen diese Wirte eine direkte Gesundheitsgefahr für Menschen in ihrer unmittelbaren Umgebung dar.
Die vorliegende Dissertation ist in kumulativer Form zusammengefasst und beinhaltet drei Einzelpublikationen sowie einen Reviewartikel.
Ziel war es, die Parasitendiversität von Hunden aus urbanen tropischen Gebieten und die Parasitendiversität des Großen Ameisenbären (Myrmecophaga tridactyla) mit Hilfe morphologischer und molekularbiologischer Methoden zu analysieren. Die jeweiligen Parasitenfaunen wurden in Hinblick auf die soziale bzw. solitäre Lebensweise der beiden Wirtsarten verglichen und ihr zoonotisches Potenzial bewertet.
Ein weiteres Ziel war die Zusammenfassung der Ektoparasitennachweise süd- und mittelamerikanischer Microchiroptera und für die europäischen Arten der Fledermaus-Gattung Myotis (hier Endo- und Ektoparasiten) auf Basis der verfügbaren Literatur. Des Weiteren sollten eigene Parasitennachweise aus Bolivien bzw. Deutschland erfolgen. Für die Nachweise aus Deutschland wurden M. myotis untersucht, deren Artzugehörigkeit vorher bestimmt wurde. Zusätzlich wurden diese Individuen auf humanpathogene Lyssaviren untersucht.
Die Nachweise erfolgten über molekularbiologische und morphologische Methoden.
Vascular tumors associated with chronic B. henselae infections are unique examples of infection-associated pathological angiogenesis. The chaotic vascular architecture and prominent myeloid infiltrate of B. henselae induced vascular lesions show many similarities with malignant tumors.
In human cancers infiltrating myeloid cells play a decisive role in tumor progression and vascularization. In particular, tumor associated macrophages (TAMs) transform the tumor microenvironment, drive tumor invasion and vascularization through secretion of pro-angiogenic and immune modulatory cytokines and participation in matrix remodeling processes.
Myeloid angiogenic cells (MACs) are a subset of circulating myeloid progenitors with important roles in regenerative and pathological angiogenesis and a critical involvement in tumor vascularization. The phenotypic plasticity and importance of MACs in pathological angiogenic processes, position these cells as key potential players in B. henselae associated vascular tumor formation.
To investigate the possible role of MACs in B henselae induced pathological angiogenesis, the objective of this study was to examine the interaction of B. henselae with MACs and determine how this may affect their angiogenic capacity.
Building on previous work by Mӓndle (2005) this study has demonstrated that MACs are susceptible to infection with B. henselae and reside in intracellular vacuoles. As in endothelial cells, infection of MACs with B. henselae was associated with inhibition of apoptosis and activation of endogenous angiogenic programs including activation of the angiogenic transcription factor HIF-1.
In addition to angiogenic re-programming on a molecular level B. henselae infection increases MAC functional angiogenic capacity. B. henselae infected MACs were found to integrate into growing endothelium and increase the rate of angiogenic sprouting in a paracrine manner.
When cultured in a Matrigel capillary formation assay, infected MACs were also found to form networks of capillary-like structures that were stable over long periods of time. The B. henselae pathogenicity factor BadA was essential for the induction of this vascular mimicry phenotype as well as the activation of HIF-1 in infected MACs indicating that this factor may play an important role in MAC angiogenic re-programming.
Examination of infected MACs via FACS analysis, cytospin immunohistochemistry and qRT-PCR revealed that endothelial differentiation does not play a role in the B. henselae induced pro-angiogenic phenotype. Instead, MACs were shown to be myeloid in phenotype displaying typical macrophage markers which were upregulated upon B. henselae infection and maintained over long-term culture.
The increased angiogenic activity of B. henselae infected MACs was found to be associated with a broad phenotypic reprogramming in infected cells. In particular, gene expression programs related to angiogenesis, structural organization, apoptosis, sterol metabolism and immune regulation, were upregulated. Further examination of microarray gene expression profiles revealed that B. henselae infected MACs display a predominantly M2 anti-inflammatory macrophage activation status.
Finally, examination of the paracrine microenvironment created by B. henselae infected MACs revealed a diverse cytokine secretion profile dominated by inflammatory-angiogenic cytokines and matrix remodeling elements and lacking expression of some of the most important cytokines involved in the expansion of the inflammatory response. This B. henselae induced activation status was demonstrated to be distinct from the general inflammatory response induced by E. coli LPS treatment.
Comparison of B. henselae infected MACs to TAMs revealed many parallels in functional and phenotypic characteristics. Both TAMs and B. henselae infected MACs demonstrate increased angiogenic capacity, invasive, and immune modulatory phenotypes and the ability to participate in the formation of vascular mimicry phenotypes under angiogenic pressure. Furthermore, the pro-angiogenic paracrine microenvironment created by B. henselae infected MACs shows many similarities to the TAM-created tumor-microenvironment.
In conclusion, these investigations have demonstrated that the infection of MACs with B. henselae results in the phenotypic re-programming towards TAM-like cells with increased pro-angiogenic, invasive and immune-modulatory qualities. The results of this study elucidate new aspects of B. henselae pathogenicity in myeloid cells and highlight the role of these cells as paracrine mediators of B. henselae induced vascular tumor formation. In addition, these findings demonstrate that manipulation of myeloid cells by pathogenic bacteria can contribute to microenvironmental regulation of pathological tissue growth and suggest parallels underlying bacterial infections and cancer.
Die Substitution von klassischen, mit der Nahrungsmittelproduktion in Konkurrenz stehenden, Substraten wie Glukose durch alternative Kohlenstoffquellen in der Biotechnologie ist sowohl aus ethischer, als auch aus ökonomischer Sicht erstrebenswert. Diese Arbeit beschreibt die Synthese von Bulkchemikalien in Form zweier Dicarboxylsäuren und einer Feinchemikalie in Form eines Sesquiterpens aus dem alternativen Substrat Methanol mit Hilfe genetisch veränderter Stämme des methylotrophen α-Proteobakteriums Methylobacterium extorquens.
Mesacon- und (2S)-Methylsuccinsäure sind Dicarboxylsäurederivate der CoA-Ester Mesaconyl- und (2S)-Methylsuccinyl-CoA, die als Intermediate im Ethylmalonyl-CoA- Weg (EMCP) vorkommen. M. extorquens nutzt den EMCP für die Regeneration von Glyoxylat, das für das Wachstum auf C1-Substraten wie Methanol obligatorisch ist. In dieser Arbeit konnte erstmals Mesacon- und (2S)-Methylsuccinsäure de novo durch die Expression einer für die Vorstufen Mesaconyl- und (2S)-Methylsuccinyl-CoA aktiven Thioesterase produziert werden. Ein kobaltlimitiertes Wachstum von M. extorquens führte aufgrund mangelnder Cofaktorversorgung zweier Vitamin-B12-abhäniger Mutasen im EMCP zu einer Akkumulation der beiden CoA-Ester-Vorstufen, womit eine Produktion von 0.65 g/l Mesacon- und (2S)-Methylsuccinsäure erreicht wurde. Weitergehende Untersuchungen belegten außerdem einen positiven Effekt eines ausgeschalteten PHB-Zyklusses auf die Produktion der beiden EMCP- Dicarboxylsäurederivate.
Diese Arbeit beinhaltet zusätzlich grundlagenwissenschaftliche Untersuchungen zur Substitution der EMCP-katalysierten Glyoxylatregeneration durch einen heterologen Glyoxylatzyklus in EMCP-negativen M. extorquens-Stämmen. Dabei konnte erstmals ein methanolverwertendes, methylotrophes Bakterium identifiziert werden, das einen Serin-Zyklus in Kombination mit dem Glyoxylat-Zyklus zur Kohlenstoffassimilation verwendet, ohne dabei zusätzliche Stoffwechselwege zur CO2-Fixierung wie den EMCP, RuMP oder CBB-Zyklus zu verwenden.
Die Präsenz einer nativen C30-Carotinoidbiosynthese, ausgehend von der Vorstufe Farnesylpyrophosphat (FPP), empfiehlt M. extorquens als Produktionsorganismus für (Sesqui-)Terpene. In dieser Arbeit wurde mit Hilfe einer induzierbar gesteuerten Expression einer Terpensynthase in Form einer α-Humulen-Synthase, einer FPP-Synthase und eines prokaryontischen Mevalonatweges, erstmals die de novo Synthese eines Terpens aus Methanol am Beispiel des α-Humulens etabliert. Durch optimierte Expressionen der Terpensynthase, FPPS und einzelner MVA-Gene mit Hilfe angepasster Translationsinitiationsraten der jeweiligen ribosomalen Bindestellen und der Verwendung eines in der nativen Carotinoidbiosynthese inhibierten M. extorquens-Stammes wurden finale Produkttiter von bis zu 1.65 g/l α-Humulen in Fed-Batch-Fermentationen erreicht.
Diese kumulative Dissertation beinhaltet außerdem einen Reviewartikel, in dem der verwendete Mikroorganismus M. extorquens in mikrobiologischer, genetischer, biochemischer und auch biotechnologischer Hinsicht ausführlich beschrieben wird. Zudem gibt ein Buchkapitel eine Übersicht über die Verwendung von Methanol in der Biotechnologie.