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Institute
In our rapidly changing world, land use has been recognized as having one of the strongest impacts on species and genetic diversity. The present state of temperate forests in Europe is a product of decisions made by former and current management and policy actions, rather than natural factors. Alterations of crown projection areas, structural complexity of the forest stand caused by thinning and cuttings, and changes in tree species composition caused by regeneration or plantings not only affect forest interior buffering against warming, but also the understorey light environment and nutrient availability. Ultimately, current silvicultural management practices have deep impact on the forest ecosystems, microenvironmental changes and forest floor understorey herbs. In response to environmental changes, plants rely on genetically heritable phenotypic variation, an important level of variation in the population, as it is prerequisite for adaptation. However, until now most studies on plant adaptation to land use focus on grassland management. Yet, studies on the adaptation of forest understorey herbs to forest management have been absent so far. This is important because understanding adaptation of understorey herbs is crucial for biodiversity conservation, forest restoration, and climate change mitigation. Studying current adaptation of understorey herbs to forest management yields insights into the evolutionary consequences of management practices, which could be employed to improve sustainable use of forest habitat.
In sum, my conducted experiments complement each other well and managed to fill in research gaps on the topic of genetically heritable phenotypic variation in understorey herbs and how it is affected by forest management and related microenvironmental variables. I showed that forest management has direct evolutionary consequences on the genetic basis of understorey herbs, but also indirectly through the microenvironment. Furthermore, I revealed that local adaptation and phenotypic plasticity of understorey herbs to forest structural attributes act along continuous gradients. And lastly, I highlighted the important role of intra-individual variation by revealing plastic responses to drought and shading, urging researchers to not ignore this important level of trait variation. Ultimately, understorey herbs in temperate forests employ phenotypic plasticity as a flexible strategy to adapt to varying environmental conditions. By adjusting their leaf characteristics, reproductive investment, and phenology, they can optimize their fitness and survival in response to changes in light availability, resource availability, and seasonal cues. The anthropogenic impact on temperate forests and understorey herbs will continue and likely increase in the future. This should urge foresters to adapt their silvicultural management decisions towards the long-term preservation of genetic diversity and, through this, the evolvability and adaptability of forest understorey herbs and associated organisms. Based on the results shown in my dissertation, variation in forest management regimes and types could be beneficial for promoting genetic diversity within several species of forest understorey herbs. Lastly, in the face of future climatic changes, the mechanisms by which plants can cope with increasing stressful environmental conditions might very well rely heavily on intra-individual variation, providing the necessary rapid plastic adjustment to changing microclimatic conditions within populations and thus increase climate change resilience.
The role of Apelin signaling and endocardial protrusions during cardiac development in zebrafish
(2023)
During cardiac development, cardiomyocytes (CMs) are delaminated from the compact muscle wall to increase the muscle mass of the heart. This process is also known as cardiac trabeculation. It has been shown that growth factors produced by endocardial cells (EdCs) are required for myocardial morphogenesis and growth. In particular, Neuregulin produced by EdCs promotes myocardial trabeculation. The deficiency of Neuregulin signaling leads to hypotrabeculation. Endocardial protrusions project from the endocardium to the myocardium are also essential for the trabeculae onset. Yet current studies only introduce the function of endocardial sprouts descriptively. This article first reports the mechanisms of endocardial sprouting during myocardial trabeculation. By living imaging, we first demonstrate that EdCs interact with CMs through membrane protrusions in zebrafish embryos. More interestingly, these protrusions stay in close contact with their target CMs in spite of the cardiac contraction. We utilize loss-of-function strategies to report the importance of myocardial apelin, which induces endocardial protrusion formation. Zebrafish lacking Apelin signaling exhibit defects in endocardial protrusion formation as well as excessive deposition of cardiac jelly and hypotrabeculation. Notably, we also present data that blocking protrusion formation in endocardial cells phenocopies the trabeculation defects in apelin mutants. Mechanistically, endocardial-derived Neuregulin requires Apelin signaling mediated endocardial protrusions, and Neuregulin dependent pERK expression is attenuated in the condition of reduced endocardial protrusion formation. Together, our data suggest that endocardial-myocardial communication through endocardial protrusions acts as an underlying principle allowing myocardial growth.
Compaction and spheroid formation modulates stemness and differentiation of human pancreas organoids
(2023)
The incidence of diabetes type 1 (T1D) in children and young adults is increasing worldwide. T1D is well treated by insulin administration. However, there is currently no long-lasting cure for this ailment. The success rate of pancreatic islet transplantation to treat T1D is limited by the availability of patient-matched islets and the necessity of using life-long immunosuppressive medication. The difficulties caused by transplantation can be overcome by generating bio-engineered pancreatic islets from patient-derived progenitor cells. Aim of this thesis is to establish new strategies for the generation and analysis of pancreatic lineages derived from human progenitor cells. It reports on the optimization of a technique to form human pancreatic spheroids from hollow monolayered human pancreas organoids (hPOs) to investigate how cell-cell and cell-matrix interaction can be leveraged to induce endocrine differentiation of the pancreas progenitor cell organoids. We introduce cell aggregation protocols to generate endocrine pancreas cell lineages from ductal pancreatic cells. Next, we study the effect of co-culture with stromal and endothelial cells to promote cell differentiation toward a pancreatic fate enhancing β cells productivity.
This thesis has focused on identifying the differences in gene expression along with phenotypical transformation during differentiation of human pancreatic organoids (hPOs) towards human β cells to be used in the future of cellular therapeutics in treating T1D patients.
Epithelial cells enable essential physiological functions, including absorption, morphogenesis, secretion, and transport. To execute these functions, epithelial cells often form three-dimensional shapes that include curved sheets of cells surrounding a pressurized fluid-filled lumen. These three-dimensional tissues (called domes) are essential for organ function, but when they are not working properly, developmental defects, inflammation, and cancer can ensue. Recently, it has been shown that the cells that form domes show active superelasticity on micropatterned plates.
We show here that the immortalized renal proximal tubule epithelial cell line, LLC-PK1, stereotypically forms tubules in 10 days. Tubule formation takes place in 4 stages. When cells are plated on a culture dish, they form a monolayer on the 1st day; on the 3rd day, three-dimensional structures are formed, called domes; and after the 4.5th day, these domes start fusing to begin the transition stage and transit to the tubule stage. At the end of the 10th day, differentiated, elongated, and matured tubes form (Figure 3.1). Therefore, tubule formation is a self-organized, stereotypic morphogenetic program under long-term, unperturbed tissue culture conditions.
We propose that tubulogenesis is a two-step process in proximal tubules by doming and wrapping. The process begins with dome formation, and as the cell layers come together in the transition stage at the edge of the dome, this leads to the formation of the lumen of the eventual tubule. We also found that F-actin provides the mechanical strength during the formation of these three-dimensional structures during tubule formation. To better understand this 4-step process on a molecular level, we performed proteomics of tubule formation to identify the different proteins that play a significant role in proximal tubule development. Importantly, we identified proximal tubule markers like synaptopondin, angiotensin 1-10, collectrin, polycystin 1, and polycystin 2. These proteins play an important role in renal tube formation and differentiation.
Cell division is carried out by highly conserved cyclin-CDK complexes, which phosphorylate various cellular components. Cyclin-CDKs act differently depending on the cell cycle phase and work cooperatively to create DNA replication and cytokinesis. Therefore, we identified that cyclin-B1, marker of proliferation Ki-67, the RAD51 recombinase, and proliferating cell nuclear antigen (PNCA) are upregulated in the monolayer stage, and the expression decreases as tubule formation takes place. The proximal tubule reabsorbs 60-65% of the glomerulus filtrate. Therefore, it requires a lot of energy generated by using the fatty acid oxidation (FAO) pathway. In our model, we found FAO expression is higher than that of the other metabolic pathways.
We found expression of an intricate protein network in mitochondria, which we interpret as a sign of mitochondrial homeostasis being vital for the FAO pathway to work. Furthermore, we also identified different types of transporters at each stage of proximal tubule formation, and we could recognize different cytoskeletal components playing a significant role in each stage of proximal tubule formation, for instance, at the monolayer stage, vimentin expression is high, and its expression is reduced as tubules form. Hence, this 2D system, at this step of characterization, seems suitable to use to study differential transport protein expression and how this might relate to physiological functions and syndromes.
Next, we inhibited different transporters using specific inhibitors and analyzed the effect on dome and tubule formation. We identified that Na+/K+ ATPase and vacuolar H+ ATPase play a significant role in the process of epithelial dynamics. Digoxin (a Na+/K+ ATPase inhibitor) treatment inhibits dome and tubule formation. Bafilomycin (a v-ATPase inhibitor) treatment demonstrated a delay in dome and tube formation. Therefore, this study shows that this 2D proximal tubule novel system can be used for screening of pharmacological leads in the context of specific aspects of kidney physiology.
Despite the recent success in growing kidney organoids, they are not well suited to investigate various pathophysiological conditions in vitro for several reasons: They grow in 3D and form a tissue that later needs to be dissected/cleared and stained to investigate pathophysiological changes. Moreover, organoids require complex and expensive protocols for generation and are challenging to use in screening approaches. Therefore, we set out to demonstrate feasibility for our 2D system using normal renal epithelial cells, which are the origin of various pathological conditions, to study pathophysiological conditions.
Chemical pollution is one of the main contributors to the degradation of lotic ecosystems and their biodiversity. Among chemicals driving lotic biodiversity decline are anthropogenic organic micropollutants (AOM), which affect the survival and functioning of freshwater organisms. Continuous exposure of freshwater organisms to AOM leads to adverse effects that sometimes cannot be traced with standard toxicity methods such as standard toxicity testing or biodiversity indices. Among these effects of AOM are selective or mutagenic effects that cause impaired species genetic diversity. Thus, the correlation between different levels of AOM and genetic diversity of species is still poorly understood. However, it can be explored by applying population genetics screening.
In Chapter 1 of this thesis, background information on environmental pollution, genetic screening, and the detection of evolutionary-relevant AOM effects in freshwater organisms are described and the thesis goals are identified. The main goal of the thesis is to study whether AOM exposure occurring in European rivers causes a significant evolutionary footprint in freshwater species and leads to a selection of more tolerant geno-and phenotypes. Therefore, population genetics indices together with high-resolution chemical exposure screening of a widespread indicator invertebrate species, Gammarus pulex (Linnaeus, 1758), living in polluted and pristine European rivers were investigated.
In Chapter 2, the development of a genetic screening method for G. pulex (microsatellites) is described. Due to genetic differentiation and the presence of morphologically cryptic lineages, the available sets of target loci do not enable a reliable population genetic characterization of G. pulex from central Germany. Thus, a novel set of microsatellite loci for a high-precision assessment of population genetic diversity was here applied. Eleven loci were first identified and thereafter amplified in G. pulex from three rivers. The new loci reliably amplified and indicated polymorphisms in the studied amphipods. The amplification resulted in the successful identification of genetically distinct populations of G. pulex from the analyzed rivers. Moreover, the microsatellite loci were amplified in other genetic lineages of G. pulex and another Gammarus species, G. fossarum, promising a broader applicability of the loci in related amphipod species.
In Chapter 3, the effects of AOM on species genetic differentiation and sensitivity to toxic chemicals in a typical central European river with pristine and AOM-polluted sections was investigated. The river’s site-specific concentrations of AOM were assessed by chemical analysis of G. pulex tissue and water samples. To test, whether different levels of AOM in the river select for pollution-dependent genotypes, the genetic structure of G. pulex from the river was analyzed. Finally, the toxicokinetics of and sensitivity to the commonly used insecticide imidacloprid were determined for amphipods sampled at pristine and polluted sections to assess whether various levels of AOM in the river influence sensitivity of G. pulex to imidacloprid. The results indicated that different levels of AOM did not drive genetic divergence of G. pulex within the river but led to an increased sensitivity of exposed amphipods to imidacloprid. The amphipods living in polluted river sections were more sensitive to the insecticide due to chronic exposure to toxic levels of AOM.
In Chapter 4, the relationship between site-specific pollution levels of AOM and genetic diversity parameters of G. pulex was analyzed at the regional scale within six rivers in central Germany. The genetic structure of G. pulex in the studied area was tested for relatedness to the waterway distance between sites. Gammarus pulex genetic diversity parameters, including allelic richness and inbreeding rate, were tested against environmental pollution parameters using linear mixed-effect- and structural-equation models. According to the results, G. pulex genetic diversity parameters were significantly associated with the detected AOM levels. At sites with high concentrations of AOM and toxicity potential G. pulex showed reduced genetic diversity and increased rates of inbreeding. These results suggest that AOM play a major role in shaping the genetic diversity of G. pulex in rivers.
According to the findings presented here, the applied microsatellites can be used to successfully detect changes in genetic patterns in freshwater amphipods facing increased levels of AOM. The findings indicate that levels of AOM representative for European rivers do not lead to the separation of genotypes among G. pulex as the connectivity between sites majorly contributes to species’ genetic structure. However, the chronic exposure to increased levels of toxic AOM leads to a reduction of species genetic diversity and increases the sensitivity of G. pulex to the toxic chemical effects.
Non-ribosomal peptide synthetases (NRPSs) are modular biosynthetic megaenzymes producing many important natural products and refer to a specific set of peptides in bacteria’s and fungi’s secondary metabolism. With the actual purpose of providing advantages within their respective ecological niche, the bioactivity of the structurally highly diverse products ranges from, e.g., antibiotic (e.g., vancomycin) to immunosuppressive (e.g., cyclosporin A) to cytostatic (e.g., echinomycin or thiocoralin) activity.
An NRPS module consists of at least three core domains that are essential for the incorporation of specific substrates with the 'multiple carrier thiotemplate mechanism' into a growing peptide chain: an adenylation (A) domain selects and activates a cognate amino acid; a thiolation (T) domain shuffles the activated amino acid and the growing peptide chain, which are attached at its post-translationally 4ʹ-phosphopantetheine (4'-PPant) group, between the active sites; a condensation (C) domain links the upstream and downstream substrates. NRPS synthesis is finished with the transfer of the assembled peptide to the C-terminal chain-terminating domain. Accordingly, the intermediate is either released by hydrolysis as a linear peptide chain or by an intramolecular nucleophilic attack as a cyclic peptide.
The NRPS’s modular character seems to imply straightforward engineering to take advantage of their features but appears to be more challenging. Since the pioneering NRPS engineering approaches focused on the reprogramming and replacement of A domains, several working groups developed advanced methods to perform a complete replacement of subdomains or single or multiple catalytic domains.
The first part of this work focusses parts of the publication with the title 'De novo design and engineering of non-ribosomal peptide synthetases', which follows up assembly line engineering with the development of a new guideline. Thereby, the pseudodimeric V-shaped structure of the C domain is exploited to separate the N-terminal (CDSub) and C-terminal (CASub) subdomains alongside a four-AA-long linker. This results in the creation of self-contained, catalytically active CASub-A-T-CDSub (XUC) building blocks. As an advantage over the previous XU concept, the characteristics (substrate- and stereoselectivity) assigned to the C domain subunits are likewise exchanged, and thus, no longer represent a barrier. Furthermore, with the XUC concept, no important interdomain interfaces are disrupted during the catalytic cycle of NRPS, allow to expect much higher production titers. Moreover, the XUC concept shows a more flexible application within its genus origin of building blocks to create peptide libraries. Additionally, with this concept only 80 different XUC building blocks are needed to cover the entire proteinogenic amino acid spectrum.
The second part of this work addresses the influence of the C domain on activity and specificity of A domains. In a comprehensive analysis, a clear influence of different C domains on the in vitro activation rate and the in vivo substrate spectrum could be observed. Further in situ and in silico characterizations indicate that these influences are neither the result of the respective A domains promiscuity nor the C domain’s proofreading, but due to an 'extended gatekeeping' function of the C domain. This novel term of an 'extended gatekeeping' function describes the very nature of interfaces that C domains can form with an A domain of interest. Therefore, the C-A interface is assumed to have a more significant contribution to a selectivity filter function.
The third part of this work combines the NRPS engineering with phylogenetic/evolutionary perspectives. At first, the C-A interface could be precisely defined and further identified to encode equivalent information corresponding to the complete C-A didomain. Moreover, the comparison of NRPSs topology reveals hints for a co-evolutionary relatedness of the C-A didomain and could be shown to reassemble even after separation. In this regard, based on a designed CAopt.py algorithm, the reassembling-compatibility of hybrid interfaces could be determined by scoring of the co-expressed NRPS hybrids. This algorithm also enables the randomization of the interface sequences, thus, leading to the identification of more functional interface variant, which cause significantly higher peptide production and could even be applied to other native and hybrid interfaces.
Die Vorläuferform der eukaryotischen mRNA (prä-mRNA) durchläuft, eine Reihe von Prozessierungs-Schritte, die schließlich zu der Synthese einer „reifen“ und Exportkompetenten mRNA führt. prä-mRNA Spleißen ist ein essentieller Teilschritt dieser Reifung bei der intragene Sequenzen, sogenannte Introns, von der prä-mRNA entfernt werden, während Exons legiert werden. Das prä-mRNA Spleißen wird durch das Spleißosom katalysiert. Dieser Mega-Dalton Komplex, besteht aus fünf Sub-Komplexen, die sich wiederum aus katalytisch aktiven „kleinen nukleären Ribonukleinsäuren“ (snRNAs) und einer Vielzahl von proteinogenen Faktoren zusammensetzen. Diese Subkomplexe, bezeichnet als snRNPs (small nuclear Ribonucleoprotein Particles), binden die prä-mRNA an charakteristischen Sequenzen und richten die prä-mRNA durch eine Reihe von Konformations-Änderungen so aus, dass benachbarte Exons in Kontakt treten und über eine biochemische Ligations-Reaktion verbunden werden können.
Die Exon- bzw Intronerkennung der snRNPs wird durch zahlreiche Spleißfaktoren reguliert. Eine Proteinfamilie, die essentiell für die Regulierung des Spleißens ist, sind Serin/Arginin-reiche Proteine (SR-Proteine). Diese binden vorzugsweise an das 3‘ oder 5’ Ende von Exons, rekrutieren snRNPs und stimulieren dadurch die Exon-Inklusion. Durch diese Stimulierung können Spleiß-Events reguliert und gezielt spezifische Exons ausgeschlossen oder eingeschlossen werden. Dieser Prozess, der als alternatives Spleißen (AS) bezeichnet wird, tritt in 95% des menschlichen Transkriptoms auf und erweitert die Diversität eines Organismus, da verschiedene Transkripte von demselben Gen erzeugt werden können und folglich die Translation unterschiedlicher Proteine mit distinkten Funktionen ermöglicht wird.
Darüber hinaus verfügt die Zelle durch das AS über eine weitere posttranskriptionale Genregulationsebene, die insbesondere unter zellulären Stressbedingungen zur Expression von alternativen Protein-Isoformen von der Zelle genutzt wird. Eine in medizinischer Hinsicht besonders relevante Stressbedingung ist die sogenannte Hypoxie, die eine Sauerstoff-Unterversorgung von Zellen oder Gewebebereichen beschreibt. Hypoxie bzw. hypoxische Bereiche finden sich in Krebszellen und treten in 90% aller soliden Tumoren auf. Als Teil der Hypoxie Stress-Antwort, verfügt die Zelle über einen Adaptations-Mechanismus, der durch Hypoxieinduzierbare Faktoren (HIF) vermittelt wird. Diese Faktoren induzieren die Transkription zahlreicher Gene und stimulieren die Expression von Stressfaktoren, die an der zellulären Adaption der Hypoxie beteiligt sind. Einer dieser Faktoren ist der vaskuläre endotheliale Wachstumsfaktor A (VEGFA), welcher unter hypoxischen Bedingungen sekretiert wird und dadurch die Proliferation von Endothelzellen, die Neubildung von Blutgefäßen und damit die Vaskularisation des hypoxischen Bereichs stimuliert.
Die zelluläre Anpassung ist jedoch nicht nur auf die transkriptionelle Regulation des HIF-vermittelten Hypoxie Signalwegs beschränkt, sondern wird auf multiplen Genexpressions-Ebenen reguliert. Obwohl bekannt ist, dass tausende Transkripte unter hypoxischen Bedingungen alternativ gespleißt werden, sind die Faktoren, die die zelluläre Stress-Antwort durch AS regulieren, sowie deren molekularer Mechanismus jedoch weitestgehend unbekannt.
Diese Arbeit umfasst die Identifizierung und Charakterisierung von AS Events, sowie den Einfluss und die Regulation von Spleißfaktoren auf AS unter hypoxischen Bedingungen. Hierzu führten wir globale Genexpressions- und AS-Analysen in HeLaKarzinomzelllinien unter Normoxie (21% O2) und Hypoxie (0.2% O2) durch und zeigen, dass 7962 Gene nach 24h Hypoxie unterschiedlich exprimiert werden. Über AS-Analysen konnten 4434 Transkripte identifiziert werden, die bei Hypoxie über AS reguliert sind. Dabei trat „Exon-Skipping“ als das am häufigsten auftretende AS-Events auf. Über PCR basierte Validierungs-Experimente konnten 5 regulierte Transkripte nachgewiesen werden. Dabei weisen Exon 3 und 4 in BORA, Exon 6 in MDM4 und Exon 4-5 in CSSP1 Exon-Skipping Events auf, während Exon-Inklusionen in CEP192 Exon 28 und in der 3’UTR von EIF4A2 validiert werden konnten.
Darüber hinaus wurde im Rahmen der AS-Analyse die Regulation des sogenannten „backsplicings“ bei Hypoxie untersucht. Im Gegensatz zum linearen Spleißens, wird beim backsplicing das 5’Ende und das 3’Ende von Exons verbunden, was die Bildung von sogenannten zirkulären RNAs (circRNAs) zufolge hat. Obwohl nur wenige Funktionen dieser RNA-Klasse bekannt sind, wurde die Regulation von circRNAs während der Zell-Differenzierung sowie in diversen Krebszellen beschrieben. Dabei können circRNAs als microRNA- oder Protein-Schwämme fungieren oder dienen als Protein-Interaktion Plattform und regulieren dabei die Genexpression.
The Southern Ocean (SO) is one of the most pristine regions of our Planet, characterised by high levels of biodiversity (5% of the global diversity) (David and Saucède 2015) and hosting a unique fauna (up to 90% of SO species are endemic) (De Broyer and Danis 2011; Chown et al. 2015). Yet, the knowledge on SO biodiversity is still far from being completed. In addition, the knowledge on the impact that changing environments have on SO species-richness is very little and for some groups, it is still totally unknown. For instance, most of studies generally focus on one single species such as Antarctic krill (Kawaguchi et al. 2011), Clio pyramidata Linnaeus, 1767 (Orr et al. 2005), Globigerina bulloides d'Orbigny, 1826 (Moy et al. 2009), or only on a high taxonomic level (e.g. phylum, class): Echinodermata, Crustacea, Mollusca, Porifera, Bryozoa, Brachiopoda, Hydrozoa, Ascidiacea, Holoturoidea
(Barnes 1999; Rowden et al. 2015; Post et al. 2017; Gutt et al. 2019; Vause et al. 2019; Pineda-Metz et al. 2020). Ultimately, the influence of sea-ice coverage on benthic species diversity was totally unknown prior to this study. In light of this, the objectives of the thesis are:
1. To expand the knowledge on shelf and deep-sea peracarid assemblage structure and abundance on a small regional (Weddell Sea) and on a large regional (Atlantic sector of the SO and South Atlantic Ocean) geographic scale.
2. To assess the environmental variables driving peracarid assemblage structure and abundance from the above mentioned areas.
3. To investigate SO benthic isopod species diversity from the Atlantic sector of the SO and assess the influence of environmental variables on their species-richness and composition.
4. To describe new possible peracarid species by means of integrative taxonomy, using morphological descriptions and whole genome sequencing analyses to support the species identification.
Objective outcomes: The present thesis provides new information on the abundance and assemblage structure based on 64766 peracarid crustaceans from different 28 locations within the Atlantic sector of the SO continental shelf and deep sea (Chapters I-II). These locations are characterised by different environmental conditions, for instance different sea-ice concentrations. Results from Chapters I-II confirmed the dominance of peracarid assemblages in the benthos, with amphipods being the most abundant group, followed by isopods. Sea ice was identified as the main driver shaping benthic peracarid assemblage structure (Chapter I). On a larger geographic scale and wider bathymetric range (e.g. including sampling locations from previous studies performed in the South Atlantic Ocean
and at a depth range from 160 to ~6000 m), depth was the main physical variable driving peracarid assemblage structure (Chapter III). In addition, 16157 isopod specimens from the Atlantic sector of the SO were identified to species level at a smaller scale (Chapter IV). In this case, sea ice was identified as the main physical driver affecting isopod diversity and composition among sampling locations (Chapter IV). Reduced concentration of sea ice
causes a decrease in isopod biodiversity, thus climate change was identified as a huge threat for this taxon and for SO benthos in general. During the identification process, two new isopod species were discovered (Chapter V). The two new species (Notopais sp.1 n. sp. and Notopais sp.2 n. sp.) were accurately described and identified by means of integrative taxonomy. This provided the first whole genome sequencing of benthic isopods from the SO and the first complete mitochondrial genome of the genus Notopais (Chapter V). Thanks to the collaboration with the University of Genoa (Dipartimento di Scienze della Terra dell'Ambiente e della Vita, DISTAV, Italy) and the National Antarctic Museum (MNA) in Genoa, two new SO species of the suborder Valvifera G. O. Sars, 1883 were described by means of classical taxonomy. In this case, a molecular approach could not be used because both new species were represented by a single specimen, therefore it was important to preserve the integrity of the holotypes (Chapters VI-VII).
Die Studien im Rahmen dieser Arbeit wurden am Modellorganismus Anabaena sp. PCC 7120 (Anabaena) durchgeführt, einem filamentösen Süßwasser-Cyanobakterium. Cyanobakterien sind photosynthetische, Gram-negative Organismen. Sie besitzen eine das Zytosol begrenzende Plasmamembran und eine Äußere Membran. TonB-abhängige Transporter (TBDTs) und Porine der Äußeren Membran bewerkstelligen und regulieren die Aufnahme von Nährstoffen. Typischerweise wenig abundante Substrate für den TBDT-vermittelten, aktiven Transport sind beispielsweise eisenhaltige Siderophore oder VitaminB12. Kleinere gelöste und abundante Stoffe wie Salze oder andere Ionen gelangen hingegen passiv durch Porine in das Periplasma.
In Anabaena wurden neun putative Porine identifiziert. Sieben hiervon wiesen eine porinspezifische Domänenstruktur auf (Alr0834, Alr2231, All4499, Alr4550, Alr4741, All5191 und All7614), und wurden im Rahmen dieser Arbeit näher betrachtet. Die Expression dieser sieben Gene wurde vergleichend untersucht, nachdem der Wildtyp in Standardmedium oder in Medium indem jeweils Mangan, Eisen, Kupfer oder Zink fehlte angezogen wurde. Außerdem wurde das Wachstum der einzelnen Porinmutanten im Vergleich zum Wildtyp auf Festmedium mit hohen Konzentrationen von Salzen, Antibiotika oder anderen Stoffen analysiert. Hierbei konnten den einzelnen Mutanten teilweise spezifische phänotypische Eigenschaften zugeschrieben werden. Zusammengefasst kann anhand der Analysenergebnisse vermutet werden, dass Alr4550 eine besondere Rolle in der Wahrung der Zellhüllenstabilität oder -integrität spielt, wohingegen das Fehlen von Alr5191 auf unbekannte Weise die Fixierung von Stickstoff zu erschweren scheint. Die alr2231-Mutante zeigte eine Resistenz gegenüber hohen Zinkkonzentrationen, was die Vermutung zulässt, dass Zink ein Substrat von Alr2231 darstellt. Für weitere Porine kann ebenfalls ein Zusammenhang zum Transport von Kupfer oder Mangan vermutet werden.
Neben Porinen wurden ebenfalls TonB-ähnliche Proteine in Anabaena untersucht. TonB ist ein plasmamembranständiges Protein, das in Komplex mit ExbB und ExbD die Energie für Transportprozesse über die Äußere Membran bereitstellt. Hierfür bindet TonB C-terminal an TBDTs und induziert dort Strukturänderungen, welche den Substratimport ins Periplasma ermöglichen. Als Energiequelle wird der Protonengradient genutzt, der über die Plasmamembran besteht. In Anabaena wurden vier putative TonB Proteine identifiziert, die sich jeweils in Länge und Domänenstruktur unterscheiden. Im Rahmen dieser Arbeit konnte durch Substrattransport-Experimente und Wachstumsanalysen gezeigt werden, dass TonB3 an der Aufnahme zweier Siderophore (Schizokinen und dem Xenosiderophor Ferrichrom) beteiligt ist, da die entsprechende Mutante sich als unfähig erwies diese zu als Eisenquelle nutzbar zu machen. Daneben wies TonB3 weitere Merkmale auf, die auch TonB-Proteinen anderer Organismen zugeschrieben wurden (Wachstumsdefizit der Mutante unter Eisenmangel, eisenabhängiges Expressionsprofil). Interessanterweise zeigte sich, dass das Siderophor Ferrichrom ebenfalls nicht als Eisenquelle für die tonB4-Mutante zur Verfügung stand, was zum Beispiel auf eine Beteiligung von TonB4 an dessen Transport hinweisen könnte.
TonB1, welches sich durch ein inkomplettes TBDT-Interaktionsmotiv auszeichnet, und TonB2 konnte keine Beteiligung am Siderophoretransport zugeschrieben werden, jedoch zeigten Mutanten der einzelnen Gene spezifische phänotypische Eigenschaften. Die tonB1-Mutante stach hervor durch ein vergleichsweise stark verzögertes Wachstum unter diazotrophen Bedingungen. Es konnte gezeigt werden, dass sowohl die Nitrogenaseaktivität als auch die expression vermindert war im tonB1-Mutantenstamm. Außerdem zeigten die Heterozysten dieser Mutante, die auf die Stickstoffixierung spezialisierten Zellen, eine abnormale Morphologie. Da die Expression von tonB1 jedoch nach dem Überführen von Wildypzellen in stickstoffreies Medium nicht erhöht war, kann eine direkte Beteiligung von TonB1 an der Heterozystendifferenzierung als unwahrscheinlich betrachtet werden. Die Zelleinschnürungen zwischen Heterozysten und vegetativen Zellen waren in I-tonB1 weniger ausgeprägt als im Wildtyp, was durch eine Anfärbung der Zellwand mit einem Fluoreszenzmarker gezeigt werden konnte. Ebenfalls konnte anhand des fluoreszierenden Markers Calcein gezeigt werden, dass die molekulare Diffusionsgeschwindigkeit zwischen Heterozysten und vegetativen Zellen, und auch zwischen zwei benachbarten vegetativen Zellen, in der tonB1-Mutante erhöht ist. Deswegen kann hier vermutlich vermehrt die Nitrogenase schädigender Sauerstoff in Heterozysten eindringen. Die aufgezählten Ergebnisse deuten auf eine Funktion von SjdR im Aufbau der Septumsstrukturen hin, beispielsweise durch Regulation der Peptidoglykansynthese oder -verteilung, weswegen TonB1 umbenannt wurde in SjdR (Septal junction disc regulator).
Die Untersuchung der tonB2-Mutante zeigte bei dieser eine veränderte Pigmentierung, eine vermehrte Lipopolysaccharidproduktion und Filamentaggregation sowie eine erhöhte Resistenz gegenüber bestimmten Antibiotika oder Detergenzien. Letzteres könnte auf die ebenfalls in der tonB2-Mutante beobachtete verringerte Porinexpression zurückgeführt werden. Es wurde außerdem eine vermehrte Anreicherung von Kupfer und Molybdän in der Mutante gemessen, was ein Grund für die Veränderte Pigmentierung sein könnte und ebenfalls die Porinexpression beeinflussen könnte. Insgesamt scheint sich das Fehlen von TonB2 auf die Integrität der Äußeren Membran auszuwirken. Daher kann für TonB2, eine Funktion in Anlehnung an das Tol-system vermutet werden.
Despite constant progress in basic and translational research, cancer is still one of the leading cause of death. In particular, tumors of the central nervous system (CNS) are usually associated with dismal prognosis. Although about 100 distinct subtypes of primary CNS tumors have been classified molecularly, metastases derived from primaries outside the CNS (= brain metastases, BrM) are more frequently observed across brain tumor patients. It is estimated that approximately 20 - 40 % of all cancer patients will develop BrM during their course of disease, and basically every tumor type is able to metastasize to the brain. Nevertheless, BrM are most frequently derived from primaries of the lung, breast, and skin (melanoma). Treatment options for patients with BrM are very limited, and standard of care therapies include surgery, ionizing radiation (e.g. whole brain radio-therapy, WBRT), and some systemic and immuno-therapeutic approaches.
The brain represents a unique organ, which in part is due to the presence of the blood-brain barrier, a unit of the neuro-vascular interface ensuring tightly regulated exchange of nutrients, molecules, and cells. Furthermore, apart from microglia the brain parenchyma does not harbor other immune cells. Those cells however can be found at the borders of the CNS residing in the meninges, for instance. Based on recent insight on the immune landscape in the CNS, a paradigm shift occurred after which the brain is no longer regarded as immune-privileged but rather immune distinct. The phenomenon of immune cell infiltration has been described before in the context of neurological disorders including Multiple Sclerosis, as well as in brain tumors.
Since the development of immune-therapeutic approaches for tumors outside the CNS that aim to evoke sustainable anti-tumor effects, it became increasingly interesting to understand and harness the immune landscape (= tumor microenvironment, TME) of brain tumors, as well. Interestingly, most of the knowledge about the TME is based on studies of primary brain tumors. However, it is known that BrM compared to primary brain tumors induce a different TME like e.g. the recruitment of much more lymphocytes, which is one of the reasons primary brain tumors are considered immunologically “cold” and poorly respond to immuno-therapies. Previous insight into the functional contribution of tumor-associated cells in BrM progression revealed for example that brain-resident cell types (e.g. astrocytes or microglia) promote BrM development and outgrowth. However, until recently a comprehensive view on the cellular composition and functional role of the brain metastases-associated TME was missing and little was known how it changes during tumor progression or standard therapy.
Hence, within this thesis it was sought to describe novel aspects of the TME of preclinical BrM models, which include two xenograft and one syngeneic mouse model. BrM was induced via intra-cardiac injection of tumor cells with a high brain tropism. Both xenograft models were based on immuno-compromised nude mice (Balb/c nude) and included the melanoma-to-brain (M2B) model H1_DL2, and the lung-to-brain (L2B) model H2030. In addition the breast-to-brain model 99LN-BrM was used in wild-type mice (BL6), and therefore represented an immuno-competent, syngeneic model. First BrMs could be detected in the xenograft models at 3 weeks after injection, whereas first 99LN BrMs were detected at 5 weeks. BrM development and progression were monitored by bioluminescence imaging once per week in the xenograft models. Tumor progression in the 99LN model was examined by magnetic resonance imaging. Based on the measurement methods, and for further histologic and cytometric experiments, mice were stratified into groups with small or large BrMs, respectively. Some initial immuno-stainings confirmed previous findings, showing that brain-resident cells like astrocytes and microglia become activated in the presence of tumor cells, whereas neurons for example rather give the impression of passive bystanders. Importantly, an accumulation of IBA1+ cells was observed during BrM progression. IBA1 is a pan-macrophage marker that stains all tumor-associated macrophages (TAMs). However previous work suggested that the TAM population consists of at least two main subpopulations in BrM as well: the resident-infiltrating microglia (MG, TAM-MG), as well as the peripheral and monocytic-derived macrophages (TAM-MDM). Since both cell types within the tumor share morphological traits, and due to the lack of markers to distinguish them, an exact discrimination of both cell types was complicated in the past. Recently, an integrative lineage-tracing-based study identified the integrin CD49d as MDM-specific in the context of brain tumor-associated myeloid cells, hence enabling a reliable dissection of both TAM populations in e.g. flow cytometric experiments.
One of the main aims of this thesis was to dissect the myeloid TME in the three different BrM models during tumor progression. Using a 5-marker flow cytometry (FCM) (CD45/CD11b/Ly6C/Ly6G/CD49d) approach, the following cell populations were examined in more detail: granulocytes, inflammatory monocytes, MDM, and MG.
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Clonal hematopoiesis of indeterminate potential (CHIP) is caused by recurrent somatic mutations leading to clonal blood cell expansion. However, direct evidence of the fitness of CHIP-mutated human hematopoietic stem cells (HSCs) in blood reconstitution is lacking. Because myeloablative treatment and transplantation enforce stress on HSCs, we followed 81 patients with solid tumors or lymphoid diseases undergoing autologous stem cell transplantation (ASCT) for the development of CHIP. We found a high incidence of CHIP (22%) after ASCT with a high mean variant allele frequency (VAF) of 10.7%. Most mutations were already present in the graft, albeit at lower VAFs, demonstrating a selective reconstitution advantage of mutated HSCs after ASCT. Thus, CHIP-mutated stem and progenitor cells largely gain on clone size upon ASCT-related blood reconstitution, leading to an increased future risk of CHIP-associated complications. CHIP increase with age and is also associated with atherosclerosis and inflammation. Age and inflammation are the major risk factors for heart failure, yet the association of CHIP with chronic ischemic heart failure (CHF) in humans is unknown. Therefore, we analyzed bone marrow-derived mononuclear cells from 200 patients with CHF by NGS to detect the presence of CHIP and associated such with long-term prognosis in patients with CHF. Forty-seven mutations with a VAF of at least 2% were found in 18.5% of 200 patients with CHF. The mutations most commonly occurred in the genes DNMT3A and TET2. During a median follow-up of 4.4 years, a significantly worse clinical outcome for patients with either DNMT3A or TET2 mutations compared with non-CHIP carriers was notable. Importantly, there was a significant dose-response association between VAF and clinical outcome. Our data suggest that somatic mutations in hematopoietic cells, may be significantly associated with the progression and poor prognosis of CHF.
The central dogma of biology is based on the concatenated transfer of information from DNA, via transcribed mRNA, to the translated protein. In eukaryotes, transcription and translation are separated locally as well as temporally by cellular compartmentalization. Prior to active export factor-dependent transport from the nucleus to the cytosol, the newly formed pre-mRNA must mature. This involves 5'capping, splicing, and endonucleolytic cleavage and polyadenylation (CPA).
Transcription of a new pre-mRNA is terminated by hydrolytic cleavage in the 3'-UTR, and the newly formed 3'-end is protected from premature degradation by synthesis of a poly(A) tail. These processes are catalyzed by four multi-protein complexes (CFIm, CFIIm, CPSF, and CsTF) and poly(A) polymerase (PAP). CPA is sequence-specific and dependent on RNA-binding proteins (RBPs). APA-specific sequences include the poly(A) motif ('AAUAAA' and certain motif variants), the UGUA motif, and U/GU-rich sequences upstream and downstream of the poly(A) signal, respectively. About 70% of mammalian genes have more than one polyadenylation site (PAS) and express transcripts of different lengths by a mechanism called alternative polyadenylation (APA). This can affect the length of the 3'UTR (3'UTR-APA) or the coding sequence of the transcript (CDS-APA) if the alternative PAS is upstream of the STOP codon. The length of the 3'UTR affects the stability, export efficiency, subcellular localization, translation rate, and local translation of the nascent transcript. 3'UTR-APA is regulated in the interplay of the cis-elements (poly(A) motif, UGUA and U/GU) and trans-elements (expression of CPA factors). In this context, the functions of the individual cis and trans elements have been extensively studied, yet the regulation of alternative polyadenylation-the decision whether to use the proximal or distal PAS-is less deciphered and requires additional study.
In murine P19 cells, we were able to demonstrate for the first time a direct link between 3'UTR-APA and nuclear export of mature mRNA by the splicing factors SRSF3 and SRSF7 and decipher the mechanism. At the core here is the direct recruitment of the export factor NXF1 by SRSF3 and SRSF7 to transcripts with 3'UTRs of different lengths.
The primary goal of the thesis presented here was to decipher the function of SRSF3 and SRSF7 in the regulation of 3'UTR-APA and to determine the basic mechanism. For this purpose, various genome-wide methods, such as RNA-Seq, MACE-Seq, and iCLIP-Seq, were integrated and the findings were supported by reporter gene and mutation studies.
Initial determination of the poly(A)-tome in P19 cells by MACE-Seq yielded approximately 16,000 PAS and showed that slightly less than 50% of all genes used two or more PAS and expressed alternative 3'UTR isoforms. Further DaPARS analyses after knockdown of Srsf3 or Srsf7 confirmed that SRSF3 affected more transcripts than SRSF7 and led primarily to the expression of long 3'UTRs, whereas SRSF7 promoted the expression of short 3'UTRs. Integration of SRSF3- and SRSF7-specific iCLIP data suggested a possible competition between SRSF3 and SRSF7 at the proximal PAS (pPAS), which could thus act as a hotspot of 3'UTR regulation.
Experiments with intron-free reporter genes revealed that SRSF3- and SRSF7-dependent regulation of 3'UTR-APA is independent of splicing. With respect to SRSF7, a concentration dependence was demonstrated. Mutation experiments involving the SRSF3- and SRSF7-specific binding motifs in the 3'UTR also confirmed the hypothesis of competition between the two SR proteins.
Extensive Co-IP experiments clearly demonstrated that only SRSF7, but not SRSF3, can interact with CFIm and FIP1 (a subunit from the CPSF complex) in an RNA-independent manner. In addition, we showed that these interactions exhibited some phosphorylation dependence, such that the interaction to FIP1 arose primarily in the semi- to hypophosphorylated state of SRSF7. Whereas the interaction to CFIm was mainly detected in the hyperphosphorylated state. The differential affinity between SRSF3 and SRSF7 for polyadenylation factors could be attributed to two SRSF7-specific domains in subsequent mutation experiments: A CCHC-type Zn finger between the RRM and the RS domain, and a hydrophobic 27 amino acid long region in the middle of the RS domain. Together, this suggested that SRSF3 could block the utilization of pPAS, whereas SRSF7 could activate it by directly recruiting polyadenylation factors.
Interestingly, we showed that knockdown of Srsf3 also negatively regulates the expression of Cpsf6 (a subunit of CFIm) through alternative splicing, which subsequently leads to decreased expression of CPSF6 and of CFIm. Reduction of CFIm led to increased expression of transcripts with short 3'UTR, analogous to knockdown of Srsf3. This mirrors the results of previous studies. A direct comparison between SRSF3- and CPSF6-specific transcripts revealed that not all targets were congruent. In addition, we found preliminary evidence for CFIm-related masking of essential cis-pPAS elements by bimodal UGUA motifs at the pPAS. In summary, we present a novel mechanism of indirect 3'UTR-APA regulation through SRSF3-conditional expression of the CFIm subunit CPSF6.
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Die Bildung von Blutgefäßen ist essentiell für die Entwicklung und Homöostase von Wirbeltieren und die Endothelzellspezifikation ist ein wichtiger erster Schritt in diesem Prozess. Das früheste bekannte Ereignis bei der Endothelzellspezifikation im Zebrafisch ist die Expression des bHLH-PAS-Transkriptionsfaktor-Gens npas4l. Ich habe eine transgene V5-Linie zum Nachweis des markierten Npas4l auf Proteinebene und eine Gal4-VP16-Reporterlinie zur Visualisierung und Verfolgung von npas4l exprimierenden Zellen in vivo generiert. Beide Linien können bereits in frühen Entwicklungsstadien nachgewiesen werden und komplementieren auch starke npas4l-Mutanten Allele. Um npas4l Reporter exprimierende Zellen in npas4l Mutanten zu verfolgen, habe ich anschließend eine mutierte Variante der Gal4-Reporterlinie erzeugt. Diese Mutante trägt eine Insertion in der Region, die die DNA-Bindedomäne kodiert. Dadurch stört sie die Npas4l-Funktion, aber nicht die Reporterexpression. Dieses mutierte Reporterallel komplementiert nicht die npas4l-Mutanten und zeigt einen starken Phänotyp, was darauf hindeutet, dass es sich um ein funktionelles Nullallel handelt. Phänotypische Analysen zeigten, dass npas4l-Reporter positive Zellen in npas4l-Mutanten nicht spezifizieren oder zur Mittelachse wandern. Stattdessen tragen sie zu den vom intermediären Mesoderm abgeleiteten pronephrischen Tubuli und dem vom paraxialen Mesoderm abgeleiteten Skelettmuskel bei. Ich habe diese Phänotypen durch Einzelzell-RNAseq an den npas4l-Reporter positiven Zellen in npas4l+/- und npas4l-/- Embryonen bestätigt. Zusammen erklären diese beiden alternativen Zellschicksale den Großteil der beobachteten Veränderungen zwischen den Genotypen. Npas4l ist dafür bekannt die Expression der drei Transkriptionsfaktorgene etsrp, tal1 und lmo2 zu fördern. Ich stellte die Hypothese auf, dass das Fehlen jedes dieser Transkriptionsfaktoren in npas4l-Mutanten verschiedene Aspekte des npas4l-Phänotyps verursacht. Daher habe ich Mutantenlinien für alle drei Gene generiert und sie sowohl in vaskulären Reporterlinien als auch im npas4l-Reporterhintergrund analysiert. Die Daten legen nahe, dass verschiedene Gene unterschiedliche Prozesse während der frühen Endothelentwicklung regulieren. In npas4l-/- und etsrp-/- Embryonen differenzieren npas4l-Reporter exprimierende Zellen nicht zu Endothelzellen und tragen stattdessen zur Skelettmuskelzellpopulation bei. In npas4l-/- und tal1-/- Embryonen können npas4l-Reporter exprimierende Zellen nicht migrieren und tragen stattdessen zu der Bildung der pronephrischen Tubuli bei. Um die Beziehung zwischen diesen Faktoren besser zu verstehen, habe ich getestet, ob die Injektion von etsrp-, tal1- oder lmo2-mRNA verschiedene Aspekte des npas4l-Phänotyps retten würde. npas4l-, etsrp- und tal1-Mutanten zeigen alle schwere vaskuläre Phänotypen. Einige Endothelzellen und vaskuläre Strukturen bleiben jedoch in jeder Mutante erhalten. Der Phänotyp ist am stärksten in npas4l-/- Embryonen, aber selbst in diesen Embryonen können einige fli1a-positive Endothelzellen in der Schwanzregion beobachtet werden. Es war unklar, ob sich diese Population von Endothelzellen unabhängig von der Npas4l-, Tal1- und Etsrp-Funktion entwickelt oder als Folge einer restlichen tal1- oder etsrp-Expression unabhängig von Npas4l. Um diese Frage zu untersuchen, habe ich Doppelmutanten generiert und nach dem Vorhandensein von fli1a-positiven Endothelzellen in diesen Mutanten gesucht. Während fli1a-positive Endothelzellen in npas4l-/- und npas4l-/-;tal1-/- Embryonen deutlich vorhanden sind, können keine solchen Zellen in npas4l-/-;etsrp-/- oder etsrp-/-;tal1-/- Embryonen beobachtet werden. Diese Daten deuten darauf hin, dass sich im Zebrafisch keine Endothelzellen entwickeln können, wenn zugleich npas4l und etsrp oder etsrp und tal1 gestört sind. Während der Verlust von etsrp zu stärkeren Defekten in npas4l-Mutanten führt, gibt es keinen zusätzlichen Phänotyp, der durch den Verlust von tal1verursacht wird, was darauf hindeutet, dass die Expression von etsrp, aber nicht die von tal1, unabhängig von Npas4l auftreten kann. Diese Idee wird durch die Beobachtung unterstützt, dass etsrp, aber nicht tal1-Expression in den meisten fli1a-exprimierenden Zellen in npas4l-/- Embryonen beobachtet wird. Dennoch wird der Großteil -Expression durch Npas4l reguliert. tal1-mRNA-Injektionen reichten aus, um eine Wildtyp-ähnliche vaskuläre Musterbildung im Bauchbereich der npas4l-/- Embryonen wiederherzustellen, einschließlich der Rettung sowohl der Zellmigration als auch der Differenzierung. Da Npas4l mehrere unterschiedliche transkriptionelle Effektoren hat, war eine so starke Rettung durch nur einen dieser Effektoren unerwartet. In den geretteten Mutanten wurde die bilaterale Population von npas4l-Reporter-positiven pronephrischen Tubuluszellen nicht entdeckt, aber die Anzahl der ektopischen npas4l-Reporter exprimierenden Muskelzellen war im Vergleich zu nicht injizierten npas4l-Mutanten gleichbleibend.
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Until quite recently, stem cell technology mainly focused on pure populations of embryonic stem cells (ES) derived from the inner cell mass of the blastocyst and induced pluripotent stem cells (iPS). Using organoids, a newly established culture technique, it is now possible to culture also organ and patient-specific adult stem (AS) and induced pluripotent stem (IPS) cells in vitro. Furthermore, it has been shown that adult stem cells, grown as organoids, are genetically stable, proliferate and maintain their multi-potency (often a bi-potency) for months. This is possible by providing conditions that recapitulate the stem cell niche of the corresponding organ. Particularly, defined growth factors and a physiological scaffold, which is provided by an extracellular matrix (ECM). Because of increasing research activities, organoids became influential in the recent years. Wide-ranging interest also led to a clearer definition: organoids must contain multiple organ-specific cell types, must be able to recapitulate some organ specific functions, and the cells must be spatially organized in a way similar to the organ they are derived from. The excitement about organoids is based on their high potential as a model to understand wound healing, cellular behaviour and differentiation processes in organogenesis. Furthermore, high potential in the drug development and in personalized stem cell therapeutic approaches has been shown. Specifically, for personalized stem cell therapy, one potential application is for chronic autoimmune diseases such as Diabetes type 1 (T1D). T1D is characterized by the immune-mediated destruction of ß-cells in the Pancreas that leads to absolute insulin deficiency. In T1D the first-line therapeutic approach is exogenous insulin replacement therapy, which always implicates the risk of high fluctuations in blood-sugar levels and therefore the risk of hypoglycaemia. Another therapeutic approach is the xenotransplantation of islets from human donors. A successful islet transplantation allows patients a years-long insulin independence. However, the therapeutic value of islet transplantation is highly limited by the availability of organ donors and by the need for chronic administration of immune suppressive medication. The use of pancreas organoids offers a promising alternative as a personalized cell therapeutic approach to treat T1D without the hypoglycaemia risks of the established therapies. In 2013 Meritxell Huch and colleagues established for the first-time organoids from the exocrine, ductal part of the pancreas. These pancreas organoids are characterized by a monolayered, spherical cell epithelium which comprises a liquid filled lumen. In addition, they showed that after transplantation of these cells into immunodeficient mice, they differentiate into ß-cells and cure T1D. However, basic knowledge of the culture growth behaviour is still lacking: to date, no growth parameters are defined and reliable and robust investigation approaches are still missing. Furthermore, basic knowledge about the organoid development and biochemical/biophysical mechanisms that generate the phenotypic structure are not identified. For a clinical approach these parameters are fundamental and therefore must be defined pre-clinically.
The aim of this study is the preclinical characterization of the hPOs...
Coupling between epidermis and amphid morphogenesis during embryonic development of C. elegans
(2021)
Sensory organs are fundamental for survival of animal populations, since the detection of environmental stimuli is crucial for localization of nourishment, predators or mating partners. In nematodes, the amphid (AM) sensilla are the largest sensory organs for detection of chemical compounds.
This study investigates how the AM sensilla acquire their special elongated shape during lima-bean to 1.5-fold embryonic stages of C. elegans head development. The dissertation also examines events facilitating the morphogenesis of other head sensilla (IL/OL/CEP) and addresses aspects of general embryonic head morphogenesis. Using high resolution live-cell imaging techniques with different combinations of markers highlighting specific tissues, this study shows that epidermal head enclosure, migration of AM socket cells (pores) and translocation of AM dendrite tips are coupled processes, facilitating the elongation of AM dendrites. Importantly, during AM dendrite elongation the AM neural cell bodies are staying stationary. Manipulation through conducting UV-Laser ablation (epidermis close to pore/pore) and RPN-6.1 dsRNA interference resulted in compromised AM pore migration and impaired dendrite elongation. This leads to the conclusion that AM pores need to be physically attached (through C. elegans apical junctions, CeAJ) to the migrating epidermal sheet and to AM dendrite tips for successful AM morphogenesis. This study infers that RPN-6.1 plays an important role for correct AM pore morphogenesis and AM pore to AM dendrite tip attachment. Our results lead to the conclusion that head enclosure drives AM pore migration and AM dendrite elongation with AM neural cell bodies staying stationary. Thereby, CeAJ are interconnecting AM dendrite tips to AM pores and CeAJ link the sensillar ending to the migrating epidermis. Thus, migration of attached target tissue (pore), with neural cell bodies staying stationary (constituting an abutment), creates a pulling force facilitating AM dendrite elongation. This passive neurite elongation procedure is coined dendrite towing in this study.
Additionally, this study discovers that translocation of IL, OL and CEP head sensilla pores is influenced by apical constriction. This conclusion was made based on the findings that IL/OL/CEP pores migrate towards the prospective mouth anterior to the epidermal leading edge, separated from AM pores and irrespective of highly impaired AM sensilla morphogenesis after strong RPN-6.1 depletion. Also, concurrent with translocation of IL/OL/CEP pores, bottle-shaped cells occur and non-muscle-myosin and apical polarity factors are getting enriched at the anterior most part of the head, indicating de-novo manifestation of apical constriction. It is furthermore assumed that apical constriction in arcade cells might contribute to early pharynx development. All in all, this study reveals two force-generating events: Head enclosure-driven AM sensilla morphogenesis via dendrite towing and, otherwise, apical constriction-facilitated translocation of IL/OL/CEP sensilla pores. These events can get separated by graded depletion of the proteasome activator RPN-6.1.
Thermoanaerobacter kivui ist ein thermophiles acetogenes Bakterium, das chemolithoautotroph auf CO2 unter Verwendung von molekularem H2 als Elektronendonor wächst und Acetat als Produkt über den Wood-Ljungdahl-Weg (WLP) bildet. Im WLP werden 2 Mol CO2 reduziert, um ein Mol Acetyl-CoA zu bilden. Erste Studien wurden durchgeführt, um die Physiologie von T. kivui zu verstehen. T. kivui wächst autotroph auf H2 + CO2 und nach Adaptation auch auf CO oder Syngas. T. kivui wächst ebenfalls auch in Minimalmedium ohne weitere Zugabe von Vitaminen, was es zu einem Biokatalysator mit hohem Potenzial für die Produktion von Chemikalien mit hohem Mehrwert macht. Heterotroph wächst T. kivui auf Glucose, Fructose, Mannose, Pyruvat oder Formiat. Kürzlich wurde beschrieben, dass T. kivui in der Lage ist, auf dem Zuckeralkohol Mannitol in Gegenwart und Abwesenheit von HCO3- (oder externem CO2) zu wachsen. Allerdings war das Wachstum in Abwesenheit von externem CO2 deutlich verlangsamt. Daher wurde in dieser Studie getestet, ob eine Zugabe von externem Formiat das "fehlende" CO2 kompensieren kann. In Kombination mit Formiat wurde das Wachstum auf Mannitol in CO2 und HCO3- freien definierten Medien bis zu einer maximalen OD600 von 2,34 und mit einer Verdopplungszeit von 2,0 ± 0,0 stimuliert, was dem Wachstumsverhalten auf Mannitol in Anwesenheit von CO2/HCO3- entsprach. In Abwesenheit von Formiat (oder CO2) erreichte T. kivui nur eine endgültige optische Dichte von bis zu 0,7 mit einer verlängerten Verdoppelungszeit von 5,2 ± 0,2 Stunden. Dieses Experiment zeigte die höhe metabolische Flexibilität von T. kivui durch die Nutzung von Formiat als Elektronenakzeptor, wenn kein oder nur wenig CO2 vorhanden ist.
Genomanalysen ergaben, dass T. kivui ein Trehalose- und Maltose-Transportsystem-Permeaseprotein (MalF) besitzt. Darüber hinaus verfügt T. kivui über Trehalose- und Maltosehydrolase-Gene, die als Kojibiose-Phosphorylase annotiert sind. Obwohl in der Originalveröffentlichung beschrieben wurde, dass der Organismus nicht auf Maltose oder Trehalose wachsen kann, konnte T. kivui im Laufe dieser Arbeit an das Wachstum auf Maltose und Trehalose adaptiert werden. Nach dem Transfer von einer Glukose-Vorkultur auf ein Medium mit 25 mM Maltose oder 25 mM Trehalose als alleinige C-Quelle wurde kein Wachstum erzielt. Bei Verwendung der gleichen Vorkultur in einem Medium mit höherer Konzentration (50 mM) Maltose oder Trehalose, begannen die Zellen zu wachsen. Bei Verwendung dieser adaptierten kulturen als Vorkultur wuchsen die Zellen in Gegenwart von in 25 mM Maltose oder Trehalose bis zu einer maximalen OD600 von 1,12 bzw. 0,73. Die Adaptation hing mit der Tatsache zusammen, dass der Organismus eine höhere Konzentration benötigt, um sich an diese Kohlenstoffquellen zu gewöhnen. Durch diese Daten wird das heterotrophe Potenzial von T. kivui erhöht.
Um die Bedeutung der wasserstoffabhängigen Kohlendioxidreduktase (HDCR) während des Wachstums auf Formiat oder auf H2 + CO2 im Stoffwechsel von T. kivui zu verstehen, wurden Studien auf molekularer Ebene durchgeführt. Die HDCR nutzt H2 direkt für die Reduktion von CO2 zu Formiat im ersten Schritt des Wood-Ljungdahl-Wegs (WLP). Um die Rolle der HDCR in dieser Reaktion zu untersuchen, wurde das hdcr-Gencluster mit Hilfe des kürzlich entwickelten Mutagenesytems für T. kivui deletiert. In Wachstumstudien konnte anschliessend gezeigt werden, dass die ߡhdcr-Deletionsmutante nicht mehr auf Formiat oder H2 + CO2 als alleiniger Kohlenstoffquelle wachsen konnte. Nach Komplementation der Mutante mit dem hdcr-Gene in cis wuchsen die Kulture wieder auf Formiat oder H2 + CO2. Diese Experimente zeigten, dass die HDCR für das Wachstum auf H2 + CO2 oder Formiat essentiell ist. Interessanterweise konnte in der ߡhdcr-Mutante ebenfalls ein verändertes Wachstum auf Glukose als alleiniger C-Quelle festgestellt werden. Die T. kivui ߡhdcr-Mutante wuchs nur bis zu einer OD600 von 0,2, während der Wildtyp und der hdcr-komplementierte Stamm bis zu einer OD600 von 2,64 bzw. 2,4 wuchsen. Damit wurde bewiesen, dass die HDCR auch für die vollständige Glukoseoxidation in T. kivui erforderlich ist. Durch die Zugabe von Formiat wurde das Wachstum vollständig wiederhergestellt, ähnlich wie beim Wildtyp. Dies belegt wieder die Nutzung Formiat als terminalen Elektronenakzeptor. Auch auf Mannitol oder Pyruvat konnte die Mutanten nur in Gegenwart von Formiat wachsen. Der Substratverbrauch und die Produktbildung der T. kivui ߡhdcr-Mutante wurden in einem Zellsuspensionsexperiment untersucht. Die Zellen verbrauchten Formiat nur in Gegenwart von Glukose und produzierten Acetat mit einem Acetat/Substrat-Verhältnis von etwas mehr als 3,0, während die Acetatproduktion nur 12 mM betrug, wenn Glukose als alleiniges Substrat verwendet wurde. Diese Ergebnisse zeigen eine enge Kopplung der Oxidation von Multikohlenstoffsubstraten an den WLP.
T. kivui ist eines der wenigen Acetogenen, die CO als einzige Kohlenstoff- und Energiequelle nutzen können. ...
The blood-brain barrier (BBB) protects the brain microenvironment from external damage. It is formed by endothelial cells (ECs) lining the brain vessels, expressing tight junctions and having reduced transcytosis, resulting in a very low paracellular and transcellular passage of substances, respectively (low permeability). The specific BBB phenotype is maintained by Wnt molecules secreted by astrocytes (ACs) that bind to receptors in ECs, and start a molecular cascade that leads to β-catenin translocating to the nucleus and activating the transcription of BBB genes.
An increasing number of studies report BBB dysfunction in Alzheimer’s disease (AD), although the topic is currently under debate. AD is a neurodegenerative condition characterized by brain depositions of Aβ aggregates and Tau neurofibrillary tangles. The aetiology of AD is unknown, although round 5% of all AD cases have a genetic origin. Mutations in APP or PSEN1/2 can lead to Aβ over-production and accumulation, causing familiar AD. There is no cure for AD, as all clinical trials failed during the past years. Consequently, I studied the role of the BBB in AD, aiming to investigate if a BBB dysfunction occurs in AD, and to identify by transcriptomic analysis novel gene regulations happening at the BBB in AD. The final objective was to evaluate the potential of identified BBB genes as therapeutical target.
I used transgenic mice expressing the human APP mutations Swiss, Dutch and Iowa under the control of the neuronal promoter Thy1 (Thy1-APPSwDI) as AD model. In this AD mouse model, I could detect Aβ deposits and memory loss by immunofluorescence (IF) and behavioural tests. Importantly, I identified an increase of BBB permeability to 3-4 kDa dextrans in 6 months, 9-12 months, and 18 months or older AD mice compared to age-matched control wild types (WT), indicating BBB dysfunction in AD mice.
In order to study the BBB transcriptional changes in AD, I sequenced the RNA from 6 and 18 months old AD and WT mouse brain microvessels (MBMVs), as well as of FACS-sorted ECs, mural cells (MuCs), ACs, and microglia (MG) in collaboration with GenXPro, a company specialized in 3’ RNA sequencing. Currently, no transcriptomic datasets of ECs and MuCs are publicly available, suggesting that this is the first study sequencing those cell types in the context of AD.
The analysis of sequencing data from MBMVs and ECs revealed a Wnt/β-catenin repression, and an increase of inflammatory genes like Ccl3 in ECs, that could explain the BBB dysfunction observed in AD mice. Furthermore, the sequencing data from MuCs identified a set of 11 genes strongly regulated in both 6 and 18 month AD groups. Three of those 11 genes are known to be involved in inflammatory processes, demonstrating that inflammation affects and plays an important role in MuCs and ECs during AD.
Thanks to published sequencing data, some up-regulated MG genes in AD are well known and recognized, such as Trem2 and Apoe. Those genes were found in the FACS-sorted MG data as well, validating the AD model and with it, the other novel sequenced datasets. Importantly, one of the most strongly AD-regulated genes in MBMV and MG samples was Dkk2, a member of the Dickkopf family of secreted proteins known to be involved in Wnt signalling modulation. Importantly, a dual luciferase reporter assay proved that Dkk2 is a Wnt inhibitor. A preliminary immunohistochemistry examination of DKK2 in human brain autopsy tissue from an AD patient and age-matched control revealed a stronger DKK2 immunoreactivity in the AD brain.
In order to answer the question whether a rescue of BBB function would ameliorate AD symptoms, I made use of a tamoxifen-inducible transgenic mouse line to activate the Wnt/β-catenin pathway specifically in ECs, leading to a gain of function (GOF) condition (Cdh5-CreERT2+/–/Ctnnb1(Ex3)fl/fl). This mouse line was then crossed with the AD line, creating AD/GOF and AD/control groups.
AD/GOF mice performed better in a Y-Maze memory test than AD/controls when the Wnt/β-catenin pathway was induced before AD onset, indicating a protective effect. Moreover, the finding implies that shielding BBB functioning in AD further protects the brain from AD toxic effects, suggesting an important role of brain vasculature in AD and its potential as therapeutic target.
This manuscript-based thesis is divided into four chapters. Chapter one is an introduction to lichens and the Antarctic. It introduces the goal of the thesis and the problems related with lichen systematics and the lack of knowledge about Antarctic lichens. The Antarctic is one of the last wildernesses, isolated from the other continents by the Antarctic Circumpolar Current, the Subantarctic Front, the Antarctic Polar Front, and the Drake Passage. Terrestrial life in Antarctica is restricted to widely separated and small ice-free areas that cover only 0.3% of the continent. Colonization of the Antarctic is a challenge for many taxa and is related to their ability for long-range dispersal and their adaptation to the harsh climate. Antarctic terrestrial ecosystems are significantly threatened by climate change, invasive species, and their interactions. Glacial retreat caused by higher than average temperatures exposes new habitats that can be easily colonized from local biota, but non-native species can also be favored by the new climatic conditions. In addition, propagule movement mediated by humans can introduce new species or change the population structure of many taxa. The terrestrial biota is comprised almost exclusively by “lower organisms” (invertebrates, bryophytes, algae, lichenized fungi, and microorganisms). Lichens are the dominant component, and the most important primary producers. Lichens are symbiotic associations consisting of a fungus (mycobiont) and one or more photosynthetic (photobiont) partners. They can disperse sexually or vegetatively. There are several problems related to the symbiotic nature of lichens that do not facilitate easy identification; although molecular data offers additional evidence, species delimitation in lichens is still not straightforward. The true number of species is underestimated due to the presence of cryptic species and species pairs. Recommended universal fungal barcode sequences (e. g. ITS) sometimes fail to delimit species pairs. Thus, it is necessary to identify fast-evolving markers that allow for the delimitation of closely related species before proceeding with the analysis of lichen populations. The goal of this thesis is to elucidate the so far unknown genetic structure among Antarctic lichen populations because of the immediate consequences for conservation strategies. The thesis focuses not only on patterns of differentiation and gene flow, but also investigates the question of human-mediated propagule transfer into Antarctica and among Antarctic sites. This project provides data on the genetic structure of Antarctic lichens that is urgently needed to develop conservation strategies in the face of global warming and increased human activities in the region. Due to the fact that it is not possible to apply all of the unspecific fingerprinting methods to lichens, microsatellites or simple sequence repeats (SSRs) are one of the best tools to investigate the genetic structure of lichen populations. SSRs offer the possibility to discriminate the lichen partners, but species-specific microsatellites have been developed for only a few species. Regarding the Antarctic, only one species has been studied with SSRs.
The second chapter describes new methods and tools to delimit closely related species of lichens and provides fast evolving markers to characterize their genetic structure. The chapter introduces the lichen species analysed in this thesis and the problems related to their correct identification by morphological methods and molecular data. Chapter two explains the sampling methods for lichen populations and the localities from small areas in which the species pairs occur together. Then the methods used to generate and validate fungal specific microsatellites that cross-amplify species pairs are described. This chapter focuses on the species pair Usnea antarctica and U. aurantiacoatra because they are the most common lichens in the Maritime Antarctic. An internal transcribed spacer (ITS) marker do not discriminate between these species, and some authors have suggested to synonymize them. Unpublished results from another Antarctic species pair, Placopsis antarctica and P. contortuplicata, are included to confirm the capability of SSRs to discriminate closely related lichen species. This thesis is the first study to generate SSRs that cross amplify species pairs, using BLAST to compare one genome against the other to obtain markers with the same length in flanking regions. The de novo developed SSRs are able to discriminate the two closely related species, and can detect variability at the population level. In the end of the chapter, ITS sequences, microsatellites, and SNPs are used to delimit the species of Usnea antarctica and U. aurantiacoatra. The chapter exposes the importance of a correct species delimitation and the ability of SSRs and SNPs to delimit the Antarctic Usnea species pair compared with the recommended universal fungal barcode sequence ITS. ...
As fossil resources are diminishing, environmental concerns arise and chemical synthesis often involves expensive catalysts or extensive extraction procedures, the demand for production of industrially relevant compounds from renewable resources increases. In this context, engineering microorganisms for production of specialty chemicals, such as 3-alkylphenols, presents an attractive, environmental-friendly approach. 3-alkylphenols have various applications: due to their antiseptic and stabilizing properties many 3-alkylphenols, including 3-methylphenol (3-MP), are utilized as additives in disinfectant reagents and biological products, while they can be also implemented as platform chemicals for production of lubricating oil additives or flavors. Some 3-akylphenols have potential for transmission control of the disease sleeping sickness that is transmitted by tsetse flies in sub-saharan Africa, since 3-ethylphenol (3-EP) and 3-propylphenol (3-PP) and to a lesser degree 3-MP were found to attract tsetse flies and improved catch rates in impregnated tsetse fly traps. Microbial fermentation of 3-alkylphenols would provide a simple and inexpensive way for local communities in Africa to produce these compounds and prepare their own tsetse fly traps.
Some molds synthesize 3-MP as an intermediate during biosynthesis of the mycotoxin patulin. However, the heterologous host Saccharomyces cerevisiae has advantageous traits for industrial application, since it is well characterized, robust, simple to handle and easily genetically accessible. In this thesis, genetical engineering approaches were utilized to establish the yeast S. cerevisiae for biotechnological production of 3-alkylphenols. As a proof of concept, the iterative polyketide synthase from Penicillium patulum, 6-methylsalicylic acid synthase (MSAS), and 6-methylsalicylic acid (6-MSA) decarboxylase PatG from Aspergillus clavatus were heterologously expressed in S. cerevisiae resulting in the first reported de novo biosynthesis of 3-MP via 6-MSA in yeast from sugars (Hitschler & Boles, 2019). It was shown that codon-optimization and genomic integration of heterologous genes, high initial cell densities and a balanced expression of PatG were beneficial for heterologous production of up to 589 mg/L 3-MP in S. cerevisiae. However, toxicity of 3-MP limited higher product accumulation.
Different in vivo detoxification strategies were implemented to face this bottleneck. Growth tests revealed that 3-methylanisole (3-MA) is less toxic to the yeast cells than 3-MP. Expression of an orcinol-O-methyltransferase from chinese rose hybrids (OOMT2) was combined with in situ extraction converting the toxic 3-MP product into the volatile 3-MA and accumulating up to 211 mg/L 3-MA in the dodecane phase. Alternatively, up to 533 mg/L 3-MP glucoside were synthesized by expression of a UDP-glycosyltransferase (UGT72B27) from Vitis vinifera in the 3-MP producing strain, revealing saccharose as beneficial carbon source and ethanol growth phase as essential for high 3-MP production, although 3-MP conversions were not yet complete. Both detoxification strategies allowed circumvention of the toxicity imposed limited product accumulation. This was demonstrated when both detoxification strategies were combined with redirection of the carbon flux through deletion of phosphoglucose isomerase gene PGI1 and feeding a mixture of fructose and glucose leading to majorly improved product formation, with up to 899 mg/L 3-MA/3-MP and 873 mg/L 3-MP/3-MP glucoside, compared to less than 313 mg/L product titers in the wild type controls (Hitschler & Boles, 2020).
For provision of the tsetse fly attractants 3-EP from propionyl-CoA and 3-PP from butyryl-CoA, the substrate promiscuities of MSAS and PatG were exploited. However, slower formation rates with the alternative substrates propionyl-CoA and butyryl-CoA suggested that competing formation of 6-MSA from the preferred priming unit acetyl-CoA was dominating in vivo. Indeed, 3-EP or 3-PP formation was not observed in 3-MP producing yeast strains. Assuming that intracellular levels of propionyl-CoA and butyryl-CoA were limiting 3-EP and 3-PP formation, different strategies were implemented to raise the supply of these alternative priming units and successfully compete with acetyl-CoA for MSAS priming.
Supplementation of propionate increased propionyl-CoA levels by endogenous pathways sufficiently to enable 3-EP formation in yeast mediated by MSAS and PatG. Deletion of the 2-methylcitrate synthases CIT2 and CIT3 revealed that degradation of propionyl-CoA was not limiting 3-EP formation at this stage. In order to raise propionyl-CoA levels further, a heterologous propionyl-CoA synthase (PrpE) was expressed in the 3-MP producing yeast strain leading to up to 12.5 mg/L 3-EP with propionate feeding and blockage of degradation. Moreover, PrpE enabled also 3-EP formation without propionate supplementation suggesting that an endogenous supply of propionate existed that was reactivated by PrpE. As threonine or 2-ketobutyrate feeding increased 3-EP titers in combination with PrpE, this indicated that threonine degradation via 2-ketobutyrate was responsible for the endogenous propionate supply. Moreover, expression of branched-chain ketoacid dehydrogenase complex from Pseudomonas putida combined with PrpE provided propionyl-CoA from endogenous 2-ketobutyrate and raised 3-EP titers up to 5.9 mg/L compared to 2.8 mg/L with only PrpE indicating a potential route for optimization of 3-EP titers independent of propionate or threonine feeding.
For 3-PP production from butyryl-CoA, a heterologous ‘reverse ß-oxidation’ pathway was introduced in the 3-MP producing yeast strain providing sufficient butyryl-CoA for biosynthesis of up to 2 mg/L 3-PP. Degradation of the precursor via ß-oxidation was slightly limiting, since deletion of fatty acyl-CoA oxidase POX1 increased 3-PP titers slightly to 2.6 mg/L.
As the concentrations of 3-alkylphenols are close to the concentrations implemented in tsetse fly traps, the engineered yeast strains have the potential for simple and inexpensive on-site production of 3-alkylphenols as tsetse fly attractants by local rural communities in Africa. In spite of this success, 3-MP remained the main product in the developed yeast strains. Since 3-EP and 3-PP are more efficient tsetse fly attractants, a shift in substrate specificities of MSAS and PatG is desirable for a more favorable 3-EP/3-MP and 3-PP/3-MP product ratio regarding tsetse fly attraction. During rational engineering of MSAS, the MSASQ625A/I752V mutant showed a beneficial shift of product ratios with up to 11 mg/L 3-EP/63 mg/L 3-MP and 4.5 mg/L 3-PP/116 mg/L 3-MP, compared to a higher proportion of 3-MP with up to 343 mg/L, 11 mg/L 3-EP and 1.5 mg/L 3-PP in the wild type controls. Further engineering of MSAS and PatG might majorly improve production of 3-EP and 3-PP.
In summary, this thesis successfully established the yeast S. cerevisiae as cell factory for production of different 3-alkylphenols optimizing expression of the heterologous production pathway, elucidating means to detoxify products and establishing different approaches to increase intracellular levels of acyl-CoA precursors. The engineered yeast strains can be potentially implemented for simple and inexpensive fermentation of tsetse fly attractants in Africa.