Biologische Hochschulschriften (Goethe-Universität)
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The fungal interaction with plants is a 400 million years old phenomenon, which presumably assisted in the plants’ establishment on land. In a natural ecosystem, all plant-ranging from large trees to sea-grasses-are colonized by fungal endophytes, which can be detected inter- and intracellularly within the tissues of apparently healthy plants, without causing obvious negative effects on their host. These ubiquitous and diverse microorganisms are likely playing important roles in plant fitness and development. However, the knowledge on the ecological functions of fungal root endophytes is scarce. Among possible functions of endophytes, they are implicated in mutualisms with plants, which may increase plant resistance to biotic stressors like herbivores and pathogens, and/or to abiotic factors like soil salinity and drought. Also, endophytes are fascinating microorganisms in regard to their high potential to produce a great spectrum of secondary metabolites with expected ecological functions. However, evidences suggest that the interactions between host plants and endophytes are not static and endophytes express different symbiotic lifestyles ranging from mutualism to parasitism, which makes difficult to predict the ecological roles of these cryptic microorganisms. To reveal the ecological function of fungal root endophytes, this doctoral thesis aims at assessing fungal root endophytes interactions with different plants and their effects on plant fitness, based on their phylogeny, traits, and competition potential in settings encompassing different abiotic contexts. To understand the cryptic implication of nonmycorrhizal endophytes in ecosystem processes, we isolated a diverse spectrum of fungal endophytes from roots of several plant species growing in different natural contexts and tested their effects on different model plants under axenic laboratory conditions. Additionally,we aimed at investigating the effect of abiotic and biotic variables on the outcome of interactions between fungal root endophytes and plants.
In summary, the morphological and physiological traits of 128 fungal endophyte strains within ten fungal orders were studied and artificial experimental systems were used to reproduce their interactions with three plant species under laboratory conditions. Under defined axenic conditions, most endophytes behaved as weak parasites, but their performance varied across plant species and fungal taxa. The variation in the interactions was partly explained by convergent fungal traits that separate groups of endophytes with potentially different niche preferences. According to my findings, I predict that the functional complementarity of strains is essential in structuring natural root endophytic communities. Additionally, the responses of plant-endophyte interactions to different abiotic factors, namely nutrient availability, light intensity, and substrate’s pH, indicate that the outcome of plant-fungus relationships may be robust to changes in the abiotic environment. The assessment of the responses of plant endophyte interactions to biotic context, as combinations of selected dominant root fungal endophytes with different degrees of trait similarity and shared evolutionary history, indicates that frequently coexisting root-colonizing fungi may avoid competition in inter-specific interactions by occupying specific niches, and that their interactions likely define the structure of root-associated fungal communities and influence the microbiome impacts on plant fitness.
In conclusion, my findings suggest that dominant fungal lineages display different ecological preferences and complementary sets of functional traits, with different niche preferences within root tissues to avoid competition. Also, their diverse effects on plant fitness is likely host-isolate dependent and robust to changes in the abiotic environment when these encompass the tolerance range of either symbiont.
The enzyme acetyl-CoA carboxylase (ACC) plays a fundamental role in the fatty acid metabolism. It regulates the first and rate limiting step in the biosynthesis of fatty acids by catalyzing the carboxylation of acetyl-CoA to malonyl-CoA and exists as two different isoforms, ACC1 and ACC2. In the last few years, ACC has been reported as an attractive drug target for treating different diseases, such as insulin resistance, hepatic steatosis, dyslipidemia, obesity, metabolic syndrome and nonalcoholic fatty liver disease. An altered fatty acid metabolism is also associated with cancer cell proliferation. In general, the inhibition of ACC provides two possibilities to regulate the fatty acid metabolism: It blocks the de novo lipogenesis in lipogenic tissues and stimulates the mitochondrial fatty acid β-oxidation. Surprisingly, the role of ACC in human vascular endothelial cells has been neglected so far. This work aimed to investigate the role of the ACC/fatty acid metabolism in regulating important endothelial cell functions like proliferation, migration and tube formation.
To investigate the function of ACC, the ACC-inhibitor soraphen A as well as an siRNA-based approach were used. This study revealed that ACC1 is the predominant isoform both in human umbilical vein endothelial cells (HUVECs) and in human dermal microvascular endothelial cells (HMECs). Inhibition of ACC via soraphen A resulted in decreased levels of malonyl-CoA and shifted the lipid composition of endothelial cell membranes. Consequently, membrane fluidity, filopodia formation and the migratory capacity were attenuated. Increasing amounts of longer acyl chains within the phospholipid subgroup phosphatidylcholine (PC) were suggested to overcompensate the shift towards shorter acyl chains within phosphatidylglycerol (PG), which resulted in a dominating effect on regulating the membrane fluidity. Most importantly, this work provided a link between changes in the phospholipid composition and altered endothelial cell migration. The antimigratory effect of soraphen A was linked to a reduced amount of PG and to an increased amount of polyunsaturated fatty acids (PUFAs) within the phospholipid cell membrane. This link was unknown in the literature so far. Interestingly, a reduced filopodia formation was observed upon ACC inhibition via soraphen A, which presumably caused the impaired migratory capacity.
This work revealed a relationship between ACC/fatty acid metabolism, membrane lipid composition and endothelial cell migration. The natural compound soraphen A emerged as a valuable chemical tool to analyze the role of ACC/fatty acid metabolism in regulating important endothelial cell functions. Furthermore, regulating endothelial cell migration via ACC inhibition promises beneficial therapeutic perspectives for the treatment of cell migration-related disorders, such as ischemia reperfusion injury, diabetic angiopathy, macular degeneration, rheumatoid arthritis, wound healing defects and cancer.
Antimicrobial resistance became a serious threat to the worldwide public health in this century. A better understanding of the mechanisms, by which bacteria infect host cells and how the host counteracts against the invading pathogens, is an important subject of current research. Intracellular bacteria of the Salmonella genus have been frequently used as a model system for bacterial infections. Salmonella are ingested by contaminated food or water and cause gastroenteritis and typhoid fever in animals and humans. Once inside the gastrointestinal tract, Salmonella can invade intestinal epithelial cells. The host cell can fight against intracellular pathogens by a process called xenophagy. For complex systems, such as processes involved in the bacterial infection of cells, computational systems biology provides approaches to describe mathematically how these intertwined mechanisms in the cell function. Computational systems biology allows the analysis of biological systems at different levels of abstraction. Functional dependencies as well as dynamic behavior can be studied. In this thesis, we used the Petri net formalism to gain a better insight into bacterial infections and host defense mechanisms and to predict cellular behavior that can be tested experimentally. We also focused on the development of new computational methods.
In this work, the first realization of a mathematical model of the xenophagic capturing of Salmonella enterica serovar Typhimurium in epithelial cells was developed. The mathematical model expressed in the Petri net formalism was constructed in an iterative way of modeling and analyses. For the model verification, we analyzed the Petri net, including a computational performance of knockout experiments named in silico knockouts, which was established in this work. The in silico knockouts of the proposed Petri net are consistent with the published experimental perturbation studies and, thus, ensures the biological credibility of the Petri net. In silico knockouts that have not been experimentally investigated yet provide hypotheses for future investigations of the pathway.
To study the dynamic behavior of an epithelial cell infected with Salmonella enterica serovar Typhimurium, a stochastic Petri net was constructed. In experimental research, a decision like "Which incubation time is needed to infect half of the epithelial cells with Salmonella?" is based on experience or practicability. A mathematical model can help to answer these questions and improve experimental design. The stochastic Petri net models the cell at different stages of the Salmonella infection. We parameterized the model by a set of experimental data derived from different literature sources. The kinetic parameters of the stochastic Petri net determine the time evolution of the bacterial infection of a cell. The model captures the stochastic variation and heterogeneity of the intracellular Salmonella population of a single cell over time. The stochastic Petri net is a valuable tool to examine the dynamics of Salmonella infections in epithelial cells and generate valuable information for experimental design.
In the last part of this thesis, a novel theoretical method was introduced to perform knockout experiments in silico. The new concept of in silico knockouts is based on the computation of signal flows at steady state and allows the determination of knockout behavior that is comparable to experimental perturbation behavior. In this context, we established the concept of Manatee invariants and demonstrated the suitability of their application for in silico knockouts by reflecting biological dependencies from the signal initiation to the response. As a proof of principle, we applied the proposed concept of in silico knockouts to the Petri net of the xenophagic recognition of Salmonella. To enable the application of in silico knockouts for the scientific community, we implemented the novel method in the software isiKnock. isiKnock allows the automatized performance and visualization of in silico knockouts in signaling pathways expressed in the Petri net formalism. In conclusion, the knockout analysis provides a valuable method to verify computational models of signaling pathways, to detect inconsistencies in the current knowledge of a pathway, and to predict unknown pathway behavior.
In summary, the main contributions of this thesis are the Petri net of the xenophagic capturing of Salmonella enterica serovar Typhimurium in epithelial cells to study the knockout behavior and the stochastic Petri net of an epithelial cell infected with Salmonella enterica serovar Typhimurium to analyze the infection dynamics. Moreover, we established a new method for in silico knockouts, including the concept of Manatee invariants and the software isiKnock. The results of these studies are useful to a better understanding of bacterial infections and provide valuable model analysis techniques for the field of computational systems biology.
Application of a developed tool to visualize newly synthesized AMPA receptor components in situ
(2018)
The information flow between neurons happens at contact points, the synapses. One underlying mechanism of learning and memory is the change in the strength of information flow in selected synapses. In order to match the huge demand in membranes and proteins to build and maintain the neurites' complex architecture, neurons use decentralized protein synthesis. Many candidate proteins for local synthesis are known, and the need of de novo synthesis for memory formation is well established. The underlying mechanisms of how somatic versus dendritic synthesis is regulated are yet to be elucidated. Which proteins are newly synthesized in order to allow learning?
In this thesis protein synthesis is studied in hippocampal neurons. The fractional distribution of somatic and dendritic synthesis for candidate proteins and their subsequent transport to their destination are investigated using a newly developed technique. In the first part of this study we describe the development of this technique and use it in the second part to answer biological questions.
We focus here on AMPA receptor subunits, the key players in fast excitatory transmission. AMPA receptors contain multiple subunits with diverse functions. It remains to be understood, when and where in a neuron these subunits come together to form a protein complex and how the choice of subunits is regulated.
The investigation of the subunits' site of synthesis and redistribution kinetics in this study will help us to understand how neurons are able to change their synaptic strength in an input specific manner which eventually allows learning and memory.
Key questions which are addressed in this study:
How can specific newly synthesized endogenous proteins be visualized in situ? What are the neuron's abilities to locally synthesize and fully assemble AMPA receptor complexes?
How fast do different AMPA receptor subunits redistribute within neurons after synthesis?
Die Analyse von DNA-Sequenzen steht spätestens seit der Feststellung ihrer tragenden Rolle in der Vererbung organismischer Eigenschaften im Fokus biologischer Fragestellungen. Seit Kurzem wird mit modernsten Methoden die Untersuchung von kompletten Genomen ermöglicht. Dies eröffnet den Zugang zu genomweiten Informationen gegenüber begrenzt aussagekräftigen markerbasierten Analysen. Eine Genomsequenz ist die ultimative Quelle an organismischer Information. Allerdings sind diese Informationen oft aufgrund technischer und biologischer Gründe komplex und werfen meist mehr Fragen auf, als sie beantworten.
Die Rekonstruktion einer bislang unbekannten Genomsequenz aus kurzen Sequenzen stellt eine technische Herausforderung dar, die mit grundlegenden, aber in der Realität nicht zwingend zutreffenden Annahmen verbunden ist. Außerdem können biologische Faktoren, wie Repeatgehalt oder Heterozygotie, die Fehlerrate einer Assemblierung stark beeinflussen. Die Beurteilung der Qualität einer de novo Assemblierung ist herausfordernd, aber zugleich äußerst notwendig. Anschließend ist eine strukturelle und funktionale Annotation von Genen, kodierenden Bereichen und repeats nötig, um umfangreiche biologische Fragestellungen beantworten zu können. Ein qualitativ hochwertiges und annotiertes assembly ermöglicht genomweite Analysen von Individuen und Populationen. Diese Arbeit beinhaltet die Assemblierung und Annotation des Genoms der Süßwasserschnecke Radix auricularia und eine Studie vergleichender Genomik von fünf Individuen aus verschiedenen molekularen Gruppen (MOTUs).
Mollusken beherbergen nach den Insekten die größte Artenvielfalt innerhalb der Tierstämme und besiedeln verschiedenste, teils extreme, Habitate. Trotz der großen Bedeutung für die Biodiversitätsforschung sind verhältnismäßig wenige genomische Daten öffentlich verfügbar. Zudem sind Arten der Gattung Radix auch aufgrund ihrer großen geografischen Verbreitung in diversen biologischen Disziplinen als Modellorganismen etabliert. Eine annotierte Genomsequenz ermöglicht über bereits untersuchte Felder hinaus die Forschung an grundlegenden biologischen Fragestellungen, wie z.B. die Funktionsweise von Hybridisierung und Artbildung. Durch Assemblierung und scaffolding von sechs whole genome shotgun Bibliotheken verschiedener insert sizes und einem transkriptbasiertem scaffolding konnte trotz des hohen Repeatgehalts ein vergleichsweise kontinuierliches assembly erhalten werden. Die erhebliche Differenz zwischen der Gesamtlänge der Assemblierung und der geschätzten Genomgröße konnte zum Großteil auf kollabierte repeats zurückgeführt werden.
Die strukturelle Annotation basierend auf Transkriptomen, Proteinen einer Datenbank und artspezifisch trainierten Genvorhersagemodellen resultierte in 17.338 proteinkodierenden Genen, die etwa 12,5% der geschätzten Genomgröße abdecken. Der Annotation wird u.a. aufgrund beinhaltender Kernrthologen, konservierter Proteindomänenarrangements und der Übereinstimmung mit de novo sequenzierten Peptiden eine hohe Qualität zugesprochen.
Das mapping der Sequenzen von fünf Radix MOTUs gegen die R. auricularia Assemblierung zeigte stark verringerte coverage außerhalb kodierender Bereiche der nicht-Referenz MOTUs aufgrund hoher Nukleotiddiversität. Für 16.039 Gene konnten Topologien berechnet werden und ein Test auf positive Selektion ausgeführt werden. Insgesamt konnte über alle MOTUs hinweg in 678 verschiedenen Genen positive Selektion detektiert werden, wobei jede MOTU ein nahezu einzigartiges Set positiv selektierter Gene beinhaltet. Von allen 16.039 untersuchten Genen konnten 56,4% funktional annotiert werden. Diese niedrige Rate wird vermutlich durch Mangel an genomischer Information in Mollusken verursacht. Anschließende Analysen auf Anreicherungen von Funktionen sind deshalb nur bedingt repräsentativ.
Neben den biologischen Ergebnissen wurden Methoden und Optimierungen genomischer Analysen von Nichtmodellorganismen entwickelt. Dazu zählen eigens angefertigte Skripte, um beispielsweise Transkriptomalignments zu filtern, Trainings eines Genvorhersagemodells automatisiert und parallelisiert auszuführen und Orthogruppen bestimmter Arten aus einer Orthologievorhersage zu extrahieren. Zusätzlich wurden Abläufe entwickelt, um möglichst viele vorhandene Daten in die Assemblierung und Annotation zu integrieren. Etwa wurde ein zusätzliches scaffolding mit eigens assemblierten Transkripten mehrerer MOTUs sequenziell und phylogenetisch begründet ausgeführt.
Insgesamt wird eine umfassende und qualitativ hochwertige Genomsequenz eines Süßwassermollusken präsentiert, welche eine Grundlage für zukünftige Forschungsprojekte z.B. im Bereich der Biodiversität, Populationsgenomik und molekularen Ökologie bietet. Die Ergebnisse dieser Arbeit stellen einen Wissenszuwachs in der Genomik von Mollusken dar, welche bisher trotz ihrer Artenvielfalt deutlich unterrepräsentiert bezüglich assemblierter und annotierter Genome auffallen.
Die membranintegrierten, rotierenden F-Typ ATP-Synthasen zählen zu den essentiellen Komponenten der bakteriellen Energieversorgung. Ihre Rolle im zellulären Energiehaushalt bestehtin der Synthese von ATP unter Nutzung des transmembranen, elektrischen Ionengradienten (Mitchell 1961, Duncan et al. 1995, Noji et al. 1997, Kinosita et al. 1998). Die rotierenden ATP-Synthasen werden entsprechend der Kationenselektivität, die sie unter physiologischen Bedingungen zeigen, in zwei verschiedene Klassen eingeteilt, die H+-selektiven, sowiedie Na+-selektiven ATP-Synthasen. Hierbei bildet die Selektivität beider Klassen für einwertige Kationen (H+ oder Na+) eine essenzielle Grundlage für ihre Rolle im Energiehaushalt der bakteriellen Zellen. Jedoch gibt es nur eine begrenzte Anzahl von anaeroben Eubakterien und Archaeen, die noch einen auf Na+- Ionen basierenden Energiehaushalt besitzen. Gut charakterisierte Beispiele für Na+-selektive ATP-Synthasen bilden die F-Typ-Synthasen von I. tartaricus, P. modestum, sowie die V/A-Typ-Enzyme von E. hirae und A. woodii. Trotz der Unterschiede in der Kationenselektivitätder unterschiedlichen F-Typ ATP-Synthasen sind sie jedoch sowohl inihre Organisation, als auch hinsichtlich ihre Wirkungsweisen ähnlich. Das Ziel, der im Rahmen dieser Arbeit durchgeführten Forschung, bestand in der Identifizierung der Faktoren, die sowohl die hohen Selektivität, als auch die Affinität des in der Membran-eingebetteten Rotor-C-Rings der ATP-Synthasezu Protonen (H+) und Na+- Ionen beeinflussen. Die Untersuchungen wurden hierbei andem c11-Ring der F-Typ-ATP-Synthase aus dem anaeroben Bakterium Ilyobacter tartaricus durchgeführt, das hierbei als Modellsystem diente. Der untersuchte Ring zeigt unter physiologischen Bedingungen eine hohe Bindungsselektivität für Na+ Ionen, kann jedoch unter nicht-physiologischen Bedingungen auch Li+ und H+ Ionen binden und zur ATP-Synthese verwenden (Neumann et al. 1998).
Das Ziel, der im Rahmen dieser Arbeit durchgeführten Forschung, bestand in der Identifizierung der Faktoren, die sowohl die hohen Selektivität, als auch die Affinität des in der Membran-eingebetteten Rotor-C-Rings der ATP-Synthasezu Protonen (H+) und Na+- Ionen beeinflussen. Die Untersuchungen wurden hierbei andem c11-Ring der F-Typ-ATP-Synthase aus dem anaeroben Bakterium Ilyobacter tartaricus durchgeführt, das hierbei als Modellsystem diente. Der untersuchte Ring zeigt unter physiologischen Bedingungen eine hohe Bindungsselektivität für Na+ Ionen, kann jedoch unter nicht-physiologischen Bedingungen auch Li+ und H+ Ionen binden und zur ATP-Synthese verwenden (Neumann et al. 1998). Die Kd- und KM-Werte wurden verwendet, um die Na+ -Bindungsaffinität der C-Ringe bzw. ATP-Synthasen zu quantifizieren. Über die Selektivität wurdebeschrieben, welche Kationen an die C-Ringe und ATP-Synthasen binden können (z. B. H+/Na+/Li+, H+/Na+ - oder nur H+ Ionen).Das Verhältnis der absoluten Bindungsaffinitäten zwischen zwei Kationen (z. B. Kd (Na+)/Kd (H+)) wurde verwendet, um die Präferenz des Enzyms für eines der Ionen zu quantifizieren. Die Faktoren, dieder Kationenselektivität und der Affinität des I. tartaricus c-Rings zugrunde liegen, wurden mit Hilfe von Mutageneseexperimenten der Aminosäuren in der Ionenbindungsstelle untersucht. Im I. tartaricus-c-Ring erfolgt die Na+ Bindung an der Grenzfläche von zwei benachbarten c-Untereinheiten des c-Rings. An der Bindung der Na+-Ionen sind sowohl Aminosäuren aus Helix 1 (Gln32), sowie von Helix 2 (Val63, Ser66, Thr67 und Tyr70) beteiligt, die in der Nähe, des für den Mechanismusessentiellen Glu65 liegen. Insgesamt wurden 19 verschiedene, spezifische Einzel- und Doppelmutationen in die Sequenz des atpE-Gens eingeführt, die für die I. tarticus-ATP-Synthase-c-Untereinheit kodiert. Bei den Experimenten mit dem I. tartaricus c-Ring (Ser66, Thr67 und Tyr70) wurden drei polare Reste der Ionenbindungsstelle durch die polaren Reste (Ser67, Ile67 oder Leu67) oder hydrophobe Reste (Ala66, Gln67 und Phe70) ersetzt, während das geladene Glu65 durch die kürzere, aber immer noch geladene Seitenkette Asp65 ausgetauscht wurde. Zur Charakterisierung der monovalenten Kationenbindung durch die Wildtyp, sowie die mutierten C-Ringe von I.-tartaricus, wurde ein Ansatz verwendet, der biochemische (DCCD-Ionen-Kompetitionsassay) und biophysikalische (ITC) Methoden kombiniert.
Die Daten der in dieser Arbeit durchgeführten Experimente, zeigen, dass c-Ringe selektiv für H+ sind, solange in der Ionenbindungsstelle des c-Rings ein ionisierbarer Glu/Asp-Rest vorhanden ist. Die H+-Bindungsaffinität des c-Rings hängt von der Hydrophobizität der Reste ab, aus der die Ionenbindungsstelle aufgebaut ist.Jedoch ist die Zahl der Faktoren, die die Na+-Selektivität des C-Rings bestimmen, weitaus größer. Von den in dieser Arbeit untersuchten Faktoren war die Zahl der polaren Reste, die Wasserstoffbrücken zu Na+ bilden, die Co-Koordination von Na+ durch strukturell vorhandene Wassermoleküle und die Anwesenheit von negativ geladenen Resten besonders wichtig für die Bindung der Na+-Ionen an den Ring. Die hohe Bindungsaffinität des c-Rings für Na+-Ionen, wird sowohl durch Wechselwirkungen begünstigt die das gebundene Na+-Ion stabilisieren, als auch den gesamten atomaren Aufbau der Ionenbindestelle, der die enthalpiegetriebene Na+-Bindungan den c-Ring begünstigen. Im Rahmen dieser eingehenden Studien konnten zum ersten Mal die thermodynamischen Eigenschaften aufgeklärt werden, die der hohen Na+-Bindungsaffinität des c-Rings zugrunde liegen, sowie der Einfluss von Mutationen auf diese Parameter ermittelt werden. Durch zahlreiche Experimente mit ATP-Synthasen, die mit mutierten c-Ringen zusammengesetzt wurden, sollte eine Verbindung zwischen Veränderungen der H+- und der Na+-Bindungsaffinitäten und Unterschiede im Betrieb der ATP-Synthase aufgeklärt werden. Die wichtigste Schlussfolgerung, die sich aus dieser Arbeit ableiten lässt, ist, besteht darin, dass sich Na+/H+-selektiven ATP-Synthasen durch den Austausch von 1-2 Aminosäureresten innerhalb der rotierenden c-Ring-Ionenbindungsstelle in ausschließlich H+-selektive, vollfunktionelle ATP-Synthasen umwandeln lassen.
Cardiac trabeculation is one of the essential processes required for the formation of a competent ventricular wall, whereby clusters of ventricular cardiomyocytes (CMs) from a single layer delaminate and expand into the cardiac jelly to form sheet-like projections in the developing heart (Samsa et al., 2013). Several congenital heart diseases are associated with defects in the formation of these trabeculae and lead to embryonic lethality (Jenni et al., 1999; Zhang et al., 2013, Jenni et al., 2001; Towbin 2010). It has been experimentally shown that lack of Nrg1/ErbB2/ErbB4, Angipoetin1/Tie2, EphrinB2/B4, BMP10, or any component of the Notch signaling pathway can cause defective trabeculation. Moreover, changes in blood flow and/or contractility can also affect trabeculation (Samsa et al., 2013). Together, these observations demonstrate that cardiac trabeculation is a highly dynamic and regulated process.
Trabeculation is a morphogenetic process that requires control over cell shape changes and rearrangements, similar to those observed during EMT. Epithelial cells within an epithelium are polarized and establish cell-cell junctions with the neighboring cells (Ikenouchi et al., 2003; Ferrer-vaquer et al., 2010), thus epithelial cell polarity is an important feature to maintain cell shape and tissue structure. During developmental processes such as cell migration and cell division or in disease states epithelial polarity might be disrupted. As a consequence of this alteration, cells lose their tight cell-cell adhesions, undergo cytoskeletal rearrangements, change their shape and gain migratory properties becoming mesenchymal cells (Micalizzi et al., 2010). In epithelial cells, apicobasal polarity is regulated by a conserved set of core complexes, including the PAR, Scribble and Crumbs complexes (Kemphues et al., 1988; Bilder and Perrimon, 2000; Teppas et al., 1984). The polarity proteins composing these complexes interact in a well organized and coordinated-manner creating molecular asymmetry along the apicobasal axis of the cell. In turn, this crosstalk regulates the maturation and stabilization of the junctions between cells and cytoskeleton in order to strengthen cell polarization (Roignot et al., 2013). Amongst the different polarity complex, Crumbs has been shown to be a key regulator of apicobasal polarity during development in both vertebrates and invertebrates (Tepass et al., 1990; Fan et al., 2004).
Here, taking advantage of zebrafish as a model organism, I study in vivo at single cell resolution changes in CM apicobasal polarity during cardiac trabeculation. Moreover, I show which factors regulate CM apicobasal polarity during this process. In addition, I dissect the role of the polarity complex Crumbs in regulating CM junctional rearrangements and the formation of the trabecular network.
G-protein coupled receptors (GPCRs) are a predominant class of cell-surface receptors in eukaryotic life. They are responsible for the perception of a broad range of ligands and involved in a multitude of physiological functions. GPCRs are therefore of crucial interest for biological and pharmaceutical research. Molecular analysis and functional characterisation of GPCRs is frequently hampered by challenges in efficient large-scale production, non-destructive purification and long-term stability. Cell-free protein synthesis (CFPS) provides new production platforms for GPCRs by extracting the protein synthesis machinery of the cell in an open system that allows target-oriented modulations of the synthesis process and direct access to the nascent polypeptide chain. CFPS is fast, reliable and highly adaptable. Unfortunately, highly productive cell-free synthesis of GPCRs is often opposed by low product quality. This thesis was aimed to adapt and improve some of the new possibilities for the cell-free production of GPCRs in high yield and quality for structural and pharmaceutical analysis. An E. coli based CFPS system was applied to synthesise various turkey and human Beta-adrenergic receptor (Beta1AR) derivatives as well as human Endothelin receptors type A and B (ETA and ETB) constructs. Both receptor families are important drug targets and pharmacologically addressed in the treatment of several cardiovascular diseases. CF-synthesis was mainly performed in presence of nanodiscs (ND), which are reconstituted high density lipoprotein particles forming discoidal bilayer patches with a diameter varyring from 6 to approx. 15 nm. The supplementation of ND in the CF-synthesis reaction caused the co-translational solubilisation of the freshly synthesised GPCRs. The fraction of the solubilised GPCR that was correctly folded was analysed by the competence to bind its ligand alprenolol or Endothelin-1, respectively. Both the solubilisation efficiency and the ability to fold in a ligand binding competent state was strongly affected by the lipid composition of the supplied ND. Best results were generally achieved with lipids having phosphoglycerol headgroups and unsaturated fatty acid chains with 18 carbon atoms. Furthermore, thermostabilisation by introduction of point mutations had a large positive impact on the folding efficiency of both Beta1AR and ETB receptor. Formation of a conserved disulphide bridge in the extracellular region was additionally found to be crucial for the function of the ETB receptor. Disulphide bridge formation could be enhanced by applying a glutathione-based redox system in the CFPS. Further improvements in the quality of ETB receptor could be made by the enrichment of heat-shock chaperones in the CF-reaction. Depending on the receptor type and DNA-template, roughly 10 – 30 nmol (350 – 1500 µg) of protein could be synthesised in 1 ml of CF-reaction mixture. After the applied optimisation steps, the fractions of correctly folded receptor could be improved by several orders of magnitude and were finally in between 35% for the thermostabilised turkey Beta1AR, 9% for the thermostabilised ETB receptor, 6.5% for the non-stabilised ETB receptor, 1 - 5% for non-stabilised turkey Beta1AR and for human Beta1AR isoforms and 0.1% for ETA receptor. Therefore, between 2 and 120 µg of GPCR could be synthesised in a ligand binding competent form, depending on the receptor and its modifications. Correctly folded turkey Beta1AR and ETB receptors were thermostable at 30°C and could be stored at 4°C for several weeks after purification. Yields of the thermostabilised turkey Beta1AR were sufficient to purify the receptor in a two-step process by ligand-binding chromatography to obtain pure and correctly folded receptor in the lipid bilayer of a ND. Furthermore, a lipid dependent ligand screen could be demonstrated with the turkey Beta1AR and significant alterations in binding affinities to currently in-use pharmaceuticals were found. The established protocols are therefore suitable and highly competetive for a variety of applications such as screening of GPCR ligands, analysis of lipid effects on GPCR function or for the systematical biochemical characterisation of GPCRs. Most promising for future approaches appears to address the suspected bottlenecks of intial insertion of the GPCR-polypeptide chain in the ND bilayer and the thermal stability of the receptors. Nevertheless, the estabilised protocols for the analysed targets in this thesis are already highly competitive to previously published production protocols either in cell-based or cell-free systems with regard to yield of functional protein, speediness and costs. Moreover, the direct accessibility and other general characteristics of cell-free synthesis open a large variety of possible applications and this work can therefore contribute to the molecular characterisation of this important receptor type and to the development of new pharmaceuticals.
Heat stress transcription factors (Hsfs) have an essential role in heat stress response (HSR) and thermotolerance by controlling the expression of hundreds of genes including heat shock proteins (Hsps) with molecular chaperone functions. Hsf family in plants shows a striking multiplicity, with more than 20 members in many species. In Solanum lycopersicum HsfA1a was reported to act as the master regulator of the onset of HSR and therefore is essential for basal thermotolerance. Evidence for this was provided by the analysis of HsfA1a co-suppression (A1CS) transgenic plants, which exhibited hypersensitivity upon exposure to heat stress (HS) due to the inability of the plants to induce the expression of many HS-genes including HsfA2, HsfB1 and several Hsps. Completion of tomato genome sequencing allowed the completion of the Hsf inventory, which is consisted of 27 members, including another three HsfA1 genes, namely HsfA1b, HsfA1c and HsfA1e.
Consequently, the suppression effect of the short interference RNA in A1CS lin e was re-evaluated for all HsfA1 genes. We found that expression of all HsfA1 proteins was suppressed in A1CS protoplasts. This result suggested that the model of single master regulator needs to be re-examined.
Expression analysis revealed that HsfA1a is constitutively expressed in different tissues and in response to HS, while HsfA1c and HsfA1e are minimally expressed in general, and show an induction during fruit ripening and a weak upregulation in late HSR. Instead HsfA1b shows preferential expression in specific tissues and is strongly and rapidly induced in response to HS. At the protein level HsfA1b and HsfA1e are rapidly degraded while HsfA1a and HsfA1c show a higher stability. In addition, HsfA1a and HsfA1c show a nucleocytosolic distribution, while HsfA1b and HsfA1e a strong nuclear retention.
A major property of a master regulator in HSR is thought to be its ability to cause a strong transactivation of a wide range of genes required for the initial activation of protective mechanisms. GUS reporter assays as well as analysis of transcript levels of several endogenous transcripts in protoplasts transiently expressing HsfA1 proteins revealed that HsfA1a can stimulate the transcription of many genes, while the other Hsfs have weaker activity and only on limited set of target genes. The low activity of HsfA1c and HsfA1e can be attributed to the lower DNA capacity of the two factors as judged by a GUS reporter repressor assay.
HsfA1a has been shown to have synergistic activity with the stress induced HsfA2 and HsfB1. The formation of such complexes is considered as important for stimulation of transcription and long term stress adaptation. All HsfA1 members show synergistic activity with HsfA2, while only HsfA1a act as co-activator of HsfB1 and HsfA7. Interestingly, HsfA1b shows an exceptional synergistic activity with HsfA3, suggesting that different Hsf complexes might regulate different HS-related gene networks. Altogether these results suggest that HsfA1a has unique characteristics within HsfA1 subfamily. This result is interesting considering the very high sequencing similarity among HsfA1s, and particularly among HsfA1a and HsfA1c.
To understand the molecular basis of this discrepancy, a series of domain swapping mutants between HsfA1a and HsfA1c were generated. Oligomerization domain and C-terminal swaps did not affect the basal activity or co-activity of the proteins. Remarkably, an HsfA1a mutant harbouring the N-terminus of HsfA1c shows reduced activity and co-activity, while the reciprocal HsfA1c with the N-terminus of HsfA1a cause a gain of activity and enhanced DNA binding capacity.
Sequence analysis of the DBD of HsfA1 proteins revealed a divergence in the highly conserved C-terminus of the turn of β3-β4 sheet. As the vast majority of HsfA1 proteins, HsfA1a at this position comprises an Arg residue (R107), while HsfA1c a Leu and HsfA1e a Cys. An HsfA1a-R107L mutant has reduced DNA binding capacity and consequently activity. Therefore, the results presented here point to the essential function of this amino acid residue for DNA binding function. Interestingly, the mutation did not affect the activity of the protein on Hsp70-1, suggesting that the functionality of the DBD and consequently the transcription factor on different promoters with variable heat stress element number and architecture is dependent on structural peculiarities of the DBD.
In conclusion, the unique properties including expression pattern, transcriptional activities, stability, DBD-peculiarities are likely responsible for the dominant function of HsfA1a as a master regulator of HSR in tomato. Instead, other HsfA1-members are only participating in HSR or developmental regulations by regulating a specific set of genes. Furthermore, HsfA1b and HsfA1e are likely function as stress primers in specific tissues while HsfA1c as a co-regulator in mild HSR. Thereby, tomato subclass A1 presents another example of function diversity not only within the Hsf family but also within the Hsf-subfamily of closely related members. The diversification based on DBD peculiarities is likely to occur in potato as well. Therefore this might have eliminated the functional redundancy observed in other species such as Arabidopsis thaliana but has probably allowed the more refined regulation of Hsf networks possibly under different stress regimes, tissues and cell types.
Im Rahmen dieser Arbeit wurden sRNAs des halophilen Archaeons Haloferax volcanii hinsichtlich ihrer biologischen und ihrer regulatorischen Funktion charakterisiert.
Um einen Überblick über die biologischen Funktionen archaealer sRNAs zu erhalten, wurde eine umfassende phänotypische Charakterisierung von 27 sRNA-Deletionsmutanten im Vergleich zum Wildtyp ausgewertet. Im Zuge dieser phänotypischen Charakterisierungen wurden zehn verschiedene Wachstumsbedingungen, morphologische Unterschiede und Veränderungen in der Zellmotilität untersucht. Hierbei zeigten nahezu alle Deletionsmutanten unter mindestens einer der getesteten Bedingungen phänotypische Unterschiede. Durch den Verlust von sRNAs wurden sowohl sogenannte Gain-of-function als auch Loss-of-function Phänotypen beobachtet. Haloarchaeale sRNAs spielen eine wichtige Rolle beim Wachstum mit verschiedenen Salzkonzentrationen, mit verschiedenen Kohlenstoffquellen und beim Schwärmverhalten, sind jedoch weniger in die Adaptation an diverse Stressbedingungen involviert.
Zur näheren Charakterisierung der regulatorischen Funktion archaealer sRNAs wurden sRNA362, sRNAhtsf468 und sRNA479 mittels molekulargenetischer Methoden wie Northern Blot-Analyse und DNA-Mikroarray sowie bioinformatischer in silico-Analyse untersucht. Das Expressionslevel von sRNA362 konnte bestimmt und potentielle Zielgene für sRNAhtsf468 und sRNA479 identifiziert werden.
Eine vorangegangene Studie zeigte den Einfluss von sRNA30 unter Hitzestress und führte zur Identifikation differentiell produzierter Proteine in Abwesenheit der sRNA. In dieser Arbeit wurde mittels Northern Blot-Analysen die Expression der sRNA30 charakterisiert. Das Wachstum in An- und Abwesenheit von sRNA30 wurde bei 42°C und 51°C phänotypisch charakterisiert und der regulatorische Einfluss der sRNA auf die mRNA differentiell regulierter Proteine durch Northern Blot-Analyse überprüft. Eine Transkriptomanalyse mittels DNA-Mikroarray nach Hitzeschock-Induktion führte zur Identifikation differentiell regulierter Gene involviert in Transportprozesse, Metabolismus, Transkriptionsregulation und die Expression anderer sRNAs. Die differentielle Regulation des Proteoms nach Hitzeschockinduktion in An- und Abwesenheit von sRNA30 konnte bestätigt werden.
Desweiteren wurde in dieser Arbeit sRNA132 und deren phosphatabhängige Regulation der Ziel-mRNA HVO_A0477-80 näher charakterisiert. Eine Induktionskinetik nach Phosphatentzug bestätigte die Bedeutung von sRNA132 für die verstärkte Expression des Operons HVO_A0477-80 unter Phosphatmangel-Bedingungen und verwies auf die Existenz weiterer Regulationsmechanismen. Während vor und nach Phosphatentzug kein Unterschied bezüglich der Zellmorphologie von Wildtyp und Deletionsmutante zu erkennen war, führte das Wachstum mit einem starken Phosphatüberschuss von 5 mM zu einer Zellverlängerung der Deletionsmutante. Die Kompetition der nativen 3‘-UTR des Operons HVO_A0477-80 mit einer Vektor-kodierten artifiziellen 3‘-UTR legt eine Regulation über die Bindung von sRNA132 an die 3‘-UTR nahe. Der Transkriptomvergleich nach Phosphatentzug in An- und Abwesenheit von sRNA132 führte zur Identifikation des Phosphoregulons der sRNA. Zu diesem Phosphoregulon gehören unter anderem zwei Glycerinphosphat-Dehydrogenasen, Transkriptionsregulatoren, eine Polyphosphatkinase und eine Glycerolphosphodiesterase. Zudem waren die Transkriptlevel der beiden ABC-Transporter HVO_A0477-80 und HVO_2375-8 für anorganisches Phosphat und des Transporters HVO_B0292-5 für Glycerinaldehyd-3-Phosphat in Abwesenheit der sRNA verringert. Die beiden ABC-Transportsysteme für anorganisches Phosphat wurden im Rahmen dieser Arbeit deletiert und weiter charakterisiert. Es konnte gezeigt werden, dass das ABC-Transportsystem HVO_2375-8 bei geringen Phosphatkonzentrationen leicht induziert wird und das Transkriptlevel in Anwesenheit von sRNA132 erhöht ist. Wachstumsversuche der jeweiligen Deletionsmutante in direkter Konkurrenz mit dem Wildtyp zeigten, dass keiner der beiden ABC-Transporter den anderen vollständig ersetzen kann und der Wildtyp mit beiden intakten ABC-Transportern unter phosphatlimitierenden Bedingungen einen Wachstumsvorteil besitzt. In silico-Analysen der Promotorbereiche von sRNA und ABC-Transporter legen zudem die Existenz von P-Boxen nahe.