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Diese Arbeit behandelt die Rolle der Proteinkinasen IKKe und TBK1 in der Progression von humanen malignene Melanomen und die Rolle von alpha-Synuclein in der Schmerzwahrnehmung von Mäusen.
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.
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.