@phdthesis{Thoma2011, author = {Thoma, Eva Christina}, title = {Directed differentiation of pluripotent stem cells induced by single genes}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-54706}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2011}, abstract = {Pluripotency describes the ability of stem cells to form every cell type of the body.. Pluripotent stem cells are e.g. embryonic stem cells (ESCs), but also the so called induced pluripotent stem cells (IPS cells), that are generated by reprogramming differentiated somatic cells into a pluripotent state. Furthermore, it has been shown that spermatogonia (SG) derived from adult testes of mouse or human are pluripotent. Because of their ability to differentiate into every somatic cell type, pluripotent stem cells have a unique status in research and regenerative medicine. For the latter, they offer a valuable opportunity to replace destroyed tissues or organs. For basic research, stem cells represent a useful system to study differentiation or developmental processes that are difficult to access in the physiological situation e.g. during embryogenesis. Both applications, however, require methods that allow efficient and directed differentiation of stem cells into defined specialized cell types. This study first aims to investigate the differentiation potential of SG derived from the teleost fish medaka (Oryzias latipes). My results demonstrate that medaka SG are able to form different somatic cell types, namely adipocytes, melanocytes, osteoblasts, and neurons. This indicates that medake SG have retained a broad differentiation potential suggesting that pluripotency is not restricted to mouse and human SG but might be conserved among vertebrates. Next, I wanted to establish a differentiation method that is solely based on ectopic expression of genes known to be essential for the formation of certain somatic cell types - so called master regulators (MRs). My findings show that ectopic expression of the melanocyte-specific transcription factor mitf-m that has previously been shown to induce differentiation of medaka ESCs into pigment cells resulted in the formation of the same cell type in medaka SG. This approach could be used to generate other somatic cell types. Thus, ectopic expression of the MRs cbfa1 and mash1 in MF-SG was sufficient to induce differentiation into osteoblasts and neurons, respectively. Interestingly, these differentiation processes included the activation of genes that are expressed earlier during embryogenesis than the differentiation-inducing MR. Furthermore, my findings show that the approach of MR-induced differentiation can be transferred to mammalian stem cell systems. Ectopic expression of the neural transcription factor ngn2 was sufficient to induce efficient and rapid differentiation of neurons in mouse ESCs. This differentiation process also included the induction of genes that in vivo are activated at earlier stages that ngn2. By generating a transgenic cell line allowing induction of ectopic ngn2 expression, it was possible to obtain a relatively pure culture of functional neurons. Ngn2-induced differentiation did not require any additional signals and occurred even under pluripotency promoting conditions. Moreover, ectopic expression of ngn2 did also induce the formation of cells with neuronal morphology in IPS cells indicating that MR-induced differentiation is operative in different stem cell types. Furthermore, protein transduction of Ngn2 into mouse ESCs also resulted in a neuronal differentiation process up to the appearance of neural precursor cells. Last, my results show that MR-induced differentiation can also be used to generate other cell types than neurons from mouse ESCs. Myoblasts and macrophage-like cells were generated by ectopic expression of the MRs myoD and cebpa, respectively. Using transgenic cell lines enabling induction of MR expression it was possible to obtain mixed cultures with two different differentiation processes occurring in parallel. Altogether this study shows that ectopic expression of single genes is sufficient to induce directed differentiation of stem cells into defined cell types. The feasibility of this approach was demonstrated for different MRs and consequently different somatic cell types. Furthermore, MR induced differentiation was operative in different stem cell types from fish and mouse. Thus, one can conclude that certain genes are able to define cell fates in in vitro stem cell systems and that this cell fate defining potential appears to be a conserved feature in vertebrates. These findings therefore provide new insights in the role of MRs in cell commitment and differentiation processes. Furthermore, this study presents a new method to induce directed differentiation of stem cells that offers several advantages regarding efficiency, rapidness, and reproducibility. MR-induced differentiation therefore represents a promising tool for both stem cell research and regenerative medicine.}, subject = {Stammzelle}, language = {en} } @phdthesis{Obier2010, author = {Obier, Nadine}, title = {Defining the end of pluripotency in mouse embryonic stem cells}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-53722}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2010}, abstract = {Stammzellen mit ihrer besonderen F{\"a}higkeit sich selbst zu erneuern und zu differenzieren stellen einen faszinierenden Zelltyp f{\"u}r Grundlagenforschung und angewandte Wissenschaften dar. Pluripotente embryonale Stammzellen (ES Zellen), die aus Zellen der inneren Zellmasse von Pr{\"a}implantationsembryonen etabliert werden, k{\"o}nnen ekto-, meso- und endodermale Zelltypen sowie Keimzellen hervorbringen. Im Gegensatz dazu sind multipotente adulte Stammzellen in ihrem Entwicklungspotential eingeschr{\"a}nkt, sie differenzieren sich zu allen Zelltypen ihres Gewebes. Zum Beispiel h{\"a}matopoetische Stammzellen (HSZs), die sich in Blut-bildenden Geweben wie dem Knochenmark befinden, verm{\"o}gen sich in alle Blutzellen zu differenzieren. W{\"a}hrend der Differenzierung von Stammzellen {\"a}ndert sich nicht deren Genom, sondern ihre epigenetische Regulation. Durch epigenetische Mechanismen werden Zelltypen mit verschiedensten Ph{\"a}notypen und Funktionen generiert. F{\"u}r Stammzelltherapien ist ein tieferes Verst{\"a}ndnis des Zusammenhangs von Epigenom und zellul{\"a}rer Funktion wichtig. Im Rahmen dieser Dissertation war es mein Ziel, differenzierende Stammzellkulturen auf ihre Genexpression, ihre Chromatinregulation und ihr Differenzierungspotiential hin zu analysieren. Um Histonmodifikationen, die einen m{\"o}glichen Mechanismus epigenetischer Regulation darstellen, global untersuchen zu k{\"o}nnen, sind zun{\"a}chst, durchusszytometrische Protokolle etabliert worden, die die Analyse einzelner Zellen erm{\"o}glichen sollten. Mit dieser Methode konnten reduzierte Levels von Histonazetylierung in differenzierten ES Zellen gezeigt werden. Im Gegensatz dazu beobachtete ich vergleichbare Levels von Histonazetylierung in unreifen und reifen Knochenmarkzellen. Zus{\"a}tzlich untersuchte ich die Wirkung des Histondeazetylase-Inhibitors (HDI) Trichostatin A (TSA) auf Knochenmarkzellkulturen, in denen auch HSZs enhalten sind. Nach Behandlung mit TSA erh{\"o}hte sich der Anteil von Zellen mit in vitro und in vivo h{\"a}matopoetischer Aktivit{\"a}t, w{\"a}hrend vor allem differenzierte Zellen in Apoptose gingen. Außerdem wurde der Verlust der Pluripotenz in differenzierenden ES Zellkulturen untersucht. Marker-basierte Analysen und funktionelle Tests wurden mit ES Zellen durchgef{\"u}hrt, die kurzfristig in vitro differenziert wurden. Es stellte sich heraus, dass nach funktionellen Gesichtspunkten die Pluripotenz bereits nach 2 Tagen Differenzierung deutlich reduziert war, beurteilt anhand der F{\"a}higkeit Kolonien zu bilden, embryoide K{\"o}rperchen (EK) zu formieren und zu kontrahierenden Herzmuskelzelltypen zu differenzieren. Im Gegensatz dazu verringerte sich die Expression von Pluripotenzmarkern erst zu sp{\"a}teren Zeitpunkten. Ich habe weiterhin beobachten k{\"o}nnen, dass die Wahl des Differenzierungssystems (Aggregations-EK, klonale EKs oder als adh{\"a}rente Einzelzellschicht) einen Einfluss auf den Fortschritt und die Homogenit{\"a}t der Differenzierung hatte. Um das Ende der Pluripotenz genauer zu untersuchen, wurden differenzierte ES Zellen zur{\"u}ck in ES Zellkulturbedingungen gebracht. Die Ergebnisse deuten an, dass 3 Tage differenzierte ES Zellen einen Punkt {\"u}berschritten haben, an dem eine R{\"u}ckkehr zur Pluripotenz allein durch Kulturbedingungen noch m{\"o}glich ist. Durch die Behandlung mit HDIs starben selektiv differenzierte ES Zellen. Des Weiteren war es Ziel dieser Arbeit, den Einuss von EED - einer essentiellen Untereinheit des Histon-methylierenden Polycomb repressive complex 2 (PRC2) - auf das Chromatin und die Funktion von ES Zellen hin zu analysieren. ES Zellen ohne EED wiesen neben dem bereits bekannten Verlust der Trimethylierung von Histon 3 an Lysin 27 (H3K27me3), global reduzierte H3K9me3 Levels sowie erh{\"o}hte Histonazetylierung auf. Trotz typischer ES Zell-Morphologie und normaler Expression von Pluripotenzgenen, besaßen EED knockout (KO)ES Zellen eine ver{\"a}nderte Organisation der Heterochromatinstruktur im Zellkern, eine verlangsamte Chromatinmobilit{\"a}t und Probleme bei der Differenzierung. Zusammenfassend gew{\"a}hren meine Daten Einblick in die epigenetische Regulation von Stammzellen. Im Besonderen konnte ich zeigen, dass die Behandlung mit HDIs f{\"u}r differenzierende Knochenmarkzellen und differenzierende ES Zellen nachteilig war und zu deren selektivem Zelltod f{\"u}hrte. Die hier durchgef{\"u}hrten Analysen ergaben, dass ES Zellen nach 3 Tagen Differenzierung das Ende der Pluripotenz erreicht hatten. Schließlich zeigten die Versuche mit EED KO ES Zellen, dass sie sich zwar selbst erneuerten und morphologisch identisch mit wildtypischen ES Zellen waren, jedoch Defekte bei der Differenzierung besaßen. Dies deutet darauf hin, dass EED nicht nur f{\"u}r undifferenzierte ES Zellen wichtig ist, sondern auch w{\"a}hrend der Differenzierung von Bedeutung ist.}, subject = {Stammzelle}, language = {en} } @phdthesis{Li2013, author = {Li, Xiaoli}, title = {Functional analyses of ES cell pluripotency by inducible knockdown of the Polycomb group protein Pcgf6}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-84015}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2013}, abstract = {Polycomb group (PcG) proteins are chromatin modifiers involved in heritable gene repression. Two main PcG complexes have been characterized: Polycomb repressive complex (PRC) 2 is involved in the initiation of gene silencing, whereas PRC1 participates in the stable maintenance of gene repression. Pcgf4 (Polycomb group protein, Bmi1) is one of the most studied PRC1 members with essential functions for embryonic development and adult stem cell self renewal. In embryonic stem cells (ES cells), Pcgf4 is poorly expressed while its paralogs (Pcgf1, Pcgf2, Pcgf3, Pcgf5 and Pcgf6) are expressed at higher levels. The relevance of the Pcgf paralog Pcgf6 for the maintenance of ESC pluripotency has not been addressed so far. My analyses revealed that Pcgf6 was the most expressed Pcgf paralog in undifferentiated ES cells. When ES cells differentiated, gene expression of Pcgf6 strongly declined. To investigate the functions of Pcgf6 in ES cells, we established a doxycycline (dox) inducible shRNA-targeted knockdown system according to publications by Seibler et al. (Seibler et al. 2005; Seibler et al. 2007). Following dox-induced knockdown (KD) of Pcgf6, we observed decreased ES cell colony formation. In parallel, gene expression of pluripotency markers Oct4, Nanog and Sox2 was reduced upon dox-treatment, wheras the expression of mesoderm genes such as T (Brachyury) were up-regulated. Further, microarray analysis revealed de-repression of several spermatogenesis-specic genes upon Pcgf6-KD, suggesting that Pcgf6 may play a role during spermatogenesis. Upon in vitro differentiation, Pcgf6-KD ES cells showed increased hemangioblast formation, paralleled by increased hematopoietic development. In summary, results of this study suggest that Pcgf6 is involved in maintaining ES cell identity by repressing lineage-specific gene expression in undifferentiated ES cells.}, subject = {Embryonale Stammzelle}, language = {en} }