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111	Three-Dimensional Neuroepithelial Culture from Human Embryonic Stem Cells and Its Use for Quantitative Conversion to Retinal Pigment Epithelium Tanaka, Elly M., Zhu, Yu, Carido, Madalena, Meinhardt, Andrea, Kurth, Thomas, Karl, Mike O., Ader, Marius 18 January 2016 (has links) A goal in human embryonic stem cell (hESC) research is the faithful differentiation to given cell types such as neural lineages. During embryonic development, a basement membrane surrounds the neural plate that forms a tight, apico-basolaterally polarized epithelium before closing to form a neural tube with a single lumen. Here we show that the three-dimensional epithelial cyst culture of hESCs in Matrigel combined with neural induction results in a quantitative conversion into neuroepithelial cysts containing a single lumen. Cells attain a defined neuroepithelial identity by 5 days. The neuroepithelial cysts naturally generate retinal epithelium, in part due to IGF-1/insulin signaling. We demonstrate the utility of this epithelial culture approach by achieving a quantitative production of retinal pigment epithelial (RPE) cells from hESCs within 30 days. Direct transplantation of this RPE into a rat model of retinal degeneration without any selection or expansion of the cells results in the formation of a donor-derived RPE monolayer that rescues photoreceptor cells. The cyst method for neuroepithelial differentiation of pluripotent stem cells is not only of importance for RPE generation but will also be relevant to the production of other neuronal cell types and for reconstituting complex patterning events from three-dimensional neuroepithelia. info:eu-repo/classification/ddc/610 ddc:610
112	RNA-based regulation of pluripotency and differentiation Kastelic, Nicolai 24 October 2022 (has links) RNA-bindende Proteine sind zentrale Regulatoren der Genexpression, aber ihre Funktionen bei der Koordinierung von Zellschicksalsentscheidungen sind unzureichend verstanden. In dieser Studie haben wir RNA interactome capture angewandt, um die globalen Dynamiken des RNA-gebundenen Proteoms während der Auflösung der Pluripotenz und neuronaler Differenzierung zu bestimmen. Wir haben entdeckt, dass 30-40% der RNA-bindenden Proteine sehr dynamisch während der Zellschicksalentscheidungen sind, die Abundanzdynamiken dieser Proteine aber nicht hauptursächlich dafür zu sein scheinen. Basierend auf unseren Daten haben wir ZAP (ZC3HAV1) als einen Faktor identifiziert, der mit Pluripotenz assoziiert ist. Um die Rolle von ZAP in der Stammzellbiologie zu analysieren, haben wir PAR-CLIP, SLAMseq und einen Differenzierungsassay angewandt. Unsere Daten haben gezeigt, dass ZAP mehr als 2,000 mRNA-Transkripte innerhalb des murinen Stammzelltranskriptoms in Abhängigkeit von CG-Dinukleotiden bindet. Zieltranskripte sind angereichert mit Genfunktionen in Zell-Zell-Interaktionen, Gewebemorphogenese und Pluripotenzregulation und werden in Abwesenheit von ZAP stabilisiert. Auβerdem haben wir herausgefunden, dass Depletion von ZAP zu flacherer und breiterer Koloniemorphologie von Stammzellen bei gleichzeitiger Fehlexpression von hunderten von Genen inklusive Lineage-Faktoren führt. Desweiteren führt Abwesenheit von ZAP zu erhöhter Geschwindigkeit bei der Auflösung der Pluripotenz. Zusammengefasst stellen wir die These auf, dass ZAP ein multi-modaler Regulator der Pluripotenz ist. ZAP agiert als positiver Regulator während Aufrechterhaltung der Pluripotenz, während es am Anfang der Pluripotenzauflösung pluripotenz-fördernde Faktoren herunterreguliert. Schlussendlich demonstriert diese Studie, wie die Erforschung von Dynamiken des RNA-gebundenen Proteoms während Zellschicksalsentscheidungen neue Wege öffnet, um die Funktion von RNA-bindenden Proteinen im entwicklungsbiologischen Kontext zu analysieren. / RNA-binding proteins are key regulators of gene expression, but their functions in coordinating cell fate transitions are poorly understood. In this study, we applied RNA interactome capture to determine the global dynamics of the RNA-bound proteome during dissolution of pluripotency and neuronal differentiation. We discovered that 30-40% of RNA-binding proteins are highly dynamic during cell fate transitions and that these dynamics do not appear to be predominantly governed by alterations in their abundance. Based on our data, we identified ZAP (ZC3HAV1) as a factor highly associated with pluripotency. In order to dissect the role of ZAP in mESC biology, we applied a variety of approaches including PAR-CLIP, SLAMseq and pluripotency exit reporter assays. We found that ZAP binds more than 2,000 mRNAs in the mESC transcriptome in a CG dinucleotide-dependent manner. Targets are enriched for transcripts encoding cell-cell adhesion, tissue morphogenesis and pro-pluripotency regulators and stabilized in absence of ZAP. Furthermore, we found that ZAP depletion leads to flattened and spreading stem cell colony morphology, concomitant misexpression of hundreds of transcripts including lineage factors and accelerated early dissolution of pluripotency. In conclusion, we propose that ZAP is a multi-modal stem cell RNA-binding protein acting as a positive regulator in maintenance of pluripotency while aiding downregulation of pro-pluripotent factors at the onset of differentiation. Ultimately, this study demonstrates how exploration of RNA-bound proteome dynamics during cell fate transitions can open paths to dissecting functions of RNA-binding proteins in a developmental context. Stammzelldifferenzierung RNA interactome capture ZC3HAV1 Pluripotenz stem cell differentiation RNA interactome capture ZC3HAV1 pluripotency 572 Biochemie 570 Biologie WD 5355 WE 2600 ddc:572 ddc:570
113	<b>The Role of Vezf1 in Mammalian Development</b> Isaiah K. Mensah (18861202) 22 June 2024 (has links) <p dir="ltr">Embryonic development relies on the complex interplay of epigenetic regulation, timely expression of genes, signal transduction pathways, and diverse morphological changes. The heart is the first organ to form during mammalian embryonic development. The proper development of the heart is critical to supply nutrients and oxygen to other cell types of the organism. Most cells that comprise the heart originate from the mesoderm post-gastrulation. Cardiomyocytes are the predominant cell type and confer function to the heart via contractile activity. The development and proliferation of cardiomyocytes ceases shortly after birth, where cardiomyocytes only nucleate and increase in size. Consequently, cardiomyocyte insufficiency underlies most cardiovascular diseases, a leading cause of death globally.</p><p dir="ltr">Vascular endothelial zinc finger 1 (VEZF1) is a transcription factor expressed predominantly in mesoderm during development. Previous studies from our lab show that the loss of VEZF1 impairs the differentiation of embryonic stem cells into endothelial cells, a cell type derived from mesoderm. Other published studies also show that Vezf1 loss impairs cardiomyocyte growth in Zebrafish and hematopoietic cell differentiation. Our work here describes a detailed investigation of the role of Vezf1 in the differentiation of mesoderm and cardiomyocytes using mouse embryonic stem cell (ESC) differentiation as a mammalian model system. We initially developed an efficient method, known as the Wnt Switch method, to differentiate ESCs into cardiomyocytes. Our technique relies on the treatment of differentiating ESCs with small molecule inhibitors: i) CHIR99021, which induces mesoderm development via the activation of Wnt signaling in the first 48 hours of differentiation, followed by ii) XAV939, which inhibits Wnt signaling and drives mesoderm cells toward cardiomyocyte differentiation pathway. The Wnt Switch method significantly increases the efficiency of cardiomyocyte derivation (86%) from ESC compared to published methods (56%).</p><p dir="ltr">Interestingly, the Wnt Switch method showed that despite the external stimulation of Wnt signaling, Vezf1 KO cells are unable to differentiate into cardiomyocytes and show reduced expression of mesodermal genes 48 hrs post-differentiation. To better understand the stage-specific role of Vezf1 in cardiomyocyte development, we generated doxycycline-inducible Vezf1 knockdown clones that significantly reduce Vezf1 protein levels upon treatment with doxycycline. We found that the knockdown of Vezf1 prior to mesoderm induction significantly impaired ESC differentiation but had no significant effect on cardiomyocyte development after mesoderm induction. These data indicate that Vezf1 expression is crucial for proper mesoderm and, thus, mesodermal lineage development. Further, FACS analysis showed reduced mesoderm cell populations derived from Vezf1 null post-differentiation. We used high throughput sequencing methods to determine genome-wide Vezf1 binding by ChIP-SEQ and compared gene expression in WT and Vezf1 null cells using RNA-SEQ. The data indicated that VEZF1 binds near the promoters of numerous Wnt signaling genes after differentiation and that the expression of Wnt pathway genes decreases when Vezf1 is lost. Interestingly, supplementing WNT3A protein in culture media of Vezf1 null cells rescues the expression of Wnt target genes necessary for mesoderm formation.</p><p dir="ltr">Differentiating Vezf1 KO cells to endothelial or cardiomyocyte lineages also resulted in massive cell death. The surviving cells interestingly stained positive for alkaline phosphatase (AP) staining, indicating retention of the pluripotency in Vezf1 KO cells. Whereas, re-culturing of WT ESC in LIF media, after differentiating them for five days in the absence of LIF, results in cell death, Vezf1 KO cells proliferate and form AP-positive and SSEA-positive colonies. We further show the retention of pluripotency gene expression post-differentiation using RNA sequencing and RT-qPCR. Moreover, we show that the continued expression of pluripotency genes post-differentiation was not a consequence of reduced global DNA methylation in Vezf1 KO cells.</p><p dir="ltr">Interestingly, our data show that Vezf1 is a transcriptional activator and binds to key pro-differentiation pathways like the MAPK signaling and WNT signaling pathways. The loss of Vezf1 correlates with reduced expression of genes in the pro-differentiation pathways. We show that CTCF, an insulator-binding protein, opportunistically binds to VEZF1 sites on genes in the pro-differentiation signaling pathways in VEZF1 KO cells. Therefore, we hypothesized that this opportunistic CTCF binding is the mechanism that drives the repression of pro-differentiation signaling genes or compensates for the loss of Vezf1 binding to support basal gene expression in the absence of VEZF1. Given the dire consequences of pluripotency in cancer stem cells, we investigated the expression of Vezf1 in cancers. We found that Vezf1 expression is reduced in many cancers and is correlated with poor prognosis. We also show that MAPK3, a prominent member of the MAPK signaling pathway, is reduced in these cancers, highlighting a strong correlation between Vezf1 expression and Mapk3 gene expression in cancers. The data extend our observation of pluripotency in ESCs to cancers. To gain further insights into the role of Vezf1 in cancer, we utilized F9 embryonic carcinoma cells. F9 cells have been reported to retain pluripotency expression post-differentiation. Interestingly, the ectopic and transient expression of Vezf1 in F9 cells significantly reduced the expression of pluripotency genes, suggesting that Vezf1 is sufficient to repress pluripotency gene expression in F9 carcinoma cells. These data highlight the significant role of Vezf1 in pluripotency gene repression and provide an excellent avenue for treating cancer relapse caused by the occurrence of cancer stem cells.</p><p dir="ltr">In conclusion, our research elucidates the critical role of Vezf1 in cardiomyocyte formation and pluripotency regulation during embryonic development. Understanding the molecular mechanisms underlying Vezf1-mediated pathways provides insights into developmental processes and holds promise for therapeutic interventions for cardiomyocyte regeneration and against cancers.</p> Signal transduction Cardiomyocyte Development cell differentiation fate Wnt signalings pluripotency heart VEZF1 Cancer stem cell Stem cells
114	In-vitro-Charakterisierung und kardiale Differenzierung von induziert pluripotenten Stammzellen der Maus / In vitro characterisation and cardiac differentiation of murine induced pluripotent stem cells Lentzen, Max-Philipp 06 April 2016 (has links) No description available. 610 cardiomyocytes induced pluripotent stem cells embryonic stem cells transcription factors lentiviral stem cell cassette pluripotency hanging drop double transgene mice neomycine eGfp Medizin (PPN619874732)
115	La dérivation de cellules souches embryonnaires chez le cheval Laflamme, Simon 08 1900 (has links) Les cellules souches embryonnaires (ES) sont porteuses de grands espoirs en recherche biomédicale dans le but d’apporter un traitement définitif à l’ostéoarthrose. Parce que certaines articulations des chevaux sont similaires à celles des humains, cet animal représente un modèle important dans l’évaluation de stratégies de régénération du cartilage. Cependant, pour expérimenter un traitement par les cellules ES chez le cheval, des cellules ES équines (eES) n’ont toujours pas pu être dérivées. Dans ce contexte, l’objectif principal de cette étude est de dériver des lignées de cellules eES. Le premier objectif de notre étude consiste à optimiser la technique de dérivation des cellules eES. Nous démontrons que la lignée de cellules nourricières et le stade de développement des embryons influencent l’efficacité de la technique de dérivation tandis que l’inhibition de voies de signalisation menant à la différenciation des cellules ES ne l’influence pas sous nos conditions. Le deuxième objectif de notre étude est de caractériser de façon plus approfondie les lignées de cellules eES obtenues. Nous démontrons que les cellules eES dérivées expriment autant des marqueurs associés aux cellules pluripotentes qu’aux cellules différenciées et que l’inhibition de voies de signalisation menant à la différenciation n’influence pas l’expression de ces marqueurs. Pour conclure, nous confirmons avoir dérivé des lignées de cellules semblables au cellules eES (eES-like) ne correspondant pas complètement aux critères des cellules ES. / Embryonic stem (ES) cells carry high hopes for biomedical research in order to provide definitive treatment for osteoarthritis. The horse is considered to be an important animal model for examining osteoarthritis treatments. However, despite almost thirty years of research, authentic equine ES (eES) cells have not yet been derived. In this context, the main objective of this study was to derive eES cell lines. The first objective of our study was to optimize the technique for deriving eES cells. We show that different feeder cell lines and embryo development stages influence the effectiveness of this technique while the use of cell signalling inhibitors does not influence eES cell derivation. The second objective was to characterize markers of pluripotency and differentiation in eES cell lines by RT-PCR. We demonstrate that the eES cells express both markers associated with pluripotent cells and differentiated cells and that the presence of cell signalling inhibitors in the culture medium does not influence the expression of these markers. In conclusion, we confirm having derived eES-like cells but these do not meet all the molecular criteria of authentic ES cells. Cellules souches embryonnaires Cellules nourricières Blastocyste Inhibiteurs de voies de signalisation Pluripotence Différenciation Cheval Embryonic stem cells Feeder cell line Blastocyst Cell signalling inhibitors pluripotency Differentiation Horse
116	Modélisation des néoplasmes myéloprolifératifs sporadiques et familiaux avec les cellules de patients induites à la pluripotence / Modeling of sporadic and familial myeloproliferative neoplasms with induced pluripotent stem cells derived from Patients Saliba, Joseph 21 October 2013 (has links) Les néoplasmes myéloprolifératifs (NMP) sont des maladies acquises touchant la cellule souche hématopoïétique et qui aboutissent à une hyperproduction de cellules sanguines dont le phénotype dépend du type du NMP. La mutation la plus proéminente des NMP est JAK2V617F. Elle peut être associée à différents NMP sporadiques et familiaux.Une des problématiques, non résolue, des NMP est de comprendre comment une même mutation JAK2V617F peut donner plusieurs maladies. Notre hypothèse est que le phénotype observé pourrait dépendre du nombre de copies de JAK2V617F. Une autre inconnue concerne la cause génétique des formes familiales.Pour ces raisons, nous avons modélisé des NMP sporadiques et un cas familial par les iPS. Cette approche devrait nous permettre d’une part, de comparer les effets de JAK2V617F à l’état hétérozygote et homozygote sur l’hématopoïèse et d’autre part, d’avancer dans la compréhension des effets d’une duplication de 5 gènes que nous avons identifiée, par une approche de génétique, comme un facteur de susceptibilité chez 2 familles.Dans la première partie du travail, concernant la modélisation des NMP sporadiques, nous avons montré que JAK2V617F augmente la prolifération des cellules myéloïdes obtenues à partir des iPS. D’autre part, nous avons pu mettre en évidence une différence marquée dans l’hypersensibilité à la TPO et à l’EPO entre les lignées hétérozygotes et homozygotes pour JAK2V617F permettant d’expliquer le phénotype des PV et des TE. Dans la deuxième partie concernant les NMP familiaux, nous avons pu mettre en évidence un phénotype spécifique attribuable à la seule duplication. Grace à ce modèle, nous allons pouvoir identifier le(s) gène(s) responsable(s) du phénotype. Ce travail apporte la preuve de concept que les iPS sont un bon outil pour modéliser les NMP sporadiques et familiaux et qu’elles peuvent servir comme outils de criblage de petites molécules développées à des fins thérapeutiques. / Myeloproliferative neoplasms (MPN) are clonal hematologic diseases which lead to an overproduction of blood cells. The affected myeloid lineage depends on the type of MPN. JAK2V617F is the most predominant mutation in MPN and can be associated with various sporadic and familial cases.One main issue to address in MPN is to understand how a single mutation JAK2V617F can give rise to several diseases. Our hypothesis is that this phenotypic heterogeneity might be due to the JAK2V617F gene dosage. Another goal is to identify the genetic cause of familial MPN.For these reasons, we modeled sporadic and familial MPN cases with iPS technology. This approach allowed us i) to compare the impact of heterozygous and homozygous JAK2V617F mutation on hematopoiesis and ii) to get insight into the effects of a 5 genes duplication that we identified as a susceptibility locus uncovered by a genetic approach in 2 families.In the first part of the work concerning sporadic MPN modeling, we showed that JAK2V617F increases iPS myeloid potential. Furthermore, we showed a marked difference in the TPO and EPO hypersensitivity between heterozygous and homozygous JAK2V617F iPS cell lines that could be linked to the difference between PV and ET. In the second part of the work, we demonstrated a specific phenotype due to the sole duplication. This model will allow us to identify the gene(s) responsible of the phenotype. This study brings the proof of concept that iPS can be used for sporadic and familial MPN modeling and drug screening. Néoplasmes myéloprolifératifs Variabilité du nombre de copies Mutations JAK2V617F Délétion 20q IPS Pluripotence Differenciation cellulaire Inhibiteurs pharmacologiques Myeloproliferative Neoplasms Copy Number Variation Mutations JAK2V617F 20q deletion IPS Pluripotency Cellular differenciation Pharmacological inhibitors
117	Understanding the dynamics of embryonic stem cell differentiation Strawbridge, Stanley Eugene January 2019 (has links) The two defining features of mouse embryonic stem (ES) cells are self-renewal and naive pluripotency, the ability to give rise to all cell lineages in the adult body. In addition to being a unique and interesting cell type, pluripotent ES cells have demonstrated their potential for continued advancements in biomedical science. Currently, there is an improved understanding in the chemical signals and the gene regulatory network responsible for the maintenance of ES cells in the naive pluripotent state. However, less is understood about how ES cells exit pluripotency. My main aim is to study the dynamics and the factors affecting the irreversible exit from pluripotency. Expression of the reporter Rex1-GFPd2, which is inactivated upon exit from naive pluripotency, was analyzed by quantitative long-term single-cell imaging over many generations. This technique allowed chemical, physical, and genealogical information to be recorded during the transition to exit. Culture conditions that provided homogeneous populations were used in all assays and these data were validated against bulk-culture data where appropriate. Changes in real-time cell behavior were seen in cell-cell contact, motility, and cell-cycle duration. Undifferentiated ES cells form tightly joined colonies, with cells that exhibit low motility and a constant cell-cycle duration. Exit is associated with increasing cell motility, decreased cell-cell contact, and an acceleration in cell proliferation. The onset of exit is associated with a sudden and irreversible inactivation of the Rex1-GFPd2 reporter. This inactivation is asynchronous, as it occurs at different times and in different generations during ES cell differentiation. However, examination of daughter cells generated from the same mother revealed a high level of synchronicity. Further investigation revealed that high levels of correlation in cell-cycle duration and Rex1-GFPd2 expression exist between differentiating sister and cousin cells, providing strong evidence that cell potency is inherited symmetrically in cell divisions during exit $\textit{in vitro}$. How cells change fate is a fundamental question in developmental biology. Knowing the cellular dynamics during the transition out of naive pluripotency is important for harnessing the potential of ES cells and understanding how cell fate decisions are made during embryonic development. The quantification of the timing of exit from naive pluripotency coupled with identifiable changes in cellular behaviors, such as motility, cell size, and cell-cycle duration, enhances the understanding of how cell fate changes are regulated during directed differentiation.
118	Pou5f1 Post-translational Modifications Modulate Gene Expression and Cell Fate Campbell, Pearl 20 December 2012 (has links) Embryonic stem cells (ESCs) are characterized by their unlimited capacity for self-renewal and the ability to contribute to every lineage of the developing embryo. The promoters of developmentally regulated loci within these cells are marked by coincident epigenetic modifications of gene activation and repression, termed bivalent domains. Trithorax group (TrxG) and Polycomb Group (PcG) proteins respectively place these epigenetic marks on chromatin and extensively colocalize with Oct4 in ESCs. Although it appears that these cells are poised and ready for differentiation, the switch that permits this transition is critically held in check. The derepression of bivalent domains upon knockdown of Oct4 or PcG underscores their respective roles in maintaining the pluripotent state through epigenetic regulation of chromatin structure. The mechanisms that facilitate the recruitment and retention of Oct4, TrxG, and PcG proteins at developmentally regulated loci to maintain the pluripotent state, however, remain unknown. Oct4 may function as either a transcriptional activator or repressor. Prevailing thought holds that both of these activities are required to maintain the pluripotent state through activation of genes implicated in pluripotency and cell-cycle control with concomitant repression of genes required for differentiation and lineage-specific differentiation. More recent evidence however, suggests that the activator function of Oct4 may play a more critical role in maintaining the pluripotent state (Hammachi et al., 2012). The purpose of the studies described in this dissertation was to clarify the underlying mechanisms by which Oct4 functions in transcriptional activation and repression. By so doing, we wished to contextualize its role in pluripotent cells, and to provide insight into how changes in Oct4 function might account for its ability to facilitate cell fate transitions. As a result of our studies we find that Oct4 function is dependent upon post-translational modifications (PTMs). We find through a combination of experimental approaches, including genome-wide microarray analysis, bioinformatics, chromatin immunoprecipitation, functional molecular, and biochemical analyses, that in the pluripotent state Oct4, Akt, and Hmgb2 participate in a regulatory feedback loop. Akt-mediated phosphorylation of Oct4 facilitates interaction with PcG recruiter Hmgb2. Consequently, Hmgb2 functions as a context dependent modulator of Akt and Oct4 function, promoting transcriptional poise at Oct4 bound loci. Sumoylation of Oct4 is then required to maintain Hmgb2 enrichment at repressed loci and to transmit the H3K27me3 mark in daughter progeny. The expression of Oct4 phosphorylation mutants however, leads to Akt inactivation and initiates the DNA Damage Checkpoint response. Our results suggest that this may subsequently facilitate chromatin reorganization and cell fate transitions. In summary, our results suggest that controlled modulation of Oct4, Akt, and Hmgb2 function is required to maintain pluripotency and for the faithful induction of transcriptional programs required for lineage specific differentiation. Oct4 pluripotency stem cells Akt Polycomb Group Proteins Trithorax Group Proteins transcriptional regulation transcriptional regulatory network cancer cell cycle checkpoint function cell fate transitions cell cycle SET complex Hmgb2 post-translational modifications Pou5f1 Signal Transduction embryonic stem cells Set
119	MicroRNA Expression Profiling of Multipotent Adult Germline Stem Cells Zovoilis, Athanasios 04 February 2009 (has links) No description available. 610 Medizin, Gesundheit Medicine microRNA embryonic stem cell spermatogonial stem cell maGSC pluripotency differentiation miR-290 miR-302 oncomirs 42.13 42.23 MED 283: Molekularbiologie {Medizin} MED 293: Embryologie {Medizin} WK 000: Entwicklungsbiologie
120	Zur Rolle von Stra8 in pluripotenten Stammzellen / On the role of Stra8 in pluripotent stem cells Kotzenberg, Linda 25 January 2011 (has links) No description available. 610 Medizin, Gesundheit Medicine Stra8 Keimzell-spezifisch Stammzellen Pluripotenz Embryonalen Stammzellen multipotent adult Germline Stem Cells Stra8 multipotent adult germline stem cell 44 M

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