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Characterizing Changes in the Transcriptional Networks underlying Pluripotency in Mouse Embryonic Stem Cells upon the Induction of DifferentiationSchwartz, Michael Louis 26 November 2012 (has links)
Mouse embryonic stem cells (mESCs) are pluripotent cells capable of differentiating into all three germ layers present in the adult mouse. In this thesis, I have investigated the transcriptional changes that mESCs undergo as they are induced to differentiate towards the mesoderm lineage by 2i/LIF withdrawal and dimethyl sulfoxide (DMSO) treatment. 5 days of differentiation causes significant drops in expression of Sox2 and Oct4 primary transcript, while expression of Nanog and Kit significantly drops after only 1 day. It was determined that DMSO has no effect on the short-term changes in Nanog and Kit expression induced by 2i/LIF withdrawal. An expanded look at pluripotency-associated genes shows significant up-regulation of Oct4 and down-regulation of Klf4 and Stat3 following only 6 hours of 2i/LIF withdrawal. This data indicates that while some aspects of the transcriptional networks underlying pluripotency respond quickly to mesodermal differentiation cues, others remain unchanged for up to 5 days.
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Characterizing Changes in the Transcriptional Networks underlying Pluripotency in Mouse Embryonic Stem Cells upon the Induction of DifferentiationSchwartz, Michael Louis 26 November 2012 (has links)
Mouse embryonic stem cells (mESCs) are pluripotent cells capable of differentiating into all three germ layers present in the adult mouse. In this thesis, I have investigated the transcriptional changes that mESCs undergo as they are induced to differentiate towards the mesoderm lineage by 2i/LIF withdrawal and dimethyl sulfoxide (DMSO) treatment. 5 days of differentiation causes significant drops in expression of Sox2 and Oct4 primary transcript, while expression of Nanog and Kit significantly drops after only 1 day. It was determined that DMSO has no effect on the short-term changes in Nanog and Kit expression induced by 2i/LIF withdrawal. An expanded look at pluripotency-associated genes shows significant up-regulation of Oct4 and down-regulation of Klf4 and Stat3 following only 6 hours of 2i/LIF withdrawal. This data indicates that while some aspects of the transcriptional networks underlying pluripotency respond quickly to mesodermal differentiation cues, others remain unchanged for up to 5 days.
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Nat1 promotes translation of specific proteins that induce differentiation of mouse embryonic stem cells / Nat1はマウス胚性幹細胞の分化を誘導する特定のタンパク質の翻訳を促進するSugiyama, Hayami 23 March 2017 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(医科学) / 甲第20286号 / 医科博第77号 / 新制||医科||5(附属図書館) / 京都大学大学院医学研究科医科学専攻 / (主査)教授 斎藤 通紀, 教授 篠原 隆司, 教授 戸口田 淳也 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM
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Defining the transcriptional and epigenetic signature of mouse embryonic stem cells with compromised developmental potencySchacker, Maria Anna January 2019 (has links)
Mouse embryonic stem (ES) cells have played a crucial role in studying developmental processes and gene function in vivo. They are extremely useful in the generation of transgenic animals as they can be genetically manipulated and subsequently microinjected into blastocyst stage embryos, where they combine with the inner cell mass and contribute to the developing embryo. Some of the resulting pups are chimaeric, consisting of a mixture of cells derived from the host blastocyst and the injected ES cells. We have identified several ES cell clones arising from gene targeting experiments with an impaired capacity to generate viable chimaeras. When injected into blastocysts, these clones cause embryonic death during mid to late gestation, suggesting that the cells are able to contribute to the embryo but interfere with normal embryonic development. The aim of this work was to identify the underlying changes in the transcriptome, epigenome or cell surface markers that have occurred in these compromised ES cells and to further define the developmental phenotype of the chimaeric embryos. Different stages during development were analysed and whereas there was little difference in embryonic death at gestational day e13.5, there was a significant decrease in embryos surviving to gestational day e17.5. Additionally, severe haemorrhaging was observed in all the dead embryos and small foci of haemorrhaging could also be seen in a number of embryos that were still alive. This was also observed at e13.5, albeit to a less severe extent. Using RNA sequencing to discover differences in the transcriptome between control ES cells and the compromised ES cells, five genes were identified that were downregulated in the compromised cells. Four of these, Gtl2, Rtl1as, Rian and Mirg are all located in the imprinted Dlk1-Dio3 region on chromosome 12 and are normally expressed from the maternal genome. This pattern was also validated in tissues from e17.5 chimaeric embryos. The expression of this locus is to a large extent regulated by a differentially methylated region located approximately 13kb upstream of the Gtl2 promoter, the IG-DMR. Whereas this is usually only methylated on the paternal copy, in the compromised ES cells both the paternal and the maternal copy were fully methylated, likely causing the silencing of Gtl2, Rtl1as, Rian and Mirg. Using the DNA methyltransferase inhibitor 5-azacytidine, expression of Gtl2 could be rescued. Injection of those 5-azacytidine treated cells into blastocysts did partially rescue the embryonic lethal phenotype. Additionally, cell surface markers were analysed in a phenotypic screen using phage display. NGS analysis of the phage outputs indicates that there may be additional differences in cell surface markers between the control and compromised ES cell clones, but their specific details remain to be identified. Overall, we have identified the maternally expressed genes of the Dlk1-Dio3 region as markers that can distinguish between ES cells with normal or compromised developmental potency and propose to include these genes in the pre-blastocyst injection screening routine for experiments involving the production of chimaeras or genetically modified mouse strains.
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Date with destiny : genetic and epigenetic factors in cell fate decisions in populations of multipotent stem cellsEdri, Shlomit January 2019 (has links)
The governance of cell fate decisions during development is a fundamental biological problem. An important aspect of this is how cells exit a multipotent state and choose their fates in a correct manner and proportion. To tackle an aspect of this problem, I have focused on 2 multipotent models: one infinite self-renewal pluripotency in an artificial environment, and the other, bipotent progenitors in the context of the mouse embryo. The first model aimed to explore the effects of chromatin-associated factors on the ability of pluripotent mouse Embryonic Stem Cells (ESCs) to self-renew, via monitoring gene expression heterogeneity of key genes. The second model focused on Neural Mesodermal Progenitors (NMPs), a bipotent cell population found in the Caudal Lateral Epiblast (CLE) of mammalian embryos, which contributes to the spinal cord and paraxial mesoderm. The aim here was to derive NMPs in vitro which exhibit similar gene expression patterns and function like their mouse embryo counterpart and study their renewal and differentiation in detail. The first multipotent model explores the effects of chromatin remodelling on cell fate decisions, specifically investigating the consequences of inhibiting the histone acetyltransferase Kat2a on the ESCs fate. I found first, that the effect of Kat2a inhibition depends on the pluripotent state of the cells; cells in a ground state exhibit a resistance to Kat2a inhibition and maintain their pluripotency, whereas cells in a naïve state experience destabilization of their pluripotency gene regulatory network and shift towards differentiation. Second, that Kat2a inhibition in the naïve state results in a decline in the gene expression noise strength contributed by the promoter activation operation, which suggests that when ESCs become lineage-primed their transcriptional noise is constrained. In the bipotent model, the NMPs are identified as cells coexpressing Sox2 and T/Brachyury, a criterion used to derive NMP-like cells from ESCs in vitro. Comparison between the different NMPs protocols stresses that Epiblast Stem Cells (EpiSCs) are an effective source for deriving a multipotent population resembling the embryo Caudal Epiblast (CE), that generates NMPs. Furthermore, self-organization of this CE-like population, resulted in axially organized aggregates. Exploiting the mouse embryo CLE as a reference shows that EpiSCs derived NMPs, monolayers and aggregates, consist of a high proportion of cells with the embryo's NMP signature. Importantly, studying this system in vitro sheds light on the sequence of events which lead to NMP emergence in vivo. On this basis, I conclude that understanding the initial state of cells at a crossroads is important to reveal the limitations it imposes on the cells fate exploration, hence makes it possible to mimic more precisely the fate decision process in vitro.
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Characterisation of HP1γ in mammalian cellsWiese, Meike January 2018 (has links)
The degree of chromatin compaction plays a fundamental role in controlling the accessibility of DNA to the transcription machinery as well as other DNA-dependent biological pathways. The mammalian HP1 (Heterochromatin protein 1) protein family consists of three members: HP1α, β and γ. Each paralogue regulates formation and maintenance of heterochromatin by binding to the repressive chromatin marks H3K9me2/3 with their chromodomains (CDs). Despite high sequence conservation, each HP1 paralogue possesses specific functions, which are likely to be cell type specific. The aim of my thesis was to find novel functions for HP1γ in mouse embryonic stem cells (mESCs) and breast cancer cells. Mass spectrometry analysis identified citrullination of residues R38 and R39 within the CD of HP1γ. I show that these residues are citrullinated by peptidyl arginine deiminase 4 (PADI4) in vitro and in vivo. Mutations in HP1γ (R38/9A), designed to mimic the loss of charge accompanied with citrullination, affect HP1γ’s binding to H3K9me3 peptides and reduce its residence time on chromatin in differentiated mESCs, indicating a role for citrullination in regulating HP1γ binding to chromatin during differentiation. Furthermore, I studied the phenotype of HP1γ depletion in two human breast cancer models and found that HP1γ is essential for cell proliferation and viability of cancer, but not of normal epithelial cells. I performed whole transcriptome analysis in breast cancer cells depleted of HP1γ and cross-referenced it with its genomic localisation, which identified increased expression of interferon/antiviral defense genes and activation of pro-apoptotic pathways. Whilst genes involved in these pathways were not directly bound by HP1γ, this analysis also identified HP1γ as a novel regulator of zinc finger (ZNF) genes. In summary, I identified novel post-translational modifications in HP1γ and characterised them in mESCs. I further demonstrated a role for HP1γ regulating breast cancer cell viability and identified HP1γ as a novel regulator of ZNF genes. My findings highlight HP1γ as a potential target for breast cancer therapy.
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The Characterization of a Human Disease-Associated Mutation Nkx2.5 R142C Using In vitro and In vivo ModelsZakariyah, Abeer January 2017 (has links)
Nkx2.5 is a cardiac transcription factor that plays a critical role in heart development. In humans, heterozygous mutations in the NKX2.5 gene result in congenital heart defects (CHDs), but the molecular mechanisms by which these mutations cause the defects are still unknown. NKX2.5 R142C is a mutation that is found to be associated with atrial septal defect and atrioventricular block in 13 patients from one family. The R142C mutation is located within both the DNA-binding domain and the nuclear localization sequence of NKX2.5 protein. The pathogenesis of CHDs in humans with R142C point mutation is not well understood. Also, a previous study in our laboratory has identified Mypt1/PP1 as a novel interacting partner of Nkx2.5 in stem cells during cardiomyogenesis. Nkx2.5 has a PP1-binding consensus sequence RVxF located in the N-terminus of the homeodomain. Notably, the PP1-binding sequence, RVxF, is mutated from arginine to cysteine in patients with the R142C heterozygous mutation. However, the ability of the R142C mutation to bind to the Mypt1/PP1 complex has not been investigated yet. The following thesis addresses the functional deficit associated with R142C by utilizing a combination of in vitro, and in vivo models. It also addresses the interaction of Mypt1/PP1 with the R142C mutation. We have generated a heterozygous mouse embryonic stem cell (mESC) line, harboring the murine homologue (R141C) of the human mutation R142C in Nkx2.5 gene. We show reduced cardiomyogenesis and impaired subcellular localization of Nkx2.5 protein in Nkx2.5R141C/+ mESCs. Gene expression profiling of Nkx2.5R141C/+ mESCs revealed a global misregulation of genes important for heart development and identified putative direct target genes of Nkx2.5 that are affected by the R141C heterozygous mutation. We also generated a mouse model harboring the human mutation R142C. We show that the Nkx2.5R141C/R141C homozygous embryos are developmentally arrested around E10.5 with delayed heart morphogenesis. Moreover, Nkx2.5R141C/+ newborn mice are grossly normal but show variable cardiac defects and downregulation of ion channel genes that later cause AV block in adult mice. Finally, we show that the R141C mutant binds to the Mypt1/PP1 complex but is not inhibited or translocated to the perinuclear region in the presence of Mypt1/PP1 as the WT Nkx2.5 is.
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FUNCTIONAL GENOMICS STUDY TO UNDERSTAND THE ROLE OF SEROTONIN IN MOUSE EMBRYONIC STEM CELLSNagari, Anusha 19 October 2011 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Serotonin (5-hydroxytryptamine, 5-HT) is a monoamine neurotransmitter that is synthesized from the amino acid L-tryptophan and is reported to localize in mitochondria of embryonic stem cells. Even before its role as a neurotransmitter in mature brain was discovered, 5-HT has been shown to play an important role in regulating brain development. However, there is a lack of knowledge about the downstream target genes regulated by serotonin in embryonic stem (ES) cells. Towards this end, our study helps in understanding transcriptional regulatory mechanisms of 5-HT responsive genes in ES cells. By combining the gene expression data with motif prediction algorithms, literature validation and comparison with public domain data, gene targets specific to endogenous or exogenous 5-HT in ES cells were identified. By performing one-way ANOVA, and volcano plots using GeneSpring software, we identified 44 5-HT induced and 29 5-HT suppressed genes, likely to be transcriptionally regulated by 4 & 2 TFs respectively. Motif enrichment analysis on these target genes using MotifScanner revealed that the transcription factor TFAP2A plays a key role in regulating the expression of 5-HT responsive genes. Furthermore, by comparing our dataset with published expression profiles of ES cells, we observed a number of 5-HT responsive target genes showing enrichment in ES cells. Genes such as Nanog, Slc38a5, Hoxb1 and Eif2s1 from this analysis have been observed to be components of ‘stemness’ phenotypes reported in literature. Functional annotation of the 5-HT responsive genes identified gene ontologies such as regulation of translation in response to stress and energy derivation by oxidation, suggesting a regulatory role for 5-HT in mitochondrial functions of ES cells. Additionally, enrichment of other biological process terms such as development of various parts of nervous system, cell adhesion, and apoptosis suggests that 5-HT target genes may play an important role in ES cell differentiation. Our study implemented a new combinatorial approach for identifying gene regulatory mechanisms involved in 5-HT responsive genes and proposed potential mediatory role for serotonin in ES cell differentiation and growth. Thus, this study provides potential 5-HT target genes in ES cells for biological validation.
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Effects of Trimethylamine N-Oxide on Mouse Embryonic Stem Cell PropertiesBarron, Catherine Mary 06 August 2020 (has links)
Trimethylamine N-oxide (TMAO) is a metabolite derived from dietary choline, betaine, and carnitine via intestinal microbiota metabolism. In several recent studies, TMAO has been shown to directly induce inflammation and reactive oxygen species (ROS) generation in numerous cell types, resulting in cell dysfunction. However, whether TMAO will impact stem cell properties remains unknown. This project aims to explore the potential impact of TMAO on mouse embryonic stem cells (mESCs), which serve as an in vitro model of the early embryo and of other potent stem cell types. Briefly, mESCs were cultured in the absence (0mM) or presence of TMAO under two different sets of treatment conditions: long-term (21 days), low-dose (20µM, 200µM, and 1000µM) treatment or short-term (5 days), high-dose (5mM, 10mM, 15mM) treatment. Under these treatment conditions, mESC viability, proliferation, and stemness were analyzed. mESC properties were not negatively impacted under long-term, low-dose TMAO treatment; however, short-term, high-dose treatment resulted in significant reduction of mESC viability and proliferation. Additionally, mESC stemness was significantly reduced when high-dose treatment was extended to 21 days. To investigate an underlying cause for TMAO-induced loss in mESC stemness, metabolic activity of the mESCs under short-term, high-dose TMAO treatment was measured with a Seahorse XFe96 Analyzer. TMAO treatment significantly decreased the rate of glycolysis, and it increased the rate of compensatory glycolysis upon inhibition of oxidative phosphorylation (OxPHOS). It also significantly increased the rate of OxPHOS, maximal respiratory capacity, and respiratory reserve. These findings indicate that TMAO induced a metabolic switch of mESCs from high glycolytic activity to greater OxPHOS activity to promote mESC differentiation. Additionally, TMAO resulted in increased proton leak, indicating increased oxidative stress, and elucidating a potential underlying mechanism for TMAO-induced loss in mESC stemness. Altogether, these findings indicate that TMAO decreases stem cell potency potentially via modulation of metabolic activity. / Master of Science / Trimethylamine N-oxide (TMAO) is a metabolite that is produced by the bacteria in the gut after the consumption of specific dietary ingredients (e.g., choline, carnitine, betaine). These ingredients are commonly found in meat and dairy products, and thus make up a large part of the average American diet. Recently, it was discovered that high TMAO levels in the bloodstream put people at an increased risk for heart disease, neurodegenerative diseases (e.g., Alzheimer's Disease), diabetes, stroke, and chronic kidney disease. At the cellular level, there is evidence that TMAO increases inflammation and the production of oxygen radicals, which causes cells to lose their function and promotes the onset of disease. TMAO has been well studied in adult cell types; however, no one has investigated whether TMAO will impact cells of the early embryo. This project aims to explore the impact of TMAO on mouse embryonic stem cells (mESCs), which are cells that represent the early stage of embryonic development and are critical for proper development of the final offspring. In addition, mESCs may also help to provide insight into how TMAO impacts other stem cell types, some of which are present throughout the entire human lifespan and play an important role in the body's ability to repair itself and maintain overall health. My project demonstrated that TMAO does not impact the overall health of mESCs under normal conditions, which signifies that TMAO generated by a pregnant mother may not directly impact the early embryonic stage of development. Further studies should be conducted to determine the potential impact of TMAO on late stages of embryonic and fetal development. Next, to simulate diseased conditions, the mESCs were treated with extremely high concentrations of TMAO in order to determine what concentration of TMAO will negatively impact these cells. It was found that at 5mM TMAO, mESCs begin to lose their basic properties and become dysfunctional. They are impaired in their viability, growth, ability to become other cell types, and in their metabolic activity. These mESC properties are shared with several types of adult stem cells, and therefore, these findings help to provide insight into how TMAO may impact stem cells found in the adult body which are exposed to a lifetime of high TMAO levels. In the future, we would like to further explore the impact of TMAO on mESCs at the molecular level as well as examine the direct impact of TMAO on other stem cell types.
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Essential amino acid depletion by embryonic stem cells as a mechanism of immune privilegeIchiryu, Naoki January 2013 (has links)
Mouse embryonic stem cells (ESCs) are capable of differentiating into any somatic cell type and are known to display fragile immune privilege in vivo and in vitro. The extent to which the depletion of essential amino acids (EAAs) by ESCs contributes to this phenomenon was investigated. ESCs were found to express various enzymes capable of catabolising EAAs within the culture medium. In particular, depletion of threonine, valine and lysine was found to have significant impact on T cell proliferation and differentiation, biasing their polarisation towards a FoxP3<sup>+</sup> T regulatory (T<sub>reg</sub>) phenotype. Supplementing ESC conditioned medium with these three EAAs alone rescued normal T cell proliferation, whereas artificially limiting their availability was sufficient to induce T<sub>reg</sub> cell differentiation to a level equivalent to general EAA depletion. The pattern of EAA catabolism by mouse ESC was shared by induced pluripotent stem cells, while mouse melanoma cell lines and human ESCs displayed distinct patterns of EAA depletion. The cytosolic branched chain aminotransferase enzyme, Bcat1, catalyses the first step of branched chain amino acid catabolism (isoleucine, leucine and valine), and is highly expressed by both mouse and human ESCs. The contribution of this enzyme to the establishment of acquired immune privilege by ESC-derived tissues was, therefore, investigated. ESC lines were derived from mice lacking Bcat1 activity and were characterised. Bcat1<sup>−/−</sup> ESC lines displayed no difference to their wildtype counterparts (Bcat1<sup>LoxP</sup>) in terms of in vitro proliferation and their capacity to form teratomas in vivo. Furthermore, the loss of Bcat1 function had little impact on the inhibition of T cell proliferation in culture, ability to induce T<sub>reg</sub> cell commitment or their ability to prevent rejection by T cell receptor transgenic recipients, suggesting the minimal contribution of Bcat1 to the depletion of EAAs by ESCs. In conclusion, EAA depletion by mouse ESC may provide a mechanistic explanation for the previously described immune-suppressive capacity of ESC.
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