The expression and regulation of genes correlating with human Embryonic Stem Cell (hESC) pluripotency and self-renewal

Gaobotse, Goabaone

January 2015

Stem cell pluripotency and self-renewal are two important attributes of human embryonic stem cells which have led to enhanced interest in stem cell research. Understanding the mechanisms that underlie the regulation and maintenance of these properties is imperative to the clinical application of stem cells. Pluripotency and self-renewal are regulated by different genes, transcription factors and other co-factors such as FoxD3 and Klf4. Oct4, Nanog and Sox2 are central to the stem cell regulatory circuitry. They form interactions with co-factors to promote cell proliferation and inhibit differentiation by negatively regulating differentiation markers. However, there are other novel pluripotency associated factors yet to be studied. In this study, bioinformatics and functional analyses were employed to identify a potential pluripotency gene called YY1AP1 from our lab's pre-existing microarray data. YY1AP1, a transcription regulatory gene, showed consistent down-regulation with induced cell differentiation. It was further investigated. First, its co-localization with Oct4 in both hESCs and iPSCs was confirmed by immunofluorescence staining. Knockdown experiments were then performed on this gene to investigate effects of knocking it down on gene expression in hESCs. Knocked-down cells were characterized for markers of pluripotency and differentiation at the transcript level. Results showed a down-regulation of pluripotency genes with no specific promotion of any of the germ layer markers. Gene expression at the protein level in knocked down cells was then assessed for YY1AP1, and its binding partner YY1, and pluripotency markers. Results showed that proteins of YY1AP1, YY1, Oct4, Nanog and CTCF were down regulated while the tumour suppressor gene protein, p53, was up-regulated in YY1AP1 deficient stem cells. Protein to protein interaction studies showed that YY1AP1, YY1, Nanog and CTCF proteins directly interacted with each other. Differentiation of YY1AP1deficient cells into EBs led to an almost complete shutdown of all gene expression, an indication that the cells did not form 'real' EBs. Differentiation of YY1AP1 ablated cells did not support any lineage promotion either. These results suggest a potentially new role for YY1AP1 in proliferation and self-renewal of stem cells through its possible direct binding to CTCF or its indirect binding to CTCF in complex with YY1.

Definition of the human embryonic stem cell niche in vitro

Soteriou, Despina

January 2012

The unique pluripotent character of human embryonic stem cells (hESCs) places them in the forefront of scientific research, especially as they hold great promise for application in regenerative medicine, as well as drug discovery and toxicity analyses. Conventionally hESCs are cultured on mitotically inactivated mouse embryonic fibroblasts (MEFs) that are derived from E13.5 mouse embryos. One of the biggest challenges in the hESC field is the development of a reproducible and defined hESC culture system that would eliminate batch-to-batch variability of the MEFs as well as exposure to feeder cells that makes hESCs less applicable for clinical use. Previous studies have shown that maintenance of pluripotency can be achieved using Matrigel, a mixture of ECM components, or ECM derived from MEFs or human fibroblasts (Xu, et al., 2001, Klimanskaya, et al., 2005). Other groups have succeeded in culturing feeder-free hESCs by using extracellular matrix (ECM) proteins, such as fibronectin, vitronectin or laminin, as substrates for hESC culture in the absence of feeders, confirming that ECM plays a key role in maintaining hESC growth (Amit, et al., 2004, Braam, et al., 2008, Baxter, et al., 2009, Rodin, et al., 2010).The aim of this work was to investigate the ECM deposited by MEF feeder cells and to isolate and identify proteins in the ECM that support undifferentiated growth of hESCs in the absence of feeders. We have investigated whether matrices derived from different passage feeders differ in their ability to support pluripotency. I also assessed the integrin receptor profile of hESCs in order to define the mechanisms of ECM engagement. ECM was extracted from two strains of feeder cells, CD1 x CD1 and MF1 x CD1, at passages 4 (early passage), 9 and 14 (late passage), and assessed for its ability to support hESC self-renewal over at least 3 passages. Tandem mass spectrometry was used to analyse the ECM composition of each MEF line, thereby allowing a comparison between different passages and different cell lines. More than 100 proteins were identified for each sample, the majority of which were ECM proteins and shared between different passage feeders. As predicted, fibronectin, which is known to support hESC self-renewal was the most prevalent species in all MEF-derived matrices. Furthermore a proteomic analysis of matrix derived from hESCs cultured in feeder-free conditions on fibronectin coating substratum revealed a number of proteins shared between supportive MEF populations and hESC, suggesting other potential candidates that may either assist or interfere with the maintenance of pluripotent hESCs. Of the proteins identified fibrillin-1, perlecan, fibulin-2 were tested as substrates for culturing hESCs in the absence of feeders, with the prospect of developing an optimised feeder-free culturing system that uses a combination defined animal-free substrates. Finally this study sought to dissect the interaction between ECM and growth factors and how these extrinsic factors may affect self-renewal and maintenance of pluripotency-associated gene expression. Interruption of hESC attachment, as well as removal of growth factors appeared to affect transcript levels of pluripotency genes, OCT4 and NANOG, suggesting that the microenvironment can influence hESC fate.

616.02774

Neural derivatives from human embryonic stem cells: a cellular and molecular model for studying the role of orthodenticle homeobox2 in medulloblastoma progression

Kaur, Ravinder

29 July 2015

Medulloblastoma (MB) is the most common malignant primary pediatric brain tumor and is divided into 4 subtypes based on different genomic alterations and gene expression profiles. This extensive heterogeneity has made it difficult to assess the functional relevance of genes to malignant progression. For example, expression of the transcription factor, Orthodenticle homeobox2 (OTX2) is frequently upregulated in multiple MB variants; however, its role may be subtype-specific. We recently demonstrated that neural precursors derived from transformed human embryonic stem cells (trans-hENs), but not their normal counterparts (hENs), resemble Groups 3 and 4 MBs. These trans-hENs also have >10-fold expression of OTX2. Therefore, we hypothesize that OTX2 has cell context-dependent functions in MB and using both normal and trans-hENs, we can delineate its specific roles in MB progression. Parallel experiments with MB cells revealed that OTX2 exerts inhibitory effects on hEN and sonic hedgehog (SHH) MB cells by regulating growth, self-renewal and migration in vitro and tumor growth in vivo. Overexpression of OTX2 was accompanied by a decrease in expression of pluripotent genes such as SOX2. This was supported by exogenous introduction of SOX2 in OTX2+ SHH MB and hENs that rescued the OTX2 induced cellular deficits including self-renewal and cell migration. In contrast, OTX2 is oncogenic and promotes self-renewal of trans-hENs and Group 3 and 4 MBs by modulating expression of genes related to neurodevelopment and axonal guidance. OTX2 may play a central role in regulating the balance between self-renewal and differentiation in these aggressive MB cells. Our studies underscore the value of hESC derivatives as alternatives to cell lines and heterogeneous patient samples for investigating the contribution of key developmental regulators to MB progression. Using the neural derivatives of hESCs, we have demonstrated a novel role for OTX2 in self-renewal and migration of hENs and MB cells. Moreover, our results reveal a cell context-dependent link between OTX2 and pluripotent genes. The association between OTX2 and axonal guidance genes is important for its oncogenic role and may potentially be exploited for managing drug resistant stem cell and highly motile cellular populations in the most aggressive Group 3 and 4 MB subtypes. / February 2017

Epigenetic and environmental determinants of undifferentiated human embryonic stem cell renewal

Koutsouraki, Eirini

January 2015

Embryonic stem cells are derived from the inner cell mass of a blastocyst-stage embryo and are characterized by the ability to self-renew and differentiate into all cell types of an adult organism, as demonstrated by their transplantation into embryos in the mouse. Isolation of cells with similar properties from human embryos has permitted the study of human cell differentiation in vitro as might occur during development. As such, human ES cells may be useful to assess and predict the developmental toxicity of environmental compounds capable of epigenetic alterations of the genome and its expression. The first objective of my research was to validate the functional significance to maintenance of an undifferentiated human ES cell state of expressed genes whose epigenetic modification is conserved across diverse lines and/or likely to be deterministic of an embryo stem cell associated epigenetic state. The second goal was to determine the sensitivity and relationship of the expression of these genes to environmental factors known to perturb the epigenome, specifically subcytotoxic exposure to diverse organic and metallic compounds and the availability of atmospheric oxygen. siRNA-mediated knockdown of genes previously identified on the basis of the conserved methylation status of gene associated Cytosine-Guanine islands (i.e. GLIS2, HMGA1, PFDN5, TET1 and JMJD2C) and two related family members (TET2 & 3) resulted in induction of cell differentiation in two independent human ES cell lines (RH1 and H9). Differentiation was reflected by morphological changes, reduction or loss of pluripotency associated markers, qualitative and quantitative reduction in genomic 5-hmC and upregulation of diverse germinal lineage markers. Subcytotoxic exposure of the same human ES cell lines to diverse compounds known to alter the epigenome (i.e. 5-azacytidine, sodium arsenite, cadmium chloride and valproic acid) generally induced downregulation of the aforementioned genes, loss of genomic hydroxymethylation and differentiation when applied under normoxia (20% O2), the exception being valproic acid. The same treatment applied under hypoxia (0.5% O2), did not induce differentiation, with the exception of cadmium chloride. Hypoxia is a general feature of developing embryos prior to the establishment of a maternal/fetal placental interface and fetal cardiovasculature. The protective effect of hypoxia was associated with elevation of ROS, expression of the dioxygenases TET1 and JMJD2C, and genomic hydroxymethylation. This research has demonstrated that genes identified on the basis of a conserved pattern of epigenetic modification function in the maintenance of an undifferentiated human ES cell phenotype. Furthermore, a human ES cell-based toxicology test system has been developed with which one can assess the subcytotoxic effects of compounds known to disrupt the epigenome and affect development by assessing their impact on maintenance of an undifferentiated human ES cell state. This is reflected by alterations in pluripotency markers, epigenetically-defined biomarkers and changes in global 5-hmC levels and the expression of genes responsible for this epigenetic modification (TET1-3). The epigenetically-defined biomarkers of pluripotent human ES cell identity (GLIS2, HMGA1, PFDN5, JMJD2C and TET1) could serve as biomarkers for screenings of compounds at an epigenetic level as their expression has been shown to be altered upon compound exposure along with monitoring the expression of 5-hmC.

616.02

Identification of Housekeeping Genes in Human Embryonic Stem Cells

Schaller, Susanne

January 2009

No description available.

housekeeping genes

human embryonic stem cells

Bioinformatics

Bioinformatik

Identification of Housekeeping Genes in Human Embryonic Stem Cells

Schaller, Susanne

January 2009

No description available.

housekeeping genes

human embryonic stem cells

Bioinformatics

Bioinformatik

Dissecting the Role of the Histone Demethylase KDM1B in Maintenance of Pluripotency and Differentiation of Human Embryonic Stem Cells

Alfarhan, Dalal

04 1900

Lysine-specific Demethylase 1B (KDM1B) is a chromatin regulator which functions as a histone eraser through the removal of the post-translational modifications mono and dimethylation of histone 3 on lysine 4 (H3K4me1/2). This process is enhanced by the formation of a complex with Nuclear Protein Glyoxylate Reductase (NPAC). NPAC resolves the sequestration of the nucleosome histone tail to allow robust demethylation of H3K4me2 by KDM1B, during transcriptional elongation by RNA polymerase 2 (RNAP II). KDM1B is involved in many crucial processes during development. Its physiological functions include the establishment of maternal genomic imprints, reset of the epigenome during somatic cell reprogramming, and regulation of brown adipogenic differentiation. In light of this, the role of KDM1B in human embryonic stem cells (hESCs) is examined through CRISPR/Cas9-editing to further dissect its biological functions during embryogenesis. CRISPR-induced knockouts of KDM1B exhibited similar cell proliferation rate and expression of OCT4 and NANOG pluripotency markers to wildtype cells. Furthermore, KDM1B-/- clones were able to maintain their pluripotency potential by differentiating to all germ layers in teratoma and embryoid body formation assays. In addition, RNA-seq of KDM1B-/- clones showed enrichment of mesoderm lineage-related gene ontology (GO) terms in the downregulated differentially expressed genes. Thus, KDM1B is believed to be dispensable during the pluripotent stage of the cell but proved fundamental during later stages of development.

KDM1B

Histone demethylation

CRISPR knockout

Human embryonic stem cells

Differentiation

Approaches to Reduce Selection of Genomic Variants in Human Pluripotent Stem Cell Culture

Riggs, Marion

13 May 2014

Optimizing culture conditions that reduce genomic instability in human pluripotent stem cells (hPSCs) is an unmet challenge in the field. Results from our lab and numerous research groups demonstrate that hPSCs are prone to genomic aberrations and single-cell passaging increases the rate of genomic alterations. However, single-cell based passaging maintains advantages for scale-up and standardizing differentiation protocols. In this study, we investigated the problem of genomic instability in hPSC cultures with the goal towards identifying and characterizing candidate genes that could contribute to generation and survival of abnormal hPSCs. Based on microarray analysis, we identify ARHGDIA, located on 17q25, as a candidate gene conferring selective advantage to trisomy 17 hPSCs. Using lentiviral approaches to overexpress ARHGDIA in hPSCs, [hPSC (Arg)], we functionally validate that in enzymatically passaged co-cultures, hPSC (Arg) lines exhibit competitive advantage against wild type hPSCs, [hPSC (WT)]. Additionally, hPSC (Arg) lines exhibit increased single-cell survival at low density plating. In co-cultures with hPSC (WT), ROCKi exposure attenuated the competitive advantage of hPSC (Arg) subpopulations. For the first time, this work demonstrates that increased expression of a gene on 17q25 confers selective advantage to hPSCs. In parallel studies, using medium devoid of bFGF containing LIF plus two inhibitors, MEK inhibitor (PD0325901) and p38 inhibitor (SB203580), we demonstrate that hPSCs are LIF responsive and can be stably maintained in naive pluripotent culture conditions. Based on their clonal viability, we propose that naive hPSCs are a more genetically stable population than primed hPSCs, when passaged as single- cells. These studies will aid the long-term goal of hPSC scale-up while promoting stable propagation of genomically normal hPSCs.

Human Embryonic Stem Cells

Cell Culture

Culture Adaptation

Pluripotent

Genomic Instability

Life Sciences

A cell-type and compartment specific analysis of glutathione and hydrogen peroxide

Trautsch, Irina Karoline

19 June 2019

No description available.

610

ROS

cardiomyocytes

human embryonic stem cells

redox sensing

Medizin (PPN619874732)

Investigating the effects of extracellular matrix molecules on human embryonic stem cells

Iskender, Banu

January 2012

Human embryonic stem cells are pluripotent cells that have indefinite replicative potential and ability to differentiate into derivatives of three germ layers. HESCs are conventionally derived and grown on mitotically inactivated mouse embryonic fibroblasts and there are some alternative feeder types of human origin that have been used to replenish hESCs while trying to prevent cross-species contamination. The trophic factors that are secreted by the feeders are found to be important for long-term pluripotency but there are also supportive culture systems for hESCs lacking feeder cells which might suggest that not only the interactions with the feeders affect the behaviour of hESCs but also the components of the niche may take part in the decision of self-renewal or differentiation. Extracellular matrix components are known to exert their stimulatory or inhibitory effects by localising cells into a specific microenvironment in natural niches but have been relatively little investigated for hESCs. The aim of this study was to investigate ECM components which might have a role in the maintenance of hESCs. I have first investigated human placental stromal fibroblasts and immortalised human placental stromal fibroblasts for the support hESC pluripotency as an anlternative feeder type to conventional mouse embryonic fibroblasts. Secondly, the matrices derived from hPSFs and ihPSFs were assessed for their ability to support hESC pluripotency. Tandem mass spectrometry was used to identify ECM components released by human feeders in order to characterise the range of extracellular matrix proteins that support the growth of self-renewing hESCs. The majority of the molecules was shared between the cell types irrespective of hPSF cell derived matrix was not being supportive for hESC pluripotency, with some ECM components being unique ihPSFs. Collagen VI, tenascin C and versican were tested for hESC attachment and as substrates for feeder-free culture system in order to develop an optimised feeder-free system. Furthermore, integrin receptor profile of different hESC lines was also determined in order to identify the mechanisms of substrate attachment. Integrin attachment was shown to be vital for hESC engagement to fibronectin and vitronectin in feeder-free systems. The components of the integrin signalling machinery were identified in hESCs and the significance of integrin-mediated signalling in hESC self-renewal was demonstrated by blocking integrin β1 on fibronectin and integrin aVβ5 on vitronectin. Moreover, intracellular signalling mediator c-Src was shown to involve in ECMregulated signalling by affecting the phosphorylation of Focal Adhesion Kinase. Inhibition of Src led to a decrease in the expression of pluripotency-associated markers. Finally, the effects of growth factor supplementation on the maintenance of pluripotency in defined feeder-free conditions were studied by withdrawal of growth factors and blocking FGF Receptors. FGF-2 was shown to be essential for long-term self-renewal while the effects on pluripotency deteriorated in the absence of both FGF-2 and Activin A. Taken together this project highlighted the importance of substrate attachment and growth factors on the regulation of hESC self-renewal.