Mechanisms Regulating Early Mesendodermal Differentiation of Human Embryonic Stem Cells: A Dissertation

VanOudenhove, Jennifer J.

02 June 2016

Key regulatory events take place at very early stages of human embryonic stem cell (hESC) differentiation to accommodate their ability to differentiate into different lineages; this work examines two separate regulatory events. To investigate precise mechanisms that link alterations in the cell cycle and early differentiation, we examined the initial stages of mesendodermal lineage commitment and observed a cell cycle pause that occurred concurrently with an increase in genes that regulate the G2/M transition, including WEE1. Inhibition of WEE1 prevented the G2 pause. Directed differentiation of hESCs revealed that cells paused during commitment to the endo- and mesodermal, but not ectodermal, lineages. Functionally, WEE1 inhibition during meso- and endodermal differentiation selectively decreased expression of definitive endodermal markers SOX17 and FOXA2. These findings reveal a novel G2 cell cycle pause required for endodermal differentiation. A role for phenotypic transcription factors in very early differentiation is unknown. From a screen of candidate factors during early mesendodermal differentiation, we found that RUNX1 is selectively and transiently up-regulated. Transcriptome and functional analyses upon RUNX1 depletion established a role for RUNX1 in promoting cell motility. In parallel, we discovered a loss of repression for several epithelial genes, indicating that RUNX1 knockdown impaired an epithelial to mesenchymal transition during differentiation. Cell biological and biochemical approaches revealed that RUNX1 depletion compromised TGFβ2 signaling. Both the decrease in motility and deregulated epithelial marker expression upon RUNX1 depletion were rescued by reintroduction of TGFβ2, but not TGFβ1. These findings identify novel roles for RUNX1-TGFβ2 signaling in mesendodermal lineage commitment.

Cell Differentiation

Human Embryonic Stem Cells

Cell Cycle

Cell Lineage

Dissertations, UMMS

Cell Biology

Cellular and Molecular Physiology

Understanding Multiple Independent Functions of the Tip60 Acetyltransferase in Embryonic Development

Acharya, Diwash

15 December 2017

Chromatin is a dynamic structure, and chromatin remodeling enzymes regulate chromatin structure to control gene expression and proper lineage specification. Tip60-p400 is a multi-subunit chromatin remodeling complex containing two biochemical activities: the Tip60 subunit is a lysine acetyltransferase (KAT) that targets histones and non-histone proteins, and p400 catalyzes ATP-dependent incorporation of histone variant H2AZ into chromatin. Both of these chromatin modifications have been widely studied with respect to gene expression, DNA damage repair, and apoptosis. Ablation of these catalytic subunits causes defects in normal embryonic development, ESC self-renewal, and gene expression. My goal has been to understand the multiple independent functions of Tip60-p400 acetyltransferase in ESC maintenance and embryonic development. I showed that Tip60 KAT function is dispensable for gene expression, chromatin accessibility, and ESC self-renewal, which is different from Tip60 knockdown phenotype. Interestingly, KAT deficient mutants exhibited defect in differentiation towards mesoderm and endoderm lineages. Consistent with this defect, I also observed gastrulation defect in mice lacking Tip60 KAT activity. Together, these data demonstrate that Tip60 KAT dependent function is only required during later stages of embryonic development, and it is dispensable for ESC self-renewal and pre-implantation development. Tip60 KAT contains four isoforms generated from alternative splicing, whose individual functions are poorly characterized. In the second part of this thesis, I investigated the developmental role of one of the isoforms of Tip60, called Tip55. Unlike Tip60 knockout mice, which lack all the isoforms and causes pre-implantation lethality, I found that ablation of Tip55 results in post-implantation lethality. I further found that loss of Tip55 causes defects in heart, and neural tube development, demonstrating the essential function of Tip55 isoform for organogenesis during embryonic development. Together, these studies have provided new insight into the functions of Tip60-p400 and the mechanisms by which this complex regulates gene expression, ESC pluripotency, and embryonic development. Furthermore, these studies set the stage for future work to identify how the catalytic and non-catalytic functions are directed to perform distinct regulatory functions, as well as how each Tip60 isoform individually contributes to formation of the mammalian body plan.

KAT5

Tip60

Gene Regulation

Embryonic stem cells

Mouse embryonic development

Cell Biology

Developmental Biology

Chromatin Dynamics in Pluripotency and Differentiation: A Dissertation

Yildirim, Ozlem

23 May 2012

Different cell types in multi-cellular organisms heritably maintain different gene expression patterns despite carrying the same genome; a phenomenon termed epigenetics. It is widely believed that the packaging state of the genome, known as chromatin structure, carries epigenetic information. How chromatin states are inherited and how chromatin structure changes during development, moreover how different epigenomes, such as chromatin and DNA modifications communicate with each other during these processes are important questions. Accordingly, understanding the mechanisms that govern pluripotency and differentiation requires details of chromatin dynamics. The major goal of my doctoral thesis was to understand the genome wide view of chromatin dynamics in embryonic stem cells. My studies centered on two aspects of chromatin dynamics in mouse embryonic stem cells—localization and function of two antagonistic chromatin regulators and genome-wide histone variant dynamics. In the first part, we examined the roles of several chromatin regulators whose loss affects the pluripotent state of ES cells. We found that two such regulators, Mbd3 and Brg1, control a large number of genes in ES cells via antagonistic effects on promoter nucleosome occupancy. Moreover, we found that both Mbd3 and Brg1 play key roles in the biology of 5-hydroxymethylcytosine (5hmC), a newly identified DNA modification. Mbd3, which was named by homology to known cytosine methyl binding domains, yet does not bind methylcytosine in vitro, co-localized in ES cells with 5hmC. Furthermore, Mbd3 localization was lost in knockdown cells lacking the major 5mC hydroxylase, Tet1. Our results suggest, contrary to current dogma, that 5hmC is more than just an intermediate in cytosine demethylation pathways, that it may regulate genes via the Mbd3/NuRD complex. Finally, we showed that both Mbd3 and Brg1 are themselves required for normal levels of 5hmC in vivo, identifying a feedback loop between 5hmC and Mbd3. Together, our results identified a possible effector for 5hmC, thereby suggesting a functional role for this DNA modification. Moreover, Brg1 and Mbd3 can now be added to the growing list of regulators with opposite effects on ES cell gene expression, suggesting that pairs of antagonistic chromatin binding proteins may be a common phenomenon in ES cell transcription regulation (Yildirim et al., Cell 2011). The second part of my dissertation concerns the dynamics of several histone variants. Seminal studies in the Henikoff lab showed that certain histone variants are replaced throughout the cell cycle, in contrast to the predominant replication-coupled mode of histone assembly. Work in yeast and flies showed that rapid histone turnover occurs at epigenetically-regulated genomic regions, such as chromatin boundary elements or Polycomb/Trithorax binding sites. Notably, promoter regions of actively transcribed genes exhibit rapid turnover, suggesting that histone turnover may have an important role in gene regulation, as higher histone turnover rate would provide higher probability of DNA element exposure and faster erasure of chromatin marks of the replaced histones. In order to extend such studies to a model for pluripotency and differentiation, we developed a system for measuring histone replacement in mouse ES cells. To be able to carry out turnover experiments in ES cells, we generated stable ES cell lines that can be induced to express epitope-tagged histone variants. Our results confirmed that histone turnover patterns are conserved from yeast to mammals and that turnover profiles are histone variant specific. Murine H3.3 turnover is similar to H3.3 turnover in flies, with peaks at the promoters of highly transcribed genes. MacroH2A2, a variant generally linked to gene repression, had a more complex turnover profile. Surprisingly, we found rapid exchange of macroH2A2 occurring around transcription start sites of a number of highly expressed genes. At poorly expressed genes, on the other hand, macroH2A2 localizes upstream or downstream of transcription start sites and is incorporated slowly, either via slow turnover or via replication-coupled incorporation. Finally, we have used those inducible ES cell lines to generate mice, which will enable future studies on tissue-specific histone replacement in vivo. In summary, my thesis work not only significantly extends our understanding of chromatin regulation in general but also provides a more detailed landscape of chromatin structure and regulation in ES cells. Extending these analyses to differentiating cells and in vivo tissue specific dynamics should provide us with a better understanding not only of cell type specific chromatin organization but also improve our ability to program and re-program genomic landscapes in vitro.

Chromatin

Embryonic Stem Cells

Epigenesis

Genetic

Amino Acids, Peptides, and Proteins

Cell and Developmental Biology

Cells

Genetic Phenomena

Genetics and Genomics

Selective Development of Myogenic Mesenchymal Cells from Human Embryonic and Induced Pluripotent Stem Cells / ヒトESおよびiPS細胞からの筋原性間葉系細胞の選択的分化誘導

Awaya, Tomonari

25 November 2013

京都大学 / 0048 / 新制・論文博士 / 博士(医学) / 乙第12788号 / 論医博第2068号 / 新制||医||1000(附属図書館) / 30807 / 京都大学大学院医学研究科医学専攻 / (主査)教授 瀬原 淳子, 教授 髙橋 淳, 教授 山下 潤 / 学位規則第4条第2項該当 / Doctor of Medical Science / Kyoto University / DFAM

Embryonic stem cells

Induced pluripotent stem cells

Skeletal muscle

Satellite cells

Myogenesis

Cell transplantation

Muscular dystrophy

490

Transplantation of embryonic and induced pluripotent stem cell-derived 3D retinal sheets into retinal degenerative mice. / 網膜変性モデルマウスへのES/iPS細胞由来立体網膜シート移植

Juthaporn, Assawachananont

23 March 2015

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第18850号 / 医博第3961号 / 新制||医||1007(附属図書館) / 31801 / 京都大学大学院医学研究科医学専攻 / (主査)教授 山下 潤, 教授 吉村 長久, 教授 中畑 龍俊 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Transplantation

Embryonic stem cells (ESCs)

Induced pluripotent stem cells (iPSCs)

Retinal differentiation

3D retinal sheet

Retinal degeneration

Outer segment

490

Effect of Topography on Mouse Embryonic Stem Cells During Pluripotency and Neural Differentiation

Nasir, Wafaa

01 October 2018

No description available.

Biomedical Engineering

Embryonic stem cells

PCL

Scaffolds, YIGSR, Neural Differentiation

Laminin

Fibronectin

Synthetic Peptides

Electrospinning

Tissue Engineering

Neuroregeneration

Nanofibers

USE OF ENDOTHELIAL-SPECIFIC PROMOTERS TO IDENTIFY AND SELECT DIFFERENTIATING STEM CELLS

Kim, Saejeong

19 March 2009

No description available.

Biomedical Research

embryonic stem cells

endothelial differentiation

isolation

endothelial promoters

selection

Flk1

Tie1

PECAM

VE-Cadherin

in vivo imaging

LENGTHENED G1 PHASE INDICATES DIFFERENTIATION STATUS IN HUMAN EMBRYONIC STEM CELLS.

Calder, Ashley

10 1900

<p>Human embryonic stem cells (hESC) have potential applications as tools for drug screening to identify small molecule regulators of self-renewal or differentiation. Elucidating the mechanisms governing lineage commitment in hESC will allow for efficient derivation of specified cell types for clinical use. Recognizing the early steps in loss of pluripotency is key to achieving both goals of drug screening and derivation of therapeutically relevant cell types. Here we report the use of a real time cell cycle fluorescent reporter for the first time in hESC that indicates onset of differentiation in a lineage unbiased manner. Pluripotent hESC possess a short cell cycle length, due primarily to a truncated G1 phase. G1 lengthens concomitant with differentiation. Stable hESC lines expressing the live cell cycle reporter exhibit fluorescence only during G1. Due to the short length of pluripotent G1 phase, G1 fluorescence is only weakly and transiently detected, however it is quickly increased to easily detectable levels upon onset of differentiation. We hypothesize that lengthened G1 phase can be used as an indicator of differentiation status of individual human embryonic stem cells.</p> <p>Cells with lengthened G1 are typically negative for pluripotency markers OCT4, Tra-1-60 and SSEA-3 following differentiation. Differentiated cells with lengthened G1 also demonstrate increased levels of lineage-specific differentiation markers at both the protein and mRNA level. Automated image analysis of hESC indicates this mutually exclusive relationship between lengthened G1 and pluripotency exists both on the cellular level and in colonies as a whole. Here we have shown that lengthened G1 indicates both loss of pluripotency and gain of lineage markers.</p> / Master of Science (MSc)

human embryonic stem cells

cell cycle

G1 length

differentiation

lineage committment

loss of pluripotency

Cell Biology

Cell Biology

Neoplastic Human Embryonic Stem Cells as a Model of Radiation Resistance of Human Cancer Stem Cells

Dingwall, Steven

10 1900

<p>Recent studies have implicated that a small sub population of cells within a tumour, termed cancer stem cells (CSCs), have an enhanced capacity for tumour formation in multiple cancers and may be responsible for recurrence of the disease after treatment. Further work has suggest that CSCs are radioresistant relative to other cell types composing tumours, in several solid cancers. The genetic and phenotypic heterogeneity of malignant CSCs, as well as the difficulty associated with culturing these cells in vitro, limits the capacity to study the response of CSCs to ionizing radiation. Further, the absence of normal known counterparts for many CSCs has made it difficult to compare the radiation responses of CSCs with the normal stem cells required for post radiotherapy tissue regeneration. Here we have shown that transformed human embryonic stem cells (t-hESCs), showing features of neoplastic progression, produce tumours resistant to radiation relative to their normal counterpart. We further show that t-hESCs have a reduced capacity for radiation induced cell death via apoptosis and exhibit altered cell cycle arrest in vitro, relative to hESCs. We found that decreased levels of p53ser15, following DNA double strand break induction, is associated with this radiation resistance.</p> / Master of Science (MSc)

radiation resistance

cancer stem cells

embryonic stem cells

radiation

Medical Biophysics

Medical Sciences

Medicine and Health Sciences

Medical Biophysics

Validation and Characterization of TCF7L1-SALL4 Protein-Protein Interaction in Mouse Embryonic Stem Cells

Seo, Caleb

January 2019

Here, we validate novel protein interactors of TCF7L1 (also known as TCF3), a downstream transcription factor in the Wnt/β-catenin signaling pathway, from an initial protein interaction screen that utilized the BioID system in mouse embryonic stem cells. The BioID-TCF7L1 screen identified multiple proteins including several transcription factors and numerous epigenetic regulators. Notably, SALL4, a key embryonic stem cell factor belonging to the SPALT family of transcription factors was validated to interact with TCF7L1 through Proximity Ligation Assay (PLA), and Co-Immunopreciptation (Co-IP). Analysing mRNA transcriptomic signatures of TCF7L1-null mEScs and SALL4 overexpressing mESCs, we observed similarly increased output of the pluripotency-gene, Tbx3, suggesting a transcriptionally opposing function between TCF7L1 and SALL4. Furthermore, we identified that SALL4 also interacted with TCF7, suggesting that SALL4 may interact with all four members of the TCF/LEF transcription factor family to regulate Wnt targets. This work further validates the utility and effectiveness of screening transcription factor interactors through the BioID system and provides important insights into SALL4 mediated Wnt regulation through the TCF/LEFs. / Thesis / Master of Science (MSc) / The biology of cells is highly complex. The genes within are under tight regulation to promote balance that is critical to the growth and status of the cell. Cells communicate with one another to support this balance through molecule secretion signaling which dictates biology. Understanding the complex biology within cells is critical, and therefore here we study one of many signaling pathways known as the Wnt Signaling Pathway. This work contributes to the knowledge of Wnt signaling by validating the interaction of proteins that dictate the onset or offset of important genes in mouse embryonic stem cells.