Embryonic stem cells alter cardiomyocyte electrophysiological properties

Karan, Priyanka

January 2008

Thesis (M. S.)--Computer Science, Georgia Institute of Technology, 2009. / Committee Chair: Dr. Samuel Dudley; Committee Member: Dr. Micheal Davis; Committee Member: Dr. Robert Butera

Embryonenschutz und Stammzellgesetz rechtliche Aspekte der Forschung mit embryonalen Stammzellen /

Brewe, Manuela.

January 2006

Thesis (Ph. D.)--Universität Mannheim, 2004/2005. / Includes bibliographical references (p. [313]-344).

Embryonic stem cells Genetic engineering

Characterization and therapeutic transplantation of stem cells /

Meyer, Jason S.,

January 2004

Thesis (Ph.D.)--University of Missouri-Columbia, 2004. / Typescript. Vita. Includes bibliographical references (leaves 153-173). Also available on the Internet.

Stem cells Embryonic stem cells

Characterization and therapeutic transplantation of stem cells

Meyer, Jason S.,

January 2004

Thesis (Ph.D.)--University of Missouri-Columbia, 2004. / Typescript. Vita. Includes bibliographical references (leaves 153-173). Also available on the Internet.

Stem cells Embryonic stem cells

Cloning and annotation of novel transcripts from human embryonic stem cells

Khattra, Jaswinder

05 1900

Both cDNA tag-based and DNA chip hybridization assays have revealed widespread transcriptional activity across mammalian genomes, providing a rich source of novel protein-coding and non-coding transcripts. Annotation and functional evaluation of this undefined transcriptome space represents a major step towards the comprehensive definition of biomolecules regulating the properties of living cells, including embryonic stem cells (ESCs) and their derivatives. In this study I analysed 87 rare mRNA transcripts from human ESCs that mapped uniquely to the human genome, in regions lacking evidence for known genes or transcripts. In addition, the transcripts appeared enriched in the hESC transcriptome as enumerated by serial analysis of gene expression (SAGE). Full-length transcripts corresponding to twelve novel LongSAGE tags were recovered and evaluated with respect to gene structure, protein-coding potential, and gene regulatory features. In addition, transcript abundance was compared between RNA isolated from undifferentiated hESCs and differentiated cells. Analysis of full-length transcripts revealed that the novel ORFs did not exceed a size of 129 amino acids and no matches were observed to well characterized protein domains. Interesting protein level predictions included small disulfide-bonded proteins, known members of which are important in a variety of biological processes. Transcripts evaluated for differential expression by real-time RT-qPCR (Reverse Transcription followed by real-time quantitative Polymerase Chain Reaction) were found to be variably expressed (0.2- to 4.5-fold) in Day-2 or Day-4 retinoic acid-induced differentiation cultures compared to undifferentiated hESCs. Relative quantitation using a universal reference RNA (derived from pooled adult tissues) showed large differences in novel transcript levels (0.002- to 35-fold) compared to hESCs. Collectively, these results provide a detailed analysis of a set of novel hESC transcripts and their abundance in early and adult differentiated cell types, both of which may advance our understanding of the transcriptional events governing stem cell behavior. / Medicine, Faculty of / Medical Genetics, Department of / Graduate

Genetics

mRNA

Embryonic stem cells

Notch signalling pathway in murine embryonic stem cell derived haematopoiesis

Huang, Caoxin

January 2013

Haematopoiesis is the process to produce haematopoietic stem cells (HSCs), haematopoietic progenitors (HPCs) and terminally differentiated cell types. In the adult, HSCs resided in bone marrow while in the embryo, haematopoiesis occurred sequentially in several niches including yolk sac, aorta-gonad-mesonephros (AGM) region, placenta and fetal liver. The AGM region is the first place where HSCs arise in vivo and therefore should provide important factors to induce haematopoiesis. The mouse embryonic stem cells (mESC) system is a powerful platform to mimic the development process in vitro and is widely utilized to study the underlying mechanisms because they are pluripotent and can be genetically manipulated. A novel co-culture system has been established by culturing differentiating mESCs with primary E10.5 AGM explants and a panel of clonal stromal cell lines derived from dorsal aorta and surrounding mesenchyme (AM) in AGM region. Results of these co-culture studies suggested that the AM-derived stromal cell lines could be a potent resource of signals to enhance haematopoiesis. Molecular mechanism involved in haematopoiesis is a key research direction for understanding the regulation network of haematopoiesis and for further clinical research. A series of studies have demonstrated involvement of the Notch signalling pathway in haematopoiesis during development but with controversial conclusions because of the difference of models concerning various time windows and manipulating populations. This project aimed to investigate the role of Notch signalling pathway during haematopoiesis in the AGM environment. We analyzed the expression of Notch ligands in AGM-derived stromal cells with or without haematopoietic enhancing ability. No correlation was observed between ligand expression and haematopoietic enhancing ability in stromal cell lines or between Notch activity in EBs and haematopoietic enhancing ability. We demonstrated that inhibition of the Notch signalling pathway using the γ-secretase inhibitor could abrogate Notch activity in both mES-derived cells and the haematopoietic enhancing AM stromal cell line. To better understand the involvement of the Notch signalling pathway in a more specific spatial-temporal environment, we established a co-culture system of haemangioblast like cells (Flk1+) with one of AM region derived stromal cell lines with haematopoietic enhancing ability . We found that the AM stromal cell line could enhance Flk1+ derived haematopoiesis as assessed by haematopoietic colony formation activity and production of CD41+cKit+ progenitor cells. Based on the issue that the inhibitor could potentially affect both the ES cells and stromal cells, we carried out genetic approaches to overexpress or knock down Notch signalling pathway in this Flk1+/AM co-culture system. Interestingly, it was found that when Notch activity was enhanced in Flk1+ cells, the production of haematopoietic progenitors was inhibited and the number of cells expressing the pan-haematopoietic marker CD45 was reduced. By using the inducible dominant negative MAML1 system to knock down Notch activity, it was found that the haematopoiesis in the Flk1+/AM co-culture system was not affected, which could be accounted for the low Notch activity in this system. These results supported the hypothesis that the Notch signalling pathway plays a role in modulating Flk1+ derived haematopoietic differentiation within the AGM microenvironment.

616.02

Molecular Mechanisms of Myogenesis in Stem Cells

Ryan, Tammy

10 August 2011

Embryonic stem cells (ESCs) represent a promising source of cells for cell replacement therapy in the context of muscle diseases; however, before ESC-based cell therapy can be translated to the clinic, we must learn to modulate cell-fate decisions in order to maximize the yield of myocytes from this systems. In order to gain a better understanding of the myogenic cell fate, we sought to define the molecular mechanisms underlying the specification and differentiation of ESCs into cardiac and skeletal muscle. More specifically, the central hypothesis of the thesis is that myogenic signalling cascades modulate cell fate via regulation of transcription factors. Retinoic acid (RA) is known to promote skeletal myogenesis, however the molecular basis for this remains unknown. We showed that RA expands the premyogenic progenitor population in mouse stem cells by directly activating pro-myogenic transcription factors such as Pax3 and Meox1. RA also acts indirectly by activating the pro-myogenic Wnt signalling cascade while simultaneously inhibiting the anti-myogenic influence of BMP4. This ultimately resulted in a significant enhancement of skeletal myogenesis. Furthermore, we showed that this effect was conserved in human embryonic stem cells, with implications for directed differentiation and cell therapy. The regulation of cardiomyogenesis by the Wnt pathway was also investigated. We identified a novel interaction between the cardiomyogenic transcription factor Nkx2.5 and the myosin phosphatase (MP) enzyme complex. Interaction with MP resulted in exclusion of Nkx2.5 from the nucleus and inhibition of its transcriptional activity. Finally, we showed that this interaction was modulated by phosphorylation of the Mypt1 subunit of MP by ROCK, downstream of Wnt3a. Treatment of differentiating mouse ESCs with Wnt3a resulted in exclusion of Nkx2.5 from the nucleus and a subsequent failure to undergo terminal differentiation into cardiomyocytes. This likely represents part of the molecular basis for Wnt-mediated inhibition of terminal differentiation of cardiomyocytes. Taken together, our results provide novel insight into the relationship between myogenic signalling cascades and downstream transcription factors and into how they function together to orchestrate the myogenic cell fate in stem cells.

embryonic stem cells

myogenesis

transcription factor

Role of Grb2 in growth and differentiation of embryonic stem cells

Murray, Helen

January 2011

Embryonic stem (ES) cells are derived from the inner cell mass of the blastocyst stage embryo. They exhibit unlimited proliferation in culture and have the ability to differentiate into all three germ layers of the developing organism, a property defined as pluripotency. Previously it was reported that growth factor-bound protein 2 (Grb2) is required for differentiation of the epiblast, the embryonic tissue that harbours the pluripotent founder cells of the foetus. GRB2 is an adapter protein involved in the activation of the mitogen-activated protein kinase (MAPK) pathway in response to extracellular signals. It has also been implicated in the activation of the phosphoinositol-3-kinase (PI3K) pathway in response to fibroblast growth factor (FGF) signaling. The work presented in this thesis examines the role of Grb2 in ES cells and describes previously unreported contributions of this adaptor protein in regulating ES cell growth and differentiation. It has been previously been shown by others that Grb2 deficient (Grb2-/-) cells grow relatively normally in ES growth medium containing serum. However, in serum free conditions (N2B27 medium) in this project, proliferation of Grb2-/- cells is reduced compared with wild type and “restored” Grb2-/- cells stably expressing a Grb2 cDNA mini gene. Under serum free conditions, Grb2-/- cells grow in tight, refractive colonies. Nanog expression was uniformly upregulated, in contrast to the heterogeneous pattern reported in serum-based medium. Colony expansion on the substratum appears to be compromised, although there is no apparent defect in the initial attachment of Grb2-/- cells. Cell cycle analysis indicates that the slower growth of Grb2-/- cells in serum free medium could be due to lengthening of the G1 phase of the ES cell cycle. In an attempt to identify the signalling deficiency responsible for the growth defect of Grb2-/- cells, MAPK activation was restored by two methods, PMA a ligand that bypasses the requirement for Grb2, and Raf-ER, a conditionally regulated component of the MAPK pathway that acts downstream of Grb2 in the MAPK pathway. Although both approaches increased MAPK signalling they were unable to rescue the growth defect. This suggests that MAPK is not required or alone is not sufficient. Inhibition of Glycogen synthase kinase 3 β (GSK3 β ) is known to augment growth of ES cells under MAPK inhibition. Surprisingly, GSK3 β inhibition did not enhance Grb2-/- cell growth. Under GSK3 β inhibition, Grb2-/- ES cells fail to thrive. It is hypothesised that under these conditions cells undergo hyper-self-renewal at the cost of growth. Grb2-/- ES cells are reported to exhibit limited differentiation potential. To examine the potency of Grb2-/- cells, these cells were subjected to embryoid body (EB) and monolayer differentiation. Analysis of EBs showed a loss of Gata4, Gata6 and endoderm marker gene expression. However, markers of ectoderm (Sox1, Pax6, MAP2), the late epiblast/nascent mesoderm (Brachyury) and markers associated with gastrulation (Twist and Snail) were expressed. Outgrowths of morphologically and immunohistochemically identifiable neuronal cells confirmed differentiation of ectodermal cell types, indicating Grb2 is not required for neuronal differentiation. However, beating cardiomyocytes could not be identified in Grb2-/- EBs, though readily found in restored Grb2-/- cells expressing the Grb2 cDNA. This suggests that there is an essential role for Grb2 in the mesoderm/cardiomyocyte differentiation pathway. This may be due to a defect in GATA factor expression since these factors are essential for cardiogenesis. In serum-free monolayer differentiation, Grb2-/- cells formed neuronal cells. Additional inhibition of the MAPK pathway using a small chemical inhibitor failed to prevent this differentiation. However, biochemical analysis of the cells indicates that this occurs when ERK activation is very low, indicating differentiation was not MAPK-independent. Grb2 mediates FGF-MAPK induced exit from the naïve ground state. These data suggest a Grb2-independent pathway can also facilitate this transition. Grb2 is dispensable for differentiation in to some lineages. However as differentiation of Grb2-/- ES cells is restricted, this indicates Grb2 is required for true pluripotency.

611

Microfluidic devices for the investigation of pluripotency in embryonic stem cells

Hodgson, Andrew Christopher

January 2017

This thesis presents the development of microfluidic devices designed to facilitate research into mouse embryonic stem cells (ESCs). ESCs are a well-studied cell, largely due to their pluripotent nature, meaning they are able to differentiate into all cell types of the body and may self-renew indefinitely in appropriate culture conditions. ESCs, along with many other lines of biological enquiry, are increasingly studied with the use of micro uidic technology which enables fine tuning of physical and chemical environments unachievable on the macro scale. Two varieties of microfluidic technology are presented in this thesis, one for high- resolution mechanical phenotyping of ESCs and the second as a novel in-chip culturing platform to study cellular transitions. Chapter 1 presents a broad introduction to ESCs and biological enquiry with microfluidics, aimed to underpin the following Chapters. Chapters 2 and 3 present self-contained projects, thus each include a motivation and introduction section more specific than that presented in Chapter 1. These Chapters also contain their own methods, results and conclusion sections. Finally, Chapter 4 presents a summary of the work performed along with an outlook of upcoming investigations. In Chapter 2, I present a microfluidic device developed and utilised in collaboration with Christophe Verstreken (Department of Physics, University of Cambridge), which has been used to apply a mechanical stress to live cells enabling measurement of their nuclear deformability. The device facilitates detection of both nucleus and cytoplasm which can then be analysed with a custom-written MATLAB code. Quantitative measurements of nuclear sizes and strains of ESCs indicated a negative Poisson ratio for nuclei of cells cultured in specific medium conditions. Furthermore, we demonstrate that the device can be used to physically phenotype at high-throughput by detecting changes in the nuclear response after treatment with actin depolymerising and chromatin decondensing agents. Finally, we show the device can be used for biologically relevant high-resolution confocal imaging of cells under compression. The work from this chapter is presented in Hodgson et al. [1]. In Chapter 3, I present a novel microfluidic platform developed in collaboration with Prof. Austin Smith and Dr Carla Mulas (Centre for Stem Cell Research, Cambridge). The developed platform enables individual ESCs to be cultured under continued observation as they exit their pluripotent stem cell state. Each cell within the device may be extracted from the chip at any time for further investigation without disturbing other cells. Assessing the transition from the stem cell state in individual cells is paramount if we are to understand the mechanisms of pluripotency.

532

The ins and outs of stem cells: regulation of cell fate in embryonic stem cells and hematopoiesis

Mumau, Melanie

January 2018

The decisions stem cells make impact both the development of adult vertebrates and systems within the body that require cellular replenishment to sustain life. Regardless whether a stem cell remains quiescent, divides, differentiates, or undergoes apoptosis—these processes are precisely controlled by internal gene regulatory networks that are instructed by external stimuli. The exact mechanisms governing stem cell fate are not completely understood. These studies explore new ways in which cell fate is mediated. Through a study of mitochondrial content in human embryonic stem cells (hESCs) and their differentiated progeny, we discovered differences in mitochondrial morphologies. Mitochondria began as elongated and networked structures in self-renewing conditions and changed their shape after differentiation. The addition of external growth factors that direct hESCs toward the definitive endoderm (DE) lineage promoted mitochondrial fragmentation, which was mediated by the mitochondrial fission machinery. Globular, punctate mitochondria were observed prior to the induction of the DE-specific transcriptional program. Differentiation of hESCs to other lineages did not result in any mitochondrial shape changes. Thus, mitochondrial fission in differentiating hESCs, an internal cellular process, is induced by DE-inducing external stimuli, an effect that was lineage specific. In a second study, we investigated the role of the splenic environment in the development of the blood system—during hematopoiesis. The spleen made a distinct contribution to hematopoiesis, a process predominantly attributed to the bone marrow. We discovered a previously unidentified population of cells, uniquely represented in the mouse spleen that could develop into erythrocytes, monocytes, granulocytes, and platelets. These multipotent progenitors of the spleen (MPPS) expressed higher levels of the transcription factor, NR4A1 compared to their bone marrow counterparts and relied on NR4A1 expression to direct their cell fate. The activation of NR4A1 in MPPS biased their production of monocytes and granulocytes in vitro whereas NR4A1-deficient MPPS over-produced erythroid lineage cells in vivo. Together, these data suggest the splenic niche supports distinct myeloid differentiation programs of multi-lineage progenitors cells. Both studies identify new mechanisms by which external stimuli regulate internal mechanisms of cell fate. These insights provide a better understanding of stem and progenitor cell differentiation that have the potential to impact cellular replacement therapies.

Immunology

Hematopoiesis

Embryonic stem cells

Cytology