Nodal signalling during targeted differentiation of human embryonic stem cells towards definitive endoderm

Miller, Duncan

January 2013

Targeted differentiation of human embryonic stem cells (hESCs) towards definitive endoderm (DE) is the first step in generating hepatic or pancreatic cell types with potential for clinical application. Characterisation and efficiency of DE differentiation is improving, however the specific effects of the different exogenous growth factors used, and the changing presence and activity of endogenous factors, are still not well understood. One such endogenous factor, the TGFβ ligand Nodal, is known to drive patterning and differentiation of the primitive streak and DE in the developing mouse embryo. The effect of Nodal signalling during hESC DE differentiation is unknown, and the common use of a related exogenous ligand Activin A may also serve to upregulate rather than simply mimic it. In order to explore this, Activin A differentiation of hESCs in defined culture conditions was analysed. The expression of characteristic mesendoderm and DE markers increased during Activin A treatment, which was significantly enhanced by the inclusion of exogenous Wnt3a. A maintained presence of the pluripotency factor Nanog was observed in most cells expressing markers of DE. The levels of Nodal and its co-receptor Cripto, which were raised during the early stage of Activin A treatment, were also marginally enhanced by Wnt3a, and evidence of Nodal endocytosis further suggested an active signalling presence. RNA interference (RNAi) of Nodal negatively affected both pluripotency maintenance during normal pluripotent culture, and the capacity to differentiate towards DE. Use of a Cripto blocking antibody also inhibited differentiation towards DE. The results strongly suggested the presence of Nodal signalling, as well as possible roles for Nanog, Wnt-related signalling, and Nodal signalling during Activin A-mediated DE differentiation. The results contribute to current understanding of how DE differentiation in hESCs is regulated. They also identify clear targets for further investigation, which would lead to improved characterisation and differentiation of DE from hESCs.

Developing DamID-seq to investigate transcription factor binding in mammalian cells

Tosti, Luca

January 2017

In order to understand gene regulatory networks (GRNs) in mammalian cells, it is pivotal to assess the interaction between proteins and DNA. In particular, the specific DNA binding activity of transcription factors (TFs) determines the expression of target genes and in general the overall connectivity of the GRN. However, the genomic location of TF binding cannot be predicted just from the DNA sequence, and functional assays are required to detect this interaction. The investigation of the binding of TF to DNA is usually accomplished by chromatin immunoprecipitation followed by next-generation sequencing (ChIP-seq). While in the last 10 years this method enabled a better understanding of how transcription is regulated in living cells, it does have some drawbacks. In particular, the need for very highly specific antibodies and the large amount of starting material limit the ability of ChIP-seq to address biological questions when dealing with samples of small quantity. A technique called DNA Adenine Methyltransferase Identification (DamID) was developed in Drosophila as an alternative method for the detection of protein- DNA interactions and it is based on the fusion of a protein of interest (POI) with the DNA adenine methyltransferase (Dam). This fusion causes DNA methylation of adenines surrounding the sites where POI binds and the subsequent identification of the methylation sites allows mapping of the binding event without antibodies and using less cells as starting material. While this technology was successful in detecting the interaction between nuclear lamina and DNA in mammalian cells, to date little reports are present in the literature about TF DamID. This is mainly due to the different nature of TF binding compared to Lamin (punctuated instead of broad) and to the elevated intrinsic activity of Dam that makes the detection of real signal above the noise challenging. I here demonstrate a step-by-step optimization of the DamID technology coupled to next-generation sequencing (DamID-seq) that I used to map the binding of the mouse embryonic stem cell master regulator Oct4 in as few as 1,000 cells. This new technology paves the way for exciting new experiments where the number of cells is scarce such as in vitro cell state change or in vivo processes.

Signalling and transcriptional regulation of early developmental lineage decisions

Morgani, Sophie Maria

January 2014

Embryonic stem (ES) cells are cell lines isolated from the embryo at a time just prior to implantation into the uterus. In the right cocktail of medium and cytokines, these cell lines can be maintained indefinitely in vitro in a self-renewing state. Initially it was assumed that these cells represented a homogeneous population however, more recently it has been shown that there are a great number of genes that are expressed heterogeneously. ES cell cultures are therefore a mix of different subpopulations, some of which have distinct functional properties including a bias or ‘lineage priming’ towards a particular cell fate. These populations are also dynamic in nature, converting from one state to another with fairly rapid kinetics. The main focus of this thesis was to gain a more in depth understanding of the mechanisms regulating heterogeneity and lineage priming in murine ES cells by asking which signalling pathways play a role in this phenomenon and how the switch between states is regulated at a transcriptional level. These questions were asked using an ES cell line containing a sensitive reporter for the endoderm marker Hex. This reporter, developed by a previous lab member, allowed the identification and separation of a population of ES cells primed towards a primitive endoderm fate. Primarily, I assessed the effect of a defined culture system (2i) on the Hex-expressing population. This culture system contains inhibitors that block FGF signalling and the Wnt pathway component GSK3. Culturing ES cells in 2i has been suggested to generate a more homogeneous culture. Here, I have shown that culturing ES cells or pre-implantation embryos in 2i did not eliminate heterogeneity but maintained them in an early state prior to lineage segregation. When ES cells were cultured in standard serum-containing medium, Hex was expressed in a mutually exclusive manner with the embryonic marker NANOG, while in 2i a subpopulation of cells coexpressed both Hex and NANOG. This population was functionally primed towards extraembryonic endoderm and trophoblast. Furthermore, these ES cells could efficiently contribute to 2-cell embryos in chimaera assays. LIF signalling promoted this population through the JAK/STAT pathway. I then asked how transcription was regulated during the switch between unprimed ES cells to those primed towards a primitive endoderm fate, as well as how regulation changes during further differentiation. To ask this, Hex positive (primed) and negative (unprimed) ES cell populations were sorted as well as a Hex positive differentiated sample. These samples were analysed by GRO-seq to determine the location, density and orientation of RNA-polymerase throughout the genome. Changes in gene expression between primed and unprimed states were regulated primarily through elongation whereas genes upregulated during differentiation were regulated at the point of de novo initiation.

616.02

Making cortex in a dish: an intrinsic mechanism of corticogenesis from embryonic stem cells.

Gaspard, Nicolas

03 September 2009

The cerebral cortex develops through the coordinated generation of dozens of neuronal subtypes, but the mechanisms involved remain unclear. Here we show that mouse embryonic stem cells, cultured without any morphogen but in the presence of a sonic hedgehog inhibitor, recapitulate in vitro the major milestones of cortical development, leading to the sequential generation of a diverse repertoire of neurons that display most salient features of genuine cortical pyramidal neurons. When grafted into the cerebral cortex, these neurons develop patterns of axonal projections corresponding to a wide range of cortical layers, but also to highly specific cortical areas, in particular visual and limbic areas, thereby demonstrating that the identity of a cortical area can be specified without any influence from the brain. The discovery of intrinsic corticogenesis sheds new light on the mechanisms of neuronal specification, and opens new avenues for the modelling and treatment of brain diseases. In a further attempt to prove the validity of this model, we have initiated the study of the mechanism of action of FoxG1, a forkhead box transcription factor involved in the control of cell fate decision in the developing cortex.

Embryonic stem cells

Developmental biology

Cerebral cortex

Cardiac Tissue Engineering

Dawson, Jennifer Elizabeth

24 June 2011

The limited treatment options available for heart disease patients has lead to increased interest in the development of embryonic stem cell (ESC) therapies to replace heart muscle. The challenges of developing usable ESC therapeutic strategies are associated with the limited ability to obtain a pure, defined population of differentiated cardiomyocytes, and the design of in vivo cell delivery platforms to minimize cardiomyocyte loss. These challenges were addressed in Chapter 2 by designing a cardiomyocyte selectable progenitor cell line that permitted evaluation of a collagen-based scaffold for its ability to sustain stem cell-derived cardiomyocyte function (“A P19 Cardiac Cell Line as a Model for Evaluating Cardiac Tissue Engineering Biomaterials”). P19 cells enriched for cardiomyocytes were viable on a transglutaminase cross-linked collagen scaffold, and maintained their cardiomyocyte contractile phenotype in vitro while growing on the scaffold. The potential for a novel cell-surface marker to purify cardiomyocytes within ESC cultures was evaluated in Chapter 3, “Dihydropyridine Receptor (DHP-R) Surface Marker Enrichment of ES-derived Cardiomyocytes”. DHP-R is demonstrated to be upregulated at the protein and RNA transcript level during cardiomyogenesis. DHP-R positive mouse ES cells were fluorescent activated cell sorted, and the DHP-R positive cultured cells were enriched for cardiomyocytes compared to the DHP-R negative population. Finally, in Chapter 4, mouse ESCs were characterized while growing on a clinically approved collagen I/III-based scaffold modified with the RGD integrin-binding motif, (“Collagen (+RGD and –RGD) scaffolds support cardiomyogenesis after aggregation of mouse embryonic stem cells”). The collagen I/III RGD+ and RGD- scaffolds sustained ESC-derived cardiomyocyte growth and function. Notably, no significant differences in cell survival, cardiac phenotype, and cardiomyocyte function were detected with the addition of the RGD domain to the collagen scaffold. Thus, in summary, these three studies have resulted in the identification of a potential cell surface marker for ESC-derived cardiomyocyte purification, and prove that collagen-based scaffolds can sustain ES-cardiomyocyte growth and function. This has set the framework for further studies that will move the field closer to obtaining a safe and effective delivery strategy for transplanting ESCs onto human hearts.

Embryonic Stem Cells

Cardiomyocytes

Collagen Scaffolds

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

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 of129 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 orDay-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.

embryonic stem cells

transcriptomes

novel proteins

Cardiac Tissue Engineering

Dawson, Jennifer Elizabeth

24 June 2011

The limited treatment options available for heart disease patients has lead to increased interest in the development of embryonic stem cell (ESC) therapies to replace heart muscle. The challenges of developing usable ESC therapeutic strategies are associated with the limited ability to obtain a pure, defined population of differentiated cardiomyocytes, and the design of in vivo cell delivery platforms to minimize cardiomyocyte loss. These challenges were addressed in Chapter 2 by designing a cardiomyocyte selectable progenitor cell line that permitted evaluation of a collagen-based scaffold for its ability to sustain stem cell-derived cardiomyocyte function (“A P19 Cardiac Cell Line as a Model for Evaluating Cardiac Tissue Engineering Biomaterials”). P19 cells enriched for cardiomyocytes were viable on a transglutaminase cross-linked collagen scaffold, and maintained their cardiomyocyte contractile phenotype in vitro while growing on the scaffold. The potential for a novel cell-surface marker to purify cardiomyocytes within ESC cultures was evaluated in Chapter 3, “Dihydropyridine Receptor (DHP-R) Surface Marker Enrichment of ES-derived Cardiomyocytes”. DHP-R is demonstrated to be upregulated at the protein and RNA transcript level during cardiomyogenesis. DHP-R positive mouse ES cells were fluorescent activated cell sorted, and the DHP-R positive cultured cells were enriched for cardiomyocytes compared to the DHP-R negative population. Finally, in Chapter 4, mouse ESCs were characterized while growing on a clinically approved collagen I/III-based scaffold modified with the RGD integrin-binding motif, (“Collagen (+RGD and –RGD) scaffolds support cardiomyogenesis after aggregation of mouse embryonic stem cells”). The collagen I/III RGD+ and RGD- scaffolds sustained ESC-derived cardiomyocyte growth and function. Notably, no significant differences in cell survival, cardiac phenotype, and cardiomyocyte function were detected with the addition of the RGD domain to the collagen scaffold. Thus, in summary, these three studies have resulted in the identification of a potential cell surface marker for ESC-derived cardiomyocyte purification, and prove that collagen-based scaffolds can sustain ES-cardiomyocyte growth and function. This has set the framework for further studies that will move the field closer to obtaining a safe and effective delivery strategy for transplanting ESCs onto human hearts.

Embryonic Stem Cells

Cardiomyocytes

Collagen Scaffolds

Embryonic stem cell-derived populations retain their tumorigenic potential

Apicella, Marisa,

January 2009

Thesis (M.S.)--Rutgers University, 2009. / "Graduate Program in Cell and Developmental Biology." Includes bibliographical references (p. 37-40).

A comparative study on the effects of feeder cells on culture of human embryonic stem cells

Hou, Yuen-chi, Denise.

January 2009

Thesis (M. Phil.)--University of Hong Kong, 2010. / Includes bibliographical references (leaves 136-153). Also available in print.