Project description:Transcription factor-mediated reprogramming is a powerful method to study cell fate changes. In this work, we demonstrate that the transcription factor Gata6 can initiate reprograming of multiple cell types to induced extraembryonic endoderm (iXEN) cells. Intriguingly, Gata6 is sufficient to drive iXEN cells from mouse pluripotent cells and differentiated neural cells. Furthermore, GATA6 induction in human ES (hES) cells also downregulates pluripotency gene expression and upregulates extraembryonic endoderm genes, revealing a conserved function in mediating this cell fate switch. Profiling transcriptional changes following Gata6 induction in mES cells reveals step-wise pluripotency factor disengagement, with initial repression of Nanog and Esrrb, then Sox2 and finally Oct4, alongside step-wise activation of extraembryonic endoderm genes. Chromatin immunoprecipitation and subsequent high-throughput sequencing analysis shows Gata6 enrichment near both pluripotency and endoderm genes, suggesting that Gata6 functions as both a direct repressor and activator. Together this demonstrates that Gata6 is a versatile and potent reprogramming factor that can act alone to drive a cell fate switch from diverse cell types. Time-course microarray analysis of Gata6-mediated reprogramming from 12 to 144 hours of doxycycline treatment in mouse embryonic stem (mES) cells compared to uninduced mES cells, embryo-derived extraembryonic endoderm (XEN) cells and Sox7 overexpressing mES cells after 144 hours of doxycycline treatment.

Project description:Transcription factor-mediated reprogramming is a powerful method to study cell fate changes. In this work, we demonstrate that the transcription factor Gata6 can initiate reprograming of multiple cell types to induced extraembryonic endoderm (iXEN) cells. Intriguingly, Gata6 is sufficient to drive iXEN cells from mouse pluripotent cells and differentiated neural cells. Furthermore, GATA6 induction in human ES (hES) cells also downregulates pluripotency gene expression and upregulates extraembryonic endoderm genes, revealing a conserved function in mediating this cell fate switch. Profiling transcriptional changes following Gata6 induction in mES cells reveals step-wise pluripotency factor disengagement, with initial repression of Nanog and Esrrb, then Sox2 and finally Oct4, alongside step-wise activation of extraembryonic endoderm genes. Chromatin immunoprecipitation and subsequent high-throughput sequencing analysis shows Gata6 enrichment near both pluripotency and endoderm genes, suggesting that Gata6 functions as both a direct repressor and activator. Together this demonstrates that Gata6 is a versatile and potent reprogramming factor that can act alone to drive a cell fate switch from diverse cell types.

Project description:Transcription factor-mediated reprogramming is a powerful method to study cell fate changes. In this work, we demonstrate that the transcription factor Gata6 can initiate reprograming of multiple cell types to induced extraembryonic endoderm (iXEN) cells. Intriguingly, Gata6 is sufficient to drive iXEN cells from mouse pluripotent cells and differentiated neural cells. Furthermore, GATA6 induction in human ES (hES) cells also downregulates pluripotency gene expression and upregulates extraembryonic endoderm genes, revealing a conserved function in mediating this cell fate switch. Profiling transcriptional changes following Gata6 induction in mES cells reveals step-wise pluripotency factor disengagement, with initial repression of Nanog and Esrrb, then Sox2 and finally Oct4, alongside step-wise activation of extraembryonic endoderm genes. Chromatin immunoprecipitation and subsequent high-throughput sequencing analysis shows Gata6 enrichment near both pluripotency and endoderm genes, suggesting that Gata6 functions as both a direct repressor and activator. Together this demonstrates that Gata6 is a versatile and potent reprogramming factor that can act alone to drive a cell fate switch from diverse cell types. (1) Microarray analysis of Gata6 overexpressing cells from 12 to 144 hours of doxycycline treatment in mouse embryonic stem (mES) cells compared to uninduced mES cells, embryo-derived XEN cells and Sox7 overexpressing mES cells after 144 hours of doxycycline treatment. (2) ChIP-seq analysis of Gata6 binding 36 hours following doxycycline treatment. (3) ChIP-seq analysis of Gata6 binding in embryo-derived XEN cells. (4) RNA-seq analysis of GATA6 overexpressing cells following 144 hours of induction in hES cells.

Project description:In early mammalian development, cleavage stage blastomeres and cells of the inner cell mass (ICM) of the blastocyst co-express embryonic and extra-embryonic transcriptional determinants. Using a double protein-based reporter we identify embryonic stem cells (ESC) that co-express the extra-embryonic factor GATA6 alongside the embryonic factor SOX2 in specific conditions. Based on single cell transcriptomics we find these population resemble unsegregated ICM, exhibiting enhanced differentiation potential for endoderm while maintaining epiblast competence and suggesting they represent an ideal model to determine how GATA6 and SOX2 influence each other's DNA binding. To relate this binding to future fate, we describe a complete enhancer set in both ESCs and naïve extraembryonic endoderm stem cells and ask whether SOX2 and GATA6 recognize these elements in ICM-like ESC sub-population. Both factors support cooperative recognition in these lineages, with GATA6 bound alongside SOX2 on a fraction of pluripotency enhancers and SOX2 alongside GATA6 more extensively on endoderm enhancers. Our findings suggest that cooperative binding between these antagonistic factors both supports self-renewal and prepares progenitor cells for later differentiation

Project description:Cell-fate decisions and lineage commitment in early embryonic development are governed by comprehensive gene-regulatory programs. However, the molecular details leading to initial segregation of different lineages remain unclear. In the second cell-fate decision, epiblast (EPI) and primitive endoderm (PrE) lineages are formed from the pluripotent inner cell mass (ICM) cells at blastocyst stage. Here, we demonstrated that the pluripotency transcription factor Zfp281 is a barrier in embryonic stem cells (ESCs) to PrE lineage differentiation. Zfp281 is expressed in extraembryonic endoderm cells (XENs), the ex vivo derivatives of PrE. But knockdown of Zfp281 doesn’t affect either maintenance or expression of the PrE master regulators in XENs. Using an in vitro differentiation protocol, we revealed that knockout of Zfp281 significantly increased the efficiency of ESC to XEN derivation. Using a Zfp281 rescue line for the knockout cells, we further confirmed that effects of elevated efficiency of XEN derivation is specifically due to loss of Zfp281. Mechanistically, we revealed that Zfp281 interacts with components in the polycomb repressive complex 2 (PRC2), and recruits PRC2 to promoters of PrE master regulators GATA4 and GATA6 for transcriptional and epigenetic repression. Taken together, our results demonstrated a novel role of Zfp281 in second cell-fate decision in embryonic stem cell differentiation.

Project description:Cell-fate decisions and lineage commitment in early embryonic development are governed by comprehensive gene-regulatory programs. However, the molecular details leading to initial segregation of different lineages remain unclear. In the second cell-fate decision, epiblast (EPI) and primitive endoderm (PrE) lineages are formed from the pluripotent inner cell mass (ICM) cells at blastocyst stage. Here, we demonstrated that the pluripotency transcription factor Zfp281 is a barrier in embryonic stem cells (ESCs) to PrE lineage differentiation. Zfp281 is expressed in extraembryonic endoderm cells (XENs), the ex vivo derivatives of PrE. But knockdown of Zfp281 doesn’t affect either maintenance or expression of the PrE master regulators in XENs. Using an in vitro differentiation protocol, we revealed that knockout of Zfp281 significantly increased the efficiency of ESC to XEN derivation. Using a Zfp281 rescue line for the knockout cells, we further confirmed that effects of elevated efficiency of XEN derivation is specifically due to loss of Zfp281. Mechanistically, we revealed that Zfp281 interacts with components in the polycomb repressive complex 2 (PRC2), and recruits PRC2 to promoters of PrE master regulators GATA4 and GATA6 for transcriptional and epigenetic repression. Taken together, our results demonstrated a novel role of Zfp281 in second cell-fate decision in embryonic stem cell differentiation.

Project description:Human embryonic stem cells (hESC) display substantial heterogeneity in gene expression, implying the existence of discrete substates within the stem cell compartment. To determine whether these substates impact fate decisions of hESC we used a GFP reporter line to investigate the properties of fractions of putative undifferentiated cells defined by their differential expression of the endoderm transcription factor, GATA6, together with the hESC surface marker, SSEA3. By single cell cloning, we confirmed that substates characterized by expression of GATA6 and SSEA3 include pluripotent stem cells capable of long term self-renewal. When clonal stem cell colonies were formed from GATA6-positive and GATA6-negative cells, more of those derived from GATA6-positive cells contained spontaneously differentiated endoderm cells than similar colonies derived from the GATA6-negative cells. We characterized these discrete cellular states using single cell transcriptomic analysis, identifying a potential role for SOX17 in the establishment of the endoderm biased stem cell state.

Project description:Investigation of the role played by GATA6 in establishing the definitive endoderm chromatin accessbility profile. We used pluripotent stem cells as a model of early development. We derived GATA6-/- pluripotent cells with an inducible GATA6 or FOXA2 construct that permits exongenous GATA6 or FOXA2 cDNA expression upon supplementation of doxycycline. We differentiated GATA6+/+ and GATA6-/- (with and without doxycyline) cells to definitive endoderm and analyzed transcription factor binding profiles using CHIP-seq.

Project description:While the reprogramming factors OCT4, SOX2, KLF4, and MYC (OSKM) can reactivate the pluripotency network in terminally differentiated cells, they also regulate expression of non-pluripotency genes in other contexts, such as the mouse primitive endoderm. The primitive endoderm is an extraembryonic lineage established alongside the pluripotent epiblast in the blastocyst, and is the progenitor pool for extraembryonic endoderm stem (XEN) cells. Several studies have shown that endodermal genes are upregulated in fibroblasts undergoing reprogramming, although whether endodermal genes promote or inhibit acquisition of pluripotency is unclear. We show that, in fibroblasts undergoing conventional reprogramming, OSKM-induced expression of endodermal genes leads to formation of induced XEN (iXEN) cells, which possess key properties of blastocyst-derived XEN cells, including morphology, transcription profile, self-renewal, and multipotency. Our data show that iXEN cells arise in parallel to iPS cells, indicating that OSKM are sufficient to drive cells to two distinct fates during reprogramming. Sequence-based mRNA transcriptional profiling of three different cell lines (MEF, XEN, iXEN) with multiple biological replicates, under two different growth medium conditions (ESC medium, XEN medium) for XEN and iXEN cells.

Project description:SOX17 directs the differentiation of the extraembryonic endoderm and acts as a human germline specifier. The replacement of an acidic residue at position 57 with a basic residue found in SOX2 turns SOX17 into a pluripotency factor. Here we systematically interrogated how mutations at this critical position affect the cellular reprogramming activity of SOX17. We found that most mutations turn SOX17 into a pluripotency factor regardless of their biophysical properties. The mutation to an aspartate allows the SOX17E57D protein to maintain a self-renewing endodermal state. Only the glutamate found in the wild-type protein can effectively block a SOX17/OCT4 dimer from binding composite DNA elements found in pluripotency enhancers. Insights into how modifications of an ultra-conserved residue affect functions of developmental transcription factor provide avenues to advance cell fate engineering.