Project description:During gastrulation, epiblast cells are pluripotent and their fate is thought to be constrained principally by their position. Cell fate is progressively restricted by localised signalling cues from areas including the primitive streak (PS). However, it is unknown whether this restriction accompanies, at the single cell level, a reduction in potency. Investigation of these early transition events in vitro is possible via the use of Epiblast Stem Cells (EpiSCs), self-renewing pluripotent cell lines equivalent to the postimplantation epiblast. Strikingly, EpiSCs express various early lineage-specific markers in self-renewing conditions. However, it is unknown whether cells that express these markers are pluripotent, spontaneously differentiated, or biased towards specific lineages. Here we show that EpiSC are inherently heterogeneous and contain two major and mutually exclusive subpopulations with PS and neural characteristics respectively. Using differentiation assays and embryo grafting we demonstrate that PS-like EpiSCs are biased towards mesoderm and endoderm differentiation but they still retain their pluripotent character. The acquisition of a PS character by undifferentiated EpiSC is mediated by paracrine Wnt signalling. Elevation of Wnt activity promotes further restriction into PS-associated cell fates which occurs via the generation of distinct clonal mesendodermal and neuromesodermal precursors. Collectively, our data suggest that primed pluripotency encompasses a range of reversible lineage-biased states reflecting the birth of pioneer lineage precursors from a pool of uncommitted EpiSCs similar to the earliest cell fate restriction events taking place in the gastrula-stage epiblast.

Project description:Embryonic stem (ES) cells are isolated from the inner cell mass (ICM) of developing blastocysts, whereas epiblast stem cells (EpiSCs) are derived from the post-implantation epiblast and are characterized by a restricted developmental potential. Although certain mouse strains, such as the non-obese diabetic (NOD) mice, are considered “non-permissive” for ES cell derivation, they retain the capacity to generate EpiSCs. Using the NOD strain as a model, we characterized the stability of pluripotent states in cells generated by ICM explantation or direct in vitro reprogramming. We find that ES-like NOD stem cells can be captured in both approaches by providing exogenous constitutive expression of Klf4 or c-Myc transcription factors or small molecules that can replace these factors during in vitro reprogramming. The fully pluripotent NOD ES and iPS cells appear “metastable”, as the cells acquire an alternative EpiSC-like identity after removal of the exogenous factors, while reintroduction of these factors converts the cells back to ICM-like pluripotency. Our findings suggest that stem cells from different genetic backgrounds can assume distinct states of pluripotency in vitro, the stability of which is regulated by endogenous genetic determinants and can be modified by the continuous presence of defined exogenous factors. Gene expression profiling was performed in mouse ES, EpiSC and EpiSC-like cell lines.

Project description:Epiblast stem cells (EpiSCs) were placed in the epiblastic cell maintenance condition (EpiSC) or in a neural plate developmental condition (Iwafuchi-Doi et al. Dev Biol 352, 354-366, 2011) for one (NPC1) or two (NPC2) days, and expression profiles of total mRNAs were compared. Duplicate EpiSC cultures (A and B) originating from the same seed culture and made in the above conditions were processed for total RNA extraction using TRI Reagent (Sigma-Aldrich), and analyzed

Project description:This study describes the transcriptome profiling of: 1) mouse ES cells and EpiSCs in LIF/serum-free (KSR) medium; 2) E14Tg2a (E14) ES cells in LIF/Serum with or without MM401 treatment; 3) rES reverted form EpiSC by MM401/LIF KSR treatment at P6, P30. RNA-Seq profiling on mouse pluripotent cells. Biological duplicates of each sample are labled as rep1/2.

Project description:A unique embryonic stem cells showing naïve state was established from primplantation mouse blastocyst but maintaind their self renew under FGF2 stimulus condition We used microarray to compare gene expression patterns of our pluripotent stem cell line (named FGF-ESC) with ESCs or EpiSCs in addition to inner cell mass from E3.5 preimplantation blastocyst as in vivo control. Total RNA was extracted from FGF-ESC, ESC, EpiSC and inner cell mass from E3.5 preimplantation blastocyst, and served for microarray analysis using Affymetrix Mouse Gene 2.1 Array

Project description:EpiSCs (epiblast stem cells) are murine pluripotent stem cells derived from the epiblast of a post-implantation embryo. These cells are primed to differentiate towards embryonic germ layers and are a useful model to study these early developmental events. PGR (progesterone receptor) is a nuclear receptor described mainly in the context of fertility and breast cancer. We noticed that it is also a TF that is expressed in primed EpiSCs, but not in naive mESCs and is further upregulated during mesoderm specification. We hypothesized that it is involved in differentiation to primitive streak and mesoderm progenitors. To test this hypothesis we generated EpiSCs with a genetic knockout of PGR using CRISPR-Cas9-mediated knock-in of an antibiotic resistance cassette. Differentiation of the wild-type and knockout cells and comparison of the different cell types allowed us to conclude that PGR is important for acquiring extraembryonic mesoderm fate and modulates cardiac differentiation, specifically it ensures that correct pools of FHF (first heart field) and SHF (second heart field) are being produced. Our study sheds light on previously unappreciated role of PGR in early embryonic development.

Project description:The comparison of mouse ESCs and ESD-EpiSCs was done using three biological replicates for each cell type. ESC samples (ESR1 p10, p20, ESR1/E p15) and ESD-EpiSC samples (EpiSC-7 p20, EpiSC-5 p22, and EpiSC-7 p25) were used for microarray analysis. Total RNA was extracted using Trizol and labeled and hybridized to Agilent Whole Mouse Genome Oligo 4X44K Microarrays (one-color platform) according to the manufacturer’s protocols.

Project description:Embryonic stem cells (ESCs), which are derived from the primitive ectoderm of pre-implantation blastocysts, are pluripotent cells and can thus contribute to the formation of all somatic cell lineages in chimeric animals. Similarly, epiblast stem cells (EpiSCs), which are derived from epiblast tissue of post-implantation embryos, are also pluripotent and can give rise to derivatives of all three germ layers in teratoma assays. Introduction of the four transcription factors Oct4/Sox2/Klf4/c-Myc into somatic cells has been shown to generate induced pluripotent stem cells (iPSCs). iPSCs exhibit ESC-like properties and are virtually identical to ESCs with respect to a number of charactertistics. However, generation of EpiSC-like cells by direct reprogramming of somatic cells using these transcription factors has not been shown to date. Here we show that Yamanaka’s four transcription factors can be used to directly generate EpiSC-like iPS cells (ePSCs) under EpiSC culture conditions. These ePSCs are identical to EpiSCs with respect to morphology, gene expression pattern, epigenetic status, and chimera formation. This is the first study to demonstrate that the culture environment in transcription factor-mediated reprogramming determines the cell fate of the reprogrammed cell. We could therefore envision that we eventually are able to shape the identity of a directly reprogrammed cell at will simply by modulating the culture conditions. RNA samples to be analyzed on microarrays were prepared using Qiagen RNeasy columns with on-column DNA digestion. 500 ng of total RNA per sample was used as input into a linear amplification protocol (Ambion), which involved synthesis of T7-linked double-stranded cDNA and 12 hrs of in-vitro transcription incorporating biotin-labelled nucleotides. Purified and labelled cRNA was then hybridized for 18 hrs onto MouseRef-8 v2 expression BeadChips (Illumina) according to the manufacturer's instructions. After washing, as recommended, chips were stained with streptavidin-Cy3 (GE Healthcare) and scanned using the iScan reader (Illumina) and accompanying software. Samples were hybridized as biological replicates. 24 samples were analyzed: MEF: Female mouse embryonic fibroblast, 2 biological rep ESC OG2: OG2 female embryonic stem cell, 2 biological rep EpiSC OG2: OG2 female EpiSC grown as single cells with conditioned medium, 2 biological rep EpiSC GOF18: GOF18 EpiSC grown as single cells with conditioned medium, 2 biological rep EpiSC T9b: T9 EpiSC on MEFs in activin-containing CDM, harvested w/o feeders, subconfluent, 2 biological rep ePSC L4: EpiSC-like iPS Cells L4, MEF reprogrammed to EpiSCs with 4F, line L4, grown with LIF and activin, 2 biological rep ePSC L7: EpiSC-like iPS cells L7, MEF reprogrammed to EpiSCs with 4F, line L7, grown with LIF and activin, 2 biological rep ePSC C1: EpiSC-like iPS Cells C1, MEF reprogrammed to EpiSCs with 4F, line C1, grown with LIF and activin, 2 biological rep ePSC C3: EpiSC-like iPS Cells C3, MEF reprogrammed to EpiSCs with 4F, line C3, grown with LIF and activin, 2 biological rep ePSC-R: EpiSC-like iPS Cells reverted, L4 ePSC cells reverted to an ESC-like state using Klf4 virus, 2 biological rep ePSC-RC1: EpiSC-like iPS Cells reverted, L4 ePSR Cre1, Cre-treated L4 ePSR cells, line 1, 2 biological rep ePSC-RC2: EpiSC-like iPS Cells reverted, L4 ePSR Cre2, Cre-treated L4 ePSR cells, line 2, 2 biological rep

Project description:Epiblast stem cells (EpiSCs) derived from post-implantation epiblast are pluripotent stem cells, epigenetically distinct from embryonic stem cells (ESCs), which are widely used in reprogramming studies. Recent achieved haploid cell lines in mammalian open a new era for high-throughput genetic screening, due to their homozygous phenotypes. Here, we report the generation of mouse haploid EpiSCs (haEpiSCs) from post-implantation embryos at embryonic day 6.5 (E6.5). These cells maintain one set of chromosomes, express pluripotent and EpiSC specific genes, and have potentials to differentiate into three germ layers. We also develop a massive mutagenesis protocol with haEpiSCs, and subsequently perform reprogramming genetic screening using this mutation library. Multiple mutants related to various pathway modules are implicated. The validation experiment proves that Knock-out (KO) of Hst3st3b1 (One of the candidates) can promote reprogramming of EpiSCs to ground state efficiently. Our results open the possibility of utilizing haEpiSCs to uncover fundamental biological processes including cell fate alternations.

Project description:Embryonic stem cells (ESCs), which are derived from the primitive ectoderm of pre-implantation blastocysts, are pluripotent cells and can thus contribute to the formation of all somatic cell lineages in chimeric animals. Similarly, epiblast stem cells (EpiSCs), which are derived from epiblast tissue of post-implantation embryos, are also pluripotent and can give rise to derivatives of all three germ layers in teratoma assays. Introduction of the four transcription factors Oct4/Sox2/Klf4/c-Myc into somatic cells has been shown to generate induced pluripotent stem cells (iPSCs). iPSCs exhibit ESC-like properties and are virtually identical to ESCs with respect to a number of charactertistics. However, generation of EpiSC-like cells by direct reprogramming of somatic cells using these transcription factors has not been shown to date. Here we show that Yamanaka’s four transcription factors can be used to directly generate EpiSC-like iPS cells (ePSCs) under EpiSC culture conditions. These ePSCs are identical to EpiSCs with respect to morphology, gene expression pattern, epigenetic status, and chimera formation. This is the first study to demonstrate that the culture environment in transcription factor-mediated reprogramming determines the cell fate of the reprogrammed cell. We could therefore envision that we eventually are able to shape the identity of a directly reprogrammed cell at will simply by modulating the culture conditions.