Project description:Embryonic Stem Cells (ESCs) and Epiblast Stem Cells (EpiSCs) are the in vitro representants of naM-CM-/ve and primed pluripotency, respectively. It is currently unclear how their epigenome underpin the phenotypic and molecular characteristics of these states of pluripotency. Here, we performed the first qualitative and quantitative comparison of DNA methylation between ESCs and EpiSCs. The global level and genomic distribution of DNA methylation were very similar between the two cell types. However, the analysis of promoter methylation patterns in EpiSCs revealed several distinct features: (i) the repression of germline-related genes by DNA methylation, a process already ongoing in ESCs but far more pronounced in EpiSCs; (ii) the hypermethylation of promoters (especially CpG rich) in EpiSC compared to both ESCs and dissected epiblasts from E6.5 and E7.5 embryos; (iii) the inability of hypomethylated (Dnmt-deficient) ESCs to be converted into EpiSCs despite their ability to self-renew. Altogether, our data show that DNA methylation is an important epigenetic regulator of gene expression in EpiSCs and suggest that it is essential for the obtention of EpiSCs. MethylCap-Seq (DNA methylation profiling) and RNA-Seq of 3 EpiStem Cells (EpiSCs) and 1 Embryonic Stem Cell line of which the data has been submitted to GEO before (part of GEO SuperSeries GSE23943 and GSE31343)

Project description:To characterize molecular features of new EpiSC lines established by the Wnt inhibition method, global gene expression profiles of the EpiSC lines were determined by microarray, and compared to those of EpiSC lines established by other group using the conventional method. Epiblasts, the source of the EpiSCs, and mESCs were also analyzed. EpiSCs and mESC were maintained as undifferentiated state on feeder layers. The stem cells were then separated from feeders, and RNAs were extracted from the stem cell lines. Embryonic tissues were manually dissected out from mouse embryos of E5.5, E6.5 or E7.5, from which RNAs were extracted.

Project description:The pluripotency of mammalian early and late epiblast could be recapitulated by naïve embryonic stem cells (ESCs) and primed epiblast stem cells (EpiSCs), respectively. However, these two states of pluripotency may not be sufficient to reflect the full complexity and developmental potency of the epiblast during mammalian early development. Here we report the establishment of self-renewing formative pluripotent stem cells (fPSCs) which manifest features of epiblast cells poised for gastrulation. fPSCs can be established from different mouse ESCs, pre-/early-gastrula epiblasts and induced PSCs. Similar to pre-/early-gastrula epiblasts, fPSCs show the transcriptomic features of formative pluripotency, which are distinct from naïve ESCs and primed EpiSCs. fPSCs show the unique epigenetic states of E6.5 epiblast, including the super-bivalency of a large set of developmental genes. Just like epiblast cells immediately before gastrulation, fPSCs can efficiently differentiate into three germ layers and primordial germ cells (PGCs) in vitro. Thus, fPSCs highlight the feasibility of using PSCs to explore the development of mammalian epiblast.

Project description:Here we show that by simple modulation of extrinsic signaling pathways, a new class of pluripotent stem cells, referred to as region selective epiblast stem cells (rsEpiSCs), could be efficiently derived from different stages of the early embryo. rsEpiSCs share features of primed pluripotency yet are distinct from EpiSCs in their molecular characteristics and ability to colonize post-implantation embryos. We performed RNA-sequencing experiments and examined the global gene expression profiles of EpiSCs, rsEpiSCs, in vivo isolated four regions of E6.5 mouse epiblasts: AP (anterior-proximal), AD (anterior-distal), PP (posterior-proximal) and PD (posterior-distal), human H1 ESCs, H1 rsESCs, H9 ESCs, H9 rsESCs, rhesus monkey ORMES23 rsESCs, and chimpanzee rsiPSCs. Examination of global gene expression profiles in 2 pluripotent stem cell types across multiple species.

Project description:Here we show that by simple modulation of extrinsic signaling pathways, a new class of pluripotent stem cells, referred to as region selective epiblast stem cells (rsEpiSCs), could be efficiently derived from different stages of the early embryo. rsEpiSCs share features of primed pluripotency yet are distinct from EpiSCs in their molecular characteristics and ability to colonize post-implantation embryos. We performed RNA-sequencing experiments and examined the global gene expression profiles of EpiSCs, rsEpiSCs, in vivo isolated four regions of E6.5 mouse epiblasts: AP (anterior-proximal), AD (anterior-distal), PP (posterior-proximal) and PD (posterior-distal), human H1 ESCs, H1 rsESCs, H9 ESCs, H9 rsESCs, rhesus monkey ORMES23 rsESCs, and chimpanzee rsiPSCs.

Project description:We reported the ALSCs derivation from E3.5 blastocysts and E6.5 epiblasts cultured in basic N2B27 medium supplemented with Acitivin A and LIF. Activin A subtitutes NODAL signaling in vivo and is an important factor for self-renewal. LIF is extracted from feeder and have an impact on sustaining pluripotency of ESCs. We combined the two factors and finding AL medium could sustaining a novel mouse embryonic stem cells. Furthermore, EpiSCs are also discovered that able to convert to rESCs by culturing in AL medium for several passages, which illustrates that AL medium not only support establishment of pluripotent stem cells from embryos in vivo but also could convert EpiSCs to rESCs. Then, based on multiple analyses of pluripotency, we performed RNA-seq of ALSCs to exploring the differences of ALSCs compared to EpiSCs and ESCs respctively. RNA-seq data showed ALSCs is different with EpiSCs or ESCs. Teratoma test proved ALSCs could contribute to three germ layers in vivo and embryonic body analysis testify ALSCs could differentiate to three germ layers like cells in vitro.

Project description:Sox2 is a key transcription factor directing embryonic stem cell (ESC) pluripotency. However, the role of SoxB1 proteins in epiblast stem cell (EpiSC) pluripotency is unknown. Here we compare the transcriptomes of pluripotent cells cultured in different conditions that express different levels of Sox2. While highest Sox2 level in ESCs are enriched for naive pluripotency markers, ESCs and EpiSCs expressing the same Sox2 level were transcriptionally distinct. Thus Sox2 levels do not dictate the distinction between ESC and EpiSC states.

Project description:To characterize molecular features of new EpiSC lines established by the Wnt inhibition method, global gene expression profiles of the EpiSC lines were determined by microarray, and compared to those of EpiSC lines established by other group using the conventional method. Epiblasts, the source of the EpiSCs, and mESCs were also analyzed.

Project description:Embryonic stem cells (ESCs) comprise at least two populations of cells with divergent states of pluripotency. Here, we show that epiblast stem cells (EpiSCs) also comprise two distinct cell populations that can be distinguished by the expression of a specific Oct4-GFP marker. These two subpopulations, Oct4-GFP positive and negative EpiSCs, are capable of converting into each other in vitro. Oct4-GFP positive and negative EpiSCs are distinct from ESCs with respect to global gene expression pattern, epigenetic profile, and Oct4 enhancer utilization. Oct4-GFP negative cells share features with cells of the late mouse epiblast and cannot form chimeras. However, Oct4-GFP positive EpiSCs, which only represent a minor EpiSC fraction, resemble cells of the early epiblast and can readily contribute to chimeras. Our findings suggest that the rare ability of EpiSCs to contribute to chimeras is due to the presence of the minor EpiSC fraction representing the early epiblast. RNA samples to be analyzed on microarrays were prepared using Qiagen RNeasy columns with on-column DNA digestion. 300 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. 6 samples were analyzed, five of them in duplicate and one of them (T9-EpiSC) a single time (11 total samples). ESC: Mouse ESC male; EpiSC: Mouse EpiSC male GOF18; Epi-Sox2: Mouse EpiSC Sox2 male GOF18 (Overexpressing WT Sox2) cultured in condition EpiSC medium (CM); EpiSC-GFP-: Mouse E3 EpiSC grown in CM and FACS-sorted for GFP-; EpiSC-GFP+: Mouse E3 EpiSC grown in CM and FACS-sorted for GFP+; T9-EpiSC: Mouse T9 EpiSC grown on medium-density CF1 MEFs in UM, 2d -Fgf2, harvested without MEFs. The supplementary file 'GSE17984_non-normalized_data.txt' contains non-normalized data for Samples GSM450294-GSM450304.

Project description:Embryonic stem cells (ESCs) comprise at least two populations of cells with divergent states of pluripotency. Here, we show that epiblast stem cells (EpiSCs) also comprise two distinct cell populations that can be distinguished by the expression of a specific Oct4-GFP marker. These two subpopulations, Oct4-GFP positive and negative EpiSCs, are capable of converting into each other in vitro. Oct4-GFP positive and negative EpiSCs are distinct from ESCs with respect to global gene expression pattern, epigenetic profile, and Oct4 enhancer utilization. Oct4-GFP negative cells share features with cells of the late mouse epiblast and cannot form chimeras. However, Oct4-GFP positive EpiSCs, which only represent a minor EpiSC fraction, resemble cells of the early epiblast and can readily contribute to chimeras. Our findings suggest that the rare ability of EpiSCs to contribute to chimeras is due to the presence of the minor EpiSC fraction representing the early epiblast.