Project description:Reprogramming to iPSCs resets the epigenome of somatic cells including the reversal of X chromosome-inactivation. We sought to gain insight into the steps underlying the reprogramming process by examining the means by which reprogramming leads to X chromosome-reactivation (XCR). Analyzing single cells in situ, we found that hallmarks of the inactive X (Xi) change sequentially, providing a direct readout of reprogramming progression. Several epigenetic changes on the Xi occur in the inverse order of developmental X-inactivation, while others are uncoupled from this sequence. Among the latter, DNA methylation has an extraordinary long persistence on the Xi during reprogramming, and, like Xist expression, is erased only after pluripotency genes are activated. Mechanistically, XCR requires both DNA demethylation and Xist silencing, ensuring that only cells undergoing faithful reprogramming initiate XCR. Our study defines the epigenetic state of multiple sequential reprogramming intermediates and establishes a paradigm for studying cell fate transitions during reprogramming. RRBS profiles were generated from female and male ES cells, female iPS cells, SSEA1+ and SSEA1- reprogramming intermediates, and male and female MEFs, for a total of 18 samples.

Project description:Reprogramming to iPSCs resets the epigenome of somatic cells including the reversal of X chromosome-inactivation. We sought to gain insight into the steps underlying the reprogramming process by examining the means by which reprogramming leads to X chromosome-reactivation (XCR). Analyzing single cells in situ, we found that hallmarks of the inactive X (Xi) change sequentially, providing a direct readout of reprogramming progression. Several epigenetic changes on the Xi occur in the inverse order of developmental X-inactivation, while others are uncoupled from this sequence. Among the latter, DNA methylation has an extraordinary long persistence on the Xi during reprogramming, and, like Xist expression, is erased only after pluripotency genes are activated. Mechanistically, XCR requires both DNA demethylation and Xist silencing, ensuring that only cells undergoing faithful reprogramming initiate XCR. Our study defines the epigenetic state of multiple sequential reprogramming intermediates and establishes a paradigm for studying cell fate transitions during reprogramming.

Project description:X chromosome reactivation (XCR) represents a paradigm to study epigenetic regulation and the reversal of chromatin silencing, although how it is linked to the pluripotency gene regulatory network, pluripotency transcription factors (TFs) and chromatin remodelling processes remains largely unexplained. Several pluripotency TFs have been linked to XCR through binding to the long non-coding RNA gene Xist, but whether other regulatory elements are involved is unclear. Here, we show that reprogramming to iPSCs induces gradual acquisition of chromatin accessibility at specific sites on the inactive X chromosome (Xi) which is subsequently propagated to other regulatory elements including enhancers and promoters. Regions that are genomically closer to day 0 accessible regions become biallelically accessible earlier, than the more distant ones. For distinct categories of chromatin regions that become biallelically accessible at different times, different sets of transcription factor (TF) motifs are enriched, including the pluripotency TFs KLF4 and cMYC. In addition, regions that become bialleliacally accessible earlier also show increased TF pluripotency binding, supporting the link between pluripotency TFs in XCR. To further explore the relationship between pluripotency TFs and XCR, we construct the active Gene Regulatory Networks (GRNs) during iPSC reprogramming using scRNA-seq and computational analyses. We reveal gene targets of 311 TFs expressed across reprogramming to iPSCs. Using this single-cell regulatory atlas, we show that X-linked genes are preferentially targeted by several pluripotency TFs. Our results suggest a new model where XCR may be coordinated by direct targeting of regulatory elements on the X chromosome by pluripotency TFs, concomitant with step-wise acquisition of chromatin accessibility. Altogether, our results demonstrate how gradual acquisition of a new GRN during reprogramming of cellular identity is linked with dynamic induction of chromatin accessibility and overcomes stable chromatin silencing on the Xi.

Project description:X chromosome reactivation (XCR) represents a paradigm to study epigenetic regulation and the reversal of chromatin silencing, although how it is linked to the pluripotency gene regulatory network, pluripotency transcription factors (TFs) and chromatin remodelling processes remains largely unexplained. Several pluripotency TFs have been linked to XCR through binding to the long non-coding RNA gene Xist, but whether other regulatory elements are involved is unclear. Here, we show that reprogramming to iPSCs induces gradual acquisition of chromatin accessibility at specific sites on the inactive X chromosome (Xi) which is subsequently propagated to other regulatory elements including enhancers and promoters. Regions that are genomically closer to day 0 accessible regions become biallelically accessible earlier, than the more distant ones. For distinct categories of chromatin regions that become biallelically accessible at different times, different sets of transcription factor (TF) motifs are enriched, including the pluripotency TFs KLF4 and cMYC. In addition, regions that become bialleliacally accessible earlier also show increased TF pluripotency binding, supporting the link between pluripotency TFs in XCR. To further explore the relationship between pluripotency TFs and XCR, we construct the active Gene Regulatory Networks (GRNs) during iPSC reprogramming using scRNA-seq and computational analyses. We reveal gene targets of 311 TFs expressed across reprogramming to iPSCs. Using this single-cell regulatory atlas, we show that X-linked genes are preferentially targeted by several pluripotency TFs. Our results suggest a new model where XCR may be coordinated by direct targeting of regulatory elements on the X chromosome by pluripotency TFs, concomitant with step-wise acquisition of chromatin accessibility. Altogether, our results demonstrate how gradual acquisition of a new GRN during reprogramming of cellular identity is linked with dynamic induction of chromatin accessibility and overcomes stable chromatin silencing on the Xi.

Project description:X chromosome reactivation (XCR) represents a paradigm to study epigenetic regulation and the reversal of chromatin silencing, although how it is linked to the pluripotency gene regulatory network, pluripotency transcription factors (TFs) and chromatin remodelling processes remains largely unexplained. Several pluripotency TFs have been linked to XCR through binding to the long non-coding RNA gene Xist, but whether other regulatory elements are involved is unclear. Here, we show that reprogramming to iPSCs induces gradual acquisition of chromatin accessibility at specific sites on the inactive X chromosome (Xi) which is subsequently propagated to other regulatory elements including enhancers and promoters. Regions that are genomically closer to day 0 accessible regions become biallelically accessible earlier, than the more distant ones. For distinct categories of chromatin regions that become biallelically accessible at different times, different sets of transcription factor (TF) motifs are enriched, including the pluripotency TFs KLF4 and cMYC. In addition, regions that become bialleliacally accessible earlier also show increased TF pluripotency binding, supporting the link between pluripotency TFs in XCR. To further explore the relationship between pluripotency TFs and XCR, we construct the active Gene Regulatory Networks (GRNs) during iPSC reprogramming using scRNA-seq and computational analyses. We reveal gene targets of 311 TFs expressed across reprogramming to iPSCs. Using this single-cell regulatory atlas, we show that X-linked genes are preferentially targeted by several pluripotency TFs. Our results suggest a new model where XCR may be coordinated by direct targeting of regulatory elements on the X chromosome by pluripotency TFs, concomitant with step-wise acquisition of chromatin accessibility. Altogether, our results demonstrate how gradual acquisition of a new GRN during reprogramming of cellular identity is linked with dynamic induction of chromatin accessibility and overcomes stable chromatin silencing on the Xi.

Project description:X chromosome reactivation (XCR) represents a paradigm to study epigenetic regulation and the reversal of chromatin silencing, although how it is linked to the pluripotency gene regulatory network, pluripotency transcription factors (TFs) and chromatin remodelling processes remains largely unexplained. Several pluripotency TFs have been linked to XCR through binding to the long non-coding RNA gene Xist, but whether other regulatory elements are involved is unclear. Here, we show that reprogramming to iPSCs induces gradual acquisition of chromatin accessibility at specific sites on the inactive X chromosome (Xi) which is subsequently propagated to other regulatory elements including enhancers and promoters. Regions that are genomically closer to day 0 accessible regions become biallelically accessible earlier, than the more distant ones. For distinct categories of chromatin regions that become biallelically accessible at different times, different sets of transcription factor (TF) motifs are enriched, including the pluripotency TFs KLF4 and cMYC. In addition, regions that become bialleliacally accessible earlier also show increased TF pluripotency binding, supporting the link between pluripotency TFs in XCR. To further explore the relationship between pluripotency TFs and XCR, we construct the active Gene Regulatory Networks (GRNs) during iPSC reprogramming using scRNA-seq and computational analyses. We reveal gene targets of 311 TFs expressed across reprogramming to iPSCs. Using this single-cell regulatory atlas, we show that X-linked genes are preferentially targeted by several pluripotency TFs. Our results suggest a new model where XCR may be coordinated by direct targeting of regulatory elements on the X chromosome by pluripotency TFs, concomitant with step-wise acquisition of chromatin accessibility. Altogether, our results demonstrate how gradual acquisition of a new GRN during reprogramming of cellular identity is linked with dynamic induction of chromatin accessibility and overcomes stable chromatin silencing on the Xi.

Project description:X chromosome inactivation (XCI) triggers drastic reorganization of chromatin architecture, which in turn facilitates XCI. However, how the 3D organization is de novo established during XCI in vivo remains poorly understood. Mouse embryos present an ideal model, as they undergo imprinted XCI, X chromosome reactivation (XCR) and subsequent random XCI. Using low-input Hi-C, we revealed a unique chromatin structure of the inactive X chromosome (Xi) during both imprinted and random XCI in early mouse embryos. A bipartite structure featured by two megadomains separated by Xist (X-megadomains), emerges in extraembryonic lineages, derived extraembryonic endoderm (XEN) cells, and also transiently in embryonic lineages. X-megadomains then diminish in adult tissues, where previously reported Dxz4-delineated megadomains (D-megadomains) appear in a strain-specific manner. Mechanistically, X-megadomains coincide with developmentally controlled activities of regulatory regions near Xist (XRRs), and loss of XRR disrupts X-megadomains. CUT&RUN revealed strong enrichment of CTCF and cohesin near Xist, despite global depletion, on Xi in embryos and XEN cells. X-megadomains are also impaired when Xist is silenced, accompanied by global cohesin restoration, or when residual cohesin is degraded, suggesting that X-megadomain formation is promoted by both global cohesin depletion and local cohesin loading. Importantly, the loss of cohesin leads to ectopic activation of regulatory elements and genes near Xist. Hence, these data reveal programming of chromatin architecture during de novo establishment of mammalian XCI in vivo, and suggest that cohesin mediates self-insulation of gene activity of essential escapees amid global silencing.

Project description:X chromosome inactivation (XCI) triggers drastic reorganization of chromatin architecture, which in turn facilitates XCI. However, how the 3D organization is de novo established during XCI in vivo remains poorly understood. Mouse embryos present an ideal model, as they undergo imprinted XCI, X chromosome reactivation (XCR) and subsequent random XCI. Using low-input Hi-C, we revealed a unique chromatin structure of the inactive X chromosome (Xi) during both imprinted and random XCI in early mouse embryos. A bipartite structure featured by two megadomains separated by Xist (X-megadomains), emerges in extraembryonic lineages, derived extraembryonic endoderm (XEN) cells, and also transiently in embryonic lineages. X-megadomains then diminish in adult tissues, where previously reported Dxz4-delineated megadomains (D-megadomains) appear in a strain-specific manner. Mechanistically, X-megadomains coincide with developmentally controlled activities of regulatory regions near Xist (XRRs), and loss of XRR disrupts X-megadomains. CUT&RUN revealed strong enrichment of CTCF and cohesin near Xist, despite global depletion, on Xi in embryos and XEN cells. X-megadomains are also impaired when Xist is silenced, accompanied by global cohesin restoration, or when residual cohesin is degraded, suggesting that X-megadomain formation is promoted by both global cohesin depletion and local cohesin loading. Importantly, the loss of cohesin leads to ectopic activation of regulatory elements and genes near Xist. Hence, these data reveal programming of chromatin architecture during de novo establishment of mammalian XCI in vivo, and suggest that cohesin mediates self-insulation of gene activity of essential escapees amid global silencing.

Project description:Erasure of epigenetic memory is required to convert somatic cells towards pluripotency. Reactivation of the inactive X chromosome (Xi) has been used to model epigenetic reprogramming in mouse, but human studies are hampered by Xi epigenetic instability and difficulties in tracking partially reprogrammed iPSCs. Here we used cell fusion to examine the earliest events in the reprogramming-induced Xi reactivation of human female fibroblasts. We show a rapid and widespread loss of Xi-associated H3K27me3 and XIST in fused cells that precedes the bi-allelic expression of selected Xi-genes by many heterokaryons (30-50%). After cell division, RNA-FISH and RNA-Seq analysis confirmed that Xi reactivation remained partial and showed that induction of human pluripotency-specific XACT transcripts occurred, but was rare (1%). These data effectively separate pre- and post-mitotic events in reprogramming-induced Xi reactivation, and suggest a hierarchy where early events such as XIST-delocalisation, are required but are insufficient to establish stable human X reactivation. We performed RNA-sequencing of human fibroblast clones derived from TERT-immortalised NHDF17914 (Lonza) before and at 5 days after fusion with mouse ESC (E14Tg2a:puroR). Two biological replicates were performed and sequenced.

Project description:Erasure of epigenetic memory is required to convert somatic cells towards pluripotency. Reactivation of the inactive X chromosome (Xi) has been used to model epigenetic reprogramming in mouse, but human studies are hampered by Xi epigenetic instability and difficulties in tracking partially reprogrammed iPSCs. Here we used cell fusion to examine the earliest events in the reprogramming-induced Xi reactivation of human female fibroblasts. We show a rapid and widespread loss of Xi-associated H3K27me3 and XIST in fused cells that precedes the bi-allelic expression of selected Xi-genes by many heterokaryons (30-50%). After cell division, RNA-FISH and RNA-Seq analysis confirmed that Xi reactivation remained partial and showed that induction of human pluripotency-specific XACT transcripts occurred, but was rare (1%). These data effectively separate pre- and post-mitotic events in reprogramming-induced Xi reactivation, and suggest a hierarchy where early events such as XIST-delocalisation, are required but are insufficient to establish stable human X reactivation.