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:In mammals, X-linked dosage compensation involves two processes: X-inactivation to balance X chromosome dosage between males and females, and X-hyperactivation to achieve X-autosome balance. Transposable elements (TEs) are repetitive mobile DNA sequences and major sources of X chromosome dosage. Current studies in X-linked dosage compensation mainly focus on genes, with TEs still remaining elusive. Here we use “So-Smart-Seq” to comprehensively determine the allelic dynamics of TEs in the context of imprinted and random X-chromosome inactivation (XCI). We find that chromosomal loci and genetic backgrounds significantly impact TE silencing, and reveal putative roles of SINEs in shaping 3D chromatin architectures. We show remarkable difference in TE silencing between two forms of XCI and discover that X-hyperactivation is absent in TEs. Our data provide deep insight for TE studies and greatly contribute to complete understanding of X-chromosome wide dosage compensation.

Project description:X-chromosome inactivation (XCI) entails a massive structural reorganization of the inactive X (Xi). However the molecular architecture of the Xi is unknown. Here we show that the Xi lacks typical autosomal features such as active/inactive compartments and topologically associating domains (TADs), except around a small number of genes that escape XCI and remain expressed. Escaping genes form TADs and retain DNA accessibility at promoter-proximal and CTCF binding sites, indicating that these loci can avoid Xist-mediated erasure of chromosomal structure. We further show that genesilencing competent Xist RNA is sufficient to induce segregation of the Xi into two ‘mega-domains’ separated by a boundary that includes the DXZ4 macrosatellite. Deletion of this boundary prior to XCI results in fusion of the megadomains and altered patterns of escape that correlate with changes in TAD structure following differentiation and XCI . Our results suggest a critical role for the boundary locus and Xist RNA in shaping the structure of the Xi and modulating escape from XCI. Our findings also point to roles of transcription and CTCF binding in TAD formation in the context of facultative heterochromatin.

Project description:X chromosome inactivation (XCI) triggers a drastic reprogramming of gene activities and chromosome architecture. However, how the 3D organization of the inactive X chromosome (Xi) is de novo established in vivo in mammals remains poorly understood. By comprehensive stage- and lineage- specific Hi-C mapping, we identified a unique Xist-separated megadomain structure (X-megadomains) on the Xi in mouse early embryos. X-megadomains emerge in extraembryonic lineages during imprinted XCI, in derived extraembryonic endoderm (XEN) cells, and transiently in the embryonic lineages during random XCI, before Dxz4-delineated megadomains (D-megadomains) occur at later stages in a strain-specific manner. Mechanistically, the emergence of X-megadomain boundary coincides with developmentally regulated enhancer activities and cohesin binding in a regulatory region near Xist (XRR). We pinpointed a subregion XRRa that is critical for the X-megadomain boundary. X-megadomains are impaired when XRRa is removed or cohesin is degraded in XEN cells. Importantly, this is accompanied by ectopic activation of regulatory elements and genes near Xist, suggesting that cohesin loading at regulatory elements promotes X-megadomains and confines local gene activities. Finally, the knockout of XRRa in mouse preimplantation embryos severely impairs the activation of Xist and the initiation of XCI. Hence, our data not only reveal stepwise chromosome folding during de novo XCI in vivo, but also support a model that regulatory element-dependent gene activation and cohesin loading simultaneously promote essential transcription activities and subsequent self-insulation amid global silencing during the early stage of XCI.

Project description:X chromosome inactivation (XCI) triggers a drastic reprogramming of gene activities and chromosome architecture. However, how the 3D organization of the inactive X chromosome (Xi) is de novo established in vivo in mammals remains poorly understood. By comprehensive stage- and lineage- specific Hi-C mapping, we identified a unique Xist-separated megadomain structure (X-megadomains) on the Xi in mouse early embryos. X-megadomains emerge in extraembryonic lineages during imprinted XCI, in derived extraembryonic endoderm (XEN) cells, and transiently in the embryonic lineages during random XCI, before Dxz4-delineated megadomains (D-megadomains) occur at later stages in a strain-specific manner. Mechanistically, the emergence of X-megadomain boundary coincides with developmentally regulated enhancer activities and cohesin binding in a regulatory region near Xist (XRR). We pinpointed a subregion XRRa that is critical for the X-megadomain boundary. X-megadomains are impaired when XRRa is removed or cohesin is degraded in XEN cells. Importantly, this is accompanied by ectopic activation of regulatory elements and genes near Xist, suggesting that cohesin loading at regulatory elements promotes X-megadomains and confines local gene activities. Finally, the knockout of XRRa in mouse preimplantation embryos severely impairs the activation of Xist and the initiation of XCI. Hence, our data not only reveal stepwise chromosome folding during de novo XCI in vivo, but also support a model that regulatory element-dependent gene activation and cohesin loading simultaneously promote essential transcription activities and subsequent self-insulation amid global silencing during the early stage of XCI.

Project description:X chromosome inactivation (XCI) triggers a drastic reprogramming of gene activities and chromosome architecture. However, how the 3D organization of the inactive X chromosome (Xi) is de novo established in vivo in mammals remains poorly understood. By comprehensive stage- and lineage- specific Hi-C mapping, we identified a unique Xist-separated megadomain structure (X-megadomains) on the Xi in mouse early embryos. X-megadomains emerge in extraembryonic lineages during imprinted XCI, in derived extraembryonic endoderm (XEN) cells, and transiently in the embryonic lineages during random XCI, before Dxz4-delineated megadomains (D-megadomains) occur at later stages in a strain-specific manner. Mechanistically, the emergence of X-megadomain boundary coincides with developmentally regulated enhancer activities and cohesin binding in a regulatory region near Xist (XRR). We pinpointed a subregion XRRa that is critical for the X-megadomain boundary. X-megadomains are impaired when XRRa is removed or cohesin is degraded in XEN cells. Importantly, this is accompanied by ectopic activation of regulatory elements and genes near Xist, suggesting that cohesin loading at regulatory elements promotes X-megadomains and confines local gene activities. Finally, the knockout of XRRa in mouse preimplantation embryos severely impairs the activation of Xist and the initiation of XCI. Hence, our data not only reveal stepwise chromosome folding during de novo XCI in vivo, but also support a model that regulatory element-dependent gene activation and cohesin loading simultaneously promote essential transcription activities and subsequent self-insulation amid global silencing during the early stage of XCI.

Project description:X chromosome inactivation (XCI) triggers a drastic reprogramming of gene activities and chromosome architecture. However, how the 3D organization of the inactive X chromosome (Xi) is de novo established in vivo in mammals remains poorly understood. By comprehensive stage- and lineage- specific Hi-C mapping, we identified a unique Xist-separated megadomain structure (X-megadomains) on the Xi in mouse early embryos. X-megadomains emerge in extraembryonic lineages during imprinted XCI, in derived extraembryonic endoderm (XEN) cells, and transiently in the embryonic lineages during random XCI, before Dxz4-delineated megadomains (D-megadomains) occur at later stages in a strain-specific manner. Mechanistically, the emergence of X-megadomain boundary coincides with developmentally regulated enhancer activities and cohesin binding in a regulatory region near Xist (XRR). We pinpointed a subregion XRRa that is critical for the X-megadomain boundary. X-megadomains are impaired when XRRa is removed or cohesin is degraded in XEN cells. Importantly, this is accompanied by ectopic activation of regulatory elements and genes near Xist, suggesting that cohesin loading at regulatory elements promotes X-megadomains and confines local gene activities. Finally, the knockout of XRRa in mouse preimplantation embryos severely impairs the activation of Xist and the initiation of XCI. Hence, our data not only reveal stepwise chromosome folding during de novo XCI in vivo, but also support a model that regulatory element-dependent gene activation and cohesin loading simultaneously promote essential transcription activities and subsequent self-insulation amid global silencing during the early stage of XCI.

Project description:X chromosome inactivation (XCI) triggers a drastic reprogramming of gene activities and chromosome architecture. However, how the 3D organization of the inactive X chromosome (Xi) is de novo established in vivo in mammals remains poorly understood. By comprehensive stage- and lineage- specific Hi-C mapping, we identified a unique Xist-separated megadomain structure (X-megadomains) on the Xi in mouse early embryos. X-megadomains emerge in extraembryonic lineages during imprinted XCI, in derived extraembryonic endoderm (XEN) cells, and transiently in the embryonic lineages during random XCI, before Dxz4-delineated megadomains (D-megadomains) occur at later stages in a strain-specific manner. Mechanistically, the emergence of X-megadomain boundary coincides with developmentally regulated enhancer activities and cohesin binding in a regulatory region near Xist (XRR). We pinpointed a subregion XRRa that is critical for the X-megadomain boundary. X-megadomains are impaired when XRRa is removed or cohesin is degraded in XEN cells. Importantly, this is accompanied by ectopic activation of regulatory elements and genes near Xist, suggesting that cohesin loading at regulatory elements promotes X-megadomains and confines local gene activities. Finally, the knockout of XRRa in mouse preimplantation embryos severely impairs the activation of Xist and the initiation of XCI. Hence, our data not only reveal stepwise chromosome folding during de novo XCI in vivo, but also support a model that regulatory element-dependent gene activation and cohesin loading simultaneously promote essential transcription activities and subsequent self-insulation amid global silencing during the early stage of XCI.

Project description:X chromosome inactivation (XCI) triggers a drastic reprogramming of gene activities and chromosome architecture. However, how the 3D organization of the inactive X chromosome (Xi) is de novo established in vivo in mammals remains poorly understood. By comprehensive stage- and lineage- specific Hi-C mapping, we identified a unique Xist-separated megadomain structure (X-megadomains) on the Xi in mouse early embryos. X-megadomains emerge in extraembryonic lineages during imprinted XCI, in derived extraembryonic endoderm (XEN) cells, and transiently in the embryonic lineages during random XCI, before Dxz4-delineated megadomains (D-megadomains) occur at later stages in a strain-specific manner. Mechanistically, the emergence of X-megadomain boundary coincides with developmentally regulated enhancer activities and cohesin binding in a regulatory region near Xist (XRR). We pinpointed a subregion XRRa that is critical for the X-megadomain boundary. X-megadomains are impaired when XRRa is removed or cohesin is degraded in XEN cells. Importantly, this is accompanied by ectopic activation of regulatory elements and genes near Xist, suggesting that cohesin loading at regulatory elements promotes X-megadomains and confines local gene activities. Finally, the knockout of XRRa in mouse preimplantation embryos severely impairs the activation of Xist and the initiation of XCI. Hence, our data not only reveal stepwise chromosome folding during de novo XCI in vivo, but also support a model that regulatory element-dependent gene activation and cohesin loading simultaneously promote essential transcription activities and subsequent self-insulation amid global silencing during the early stage of XCI.