Project description:Zygote inherits parental genomes with distinct chromatin structure. In eutherian mammals, this asymmetry is seen as crucial for embryonic development notably through its involvement in gene imprinting. Besides the well-established role of DNA methylation for gene imprinting, H3K27me3 has also been shown to mediate a transient form of imprinting in mice. Here, we show that maternal deletion of Ezhip, a negative regulator of PRC2, while increasing the asymmetric distribution of H3K27me3 among the parental genomes at the zygotic stage, in fine, impairs H3K27me3-dependent imprinting and mitigates X Chromosome Inactivation in pre-implantation embryos. We show that EZHIP protein, translated from the maternal pool of RNAs, is present during the first cell divisions post-fertilization. It limits PRC2 enzymatic, avoiding the flattening of H3K27me3 deposition throughout the genome and the equalization of H3K27me3 deposition on the two parental genomes. Our study reveals the necessary inhibition of PRC2 activity post-fertilization for proper development in mice.

Project description:Epigenetic memory undergoes drastic reprogramming in intergenerational gamete-to-embryo transition. H3K27me3, a histone mark catalyzed by PRC2 (Polycomb Repressive Complex 2), is an evolutionally conserved histone mark that plays essential roles in stably repressing developmental genes to maintain cell-type-specific programs. In mice, H3K27me3-mediated epigenetic memory, however, undergoes both resetting at classic Polycomb targets and inheritance of broad H3K27me3 domains that mediate noncanonical imprinting (noncanonical H3K27me3 domains) during early embryogenesis. How such erasure and inheritance are achieved simultaneously remains elusive. Here, through temporal profiling of chromatin occupancy, we show that PRC2 associates with H3K27me3 at both Polycomb targets and noncanonical domains in growing oocytes. PRC2 then pre-disassembles and dissociates from chromatin in mature oocytes, before H3K27me3 erasure at Polycomb targets after fertilization. PRC2 reappears at Polycomb targets in blastocysts when H3K27me3 initiates restoration. By contrast, noncanonical H3K27me3 domains persist to blastocysts, where PRC2 rapidly rebinds by the end of 1-cell embryos until blastocysts. Mechanistically, we found that such noncanonical PRC2 action is regulated by EZHIP, a PRC2 inhibitory factor. By doing so, EZHIP plays a key role in both H3K27me3 erasure and intergenerational inheritance, as well as H3K27me3 re-establishment. Ezhip is highly translated around fertilization, which strongly restricts PRC2 activity, leading to gradual decrease of H3K27me3. Upon knockout of maternal Ezhip, PRC2 becomes hyperactive, binds promiscuously in the genome and deposits widespread H3K27me3. Consequently, H3K27me3 allelic bias and noncanonical imprinting, including imprinted X chromosome inactivation, are impaired. Unexpectedly, the widespread ectopic H3K27me3 paradoxically causes de-repression of H3K27me3 targets, possibly due to dilution of H3K27me3 effectors. Loss of Ezhip further attenuates H3K27me3 restoration at Polycomb targets during peri-implantation, and leads to gene dysregulation and sub-lethality after implantation. Taken together, we uncover PRC2 noncanonical chromatin association during the parental-to-embryonic transition and identify Ezhip as a crucial regulator for both erasure and inheritance of intergenerational epigenetic memories.

Project description:Epigenetic memory undergoes drastic reprogramming in intergenerational gamete-to-embryo transition. H3K27me3, a histone mark catalyzed by PRC2 (Polycomb Repressive Complex 2), is an evolutionally conserved histone mark that plays essential roles in stably repressing developmental genes to maintain cell-type-specific programs. In mice, H3K27me3-mediated epigenetic memory, however, undergoes both resetting at classic Polycomb targets and inheritance of broad H3K27me3 domains that mediate noncanonical imprinting (noncanonical H3K27me3 domains) during early embryogenesis. How such erasure and inheritance are achieved simultaneously remains elusive. Here, through temporal profiling of chromatin occupancy, we show that PRC2 associates with H3K27me3 at both Polycomb targets and noncanonical domains in growing oocytes. PRC2 then pre-disassembles and dissociates from chromatin in mature oocytes, before H3K27me3 erasure at Polycomb targets after fertilization. PRC2 reappears at Polycomb targets in blastocysts when H3K27me3 initiates restoration. By contrast, noncanonical H3K27me3 domains persist to blastocysts, where PRC2 rapidly rebinds by the end of 1-cell embryos until blastocysts. Mechanistically, we found that such noncanonical PRC2 action is regulated by EZHIP, a PRC2 inhibitory factor. By doing so, EZHIP plays a key role in both H3K27me3 erasure and intergenerational inheritance, as well as H3K27me3 re-establishment. Ezhip is highly translated around fertilization, which strongly restricts PRC2 activity, leading to gradual decrease of H3K27me3. Upon knockout of maternal Ezhip, PRC2 becomes hyperactive, binds promiscuously in the genome and deposits widespread H3K27me3. Consequently, H3K27me3 allelic bias and noncanonical imprinting, including imprinted X chromosome inactivation, are impaired. Unexpectedly, the widespread ectopic H3K27me3 paradoxically causes de-repression of H3K27me3 targets, possibly due to dilution of H3K27me3 effectors. Loss of Ezhip further attenuates H3K27me3 restoration at Polycomb targets during peri-implantation, and leads to gene dysregulation and sub-lethality after implantation. Taken together, we uncover PRC2 noncanonical chromatin association during the parental-to-embryonic transition and identify Ezhip as a crucial regulator for both erasure and inheritance of intergenerational epigenetic memories.

Project description:Epigenetic memory undergoes drastic reprogramming in intergenerational gamete-to-embryo transition. H3K27me3, a histone mark catalyzed by PRC2 (Polycomb Repressive Complex 2), is an evolutionally conserved histone mark that plays essential roles in stably repressing developmental genes to maintain cell-type-specific programs. In mice, H3K27me3-mediated epigenetic memory, however, undergoes both resetting at classic Polycomb targets and inheritance of broad H3K27me3 domains that mediate noncanonical imprinting (noncanonical H3K27me3 domains) during early embryogenesis. How such erasure and inheritance are achieved simultaneously remains elusive. Here, through temporal profiling of chromatin occupancy, we show that PRC2 associates with H3K27me3 at both Polycomb targets and noncanonical domains in growing oocytes. PRC2 then pre-disassembles and dissociates from chromatin in mature oocytes, before H3K27me3 erasure at Polycomb targets after fertilization. PRC2 reappears at Polycomb targets in blastocysts when H3K27me3 initiates restoration. By contrast, noncanonical H3K27me3 domains persist to blastocysts, where PRC2 rapidly rebinds by the end of 1-cell embryos until blastocysts. Mechanistically, we found that such noncanonical PRC2 action is regulated by EZHIP, a PRC2 inhibitory factor. By doing so, EZHIP plays a key role in both H3K27me3 erasure and intergenerational inheritance, as well as H3K27me3 re-establishment. Ezhip is highly translated around fertilization, which strongly restricts PRC2 activity, leading to gradual decrease of H3K27me3. Upon knockout of maternal Ezhip, PRC2 becomes hyperactive, binds promiscuously in the genome and deposits widespread H3K27me3. Consequently, H3K27me3 allelic bias and noncanonical imprinting, including imprinted X chromosome inactivation, are impaired. Unexpectedly, the widespread ectopic H3K27me3 paradoxically causes de-repression of H3K27me3 targets, possibly due to dilution of H3K27me3 effectors. Loss of Ezhip further attenuates H3K27me3 restoration at Polycomb targets during peri-implantation, and leads to gene dysregulation and sub-lethality after implantation. Taken together, we uncover PRC2 noncanonical chromatin association during the parental-to-embryonic transition and identify Ezhip as a crucial regulator for both erasure and inheritance of intergenerational epigenetic memories.

Project description:Paternal and maternal epigenomes undergo dramatic changes after fertilization. How this relates to the 3D reorganisation of the parental genomes and their transcription patterns during early development remains unclear. Here we track structural dynamics during early mouse development using allele-specific single cell HiC integrated with transcriptome and chromatin changes, to combine parental features with early gene expression including during imprinted X-chromosome inactivation. We uncover a marked structural asymmetry following fertilization, with mostly maternal-specific domains of interaction that coincide with polycomb H3K27me3 domains. They form local repressive compartments and result in parentally-biased gene expression, including transient imprinting loci such as the X-inactivation center. These asymmetric domains later resolve into classical active and inactive compartments. Topologically associated domains are also established progressively, in a non parental specific manner and are associated with active chromatin. They are lost when gene expression is not maintained on the paternal X. Our study reveals unprecedented dynamics in parental specific 3D genome organization and gene expression during early development.

Project description:In this study, we report that EZHIP and H3 K27M preferentially interact with an allosterically activated form of PRC2 in vivo. The formation of H3 K27M- and EZHIP-PRC2 complexes occurs at CpG islands containing H3K27me3 and impedes PRC2 and H3K27me3 spreading. Moreover, we find that H3 K27M inhibits PRC2 in trans and can reduce H3K27me3 levels independent of chromatin incorporation. While EZHIP is not found outside of placental mammals, we find that expression of human EZHIP reduces H3K27me3 in Drosophila melanogaster through a conserved molecular mechanism.

Project description:In this study, we report that EZHIP and H3 K27M preferentially interact with an allosterically activated form of PRC2 in vivo. The formation of H3 K27M- and EZHIP-PRC2 complexes occurs at CpG islands containing H3K27me3 and impedes PRC2 and H3K27me3 spreading. Moreover, we find that H3 K27M inhibits PRC2 in trans and can reduce H3K27me3 levels independent of chromatin incorporation. While EZHIP is not found outside of placental mammals, we find that expression of human EZHIP reduces H3K27me3 in Drosophila melanogaster through a conserved molecular mechanism.

Project description:In this study, we report that EZHIP and H3 K27M preferentially interact with an allosterically activated form of PRC2 in vivo. The formation of H3 K27M- and EZHIP-PRC2 complexes occurs at CpG islands containing H3K27me3 and impedes PRC2 and H3K27me3 spreading. Moreover, we find that H3 K27M inhibits PRC2 in trans and can reduce H3K27me3 levels independent of chromatin incorporation. While EZHIP is not found outside of placental mammals, we find that expression of human EZHIP reduces H3K27me3 in Drosophila melanogaster through a conserved molecular mechanism.

Project description:In this study, we report that EZHIP and H3 K27M preferentially interact with an allosterically activated form of PRC2 in vivo. The formation of H3 K27M- and EZHIP-PRC2 complexes occurs at CpG islands containing H3K27me3 and impedes PRC2 and H3K27me3 spreading. Moreover, we find that H3 K27M inhibits PRC2 in trans and can reduce H3K27me3 levels independent of chromatin incorporation. While EZHIP is not found outside of placental mammals, we find that expression of human EZHIP reduces H3K27me3 in Drosophila melanogaster through a conserved molecular mechanism.

Project description:In this study, we report that EZHIP and H3 K27M preferentially interact with an allosterically activated form of PRC2 in vivo. The formation of H3 K27M- and EZHIP-PRC2 complexes occurs at CpG islands containing H3K27me3 and impedes PRC2 and H3K27me3 spreading. Moreover, we find that H3 K27M inhibits PRC2 in trans and can reduce H3K27me3 levels independent of chromatin incorporation. While EZHIP is not found outside of placental mammals, we find that expression of human EZHIP reduces H3K27me3 in Drosophila melanogaster through a conserved molecular mechanism.