Project description:Ovarian reserve defines the female reproductive lifespan, which in humans spans decades due to the robust maintenance of meiotic arrest in non-growing oocytes residing in primordial follicles. Dynamic epigenomic reprogramming and programming occur during mammalian germline and early embryonic development. However, the chromatin-based mechanisms that underlie the establishment and maintenance of ovarian reserves are poorly defined. Here, we report a comprehensive epigenomic landscape of mouse perinatal oocytes and unravel Polycomb-based mechanisms underlying ovarian reserve development. By quantitatively profiling key histone modifications, including the Polycomb-mediated repressive marks H2AK119ub and H3K27me3, we identified two major epigenomic transitions: one for ovarian reserve formation from meiotic prophase I to dictyate-arrested non-growing oocytes, and another for ovarian reserve activation from non-growing to growing oocytes. Combining conditional loss-of-function mouse models for Polycomb Repressive Complex 1 or 2 (PRC1/2), we show that PRC1-H2AK119ub and PRC2-H3K27me3 undergo differential dynamics during perinatal oogenesis and have distinct biological functions in ovarian reserve formation and maintenance. Notably, PRC1-H2AK119ub presets the epigenetic states in non-growing oocytes and provides a blueprint for the PRC2-H3K27me3 profile, which is globally reprogrammed as oocytes exit the ovarian reserve and grow. Our study determines a comprehensive epigenomic roadmap of perinatal oogenesis, shedding light on how the ovarian reserve is formed, maintained, and activated, emphasizing a critical window of epigenetic programming during female germline development.

Project description:Ovarian reserve defines the female reproductive lifespan, which in humans spans decades due to the robust maintenance of meiotic arrest in non-growing oocytes residing in primordial follicles. Dynamic epigenomic reprogramming and programming occur during mammalian germline and early embryonic development. However, the chromatin-based mechanisms that underlie the establishment and maintenance of ovarian reserves are poorly defined. Here, we report a comprehensive epigenomic landscape of mouse perinatal oocytes and unravel Polycomb-based mechanisms underlying ovarian reserve development. By quantitatively profiling key histone modifications, including the Polycomb-mediated repressive marks H2AK119ub and H3K27me3, we identified two major epigenomic transitions: one for ovarian reserve formation from meiotic prophase I to dictyate-arrested non-growing oocytes, and another for ovarian reserve activation from non-growing to growing oocytes. Combining conditional loss-of-function mouse models for Polycomb Repressive Complex 1 or 2 (PRC1/2), we show that PRC1-H2AK119ub and PRC2-H3K27me3 undergo differential dynamics during perinatal oogenesis and have distinct biological functions in ovarian reserve formation and maintenance. Notably, PRC1-H2AK119ub presets the epigenetic states in non-growing oocytes and provides a blueprint for the PRC2-H3K27me3 profile, which is globally reprogrammed as oocytes exit the ovarian reserve and grow. Our study determines a comprehensive epigenomic roadmap of perinatal oogenesis, shedding light on how the ovarian reserve is formed, maintained, and activated, emphasizing a critical window of epigenetic programming during female germline development.

Project description:We assessed the levels of the PRC1 Polycomb mark, RYBP, H2AK119Ub1, and the PRC2 Polycomb mark, H3K27me3, considering the extensive crosstalk between PRC1 and PRC2 activities.

Project description:Polycomb Repressive Complexes PRC1 and PRC2 play a crucial role in silencing lineage-specific genes during early embryogenesis. To provide new insights in polycomb biology, we profiled the proximal interactome (proxeome) of the catalytic subunits RNF2 (PRC1) and EZH2 (PRC2) in mouse embryonic stem cells (mESCs). This revealed >100 proteins proximal to PRC2 and PRC1, which mainly comprise transcription factors, transcriptional regulators and RNA binding proteins. Interestingly, the EZH2 proxeome included both PRC complexes, while the RNF2 proxeome only identified PRC1 subunits. More than half of the PRC2 proximal proteins are shared with PRC1, revealing the molecular constitution of polycomb chromatin domains. We identified several pluripotency-associated transcription factors, including NANOG, for which we confirmed genomic co-localisation with PRC2. Upon PRC2 disruption, NANOG redistributes to specific sites containing its DNA binding motif. Finally, we compared PRC2 proximal interactomes between naïve mESCs, serum-cultured mESCs and embryoid bodies, altogether providing a comprehensive resource in different cellular contexts that may help to further decipher Polycomb biology.

Project description:Polycomb Repressive Complexes PRC1 and PRC2 play a crucial role in silencing lineage-specific genes during early embryogenesis. To provide new insights in polycomb biology, we profiled the proximal interactome (proxeome) of the catalytic subunits RNF2 (PRC1) and EZH2 (PRC2) in mouse embryonic stem cells (mESCs). This revealed >100 proteins proximal to PRC2 and PRC1, which mainly comprise transcription factors, transcriptional regulators and RNA binding proteins. Interestingly, the EZH2 proxeome included both PRC complexes, while the RNF2 proxeome only identified PRC1 subunits. More than half of the PRC2 proximal proteins are shared with PRC1, revealing the molecular constitution of polycomb chromatin domains. We identified several pluripotency-associated transcription factors, including NANOG, for which we confirmed genomic co-localisation with PRC2. Upon PRC2 disruption, NANOG redistributes to specific sites containing its DNA binding motif. Finally, we compared PRC2 proximal interactomes between naïve mESCs, serum-cultured mESCs and embryoid bodies, altogether providing a comprehensive resource in different cellular contexts that may help to further decipher Polycomb biology.

Project description:The ovarian reserve defines the female reproductive lifespan, which in humans spans decades due to robust maintenance of meiotic arrest in oocytes residing in primordial follicles. Epigenetic reprogramming, including DNA demethylation, accompanies meiotic entry, but the chromatin changes that underpin the generation and preservation of ovarian reserves are poorly defined. We report that the Polycomb Repressive Complex 1 (PRC1) establishes repressive chromatin states in perinatal mouse oocytes that directly suppress the gene expression program of meiotic prophase-I and thereby enable the transition to dictyate arrest. PRC1 dysfuction causes depletion of the ovarian reserve and leads to premature ovarian failure. Our study demonstrates a fundamental role for PRC1-mediated gene silencing in female reproductive lifespan, and reveals a critical window of epigenetic programming required to establish ovarian reserve.

Project description:In mammals, chromatin organization undergoes drastic reorganization during oocyte development. However, the dynamics of three-dimensional chromatin structure in this process is poorly characterized. Using low-input Hi-C (genome-wide chromatin conformation capture), we found that a unique chromatin organization gradually appears during mouse oocyte growth. Oocytes at late stages show self-interacting, cohesin-independent compartmental domains marked by H3K27me3, therefore termed Polycomb-associating domains (PADs). PADs and inter-PAD (iPAD) regions form compartment-like structures with strong inter-domain interactions among nearby PADs. PADs disassemble upon meiotic resumption from diplotene arrest but briefly reappear on the maternal genome after fertilization. Upon maternal depletion of Eed, PADs are largely intact in oocytes, but their reestablishment after fertilization is compromised. By contrast, depletion of Polycomb repressive complex 1 (PRC1) proteins attenuates PADs in oocytes, which is associated with substantial gene de-repression in PADs. These data reveal a critical role of Polycomb in regulating chromatin architecture during mammalian oocyte growth and early development.

Project description:In mammals, chromatin organization undergoes drastic reorganization during oocyte development. However, the dynamics of three-dimensional chromatin structure in this process is poorly characterized. Using low-input Hi-C (genome-wide chromatin conformation capture), we found that a unique chromatin organization gradually appears during mouse oocyte growth. Oocytes at late stages show self-interacting, cohesin-independent compartmental domains marked by H3K27me3, therefore termed Polycomb-associating domains (PADs). PADs and inter-PAD (iPAD) regions form compartment-like structures with strong inter-domain interactions among nearby PADs. PADs disassemble upon meiotic resumption from diplotene arrest but briefly reappear on the maternal genome after fertilization. Upon maternal depletion of Eed, PADs are largely intact in oocytes, but their reestablishment after fertilization is compromised. By contrast, depletion of Polycomb repressive complex 1 (PRC1) proteins attenuates PADs in oocytes, which is associated with substantial gene de-repression in PADs. These data reveal a critical role of Polycomb in regulating chromatin architecture during mammalian oocyte growth and early development.

Project description:In mammals, chromatin organization undergoes drastic reorganization during oocyte development. However, the dynamics of three-dimensional chromatin structure in this process is poorly characterized. Using low-input Hi-C (genome-wide chromatin conformation capture), we found that a unique chromatin organization gradually appears during mouse oocyte growth. Oocytes at late stages show self-interacting, cohesin-independent compartmental domains marked by H3K27me3, therefore termed Polycomb-associating domains (PADs). PADs and inter-PAD (iPAD) regions form compartment-like structures with strong inter-domain interactions among nearby PADs. PADs disassemble upon meiotic resumption from diplotene arrest but briefly reappear on the maternal genome after fertilization. Upon maternal depletion of Eed, PADs are largely intact in oocytes, but their reestablishment after fertilization is compromised. By contrast, depletion of Polycomb repressive complex 1 (PRC1) proteins attenuates PADs in oocytes, which is associated with substantial gene de-repression in PADs. These data reveal a critical role of Polycomb in regulating chromatin architecture during mammalian oocyte growth and early development.

Project description:Polycomb group proteins form two main complexes, PRC2 and PRC1, which generally coregulate their target genes. Here, we show that PRC1 components act as neoplastic tumor suppressors independently of PRC2 function. By mapping the distribution of PRC1 components and the histone H3K27me3 mark, we identify genes that acquire PRC1 and H3K27me3 in larvae, and a much larger set of genes bound by PRC1 in the absence of H3K27me3 in larval tissues. These genes massively outnumber canonical targets and they are preeminently involved in the regulation of cell proliferation, signaling and polarity. Mutation in PRC1 components specifically deregulates this set of genes, whereas canonical targets are derepressed in both PRC1 and PRC2 mutants. In human ES cells, PRC1 components colocalize with H3K27me3 like in Drosophila embryos, whereas they are selectively recruited to a large set of proliferation and signaling-associated genes in differentiated cell types, showing that the redeployment of PRC1 components during development is evolutionarily conserved. Comparative study of Polycomb group proteins and histon marks during development with ChIP-Seq and RNA-Seq data in eye discs and wing discs (L3 stage) in Drosophila