Project description:Chromatin landscapes are disrupted during DNA replication and must be restored faithfully to maintain genome regulation and cell identity. The H3-H4 modification landscape is restored by parental histone recycling and post-replication modification of new histone H3-H4. How DNA replication impact on histone H2A-H2B is unknown. Here, we track H2A-H2B modifications and H2A.Z during DNA replication and across the cell cycle using quantitative genomics. We show that H2AK119ub, H2BK120ub, and H2A.Z are recycled quantitatively and accurately during DNA replication. H2A-H2B are recycled symmetrically to daughter strands largely independent of known H3-H4 recycling pathways. Post-replication, H2A-H2B modifications are rapidly restored, and the rapid wave of H2AK119ub supports accurate restoration of H3K27me3. This work reveals epigenetic transmission of H2A-H2B modification during DNA replication and identifies H3-H4 and H2A-H2B crosstalk in epigenome propagation. We propose that rapid short-term memory of recycled H2A-H2B modifications facilitates reestablishment of slow, long-term chromatin state memory.

Project description:Chromatin landscapes are disrupted during DNA replication and must be restored faithfully to maintain genome regulation and cell identity. The H3-H4 modification landscape is restored by parental histone recycling and post-replication modification of new histone H3-H4. How DNA replication impact on histone H2A-H2B is unknown. Here, we track H2A-H2B modifications and H2A.Z during DNA replication and across the cell cycle using quantitative genomics. We show that H2AK119ub, H2BK120ub, and H2A.Z are recycled quantitatively and accurately during DNA replication. H2A-H2B are recycled symmetrically to daughter strands largely independent of known H3-H4 recycling pathways. Post-replication, H2A-H2B modifications are rapidly restored, and the rapid wave of H2AK119ub supports accurate restoration of H3K27me3. This work reveals epigenetic transmission of H2A-H2B modification during DNA replication and identifies H3-H4 and H2A-H2B crosstalk in epigenome propagation. We propose that rapid short-term memory of recycled H2A-H2B modifications facilitates reestablishment of slow, long-term chromatin state memory.

Project description:Chromatin landscapes are disrupted during DNA replication and must be restored faithfully to maintain genome regulation and cell identity. The H3-H4 modification landscape is restored by parental histone recycling and post-replication modification of new histone H3-H4. How DNA replication impact on histone H2A-H2B is unknown. Here, we track H2A-H2B modifications and H2A.Z during DNA replication and across the cell cycle using quantitative genomics. We show that H2AK119ub, H2BK120ub, and H2A.Z are recycled quantitatively and accurately during DNA replication. H2A-H2B are recycled symmetrically to daughter strands largely independent of known H3-H4 recycling pathways. Post-replication, H2A-H2B modifications are rapidly restored, and the rapid wave of H2AK119ub supports accurate restoration of H3K27me3. This work reveals epigenetic transmission of H2A-H2B modification during DNA replication and identifies H3-H4 and H2A-H2B crosstalk in epigenome propagation. We propose that rapid short-term memory of recycled H2A-H2B modifications facilitates reestablishment of slow, long-term chromatin state memory.

Project description:Identification of 29 Kbz sites on yeast H3, H4, H2A, H2A.Z, and H2B by LC-MS/MS.

Project description:Epigenetic inheritance during DNA replication requires an orchestrated assembly of nucleosomes from parental and newly synthesized histones. We analyzed Drosophila HisC mutant embryos harboring a deletion of all canonical histone genes, in which nucleosome assembly relies on parental histones from cell cycle 14 onwards. Lack of new histone synthesis and parental histone recycling leads to more accessible chromatin and reduced nucleosome occupancy. This leads to upregulated and spurious transcription, whereas the control of the developmental transcriptional program is partially maintained. Importantly, the genomic positions of modified parental H2A, H2B, and H3 are restored during DNA replication. Therefore, the results suggest that parental histones with active or repressive marks are recycled to preserve the epigenetic landscape during DNA replication in vivo.

Project description:Epigenetic inheritance during DNA replication requires an orchestrated assembly of nucleosomes from parental and newly synthesized histones. We analyzed Drosophila HisC mutant embryos harboring a deletion of all canonical histone genes, in which nucleosome assembly relies on parental histones from cell cycle 14 onwards. Lack of new histone synthesis and parental histone recycling leads to more accessible chromatin and reduced nucleosome occupancy. This leads to upregulated and spurious transcription, whereas the control of the developmental transcriptional program is partially maintained. Importantly, the genomic positions of modified parental H2A, H2B, and H3 are restored during DNA replication. Therefore, the results suggest that parental histones with active or repressive marks are recycled to preserve the epigenetic landscape during DNA replication in vivo.

Project description:Epigenetic inheritance during DNA replication requires an orchestrated assembly of nucleosomes from parental and newly synthesized histones. We analyzed Drosophila HisC mutant embryos harboring a deletion of all canonical histone genes, in which nucleosome assembly relies on parental histones from cell cycle 14 onwards. Lack of new histone synthesis and parental histone recycling leads to more accessible chromatin and reduced nucleosome occupancy. This leads to upregulated and spurious transcription, whereas the control of the developmental transcriptional program is partially maintained. Importantly, the genomic positions of modified parental H2A, H2B, and H3 are restored during DNA replication. Therefore, the results suggest that parental histones with active or repressive marks are recycled to preserve the epigenetic landscape during DNA replication in vivo.

Project description:Epigenetic inheritance during DNA replication requires an orchestrated assembly of nucleosomes from parental and newly synthesized histones. We analyzed Drosophila HisC mutant embryos harboring a deletion of all canonical histone genes, in which nucleosome assembly relies on parental histones from cell cycle 14 onwards. Lack of new histone synthesis and parental histone recycling leads to more accessible chromatin and reduced nucleosome occupancy. This leads to upregulated and spurious transcription, whereas the control of the developmental transcriptional program is partially maintained. Importantly, the genomic positions of modified parental H2A, H2B, and H3 are restored during DNA replication. Therefore, the results suggest that parental histones with active or repressive marks are recycled to preserve the epigenetic landscape during DNA replication in vivo.

Project description:Epigenetic inheritance during DNA replication requires an orchestrated assembly of nucleosomes from parental and newly synthesized histones. We analyzed Drosophila HisC mutant embryos harboring a deletion of all canonical histone genes, in which nucleosome assembly relies on parental histones from cell cycle 14 onwards. Lack of new histone synthesis and parental histone recycling leads to more accessible chromatin and reduced nucleosome occupancy. This leads to upregulated and spurious transcription, whereas the control of the developmental transcriptional program is partially maintained. Importantly, the genomic positions of modified parental H2A, H2B, and H3 are restored during DNA replication. Therefore, the results suggest that parental histones with active or repressive marks are recycled to preserve the epigenetic landscape during DNA replication in vivo.

Project description:Histone acetylation is important for the activation of gene transcription but little is known about its direct ‘read/write’ mechanisms. Here, we report cryo-electron microscopy structures in which a p300/CBP multidomain monomer recognizes histone H4 N-terminal tail (NT) acetylation (ac) in a nucleosome and acetylates non-H4 histone NTs within the same nucleosome. p300/CBP not only recognized H4NTac via the bromodomain pocket responsible for ‘reading’, but also interacted with the DNA minor grooves via the outside of that pocket. This directed the catalytic center of p300/CBP to one of the non-H4 histone NTs. The primary target that p300 ‘writes’ by ‘reading’ H4NTac was H2BNT, and H2BNTac promoted H2A-H2B dissociation from the nucleosome. We propose a model in which p300/CBP ‘replicates’ histone NT acetylation within the H3-H4 tetramer to inherit epigenetic storage, and ‘transcribes’ it from the H3-H4 tetramer to the H2B-H2A dimers to activate context-dependent gene transcription through local nucleosome destabilization.