Project description:In the process of DNA replication, the first steps in restoring the chromatin landscape involve parental histone recycling and new histone deposition. Disrupting histone recycling to either the leading or lagging strand induces asymmetric histone inheritance, impacting epigenome maintenance and cellular identity. However, the order and kinetics of these effects remain elusive. Here, we employ inducible mutants to dissect the early and late consequences of impaired histone recycling. Simultaneous disruption of both leading (POLE4) and lagging strand (MCM2-2A) recycling pathways impairs transmission of parental histones to newly synthesized DNA, with release of some parental histones to the soluble pool. Subsequently, H3K27me3 accumulates aberrantly during chromatin restoration in a manner preceding gene expression changes. Loss of histone inheritance and the ensuing chromatin restoration defects alter gene expression in embryonic stem cells, challenges differentiation programs and cell viability. Our findings demonstrate the importance of efficient transmission of histone-based information during DNA replication for maintaining chromatin landscapes, differentiation potential, and cellular viability.

Project description:In the process of DNA replication, the first steps in restoring the chromatin landscape involve parental histone recycling and new histone deposition. Disrupting histone recycling to either the leading or lagging strand induces asymmetric histone inheritance, impacting epigenome maintenance and cellular identity. However, the order and kinetics of these effects remain elusive. Here, we employ inducible mutants to dissect the early and late consequences of impaired histone recycling. Simultaneous disruption of both leading (POLE4) and lagging strand (MCM2-2A) recycling pathways impairs transmission of parental histones to newly synthesized DNA, with release of some parental histones to the soluble pool. Subsequently, H3K27me3 accumulates aberrantly during chromatin restoration in a manner preceding gene expression changes. Loss of histone inheritance and the ensuing chromatin restoration defects alter gene expression in embryonic stem cells, challenges differentiation programs and cell viability. Our findings demonstrate the importance of efficient transmission of histone-based information during DNA replication for maintaining chromatin landscapes, differentiation potential, and cellular viability.

Project description:In the process of DNA replication, the first steps in restoring the chromatin landscape involve parental histone recycling and new histone deposition. Disrupting histone recycling to either the leading or lagging strand induces asymmetric histone inheritance, impacting epigenome maintenance and cellular identity. However, the order and kinetics of these effects remain elusive. Here, we employ inducible mutants to dissect the early and late consequences of impaired histone recycling. Simultaneous disruption of both leading (POLE4) and lagging strand (MCM2-2A) recycling pathways impairs transmission of parental histones to newly synthesized DNA, with release of some parental histones to the soluble pool. Subsequently, H3K27me3 accumulates aberrantly during chromatin restoration in a manner preceding gene expression changes. Loss of histone inheritance and the ensuing chromatin restoration defects alter gene expression in embryonic stem cells, challenges differentiation programs and cell viability. Our findings demonstrate the importance of efficient transmission of histone-based information during DNA replication for maintaining chromatin landscapes, differentiation potential, and cellular viability.

Project description:The inheritance of parental histones across the replication fork is thought to mediate epigenetic memory. Here, we reveal that fission yeast Mrc1 (Claspin in humans) binds H3-H4 tetramers and operates as a central coordinator of symmetric parental histone inheritance. Mrc1 mutants in a key connector domain disrupted segregation of parental histones to the lagging strand comparable to Mcm2 histone-binding mutants. Both mutants showed clonal and asymmetric loss of H3K9me-mediated gene silencing. AlphaFold predicted co-chaperoning of H3-H4 tetramers by Mrc1 and Mcm2, with the Mrc1 connector domain bridging histone and Mcm2 binding. Biochemical and functional analysis validated this model and revealed a duality in Mrc1 function: disabling histone binding in the connector domain disrupted lagging strand recycling while another histone-binding mutation impaired leading strand recycling. We propose Mrc1 toggles histones between the lagging and leading strand recycling pathways, in part by intra-replisome co-chaperoning, to ensure epigenetic transmission to both daughter cells.

Project description:The inheritance of parental histones across the replication fork is thought to mediate epigenetic memory. Here, we reveal that fission yeast Mrc1 (Claspin in humans) binds H3-H4 tetramers and operates as a central coordinator of symmetric parental histone inheritance. Mrc1 mutants in a key connector domain disrupted segregation of parental histones to the lagging strand comparable to Mcm2 histone-binding mutants. Both mutants showed clonal and asymmetric loss of H3K9me-mediated gene silencing. AlphaFold predicted co-chaperoning of H3-H4 tetramers by Mrc1 and Mcm2, with the Mrc1 connector domain bridging histone and Mcm2 binding. Biochemical and functional analysis validated this model and revealed a duality in Mrc1 function: disabling histone binding in the connector domain disrupted lagging strand recycling while another histone-binding mutation impaired leading strand recycling. We propose Mrc1 toggles histones between the lagging and leading strand recycling pathways, in part by intra-replisome co-chaperoning, to ensure epigenetic transmission to both daughter cells. This SuperSeries is composed of the SubSeries listed below.

Project description:The inheritance of parental histones across the replication fork is thought to mediate epigenetic memory. Here, we reveal that fission yeast Mrc1 (Claspin in humans) binds H3-H4 tetramers and operates as a central coordinator of symmetric parental histone inheritance. Mrc1 mutants in a key connector domain disrupted segregation of parental histones to the lagging strand comparable to Mcm2 histone-binding mutants. Both mutants showed clonal and asymmetric loss of H3K9me-mediated gene silencing. AlphaFold predicted co-chaperoning of H3-H4 tetramers by Mrc1 and Mcm2, with the Mrc1 connector domain bridging histone and Mcm2 binding. Biochemical and functional analysis validated this model and revealed a duality in Mrc1 function: disabling histone binding in the connector domain disrupted lagging strand recycling while another histone-binding mutation impaired leading strand recycling. We propose Mrc1 toggles histones between the lagging and leading strand recycling pathways, in part by intra-replisome co-chaperoning, to ensure epigenetic transmission to both daughter cells.

Project description:Parental histone recycling is essential for the restoration of chromatin-based epigenetic information during chromatin replication; however, the specific mechanisms underlying the local recycling of parental histones remain poorly understood. Here, we reveal an unexpected role of the Spt16-N domain in histone chaperone FACT during parental histone recycling and transfer in budding yeast. We found that depletion of Spt16 or mutations in the Spt16 middle domain leads to defects in both parental histone recycling and new histone deposition, affecting both the leading and lagging strands of DNA replication forks, highlighting the essential role of the FACT complex in both parental histone recycling and new histone deposition. Surprisingly, Spt16-N deletion results in an apparent defect in parental histone recycling, with a more pronounced defect on the lagging strand than the corresponding leading strand. Mechanistically, the Spt16-N domain acts as a protective barrier, shielding FACT-bound histone H3-H4 and facilitating its interaction with Mcm2, which ensures efficient local parental histone recycling. Collectively, the Spt16-N domain provides a protein–protein interaction module allowing FACT to act as a shuttle chaperone, cooperate with multiple replisome components, which act as co-chaperones, to form a complex involving the shuttle chaperone, histones, and co-chaperones, during parental histone recycling and transfer.

Project description:Chromatin replication is intricately intertwined with DNA replication, and the recycling of parental histones is essential for epigenetic inheritance. The transfer of parental histones to both the DNA replication leading and lagging strands involves two distinct pathways: the leading strand utilizes DNA polymerase ε subunits Dpb3/Dpb4, while the lagging strand is facilitated by the MCM helicase subunit Mcm2. However, the process by which Mcm2, moving along the leading strand, facilitates the transfer of parental histones to the lagging strand remains unclear. Our study reveals that the deletion of Pol32, a non-essential subunit of major lagging-strand DNA polymerase δ, results in a predominant transfer of parental histone H3-H4 to the replication leading strand. Biochemical analyses further demonstrate that Pol32 can bind histone H3-H4 both in vivo and in vitro. The interaction of Pol32 with parental histone H3-H4 is disrupted by the mutation of Mcm2's histone H3-H4 binding domain. In conclusion, our findings identify the DNA polymerase delta subunit Pol32 as a novel key histone chaperone downstream of Mcm2, mediating the transfer of parental histones to the lagging strand during DNA replication.

Project description:Recycling of parental histones is an important step in epigenetic inheritance. During DNA replication, DNA polymerase epsilon subunit DPB3/DPB4 and DNA replication helicase subunit MCM2 are involved in the transfer of parental histones to the leading and lagging DNA strands, respectively. Single Dpb3 deletion (dpb3[DELTA]) or Mcm2 mutation (mcm2-3A), which each disrupt one parental histone transfer pathway, leads to the other[prime]s predominance. However, the impact of the two histone transfer pathways on chromatin structure and DNA repair remains elusive. In this study, we used budding yeast Saccharomyces cerevisiae to determine the genetic and epigenetic outcomes from disruption of parental histone H3-H4 tetramer transfer. We found that a dpb3[DELTA]/mcm2-3A double mutant did not exhibit the single dpb3[DELTA] and mcm2-3A mutants[prime] asymmetric parental histone patterns, suggesting that the processes by which parental histones are transferred to the leading and lagging strands are independent. Surprisingly, the frequency of homologous recombination was significantly lower in dpb3[DELTA], mcm2-3A, and dpb3[DELTA]/mcm2-3A mutants relative to the wild-type strain, likely due to the elevated levels of free histones detected in the mutant cells. Together, these findings indicate that proper transfer of parental histones to the leading and lagging strands during DNA replication is essential for maintaining chromatin structure and that high levels of free histones due to parental histone transfer defects are detrimental to cells.

Project description:During DNA replication parental, nucleosomic histones are segregated almost symmetrically to the two daughter DNA strands enabling mitotic inheritance of histones and their PTMs. In MCM2 histone-binding mutant ESCs (MCM2-2A), histones are recycled asymmetrically to the leading strand. To evaluate if loss of parental histones contributes to the asymmetry, we tracked new and old histones quantitatively by pulse-Triple-SILAC-MS. The quantification showed no change in dilution and incorporation dynamics in MCM2-2A cells, demonstrating that parental histones are not lost at replication forks but re-routed from the lagging to the leading strand.