Symmetric inheritance of parental histones governs epigenome maintenance and embryonic stem cell identity.

Modified parental histones are segregated symmetrically to daughter DNA strands during replication and can be inherited through mitosis. How this may sustain the epigenome and cell identity remains unknown. Here we show that transmission of histone-based information during DNA replication maintains epigenome fidelity and embryonic stem cell plasticity. Asymmetric segregation of parental histones H3-H4 in MCM2-2A mutants compromised mitotic inheritance of histone modifications and globally altered the epigenome. This included widespread spurious deposition of repressive modifications, suggesting elevated epigenetic noise. Moreover, H3K9me3 loss at repeats caused derepression and H3K27me3 redistribution across bivalent promoters correlated with misexpression of developmental genes. MCM2-2A mutation challenged dynamic transitions in cellular states across the cell cycle, enhancing naïve pluripotency and reducing lineage priming in G1. Furthermore, developmental competence was diminished, correlating with impaired exit from pluripotency. Collectively, this argues that epigenetic inheritance of histone modifications maintains a correctly balanced and dynamic chromatin landscape able to support mammalian cell differentiation.

Recycling of modified H2A-H2B provides short-term memory of chromatin states.

Chromatin landscapes are disrupted during DNA replication and must be restored faithfully to maintain genome regulation and cell identity. The histone H3-H4 modification landscape is restored by parental histone recycling and modification of new histones. How DNA replication impacts on histone H2A-H2B is currently unknown. Here, we measure H2A-H2B modifications and H2A.Z during DNA replication and across the cell cycle using quantitative genomics. We show that H2AK119ub1, H2BK120ub1, and H2A.Z are recycled accurately during DNA replication. Modified H2A-H2B are segregated symmetrically to daughter strands via POLA1 on the lagging strand, but independent of H3-H4 recycling. Post-replication, H2A-H2B modification and variant landscapes are quickly restored, and H2AK119ub1 guides accurate restoration of H3K27me3. This work reveals epigenetic transmission of parental H2A-H2B during DNA replication and identifies cross talk between H3-H4 and H2A-H2B modifications in epigenome propagation. We propose that rapid short-term memory of recycled H2A-H2B modifications facilitates restoration of stable H3-H4 chromatin states.

Distinctive features of lincRNA gene expression suggest widespread RNA-independent functions.

Eukaryotic genomes produce RNAs lacking protein-coding potential, with enigmatic roles. We integrated three approaches to study large intervening noncoding RNA (lincRNA) gene functions. First, we profiled mouse embryonic stem cells and neural precursor cells at single-cell resolution, revealing lincRNAs expressed in specific cell types, cell subpopulations, or cell cycle stages. Second, we assembled a transcriptome-wide atlas of nuclear lincRNA degradation by identifying targets of the exosome cofactor Mtr4. Third, we developed a reversible depletion system to separate the role of a lincRNA gene from that of its RNA. Our approach distinguished lincRNA loci functioning in trans from those modulating local gene expression. Some genes express stable and/or abundant lincRNAs in single cells, but many prematurely terminate transcription and produce lincRNAs rapidly degraded by the nuclear exosome. This suggests that besides RNA-dependent functions, lincRNA loci act as DNA elements or through transcription. Our integrative approach helps distinguish these mechanisms.

MCM2 promotes symmetric inheritance of modified histones during DNA replication.

During genome replication, parental histones are recycled to newly replicated DNA with their posttranslational modifications (PTMs). Whether sister chromatids inherit modified histones evenly remains unknown. We measured histone PTM partition to sister chromatids in embryonic stem cells. We found that parental histones H3-H4 segregate to both daughter DNA strands with a weak leading-strand bias, skewing partition at topologically associating domain (TAD) borders and enhancers proximal to replication initiation zones. Segregation of parental histones to the leading strand increased markedly in cells with histone-binding mutations in MCM2, part of the replicative helicase, exacerbating histone PTM sister chromatid asymmetry. This work reveals how histones are inherited to sister chromatids and identifies a mechanism by which the replication machinery ensures symmetric cell division.

RNA fate determination through cotranscriptional adenosine methylation and microprocessor binding.

Eukaryotic gene expression is heavily regulated at the transcriptional and post-transcriptional levels. An additional layer of regulation occurs co-transcriptionally through processing and decay of nascent transcripts physically associated with chromatin. This process involves RNA interference (RNAi) machinery and is well documented in yeast, but little is known about its conservation in mammals. Here we show that Dgcr8 and Drosha physically associate with chromatin in murine embryonic stem cells (mES), specifically with a subset of transcribed coding and noncoding genes. Dgcr8 recruitment to chromatin is dependent on transcription as well as methyltransferase-like 3 (Mettl3), which catalyzes RNA N6-methyladenosine (m6A). Intriguingly, we found that acute temperature stress causes radical relocalization of Dgcr8 and Mettl3 to heat-shock genes, where they act to co-transcriptionally mark mRNAs for subsequent RNA degradation. Together, our findings elucidate a novel mode of co-transcriptional gene regulation, in which m6A serves as a chemical mark that instigates subsequent post-transcriptional RNA-processing events.