ChIP‐Seq of ERα and RNA polymerase II defines genes differentially responding to ligands

We used ChIP‐Seq to map ERα‐binding sites and to profile changes in RNA polymerase II (RNAPII) occupancy in MCF‐7 cells in response to estradiol (E2), tamoxifen or fulvestrant. We identify 10 205 high confidence ERα‐binding sites in response to E2 of which 68% contain an estrogen response element (ERE) and only 7% contain a FOXA1 motif. Remarkably, 596 genes change significantly in RNAPII occupancy (59% up and 41% down) already after 1 h of E2 exposure. Although promoter proximal enrichment of RNAPII (PPEP) occurs frequently in MCF‐7 cells (17%), it is only observed on a minority of E2‐regulated genes (4%). Tamoxifen and fulvestrant partially reduce ERα DNA binding and prevent RNAPII loading on the promoter and coding body on E2‐upregulated genes. Both ligands act differently on E2‐downregulated genes: tamoxifen acts as an agonist thus downregulating these genes, whereas fulvestrant antagonizes E2‐induced repression and often increases RNAPII occupancy. Furthermore, our data identify genes preferentially regulated by tamoxifen but not by E2 or fulvestrant. Thus (partial) antagonist loaded ERα acts mechanistically different on E2‐activated and E2‐repressed genes.     

Structural characterization of Set1 RNA recognition motifs and their role in histone H3 lysine 4 methylation

The yeast Set1 histone H3 lysine 4 (H3K4) methyltransferase contains, in addition to its catalytic SET domain, a conserved RNA recognition motif (RRM1). We present here the crystal structure and the secondary structure assignment in solution of the Set1 RRM1. Although RRM1 has the expected betaalphabetabetaalphabeta RRM-fold, it lacks the typical RNA-binding features of these modules. RRM1 is not able to bind RNA by itself in vitro, but a construct combining RRM1 with a newly identified downstream RRM2 specifically binds RNA. In vivo, H3K4 methylation is not affected by a point mutation in RRM2 that preserves Set1 stability but affects RNA binding in vitro. In contrast mutating RRM1 destabilizes Set1 and leads to an increase of dimethylation of H3K4 at the 5'-coding region of active genes at the expense of trimethylation, whereas both, dimethylation decreases at the 3'-coding region. Taken together, our results suggest that Set1 RRMs bind RNA, but Set1 RNA-binding activity is not linked to H3K4 methylation.     

SETDB1/NSD-dependent H3K9me3/H3K36me3 dual heterochromatin maintains gene expression profiles by bookmarking poised enhancers

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Drought‐inducible changes in the histone modification H3K9ac are associated with drought‐responsive gene expression in Brachypodium distachyon

• H3K9ac, an epigenetic marker, is widely distributed in plant genomes. H3K9ac enhances gene expression, which is highly conserved in eukaryotes. However, genome‐wide studies of H3K9ac in monocot species are limited, and the changes in H3K9ac under drought stress for individual genes are still not clear.
• We analysed changes in the H3K9ac level of Brachypodium distachyon under 20% PEG‐6000‐simulated drought stress conditions. We also performed chromatin immunoprecipitation, followed by next generation sequencing (ChIP‐seq) on H3K9ac to reveal changes in H3K9ac for individual genes at the genome‐wide level.
• Our study showed that H3K9ac was mainly enriched in gene exon regions. Drought increased or decreased the H3K9ac level at specific genomic loci. We identified 40 genes associated with increased H3K9ac levels and 36 genes associated with decreased H3K9ac levels under drought stress. Further, RT‐qPCR analyses showed that H3K9ac was positively associated with gene expression of those drought‐responsive genes.
• We conclude that H3K9ac enhances the expression level of a large number of drought‐responsive genes under drought stress in B. distachyon. The data presented here will help to reveal the correlation of some specific drought‐responsive genes and their enriched H3K9ac levels in the model plant B. distachyon.

     

RNA polymerase II acts as an RNA‐dependent RNA polymerase to extend and destabilize a non‐coding RNA

RNA polymerase II (Pol II) is a well‐characterized DNA‐dependent RNA polymerase, which has also been reported to have RNA‐dependent RNA polymerase (RdRP) activity. Natural cellular RNA substrates of mammalian Pol II, however, have not been identified and the cellular function of the Pol II RdRP activity is unknown. We found that Pol II can use a non‐coding RNA, B2 RNA, as both a substrate and a template for its RdRP activity. Pol II extends B2 RNA by 18 nt on its 3′‐end in an internally templated reaction. The RNA product resulting from extension of B2 RNA by the Pol II RdRP can be removed from Pol II by a factor present in nuclear extracts. Treatment of cells with α‐amanitin or actinomycin D revealed that extension of B2 RNA by Pol II destabilizes the RNA. Our studies provide compelling evidence that mammalian Pol II acts as an RdRP to control the stability of a cellular RNA by extending its 3′‐end.     

Stress‐associated H3K4 methylation accumulates during postnatal development and aging of rhesus macaque brain

Epigenetic modifications are critical determinants of cellular and developmental states. Epigenetic changes, such as decreased H3K27me3 histone methylation on insulin/IGF1 genes, have been previously shown to modulate lifespan through gene expression regulation. However, global epigenetic changes during aging and their biological functions, if any, remain elusive. Here, we examined the histone modification H3K4 dimethylation (H3K4me2) in the prefrontal cortex of individual rhesus macaques at different ages by chromatin immunoprecipitation, followed by deep sequencing (ChIP‐seq) at the whole genome level. Through integrative analysis of the ChIP‐seq profiles with gene expression data, we found that H3K4me2 increased at promoters and enhancers globally during postnatal development and aging, and those that correspond to gene expression changes in cis are enriched for stress responses, such as the DNA damage response. This suggests that metabolic and environmental stresses experienced by an organism are associated with the progressive opening of chromatin. In support of this, we also observed increased expression of two H3K4 methyltransferases, SETD7 and DPY30, in aged macaque brain.