Project description:H2B mono-ubiquitylation is required for multiple methylations of both H3K4 and H3K79 and has been implicated in gene expression from yeast to human. However, molecular crosstalk between H2BUb1 and other modifications, especially H3K4 and H3K79 methylations, remains unclear in vertebrates. To understand the functional role of H2BUb1, genome-wide histone modification patterns were measured in human cells. This study proposes dual roles of H2BUb1 that are both H3 methylation dependent and independent. First, H2BUb1 is a 5'-enriched active transcription mark and is co-occupied with H3K79 methylations in actively transcribed regions. Importantly, this study found a unique role of H2BUb1 in chromatin architecture independent of histone H3 methylations. H2BUb1 is well positioned in exon-intron boundaries of highly expressed exons and is specifically enriched in 5'-biased exons. Furthermore, H2BUb1 demonstrates increased occupancy in skipped exons compared to flanking exons for the human and mouse genome. Our findings suggest that a potentiating mechanism links H2BUb1 to both H3K79 methylations in actively transcribed regions and the exon-intron structure of highly expressed exons through the regulation of nucleosome dynamics during transcription elongation. We generated high-throughput sequencing (ChIP-seq) data for genome-wide occupancy of H2BUb1, nucleosome, H3K4me3, H3K36me3, H379me1/2/3, H3Ac, and mRNA in human embryonic carcinoma cells. We performed ChIP-seq for seven different histone modifications, MNase-seq, mRNA-seq (two replications), and inputDNA-seq in NCCIT cell lines (human embryonic carcinoma cell lines). We also performed mRNA-seq for RNF20-siRNA transfected NCCIT cells, where H2BUb1 signals decreased.

Project description:Various histone modifications decorate nucleosomes within transcribed genes. Among these, monoubiquitylation of histone H2B (H2Bub1) and methylation of histone H3 on lysines 36 (H3K36me2/3) and 79 (H3K79me2/3) correlate positively with gene expression. By measuring the progression of the transcriptional machinery along genes within live cells, we now report that H2B monoubiquitylation occurs co-transcriptionally and accurately reflects the advance of RNA polymerase II (Pol II). In contrast, H3K36me3 and H3K79me2 are less dynamic and represent Pol II movement less faithfully. High resolution ChIP-seq reveals that H2Bub1 levels are selectively reduced at exons, and decrease in an exon-dependent stepwise manner towards the 3' end of genes. Exonic depletion of H2Bub1 in gene bodies is highly correlated with Pol II pausing at exons, suggesting elongation rate changes associated with intron-exon structure. Overall, our data shed light on the organization of H2Bub1 within transcribed genes, and single out H2Bub1 as a reliable marker for ongoing transcription elongation. H2Bub1 and H2B ChIP-seq in NT2 cells

Project description:Various histone modifications decorate nucleosomes within transcribed genes. Among these, monoubiquitylation of histone H2B (H2Bub1) and methylation of histone H3 on lysines 36 (H3K36me2/3) and 79 (H3K79me2/3) correlate positively with gene expression. By measuring the progression of the transcriptional machinery along genes within live cells, we now report that H2B monoubiquitylation occurs co-transcriptionally and accurately reflects the advance of RNA polymerase II (Pol II). In contrast, H3K36me3 and H3K79me2 are less dynamic and represent Pol II movement less faithfully. High resolution ChIP-seq reveals that H2Bub1 levels are selectively reduced at exons, and decrease in an exon-dependent stepwise manner towards the 3' end of genes. Exonic depletion of H2Bub1 in gene bodies is highly correlated with Pol II pausing at exons, suggesting elongation rate changes associated with intron-exon structure. Overall, our data shed light on the organization of H2Bub1 within transcribed genes, and single out H2Bub1 as a reliable marker for ongoing transcription elongation.

Project description:Genomic features of DSB re-landscaping in rtf1 mutants. Histone modification is a critical determinant of frequency and location of double-strand breaks (DSBs), which induce recombination during meiosis. The Set1-dependent histone H3K4 and Dot1-dependent H3K79 methylations play an important role in DSB formations in budding yeast. Both methylations are promoted by the RNA polymerase II associated factor 1 (Paf1) complex, Paf1C. This study addressed a role of the Paf1C component Rtf1, which is critical for H3K4 and H3K79 methylations, for the regulation of meiotic DSB formation. Similar to set1 mutation, rtf1 mutation decreased the occurrence of DSBs in the genome. The rtf1 set1 double mutant exhibited a larger reduction in the levels of DSBs than the frequency of DSBs detected in either of the single mutants; this indicates independent roles of Rtf1 and Set1 in DSB formation. Importantly, the distribution of DSBs along chromosomes in the rtf1 mutant changed in a different manner than the pattern observed in the set1 and set1 dot1 mutants; this was characterized by enhanced DSB formation at some DSB-cold regions. These observations suggest that Rtf1, and, possibly, the Paf1C, determine DSB landscape in the genome, independent of H3K4 methylation.

Project description:The methylation of histone H3 lysine 79 (H3K79) acts as an active chromatin marker and is enriched in actively transcribed regions of the genome. However, demethylase of this mark remains unknown despite intensive research. Here, we show that KDM2B (FBXL10), a member of the Jumonji C (JmjC) family of proteins and previously known for its histone H3K36 demethylase activity, is a di- and trimethyl H3K79 demethylase. We demonstrate that KDM2B induces transcriptional repression of HOXA7 and MEIS1 via occupancy of promoters and demethylation of H3K79. Furthermore, genome-wide analysis suggests that H3K79 methylation levels are increased when KDM2B is depleted, suggesting that KDM2B functions as an H3K79 demethylase in vivo. Finally, stable KDM2B-knockdown cell lines exhibited displacement of SIRT1, with concomitant increases in H3K79 methylation and H4K16 acetylation. Our findings identify KDM2B as an H3K79 demethylase and link its function to transcriptional repression via SIRT1-mediated chromatin silencing.

Project description:Methylation of histone H3 lysine 4 (H3K4) by the Set1/COMPASS complex is coupled with active transcription, and this modification is important for regulating gene expression. Set1/COMPASS associates with the RNA polymerase II (RNApII) C-terminal domain (CTD) to establish proper levels and distribution of H3K4 methylations.To ask how the Set1-RNApII CTD binding affects the occupancy and overall level of H3K4 methylations, ChIP-Seq was pefromed in cells transformed with full length or N-terminal truncated Set1. Our results indicate that Set1-RNApII CTD interaction is necessary for maintaining H3K4 methylations throughout the genes.

Project description:A hallmark of genes transcribed by RNA polymerase II (RNApII) is a "gradient" of histone H3 lysine 4 (H3K4) methylation. Various factors differentially bind to H3K4me3 near promoters, H3K4me2 just downstream, and H3K4me1 further downstream to modulate gene expression. Set1/COMPASS, the single S. cerevisiae H3K4 methyltransferase, binds transcribing RNApII, but COMPASS may also be allosterically regulated by specific subunits and histone H2B ubiquitylation. To ask whether differential H3K4 methylation is determined by regulated activity at specific gene locations or by the amount of time COMPASS spends near the nucleosome, ChIP-Seq analyses was performed in cells with altered transcription elongation rates or with Set1 fused to RNApII. Our results support a simple model where higher H3K4 methylations result from both increased duration and frequency of COMPASS proximity to the nucleosome.

Project description:PARP-1 binds to specific nucleosomes to regulate gene activity. While PARP-1's role in transcription inititaion is known, a surprising finding here was that PARP-1 is highly enriched at exon-intron and intron-exon boundaries, sort of demarcting exons. This indicating a role in alternative splicing.

Project description:PARP-1 binds to specific nucleosomes to regulate gene activity. While PARP-1's role in transcription inititaion is known, a surprising finding here was that PARP-1 is highly enriched at exon-intron and intron-exon boundaries, sort of demarcting exons. Thius indicating a role in alternative splicing.

Project description:How the splicing machinery defines exons or introns as the spliced unit has remained a puzzle for 30 years. Here we demonstrate that peripheral and central regions of the nucleus harbor genes with two distinct exon-intron GC content architectures that differ in the splicing outcome. Genes with low GC content exons, flanked by long introns with lower GC content, are localized in the periphery, and the exons are defined as the spliced unit. Alternative splicing of these genes results in exon skipping. In contrast, the nuclear center contains genes with a high GC content in the exons and short flanking introns. Most splicing of these genes occurs via intron definition, and aberrant splicing leads to intron retention. We demonstrate that the nuclear periphery and center generate different environments for the regulation of alternative splicing, and that two sets of splicing factors form discrete regulatory subnetworks for the two gene architectures. Our study connects 3D genome organization and splicing, thus demonstrating that exon and intron definition modes of splicing occur in different nuclear regions.