Project description:Set2 co-transcriptionally methylates lysine 36 of histone H3 (H3K36), producing mono-, di-, and trimethylation (H3K36me1/2/3). These modifications recruit or repel chromatin effector proteins important for transcriptional fidelity, mRNA splicing, and DNA repair. However, it was not known whether the different methylation states of H3K36 have distinct biological functions. Here, we use engineered forms of Set2 that produce different lysine methylation states to identify unique and shared functions for H3K36 modifications. Although H3K36me1/2 and H3K36me3 are functionally redundant in many SET2 deletion phenotypes, we found that H3K36me3 has a unique function related to Bur1 kinase activity and FACT (facilitates chromatin transcription) complex function. Further, during nutrient stress, either H3K36me1/2 or H3K36me3 represses high levels of histone acetylation and cryptic transcription that arises from within genes. Our findings uncover the potential for the regulation of diverse chromatin functions by different H3K36 methylation states.

Project description:Set2-mediated H3K36 methylation states redundantly repress the production of antisense transcripts:: role in transcription regulation

Project description:In budding yeast, Set2 catalyzes di- and trimethylation of H3K36 (H3K36me2 and H3K36me3) via an interaction between its SRI domain and C-terminal repeats of RNA polymerase II (Pol2) phosphorylated at Ser2 and Ser5 (CTD-S2,5-P). H3K36me2 recruits the Rpd3S histone deacetylase complex to repress cryptic transcription from transcribed regions. In fission yeast, Set2 is also responsible for H3K36 methylation, which represses a subset of RNAs including heterochromatic and subtelomeric RNAs, at least in part via recruitment of Clr6 complex II, a homolog of Rpd3S. Here, we show that CTD-S2P–dependent interaction of fission yeast Set2 with Pol2 via the SRI domain is required for formation of H3K36me3, but not H3K36me2. H3K36me3 silenced heterochromatic and subtelomeric transcripts through post-transcriptional and transcriptional mechanisms, respectively, whereas H3K36me2 did not. Clr6 complex II appeared not to be responsible for heterochromatic silencing. Our results demonstrate that H3K36 methylation has multiple outputs in fission yeast; these findings provide insight into the multiple roles of H3K36 methylation in metazoans, which have different enzymes for synthesis of H3K36me1/2 and H3K36me3. Gene expression profile at exponentially-growing phase.in the fission yeast deletion mutants of set2.

Project description:In budding yeast, Set2 catalyzes di- and trimethylation of H3K36 (H3K36me2 and H3K36me3) via an interaction between its SRI domain and C-terminal repeats of RNA polymerase II (Pol2) phosphorylated at Ser2 and Ser5 (CTD-S2,5-P). H3K36me2 recruits the Rpd3S histone deacetylase complex to repress cryptic transcription from transcribed regions. In fission yeast, Set2 is also responsible for H3K36 methylation, which represses a subset of RNAs including heterochromatic and subtelomeric RNAs, at least in part via recruitment of Clr6 complex II, a homolog of Rpd3S. Here, we show that CTD-S2P–dependent interaction of fission yeast Set2 with Pol2 via the SRI domain is required for formation of H3K36me3, but not H3K36me2. H3K36me3 silenced heterochromatic and subtelomeric transcripts through post-transcriptional and transcriptional mechanisms, respectively, whereas H3K36me2 did not. Clr6 complex II appeared not to be responsible for heterochromatic silencing. Our results demonstrate that H3K36 methylation has multiple outputs in fission yeast; these findings provide insight into the multiple roles of H3K36 methylation in metazoans, which have different enzymes for synthesis of H3K36me1/2 and H3K36me3.

Project description:The transcription elongation factor Spt6 and the H3K36 methyltransferase Set2 are both required for H3K36 methylation and transcriptional fidelity in Saccharomyces cerevisiae. By selecting for suppressors of a transcriptional defect in an spt6 mutant, we have isolated dominant SET2 mutations (SET2sup mutations) in a region encoding a proposed autoinhibitory domain. The SET2sup mutations suppress the H3K36 methylation defect in the spt6 mutant, as well as in other mutants that impair H3K36 methylation. ChIP-seq studies demonstrate that the H3K36 methylation defect in the spt6 mutant, as well as its suppression by a SET2sup mutation, occur at a step following the recruitment of Set2 to chromatin. Other experiments show that a similar genetic relationship between Spt6 and Set2 exists in Schizosaccharomyces pombe. Taken together, our results suggest a conserved mechanism by which the Set2 autoinhibitory domain requires multiple interactions to ensure that H3K36 methylation occurs specifically on actively transcribed chromatin.

Project description:Set2-mediated methylation of H3K36 (H3K36me) regulates a diverse number of activities including DNA repair, mRNA splicing and the suppression of inappropriate or ‘cryptic’ transcription. Here, we describe an unexpected connection between Set2-mediated H3K36me and the regulation of nutrient stress response. We find cells deleted for SET2 (set2∆) are sensitive to inhibitors of Tor1, Tor2 and MAP kinase pathways that regulate the nutrient response pathway. Further genetic and biochemical analyses confirm a role for Set2-mediated H3K36me in nutrient stress response. At the molecular level, set2∆ cells demonstrate a dysregulated genome-wide transcriptional response to nutrient stress. Remarkably, newly initiated and bi-directional transcription events within the bodies of genes develop in set2∆ cells during nutrient stress. Importantly, these antisense transcripts extend into the promoters of the genes they arise from, resulting in pervasive transcriptional interference. Our results suggest that Set2-enforced transcriptional fidelity is critical to the proper regulation highly-tuned transcription programs.

Project description:Selective suppression of antisense transcription by Set2-mediated H3K36 methylation

Project description:In yeast and other eukaryotes, the histone methyltransferase Set1 mediates methylation of lysine 4 on histone H3 (H3K4me). This modification marks the 5' end of transcribed genes in a 5' to 3' tri- to di- to monomethyl gradient, and promotes association of chromatin remodeling enzymes that regulate transcription. In a screen to identify factors that control the distinct H3K4 methylation states, we identified Ctk1, the serine 2 C-terminal domain (CTD) kinase for RNA polymerase II (RNAP II). We found that CTK1 deletion nearly abolished H3K4 monomethylation, yet caused a significant increase in H3K4 di- and trimethylation. Both on individual genes and genome-wide, the loss of CTK1 disrupted the H3K4 methylation patterns normally observed. H3K4me2 and H3K4me3 spread 3' into the body of genes, while H3K4 monomethylation was diminished. These effects were dependent on the catalytic activity of Ctk1, but are independent of Set2-mediated H3K36 methylation. Furthermore, these effects are not due to spurious transcription initiation in the body of genes, changes in RNAP II occupancy, changes in serine 5 CTD phosphorylation patterns, or to ‘transcriptional stress’. These data show that Ctk1 acts to restrict the spread of H3K4 methylation through a mechanism that is independent of a general transcription defect. The evidence presented indicates that Ctk1 controls the maintenance of suppressive chromatin in the coding regions of genes by both promoting H3K36 methylation, which leads to histone hypoacetylation, and by preventing the 3' spread of H3K4 trimethylation, a mark associated with chromatin remodeling at the 5' end of genes. Keywords: ChIP-chip

Project description:Histone tails are post-translationally modified at multiple sites, including Lys36 on histone H3 (H3K36). The H3K36 methylation has been shown to associate with the transcription of active euchromatin, alternative splicing, DNA repair and recombination. However, the role of H3K36 methylation during cell differentiation is still obscure.Previous investigations found that a site specific Lys-to-Met mutation on histones can serve as an inhibitor of this site specific methyltransferases to repress global methylation on that lysine of histones. In this study we usedH3K36 Lys-to-Met mutant (H3K36M) as a tool to investigaterole of H3K36 methylation in our cell differentiation system. Expression of H3K36M repressed global H3K36 methylation but increased H3K27me3 as previously reported. On our cell differentiation system, H3K36M suppressed adipogenesis and myogenesis. Our pioneer RNA-seqstudy further showed that H3K36M repressed the expression of master regulator genes. Here, we did ChIP-seq of several histone modifications to further explore the changes on the epigenome by expression of H3K36M. Interestingly, on some important master regulator genes loci, the repressive marker H3K27me3 increased significantly, correlated with the repression on their expression. The H3K36M decreases global H3K36 di- and tri-methylation. To clarify which H3K36 methyltransferase is important for cell differentiation, we knocked down H3K36 di-methyltransferases Nsd1 and Nsd2, H3K36 tri-methyltransferase Setd2 separately. Nsd2 knockdown, but not Nsd1 or Setd2,can phenocopythe adipogenesis defect in H3K36M expressed cells.Comparing in RNA-seq results, Nsd2 knockdown cells showed similar gene expression profile with H3K36M expressed cells in adipogenesis. These suggest that Nsd2-mediated H3K36me2 plays an important role in adipogenesis.To study the role of H3K36 methylation in vivo, we generated an aP2 promoter driven H3K36M expressed transgenic mouse (Tg), to express H3K36M specifically in adipose tissue. The Tg mice showedsignificant dysfunction in both white and brown adipose tissues. Their fat tissues gene expression profile changed significantly. All of these indicate that H3K36 methylation is important for adipose tissue developmentin vivo.Together, our comprehensive studies provide novel insights into dynamics of H3K36 methylation and its important role in transcriptional regulation of cell differentiation and mouse fat tissue development.

Project description:Histone lysine methylation is a key epigenetic modification that regulates eukaryotic transcription. In Saccharomyces cerevisiae, it is controlled by a reduced but evolutionarily conserved suite of methyltransferase (Set1p, Set2p, Dot1p, and Set5p) and demethylase (Jhd1p, Jhd2p, Rph1p, and Gis1p) enzymes. Many of these enzymes are extensively phosphorylated in vivo; however, the functions of specific phosphosites are poorly understood. Here, we comprehensively investigate the phosphoregulation of the yeast histone methylation network by analysing 40 phosphosites on six enzymes through mutagenesis. A total of 82 genomically-edited S. cerevisiae strains were generated and screened for changes in native H3K4, H3K36, and H3K79 methylation levels, and for sensitivity to environmental stress conditions. This demonstrated the functional relevance of phosphosites on methyltransferase Set2p (S6, S8, S10, and T127) and demethylase Jhd1p (S44) in the regulation of H3K36 methylation in vivo, and in the coordination of specific stress response pathways in budding yeast. Proteomic analysis of SET2 mutants revealed that phosphorylation site mutations lead to significant downregulation of membrane-associated proteins and processes, consistent with changes brought about by SET2 deletion. This study represents the first systematic investigation into the phosphoregulation of an entire epigenetic network in any eukaryote, and our findings establish phosphorylation as an important regulator of histone lysine methylation in S. cerevisiae.