Project description:Meiotic recombination is initiated by developmentally programmed DNA double-strand breaks (DSBs). In S. cerevisiae, the vast majority of DSBs occur in the nucleosome-depleted regions at gene promoters, where transcription factors (TFs) bind. It has been proposed that TF binding can stimulate DSB formation nearby by modulating local chromatin structure. However, a prior study in TF bas1 mutant suggested that the role of TF binding in determining break formation is complex. Here, we examined fine-scale DSB distributions in TF mutant (bas1Δ and ino4Δ) strains. In bas1Δ mutants, 239 out of the 2468 hotspots showed reduced DSB activity, whereas 87 hotspots showed increased DSB activity. Similarly, in ino4Δ mutant, 415 out of the 2468 hotspots showed reduced DSB activity, whereas 322 hotspots showed increased DSB activity. We also mapped Bas1 and Ino4 binding sites in meiosis and found that only a small portion of the affected hotspots contained TF binding sites. This indicates that TF can influence DSB distribution both directly and indirectly. Surprisingly, these DSB changes in TF mutants did not correlate with change in chromatin structure and histone H3K4me3 modification, suggesting that the role of TF on DSB distribution cannot be simply explained by affecting local chromatin status. Twelve samples total: four wild type, four bas1 mutant and four ino4 mutant (each an independent culture has one H3K4me3 ChIP sample and one H3 ChIP sample)
Project description:Meiotic recombination is initiated by developmentally programmed DNA double-strand breaks (DSBs). In S. cerevisiae, the vast majority of DSBs occur in the nucleosome-depleted regions at gene promoters, where transcription factors (TFs) bind. It has been proposed that TF binding can stimulate DSB formation nearby by modulating local chromatin structure. However, a prior study in TF bas1 mutant suggested that the role of TF binding in determining break formation is complex. Here, we examined fine-scale DSB distributions in TF mutant (bas1Δ and ino4Δ) strains. In bas1Δ mutants, 239 out of the 2468 hotspots showed reduced DSB activity, whereas 87 hotspots showed increased DSB activity. Similarly, in ino4Δ mutant, 415 out of the 2468 hotspots showed reduced DSB activity, whereas 322 hotspots showed increased DSB activity. We also mapped Bas1 and Ino4 binding sites in meiosis and found that only a small portion of the affected hotspots contained TF binding sites. This indicates that TF can influence DSB distribution both directly and indirectly. Surprisingly, these DSB changes in TF mutants did not correlate with change in chromatin structure and histone H3K4me3 modification, suggesting that the role of TF on DSB distribution cannot be simply explained by affecting local chromatin status. Four samples total: Bas1-Myc (ChIP and input samples), Ino4-Myc (ChIP and input samples)
Project description:Project abstract : The trimethylation of histone H3 lysine 4 (H3K4me3) is a crucial factor in defining the promoter regions of active genes in all eukaryotes ranging from Saccharomyces cerevisiae (yeast) to humans. In budding yeast, this trimethylation process facilitated by the Set1 complex results in H3K4me3 requiring a prior mono-ubiquitination at the histone H2BK123 residue (H2Bub) by E2 enzyme Rad6 and E3 enzyme Bre1. A previous in vitro study suggested that ubiquitinated H2B directly facilitates H3K4me3. However, even low levels of global H2Bub is sufficient for the required H3K4me3 in yeast cells, thereby indicating that other factors resulting in the H2Bub-dependent H3K4me3 remain unknown. This study revealed the high level of correlation of H3K4me3 with chromatin recruitment of Rad6 at the genome-wide level. Rad6 is confirmd to interact and co-localize with Swd2/Cps35, a key factor for the H2Bub-dependent H3K4me3 in genes with high levels of H3K4me3 and intronic genes rather than non-intronic genes. This study therefore provides a mechanistic insight of the H2Bub-Rad6- Swd2/Cps35-H3K4me3 axis and its potential role in RNA biogenesis.
Project description:Meiotic recombination is initiated by developmentally programmed DNA double-strand breaks (DSBs). In S. cerevisiae, the vast majority of DSBs occur in the nucleosome-depleted regions at gene promoters, where transcription factors (TFs) bind. It has been proposed that TF binding can stimulate DSB formation nearby by modulating local chromatin structure. However, a prior study in TF bas1 mutant suggested that the role of TF binding in determining break formation is complex. Here, we examined fine-scale DSB distributions in TF mutant (bas1Δ and ino4Δ) strains. In bas1Δ mutants, 239 out of the 2468 hotspots showed reduced DSB activity, whereas 87 hotspots showed increased DSB activity. Similarly, in ino4Δ mutant, 415 out of the 2468 hotspots showed reduced DSB activity, whereas 322 hotspots showed increased DSB activity. We also mapped Bas1 and Ino4 binding sites in meiosis and found that only a small portion of the affected hotspots contained TF binding sites. This indicates that TF can influence DSB distribution both directly and indirectly. Surprisingly, these DSB changes in TF mutants did not correlate with change in chromatin structure and histone H3K4me3 modification, suggesting that the role of TF on DSB distribution cannot be simply explained by affecting local chromatin status. Nine samples total: two wild type, four bas1 mutant and three ino4 mutant (each an independent culture)