Project description:Domains of heterochromatin play important roles in the maintenance and regulation of eukaryotic genomes. However, the repressive nature of heterochromatin combined with its propensity to self-propagate necessitates the existence of robust mechanisms that limit heterochromatin spreading and thereby avoid silencing of expressed genes. A number of specific sequence elements have been found to serve as barriers to heterochromatin spreading; however, the mechanisms by which spreading is curtailed are generally not well understood. Here we uncover a role for PAF complex component Leo1 in regulating heterochromatin cis-spreading. A genetic screen revealed that loss of Leo1 results in spreading of heterochromatin across a centromeric (IRC) boundary element in fission yeast. Similar heterochromatin spreading was seen upon deletion of other components of the PAF complex, but not other factors involved in transcription-coupled chromatin modification, indicating a specific role for the PAF complex in heterochromatin regulation. Loss of Leo1 is associated with reduced levels of H4K16 acetylation at the boundary, while tethering of the H4K16 acetyltransferase Mst1 to boundary chromatin suppresses heterochromatin spreading in leo1? cells, suggesting that Leo1 antagonises heterochromatin spreading by facilitating H4K16 acetylation. Interestingly, Leo1 also regulates heterochromatin spreading independently of boundaries, and loss of Leo1 causes redistribution of heterochromatin, in particular resulting in substantial expansion of telomeric heterochromatin domains. The PAF complex is known to be an important regulator of transcription-related chromatin modifications; our findings reveal a previously undescribed role for this complex in global regulation of heterochromatin spreading in cis. 8 samples: input (whole cell extract) and IP from H3K9me2 ChIP in wild-type and leo1? cells, in duplicate

Project description:Heterochromatin spreading leads to the silencing of genes within its path, and boundary elements have evolved to constrain such spreading. In fission yeast, heterochromatin at centromeres I and III is flanked by inverted repeats termed IRCs, which are required for proper boundary functions. However, the mechanisms by which IRCs prevent heterochromatin spreading are unknown. Here, we identified Bdf2, homologous to the mammalian BET family of double bromodomain proteins involved in diverse types of cancers, as a factor required for proper boundary function at IRCs. Bdf2 is enriched at IRCs through its interaction with the boundary protein Epe1. The bromodomains of Bdf2 recognize acetylated histone H4 tails and antagonize Sir2-mediated deacetylation of histone H4K16 to prevent heterochromatin spreading. Our results thus illustrate a mechanism of establishing chromosome boundaries at specific sites through the recruitment of a factor that protects euchromatic histone modifications. They also reveal a previously unappreciated function of H4K16 acetylation, which cooperates with H3K9 methylation to regulate heterochromatin spreading. Two samples, H4K16ac & Bdf2-Flag

Project description:Heterochromatin spreading leads to the silencing of genes within its path, and boundary elements have evolved to constrain such spreading. In fission yeast, heterochromatin at centromeres I and III is flanked by inverted repeats termed IRCs, which are required for proper boundary functions. However, the mechanisms by which IRCs prevent heterochromatin spreading are unknown. Here, we identified Bdf2, homologous to the mammalian BET family of double bromodomain proteins involved in diverse types of cancers, as a factor required for proper boundary function at IRCs. Bdf2 is enriched at IRCs through its interaction with the boundary protein Epe1. The bromodomains of Bdf2 recognize acetylated histone H4 tails and antagonize Sir2-mediated deacetylation of histone H4K16 to prevent heterochromatin spreading. Our results thus illustrate a mechanism of establishing chromosome boundaries at specific sites through the recruitment of a factor that protects euchromatic histone modifications. They also reveal a previously unappreciated function of H4K16 acetylation, which cooperates with H3K9 methylation to regulate heterochromatin spreading.

Project description:Maintenance of open and repressed chromatin states is crucial for regulation of gene expression. To study the genes involved in maintaining chromatin states we generated a random mutant library using the Hermes transposon mutagenesis system in fission yeast Schizosacchromyces pombe. The silencing of reporter genes inserted in the euchromatic region adjacent to the heterochromatic mating type locus was monitored. We identified Leo1-Paf1, a subcomplex of the RNA Polymerase II Associated Factor 1 Complex (Paf1C), required to prevent spreading of heterochromatin into euchromatin. Through high-resolution genome-wide ChIP (ChIP-exo) we mapped the heterochromatin mark H3K9me2 in leo1∆ cells. Loss of Leo1-Paf1 led to increased heterochromatin stability at several facultative heterochromatin loci. The RNAi machinery is the major pathway for heterochromatin formation in S. pombe. However, small RNA sequencing showed that heterochromatin assembly in leo1∆ cells was RNAi-independent. By examining histone turnover rate in leo1∆ cells, we showed that deletion of Leo1 decreased nucleosome turnover, which led to heterochromatin spreading. Our data revealed that Leo1-Paf1 promotes chromatin state fluctuations by enhancing histone turnover.

Project description:Maintenance of open and repressed chromatin states is crucial for regulation of gene expression. To study the genes involved in maintaining chromatin states we generated a random mutant library using the Hermes transposon mutagenesis system in fission yeast Schizosacchromyces pombe. The silencing of reporter genes inserted in the euchromatic region adjacent to the heterochromatic mating type locus was monitored. We identified Leo1-Paf1, a subcomplex of the RNA Polymerase II Associated Factor 1 Complex (Paf1C), required to prevent spreading of heterochromatin into euchromatin. Through high-resolution genome-wide ChIP (ChIP-exo) we mapped the heterochromatin mark H3K9me2 in leo1∆ cells. Loss of Leo1-Paf1 led to increased heterochromatin stability at several facultative heterochromatin loci. The RNAi machinery is the major pathway for heterochromatin formation in S. pombe. However, small RNA sequencing showed that heterochromatin assembly in leo1∆ cells was RNAi-independent. By examining histone turnover rate in leo1∆ cells, we showed that deletion of Leo1 decreased nucleosome turnover, which led to heterochromatin spreading. Our data revealed that Leo1-Paf1 promotes chromatin state fluctuations by enhancing histone turnover.

Project description:Both H3K9me3 and DNA methylation are subject to spreading mechanisms to effectively cover incipient chromatin across heterochromatin domains. Boundary elements and associated limiting factors are necessary to prevent heterochromatin from spreading into neighboring, gene-rich heterochromatin. LSD1 was identified to be one such factor, given previous studies in other models and high conservation throughout eukaryotes. This study identifies the LSD complex in Neurospora and characterizes the heterochromatin spreading defect in Neurospora crassa ∆lsd1 strains. We found ∆lsd1 strains to possess variable extents of excessive heterochromatin spreading, and that this is dependent on the presence of DNA methylation, unlike at canonical heterochromatin domains where loss of DNA methylation has no effect on the presence of other heterochromatin marks (H3K9me3 and HP1-binding). Our findings provide insight of LSD1 function in heterochromatin regulation.

Project description:The MYST HAT Sas2 is part of the SAS-I complex. The target for acetylation by Sas2 is Lys16 of histone H4 (H4 K16Ac). This acetylation site marks euchromatic regions and opposes the spreading of heterochromatin at telomere-proximal regions. Changes of SAS-I-mediated H4 K16Ac on a genome-wide scale comparing wt and sas2M-bM-^HM-^F cells were investigated in this study. We found a pronounced, genome-wide loss of H4 K16 acetylation in the body of transcribed genes in the absence of Sas2. Furthermore, the influence of Sas2 on gene expression was investigated in RNA expression arrays. H4 K16Ac and H4 in wt and sas2M-bM-^HM-^F was ChIPed. ChIP experiments were performed three times with independent chromatin preparations.

Project description:Leo1 is a Global Regulator of Heterochromatin Cis-spreading

Project description:The MYST HAT Sas2 is part of the SAS-I complex. The target for acetylation by Sas2 is Lys16 of histone H4 (H4 K16Ac). This acetylation site marks euchromatic regions and opposes the spreading of heterochromatin at telomere-proximal regions. Changes of SAS-I-mediated H4 K16Ac on a genome-wide scale comparing wt and sas2∆ cells were investigated in this study. We found a pronounced, genome-wide loss of H4 K16 acetylation in the body of transcribed genes in the absence of Sas2. Furthermore, the influence of Sas2 on gene expression was investigated in RNA expression arrays.

Project description:Chromosomes must correctly fold in eukaryotic nuclei for proper genome function. Eukaryotic organisms hierarchically organize their genomes: in the fungus Neurospora crassa, chromatin fiber loops compact into Topologically Associated Domain (TAD)-like structures that are anchored by heterochromatic region aggregates. However, insufficient information exists on how histone post-translational modifications, including acetylation, impact genome organization. In Neurospora, the HCHC (HDA-1, CDP-2, HP1, CHAP) complex deacetylates heterochromatic regions including centromeres: loss of individual HCHC members increases centromeric acetylation and cytosine methylation. Here, we evaluate the role of the HCHC complex on genome organization using chromosome conformation capture with high-throughput sequencing (Hi-C) in Δcdp-2 or Δchap deletion strains. CDP-2 loss increases interactions between intra- and inter-chromosomal heterochromatic regions, while removal of CHAP decreases heterochromatic region compaction. Individual HCHC mutants exhibit different histone PTM patterns genome-wide: in Dcdp-2, heterochromatic H4K16 acetylation is increased, yet some heterochromatic regions lose H3K9 trimethylation, which locally increases inter-heterochromatin contacts; CHAP loss produces minimal acetylation changes but increases H3K9me3 enrichment in heterochromatin. Furthermore, deletion of the DIM-2 DNA methyltransferase in a Δcdp-2 background causes extensive genome disorder, as heterochromatic-euchromatic contacts increase despite additional H3K9me3 enrichment. Our results highlight how enhanced cytosine methylation ensures heterochromatic compartmentalization when silenced regions are acetylated.