Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Hda1C directly binds to actively transcribed regions likely via the interaction with elongating RNA PolII and/or with nascent RNA transcripts. The Arb2 domain of Hda1 is also critical for its binding to chromatin. Interestingly, Hda1C specifically deacetylates histone H4 but not H3 at active genes to suppress nucleosome instability and partially inhibit elongation. In contrast, Hda1C mainly deacetylates histone H3 at inactive genes to delay gene induction.

Project description:Hda1C directly binds to actively transcribed regions likely via the interaction with elongating RNA PolII and/or with nascent RNA transcripts. The Arb2 domain of Hda1 is also critical for its binding to chromatin. Interestingly, Hda1C specifically deacetylates histone H4 but not H3 at active genes to suppress nucleosome instability and partially inhibit elongation. In contrast, Hda1C mainly deacetylates histone H3 at inactive genes to delay gene induction.

Project description:Transcription-dependent targeting of Hda1C to hyperactive genes mediates H4-specific deacetylation in yeast

Project description:Transcription-dependent targeting of Hda1C to hyperactive genes mediates H4-specific deacetylation in yeast (ChIP-seq)

Project description:Transcription-dependent targeting of Hda1C to hyperactive genes mediates H4-specific deacetylation in yeast (RNA-seq)

Project description:Xbp1 has been shown to regulate the cell cycle as a transcriptional repressor in budding yeast Saccharomyces cerevisiae. In this study, we demonstrated that Xbp1 regulates DNA double-strand break (DSB) repair in S. cerevisiae. Xbp1 physically and genetically interacts with the histone deacetylase Rpd3 complex. Chromatin immunoprecipitation revealed that Xbp1 is required for efficient deacetylation of histone H4 flanking DSBs by the Rpd3 complex. Deletion of XBP1 leads to the delayed deacetylation of histone H4, which is coupled with increased nucleosome displacement, increased DNA end resection and decreased non-homologous end-joining (NHEJ). In response to DNA damage, Xbp1 is upregulated in a Mec1-Rad9-Rad53 checkpoint pathway-dependent manner and undergoes dephosphorylation. Cdk1, a central regulator of S. cerevisiae cell cycle, is responsible for Xbp1 phosphorylation at residues Ser146, Ser271 and Ser551. Substitution of these serine residues with alanine not only increases the association of Xbp1 with the Rpd3 complex and its recruitment to a DSB, but also promotes DSB repair. Together, our findings reveal a role for Xbp1 in DSB repair via NHEJ through regulation of histone H4 acetylation and nucleosome displacement in a positive feedback manner.

Project description:Hsp70 is a highly conserved molecular chaperone critical for the folding of new and denatured proteins. While traditional models state that cells respond to stress by upregulating inducible HSPs, this response is relatively slow and is limited by transcriptional and translational machinery. Recent studies have identified a number of post-translational modifications (PTMs) on Hsp70 that act to fine-tune its function. We utilized mass spectrometry to determine whether yeast Hsp70 (Ssa1) is differentially modified upon heat shock. We uncovered four lysine residues on Ssa1, K86, K185, K354 and K562 that are deacetylated in response to heat shock. Mutation of these sites cause a substantial remodeling of the Hsp70 interaction network of co-chaperone partners and client proteins while preserving essential chaperone function. Acetylation/deacetylation at these residues alter expression of other heat-shock induced chaperones as well as directly influencing Hsf1 activity. Taken together our data suggest that cells may have the ability to respond to heat stress quickly though Hsp70 deacetylation, followed by a slower, more traditional transcriptional response.

Project description:The Forkhead transcription factor FOXA2 plays a fundamental role in controlling metabolic homeostasis in the liver during fasting. The precise molecular regulation of FOXA2 in response to nutrients is not fully understood. Here, we studied whether FOXA2 could be controlled at a post-translational level by acetylation. By means of LC-MS/MS analyses, we identified five acetylated residues in FOXA2. Sirtuin family member SIRT1 was found to interact with and deacetylate FOXA2, the latter process being dependent on the NAD+-binding catalytic site of SIRT1. Deacetylation by SIRT1 reduced protein stability of FOXA2 by targeting it towards proteasomal degradation, and inhibited transcription from the FOXA2-driven G6pase and CPT1a promoters. While mutation of the five identified acetylated residues weakly affected protein acetylation and stability, mutation of at least seven additional lysine residues was required to abolish acetylation and reduce protein levels of FOXA2. The importance of acetylation of FOXA2 became apparent upon changes in nutrient levels. The interaction of FOXA2 and SIRT1 was strongly reduced upon nutrient withdrawal in cell culture, while enhanced Foxa2 acetylation levels were observed in murine liver in vivo after starvation for 36 hours. Collectively, this study demonstrates that SIRT1 controls the acetylation level of FOXA2 in a nutrient-dependent manner and in times of nutrient shortage the interaction between SIRT1 and FOXA2 is reduced. As a result, FOXA2 is protected from degradation by enhanced acetylation, hence enabling the FOXA2 transcriptional program to be executed to maintain metabolic homeostasis.

Project description:Eukaryotic chromatin is composed of nucleosomes, which contain nearly two coils of DNA wrapped around a central histone octamer. The octamer contains an H3-H4 tetramer and two H2A-H2B dimers. Gene activation is associated with chromatin disruption: a wider nucleosome-depleted region (NDR) at the promoter and reduced nucleosome occupancy over the coding region. Here, we examine the nature of disrupted chromatin after induction, using MNase-seq to map nucleosomes and subnucleosomes, and a refined high-resolution ChIP-seq method to map H4, H2B and RNA polymerase II (Pol II) genome-wide. Over coding regions, induced genes show a differential loss of H2B relative to H4, which correlates with Pol II density and the appearance of subnucleosomes. After induction, Pol II is surprisingly low at the promoter, but accumulates on the gene and downstream of the termination site, implying that dissociation is very slow. Thus, induction-dependent chromatin disruption reflects both eviction of H2A-H2B dimers and the presence of queued Pol II elongation complexes. We propose that slow Pol II dissociation after transcription is a major factor in chromatin disruption and that it may be of critical importance in gene regulation.