Project description:Evidence suggests that the TAF1 subunit of TFIID is a histone acetyltransferase (HAT) that is functionally redundant with the Gcn5 HAT of the SAGA and ADA complexes. Here we test a number of predictions of this hypothesis by examining the in vivo histone acetylation targets of TAF1 and Gcn5, and re-examining the basis for the reported genome-wide functional redundancy between TAF1 and Gcn5. Our findings do not support a number of basic tenets of the hypothesis, thus bringing into question the physiological presence of any TAF1 HAT function in yeast. We have also conducted genome-wide expression profiles of numerous other HATs (Elp3, Hat1, Hpa2, Sas3) in an effort identify potential functional redundancy between TAF1 and other HATs, and find none. Further investigation of TAF1 and the Esa1 HAT re-affirm a link between histone H4 acetylation by Esa1, and TFIID binding via interactions with acetylated histone H4-binding protein Bdf1. Keywords: ChIP-chip, genetic modification

Project description:Evidence suggests that the TAF1 subunit of TFIID is a histone acetyltransferase (HAT) that is functionally redundant with the Gcn5 HAT of the SAGA and ADA complexes. Here we test a number of predictions of this hypothesis by examining the in vivo histone acetylation targets of TAF1 and Gcn5, and re-examining the basis for the reported genome-wide functional redundancy between TAF1 and Gcn5. Our findings do not support a number of basic tenets of the hypothesis, thus bringing into question the physiological presence of any TAF1 HAT function in yeast. We have also conducted genome-wide expression profiles of numerous other HATs (Elp3, Hat1, Hpa2, Sas3) in an effort identify potential functional redundancy between TAF1 and other HATs, and find none. Further investigation of TAF1 and the Esa1 HAT re-affirm a link between histone H4 acetylation by Esa1, and TFIID binding via interactions with acetylated histone H4-binding protein Bdf1. Keywords: genetic modification

Project description:The nucleosome remodeling complex RSC functions throughout the yeast genome to set the positions of -1 and +1 nucleosomes and thereby determines the widths of nucleosome-depleted regions (NDRs). The related complex SWI/SNF participates in nucleosome remodeling/eviction and promoter activation at certain yeast genes, including those activated by transcription factor Gcn4, but does not appear to function broadly in establishing NDRs. By analyzing the large cohort of Gcn4-induced genes in mutants lacking the catalytic subunits of SWI/SNF or RSC, we uncovered cooperation between these remodelers in evicting nucleosomes from different locations in the promoter and in repositioning the +1 nucleosome downstream to produce wider NDRs, highly depleted of nucleosomes, during transcriptional activation. SWI/SNF also functions on par with RSC at the most highly transcribed constitutively expressed genes, suggesting general cooperation by these remodelers for maximal transcription. SWI/SNF and RSC occupancies are greatest at the most highly expressed genes, consistent with their cooperative functions in nucleosome remodeling and transcriptional activation. Thus, SWI/SNF acts comparably to RSC in forming wide, nucleosome-free NDRs to achieve high-level transcription, but only at the most highly expressed genes exhibiting the greatest SWI/SNF occupancies.

Project description:RSC (remodels the structure of chromatin) is an essential ATP-dependent chromatin remodeling complex in Saccharomyces cerevisiae. The catalytic subunit of RSC, Sth1 uses its ATPase activity to slide or remove nucleosomes. RSC has been shown to regulate the width of the nucleosome-depleted regions (NDRs) by sliding the flanking nucleosomes away from NDRs. As such the nucleosomes encroach NDRs when RSC is depleted and leads to transcription initiation defects. In this study, we examined the effects of the catalytic-dead Sth1 on transcription and compared them to the effects observed during acute and rapid Sth1 depletion by auxin-induced degron strategy. We found that rapid depletion of Sth1 reduces recruitment of TBP and Pol II in highly transcribed genes, as would be expected considering its role in regulating chromatin structure at promoters. In contrast, cells harboring the catalytic-dead Sth1 exhibited a severe reduction in TBP binding, but surprisingly, also displayed a substantial accumulation in Pol II occupancies within coding regions. After depleting endogenous Sth1 in the catalytic dead mutant, we observed a further increase in Pol II occupancies, suggesting that the inactive Sth1 contributed to the observed accumulation of Pol II in coding regions. Notwithstanding the Pol II increase, the ORF occupancies of histone chaperones FACT and Spt6 were significantly reduced in the mutant. These results suggest a potential role for RSC in recruiting/retaining these chaperones in coding regions. Pol II accumulation despite substantial reductions in TBP, FACT, and Spt6 occupancies in the catalytic-dead mutant could be indicative of severe transcription elongation and termination defects. Such defects would be consistent with studies showing that RSC is recruited to coding regions in a transcription-dependent manner. Thus, these findings imply a role for RSC in transcription elongation and termination processes, in addition to its established role in transcription initiation.

Project description:ESA1 (essential SAS-family acetyltransferase) is the only known yeast histone acetyltransferase (HAT) required for cell viability. It is a member of the MYST (MOZ, YBF2/SAS3, SAS2, Tip60) family of HAT proteins and contains a conserved acetyltransferase domain in addition to a chromodomain. While ESA1’s HAT activity is important in processes such as deoxyribonucleic acid (DNA) repair, acetylation is likely not its essential function. Our lab has shown that mutants with a single point mutation in the active site cysteine are still viable even though their acetyltransferase abilities are abolished. Furthermore, chromatin immunoprecipitation assays have shown ESA1 distributed evenly along the length of chromatin, not localized to specific promoters as would be expected from a HAT protein involved in transcriptional regulation. As is the case for other HAT proteins, ESA1’s acetyltransferase activity is significant, but in processes such as DNA replication, DNA repair and cell cycle progression. The aim of this project is to determine the essential function of ESA1 - the catalytic subunit of the yeast HAT complex, NuA4 (nucleosome acetyltransferase of H4) – using a bypass suppression screen to identify suppressors of ESA1. It is proposed that suppressing mutations will alter a gene involved in the process that is the essential function of ESA1. Thus, identifying a suppressor that can bypass the need for ESA1 may provide insight into its essential function. Since ESA1 is an essential gene, a haploid esa1∆ strain in which wild-type ESA1 is provided on a centromeric plasmid was utilized. The bypass suppression screen resulted in suppressors of ESA1 that allowed esa1∆ cells to be viable even in the absence of the essential gene. These second site suppressors (sup-) of ESA1 each show the Mendelian segregation pattern of the suppressing gene and ESA1 in 2:2 ratios, implying they are single genes unlinked to ESA1. Microarray and nuclear morphology studies show abnormal gene expression and morphology of the esa1- sup- cells, further implicating the suppressing mutation in DNA repair and replication processes. Investigating ESA1’s essential role and a probable conservation of function across species can provide a deeper understanding of the capabilities of HAT complexes. Keywords: Comparison of strains lacking essential ESA1 gene to those containing an ESA1 bypass suppressor.

Project description:ESA1 (essential SAS-family acetyltransferase) is the only known yeast histone acetyltransferase (HAT) required for cell viability. It is a member of the MYST (MOZ, YBF2/SAS3, SAS2, Tip60) family of HAT proteins and contains a conserved acetyltransferase domain in addition to a chromodomain. While ESA1’s HAT activity is important in processes such as deoxyribonucleic acid (DNA) repair, acetylation is likely not its essential function. Our lab has shown that mutants with a single point mutation in the active site cysteine are still viable even though their acetyltransferase abilities are abolished. Furthermore, chromatin immunoprecipitation assays have shown ESA1 distributed evenly along the length of chromatin, not localized to specific promoters as would be expected from a HAT protein involved in transcriptional regulation. As is the case for other HAT proteins, ESA1’s acetyltransferase activity is significant, but in processes such as DNA replication, DNA repair and cell cycle progression. The aim of this project is to determine the essential function of ESA1 - the catalytic subunit of the yeast HAT complex, NuA4 (nucleosome acetyltransferase of H4) – using a bypass suppression screen to identify suppressors of ESA1. It is proposed that suppressing mutations will alter a gene involved in the process that is the essential function of ESA1. Thus, identifying a suppressor that can bypass the need for ESA1 may provide insight into its essential function. Since ESA1 is an essential gene, a haploid esa1∆ strain in which wild-type ESA1 is provided on a centromeric plasmid was utilized. The bypass suppression screen resulted in suppressors of ESA1 that allowed esa1∆ cells to be viable even in the absence of the essential gene. These second site suppressors (sup-) of ESA1 each show the Mendelian segregation pattern of the suppressing gene and ESA1 in 2:2 ratios, implying they are single genes unlinked to ESA1. Microarray and nuclear morphology studies show abnormal gene expression and morphology of the esa1 sup- cells, further implicating the suppressing mutation in DNA repair and replication processes. Investigating ESA1’s essential role and a probable conservation of function across species can provide a deeper understanding of the capabilities of HAT complexes. Experiment Overall Design: Eight samples were analyzed. The only variables are the ESA1 and SUP2 genes. WT (ESA1 SUP2), 2 replicates. Single mutant (ESA1 sup2-), 3 replicates. Double mutant (esa1 sup2-), 3 replicates.

Project description:The chromatin remodelers (CRs) SWI/SNF and RSC function in evicting promoter nucleosomes at highly expressed yeast genes, particularly those activated by transcription factor Gcn4. Ino80 remodeling complex (Ino80C) can establish nucleosome-depleted regions (NDRs) in reconstituted chromatin, and was implicated in removing histone variant H2A.Z from the -1 and +1 nucleosomes flanking NDRs; however, Ino80C’s function in transcriptional activation in vivo is not well understood. Analyzing the cohort of Gcn4-induced genes in ino80Δ mutants has uncovered a role for Ino80C on par with SWI/SNF in evicting promoter nucleosomes and transcriptional activation. Compared to SWI/SNF, Ino80C generally functions over a wider region, spanning the -1 and +1 nucleosomes, NDR, and proximal genic nucleosomes, at genes highly dependent on its function. Defects in nucleosome eviction in ino80Δ cells are frequently accompanied by reduced promoter occupancies of TBP, and diminished transcription; and Ino80 is enriched at genes requiring its remodeler activity. Importantly, nuclear depletion of Ino80 impairs promoter nucleosome eviction even in a mutant lacking H2A.Z. Thus, Ino80C acts widely in the yeast genome together with RSC and SWI/SNF in evicting promoter nucleosomes and enhancing transcription, all in a manner at least partly independent of H2A.Z editing.

Project description:ISWI-family chromatin remodelers organize nucleosome arrays, while SWI/SNF-family remodelers (RSC) disorganize and eject nucleosomes, implying an antagonism that is largely unexplored in vivo. Here, we describe two independent genetic screens for rsc suppressors that yielded mutations in the promoter-focused ISW1a complex, or mutations in the ‘basic patch’ of histone H4 (an epitope that regulates ISWI activity), strongly supporting RSC-ISW1a antagonism in vivo. RSC and ISW1a largely co-localize, and genomic nucleosome studies using rsc isw1 mutant combinations revealed opposing functions: promoters classified with a nucleosome-deficient region (NDR) gain nucleosome occupancy in rsc mutants, but this gain is attenuated in rsc isw1 double mutants. Furthermore, promoters lacking NDRs have the highest occupancy of both remodelers, consistent with regulation by nucleosome occupancy, and decreased transcription in rsc mutants. Taken together, we provide the first genetic and genomic evidence for RSC-ISW1a antagonism, and reveal different mechanisms at two different promoter architectures.

Project description:ISWI-family chromatin remodelers organize nucleosome arrays, while SWI/SNF-family remodelers (RSC) disorganize and eject nucleosomes, implying an antagonism that is largely unexplored in vivo. Here, we describe two independent genetic screens for rsc suppressors that yielded mutations in the promoter-focused ISW1a complex, or mutations in the ‘basic patch’ of histone H4 (an epitope that regulates ISWI activity), strongly supporting RSC-ISW1a antagonism in vivo. RSC and ISW1a largely co-localize, and genomic nucleosome studies using rsc isw1 mutant combinations revealed opposing functions: promoters classified with a nucleosome-deficient region (NDR) gain nucleosome occupancy in rsc mutants, but this gain is attenuated in rsc isw1 double mutants. Furthermore, promoters lacking NDRs have the highest occupancy of both remodelers, consistent with regulation by nucleosome occupancy, and decreased transcription in rsc mutants. Taken together, we provide the first genetic and genomic evidence for RSC-ISW1a antagonism, and reveal different mechanisms at two different promoter architectures.

Project description:ISWI-family chromatin remodelers organize nucleosome arrays, while SWI/SNF-family remodelers (RSC) disorganize and eject nucleosomes, implying an antagonism that is largely unexplored in vivo. Here, we describe two independent genetic screens for rsc suppressors that yielded mutations in the promoter-focused ISW1a complex, or mutations in the ‘basic patch’ of histone H4 (an epitope that regulates ISWI activity), strongly supporting RSC-ISW1a antagonism in vivo. RSC and ISW1a largely co-localize, and genomic nucleosome studies using rsc isw1 mutant combinations revealed opposing functions: promoters classified with a nucleosome-deficient region (NDR) gain nucleosome occupancy in rsc mutants, but this gain is attenuated in rsc isw1 double mutants. Furthermore, promoters lacking NDRs have the highest occupancy of both remodelers, consistent with regulation by nucleosome occupancy, and decreased transcription in rsc mutants. Taken together, we provide the first genetic and genomic evidence for RSC-ISW1a antagonism, and reveal different mechanisms at two different promoter architectures.