Project description:RSC and ISW1 Chromatin Remodelers Display Functional and Chromatin-based Promoter Antagonism [HybMap microarray]

Project description:RSC and ISW1 Chromatin Remodelers Display Functional and Chromatin-based Promoter Antagonism [MNase-Seq]

Project description:RSC and ISW1 Chromatin Remodelers Display Functional and Chromatin-based Promoter Antagonism [nucleosome occupancy]

Project description:RSC and ISW1 Chromatin Remodelers Display Functional and Chromatin-based Promoter Antagonism [ChIP-chip]

Project description:RSC and ISW1 Chromatin Remodelers Display Functional and Chromatin-based Promoter Antagonism [ChIP-seq]

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. Genome-wide nucleosome occupancy maps in wild-type, mutant RSC, and mutant ISW1 strains were generated by hybridization of mononucleosomal DNA to microarrays. Strains carrying Sth1 degron and either pGal-UBR1 (YBC2191) or ubr1 null (YBC2192) represent RSC null and RSC wildtype, respectively. Strains carrying Sth1 degron isw1 null and either pGal-UBR1 (YBC2467) or ubr1 null (YBC2468) represent RSC null isw1 null and RSC wildtype isw1 null, respectively. Mononucleosomes were isolated from three independent biological replicates from each genotype. Please note that each sample consists of three replicates (i.e. three raw data files) and the sample data table contains combined quantile normalized data of the replicates.

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. Genomic localization of RSC, ISW1a, and SWI/SNF complexes were measured by chromatin immunoprecipitation followed by Illumina paired-end sequencing. Four strains were analyzed, including Rsc8-9xMyc (YBC2882), Sth1-2xFlag (YBC601 p3018), Ioc3-13xMyc (YBC2883), and Snf2-13xMyc (YBC3010). Each sample consists of one chromatin immunoprecipitate and one input chromatin control.

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. Genome-wide nucleosome occupancy maps in RSC and rsc null strains were generated by paired-end sequencing of mononucleosomal DNA. Strains carrying the Sth1 degron allele and either pGal-UBR1 (YBC3386) or ubr1 null (YBC3387) represent RSC null and RSC wildtype, respectively.

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. Total RNA expression was determined by the HybMap protocol, hybridization of total RNA to genomic tiling microarray followed by detection with an anti-RNA-DNA-hybrid antibody. Total RNA was isolated from three independent biological replicates of each strain, including wild type (YBC1894), rsc2ts (YBC1111), isw1 null (YBC1416), ioc3 null (YBC2693), isw1 null rsc2ts (YBC3227), and ioc3 null rsc2ts (YBC3228). Please note that each sample consists of three replicates (i.e. three raw data files) and the sample data table contains combined quantile normalized data of the replicates.

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. Genomic localization of RSC and ISW1a complexes were measured by chromatin immunoprecipitation followed by genome-wide microarray hybridization. Two independent biological replicates of two strains, Rsc8-9xMyc (YBC2882) and Ioc3-13xMyc (YBC2883), each grown in two different media, rich glucose media (YPD) or minimal synthetic glucose (SD) media. Each sample consists of one chromatin immunoprecipitate and one input chromatin control. Please note that each sample consists of two replicates (i.e. two raw data files) and the sample data table contains combined quantile normalized data of the replicates.