Project description:The chromatin architecture of eukaryotic gene promoters is generally characterized by a nucleosome-free region (NFR) flanked by at least one H2A.Z variant nucleosome. Computational predictions of nucleosome positions based on thermodynamic properties of DNA-histone interactions have met with limited success. Here we show that the action of the essential RSC remodeling complex in S. cerevisiae helps explain the discrepancy between theory and experiment. In RSC-depleted cells, NFRs shrink such that the average positions of flanking nucleosomes move toward predicted sites. Nucleosome positioning at distinct subsets of promoters additionally requires the essential Myb family proteins Abf1 and Reb1, whose binding sites are enriched in NFRs. In contrast, H2A.Z deposition is dispensable for nucleosome positioning. By regulating H2A.Z deposition using a steroid-inducible protein splicing strategy, we show that NFR establishment is necessary for H2A.Z deposition. These studies suggest an ordered pathway for the assembly of promoter chromatin architecture. Nucleosome positions were mapped in a variety of strains under a variety of conditions to determine how several proteins are involved in nucleosome positioning. All replicates are biological replicates. Each set of replicates is balanced in terms of Cy3:Cy5 such that there are equal numbers of Cy3:Cy5 and Cy5:Cy3 arrays (format: mononucleosomal DNA:reference DNA). Changes in gene expression in a strain carrying either the Sth1-degron or Abf1-Reb1-degron under degron-inducing conditions were profiled by hybridizing labeled cDNA derived from the degron strain against labeled cDNA derived from a control strain lacking the degron, but grown under the same conditions. Four biological replicates for each experiment were done using a balanced dye-swap design.

Project description:Abstract: In the yeast S. pombe, multiple chromatin-modifying enzymes are required for heterochromatin formation, yet how their actions alter chromatin structure to block access to DNAby the transcriptional machinery is unknown. We constructed high-resolution nucleosome occupancy maps of heterochromatic regions in wild-type strains and in mutants lacking the H3K9 methyltransferase Clr4 or one of the two activities of the silencing effector complex SHREC. Fourier analysis reveals that these enzymes do not increase the regularity of nucleosome spacing. Rather, their principal effect was to induce the elimination of nucleosome-free regions (NFRs). Both NFRs associated with transcription initiation sites as well as those not associated with promoters are affected. As in S. cerevisiae, repressed genes in euchromatin retain their NFRs. Thus, NFR elimination cannot be explained as a secondary consequence of repression. The maps also show that TFIIIC boundary elements have NFRs resistant to silencing, suggesting a potential role in preventing lateral spread of heterochromatin. NFR elimination offers a mechanism by which heterochromatin restricts access of the transcriptional machinery to DNA. Nucleosome positions in either heterochromatin or euchromatin were mapped in various mutants to determine whether chromatin structure is altered upon heterochromatic silencing. Eight strains were assayed for nucleosome positioning in heterochromatin while two strains were assayed for nucleosome positioning in euchromatin. Two biological replicates were assayed for each strain. No dye swaps were done. RNA transcripts were also mapped using the heterochromatin tiling arrays to determine where RNA transcripts accumulate in heterochromatin. Three strains were assayed for transcripts in heterochromatin by hybridizing cy5-labeled cDNA created from total RNA against cy3-labeled cDNA created from RNA synthesized from sonicated genomic DNA. Two biological replicates were assayed for each strain.

Project description:Nucleosome arrays begin at nucleosome-free promoter regions (NFRs) and regulate gene expression. Reconstituting such organization throughout a genome with purified proteins is a critical challenge in establishing biochemical mechanisms for chromosome assembly. Here we establish a four-step hierarchical building plan for yeast genomic nucleosome organization using only purified components: genomic DNA, histones, site-specific organizing factors Abf1 and Reb1, and the chromatin remodelers RSC, ISW2, INO80, and ISW1a. First, RSC makes NFRs by translating promoter poly(dA:dT) tracts into directional nucleosome removal. Second, +1 nucleosomes are positioned by INO80 at most genes potentially involving DNA shape, or by ISW2 using gene-specific Abf1 and Reb1. Third, INO80 or ISW2 create arrays with wide spacing. Fourth, ISW1a tightens the spacing and creates properly positioned arrays. We conclude that entire genomes use a simple set of rules and proteins, without transcription, to build a common chromatin architecture. In this study, nucleosomes were assembled using Salt Gradient Dialysis (SGD) on yeast genomic DNA library. Assembled nucleosomes were either left untreated (labelled as "SGD", control), treated with whole cell extract (WCE), mutant extracts (rsc3ts WCE, isw1 isw2 chd1 WCE), purified remodelers; singly or in combinations (RSC, ISW1a, ISW1b, ISW2, INO80, CHD1, SWI/SNF), combinations of mutant extracts and chromatin remodelers or combination of General Regulatory Factors (Abf1, Reb1) and chromatin remodelers. The resulting nucleosome positions were mapped genome-wide using MNase-(anti-H3-ChIP)-Seq.

Project description:Replication of vertebrate genomes is tightly regulated to ensure accurate duplication, but our understanding of the interplay between genetic and epigenetic factors in this regulation remains incomplete. Here, we investigated the involvement of three elements enriched at gene promoters and replication origins: guanine-rich motifs potentially forming G-quadruplexes (pG4s), nucleosome-free regions (NFRs), and the histone variant H2A.Z, in the firing of origins of replication in vertebrates. We show that two pG4s on the same DNA strand (dimeric pG4s) are sufficient to induce assembly of an efficient minimal replication origin without inducing transcription. Dimeric pG4s in replication origins trigger formation of an NFR next to precisely positioned nucleosomes enriched in H2A.Z on this minimal origin and genome-wide. Thus, our data suggest a crucial role for dimeric pG4s in the organization and duplication of vertebrate genomes. It supports the hypothesis that a nucleosome close to an NFR is a shared signal for the formation of replication origins in eukaryotes.

Project description:Abstract: In the yeast S. pombe, multiple chromatin-modifying enzymes are required for heterochromatin formation, yet how their actions alter chromatin structure to block access to DNAby the transcriptional machinery is unknown. We constructed high-resolution nucleosome occupancy maps of heterochromatic regions in wild-type strains and in mutants lacking the H3K9 methyltransferase Clr4 or one of the two activities of the silencing effector complex SHREC. Fourier analysis reveals that these enzymes do not increase the regularity of nucleosome spacing. Rather, their principal effect was to induce the elimination of nucleosome-free regions (NFRs). Both NFRs associated with transcription initiation sites as well as those not associated with promoters are affected. As in S. cerevisiae, repressed genes in euchromatin retain their NFRs. Thus, NFR elimination cannot be explained as a secondary consequence of repression. The maps also show that TFIIIC boundary elements have NFRs resistant to silencing, suggesting a potential role in preventing lateral spread of heterochromatin. NFR elimination offers a mechanism by which heterochromatin restricts access of the transcriptional machinery to DNA.

Project description:The directionality of gene promoters, the proportion of protein coding over divergent noncoding transcription, is highly variable and regulated. How promoter directionality is controlled remains poorly understood. We show that chromatin remodelling complex RSC, general regulatory factors (GRFs) including transcription factors (TFs) can facilitate promoter directionality by attenuating divergent noncoding transcription. Depletion of RSC increased divergent noncoding and decreased protein coding transcription of promoters with strong directionality. Consistent with RSC’s role in regulating chromatin, RSC depletion negatively impacts nucleosome positions upstream of the nucleosome depleted region where divergent transcription initiates, suggesting that nucleosome positioning upstream in promoters physically blocks the recruitment of transcription machinery. Likewise, divergent transcription can be suppressed by targeting GRFs and TFs or the bulky dCas9 protein to transcriptional initiation sites. We propose that RSC mediated nucleosome positioning, GRFs including TFs form the physical barriers in promoters for limiting of divergent transcription, thereby controlling promoter directionality.

Project description:The directionality of gene promoters, the proportion of protein coding over divergent noncoding transcription, is highly variable and regulated. How promoter directionality is controlled remains poorly understood. We show that chromatin remodelling complex RSC, general regulatory factors (GRFs) including transcription factors (TFs) can facilitate promoter directionality by attenuating divergent noncoding transcription. Depletion of RSC increased divergent noncoding and decreased protein coding transcription of promoters with strong directionality. Consistent with RSC’s role in regulating chromatin, RSC depletion negatively impacts nucleosome positions upstream of the nucleosome depleted region where divergent transcription initiates, suggesting that nucleosome positioning upstream in promoters physically blocks the recruitment of transcription machinery. Likewise, divergent transcription can be suppressed by targeting GRFs and TFs or the bulky dCas9 protein to transcriptional initiation sites. We propose that RSC mediated nucleosome positioning, GRFs including TFs form the physical barriers in promoters for limiting of divergent transcription, thereby controlling promoter directionality.

Project description:How is chromatin architecture established and what role does it play in activation of transcription? We show that a regulatory locus in yeast (the UASg) bears, in addition to binding sites for the activator Gal4, sites bound by the protein RSC. RSC tightly positions a nucleosome, evidently partially unwound, in a structure that facilitates Gal4 binding to its sites. The complex comprises a barrier that suffices to impose characteristic features of chromatin architecture. Removal of RSC allows ordinary nucleosomes to form more broadly over the UASg, and these nucleosomes compete with (but do not exclude) Gal4 binding to its sites. Taken with our previous work, the results show that both prior to and following induction specific DNA binding proteins are the predominant determinants of chromatin architecture at the GAL1/10 genes. RSC/nucleosome complexes are found scattered throughout the yeast genome. We surmise, also, that Gal4 works in higher eukaryotes despite whatever obstacle broadly positioned nucleosomes present. Chromatin was digested under conditions that yielded primarily mononucleosomes, and RSC-bearing fragments were recovered on IgG-beads. Fragments (of size ca. 50-200 bp) were analyzed by paired-end high throughput DNA sequencing (Illumina). This technique determines the sequences found at both ends of each fragment, thus revealing the sizes and genomic origin of these fragments.

Project description:How is chromatin architecture established and what role does it play in activation of transcription? We show that a regulatory locus in yeast (the UASg) bears, in addition to binding sites for the activator Gal4, sites bound by the protein RSC. RSC tightly positions a nucleosome, evidently partially unwound, in a structure that facilitates Gal4 binding to its sites. The complex comprises a barrier that suffices to impose characteristic features of chromatin architecture. Removal of RSC allows ordinary nucleosomes to form more broadly over the UASg, and these nucleosomes compete with (but do not exclude) Gal4 binding to its sites. Taken with our previous work, the results show that both prior to and following induction specific DNA binding proteins are the predominant determinants of chromatin architecture at the GAL1/10 genes. RSC/nucleosome complexes are found scattered throughout the yeast genome. We surmise, also, that Gal4 works in higher eukaryotes despite whatever obstacle broadly positioned nucleosomes present.

Project description:In S. cerevisiae, histone variant H2A.Z is deposited in euchromatin at the flanks of silent heterochromatin to prevent its ectopic spread. The degree to which H2A.Z is found and functions elsewhere is unknown. Here we show that H2A.Z nucleosomes are found at promoter regions of nearly all genes in euchromatin. They generally occur as two positioned nucleosomes that flank a nucleosome-free region (NFR) that contains the transcription start site. Astonishingly, enrichment at 5’ ends is independent of transcriptional state as it is observed not only at actively transcribed genes, but also at inactive loci. Mutagenesis of a typical promoter revealed a 22 bp segment of DNA sufficient to program formation of a NFR flanked by two H2A.Z nucleosomes. This segment contains a binding site of the Myb-related protein Reb1 and an adjacent dT:dA tract. Efficient deposition of H2A.Z is further promoted by a specific pattern of histone H3 and H4 tail acetylation and the bromodomain protein Bdf1, a component of the Swr1 complex that deposits H2A.Z. These data define DNA- and histone-based mechanisms by which dividing cells define the 5’ ends of genes and preserve their euchromatic state in the absence of transcription. Keywords: ChIP-chip