Project description: Not available

Project description: Not available

Project description: Not available

Project description: Not available

Project description: Not available

Project description:In budding yeast, telomeres and the mating type (HM) loci are found in a heterochromatin-like silent structure initiated by Rap1 and extended by the interaction of Sir (Silencing Information Regulator) proteins with histones. Binding data demonstrate that both the H3 and H4 N terminal domains required for silencing in vivo interact directly with Sir3 and Sir4 in vitro. The role of H4 lysine 16 deacetylation is well established in Sir3 protein recruitment, however that of the H3 N terminal tail has remained unclear. In order to characterize the role of H3 in silent chromatin formation and compare it to H4 we have generated comprehensive high resolution genome-wide binding maps of heterochromatin proteins. We find that H4 lysine 16 deacetylation is required for the recruitment and spreading of heterochromatin proteins at all telomeres and HM loci. In contrast the H3 N terminus is required for neither recruitment nor spreading of Sir proteins. Instead, deletion of the H3 tail leads to increased accessibility within heterochromatin of an ectopic bacterial dam methylase and the decreased mobility of an HML heterochromatic fragment in sucrose gradients. These findings indicate an altered chromatin structure. We propose that Sir proteins recruited by the H4 tail then interact with the H3 tail to form a higher order silent chromatin structure.

Project description:Within the cell nucleus, histone H1 is the most mobile histone. Yet, it is regarded as key to the establishment and stability of chromatin higher-order structure. The implication is that chromatin higher-order structure is dynamic, in part due to the mobility of H1. Defining the positions of H1 on chromatin in situ, therefore, represents a challenge. Immunoprecipitation of formaldehyde-fixed and sonicated chromatin, followed by DNA sequencing (xChIP-seq) is traditionally the method for mapping histones onto DNA elements. But since sonication fragmentation precedes ChIP, there is a consequent loss of information about chromatin higher-order structure. A second formaldehyde fixation after antibody binding to intact in situ chromatin, but before sonication (xxChIP-seq), preserves this information and reveals which histone epitopes are inaccessible in situ. In this study, the distribution of two histone H1 variants H1.2 and H1.5 is defined and compared by both xChIP-seq and xxChIP-seq in undifferentiated HL-60/S4 cells, illustrating the influences of preserved chromatin higher-order structure. We have found that xChIP and xxChIP signals are anticorrelated. H1.2 versus H1.5-enrichments were particularly distinct near bound Pol II, SMC3 proteins, as well as domains marked by H3K4me1, H3K9ac, H3K27ac and H3K36me3. H1.5-enriched regions have an average nucleosome repeat length NRL=184 bp, as opposed to 190 bp for H1.2-enriched regions. We have also studied the distribution of H1 variants with respect to DNA methylation. Most changes of DNA methylation during differentiation appear within ~60bp from the nucleosome entry/exit and are preferably associated with H1.2-bound nucleosomes, whereas H1.5 histones are depleted from CpGs. Our results suggest that different physical packing of nucleosomes may exist in H1.2- versus H1.5-enriched areas, characterized by differential H1 epitope exposure as assessed by xChIP and xxChIP.

Project description: Not available

Project description:This SuperSeries is composed of the SubSeries listed below. Refer to individual Series

Project description:The packaging of DNA into chromatin plays an important role in transcriptional regulation and nuclear processes. Brahma related gene-1 SMARCA4 (also known as BRG1), the essential ATPase subunit of the mammalian SWI/SNF chromatin remodeling complex, uses the energy from ATP hydrolysis to disrupt nucleosomes at target regions. Although the transcriptional role of SMARCA4 at gene promoters is well-studied, less is known about its role in higher-order genome organization. SMARCA4 knockdown in human mammary epithelial MCF-10A cells resulted in 176 up-regulated genes, including many related to lipid and calcium metabolism, and 1292 down-regulated genes, some of which encode extracellular matrix (ECM) components that can exert mechanical forces and affect nuclear structure. ChIP-seq analysis of SMARCA4 localization and SMARCA4-bound super-enhancers demonstrated extensive binding at intergenic regions. Furthermore, Hi-C analysis showed extensive SMARCA4-mediated alterations in higher-order genome organization at multiple resolutions. First, SMARCA4 knockdown resulted in clustering of intra- and inter- sub-telomeric regions, demonstrating a novel role for SMARCA4 in telomere organization. SMARCA4 binding was enriched at TAD (Topologically Associating Domain) boundaries, and SMARCA4 knockdown resulted in weakening of TAD boundary strength. Taken together, these findings provide a dynamic view of SMARCA4-dependent changes in higher-order chromatin organization and gene expression, identifying SMARCA4 as a novel component of chromatin organization. Hi-C and RNA-seq experiments were conducted in MCF-10A shSCRAM and shSMARCA4 cells. SMARCA4 ChIP-seq was conducted in wildtype MCF-10A cells.