Project description:Mapping nucleosome resolution chromosome folding in yeast by Micro-C

Project description:We describe a Hi-C based method, Micro-C, in which micrococcal nuclease is used instead of restriction enzymes to fragment chromatin, enabling nucleosome resolution chromosome folding maps. Analysis of Micro-C maps for budding yeast reveals abundant self-associating domains similar to those reported in other species, but not previously observed in yeast. These structures, far shorted than topologically-associating domains in mammals, typically encompass one to five genes in yeast. Strong boundaries between self-associating domains occur at promoters of highly transcribed genes, and regions of rapid histone turnover that are typically bound by the RSC chromatin-remodeling complex. Investigation of chromosome folding in mutants confirms roles for RSC, “gene looping” factor Ssu72, Mediator, H3K56 acetyltransferase Rtt109, and N-terminal tail of H4 in folding of the yeast genome. This approach provides detailed structural maps of a eukaryotic genome and our findings provide insights into the machinery underlying chromosome compaction. Chromatin is fragmented by Mnase, subsequenct nucleosomal end repair, and a modified two-step method for purfiying ligation products. Using Illumina paired-end sequencing maps Micro-C library and generates nucleosome resolution contact maps. The readme.txt file contains additional description of how each processed data file was generated.

Project description:Structural analysis of chromosome folding in vivo has been revolutionized by Chromosome Conformation Capture (3C) and related methods, which use proximity ligation to identify chromosomal loci in physical contact. We recently described a variant 3C technique, Micro-C, in which chromatin is fragmented to mononucleosomes using micrococcal nuclease, enabling nucleosome-resolution folding maps of the genome. Here, we describe an improved Micro-C protocol using long crosslinkers, termed Micro-C XL, which exhibits greatly increased signal to noise, and provides further insight into the folding of the yeast genome. We also find that signal to noise is much improved in Micro-C XL libraries generated from relatively insoluble chromatin as opposed to soluble material, providing a simple method to physically enrich for bona-fide long-range interactions. Micro-C XL maps of the budding and fission yeast genomes reveal both short-range chromosome fiber features such as chromosomally-interacting domains (CIDs), as well as higher-order features such as clustering of centromeres and telomeres, thereby addressing the primary discrepancy between prior Micro-C data and reported 3C and Hi-C analyses. Interestingly, comparison of chromosome folding maps of S. cerevisiae and S. pombe revealed widespread qualitative similarities, yet quantitative differences, between these distantly-related species. Micro-C XL thus provides a single assay suitable for interrogation of chromosome folding at length scales from the nucleosome to the full genome.

Project description:Transcriptional reactivation of hTERT is the limiting step in tumorigenesis. While mutations in hTERT promoter in 19% of cancers are recognized as key drivers of hTERT reactivation, mechanisms by which wildtype hTERT (WT-hTERT) promoter is reactivated, in majority of human cancers, remain unknown. Using primary colorectal cancers (CRC) we identify, Tert INTeracting region 2 (T-INT2), the critical chromatin region essential for reactivating WT-hTERT promoter in CRCs. T-INT2 is essential for the formation of a unique chromatin architecture needed for the reactivation of WT-hTERT. This cancer-cell-specific WT-hTERT reactivation is mediated by -catenin and JunD signalling via T-INT2. Pharmacological screens uncovered Salinomycin, which inhibits WT-hTERT reactivation by blocking T-INT2 mediated formation of chromatin architecture essential for WT-hTERT promoter reactivation. Our results provide a framework for therapeutic targeting of WT-hTERT, specifically in cancer cells and explain, for the first time how known CRC alterations, such as APC lead to WT-hTERT promoter reactivation during oncogene-induced stepwise-transformation.

Project description:ChIP-chip analyses of Psc3 in wild-type and mutant fission yeast cells. Eukaryotic genomes are folded into three-dimensional structures that govern diverse hromosomal procsses. Studeis in Drosophila and mammals have revealed large self-associating tomological domains whose borders are enriched in cohesin/CTCF factors that are required for long-range intrations. However, mechanisms governing higher-order folding of chromatin fivbers and the exact function of cohesin in this process remain poor understood. Here we perform Hi-C to explore the organization of the Schizosaccharomyces pombe genome at high-resolution, which despite its small size comprises fundamental features found in higher eukaryotes. Our analyses reveal that in addition to determinants of Rabl-like chromosome architecture, smaller locally interacting regions of chromatin, referred to as globules, are a distinctive features of S. pombe chromosome organization. This feature of chromatin architecture requires a function of cohesin distinct from its role in sister chromatid cohesion. Cohesin is enriched at globule boundaries and its loss causes disruption of local globule structure and global chromosome territories. Heterochromatin, which selectively loads cohesin at specific loci including pericentromric and subtelomeric domains, is dispensable for globule formation but uniquely impacts genome organization through chromatin compaction by enforcing Rabl configuration. Genome-wide distribution of Psc3 were determined by ChIP-chip analysis in wild-type and mutant fission yeast cells.

Project description:The study investigates CTCF/cohesin binding and chromatin looping by ChIP-seq and Micro-C. By ChIP-seq, we determined the genome-wide binding profiles of CTCF and Smc1a cohesin subunit in a knock-in mouse ES cell line (wt-CTCF; clone C59) with endogenously tagged wild type CTCF (FLAG-Halo-mCTCF) and Rad21 (mRad21-SNAPf-V5), and compared them to the same ES line expressing a mutant CTCF (ΔRBR-CTCF; clone C59D2), where we replaced a previously described RNA binding region with a short linker (GDGAGLINS) followed by a 3xHA tag (N576_D611del::3xHA). By Micro-C, we compared nucleosome-resolution chromosome folding maps of the same ES cell lines C59 and C59D2 described above, to determine the effect of deleting CTCF RNA binding region on chromatin looping.

Project description:we generated CUT&Tag, ATAC-seq, RNA-seq, high-resolution Hi-C and Micro-C datasets for finer-scale dissection of chromatin architecture alterations in radiation induced malignant transformation of bronchial epithelial cells.

Project description:we generated CUT&Tag, ATAC-seq, RNA-seq, high-resolution Hi-C and Micro-C datasets for finer-scale dissection of chromatin architecture alterations in radiation induced malignant transformation of bronchial epithelial cells.

Project description:we generated CUT&Tag, ATAC-seq, RNA-seq, high-resolution Hi-C and Micro-C datasets for finer-scale dissection of chromatin architecture alterations in radiation induced malignant transformation of bronchial epithelial cells.

Project description:we generated CUT&Tag, ATAC-seq, RNA-seq, high-resolution Hi-C and Micro-C datasets for finer-scale dissection of chromatin architecture alterations in radiation induced malignant transformation of bronchial epithelial cells.