Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Variable chromatin structure revealed by in situ spatially correlated DNA cleavage mapping

Project description:Chromatin structure at the length scale encompassing nucleosome-nucleosome interactions is thought to play a crucial role in regulating transcription and access to DNA. However, this chromatin secondary structure remains poorly understood compared to the primary structure of single nucleosomes or the tertiary structure of long-range looping interactions. Here we report the first genome-wide map of chromatin conformation in human cells at the 1-3 nucleosome (50-500 bp) scale, obtained using ionizing radiation-induced spatially correlated cleavage of DNA with sequencing (RICC-seq). Unbiased analysis of RICC-seq DNA fragments in 1 Mb windows reveals a similar fragment length profile across the genome, with regional enrichment of characteristic fragments spanning tri-nucleosome units in heterochromatin. We observe differences in nucleosome-nucleosome contacts among euchromatin, H3K27me3-marked heterochromatin, and H3k9me3-marked heterochromatin. After calibrating RICC-seq signal to 3D distances, we show that compact 2-start helical fiber structures with stacked alternating nucleosomes are consistent with RICC-seq fragmentation patterns from H3K9me3-marked heterochromatin, while non-compact zig-zags and other extended structures are preferred in open chromatin. Our data support a model of heterochromatin condensation in native, intact nuclei consistent with longitudinal compaction of two-start helical fibers.

Project description:Chromatin structure at the length scale encompassing nucleosome-nucleosome interactions is thought to play a crucial role in regulating transcription and access to DNA. However, this chromatin secondary structure remains poorly understood compared to the primary structure of single nucleosomes or the tertiary structure of long-range looping interactions. Here we report the first genome-wide map of chromatin conformation in human cells at the 1-3 nucleosome (50-500 bp) scale, obtained using ionizing radiation-induced spatially correlated cleavage of DNA with sequencing (RICC-seq). Unbiased analysis of RICC-seq DNA fragments in 1 Mb windows reveals a similar fragment length profile across the genome, with regional enrichment of characteristic fragments spanning tri-nucleosome units in heterochromatin. We observe differences in nucleosome-nucleosome contacts among euchromatin, H3K27me3-marked heterochromatin, and H3k9me3-marked heterochromatin. After calibrating RICC-seq signal to 3D distances, we show that compact 2-start helical fiber structures with stacked alternating nucleosomes are consistent with RICC-seq fragmentation patterns from H3K9me3-marked heterochromatin, while non-compact zig-zags and other extended structures are preferred in open chromatin. Our data support a model of heterochromatin condensation in native, intact nuclei consistent with longitudinal compaction of two-start helical fibers.

Project description:The structure of chromatin plays pivotal roles in regulating gene transcription, DNA replication and repair, and chromosome segregation. This structure, however, remains elusive. Here, using cryo-FIB and cryo-ET, we delineate the 3D architecture of native chromatin fibres in intact interphase human T-lymphoblasts and determine the in situ structures of nucleosomes in different conformations. These chromatin fibres are not structured as uniform 30 nm one-start or two-start filaments but are composed of relaxed, variable zigzag organizations of nucleosomes connected by straight linker DNA. Nucleosomes with little H1 and linker DNA density are distributed randomly without any spatial preference. This work will inspire future high-resolution investigations on native chromatin structures in situ at both a single-nucleosome level and a population level under many different cellular conditions in health and disease.

Project description:Separase is a protease that performs critical functions in the maintenance of genetic homeostasis. Among them, the cleavage of the meiotic cohesin during meiosis is a key step in producing gametes in eukaryotes. However, the exact chromosomal localization of this proteolytic cleavage was not addressed due to the lack of experimental tools. To this end, we developed a method based on monoclonal antibodies capable of recognizing the predicted neo-epitopes produced by separase-mediated proteolysis in the RAD21 and REC8 cohesin subunits. To validate the epigenomic strategy of mapping cohesin proteolysis, anti-RAD21 neo-epitopes antibodies were used in ChIP-On-ChEPseq analysis of human cells undergoing mitotic anaphase. Second, a similar analysis applied for mapping of REC8 cleavage in germline cells in Macaque showed a correlation with a subset of alpha-satellites and other repeats, directly demonstrating that the site-specific mei-cohesin proteolysis hotspots are coincident but not identical with centromeres. The sequences for the corresponding immunoglobulin genes show a convergence of antibodies with close specificity. This approach could be potentially used to investigate cohesin ring opening events in other chromosomal locations, if applied to single cells.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Mapping separase-mediated cleavage in situ

Project description:Chromatin accessibility mapping is a powerful approach to identify potential regulatory elements. A popular example is ATAC-seq, whereby Tn5 transposase inserts sequencing adapters into accessible DNA ('tagmentation'). CUT&Tag is a tagmentation-based epigenomic profiling method in which antibody tethering of Tn5 to a chromatin epitope of interest profiles specific chromatin features in small samples and single cells. Here, we show that by simply modifying the tagmentation conditions for histone H3K4me2 or H3K4me3 CUT&Tag, antibody-tethered tagmentation of accessible DNA sites is redirected to produce chromatin accessibility maps that are indistinguishable from the best ATAC-seq maps. Thus, chromatin accessibility maps can be produced in parallel with CUT&Tag maps of other epitopes with all steps from nuclei to amplified sequencing-ready libraries performed in single PCR tubes in the laboratory or on a home workbench. As H3K4 methylation is produced by transcription at promoters and enhancers, our method identifies transcription-coupled accessible regulatory sites.

Project description:Eukaryotic DNA replication origins differ both in their efficiency and in the characteristic time during S phase when they become active. The biological basis for these differences remains unknown, but they could be a consequence of chromatin structure. The availability of genome-wide maps of nucleosome positions has led to an explosion of information about how nucleosomes are assembled at transcription start sites, but no similar maps exist for DNA replication origins. Here we combine high-resolution genome-wide nucleosome maps with comprehensive annotations of DNA replication origins to identify patterns of nucleosome occupancy at eukaryotic replication origins. On average, replication origins contain a nucleosome depleted region centered next to the ACS element, flanked on both sides by arrays of well-positioned nucleosomes. Our analysis identified DNA sequence properties that correlate with nucleosome occupancy at replication origins genome-wide and that are correlated with the nucleosome-depleted region. Clustering analysis of all annotated replication origins revealed a surprising diversity of nucleosome occupancy patterns. We provide evidence that the origin recognition complex, which binds to the origin, acts as a barrier element to position and phase nucleosomes on both sides of the origin. Finally, analysis of chromatin reconstituted in vitro reveals that origins are inherently nucleosome depleted. Together our data provide a comprehensive, genome-wide view of chromatin structure at replication origins and suggest a model of nucleosome positioning at replication origins in which the underlying sequence occludes nucleosomes to permit binding of the origin recognition complex, which then (likely in concert with nucleosome modifiers and remodelers) positions nucleosomes adjacent to the origin to promote replication origin function.