Project description:Mammalian development is associated with extensive changes in gene expression, chromatin accessibility, and nuclear structure. Here, we follow such changes associated with mouse embryonic stem cell differentiation and X inactivation by integrating, for the first time, allele-specific data obtained by high-throughput single-cell RNA-seq, ATAC-seq, and Hi-C. In differentiated cells, contact decay profiles, which clearly distinguish the active and inactive X chromosomes, reveal loss of the inactive X-specific structure at mitosis followed by a rapid reappearance, suggesting a bookkeeping mechanism. In differentiating embryonic stem cells, changes in contact decay profiles are detected in parallel on both the X chromosomes and autosomes, suggesting profound simultaneous reorganization. The onset of the inactive X-specific structure in single cells is notably delayed relative to that of gene silencing, consistent with the idea that chromatin compaction is a late event of X inactivation. Novel computational approaches to effectively align single-cell gene expression, chromatin accessibility, and 3D chromosome structure reveal that long-range structural changes to chromosomes appear as discrete events, unlike progressive changes in gene expression and chromatin accessibility. ### Competing Interest Statement The authors have declared no competing interest.

Project description:Mammalian development is associated with extensive changes in gene expression, chromatin accessibility, and nuclear structure. Here, we follow such changes associated with mouse embryonic stem cell differentiation and X inactivation by integrating, for the first time, allele-specific data obtained by high-throughput single-cell RNA-seq, ATAC-seq, and Hi-C. In differentiated cells, contact decay profiles, which clearly distinguish the active and inactive X chromosomes, reveal loss of the inactive X-specific structure at mitosis followed by a rapid reappearance, suggesting a bookkeeping mechanism. In differentiating embryonic stem cells, changes in contact decay profiles are detected in parallel on both the X chromosomes and autosomes, suggesting profound simultaneous reorganization. The onset of the inactive X-specific structure in single cells is notably delayed relative to that of gene silencing, consistent with the idea that chromatin compaction is a late event of X inactivation. Novel computational approaches to effectively align single-cell gene expression, chromatin accessibility, and 3D chromosome structure reveal that long-range structural changes to chromosomes appear as discrete events, unlike progressive changes in gene expression and chromatin accessibility. ### Competing Interest Statement The authors have declared no competing interest.

Project description:Mammalian development is associated with extensive changes in gene expression, chromatin accessibility, and nuclear structure. Here, we follow such changes associated with mouse embryonic stem cell differentiation and X inactivation by integrating, for the first time, allele-specific data obtained by high-throughput single-cell RNA-seq, ATAC-seq, and Hi-C. In differentiated cells, contact decay profiles, which clearly distinguish the active and inactive X chromosomes, reveal loss of the inactive X-specific structure at mitosis followed by a rapid reappearance, suggesting a bookkeeping mechanism. In differentiating embryonic stem cells, changes in contact decay profiles are detected in parallel on both the X chromosomes and autosomes, suggesting profound simultaneous reorganization. The onset of the inactive X-specific structure in single cells is notably delayed relative to that of gene silencing, consistent with the idea that chromatin compaction is a late event of X inactivation. Novel computational approaches to effectively align single-cell gene expression, chromatin accessibility, and 3D chromosome structure reveal that long-range structural changes to chromosomes appear as discrete events, unlike progressive changes in gene expression and chromatin accessibility. ### Competing Interest Statement The authors have declared no competing interest. ### This SuperSeries is composed of the SubSeries listed below.

Project description:Mitosis entails global alterations to chromosome structure and nuclear architecture, concomitant with transient silencing of transcription. How cells transmit transcriptional states through mitosis remains incompletely understood. While many nuclear factors dissociate from mitotic chromosomes, the observation that certain nuclear factors and chromatin features remain associated with individual loci during mitosis originated the hypothesis that they could provide transcriptional memory through mitosis. To obtain the first genome-wide view of the dynamics of chromatin structure during mitosis, we compared the DNase sensitivity of interphase and mitotic chromatin at two stages of cellular maturation in a rapidly dividingmurine erythroblastmodel. Despite global chromosome condensation visible during mitosis at the microscopic level, the chromatin accessibility landscape is largely unaltered. However, mitotic chromatin accessibility is locally dynamic, with individual loci maintaining none, some, or all of their interphase accessibility. Mitotic reduction in accessibility occurs primarily within narrow, highly hypersensitive sites that frequently coincide with transcription factor binding sites, whereas broader domains of moderate accessibility tend to be more stable. In mitosis, proximal promoters generally maintain their accessibility, whereas distal regulatory elements preferentially lose accessibility. Promoters with the highest degree of accessibility preservation in mitosis tend to also be accessible across many murine tissues in interphase. Transcription factor GATA1 exerts site-specific changes in interphase accessibility that are most pronounced at distal regulatory elements, but does not visibly influence mitotic accessibility. We conclude that features of open chromatin are remarkably stable through mitosis and are modulated at the level of individual genes and regulatory elements. Dnase-Seq data is integrated with Chip-seq [GSE36589, GSE30142] and RNA-seq to examine epigentic changes in mitosis. We performed DNase-seq on two cell lines, G1E and G1E-ER4, both on an asynchronus population, and on a sample of cells in mitosis; each of the 4 experiments in triplicate.

Project description:In mammals, one of the female X chromosomes and all imprinted genes are expressed exclusively from a single allele in somatic cells. To evaluate structural changes associated with allelic silencing, we have applied a recently developed Hi-C assay that uses DNase I for chromatin fragmentation to mouse F1 hybrid systems. Results We find radically different conformations for the two female mouse X chromosomes. The inactive X has two superdomains of frequent intrachromosomal contacts separated by a boundary/hinge region. Comparison with the recently reported bipartite 3D structure of the human inactive X shows that the genomic content of the superdomains differs between species, but part of the hinge is conserved and located near the Dxz4/DXZ4 locus. In mouse, the hinge region also contains a minisatellite Ds-TR, and both Dxz4 and Ds-TR appear to be anchored to the nucleolus. Genes that escape X inactivation do not cluster but are located near the periphery of the 3D structure, as are regions enriched in CTCF or RNA polymerase. Fewer short-range intrachromosomal contacts are detected for the inactive alleles of genes subject to X inactivation, compared to the active alleles and to genes that escape X inactivation. This pattern is also evident for imprinted genes, in which more chromatin contacts are detected for the expressed allele. Conclusions By applying a novel Hi-C method to map allelic chromatin contacts, we discover a specific bipartite organization of the mouse inactive X chromosome that probably plays an important role in maintenance of gene silencing. Examination of Nucleophosmin-binding profiles in male and female mouse livers

Project description:Trisomy is the presence of one extra copy of an entire chromosome or its part in a cell nucleus. In humans, autosomal trisomies are associated with severe developmental abnormalities leading to embryonic lethality, miscarriage or pronounced deviations of various organs and systems at birth. Trisomies are characterized by alterations in gene expression level not exclusively on the trisomic chromosome, but throughout the genome. Here, we applied high-throughput chromo-some conformation capture technique (Hi-C) to study chromatin 3D structure in human donor chorion cells carrying additional chromosome 13 (Patau syndrome), chromosome 16 (the most common trisomy), and in cultured fibroblasts with extra chromosome 18 (Edwards syndrome). The presence of extra chromosomes 13 and 16, but not 18, results in systematic changes of contact frequencies between small and large chromosomes. Analyzing the behavior of individual chro-mosomes, we determined that a limited number of chromosomes change their contact patterns stochastically in trisomic cells, and that it could be linked to LAD and gene content. We also found that genome regions which are more compacted in trisomic cells are significantly enriched in housekeeping genes that potentially suggest the decrease of chromatin accessibility and tran-scription level. These results provide a framework for understanding the mechanisms of pan-genome transcription dysregulation in trisomies in the context of chromatin spatial organi-zation.

Project description:We report the application of in situ Hi-C technology to 40 colorectal cancer patients and 10 paired-normal tissue to identify CRC specific changes in 3D chromatin structure. The chromatin contact matrices were generated by the sequencing data and image processing/deep learning-based algorithm was proposed to identify long-range abnormal chromatin interaction patterns in the contact matrices. The tumor specific 3D chromatin structure changes and the enhancer-promoter rewiring mediated by the identified chromatin structure changes were analyzed. The complex chromosome-wide rearrangements such as chromothripsis and its effect to 3D chromatin structure were also observed.

Project description:Genome organization in diverse eukaryotes follows conserved principles including the formation of chromosome territories (CT), chromatin compartments, and TADs. Here, we describe the 3D architecture of holocentric chromosomes in the silkworm Bombyx mori. At the genome-wide scale, B. mori chromosomes are highly territorial lacking any visible trans contact pattern. At the chromosomal scale, B. mori chromosomes segregate into three chromatin compartments: an active A and an inactive B as described in other eukaryotes, and a third type, X, with a unique contact pattern. Compartment X is strongly enriched for short-range interactions and depleted of long-range interactions, hosts a specific combination of genetic and epigenetic features and localizes towards the periphery of CT. Biophysical simulations reveal the necessity of the combined effects of affinity-based compartmentalization and activity-based loop extrusion to lead to the unique interaction patterns observed. Our analyses contribute to our understanding how chromosomes fold highlighting the evolutionary plasticity of 3D genome organization.

Project description:Genome organization in diverse eukaryotes follows conserved principles including the formation of chromosome territories (CT), chromatin compartments, and TADs. Here, we describe the 3D architecture of holocentric chromosomes in the silkworm Bombyx mori. At the genome-wide scale, B. mori chromosomes are highly territorial lacking any visible trans contact pattern. At the chromosomal scale, B. mori chromosomes segregate into three chromatin compartments: an active A and an inactive B as described in other eukaryotes, and a third type, X, with a unique contact pattern. Compartment X is strongly enriched for short-range interactions and depleted of long-range interactions, hosts a specific combination of genetic and epigenetic features and localizes towards the periphery of CT. Biophysical simulations reveal the necessity of the combined effects of affinity-based compartmentalization and activity-based loop extrusion to lead to the unique interaction patterns observed. Our analyses contribute to our understanding how chromosomes fold highlighting the evolutionary plasticity of 3D genome organization.

Project description:Genome organization in diverse eukaryotes follows conserved principles including the formation of chromosome territories (CT), chromatin compartments, and TADs. Here, we describe the 3D architecture of holocentric chromosomes in the silkworm Bombyx mori. At the genome-wide scale, B. mori chromosomes are highly territorial lacking any visible trans contact pattern. At the chromosomal scale, B. mori chromosomes segregate into three chromatin compartments: an active A and an inactive B as described in other eukaryotes, and a third type, X, with a unique contact pattern. Compartment X is strongly enriched for short-range interactions and depleted of long-range interactions, hosts a specific combination of genetic and epigenetic features and localizes towards the periphery of CT. Biophysical simulations reveal the necessity of the combined effects of affinity-based compartmentalization and activity-based loop extrusion to lead to the unique interaction patterns observed. Our analyses contribute to our understanding how chromosomes fold highlighting the evolutionary plasticity of 3D genome organization.