Project description:Background. Mammalian cells are flexible and can rapidly change shape when they contract, adhere, or migrate. Their nucleus must be stiff enough to withstand cytoskeletal forces, but flexible enough to remodel as the cell changes shape. This is particularly important for cells migrating through constricted space, where the nuclear shape must change in order to fit through. This happens many times in the life cycle of a neutrophil, which must protect its chromatin from damage and disruption associated with migration. Results. Total RNA-sequencing identified that neutrophil migration through 5 or 14 µm pores was associated with changes in the transcript levels of inflammation and chemotaxis-related genes, when compared to unmigrated cells. Differentially expressed transcripts specific to migration with constriction were enriched for groups of genes associated with cytoskeleton remodelling. Hi-C was used to capture the genome organisation in control and migrated cells. Chromatin did not switch between the active (A) and inactive (B) compartments after migration. However, global depletion of mid- to long-range contacts was observed following active migration through the 5 µm pores. Chromatin contacts that decreased in frequency were enriched in inactive chromatin. Conclusion. Mid- to long-range contacts are preferentially lost within inactive chromatin, thus protecting transcriptionally active contacts from the disruptive effects of migration with constriction. This is consistent with current hypotheses implicating heterochromatin as the mechanoresponsive form of chromatin. Further investigation concerning the contribution of heterochromatin to stiffness, flexibility, and protection of nuclear function will be important for understanding cell migration in human health and disease.

Project description:Detailed genomic contact maps have revealed that chromosomes are composed of developmentally stable topologically associated domains (TADs) and more flexible sub-TADs. These domains reside in active and inactive nuclear compartments, but cause and consequence of compartmentalization are largely unknown. Here, we combined lacO/lacR binding platforms with allele-specific 4C technologies to track their precise position in the three-dimensional genome upon recruitment of NANOG, SUV39H1 or EZH2. We observed locked genomic loci resistant to spatial repositioning and unlocked loci that could be repositioned to different nuclear sub-compartments with distinct chromatin signatures. Focal protein recruitment caused the entire sub- TAD, but not surrounding regions, to engage in new genomic contacts. Compartment switching was uncoupled from gene expression changes and enzymatically modifying histones per se was insufficient for repositioning. Collectively this suggests that transassociated factors determine three-dimensional compartmentalization independent of their cis-effect on local chromatin composition and activity. 4C-seq was performed on a range of viewpoints in 129/Sv;C57BL/6 embryonic stem cells carying a lacO array in chromosome 8 and 11.

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:Nuclear Pores provide a scaffold for induced enhancer promoter contacts

Project description:The spatial organization of DNA in the cell nucleus is an emerging key contributor to genomic function. We have developed 4C technology, or 3C-on-chip, which allows for an unbiased genome-wide search for DNA loci that contact a given locus in the nuclear space. We demonstrate here that active and inactive genes are engaged in many long-range intrachromosomal interactions and can also form interchromosomal contacts. The active b-globin locus in fetal liver contacts mostly transcribed, but not necessarily tissue-specific, loci elsewhere on chromosome 7, while the inactive locus in fetal brain contacts different, transcriptionally silent, loci. A housekeeping gene in a gene dense region on chromosome 8 forms long-range contacts predominantly with other active gene clusters, both in cis and in trans, and many of these intra- and interchromosomal interactions are conserved between the tissues analyzed. Our data demonstrate that chromosomes fold into areas of active chromatin and areas of inactive chromatin and establish 4C technology as a powerful tool to study nuclear architecture. Keywords: 4C technology

Project description:One round migration through 3 μm pores promotes changes in transcription of T-ALL cells

Project description:Detailed genomic contact maps have revealed that chromosomes are composed of developmentally stable topologically associated domains (TADs) and more flexible sub-TADs. These domains reside in active and inactive nuclear compartments, but cause and consequence of compartmentalization are largely unknown. Here, we combined lacO/lacR binding platforms with allele-specific 4C technologies to track their precise position in the three-dimensional genome upon recruitment of NANOG, SUV39H1 or EZH2. We observed locked genomic loci resistant to spatial repositioning and unlocked loci that could be repositioned to different nuclear sub-compartments with distinct chromatin signatures. Focal protein recruitment caused the entire sub- TAD, but not surrounding regions, to engage in new genomic contacts. Compartment switching was uncoupled from gene expression changes and enzymatically modifying histones per se was insufficient for repositioning. Collectively this suggests that transassociated factors determine three-dimensional compartmentalization independent of their cis-effect on local chromatin composition and activity.

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.

Project description:It is becoming increasingly clear that the shape of the genome importantly influences transcription regulation. Pluripotent stem cells (PSCs) such as embryonic stem cells (ESCs) were recently shown to organize their chromosomes into topological domains that are largely invariant between cell types. Here, we applied 4C technology and combined ChIP-seq with Hi-C data to demonstrate that inactive chromatin is unusually disorganized in PSC nuclei. We show that gene promoters engage in contacts between topological domains in a largely tissue-independent manner while enhancers have a more tissue-restricted interaction profile. Most strikingly, genomic clusters of pluripotency factor binding sites find each other very efficiently, in a manner that is strictly PSC-specific, dependent on the presence of Oct4 and Nanog protein and inducible upon artificial recruitment of Nanog to a selected chromosomal site. We conclude that pluripotent stem cells have a unique higher-order genome structure shaped by pluripotency factors. We speculate that this interactome enhances the robustness of the pluripotent state. 4C-seq was performed on a range of viewpoints in pluripotent (2x ESC, iPSC) and differentiated (neural precursor cells and astrocytes) cell lines.

Project description:A subset of genomic regions, including one of the female X chromosomes and all imprinted genes, are expressed exclusively from a single allele in somatic cells of mammals. To evaluate structural changes associated with allelic silencing, we used mouse F1 hybrid systems in which X inactivation is skewed and alleles can be distinguished based on single nucleotide polymorphisms to analyze chromatin contacts by a new Hi-C assay that uses DNase I for chromatin fragmentation. Both DNase Hi-C and in situ DNase Hi-C reveal a radically different conformation between the two female mouse X chromosomes. Two superdomains of frequent intrachromosomal contacts separated by a hinge region are specifically observed on the inactive X chromosome both in vivo (brain) and in vitro (Patski cells). A bipartite 3D organization of the inactive X has been also reported in human lymphoblastoid cells, suggesting that this conserved structure probably plays an important role in maintenance of gene silencing on the inactive X. Interestingly, we found that the genomic content of the superdomains differs between species, but that part of the hinge region is conserved and located near the Dxz4/DXZ4 locus that binds CTCF on the inactive X. In mouse, the hinge region also contains a minisatellite Ds-TR adjacent to a promoter with strong CTCF binding. Both Dxz4 and Ds-TR bind nucleophosmin and are enriched in nucleolus-associated chromatin, suggesting anchoring to the nucleolus. Genes that escape X inactivation do not cluster but are preferentially located near the periphery of the 3D structure. Regions enriched in CTCF or RNA polymerase are also preferentially located on the periphery of the inactive X while LINE1 elements are preferentially on the interior. Genes subject to silencing exhibit fewer detectable intrachromosomal contacts than escape genes. This transcription-coupled pattern is also evident for imprinted genes, in which more chromatin contacts are detected on the expressed allele, suggesting greater constraint on the organization of expressed genomic regions.