Project description:Higher-order chromatin conformation plays critical role in regulating gene expression and biological development, here we show that HNRNPU, a nuclear matrix attachment factor, is a regulator of 3D genome architecture at multiple levels in mouse hepatocytes. We demonstrate that depletion of HNRNPU results into a global reorganization of nuclear bodies and re-localization of chromatin towards nuclear periphery. Additionally, upon HNRNPU depletion, chromatin interactions between A-type (active) and B-type (inactive) compartments increase significantly but those among same types of compartments decrease significantly, which associate with global gene expression changes. While TADs remain largely invariant, both inter- and intra-TAD interactions increase significantly in A-type compartments but decrease in B-type compartments. Mechanically, HNRNPU complexes with structural proteins CTCF and RAD21; depletion of HNRNPU specifically weakens the bindings of RAD21 to the chromatin, which is highly correlated with the weakness of chromatin loops.

Project description:Higher-order chromatin conformation plays critical role in regulating gene expression and biological development, here we show that HNRNPU, a nuclear matrix attachment factor, is a regulator of 3D genome architecture at multiple levels in mouse hepatocytes. We demonstrate that depletion of HNRNPU results into a global reorganization of nuclear bodies and re-localization of chromatin towards nuclear periphery. Additionally, upon HNRNPU depletion, chromatin interactions between A-type (active) and B-type (inactive) compartments increase significantly but those among same types of compartments decrease significantly, which associate with global gene expression changes. While TADs remain largely invariant, both inter- and intra-TAD interactions increase significantly in A-type compartments but decrease in B-type compartments. Mechanically, HNRNPU complexes with structural proteins CTCF and RAD21; depletion of HNRNPU specifically weakens the bindings of RAD21 to the chromatin, which is highly correlated with the weakness of chromatin loops.

Project description:Higher-order chromatin conformation plays critical role in regulating gene expression and biological development, here we show that HNRNPU, a nuclear matrix attachment factor, is a regulator of 3D genome architecture at multiple levels in mouse hepatocytes. We demonstrate that depletion of HNRNPU results into a global reorganization of nuclear bodies and re-localization of chromatin towards nuclear periphery. Additionally, upon HNRNPU depletion, chromatin interactions between A-type (active) and B-type (inactive) compartments increase significantly but those among same types of compartments decrease significantly, which associate with global gene expression changes. While TADs remain largely invariant, both inter- and intra-TAD interactions increase significantly in A-type compartments but decrease in B-type compartments. Mechanically, HNRNPU complexes with structural proteins CTCF and RAD21; depletion of HNRNPU specifically weakens the bindings of RAD21 to the chromatin, which is highly correlated with the weakness of chromatin loops.

Project description:Higher-order chromatin conformation plays critical role in regulating gene expression and biological development, here we show that HNRNPU, a nuclear matrix attachment factor, is a regulator of 3D genome architecture at multiple levels in mouse hepatocytes. We demonstrate that depletion of HNRNPU results into a global reorganization of nuclear bodies and re-localization of chromatin towards nuclear periphery. Additionally, upon HNRNPU depletion, chromatin interactions between A-type (active) and B-type (inactive) compartments increase significantly but those among same types of compartments decrease significantly, which associate with global gene expression changes. While TADs remain largely invariant, both inter- and intra-TAD interactions increase significantly in A-type compartments but decrease in B-type compartments. Mechanically, HNRNPU complexes with structural proteins CTCF and RAD21; depletion of HNRNPU specifically weakens the bindings of RAD21 to the chromatin, which is highly correlated with the weakness of chromatin loops.

Project description:SATB1, a nuclear matrix-associated protein, has long been proposed to function as a global chromatin loop organizer in T cells. However, the precise roles of SATB1 in chromatin organization remain elusive. Here we show that the depletion of SATB1 in immortalized T cells led to pronounced changes in gene expression, particularly for genes involved in cell proliferation and T cell activation, as well as 3D genome architecture at multiple scales, including the A/B compartment, topologically associating domains (TADs), and loops. Importantly, SATB1 extensively colocalizes with CTCF throughout the genome. Depletion of SATB1 led to increased association among the SATB1/CTCF co-occupied sites, as well as increased chromatin contacts across these sites, thereby altering the genome-wide chromatin loop landscape. SATB1 does not regulate genome architecture by modulating CTCF occupancy. Rather, the topological effects imposed by SATB1 may be attributed to SATB1-dependent anchoring of CTCF to the salt extraction-resistant nuclear matrix. Together, our findings suggest that the functional interplay between nuclear matrix and CTCF plays a critical role in orchestrating 3D genome organization.

Project description:SATB1, a nuclear matrix-associated protein, has long been proposed to function as a global chromatin loop organizer in T cells. However, the precise roles of SATB1 in chromatin organization remain elusive. Here we show that the depletion of SATB1 in immortalized T cells led to pronounced changes in gene expression, particularly for genes involved in cell proliferation and T cell activation, as well as 3D genome architecture at multiple scales, including the A/B compartment, topologically associating domains (TADs), and loops. Importantly, SATB1 extensively colocalizes with CTCF throughout the genome. Depletion of SATB1 led to increased association among the SATB1/CTCF co-occupied sites, as well as increased chromatin contacts across these sites, thereby altering the genome-wide chromatin loop landscape. SATB1 does not regulate genome architecture by modulating CTCF occupancy. Rather, the topological effects imposed by SATB1 may be attributed to SATB1-dependent anchoring of CTCF to the salt extraction-resistant nuclear matrix. Together, our findings suggest that the functional interplay between nuclear matrix and CTCF plays a critical role in orchestrating 3D genome organization.

Project description:SATB1, a nuclear matrix-associated protein, has long been proposed to function as a global chromatin loop organizer in T cells. However, the precise roles of SATB1 in chromatin organization remain elusive. Here we show that the depletion of SATB1 in immortalized T cells led to pronounced changes in gene expression, particularly for genes involved in cell proliferation and T cell activation, as well as 3D genome architecture at multiple scales, including the A/B compartment, topologically associating domains (TADs), and loops. Importantly, SATB1 extensively colocalizes with CTCF throughout the genome. Depletion of SATB1 led to increased association among the SATB1/CTCF co-occupied sites, as well as increased chromatin contacts across these sites, thereby altering the genome-wide chromatin loop landscape. SATB1 does not regulate genome architecture by modulating CTCF occupancy. Rather, the topological effects imposed by SATB1 may be attributed to SATB1-dependent anchoring of CTCF to the salt extraction-resistant nuclear matrix. Together, our findings suggest that the functional interplay between nuclear matrix and CTCF plays a critical role in orchestrating 3D genome organization.

Project description:SATB1, a nuclear matrix-associated protein, has long been proposed to function as a global chromatin loop organizer in T cells. However, the precise roles of SATB1 in chromatin organization remain elusive. Here we show that the depletion of SATB1 in immortalized T cells led to pronounced changes in gene expression, particularly for genes involved in cell proliferation and T cell activation, as well as 3D genome architecture at multiple scales, including the A/B compartment, topologically associating domains (TADs), and loops. Importantly, SATB1 extensively colocalizes with CTCF throughout the genome. Depletion of SATB1 led to increased association among the SATB1/CTCF co-occupied sites, as well as increased chromatin contacts across these sites, thereby altering the genome-wide chromatin loop landscape. SATB1 does not regulate genome architecture by modulating CTCF occupancy. Rather, the topological effects imposed by SATB1 may be attributed to SATB1-dependent anchoring of CTCF to the salt extraction-resistant nuclear matrix. Together, our findings suggest that the functional interplay between nuclear matrix and CTCF plays a critical role in orchestrating 3D genome organization.

Project description:Spatial genome organization is critical for precise gene regulation during development. Special AT-rich sequence binding protein 1 (SATB1) has long been proposed to act as a global chromatin loop organizer in T cells. However, the exact functions of SATB1 in genome organization remain elusive. Here we show that the depletion of SATB1 in human and murine T cells led to transcriptional dysregulation for genes involved in T cell activation, as well as alterations of 3D genome architecture at multiple scales, including the A/B compartment, topologically associating domains (TADs), and loops. Importantly, SATB1 extensively colocalizes with CTCF throughout the genome. Depletion of SATB1 led to increased chromatin contacts among and across the SATB1/CTCF co-occupied sites, thereby affecting the transcription of critical genes involved in T cell activation. The loss of SATB1 did not affect the genome-wide occupancy of CTCF, but significantly reduced the retention of CTCF in the nuclear matrix. Collectively, our data reveal that SATB1 constrains chromatin topology surrounding CTCF-binding sites by tethering CTCF to the nuclear matrix, and suggest that the functional interplay between SATB1 and CTCF contributes to 3D genome organization.

Project description:Spatial genome organization is critical for precise gene regulation during development. Special AT-rich sequence binding protein 1 (SATB1) has long been proposed to act as a global chromatin loop organizer in T cells. However, the exact functions of SATB1 in genome organization remain elusive. Here we show that the depletion of SATB1 in human and murine T cells led to transcriptional dysregulation for genes involved in T cell activation, as well as alterations of 3D genome architecture at multiple scales, including the A/B compartment, topologically associating domains (TADs), and loops. Importantly, SATB1 extensively colocalizes with CTCF throughout the genome. Depletion of SATB1 led to increased chromatin contacts among and across the SATB1/CTCF co-occupied sites, thereby affecting the transcription of critical genes involved in T cell activation. The loss of SATB1 did not affect the genome-wide occupancy of CTCF, but significantly reduced the retention of CTCF in the nuclear matrix. Collectively, our data reveal that SATB1 constrains chromatin topology surrounding CTCF-binding sites by tethering CTCF to the nuclear matrix, and suggest that the functional interplay between SATB1 and CTCF contributes to 3D genome organization.