Project description:Chromatin is the physiological template for all biological processes in the eukaryotic cell nucleus. In addition, the structure of chromatin is intrinsically related to its function. Thus, studying the dynamics of three-dimensional (3D) chromatin structure is essential to understand these biological processes. Recent publications based on integrative analysis of multi-omics studies have provided comprehensive and multilevel insights into 3D genome organization emphasizing its role during transcriptional regulation. However, the function of nuclear microRNAs in 3D genome organization has remained elusive. Here we show that mature microRNA 9 (miR-9) is enriched at promoters and super-enhancers (SE) of genes that are inducible by tissue growth factor beta 1 (TGFB1) signaling. Further, we found that nuclear miR-9 is required for broad domains of the euchromatin histone mark H3K4me3 (histone 3 tri-methylated lysine 4), as well as the nucleic acid secondary structure G-quadruplexes (G4s), both are chromatin features related to increased transcriptional activity. Moreover, we show that nuclear miR-9 is required for promoter-super-enhancer looping. Our study places a nuclear microRNA in the same structural and functional context with G4s and promoter-enhancer interactions during 3D genome organization and transcriptional activation induced by TGFB1 signaling, a pathway that plays important role in hyperproliferative diseases, such as cancer and fibrosis.

Project description:Chromatin is the physiological template for all biological processes in the eukaryotic cell nucleus. In addition, the structure of chromatin is intrinsically related to its function. Thus, studying the dynamics of three-dimensional (3D) chromatin structure is essential to understand these biological processes. Recent publications based on integrative analysis of multi-omics studies have provided comprehensive and multilevel insights into 3D genome organization emphasizing its role during transcriptional regulation. However, the function of nuclear microRNAs in 3D genome organization has remained elusive. Here we show that mature microRNA 9 (miR-9) is enriched at promoters and super-enhancers (SE) of genes that are inducible by tissue growth factor beta 1 (TGFB1) signaling. Further, we found that nuclear miR-9 is required for broad domains of the euchromatin histone mark H3K4me3 (histone 3 tri-methylated lysine 4), as well as the nucleic acid secondary structure G-quadruplexes (G4s), both are chromatin features related to increased transcriptional activity. Moreover, we show that nuclear miR-9 is required for promoter-super-enhancer looping. Our study places a nuclear microRNA in the same structural and functional context with G4s and promoter-enhancer interactions during 3D genome organization and transcriptional activation induced by TGFB1 signaling, a pathway that plays important role in hyperproliferative diseases, such as cancer and fibrosis.

Project description:Studying the dynamics of three-dimensional (3D) chromatin structure is essential to the understanding of biological processes in the nucleus. Integrative analysis of multi-omics data in recent publications have provided comprehensive and multilevel insight into 3D genome organization emphasizing its role for transcriptional regulation. While enhancers are regulatory elements that play a central role in the spatiotemporal control of gene expression, chromatin looping has been broadly accepted as a means for enhancer-promoter interactions yielding cell-type-specific gene expression signatures. On the other hand, G-quadruplexes (G4s) are non-canonical DNA secondary structures that are enriched at promoters and related to increased gene expression. However, the role of G4s in promoter-distal regulatory elements, such as super-enhancers (SE), as well as in 3D genome organization and chromatin looping mediating long-range enhancer-promoter interactions has remained elusive. Here we show that mature microRNA 9 (miR-9) is enriched at promoters and SE of genes that are inducible by tissue growth factor beta 1 (TGFB1) signaling. Further, we find that nuclear miR-9 is required for chromatin features related to increased transcriptional activity, such as broad domains of the euchromatin histone mark H3K4me3 (histone 3 tri-methylated lysine 4) and G4s. Moreover, we show that nuclear miR-9 is required for promoter-super-enhancer looping. Our study places a nuclear microRNA in the same structural and functional context with G4s and promoter-enhancer interactions during 3D genome organization and transcriptional activation induced by TGFB1 signaling, a critical regulator of proliferation programs in cancer and fibrosis.

Project description:Studying the dynamics of three-dimensional (3D) chromatin structure is essential to the understanding of biological processes in the nucleus. Integrative analysis of multi-omics data in recent publications have provided comprehensive and multilevel insight into 3D genome organization emphasizing its role for transcriptional regulation. While enhancers are regulatory elements that play a central role in the spatiotemporal control of gene expression, chromatin looping has been broadly accepted as a means for enhancer-promoter interactions yielding cell-type-specific gene expression signatures. On the other hand, G-quadruplexes (G4s) are non-canonical DNA secondary structures that are enriched at promoters and related to increased gene expression. However, the role of G4s in promoter-distal regulatory elements, such as super-enhancers (SE), as well as in 3D genome organization and chromatin looping mediating long-range enhancer-promoter interactions has remained elusive. Here we show that mature microRNA 9 (miR-9) is enriched at promoters and SE of genes that are inducible by tissue growth factor beta 1 (TGFB1) signaling. Further, we find that nuclear miR-9 is required for chromatin features related to increased transcriptional activity, such as broad domains of the euchromatin histone mark H3K4me3 (histone 3 tri-methylated lysine 4) and G4s. Moreover, we show that nuclear miR-9 is required for promoter-super-enhancer looping. Our study places a nuclear microRNA in the same structural and functional context with G4s and promoter-enhancer interactions during 3D genome organization and transcriptional activation induced by TGFB1 signaling, a critical regulator of proliferation programs in cancer and fibrosis.

Project description:Spatial genome organization is essential to direct fundamental DNA-templated biological processes (e.g. transcription, replication, and repair), but the 3D in situ nanometer-scale structure of accessible cis-regulatory DNA elements within the crowded nuclear environment remains elusive. Here, we combined the recently developed Assay for Transposase-Accessible Chromatin with visualization (ATAC-see), PALM super-resolution imaging and lattice light-sheet microscope (a method termed 3D ATAC-PALM) to selectively image and quantitatively analyze key features of the 3D accessible genome in single cells. 3D ATAC-PALM reveals that accessible chromatin are non-homogeneously organized into spatially segregated clusters or accessible chromatin domains (ACDs). To directly link imaging and genomic data, we optimized multiplexed imaging of 3D ATAC-PALM with Oligopaint DNA-FISH, RNA-FISH and protein fluorescence. We found that ACDs colocalize with active chromatin and enclose transcribed genes. By applying these methods to analyze genetically purterbed cells, we demonstrated that genome architectural protein CTCF prevents excessive clustering of accessible chromatin and decompacts ACDs. These results highlight the 3D ATAC-PALM as a useful tool to probe the structure and organizing mechanism of the genome.

Project description:Pluripotent states of embryonic stem cells (ESCs) with distinct transcription profile affect their differentiation capacity and therapeutic potential. By single cell analysis of high-resolution three-dimensional (3D) genome structure, we show that remodeling genome structure is highly associated with pluripotent states of human ESCs (hESCs). Naive pluripotent state is featured with specialized 3D genome structures and clear chromatin compartmentation distinct from primed state. Naive pluripotent state may be achieved by remodeled active euchromatin compartment and less chromatin interaction in the nuclear center. This unique genome organization is linked to elevated chromatin accessibility on enhancers and thus high expression levels of naive pluripotent genes localized in this region. On the contrary, primed state exhibits intermingled genome organization. Moreover, active euchromatin and primed pluripotent genes are distributed in the nuclear periphery and yet repressive heterochromatin densely concentrated in the nuclear center, reducing chromatin accessibility and transcription of naive genes. Thus, inversion or relocation of heterochromatin to euchromatin compartmentation is related to regulating chromatin accessibility and thus define pluripotent states and cell identity.

Project description:Pluripotent states of embryonic stem cells (ESCs) with distinct transcription profile affect their differentiation capacity and therapeutic potential. By single cell analysis of high-resolution three-dimensional (3D) genome structure, we show that remodeling genome structure is highly associated with pluripotent states of human ESCs (hESCs). Naive pluripotent state is featured with specialized 3D genome structures and clear chromatin compartmentation distinct from primed state. Naive pluripotent state may be achieved by remodeled active euchromatin compartment and less chromatin interaction in the nuclear center. This unique genome organization is linked to elevated chromatin accessibility on enhancers and thus high expression levels of naive pluripotent genes localized in this region. On the contrary, primed state exhibits intermingled genome organization. Moreover, active euchromatin and primed pluripotent genes are distributed in the nuclear periphery and yet repressive heterochromatin densely concentrated in the nuclear center, reducing chromatin accessibility and transcription of naive genes. Thus, inversion or relocation of heterochromatin to euchromatin compartmentation is related to regulating chromatin accessibility and thus define pluripotent states and cell identity.

Project description:Pluripotent states of embryonic stem cells (ESCs) with distinct transcription profile affect their differentiation capacity and therapeutic potential. By single cell analysis of high-resolution three-dimensional (3D) genome structure, we show that remodeling genome structure is highly associated with pluripotent states of human ESCs (hESCs). Naive pluripotent state is featured with specialized 3D genome structures and clear chromatin compartmentation distinct from primed state. Naive pluripotent state may be achieved by remodeled active euchromatin compartment and less chromatin interaction in the nuclear center. This unique genome organization is linked to elevated chromatin accessibility on enhancers and thus high expression levels of naive pluripotent genes localized in this region. On the contrary, primed state exhibits intermingled genome organization. Moreover, active euchromatin and primed pluripotent genes are distributed in the nuclear periphery and yet repressive heterochromatin densely concentrated in the nuclear center, reducing chromatin accessibility and transcription of naive genes. Thus, inversion or relocation of heterochromatin to euchromatin compartmentation is related to regulating chromatin accessibility and thus define pluripotent states and cell identity.

Project description:The packaging of DNA into chromatin plays an important role in transcriptional regulation and nuclear processes. Brahma related gene-1 SMARCA4 (also known as BRG1), the essential ATPase subunit of the mammalian SWI/SNF chromatin remodeling complex, uses the energy from ATP hydrolysis to disrupt nucleosomes at target regions. Although the transcriptional role of SMARCA4 at gene promoters is well-studied, less is known about its role in higher-order genome organization. SMARCA4 knockdown in human mammary epithelial MCF-10A cells resulted in 176 up-regulated genes, including many related to lipid and calcium metabolism, and 1292 down-regulated genes, some of which encode extracellular matrix (ECM) components that can exert mechanical forces and affect nuclear structure. ChIP-seq analysis of SMARCA4 localization and SMARCA4-bound super-enhancers demonstrated extensive binding at intergenic regions. Furthermore, Hi-C analysis showed extensive SMARCA4-mediated alterations in higher-order genome organization at multiple resolutions. First, SMARCA4 knockdown resulted in clustering of intra- and inter- sub-telomeric regions, demonstrating a novel role for SMARCA4 in telomere organization. SMARCA4 binding was enriched at TAD (Topologically Associating Domain) boundaries, and SMARCA4 knockdown resulted in weakening of TAD boundary strength. Taken together, these findings provide a dynamic view of SMARCA4-dependent changes in higher-order chromatin organization and gene expression, identifying SMARCA4 as a novel component of chromatin organization. Hi-C and RNA-seq experiments were conducted in MCF-10A shSCRAM and shSMARCA4 cells. SMARCA4 ChIP-seq was conducted in wildtype MCF-10A cells.

Project description:CCCTC-binding factor (CTCF) is an architectural protein involved in the three-dimensional organization of chromatin. In this study, we systematically assayed the 3D genomic contact profiles of hundreds of CTCF binding sites in multiple tissues with high-resolution 4C-seq. We find both developmentally stable and dynamic chromatin loops. As recently reported, our data also suggest that chromatin loops preferentially form between CTCF binding sites oriented in a convergent manner. To directly test this, we used CRISPR-Cas9 genome editing to delete core CTCF binding sites in three loci, including the CTCF site in the Sox2 super-enhancer. In all instances, CTCF and cohesin recruitment were lost, and chromatin loops with distal CTCF sites were disrupted or destabilized. Re-insertion of oppositely oriented CTCF recognition sequences restored CTCF and cohesin recruitment, but did not re-establish chromatin loops. We conclude that CTCF binding polarity plays a functional role in the formation of higher order chromatin structure. 4C-seq was performed on a large number of viewpoints in E14 embryonic stem cells, neural precursor cells and primary fetal liver cells