Project description:CTCF is a master regulator that plays a role in genome architecture and gene expression. A key aspect of CTCF’s mechanism involves bringing together distant genetic elements for intra- and inter-chromosomal interactions. Evidence from epigenetic processes, such as X-chromosome inactivation (XCI), suggests that CTCF may carry out its functions through interacting RNAs. Using genome-wide approaches to investigate the relationship between CTCF’s RNA interactome and its epigenomic landscape, here we report that CTCF interacts with thousands of transcripts in mouse embryonic stem cells (mESC), many in close proximity to CTCF’s genomic binding sites. Biochemical analysis demonstrates that CTCF is a high-affinity RNA binding protein that contacts RNA directly and specifically. In the XCI model, CTCF binds the active and inactive X-chromosomes allele-specifically. At the X-inactivation center, Tsix RNA binds CTCF and targets CTCF to a region associated with X-chromosome pairing. Our work implicates CTCF-RNA interactions in long-range chromosomal interactions in trans and adds a new layer of complexity to CTCF regulation. The genome-wide datasets reported here will provide a useful resource for further study of CTCF-mediated epigenomic regulation. CTCF RNA interactome was identified by UV-crosslinking and immunoprecipitation followed by high-throughput sequencing (CLIP-seq), and was compared to CTCF's epigenomic landscape as obtained by chromatin immunoprecipitation (ChIP-seq).

Project description:CTCF is the most studied transcription factor, which is essential for chromatin interaction maintenance. Although several independent studies reported that CTCF protein could pull down RNAs in vitro and in cells, there are continuous debates about authenticity of the RNA-binding affinity of CTCF and its biological role, mainly due to the concerns of limited research techniques such as CLIP-seq. To systematically investigate the RNA-interaction with CTCF and the impact on gene regulation, we conducted in vivo CTCF ChIP-seq under three conditions, including RNase A treatment, Triptolide-mediated transcription inhibition and auxin-inducible degron mediated RNA-binding domain mutant swap. Our results consistently suggest that when RNA-interaction with CTCF protein was impaired in vivo, the DNA occupancy of CTCF remains the same at the genome-wide scale. Our data provide a complementary approach and in silico evidence to re-considerate the role of RNA-binding affinity of CTCF.

Project description:CTCF is a master regulator that plays a role in genome architecture and gene expression. A key aspect of CTCF’s mechanism involves bringing together distant genetic elements for intra- and inter-chromosomal interactions. Evidence from epigenetic processes, such as X-chromosome inactivation (XCI), suggests that CTCF may carry out its functions through interacting RNAs. Using genome-wide approaches to investigate the relationship between CTCF’s RNA interactome and its epigenomic landscape, here we report that CTCF interacts with thousands of transcripts in mouse embryonic stem cells (mESC), many in close proximity to CTCF’s genomic binding sites. Biochemical analysis demonstrates that CTCF is a high-affinity RNA binding protein that contacts RNA directly and specifically. In the XCI model, CTCF binds the active and inactive X-chromosomes allele-specifically. At the X-inactivation center, Tsix RNA binds CTCF and targets CTCF to a region associated with X-chromosome pairing. Our work implicates CTCF-RNA interactions in long-range chromosomal interactions in trans and adds a new layer of complexity to CTCF regulation. The genome-wide datasets reported here will provide a useful resource for further study of CTCF-mediated epigenomic regulation.

Project description:CTCF (CCCTC-binding factor) is a highly conserved 11-zinc finger DNA binding protein with tens of thousands of binding sites genome-wide. CTCF acts as a multifunctional regulator of transcription, having been previously associated with activator, repressor, and insulator activity. These diverse regulatory functions are crucial for preimplantation development and are implicated in the regulation of numerous lineage-specific genes. Despite playing a critical role in developmental gene regulation, the mechanisms that underlie developmental changes in CTCF recruitment and function are poorly understood. Our previous work suggested that differences in CTCF’s binding site sequence may affect the regulation of CTCF recruitment, as well as CTCF’s regulatory function. To investigate these two possibilities directly during a developmental process, changes in genome-wide CTCF binding and gene expression were characterized during in vitro differentiation of mouse embryonic stem cells. CTCF binding sites were initially separated into three classes (named LowOc, MedOc, and HighOc) based on similarity to the consensus motif. The LowOc class, with lower-similarity to the consensus motif, is more likely to show changes in binding during differentiation. These more dynamically bound sites are enriched for motifs that confer a lower in vitro affinity for CTCF, suggesting a mechanism where sites with low-binding affinity are more amenable to developmental control. Additionally, by comparing changes in CTCF binding with changes in gene expression during differentiation, we show that LowOc and HighOc sites are associated with distinct regulatory functions. In sum, these results suggest that the regulatory control of CTCF’s binding and function is dependent in part upon specific motifs within its DNA binding site.

Project description:CTCF (CCCTC-binding factor) is a highly conserved 11-zinc finger DNA binding protein with tens of thousands of binding sites genome-wide. CTCF acts as a multifunctional regulator of transcription, having been previously associated with activator, repressor, and insulator activity. These diverse regulatory functions are crucial for preimplantation development and are implicated in the regulation of numerous lineage-specific genes. Despite playing a critical role in developmental gene regulation, the mechanisms that underlie developmental changes in CTCF recruitment and function are poorly understood. Our previous work suggested that differences in CTCF’s binding site sequence may affect the regulation of CTCF recruitment, as well as CTCF’s regulatory function. To investigate these two possibilities directly during a developmental process, changes in genome-wide CTCF binding and gene expression were characterized during in vitro differentiation of mouse embryonic stem cells. CTCF binding sites were initially separated into three classes (named LowOc, MedOc, and HighOc) based on similarity to the consensus motif. The LowOc class, with lower-similarity to the consensus motif, is more likely to show changes in binding during differentiation. These more dynamically bound sites are enriched for motifs that confer a lower in vitro affinity for CTCF, suggesting a mechanism where sites with low-binding affinity are more amenable to developmental control. Additionally, by comparing changes in CTCF binding with changes in gene expression during differentiation, we show that LowOc and HighOc sites are associated with distinct regulatory functions. In sum, these results suggest that the regulatory control of CTCF’s binding and function is dependent in part upon specific motifs within its DNA binding site.

Project description:Accumulated data suggest that transcription factor CTCF is indispensable to define topologically associated domain (TAD) boundaries and to maintain intra-TAD chromatin loop structures. However, upon genome-wide acute depletion of CTCF, the discrepancy between global reduction of chromatin interactions and minimal alteration of transcription has been evidently observed. To understand CTCF’s direct role in chromatin accessibility and global transcriptional regulation, we have systematically integrated data collected from ATAC-seq, RNA-seq, whole genome bisulfite-seq, Cut&Run and HiC in a previously established CTCF-miniAID knock-in cell lines. Acute degradation of CTCF markedly rewires genome-wide chromatin accessibility but not DNA methylation. Differentially altered ATAC-seq peaks are highly associated with adjacent CTCF binding sites, supporting the direct link between CTCF occupancy and its surrounding chromatin accessibility. Increased ATAC-seq peaks upon CTCF loss are notably associated with enhanced transcription at promoter regions and insulator sites, while decreased ATAC-seq peaks are significantly enriched at DNA loops. Furthermore, using CTCF associated multi-Omics data we have established a combinatorial data analysis pipeline to discover novel CTCF mediated insulators in the genome, by which we have successfully identified 67 novel insulators at non-coding regions distal to promoters. Functional CRISPR interference (CRISPRi) unconstrained the repressive transcriptional regulation of target genes. In sum, using CTCF acute depletion cell model and multi-Omics analysis, we concluded that CTCF loss rewires genome-wide chromatin accessibility, which plays a critical role for transcriptional regulation.

Project description:Deciphering the role of RNA in regulating CTCF’s DNA binding affinity in leukemia cells [CTCF-ChIP]

Project description:Deciphering the role of RNA in regulating CTCF’s DNA binding affinity in leukemia cells [CTCF-HA-ChIP]

Project description:Deciphering the role of RNA in regulating CTCF’s DNA binding affinity in leukemia cells

Project description:In this assay, we aimed to investigate the occupancy of ZFP661 in the mouse genome and its possible role in regulating the occupancies of CTCF and cohesin, which are two key factors in establishing 3D chromatin structures. To achieve this, we performed ChIP-seq in ZFP661-3HA endogenously tagged mESCs (for ZFP661), Zfp661 knockout (KO) mESCs (for CTCF and RAD21), and ZFP661-3HA overexpressing (OE) mESCs (for ZFP661, CTCF, RAD21, KAP1, and H3K9me3). Our results reveal that 1) ZFP661 binding peaks were co-occupied with those of CTCF; 2) ZFP661 binds exclusively inside the CTCF loop anchors; and 3) ZFP661 can suppress cohesin binding at CTCF barriers without altering CTCF binding.