Project description:CTCF, a highly studied transcription factor, is essential for chromatin interaction maintenance. Several independent studies have reported that CTCF interacts with RNAs in vitro and in cells. Yet continuous debates about the authenticity of the RNA-binding affinity of CTCF and its biological role remain in large part due to limited research techniques available, such as CLIP-seq. Here, we investigated the role RNA plays on CTCF’s transcription factor function through its chromatin occupancy. To systematically investigate whether RNAs affect CTCF’s ability to bind DNA, we perturbed CTCF-RNA interactions by three independent approaches and examined CTCF genome occupancy by ChIP-seq. Although RnaseA A and Triptolide treatment each affected a certain number of CTCF-binding peaks, few peaks overlapped between treatment groups indicating the effect of RNA in regulating CTCF’s DNA binding affinity was modest and variable between loci. In addition, limited transcriptional or chromatin accessibility changes were observed between cells expressing wild-type CTCF or CTCF lacking the RNA binding region. Our data provide a complementary approach and in silico evidence to reconsider the significance of RNA affecting CTCF’s DNA-binding affinity in a global manner.

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

Project description:Low affinity CTCF binding drives transcriptional regulation whereas high affinity binding encompasses architectural functions.

Project description:ChIPseq was performed on cells depleted for CTCF by AID2 auxin degradation to examine CTCF DNA binding affinity. ChIP seq was also performed on cells depleted for endogenous CTCF and expressing HA tagged WT CTCF and CTCF mutants (deltaZF1, deltaZF10 and deltaRBR) to examine how functional deletions affect CTCF DNA binding affinity.

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 CTCFM-bM-^@M-^Ys binding site sequence may affect the regulation of CTCF recruitment, as well as CTCFM-bM-^@M-^Ys 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 CTCFM-bM-^@M-^Ys binding and function is dependent in part upon specific motifs within its DNA binding site. Mouse E14 ES cells were differentiated in vitro for 4.5 days using retinoic acid. RNA-Seq was performed from cells collected before and after differentiation.

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 CTCFM-bM-^@M-^Ys binding site sequence may affect the regulation of CTCF recruitment, as well as CTCFM-bM-^@M-^Ys 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 CTCFM-bM-^@M-^Ys binding and function is dependent in part upon specific motifs within its DNA binding site. Mouse E14 ES cells were differentiated in vitro for 4.5 days using retinoic acid. ChIP-seq for CTCF and an IgG control was performed from cells collected before and after differentiation. For undifferentiated cells, data were generated in two biological replicates.

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:CCCTC-binding factor (CTCF) is a DNA-binding protein that plays important roles in chromatin organization, though the mechanism by which CTCF carries out these functions is not fully understood. Recent studies show that CTCF recruits the cohesin complex to insulator sites and that cohesin is required for insulator activity. Here we have shown that the DEAD box RNA helicase p68 (DDX5) and its associated noncoding RNA, steroid receptor RNA activator (SRA), form a complex with CTCF that is essential for insulator function. p68 was detected at CTCF sites in the IGF2/H19 imprinted control region (ICR) as well as other genomic CTCF sites. In vivo depletion of SRA or p68 reduced CTCF-mediated insulator activity at the IGF2/H19 ICR, increased levels of IGF2 expression, and increased interactions between the endodermal enhancer and IGF2 promoter. p68/SRA also interacts with members of the cohesin complex. Depletion of either p68 or SRA does not affect CTCF binding to its genomic sites, but it does reduce cohesin binding. The results suggest that p68/SRA stabilizes the interaction of cohesin with CTCF, by binding to both, and is required for proper insulator function. Identification of p68-binding sites in Hela cells using ChIP-Seq.

Project description:Chromosome loops shift dynamically during development, homeostasis, and disease. CTCF is known to anchor loops and construct 3D genomes, but how anchor sites are selected is not yet understood. Here we unveil Jpx RNA as a determinant of anchor selectivity. Jpx RNA targets thousands of genomic sites, preferentially binding promoters of active genes. Depleting Jpx RNA causes ectopic CTCF binding, massive shifts in chromosome looping, and downregulation of >700 Jpx target genes. Without Jpx, thousands of lost loops are replaced by de novo loops anchored by ectopic CTCF sites. Although Jpx controls CTCF binding on a genome-wide basis, it acts selectively at the subset of developmentally sensitive CTCF sites. Specifically, Jpx targets low-affinity CTCF motifs and displaces CTCF protein through competitive inhibition. We conclude that Jpx acts as a CTCF release factor and shapes the 3D genome by regulating anchor site usage.

Project description:The METTL3-METTL14 heterodimer is the core component of the N6-methyltransferase complex (MTC) that catalyzes methylation of adenosine residues at the N(6) position of RNA. As the non-catalytic subunit of the MTC, METTL14 functions as the RNA-binding scaffold that recognizes the RNA substrate. We found METTL14 could interacte with chromatin through recognition of H3K36me3. ChIP-seq with HA-tagged METTL14 using an HA antibody identified 300 peaks in HepG2 cells, among which 53% peaks were located in the gene body and only 3% peaks were located in the promoter. The binding sites of METTL14 on chromatin correlate with that of H3K36me3.To investigat whether this interaction is Pol II dependent, we treated cells with a Pol II inhibitor 5,6-Dichlorobenzimidazole 1-β-D-ribofuranoside (DRB) for a short time. Interestingly, we found the interaction of METTL14 with chromatin in gene body region was not affected by DRB treatment .