Project description:Background: CTCF is a well-established chromatin architectural protein that also plays various roles in transcriptional regulation. While CTCF biology has been extensively studied, how the domains of CTCF function to regulate transcription remains unknown. Additionally, the original auxin-inducible degron 1 (AID1) system has limitations to investigate the function of CTCF. Results: We employ an improved auxin-inducible degron technology, AID2, to facilitate the study of acute depletion of CTCF while overcoming the limitations of the previous AID system. As previously observed through the AID1 system and steady-state RNA analysis, the new AID2 system combined with SLAM-seq confirms that CTCF depletion leads to modest nascent and steady-state transcripts changes. A CTCF domain sgRNA library screening identifies the zinc finger (ZF) domain as the region within CTCF with the most functional relevance, including ZFs 1 and 10. Removal of ZFs 1 and 10 reveals genomic regions that independently require these ZFs for DNA binding and transcriptional regulation. Notably, loci regulated by either ZF1 or ZF10 exhibit unique CTCF binding motifs specific to each ZF. Conclusions: By extensively comparing the AID1 and AID2 systems for CTCF degradation in SEM cells, we confirm that AID2 degradation is superior for achieving miniAID tagged protein degradation without the limitations of the AID1 system. The model we create that combines AID2 depletion of CTCF with exogenous overexpression of CTCF mutants allows us to demonstrate how peripheral ZFs intricately orchestrate transcriptional regulation in a cellular context for the first time.

Project description:Background: CTCF is a well-established chromatin architectural protein that also plays various roles in transcriptional regulation. While CTCF biology has been extensively studied, how the domains of CTCF function to regulate transcription remains unknown. Additionally, the original auxin-inducible degron 1 (AID1) system has limitations to investigate the function of CTCF. Results: We employ an improved auxin-inducible degron technology, AID2, to facilitate the study of acute depletion of CTCF while overcoming the limitations of the previous AID system. As previously observed through the AID1 system and steady-state RNA analysis, the new AID2 system combined with SLAM-seq confirms that CTCF depletion leads to modest nascent and steady-state transcripts changes. A CTCF domain sgRNA library screening identifies the zinc finger (ZF) domain as the region within CTCF with the most functional relevance, including ZFs 1 and 10. Removal of ZFs 1 and 10 reveals genomic regions that independently require these ZFs for DNA binding and transcriptional regulation. Notably, loci regulated by either ZF1 or ZF10 exhibit unique CTCF binding motifs specific to each ZF. Conclusions: By extensively comparing the AID1 and AID2 systems for CTCF degradation in SEM cells, we confirm that AID2 degradation is superior for achieving miniAID tagged protein degradation without the limitations of the AID1 system. The model we create that combines AID2 depletion of CTCF with exogenous overexpression of CTCF mutants allows us to demonstrate how peripheral ZFs intricately orchestrate transcriptional regulation in a cellular context for the first time.

Project description:We coupled an auxin-induced degron (AID) system with precision nuclear run-on (PRO-seq). Oriented CTCF motifs in gene bodies are associated with transcriptional stalling in a manner ostensibly independent of bound CTCF. CTCF binding sites display highly variable resistance to degradation, with persistent sites displaying architectural related features.

Project description:We coupled an auxin-induced degron (AID) system with precision nuclear run-on (PRO-seq). Oriented CTCF motifs in gene bodies are associated with transcriptional stalling in a manner ostensibly independent of bound CTCF. CTCF binding sites display highly variable resistance to degradation, with persistent sites displaying architectural related features.

Project description:In this experiment, we sought to identify how the distribution of CTCF, MAZ, and RAD21 change in CTCF-degron (no auxin), CTCF-degron (auxin), CTCF-degron MAZ KO (no auxin), and CTCF-degron MAZ KO (auxin) backgrounds in mouse embryonic stem cells (ESCs).

Project description:The “CTCF code” hypothesis posits that CTCF pleotropic functions are driven by recognition of diverse DNA sequences through combinatorial use of its 11 zinc fingers (ZFs). This model however is supported by in vitro binding studies of a limited number of sequences. To directly test CTCF multivalency in vivo we here define ZF binding requirements at ~50,000 genomic sites in primary lymphocytes. We find that CTCF reads sequence diversity through ZF clustering. ZFs4-7 anchor CTCF to ~80% of targets containing the 20bp core motif. Non-conserved flanking sequences are recognized by ZFs1-2 and ZFs8- 11 clusters, which also stabilize CTCF broadly. Alternatively, CTCF employ ZFs9-11 to associate with a second phylogenetically-conserved upstream motif at ~15% of its sites. Individually, ZFs increase overall binding affinity and chromatin residence time. Unexpectedly, we also uncover a conserved downstream DNA motif that destabilizes CTCF occupancy. CTCF thus associates with a wide array of DNA modules via combinatorial clustering of its 11 ZFs.

Project description:The transcription factor CTCF appears indispensable in defining topologically associated domain boundaries and maintaining chromatin loop structures within these domains, supported by numerous functional studies. However, acute depletion of CTCF globally reduces chromatin interactions but does not significantly alter transcription. Here we systematically integrated multi-omics data including ATAC-seq, RNA-seq, WGBS, Hi-C, Cut&Run, CRISPR-Cas9 survival dropout screening, time-solved deep proteomic and phosphoproteomic analyses in cells carrying auxin-induced degron at endogenous CTCF locus. Acute CTCF protein degradation markedly rewired genome-wide chromatin accessibility. Increased accessible chromatin regions were largely located adjacent to CTCF-binding sites at promoter regions and insulator sites and were associated with enhanced transcription of nearby genes. In addition, we used CTCF-associated multi-omics data to establish a combinatorial data analysis pipeline to discover CTCF co-regulatory partners in regulating downstream gene expression. We successfully identified 40 candidates, including multiple established partners (i.e., MYC) supported by all layers of evidence. Interestingly, many CTCF co-regulators (e.g., YY1, ZBTB7A) that have evident alterations of respective downstream gene expression do not show changes at their expression levels across the multi-omics measurements upon acute CTCF loss, highlighting the strength of our system to discover hidden co-regulatory partners associated with CTCF-mediated transcription. This study highlights CTCF loss rewires genome-wide chromatin accessibility, which plays a critical role in transcriptional regulation

Project description:The objective of the experiment was to determine the impact of cap-adjacent 2'-O-ribose methylation on steady-state mRNA levels. We depleted CMTR-1 protein, which is the main enzyme responsible for of cap-adjacent 2'-O-ribose methylation in C. elegans. This was achieved using animals homozygous for an auxin-degron allele of the endogenous cmtr-1 gene in genetic background that constitutively expressed TIR1(F74G) protein (cshIs140 allele derived from HML1012). The depletion was achieved using the auxin analogue 5-Ph-IAA. Experiment was carried out in triplicate and depletion of CMTR-1 was confirmed by Western blotting.

Project description:In human cells, CTCF’s role in genomic organization and global transcription regulation is less clearly defined due to the lack of available tools to efficiently deplete CTCF. Here, we used an auxin-inducible degron system to conditionally deplete CTCF in a human B-cell lymphoblastic leukemia (B-ALL) cell line, SEM. Cut & Run ChIP-seq showed acute depletion of CTCF disrupted the direct interaction between the MYC promoter and its distal enhancer cluster residing ~1.8 Mb downstream.

Project description:The impact of acute RBM8A depletion on nascent transcription (using the auxin (IAA)-inducible degron system in conjunction with 4sU-sequencing) was investigated.