Project description:Dynamic genome folding is important for V(D)J recombination at the immunoglobulin kappa (Igk) locus, which recombines Jk and Vk gene segments across a 3.2 Mb region in both deletional and inversional orientations. Chromatin loop extrusion and diffusion are considered two key mechanisms underlying Igk folding, but how they coordinate remains unclear. Here we show that CTCF is a key regulator coupling loop extrusion and diffusion during Igk V-J rearrangement, promoting recombination in both orientations across long genomic distances. Mechanistically, the CTCF N-terminus promotes long-range loop extrusion that facilitates distal Vk usage by stabilizing cohesin against WAPL release, and also forms loop barriers enabling chromatin diffusion for inversional Vk joining. In CTCF N-terminal-deficient B cells, defects in inversional Vk joining are not restored by WAPL depletion but are instead largely rescued by a dCas9-blockade targeted to the Vk-Jk intergenic region, mimicking the CTCF barrier. Our findings thus highlight how CTCF coordinates distinct genome-folding mechanisms through its dual roles in cohesin stabilization and extrusion barrier formation to ensure the generation of a diverse Igk repertoire.

Project description:Dynamic genome folding is important for V(D)J recombination at the immunoglobulin kappa (Igk) locus, which recombines Jk and Vk gene segments across a 3.2 Mb region in both deletional and inversional orientations. Chromatin loop extrusion and diffusion are considered two key mechanisms underlying Igk folding, but how they coordinate remains unclear. Here we show that CTCF is a key regulator coupling loop extrusion and diffusion during Igk V-J rearrangement, promoting recombination in both orientations across long genomic distances. Mechanistically, the CTCF N-terminus promotes long-range loop extrusion that facilitates distal Vk usage by stabilizing cohesin against WAPL release, and also forms loop barriers enabling chromatin diffusion for inversional Vk joining. In CTCF N-terminal-deficient B cells, defects in inversional Vk joining are not restored by WAPL depletion but are instead largely rescued by a dCas9-blockade targeted to the Vk-Jk intergenic region, mimicking the CTCF barrier. Our findings thus highlight how CTCF coordinates distinct genome-folding mechanisms through its dual roles in cohesin stabilization and extrusion barrier formation to ensure the generation of a diverse Igk repertoire.

Project description:Dynamic genome folding is important for V(D)J recombination at the immunoglobulin kappa (Igk) locus, which recombines Jk and Vk gene segments across a 3.2 Mb region in both deletional and inversional orientations. Chromatin loop extrusion and diffusion are considered two key mechanisms underlying Igk folding, but how they coordinate remains unclear. Here we show that CTCF is a key regulator coupling loop extrusion and diffusion during Igk V-J rearrangement, promoting recombination in both orientations across long genomic distances. Mechanistically, the CTCF N-terminus promotes long-range loop extrusion that facilitates distal Vk usage by stabilizing cohesin against WAPL release, and also forms loop barriers enabling chromatin diffusion for inversional Vk joining. In CTCF N-terminal-deficient B cells, defects in inversional Vk joining are not restored by WAPL depletion but are instead largely rescued by a dCas9-blockade targeted to the Vk-Jk intergenic region, mimicking the CTCF barrier. Our findings thus highlight how CTCF coordinates distinct genome-folding mechanisms through its dual roles in cohesin stabilization and extrusion barrier formation to ensure the generation of a diverse Igk repertoire.

Project description:Dynamic genome folding is important for V(D)J recombination at the immunoglobulin kappa (Igk) locus, which recombines Jk and Vk gene segments across a 3.2 Mb region in both deletional and inversional orientations. Chromatin loop extrusion and diffusion are considered two key mechanisms underlying Igk folding, but how they coordinate remains unclear. Here we show that CTCF is a key regulator coupling loop extrusion and diffusion during Igk V-J rearrangement, promoting recombination in both orientations across long genomic distances. Mechanistically, the CTCF N-terminus promotes long-range loop extrusion that facilitates distal Vk usage by stabilizing cohesin against WAPL release, and also forms loop barriers enabling chromatin diffusion for inversional Vk joining. In CTCF N-terminal-deficient B cells, defects in inversional Vk joining are not restored by WAPL depletion but are instead largely rescued by a dCas9-blockade targeted to the Vk-Jk intergenic region, mimicking the CTCF barrier. Our findings thus highlight how CTCF coordinates distinct genome-folding mechanisms through its dual roles in cohesin stabilization and extrusion barrier formation to ensure the generation of a diverse Igk repertoire.

Project description:Dynamic genome folding plays a crucial role in cellular functions, including V(D)J recombination at the immunoglobulin kappa (Igκ) locus for antibody generation. This process involves frequent recombination between Jκ and Vκ gene segments over a 3.2 Mb region in both deletional and inversional orientations. While loop extrusion and diffusion are thought to facilitate Igκ recombination, their cooperative mechanisms remain unclear. Our study demonstrates CTCF as a key regulator coupling loop extrusion and diffusion to enhance Vκ recombination in both orientations across large genomic distances. We show that CTCF's N-terminus promotes long-range loop extrusion important for distal Vκ usage by stabilizing cohesin against Wapl release. Furthermore, CTCF's loop barrier function is essential for inversional Vκ usage via enabling diffusion. In CTCF N-terminus mutants, defects in inversional Vκ joining were not corrected by Wapl depletion alone but improved with targeted dCas9 blockade mimicking the CTCF barrier. These findings reveal that CTCF regulates immune diversity via diverse mechanisms and underscore its versatility in gene regulation.

Project description:In developing B lymphocytes, V(D)J recombination assembles IgH and Igk variable region exons from hundreds of gene segments clustered across mega-base Igh and Igk loci. V, D, and J segments are flanked by conserved recombination signal sequences (RSSs) that target RAG endonuclease. RAG orchestrates Igh V(D)J recombination upon capturing a JH-RSS within the JH-RSS-based recombination center (RC). JH-RSS orientation programs RAG to scan upstream D- and VH-containing chromatin linearly presented by cohesin-mediated loop extrusion. During Igh scanning, RAG robustly utilizes only D- or VH-RSSs in convergent ("deletional") orientation with JH-RSSs. However, for Vk-to-Jk joining, RAG utilizes Vk-RSSs from deletional- and inversional-oriented clusters, inconsistent with linear scanning. Here, we elucidate the Vk-to-Jk joining mechanism. Igk undergoes robust primary and secondary rearrangements, which confounds scanning assays. Thus, we engineered cells to undergo only primary Vk-to-Jk rearrangements and found that RAG-scanning from the primary Jk-RC terminates just 8kb upstream within the CTCF-Site-based Sis element. While Sis and the Jk-RC barely interacted with the Vk locus, the CTCF-site-based Cer element, 4kb upstream of Sis, interacted with various loop-extrusion impediments across the locus. Like VH-locus inversion, DJH inversion abrogated VH-to-DJH joining; yet Vk-locus or Jk inversion allowed robust Vk-to-Jk joining. Together, these experiments implicated loop extrusion in bringing Vks near Cer for short-range diffusion-mediated capture by RC-based RAG. To elucidate key mechanistic elements for diffusional V(D)J recombination in Igk versus Igh, we assayed Vk-to-JH and D-to-Jk rearrangements in hybrid Igh-Igk loci generated by targeted chromosomal translocations, and pinpointed remarkably strong Vk and Jk RSSs. Indeed, RSS replacements in hybrid or normal Igk and Igh loci confirmed ability of Igk versus Igh RSSs to promote robust diffusional joining. We propose that Igk evolved strong RSSs to mediate diffusional Vk-to-Jk joining; while Igh evolved weaker RSSs requisite for modulating VH joining by RAG scanning impediments.

Project description:In developing B lymphocytes, V(D)J recombination assembles IgH and Igk variable region exons from hundreds of gene segments clustered across mega-base Igh and Igk loci. V, D, and J segments are flanked by conserved recombination signal sequences (RSSs) that target RAG endonuclease. RAG orchestrates Igh V(D)J recombination upon capturing a JH-RSS within the JH-RSS-based recombination center (RC). JH-RSS orientation programs RAG to scan upstream D- and VH-containing chromatin linearly presented by cohesin-mediated loop extrusion. During Igh scanning, RAG robustly utilizes only D- or VH-RSSs in convergent ("deletional") orientation with JH-RSSs. However, for Vk-to-Jk joining, RAG utilizes Vk-RSSs from deletional- and inversional-oriented clusters, inconsistent with linear scanning. Here, we elucidate the Vk-to-Jk joining mechanism. Igk undergoes robust primary and secondary rearrangements, which confounds scanning assays. Thus, we engineered cells to undergo only primary Vk-to-Jk rearrangements and found that RAG-scanning from the primary Jk-RC terminates just 8kb upstream within the CTCF-Site-based Sis element. While Sis and the Jk-RC barely interacted with the Vk locus, the CTCF-site-based Cer element, 4kb upstream of Sis, interacted with various loop-extrusion impediments across the locus. Like VH-locus inversion, DJH inversion abrogated VH-to-DJH joining; yet Vk-locus or Jk inversion allowed robust Vk-to-Jk joining. Together, these experiments implicated loop extrusion in bringing Vks near Cer for short-range diffusion-mediated capture by RC-based RAG. To elucidate key mechanistic elements for diffusional V(D)J recombination in Igk versus Igh, we assayed Vk-to-JH and D-to-Jk rearrangements in hybrid Igh-Igk loci generated by targeted chromosomal translocations, and pinpointed remarkably strong Vk and Jk RSSs. Indeed, RSS replacements in hybrid or normal Igk and Igh loci confirmed ability of Igk versus Igh RSSs to promote robust diffusional joining. We propose that Igk evolved strong RSSs to mediate diffusional Vk-to-Jk joining; while Igh evolved weaker RSSs requisite for modulating VH joining by RAG scanning impediments.

Project description:Extended loop extrusion across the immunoglobulin heavy-chain (Igh) locus facilitates VH-DJH recombination in pro-B cells by aligning the VH and DJH segments for RAG-mediated cleavage. This cohesin-mediated process, resulting in global changes of the chromosome architecture in pro-B cells, depends on a 3-fold downregulation of the cohesin-release factor Wapl by Pax5-induced repression of the Wapl promoter. Here, we demonstrate that chromatin looping and VK-JK recombination at the Igk locus was insensitive to a 3-fold Wapl increase in pre-B cells. Given the equally low Wapl mRNA levels in pro-B and pre-B cells, the Wapl protein was unexpectedly expressed at a 2.2-fold higher level in pre-B cells compared to pro-B cells, which resulted in a distinct chromosomal architecture with normalized loop sizes in pre-B cells. High-resolution analysis of the Igk locus identified multiple internal loops, which likely juxtapose VK and JK elements to facilitate VK-JK recombination. The higher Wapl expression in Igm-transgenic pre-B cells prevented extended loop extrusion at the Igh locus, leading to recombination of only the 6 most 3’ proximal VH genes and to allelic exclusion of all other VH genes in pre-B cells. Hence, the different chromosomal architectures in pro-B and pre-B cells forced the Igh and Igk loci to assume distinct folding principles to undergo V gene recombination.

Project description:Deep sequencing has the potential to provide great insight into the composition of the antibody repertoire and is now widely used. To date there has not been a study directly comparing relative rearrangement frequencies obtained with unbiased amplification from genomic DNA (gDNA) and cDNA from the same set of cells to elucidate any differences. Here we use a recently developed method for unbiased amplification of gDNA and directly compare the data to the unbiased RNA IgK repertoire from the same pre-B cell pool. We find that ~20% of Vk genes have relative rearrangement frequencies > 2-fold up or down in the RNA vs DNA libraries, including many members of the Vk4, Vk3 and Vk6 families. Regression analysis indicates that Ikaros and E2A binding are associated with strong promoters. Within the pre-B repertoire, we found that the vastly unequal Vk gene rearrangement frequencies are best predicted by epigenetic marks of enhancers. In particular, the levels of newly arising H3K4me1 peaks associated with many Vk genes in pre-B cells are most predictive of rearrangement levels. Comparison of IgK rearrangements that occur in pro-B cells and pre-B cells from the same mice reveal a pro-B cell bias towards usage of Jk-distal Vk genes, particularly Vk 10-96 and surrounding genes. Regression analysis indicates that PU.1 binding is the highest predictor of high Vk gene rearrangement frequency in pro-B cells. Lastly, repertoires of iEk -/- pre-B cells reveal that the intronic enhancer actively influences Vk gene usage and displays a germline transcriptional sphere of influence extending to Vk 6-15, overlapping with the deficit in Jk proximal Vk gene usage. These represent previously unknown roles for iEk in addition to its major function in stimulating overall IgK rearrangement.

Project description:CTCF (CCCTC-binding factor) instructs 3D genome folding by anchoring or forestalling cohesin loop extrusion, but the exact mechanism remains obscure. Here, using clustered protocadherins (cPcdh) as model genes, we report that CTCF assists or facilitates cohesin loop extrusion by enhancing its processivity. Specifically, we show that, compared with the Pcdh alpha and gamma clusters, the Pcdh beta cluster is greatly affected upon CTCF Y226A/F228A mutation in the N-terminal domain. Given the long-range distance of the Pcdh beta cluster from the distal enhancer, this finding has interesting implications in CTCF regulation of cohesin processivity along the linear chromatin during DNA loop extrusion. In particular, the effect on cohesin processivity upon CTCF Y226A/F228A mutation is conspicuously similar to that of WAPL overexpression, suggesting that, in addition to the general view of blocking or forestalling cohesin, CTCF may also enhances or facilitates cohesin loop extrusion.