CTCF orchestrates long-range cohesin-driven V(D)J recombinational scanning.

The RAG endonuclease initiates Igh locus V(D)J recombination in progenitor (pro)-B cells1. Upon binding a recombination centre-based JH, RAG scans upstream chromatin via loop extrusion, potentially mediated by cohesin, to locate Ds and assemble a DJH-based recombination centre2. CTCF looping factor-bound elements (CBEs) within IGCR1 upstream of Ds impede RAG scanning3-5; however, their inactivation allows scanning to proximal VHs, where additional CBEs activate rearrangement and impede scanning any further upstream5. Distal VH utilization is thought to involve diffusional access to the recombination centre following large-scale Igh locus contraction6-8. Here we test the potential of linear RAG scanning to mediate distal VH usage in G1-arrested v-Abl pro-B cell lines9, which undergo robust D-to-JH but little VH-to-DJH rearrangements, presumably owing to lack of locus contraction2,5. Through an auxin-inducible approach10, we degraded the cohesin component RAD2110-12 or CTCF12,13 in these G1-arrested lines. Degradation of RAD21 eliminated all V(D)J recombination and interactions associated with RAG scanning, except for reecombination centre-located DQ52-to-JH joining, in which synapsis occurs by diffusion2. Remarkably, while degradation of CTCF suppressed most CBE-based chromatin interactions, it promoted robust recombination centre interactions with, and robust VH-to-DJH joining of, distal VHs, with patterns similar to those of 'locus-contracted' primary pro-B cells. Thus, downmodulation of CTCF-bound scanning-impediment activity promotes cohesin-driven RAG scanning across the 2.7-Mb Igh locus.

The fundamental role of chromatin loop extrusion in physiological V(D)J recombination.

The RAG endonuclease initiates Igh V(D)J assembly in B cell progenitors by joining D segments to JH segments, before joining upstream VH segments to DJH intermediates1. In mouse progenitor B cells, the CTCF-binding element (CBE)-anchored chromatin loop domain2 at the 3' end of Igh contains an internal subdomain that spans the 5' CBE anchor (IGCR1)3, the DH segments, and a RAG-bound recombination centre (RC)4. The RC comprises the JH-proximal D segment (DQ52), four JH segments, and the intronic enhancer (iEµ)5. Robust RAG-mediated cleavage is restricted to paired V(D)J segments flanked by complementary recombination signal sequences (12RSS and 23RSS)6. D segments are flanked downstream and upstream by 12RSSs that mediate deletional joining with convergently oriented JH-23RSSs and VH-23RSSs, respectively6. Despite 12/23 compatibility, inversional D-to-JH joining via upstream D-12RSSs is rare7,8. Plasmid-based assays have attributed the lack of inversional D-to-JH joining to sequence-based preference for downstream D-12RSSs9, as opposed to putative linear scanning mechanisms10,11. As RAG linearly scans convergent CBE-anchored chromatin loops4,12-14, potentially formed by cohesin-mediated loop extrusion15-18, we revisited its scanning role. Here we show that the chromosomal orientation of JH-23RSS programs RC-bound RAG to linearly scan upstream chromatin in the 3' Igh subdomain for convergently oriented D-12RSSs and, thereby, to mediate deletional joining of all D segments except RC-based DQ52, which joins by a diffusion-related mechanism. In a DQ52-based RC, formed in the absence of JH segments, RAG bound by the downstream DQ52-RSS scans the downstream constant region exon-containing 3' Igh subdomain, in which scanning can be impeded by targeted binding of nuclease-dead Cas9, by transcription through repetitive Igh switch sequences, and by the 3' Igh CBE-based loop anchor. Each scanning impediment focally increases RAG activity on potential substrate sequences within the impeded region. High-resolution mapping of chromatin interactions in the RC reveals that such focal RAG targeting is associated with corresponding impediments to the loop extrusion process that drives chromatin past RC-bound RAG.