Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:We performed CSR-HTGTS-Seq, 3C-HTGTS, GRO-Seq and ChIP-Seq in mature splenic B cells with different stimulation study physiological roles of 3'CBEs in antibody class switching

Project description:We performed CSR-HTGTS-Seq, 3C-HTGTS, GRO-Seq and ChIP-Seq in mature splenic B cells with different stimulation study physiological roles of 3'CBEs in antibody class switching

Project description:We performed CSR-HTGTS-Seq, 3C-HTGTS, GRO-Seq and ChIP-Seq in mature splenic B cells with different stimulation study physiological roles of 3'CBEs in antibody class switching

Project description:The physiological role of 3’CBEs in antibody class switching

Project description:The physiological role of 3’CBEs in antibody class switching (3C-HTGTS)

Project description:The physiological role of 3’CBEs in antibody class switching (GRO-Seq)

Project description:The physiological role of 3’CBEs in antibody class switching (CSR-HTGTS-Seq)

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:In a B lymphocyte immunoglobulin heavy chain locus (IgH), a developmentally assembled V(D)J exon encoding an antibody variable region lies upstream of exons encoding a m constant region (Cm), allowing generation of mIgH chain transcripts and IgM-class antibodies1. Mouse IgH class switch recombination (CSR) replaces Cmwith one of 6 sets of constant region exons (CHs) that lie 100-200kb downstream1. Each CH is flanked upstream by a promoter, non-coding I-exon, and long repetitive switch (S) region1,2. Cytokines/activators induce specific I-promoter transcription and activation-induced cytidine deaminase (AID)2,3. AID is transcriptionally-targeted to initiate DNA breaks in Sm and activated downstream acceptor S regions, which are joined in deletional orientation to complete CSR4,5. 3’IgH regulatory region (3’IgHRR) enhancers control upstream I promoters and, thereby, CSR via linear competition involving I promoter/3’IgHRR interactions6-11. Here, we report that synapsis of regulatory elements, S regions and DSBs for CSR is achieved by chromatin loop extrusion. In naive B cells, 3’IgHRR enhancers and adjacent 3’IgH CTCF-binding elements (CBEs) interact via loop extrusion with the upstream Igh intronic enhancer (iEm)/Sm locale to generate dynamic 200kb 3’Igh basal loop. In CSR-activated B cells, induced transcription from I-promoters within this basal loop generates dynamic sub-loops that directionally align Sm and target S regions near the 3’IgHRR for CSR. In CH12F3 B lymphoma cells, inactivation of the constitutively active Ia-promoter abrogates looping and CSR to Sa, while activating transcription, looping, and CSR to upstream S regions. CBEs inserted upstream of Ia in convergent orientation with 3’IgH CBEs generate sub-loops that activate inversional Sa CSR. In I-promoter-deleted CH12F3 cells, this ectopic CBE-based sub-loop inactivates upstream S region CSR, while transcriptionally activating non-S region sequences adjacent to the inserted CBEs for S synapsis and CSR. Together, our findings implicate chromatin loop extrusion in the “unprecedented mechanism”5 by which Igh organization in cis promotes orientation-specific CSR DSB joining.