Project description:Activation-induced cytidine deaminase (AID)-initiated immunoglobulin heavy chain (Igh) class switch recombination (CSR) replaces donor Cμ constant region exons (CHs) with a downstream acceptor CH to generate different functional antibody isotypes. However, mechanisms governing orientation-specific productive CSR remain incompletely understood. Through analysing the characteristics of evolved constant regions and constructing diversified constant regions to recapitulate productive CSR in jawed vertebrates to systematically dissect productive CSR determinants, we found that switch topological configuration (STC), including transcriptional orientation, chromatin distance, and chromatin domain of Igh, determines orientation-specific joining of AID-initiated breaks for productive CSR. Long-distance CHs under co-oriented transcription within Igh domain foster predominantly deletional joining-mediated productive CSR. In contrast, oppositely transcribed and short-distance CHs affect end-joining bias via promoting diffusion-mediated inversional joining for CSR with lower efficiency. Moreover, AID-initiated breaks in different domains, facilitate more diffusion-mediated orientation-unbiased end-joining for non-productive CSR. Our findings uncover chromatin-intrinsic mechanisms safeguarding orientation-specific productive CSR throughout evolution.

Project description:Activation-induced cytidine deaminase (AID)-initiated immunoglobulin heavy chain (Igh) class switch recombination (CSR) replaces donor Cμ constant region exons (CHs) with a downstream acceptor CH to generate different functional antibody isotypes. However, mechanisms governing orientation-specific productive CSR remain incompletely understood. Through analysing the characteristics of evolved constant regions and constructing diversified constant regions to recapitulate productive CSR in jawed vertebrates to systematically dissect productive CSR determinants, we found that switch topological configuration (STC), including transcriptional orientation, chromatin distance, and chromatin domain of Igh, determines orientation-specific joining of AID-initiated breaks for productive CSR. Long-distance CHs under co-oriented transcription within Igh domain foster predominantly deletional joining-mediated productive CSR. In contrast, oppositely transcribed and short-distance CHs affect end-joining bias via promoting diffusion-mediated inversional joining for CSR with lower efficiency. Moreover, AID-initiated breaks in different domains, facilitate more diffusion-mediated orientation-unbiased end-joining for non-productive CSR. Our findings uncover chromatin-intrinsic mechanisms safeguarding orientation-specific productive CSR throughout evolution.

Project description:Activation-induced cytidine deaminase (AID)-initiated immunoglobulin heavy chain (Igh) class switch recombination (CSR) replaces donor Cμ constant region exons (CHs) with a downstream acceptor CH to generate different functional antibody isotypes. However, mechanisms governing orientation-specific productive CSR remain incompletely understood. Through analysing the characteristics of evolved constant regions and constructing diversified constant regions to recapitulate productive CSR in jawed vertebrates to systematically dissect productive CSR determinants, we found that switch topological configuration (STC), including transcriptional orientation, chromatin distance, and chromatin domain of Igh, determines orientation-specific joining of AID-initiated breaks for productive CSR. Long-distance CHs under co-oriented transcription within Igh domain foster predominantly deletional joining-mediated productive CSR. In contrast, oppositely transcribed and short-distance CHs affect end-joining bias via promoting diffusion-mediated inversional joining for CSR with lower efficiency. Moreover, AID-initiated breaks in different domains, facilitate more diffusion-mediated orientation-unbiased end-joining for non-productive CSR. Our findings uncover chromatin-intrinsic mechanisms safeguarding orientation-specific productive CSR throughout evolution.

Project description:During B cell development, RAG endonuclease cleaves immunoglobulin heavy chain (IgH) V, D, and J gene segments and orchestrates their fusion as deletional events that assemble a V(D)J exon in the same transcriptional orientation as adjacent Cμ constant region exons. In mice, six additional sets of constant region exons (CHs) lie 100-200kb downstream in the same transcriptional orientation as V(D)J and Cμ exons. Long repetitive switch (S) regions precede Cμ and downstream CHs. In mature B cells, class switch recombination (CSR) generates different antibody classes by replacing Cμ with a downstream CH. Activation Induced Cytidine Deaminase (AID) initiates CSR by promoting deamination lesions within Sμ and a downstream acceptor S region; these lesions are converted into DNA double strand breaks (DSBs) by general DNA repair factors. Productive CSR must occur in a deletional orientation by joining the upstream end of an Sμ DSB to the downstream end of an acceptor S region DSB. However, the relative frequency of deletional to inversional CSR junctions had not been measured. Thus, whether orientation-specific joining is a programmed mechanistic feature of CSR as it is for V(D)J recombination and, if so, how this is achieved was unknown. To address this question, we adapted high throughput genome wide translocation sequencing (HTGTS) into a highly sensitive DSB end-joining assay and applied it to endogenous AID-initiated S region DSBs. We find that CSR indeed is programmed to occur in a productive deletional orientation and does so via an unprecedented mechanism that involves in cis IgH organizational features in combination with frequent S region DSBs initiated by AID. We further implicate ATM-dependent DSB response (DSBR) factors in enforcing this mechanism and provide a solution to the enigma of why CSR is so reliant on the 53BP1 DSBR factor. We performed high-throughput genome-wide translocation sequencing (HTGTS) with different B cell genotypes that induces either I-SceI or AID-initiated DSBs as bait to study their joining pattern to AID-initiated S region breaks Please note that the 'ΔSγ1_2xI/ΔSµ_2xI-3' raw data files were analyzed twice with different reference assemblies to address specific points, and associated with both 'ΔSγ1_2xI_ΔSµ_2xI-3'.txt and Sγ1_2xI_ΔSµ_2xI-3'_trans-Sm.txt processed data files. As for the reference genome mm9_129_IgHC, it is a custom built generated based on mm9 (Bl6 line based mouse genome) and the partial genome sequence of another mouse line 129sv. It is not currently available in any public database however can be easily obtained either from the authors or self-built using information provided in the associated manuscript.

Project description:During B cell development, RAG endonuclease cleaves immunoglobulin heavy chain (IgH) V, D, and J gene segments and orchestrates their fusion as deletional events that assemble a V(D)J exon in the same transcriptional orientation as adjacent Cμ constant region exons. In mice, six additional sets of constant region exons (CHs) lie 100-200kb downstream in the same transcriptional orientation as V(D)J and Cμ exons. Long repetitive switch (S) regions precede Cμ and downstream CHs. In mature B cells, class switch recombination (CSR) generates different antibody classes by replacing Cμ with a downstream CH. Activation Induced Cytidine Deaminase (AID) initiates CSR by promoting deamination lesions within Sμ and a downstream acceptor S region; these lesions are converted into DNA double strand breaks (DSBs) by general DNA repair factors. Productive CSR must occur in a deletional orientation by joining the upstream end of an Sμ DSB to the downstream end of an acceptor S region DSB. However, the relative frequency of deletional to inversional CSR junctions had not been measured. Thus, whether orientation-specific joining is a programmed mechanistic feature of CSR as it is for V(D)J recombination and, if so, how this is achieved was unknown. To address this question, we adapted high throughput genome wide translocation sequencing (HTGTS) into a highly sensitive DSB end-joining assay and applied it to endogenous AID-initiated S region DSBs. We find that CSR indeed is programmed to occur in a productive deletional orientation and does so via an unprecedented mechanism that involves in cis IgH organizational features in combination with frequent S region DSBs initiated by AID. We further implicate ATM-dependent DSB response (DSBR) factors in enforcing this mechanism and provide a solution to the enigma of why CSR is so reliant on the 53BP1 DSBR factor.

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  constant region (C), allowing generation of IgH chain transcripts and IgM-class antibodies1. Mouse IgH class switch recombination (CSR) replaces C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 S 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 (iE)/S 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 S and target S regions near the 3’IgHRR for CSR. In CH12F3 B lymphoma cells, inactivation of the constitutively active I-promoter abrogates looping and CSR to S, while activating transcription, looping, and CSR to upstream S regions. CBEs inserted upstream of I in convergent orientation with 3’IgH CBEs generate sub-loops that activate inversional S 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.

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.

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.

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  constant region (C), allowing generation of IgH chain transcripts and IgM-class antibodies1. Mouse IgH class switch recombination (CSR) replaces C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 S 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 (iE)/S 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 S and target S regions near the 3’IgHRR for CSR. In CH12F3 B lymphoma cells, inactivation of the constitutively active I-promoter abrogates looping and CSR to S, while activating transcription, looping, and CSR to upstream S regions. CBEs inserted upstream of I in convergent orientation with 3’IgH CBEs generate sub-loops that activate inversional S 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.

Project description:The shieldin (SHLD) complex, composed of SHLD1, SHLD2, SHLD3 and MAD2L2/REV7, acts downstream of 53BP1 to counteract DNA double-strand break (DSB) end-resection and promote non-homologous end-joining (NHEJ). While 53BP1 is essential for immunoglobulin heavy chain class switch recombination (CSR), long-range V(D)J recombination and for repair of RAG-induced DSBs in XLF-deficient cells, the role of SHLD in these activities remains elusive. Here, we report that contrary to 53BP1, SHLD1 is dispensable for lymphocyte development and V(D)J recombination, even in the sensitized XLF-deficient background or for the joining of distant V(D)J segments. By contrast, SHLD1 restricts resection at AID-induced DSB ends in both NHEJ-proficient and NHEJ-deficient B cells, providing an end-protection mechanism that permits productive CSR. Finally, we show that this end-protection function is required for orientation-specific joining of AID-initiated DSBs. We propose that 53BP1 promotes V(D)J recombination and CSR through two distinct mechanisms; the synapsis of V(D)J segments and switch regions within chromatin independently of SHLD and the protection of AID-DSB ends against resection mediated by SHLD.