Chunguang Guo

Mechanisms of programmed DNA lesions and genomic instability in the immune system.

Chromosomal translocations involving antigen receptor loci are common in lymphoid malignancies. Translocations require DNA double-strand breaks (DSBs) at two chromosomal sites, their physical juxtaposition, and their fusion by end-joining. Ability of lymphocytes to generate diverse repertoires of antigen receptors and effector antibodies derives from programmed genomic alterations that produce DSBs. We discuss these lymphocyte-specific processes, with a focus on mechanisms that provide requisite DSB target specificity and mechanisms that suppress DSB translocation. We also discuss recent work that provides new insights into DSB repair pathways and the influences of three-dimensional genome organization on physiological processes and cancer genomes.

CTCF-binding elements mediate control of V(D)J recombination

Immunoglobulin heavy chain (IgH) variable region exons are assembled from VH, D and JH gene segments in developing B lymphocytes. Within the 2.7-megabase mouse Igh locus, V(D)J recombination is regulated to ensure specific and diverse antibody repertoires. Here we report in mice a key Igh V(D)J recombination regulatory region, termed intergenic control region 1 (IGCR1), which lies between the VH and D clusters. Functionally, IGCR1 uses CTCF looping/insulator factor-binding elements and, correspondingly, mediates Igh loops containing distant enhancers. IGCR1 promotes normal B-cell development and balances antibody repertoires by inhibiting transcription and rearrangement of DH-proximal VH gene segments and promoting rearrangement of distal VH segments. IGCR1 maintains ordered and lineage-specific VH(D)JH recombination by suppressing VH joining to D segments not joined to JH segments, and VH to DJH joins in thymocytes, respectively. IGCR1 is also required for feedback regulation and allelic exclusion of proximal VH-to-DJH recombination. Our studies elucidate a long-sought Igh V(D)J recombination control region and indicate a new role for the generally expressed CTCF protein.

ATM Damage Response and XLF Repair Factor are Functionally Redundant In Joining DNA Breaks

Classical non-homologous DNA end-joining (NHEJ) is a major mammalian DNA double-strand-break (DSB) repair pathway. Deficiencies for classical NHEJ factors, such as XRCC4, abrogate lymphocyte development, owing to a strict requirement for classical NHEJ to join V(D)J recombination DSB intermediates. The XRCC4-like factor (XLF; also called NHEJ1) is mutated in certain immunodeficient human patients and has been implicated in classical NHEJ; however, XLF-deficient mice have relatively normal lymphocyte development and their lymphocytes support normal V(D)J recombination. The ataxia telangiectasia-mutated protein (ATM) detects DSBs and activates DSB responses by phosphorylating substrates including histone H2AX. However, ATM deficiency causes only modest V(D)J recombination and lymphocyte developmental defects, and H2AX deficiency does not have a measurable impact on these processes. Here we show that XLF, ATM and H2AX all have fundamental roles in processing and joining DNA ends during V(D)J recombination, but that these roles have been masked by unanticipated functional redundancies. Thus, combined deficiency of ATM and XLF nearly blocks mouse lymphocyte development due to an inability to process and join chromosomal V(D)J recombination DSB intermediates. Combined XLF and ATM deficiency also severely impairs classical NHEJ, but not alternative end-joining, during IgH class switch recombination. Redundant ATM and XLF functions in classical NHEJ are mediated by ATM kinase activity and are not required for extra-chromosomal V(D)J recombination, indicating a role for chromatin-associated ATM substrates. Correspondingly, conditional H2AX inactivation in XLF-deficient pro-B lines leads to V(D)J recombination defects associated with marked degradation of unjoined V(D)J ends, revealing that H2AX has a role in this process.

Elements between the IgH variable (V) and diversity (D) clusters influence antisense transcription and lineage-specific V(D)J recombination

Ig and T-cell receptor (TCR) variable-region gene exons are assembled from component variable (V), diversity (D) and joining (J) gene segments during early B and T cell development. The RAG1/2 endonuclease initiates V(D)J recombination by introducing DNA double-strand breaks at borders of the germ-line segments. In mice, the Ig heavy-chain (IgH) locus contains, from 5′ to 3′, several hundred VH gene segments, 13 D segments, and 4 JH segments within a several megabase region. In developing B cells, IgH variable-region exon assembly is ordered with D to JH rearrangement occurring on both alleles before appendage of a VH segment. Also, IgH VH to DJH rearrangement does not occur in T cells, even though DJH rearrangements occur at low levels. In these contexts, V(D)J recombination is controlled by modulating substrate gene segment accessibility to RAG1/2 activity. To elucidate control elements, we deleted the 100-kb intergenic region that separates the VH and D clusters (generating ΔVH-D alleles). In both B and T cells, ΔVH-D alleles initiated high-level antisense and, at lower levels, sense transcription from within the downstream D cluster, with antisense transcripts extending into proximal VH segments. In developing T lymphocytes, activated germ-line antisense transcription was accompanied by markedly increased IgH D-to-JH rearrangement and substantial VH to DJH rearrangement of proximal IgH VH segments. Thus, the VH-D intergenic region, and likely elements within it, can influence silencing of sense and antisense germ-line transcription from the IgH D cluster and thereby influence targeting of V(D)J recombination.

Functional redundancy between repair factor XLF and damage response mediator 53BP1 in V(D)J recombination and DNA repair.

The classical nonhomologous DNA end-joining (C-NHEJ) double-strand break (DSB) repair pathway in mammalian cells maintains genome stability and is required for V(D)J recombination and lymphocyte development. Mutations in the XLF C-NHEJ factor or ataxia telangiectasia-mutated (ATM) DSB response protein cause radiosensitivity and immunodeficiency in humans. Although potential roles for XLF in C-NHEJ are unknown, ATM activates a general DSB response by phosphorylating substrates, including histone H2AX and 53BP1, which are assembled into chromatin complexes around DSBs. In mice, C-NHEJ, V(D)J recombination, and lymphocyte development are, at most, modestly impaired in the absence of XLF or ATM, but are severely impaired in the absence of both. Redundant functions of XLF and ATM depend on ATM kinase activity; correspondingly, combined XLF and H2AX deficiency severely impairs V(D)J recombination, even though H2AX deficiency alone has little impact on this process. These and other findings suggest that XLF may provide functions that overlap more broadly with assembled DSB response factors on chromatin. As one test of this notion, we generated mice and cells with a combined deficiency for XLF and 53BP1. In this context, 53BP1 deficiency, although leading to genome instability, has only modest effects on V(D)J recombination or lymphocyte development. Strikingly, we find that combined XLF/53BP1 deficiency in mice severely impairs C-NHEJ, V(D)J recombination, and lymphocyte development while also leading to general genomic instability and growth defects. We conclude that XLF is functionally redundant with multiple members of the ATM-dependent DNA damage response in facilitating C-NHEJ and discuss implications of our findings for potential functions of these factors.

CTCF-binding elements 1 and 2 in the Igh intergenic control region cooperatively regulate V(D)J recombination.

Significance Mice and humans generate diverse antibody repertoires through a genomic rearrangement process termed “V(D)J recombination” that assembles genetic regions that encode antigen-binding portions of antibodies by cutting and pasting together different combinations of V, D, and J gene segments. V(D)J recombination is strictly controlled to ensure generating a sufficiently large antibody repertoire to recognize any pathogen encountered and to minimize generation of self-reactive antibodies. Across the large antibody heavy-chain locus, V(D)J recombination regulation depends on a small control region, intergenic control region 1 (IGCR1), containing two CCCTC-binding factor–binding elements (CBEs) that bind a broadly expressed factor implicated in chromosomal looping. The current studies show that these two CBEs function cooperatively to mediate full IGCR1 functions and suggest a working model for how they do so. Ig heavy chain (IgH) variable region exons are assembled from V, D, and J gene segments during early B-lymphocyte differentiation. A several megabase region at the “distal” end of the mouse IgH locus (Igh) contains hundreds of VHs, separated by an intergenic region from Igh Ds, JHs, and constant region exons. Diverse primary Igh repertoires are generated by joining Vs, Ds, and Js in different combinations, with a given B cell productively assembling only one combination. The intergenic control region 1 (IGCR1) in the VH-to-D intergenic region regulates Igh V(D)J recombination in the contexts of developmental order, lineage specificity, and feedback from productive rearrangements. IGCR1 also diversifies IgH repertoires by balancing proximal and distal VH use. IGCR1 functions in all these regulatory contexts by suppressing predominant rearrangement of D-proximal VHs. Such IGCR1 functions were neutralized by simultaneous mutation of two CCCTC-binding factor (CTCF)-binding elements (CBE1 and CBE2) within it. However, it was unknown whether only one CBE mediates IGCR1 functions or whether both function in this context. To address these questions, we generated mice in which either IGCR1 CBE1 or CBE2 was replaced with scrambled sequences that do not bind CTCF. We found that inactivation of CBE1 or CBE2 individually led to only partial impairment of various IGCR1 functions relative to the far greater effects of inactivating both binding elements simultaneously, demonstrating that they function cooperatively to achieve full IGCR1 regulatory activity. Based on these and other findings, we propose an orientation-specific looping model for synergistic CBE1 and CBE2 functions.

Antigen-specific B-cell receptor sensitizes B cells to infection by influenza virus

Influenza A virus-specific B lymphocytes and the antibodies they produce protect against infection. However, the outcome of interactions between an influenza haemagglutinin-specific B cell via its receptor (BCR) and virus is unclear. Through somatic cell nuclear transfer we generated mice that harbour B cells with a BCR specific for the haemagglutinin of influenza A/WSN/33 virus (FluBI mice). Their B cells secrete an immunoglobulin gamma 2b that neutralizes infectious virus. Whereas B cells from FluBI and control mice bind equivalent amounts of virus through interaction of haemagglutinin with surface-disposed sialic acids, the A/WSN/33 virus infects only the haemagglutinin-specific B cells. Mere binding of virus is not sufficient for infection of B cells: this requires interactions of the BCR with haemagglutinin, causing both disruption of antibody secretion and FluBI B-cell death within 18 h. In mice infected with A/WSN/33, lung-resident FluBI B cells are infected by the virus, thus delaying the onset of protective antibody release into the lungs, whereas FluBI cells in the draining lymph node are not infected and proliferate. We propose that influenza targets and kills influenza-specific B cells in the lung, thus allowing the virus to gain purchase before the initiation of an effective adaptive response.

Functional redundancy between the XLF and DNA-PKcs DNA repair factors in V(D)J recombination and nonhomologous DNA end joining

Classical nonhomologous end joining (C-NHEJ) is a major mammalian DNA double-strand break (DSB) repair pathway that is required for assembly of antigen receptor variable region gene segments by V(D)J recombination. Recombination activating gene endonuclease initiates V(D)J recombination by generating DSBs between two V(D)J coding gene segments and flanking recombination signal sequences (RS), with the two coding ends and two RS ends joined by C-NHEJ to form coding joins and signal joins, respectively. During C-NHEJ, recombination activating gene factor generates two coding ends as covalently sealed hairpins and RS ends as blunt 5′-phosphorylated DSBs. Opening and processing of coding end hairpins before joining by C-NHEJ requires the DNA-dependent protein kinase catalytic subunit (DNA-PKcs). However, C-NHEJ of RS ends, which do not require processing, occurs relatively normally in the absence of DNA-PKcs. The XRCC4-like factor (XLF) is a C-NHEJ component that is not required for C-NHEJ of chromosomal signal joins or coding joins because of functional redundancy with ataxia telangiectasia mutated kinase, a protein that also has some functional overlap with DNA-PKcs in this process. Here, we show that XLF has dramatic functional redundancy with DNA-PKcs in the V(D)J SJ joining process, which is nearly abrogated in their combined absence. Moreover, we show that XLF functionally overlaps with DNA-PKcs in normal mouse development, promotion of genomic stability in mouse fibroblasts, and in IgH class switch recombination in mature B cells. Our findings suggest that DNA-PKcs has fundamental roles in C-NHEJ processes beyond end processing that have been masked by functional overlaps with XLF.

PAIRing for Distal Igh Locus V(D)J Recombination

In this issue of Immunity Ebert et al. (2011) defined the lineage- and stage-specific Pax5-dependent cis-sequences termed PAIR elements in the distal region of the mouse heavy chain immunoglobulin locus (Igh). These sequences may have a role in long-range IgH V(D)J recombination.