Class switch recombination: an emerging mechanism

SHLD2 promotes class switch recombination by preventing inactivating deletions within the Igh locus

The newly identified shieldin complex, composed of SHLD1, SHLD2, SHLD3, and REV7, lies downstream of 53BP1 and acts to inhibit DNA resection and promote NHEJ. Here, we show that Shld2^-/- mice have defective class switch recombination (CSR) and that loss of SHLD2 can suppress the embryonic lethality of a Brca1^Δ11 mutation, highlighting its role as a key effector of 53BP1. Lymphocyte development and RAG1/2-mediated recombination were unaffected by SHLD2 deficiency. Interestingly, a significant fraction of Shld2^-/- primary B-cells and 53BP1- and shieldin-deficient CH12F3-2 B-cells permanently lose expression of immunoglobulin upon induction of CSR; this population of Ig-negative cells is also seen in other NHEJ-deficient cells and to a much lesser extent in WT cells. This loss of Ig is due to recombination coupled with overactive resection and loss of coding exons in the downstream acceptor constant region. Collectively, these data show that SHLD2 is the key effector of 53BP1 and critical for CSR in vivo by suppressing large deletions within the Igh locus.

AID Phosphorylation Regulates Mismatch Repair-Dependent Class Switch Recombination and Affinity Maturation

Activation-induced cytidine deaminase (AID) generates U:G mismatches in Ig genes that can be converted into untemplated mutations during somatic hypermutation or DNA double-strand breaks during class switch recombination (CSR). Null mutations in UNG and MSH2 demonstrate the complementary roles of the base excision repair (BER) and mismatch repair pathways, respectively, in CSR. Phosphorylation of AID at serine 38 was previously hypothesized to regulate BER during CSR, as the AID phosphorylation mutant, AID(S38A), cannot interact with APE1, a BER protein. Consistent with these findings, we observe a complete block in CSR in AID^S38A/S38AMSH2^-/- mouse B cells that correlates with an impaired mutation frequency at 5'Sμ. Similarly, somatic hypermutation is almost negligible at the JH4 intron in AID^S38A/S38AMSH2^-/- mouse B cells, and, consistent with this, NP-specific affinity maturation in AID^S38A/S38AMSH2^-/- mice is not significantly elevated in response to NP-CGG immunization. Surprisingly, AID^S38A/S38AUNG^-/- mouse B cells also cannot complete CSR or affinity maturation despite accumulating significant mutations in 5'Sμ as well as the JH4 intron. These data identify a novel role for phosphorylation of AID at serine 38 in mismatch repair-dependent CSR and affinity maturation.

Three-dimensional architecture of the IgH locus facilitates class switch recombination

Immunoglobulin (Ig) class switch recombination (CSR) is responsible for diversification of antibody effector function during an immune response. This region-specific recombination event, between repetitive switch (S) DNA elements, is unique to B lymphocytes and is induced by activationinduced deaminase (AID). CSR is critically dependent on transcription of noncoding RNAs across S regions. However, mechanistic insight regarding this process has remained unclear. New studies indicate that long-range intrachromosomal interactions among IgH transcriptional elements organize the formation of the S/S synaptosome, as a prerequisite for CSR. This three-dimensional chromatin architecture simultaneously brings promoters and enhancers into close proximity to facilitate transcription. Here, we recount how transcription across S DNA promotes accumulation of RNA polymerase II, leading to the introduction of activating chromatin modifications and hyperaccessible chromatin that is amenable to AID activity.

Non-homologous end joining mediated DNA repair is impaired in the NUP98-HOXD13 mouse model for myelodysplastic syndrome

Chromosomal translocations typically impair cell differentiation and often require secondary mutations for malignant transformation. However, the role of a primary translocation in the development of collaborating mutations is debatable. To delineate the role of leukemic translocation NUP98-HOXD13 (NHD13) in secondary mutagenesis, DNA break and repair mechanisms in stimulated mouse B lymphocytes expressing NHD13 were analyzed. Our results showed significantly reduced expression of non-homologous end joining (NHEJ)-mediated DNA repair genes, DNA Pkcs, DNA ligase4, and Xrcc4 leading to cell cycle arrest at G2/M phase. Our results showed that expression of NHD13 fusion gene resulted in impaired NHEJ-mediated DNA break repair.

AID targeting is dependent on RNA polymerase II pausing

Activation induced deaminase (AID) is globally targeted to immunoglobulin loci, preferentially focused to switch (S) regions and variable (V) regions, and prone to attack hotspot motifs. Nevertheless, AID deamination is not exclusive to Ig loci and the rules regulating AID targeting remain unclear. Transcription is critically required for class switch recombination and somatic hypermutation. Here, I consider the unique features associated with S region transcription leading to RNA polymerase II pausing, that in turn promote the introduction of activating chromatin remodeling, histone modifications and recruitment of AID to targeted S regions. These findings allow for a better understanding of the interplay between transcription, AID targeting and mistargeting to Ig and non-Ig loci.

Growth factor independence 1 (Gfi1) as a regulator of lymphocyte development and activation

T- and B-lymphocytes are important elements in the immune defense repertoire of higher organisms. The development and function of lymphoid cells is regulated at many levels one being the control of gene expression by transcription factors. The zinc finger transcriptional repressor Gfi1 has emerged as a factor that is critically implicated in the commitment of precursor cells for the lymphoid lineage. In addition, Gfi1 controls distinct stages of early T- or B-lymphoid development and is also critical for their maturation, activation and effector function. From many years of work, a picture emerges in which Gfi1 is part of a complicated, but well orchestrated network of interdependent regulators, most of which impinge on lymphoid development and activation by transcriptional regulation. Biochemical studies show that Gfi1 is part of a large DNA binding multi-protein complex that enables histone modifications, but may also control alternative pre mRNA splicing. Many insights into the biological role of Gfi1 have been gained through the study of gene deficient mice that have defects in B- and T-cell differentiation, in T-cell selection and polarization processes and in the response of mature B- and T-cells towards antigen. Most importantly, the defects seen in Gfi1 deficient mice also point to roles of Gfi1 in diseases of the immune system that involve auto-immune responses and acute lymphoid leukemia and lymphoma.

Switch region identity plays an important role in Ig class switch recombination

Ig class switch recombination (CSR) is regulated through long-range intrachromosomal interactions between germline transcript promoters and enhancers to initiate transcription and create chromatin accessible to activation-induced deaminase attack. CSR occurs between switch (S) regions that flank Cmu and downstream C(H) regions and functions via an intrachromosomal deletional event between the donor Smicro region and a downstream S region. It is unclear to what extent S region primary sequence influences differential targeting of CSR to specific isotypes. We address this issue in this study by generating mutant mice in which the endogenous Sgamma3 region was replaced with size-matched Sgamma1 sequence. B cell activation conditions are established that support robust gamma3 and gamma1 germline transcript expression and stimulate IgG1 switching but suppress IgG3 CSR. We found that the Sgamma1 replacement allele engages in micro-->gamma3 CSR, whereas the intact allele is repressed. We conclude that S region identity makes a significant contribution to CSR. We propose that the Sgamma1 region is selectively targeted for CSR following the induction of an isotype-specific factor that targets the S region and recruits CSR machinery.

Toll-like receptors and B-cell receptors synergize to induce immunoglobulin class-switch DNA recombination: relevance to microbial antibody responses

Differentiation of naïve B cells, including immunoglobulin class-switch DNA recombination, is critical for the immune response and depends on the extensive integration of signals from the B-cell receptor (BCR), tumor necrosis factor (TNF) family members, Toll-like receptors (TLRs), and cytokine receptors. TLRs and BCR synergize to induce class-switch DNA recombination in T cell-dependent and T cell-independent antibody responses to microbial pathogens. BCR triggering together with simultaneous endosomal TLR engagement leads to enhanced B-cell differentiation and antibody responses. Te requirement of both BCR and TLR engagement would ensure appropriate antigen-specific activation in an infection. Co-stimulation of TLRs and BCR likely plays a significant role in anti-microbial antibody responses to contain pathogen loads until the T cell-dependent antibody responses peak. Furthermore, the temporal sequence of different signals is also critical for optimal B cell responses, as exemplified by the activation of B cells by initial TLR engagement, leading to the up-regulation of co-stimulatory CD80 and MCH-II receptors, which result in more efficient interactions with T cells, thereby enhancing the germinal center reaction and antibody affinity maturation. Overall, BCR and TLR stimulation and the integration with signals from the pathogen or immune cells and their products determine the ensuing B-cell antibody response.

S region sequence, RNA polymerase II, and histone modifications create chromatin accessibility during class switch recombination

Immunoglobulin class switch recombination is governed by long-range interactions between enhancers and germline transcript promoters to activate transcription and modulate chromatin accessibility to activation-induced cytidine deaminase (AID). However, mechanisms leading to the differential targeting of AID to switch (S) regions but not to constant (C_H) regions remain unclear. We show that S and C_H regions are dynamically modified with histone marks that are associated with active and repressed chromatin states, respectively. Chromatin accessibility is superimposable with the activating histone modifications, which extend throughout S regions irrespective of length. High density elongating RNA polymerase II (RNAP II) is detected in S regions, suggesting that the transcription machinery has paused and stalling is abolished by deletion of the S region. We propose that RNAP II enrichment facilitates recruitment of histone modifiers to generate accessibility. Thus, the histone methylation pattern produced by transcription localizes accessible chromatin to S regions, thereby focusing AID attack.

Binding of LBP-1a to specific immunoglobulin switch regions in vivo correlates with specific repression of class switch recombination

Upon stimulation of mature B cells, class switch recombination (CSR) can alter the specific immunoglobulin heavy chain constant region that is expressed. In a tissue culture cell line, we previously demonstrated that inhibition of late SV40 factor (LSF) family members enhanced IgM to IgA CSR. Here, isotype specificity of CSR regulation by LSF family members is addressed in primary mouse splenic B cells. First, we demonstrate that leader-binding protein-1a (LBP-1a) is the prevalent family member in B lymphocytes. Second, we demonstrate by ChIP that LBP-1a binds genomic sequences around mouse switch (S) regions in an isotype-specific manner, in accordance with computational predictions: binding is observed to Smu and Salpha, but not to the tested Sgamma1, regions. Importantly, binding of LBP-1a is tightly regulated, with occupancy at genomic S regions dramatically decreasing following LPS stimulation. Finally, the consequence of DNA-binding by LBP-1a is determined using bone marrow chimeric mice in which LSF/LBP-1 activity is inhibited in hematopoietic lineages. Upon in vitro stimulation of such primary B cells, CSR occurs with a higher efficiency to IgA, but not to IgG1. These results are supportive of a model whereby LBP-1a represses CSR in an isotype-specific manner via direct interaction with S regions involved in the recombination.

Timing matters: error-prone gap filling and translesion synthesis in immunoglobulin gene hypermutation

By temporarily deferring the repair of DNA lesions encountered during replication, the bypass of DNA damage is critical to the ability of cells to withstand genomic insults. Damage bypass can be achieved either by recombinational mechanisms that are generally accurate or by a process called translesion synthesis. Translesion synthesis involves replacing the stalled replicative polymerase with one of a number of specialized DNA polymerases whose active sites are able to tolerate a distorted or damaged DNA template. While this property allows the translesion polymerases to synthesize across damaged bases, it does so with the trade-off of an increased mutation rate. The deployment of these enzymes must therefore be carefully regulated. In addition to their important role in general DNA damage tolerance and mutagenesis, the translesion polymerases play a crucial role in converting the products of activation induced deaminase-catalysed cytidine deamination to mutations during immunoglobulin gene somatic hypermutation. In this paper, we specifically consider the control of translesion synthesis in the context of the timing of lesion bypass relative to replication fork progression and arrest at sites of DNA damage. We then examine how recent observations concerning the control of translesion synthesis might help refine our view of the mechanisms of immunoglobulin gene somatic hypermutation.

Genetic evidence for single-strand lesions initiating Nbs1-dependent homologous recombination in diversification of Ig v in chicken B lymphocytes

Homologous recombination (HR) is initiated by DNA double-strand breaks (DSB). However, it remains unclear whether single-strand lesions also initiate HR in genomic DNA. Chicken B lymphocytes diversify their Immunoglobulin (Ig) V genes through HR (Ig gene conversion) and non-templated hypermutation. Both types of Ig V diversification are initiated by AID-dependent abasic-site formation. Abasic sites stall replication, resulting in the formation of single-stranded gaps. These gaps can be filled by error-prone DNA polymerases, resulting in hypermutation. However, it is unclear whether these single-strand gaps can also initiate Ig gene conversion without being first converted to DSBs. The Mre11-Rad50-Nbs1 (MRN) complex, which produces 3′ single-strand overhangs, promotes the initiation of DSB-induced HR in yeast. We show that a DT40 line expressing only a truncated form of Nbs1 (Nbs1^p70) exhibits defective HR-dependent DSB repair, and a significant reduction in the rate—though not the fidelity—of Ig gene conversion. Interestingly, this defective gene conversion was restored to wild type levels by overproduction of Escherichia coli SbcB, a 3′ to 5′ single-strand–specific exonuclease, without affecting DSB repair. Conversely, overexpression of chicken Exo1 increased the efficiency of DSB-induced gene-targeting more than 10-fold, with no effect on Ig gene conversion. These results suggest that Ig gene conversion may be initiated by single-strand gaps rather than by DSBs, and, like SbcB, the MRN complex in DT40 may convert AID-induced lesions into single-strand gaps suitable for triggering HR. In summary, Ig gene conversion and hypermutation may share a common substrate—single-stranded gaps. Genetic analysis of the two types of Ig V diversification in DT40 provides a unique opportunity to gain insight into the molecular mechanisms underlying the filling of gaps that arise as a consequence of replication blocks at abasic sites, by HR and error-prone polymerases.

An important class of chemotherapeutic drugs used in the treatment of cancer induces DNA damage that interferes with DNA replication. The resulting block to replication results in the formation of single-strand gaps in DNA. These gaps can be filled by specialized DNA polymerases, a process associated with the introduction of mutations or by recombination with an undamaged segment of DNA with an identical or similar sequence. Our work shows that diversification of the antibody genes in the chicken B cell line DT40, which is initiated by localized replication-stalling DNA damage, proceeds by formation of a single-strand intermediate. These gaps are generated by the action of a specific nuclease complex, comprising the Mre11, Rad50, and Nbs1 proteins, which have previously been implicated in the initiation of homologous recombination from double-strand breaks. However, in this context, their dysfunction can be reversed by the expression of a bacterial single-strand–specific nuclease, SbcB. Antibody diversification in DT40 thus provides an excellent model for studying the process of replication-stalling DNA damage and will allow a more detailed understanding of the mechanisms underlying gap repair and cellular tolerance of chemotherapeutic agents.

Chronic lymphocytic leukaemia: an immunobiology approach

B cell chronic lymphocytic leukaemia (CLL) is the most common adult leukaemia that follows an extremely variable clinical course. Several important prognostic parameters defining pathogenic and clinical subgroups of CLL have been identified and validated recently. The biological significance of immunoglobulin (Ig) heavy chain variable region gene (IgHV) mutational status and associated ZAP-70 over-expression, CD38 and chromosomal aberrations have enabled to identify patients at high risk for early disease progression and inferior survival. Moreover, studies of the B cell antigen receptor (BCR) structure and receptor signalling have been most helpful in revealing some new aspects of the biology of this disease. In particular, the analysis of IG genes has revealed that the expressed IgHV/IgKV/IgLV gene repertoires of CLL cells differ from those of normal B cells. A further unique feature of the CLL IG repertoire is the existence of subsets of cases with "stereotyped" BCRs. Accumulating molecular and phenotypic data support the notion that CLL development and evolution is not a simple scholastic event and strongly indicates a role for antigen in driving the cell of origin for at least some subsets of CLL cases.

AID- and Ung-dependent generation of staggered double-strand DNA breaks in immunoglobulin class switch DNA recombination: a post-cleavage role for AID

Class switch DNA recombination (CSR) substitutes an immunoglobulin (Ig) constant heavy chain (C(H)) region with a different C(H) region, thereby endowing an antibody with different biological effector functions. CSR requires activation-induced cytidine deaminase (AID) and occurrence of double-strand DNA breaks (DSBs) in S regions of upstream and downstream C(H) region genes. DSBs are critical for CSR and would be generated through deamination of dC by AID, subsequent dU deglycosylation by uracil DNA glycosylase (Ung) and nicking by apurinic/apyrimidic endonuclease (APE) of nearby abasic sites on opposite DNA strands. We show here that in human and mouse B cells, S region DSBs can be generated in an AID- and Ung-independent fashion. These DSBs are blunt and 5'-phosphorylated. In B cells undergoing CSR, blunt and 5'-phosphorylated DSBs are processed in an AID- and Ung-dependent fashion to yield staggered DNA ends. Blunt and 5'-phosphorylated DSBs can be readily detected in human and mouse AID- or Ung-deficient B cells. These B cells are CSR defective, but show evidence of intra-S region recombination. Forced expression of AID in AID-negative B cells converts blunt S region DSBs to staggered DSBs. Conversely, forced expression of dominant negative AID or inhibition of Ung by Ung inhibitor (Ugi) in switching B cells abrogates the emergence of staggered DSBs and concomitant CSR. Thus, AID and Ung generate staggered DSBs not only by cleaving intact double-strand DNA, but also by processing blunt DSB ends, whose generation is AID- and Ung-independent, thereby outlining a post-cleavage role for AID in CSR.

Mechanism and regulation of class switch recombination

Antibody class switching occurs in mature B cells in response to antigen stimulation and costimulatory signals. It occurs by a unique type of intrachromosomal deletional recombination within special G-rich tandem repeated DNA sequences [called switch, or S, regions located upstream of each of the heavy chain constant (C(H)) region genes, except Cdelta]. The recombination is initiated by the B cell-specific activation-induced cytidine deaminase (AID), which deaminates cytosines in both the donor and acceptor S regions. AID activity converts several dC bases to dU bases in each S region, and the dU bases are then excised by the uracil DNA glycosylase UNG; the resulting abasic sites are nicked by apurinic/apyrimidinic endonuclease (APE). AID attacks both strands of transcriptionally active S regions, but how transcription promotes AID targeting is not entirely clear. Mismatch repair proteins are then involved in converting the resulting single-strand DNA breaks to double-strand breaks with DNA ends appropriate for end-joining recombination. Proteins required for the subsequent S-S recombination include DNA-PK, ATM, Mre11-Rad50-Nbs1, gammaH2AX, 53BP1, Mdc1, and XRCC4-ligase IV. These proteins are important for faithful joining of S regions, and in their absence aberrant recombination and chromosomal translocations involving S regions occur.

S-S synapsis during class switch recombination is promoted by distantly located transcriptional elements and activation-induced deaminase

Molecular mechanisms underlying synapsis of activation-induced deaminase (AID)-targeted S regions during class switch recombination (CSR) are poorly understood. By using chromosome conformation capture techniques, we found that in B cells, the Emicro and 3'Ealpha enhancers were in close spatial proximity, forming a unique chromosomal loop configuration. B cell activation led to recruitment of the germline transcript (GLT) promoters to the Emicro:3'Ealpha complex in a cytokine-dependent fashion. This structure facilitated S-S synapsis because Smicro was proximal to Emicro and a downstream S region was corecruited with the targeted GLT promoter to Emicro:3'Ealpha. We propose that GLT promoter association with the Emicro:3'Ealpha complex creates an architectural scaffolding that promotes S-S synapsis during CSR and that these interactions are stabilized by AID. Thus, the S-S synaptosome is formed as a result of the self-organizing transcription system that regulates GLT expression and may serve to guard against spurious chromosomal translocations.

NF-kappa B binds to the immunoglobulin S gamma 3 region in vivo during class switch recombination

Ig class switch recombination (CSR) is dependent upon the expression of activation-induced deaminase and targeted to specific isotypes by germ-line transcript expression and isotype-specific factors. NF-kappaB plays critical roles in multiple aspects of B cell biology and has been implicated in the mechanism of CSR by in vitro binding assays and altered S/S junctions derived from NF-kappaB p50-deficient mice. However, the pleiotropic contributions of NF-kappaB to gene expression in B cells has made discerning a direct role for NF-kappaB in CSR difficult. We now observe that binding of NF-kappaB components p50 and p65 is detected on Sgamma3 in vivo following lipopolysaccharide (LPS) activation and repressed by LPS + IL-4, suggesting a direct role for this factor in CSR. In vivo footprinting confirms occupancy of a previously defined NF-kappaB recognition site in Sgamma3 with the same temporal kinetics as found in the chromatin immunoprecipitation analysis. Binding of NF-kappaB components p50 and p65 was also detected on Sgamma1 following B cell activation. H3 histone hyper acetylation at Sgamma1 is strongly correlated with NF-kappaB binding, suggesting that NF-kappaB mediates chromatin remodeling in the Sgamma3 and Sgamma1 region.

Evolution of the Immunoglobulin Heavy Chain Class Switch Recombination Mechanism

To mount an optimum immune response, mature B lymphocytes can change the class of expressed antibody from IgM to IgG, IgA, or IgE through a recombination/deletion process termed immunoglobulin heavy chain (IgH) class switch recombination (CSR). CSR requires the activation-induced cytidine deaminase (AID), which has been shown to employ single-stranded DNA as a substrate in vitro. IgH CSR occurs within and requires large, repetitive sequences, termed S regions, which are parts of germ line transcription units (termed "C(H) genes") that are composed of promoters, S regions, and individual IgH constant region exons. CSR requires and is directed by germ line transcription of participating C(H) genes prior to CSR. AID deamination of cytidines in S regions appears to lead to S region double-stranded breaks (DSBs) required to initiate CSR. Joining of two broken S regions to complete CSR exploits the activities of general DNA DSB repair mechanisms. In this chapter, we discuss our current knowledge of the function of S regions, germ line transcription, AID, and DNA repair in CSR. We present a model for CSR in which transcription through S regions provides DNA substrates on which AID can generate DSB-inducing lesions. We also discuss how phosphorylation of AID may mediate interactions with cofactors that facilitate access to transcribed S regions during CSR and transcribed variable regions during the related process of somatic hypermutation (SHM). Finally, in the context of this CSR model, we further discuss current findings that suggest synapsis and joining of S region DSBs during CSR have evolved to exploit general mechanisms that function to join widely separated chromosomal DSBs.

Tying the loose ends together in DNA double strand break repair with 53BP1

To maintain genomic stability and ensure the fidelity of chromosomal transmission, cells respond to various forms of genotoxic stress, including DNA double-stranded breaks (DSBs), through the activation of DNA damage response signaling networks. In response to DSBs as induced by ionizing radiation (IR), during DNA replication, or through immunoglobulin heavy chain (IgH) rearrangements in B cells of lymphoid origin, the phosphatidyl inositol-like kinase (PIK) kinases ATM (mutated in ataxia telangiectasia), ATR (ATM and Rad3-related kinase), and the DNA-dependent protein kinase (DNA-PK) activate signaling pathways that lead to DSB repair. DSBs are repaired by either of two major, non-mutually exclusive pathways: homologous recombination (HR) that utilizes an undamaged sister chromatid template (or homologous chromosome) and non- homologous end joining (NHEJ), an error prone mechanism that processes and joins broken DNA ends through the coordinated effort of a small set of ubiquitous factors (DNA-PKcs, Ku70, Ku80, artemis, Xrcc4/DNA lig IV, and XLF/Cernunnos). The PIK kinases phosphorylate a variety of effector substrates that propagate the DNA damage signal, ultimately resulting in various biological outputs that influence cell cycle arrest, transcription, DNA repair, and apoptosis. A variety of data has revealed a critical role for p53-binding protein 1 (53BP1) in the cellular response to DSBs including various aspects of p53 function. Importantly, 53BP1 plays a major role in suppressing translocations, particularly in B and T cells. This report will review past experiments and current knowledge regarding the role of 53BP1 in the DNA damage response.

The in vivo pattern of AID targeting to immunoglobulin switch regions deduced from mutation spectra in msh2-/- ung-/- mice

Immunoglobulin (Ig) class switching is initiated by deamination of C→U within the immunoglobulin heavy chain locus, catalyzed by activation-induced deaminase (AID). In the absence of uracil-DNA glycosylase (UNG) and the homologue of bacterial MutS (MSH)–2 mismatch recognition protein, the resultant U:G lesions are not processed into switching events but are fixed by replication allowing sites of AID-catalyzed deamination to be identified by the resulting C→T mutations. We find that AID targets cytosines in both donor and acceptor switch regions (S regions) with the deamination domains initiating ∼150 nucleotides 3′ of the I exon start sites and extending over several kilobases (the IgH intronic enhancer is spared). Culturing B cells with interleukin 4 or interferon γ specifically enhanced deamination around Sγ1 and Sγ2a, respectively. Mutation spectra suggest that, in the absence of UNG and MSH2, AID may occasionally act at the μ switch region in an apparently processive manner, but there is no marked preference for targeting of the transcribed versus nontranscribed strand (even in areas capable of R loop formation). The data are consistent with switch recombination being triggered by transcription-associated, strand-symmetric AID-mediated deamination at both donor and acceptor S regions with cytokines directing isotype specificity by potentiating AID recruitment to the relevant acceptor S region.

AID-dependent histone acetylation is detected in immunoglobulin S regions

Class switch recombination (CSR) is regulated by the expression of activation-induced deaminase (AID) and germline transcripts (GLTs). AID-dependent double-strand breaks (DSBs) are introduced into switch (S) regions and stimulate CSR. Although histone acetylation (Ac) has been well documented in transcription regulation, its role in DNA damage repair remains largely unexplored. The 1B4.B6 B cell line and normal splenic B cells were activated to undergo CSR and analyzed for histone Ac by chromatin immunoprecipitation (ChIP). A detailed study of the Iγ3-Sγ3-Cγ3 locus demonstrated that acetylated histones are focused to the Iγ3 exon and the Sγ3 region but not to the intergenic areas. Histone H3 Ac is strongly correlated with GLT expression at four S regions, whereas H4 Ac was better associated with B cell activation and AID expression. To more directly examine the relationship between H4 Ac and AID, LPS-activated AID KO and WT B cells were analyzed and express comparable levels of GLTs. In AID-deficient B cells, both histones H3 and H4 are reduced where H4 is more severely affected as compared with WT cells. Our findings raise the intriguing possibility that histone H4 Ac at S regions is a marker for chromatin modifications associated with DSB repair during CSR.