Activation-induced cytidine deaminase initiates immunoglobulin gene conversion and hypermutation by a common intermediate

Depending on the species and the lymphoid organ, activation-induced cytidine deaminase (AID) expression triggers diversification of the rearranged immunoglobulin (Ig) genes by pseudo V (ψV) gene- templated gene conversion or somatic hypermutation. To investigate how AID can alternatively induce recombination or hypermutation, ψV gene deletions were introduced into the rearranged light chain locus of the DT40 B-cell line. We show that the stepwise removal of the ψV donors not only reduces and eventually abolishes Ig gene conversion, but also activates AID-dependent Ig hypermutation. This strongly supports a model in which AID induces a common modification in the rearranged V(D)J segment, leading to a conversion tract in the presence of nearby donor sequences and to a point mutation in their absence.     

Brca1 in immunoglobulin gene conversion and somatic hypermutation

Defects in Brca1 confer susceptibility to breast cancer and genomic instability indicative of aberrant repair of DNA breaks. Brca1 was previously implicated in the homologous recombination pathway via effects on the assembly of recombinase Rad51. Activation-induced cytidine deaminase (AID) deaminates C to U in B lymphocyte immunoglobulin (Ig) DNA to initiate programmed DNA breaks. Subsequent uracil-glycosylase mediated U removal, and perhaps further processing, leads to four known classes of mutation: Ig class switch recombination that results in a region-specific genomic deletion, Ig somatic hypermutation that introduces point mutations in Ig V-regions, Ig gene conversion in vertebrates that possess Ig pseudo-V genes, and translocations common to B cell lymphomas. We tested the involvement of Brca1 in AID-dependent Ig diversification in chicken DT40 cells. The DT40 cell line diversifies IgVlambda mainly by gene conversion, and less so by point mutation. Brca1-deficiency caused a shift in Vlambda diversification, significantly reducing the proportion of gene conversions relative to point mutations. Thus, Brca1 regulates AID-dependent DNA lesion repair. Interestingly, while Brca1 is required to recruit ubiquitinated FancD2 to DNA damage, the phenotype of Brca1-deficient DT40 differs from the one of FancD2-deficient DT40, in which both gene conversion and non-templated mutations are impaired.     

Activation-induced cytidine deaminase induces reproducible DNA breaks at many non-Ig Loci in activated B cells

After immunization or infection, activation-induced cytidine deaminase (AID) initiates diversification of immunoglobulin (Ig) genes in B cells, introducing mutations within the antigen-binding V regions (somatic hypermutation, SHM) and double-strand DNA breaks (DSBs) into switch (S) regions, leading to antibody class switch recombination (CSR). We asked if, during B cell activation, AID also induces DNA breaks at genes other than IgH genes. Using a nonbiased genome-wide approach, we have identified hundreds of reproducible, AID-dependent DSBs in mouse splenic B cells shortly after induction of CSR in culture. Most interestingly, AID induces DSBs at sites syntenic with sites of translocations, deletions, and amplifications found in human B cell lymphomas, including within the oncogene B cell lymphoma11a (bcl11a)/evi9. Unlike AID-induced DSBs in Ig genes, genome-wide AID-dependent DSBs are not restricted to transcribed regions and frequently occur within repeated sequence elements, including CA repeats, non-CA tandem repeats, and SINEs.     

Activation-induced cytosine deaminase (AID) is actively exported out of the nucleus but retained by the induction of DNA breaks

Activation-induced cytosine deaminase (AID) is a cytosine deaminase that is critical to immunoglobulin hypermutation, class switch recombination, and gene conversion. In the context of hypermutating B cells, AID deaminates cytosine in the DNA of immunoglobulin genes, leading to the accumulation of mutations in the variable regions. However, when AID is expressed ectopically, it is a generalized mutator of G:C base pairs. Therefore, we asked whether AID may be partially regulated by an active system of nuclear export. We found that removal of a highly conserved nuclear export signal in the C terminus of AID causes accumulation of AID in the nucleus. However, a putative nuclear localization signal in the N terminus does not appear to be functional. Finally, we found that agents that induce DNA breaks caused retention of AID in the nucleus, suggesting that DNA breaks or the repair patches initiated as a result are a substrate for AID binding.     

The Interaction between AID and CIB1 Is Nonessential for Antibody Gene Diversification by Gene Conversion or Class Switch Recombination

Activation-induced deaminase (AID) initiates somatic hypermutation, gene conversion and class switch recombination by deaminating variable and switch region DNA cytidines to uridines. AID is predominantly cytoplasmic and must enter the nuclear compartment to initiate these distinct antibody gene diversification reactions. Nuclear AID is relatively short-lived, as it is efficiently exported by a CRM1-dependent mechanism and it is susceptible to proteasome-dependent degradation. To help shed light on mechanisms of post-translational regulation, a yeast-based screen was performed to identify AID-interacting proteins. The calcium and integrin binding protein CIB1 was identified by sequencing and the interaction was confirmed by immunoprecipitation experiments. The AID/CIB1 resisted DNase and RNase treatment, and it is therefore unlikely to be mediated by nucleic acid. The requirement for CIB1 in AID-mediated antibody gene diversification reactions was assessed in CIB1-deficient DT40 cells and in knockout mice, but immunoglobulin gene conversion and class switch recombination appeared normal. The DT40 system was also used to show that CIB1 over-expression has no effect on gene conversion and that AID-EGFP subcellular localization is normal. These combined data demonstrate that CIB1 is not required for AID to mediate antibody gene diversification processes. It remains possible that CIB1 has an alternative, a redundant or a subtle non-limiting regulatory role in AID biology.     

Gene conversion in human rearranged immunoglobulin genes

Over the past 20 years, many DNA sequences have been published suggesting that all or part of the V(H) segment of a rearranged immunoglobulin gene may be replaced in vivo. Two different mechanisms appear to be operating. One of these is very similar to primary V(D)J recombination, involving the RAG proteins acting upon recombination signal sequences, and this has recently been proven to occur. Other sequences, many of which show partial V(H) replacements with no addition of untemplated nucleotides at the V(H)-V(H) joint, have been proposed to occur by an unusual RAG-mediated recombination with the formation of hybrid (coding-to-signal) joints. These appear to occur in cells already undergoing somatic hypermutation in which, some authors are convinced, RAG genes are silenced. We recently proposed that the latter type of V(H) replacement might occur by homologous recombination initiated by the activity of AID (activation-induced cytidine deaminase), which is essential for somatic hypermutation and gene conversion. The latter has been observed in other species, but not in human Ig genes, so far. In this paper, we present a new analysis of sequences published as examples of the second type of rearrangement. This not only shows that AID recognition motifs occur in recombination regions but also that some sequences show replacement of central sections by a sequence from another gene, similar to gene conversion in the immunoglobulin genes of other species. These observations support the proposal that this type of rearrangement is likely to be AID-mediated rather than RAG-mediated and is consistent with gene conversion.     

DNA substrate length and surrounding sequence affect the activation-induced deaminase activity at cytidine

Activation-induced deaminase (AID) is required for both immunoglobulin class switch recombination and somatic hypermutation. AID is known to deaminate cytidines in single-stranded DNA, but the relationship of this step to the class switch or somatic hypermutation processes is not entirely clear. We have studied the activity of a recombinant form of the mouse AID protein that was purified from a baculovirus expression system. We find that the length of the single-stranded DNA target is critical to the action of AID at the Cs positioned anywhere along the length of the DNA. The DNA sequence surrounding a given C influences AID deamination efficiency. AID preferentially deaminates Cs in the WRC motif, and additionally has a small but consistent preference for purine at the position after the WRC, thereby favoring WRCr (the lowercase r corresponds to the smaller impact on activity).     

DNA-dependent protein kinase inhibits AID-induced antibody gene conversion

Affinity maturation and class switching of antibodies requires activation-induced cytidine deaminase (AID)-dependent hypermutation of Ig V(D)J rearrangements and Ig S regions, respectively, in activated B cells. AID deaminates deoxycytidine bases in Ig genes, converting them into deoxyuridines. In V(D)J regions, subsequent excision of the deaminated bases by uracil-DNA glycosylase, or by mismatch repair, leads to further point mutation or gene conversion, depending on the species. In Ig S regions, nicking at the abasic sites produced by AID and uracil-DNA glycosylases results in staggered double-strand breaks, whose repair by nonhomologous end joining mediates Ig class switching. We have tested whether nonhomologous end joining also plays a role in V(D)J hypermutation using chicken DT40 cells deficient for Ku70 or the DNA-dependent protein kinase catalytic subunit (DNA-PKcs). Inactivation of the Ku70 or DNA-PKcs genes in DT40 cells elevated the rate of AID-induced gene conversion as much as 5-fold. Furthermore, DNA-PKcs-deficiency appeared to reduce point mutation. The data provide strong evidence that double-strand DNA ends capable of recruiting the DNA-dependent protein kinase complex are important intermediates in Ig V gene conversion.     

Immunoglobulin isotype switching is inhibited and somatic hypermutation perturbed in UNG-deficient mice

BACKGROUND: We have previously proposed that deamination of cytosine to uracil at sites within the immunoglobulin loci by activation-induced deaminase (AID) triggers antibody diversification. The pattern of diversification (phase 1 or 2 hypermutation, gene conversion, or switch recombination) is viewed as depending on the mode of resolution of the dU/dG lesion. A major resolution mode involves excising the uracil, an activity that at least four different enzymes can accomplish in the mouse. RESULTS: Deficiency in UNG uracil-DNA glycosylase alone is sufficient to distort the pathway of hypermutation in mice. In ung(-/-) animals, mutations at dC/dG pairs are dramatically shifted toward transitions (95%), indicating that the generation of abasic sites (which can induce transversions) has been inhibited. The pattern of substitutions at dA/dT pairs is unaffected. Class-switch recombination is substantially, but not totally, inhibited. CONCLUSIONS: The results provide strong support for the DNA deamination model for antibody diversification with respect to class-switching as well as hypermutation and, in the context of this model, suggest that (i) UNG is the major mouse DNA glycosylase responsible for processing the programmed dU/dG lesions within the immunoglobulin locus; (ii) the second (dA/dT-biased) phase of mutation is probably triggered by recognition of the initiating dU/dG lesion; and (iii) switch recombination largely proceeds via formation of an abasic site, although (iv) an UNG-independent pathway of switch recombination exists, which could reflect action by another uracil-DNA glycosylase but might alternatively be explained by a distinct pathway of resolution, for example, one involving MSH2/MSH6 recognition of the dU/dG lesion.     

Transcription-coupled mutagenesis by the DNA deaminase AID

Activation-induced deaminase (AID) initiates switch recombination and somatic hypermutation of immunoglobulin genes in activated B cells. Compelling evidence now shows that AID travels with RNA polymerase II to deaminate actively transcribed DNA.     

Identification of a specific domain required for dimerization of activation-induced cytidine deaminase

Activation-induced cytidine deaminase (AID) is essential to all three genetic alterations required for generation of antigen-specific immunoglobulin: class switch recombination, somatic hypermutation, and gene conversion. Here we demonstrate that AID molecules form a homodimer autonomously in the absence of RNA, DNA, other cofactors, or post-translational modifications. Studies on serial deletion mutants revealed the minimum region between Thr27 and His56 responsible for dimerization. Analyses of point mutations within this region revealed that the residues between Gly47 and Gly54 are most important for the dimer formation. Functional analyses of these mutations indicate that all mutations impairing the dimer formation are inefficient for class switching, suggesting that dimer formation is required for class switching activity. Dimer formation and its requirement for the function of AID are features that AID shares with APOBEC-1, an RNA editing enzyme of apolipoprotein B100 mRNA.     

Recombinogenic phenotype of human activation-induced cytosine deaminase

Class switch recombination, gene conversion, and somatic hypermutation that diversify rearranged Ig genes to produce various classes of high affinity Abs are dependent on the enzyme activation-induced cytosine deaminase (AID). Evidence suggests that somatic hypermutation is due to error-prone DNA repair that is initiated by AID-mediated deamination of cytosine in DNA, whereas the mechanism by which AID controls recombination remains to be elucidated. In this study, using a yeast model system, we have observed AID-dependent recombination. Expression of human AID in wild-type yeast is mutagenic for G-C to A-T transitions, and as expected, this mutagenesis is increased upon inactivation of uracil-DNA glycosylase. AID expression also strongly induces intragenic mitotic recombination, but only in a strain possessing uracil-DNA glycosylase. Thus, the initial step of base excision repair is required for AID-dependent recombination and is a branch point for either hypermutagenesis or recombination.     

Cell Cycle Regulates Nuclear Stability of AID and Determines the Cellular Response to AID

AID (Activation Induced Deaminase) deaminates cytosines in DNA to initiate immunoglobulin gene diversification and to reprogram CpG methylation in early development. AID is potentially highly mutagenic, and it causes genomic instability evident as translocations in B cell malignancies. Here we show that AID is cell cycle regulated. By high content screening microscopy, we demonstrate that AID undergoes nuclear degradation more slowly in G1 phase than in S or G2-M phase, and that mutations that affect regulatory phosphorylation or catalytic activity can alter AID stability and abundance. We directly test the role of cell cycle regulation by fusing AID to tags that destabilize nuclear protein outside of G1 or S-G2/M phases. We show that enforced nuclear localization of AID in G1 phase accelerates somatic hypermutation and class switch recombination, and is well-tolerated; while nuclear AID compromises viability in S-G2/M phase cells. We identify AID derivatives that accelerate somatic hypermutation with minimal impact on viability, which will be useful tools for engineering genes and proteins by iterative mutagenesis and selection. Our results further suggest that use of cell cycle tags to regulate nuclear stability may be generally applicable to studying DNA repair and to engineering the genome.     

Antibody diversification caused by disrupted mismatch repair and promiscuous DNA polymerases

The enzyme activation-induced deaminase (AID) targets the immunoglobulin loci in activated B cells and creates DNA mutations in the antigen-binding variable region and DNA breaks in the switch region through processes known, respectively, as somatic hypermutation and class switch recombination. AID deaminates cytosine to uracil in DNA to create a U:G mismatch. During somatic hypermutation, the MutSα complex binds to the mismatch, and the error-prone DNA polymerase η generates mutations at A and T bases. During class switch recombination, both MutSα and MutLα complexes bind to the mismatch, resulting in double-strand break formation and end-joining. This review is centered on the mechanisms of how the MMR pathway is commandeered by B cells to generate antibody diversity.     

Gene conversion-like sequence transfers between transgenic antibody V genes are independent of RAD54

Homology-based Ig gene conversion is a major mechanism for Ab diversification in chickens and the Rad54 DNA repair protein plays an important role in this process. In mice, although gene conversion appears to be rare among endogenous Ig genes, Ab H chain transgenes undergo isotype switching and gene conversion-like sequence transfer processes that also appear to involve homologous recombination or gene conversion. Furthermore, homology-based DNA repair has been suggested to be important for somatic mutation of endogenous mouse Ig genes. To assess the role of Rad54 in these mouse B cell processes, we have analyzed H chain transgene isotype switching, sequence transfer, and somatic hypermutation in mice that lack RAD54. We find that Rad54 is not required for either transgene switching or transgene hypermutation. Furthermore, even transgene sequence transfers that are known to require homology-based recombinations are Rad54 independent. These results indicate that mouse B cells must use factors for promoting homologous recombination that are distinct from the Rad54 proteins important in homology-based chicken Ab gene recombinations. Our findings also suggest that mouse H chain transgene sequence transfers might be more closely related to an error-prone homology-based somatic hypermutational mechanism than to the hyperconversion mechanism that operates in chicken B cells.