Uracil DNA glycosylase disruption blocks Ig gene conversion and induces transition mutations

Ig gene conversion is most likely initiated by activation-induced cytidine deaminase-mediated cytosine deamination. If the resulting uracils need to be further processed by uracil DNA glycosylase (UNG), UNG inactivation should block gene conversion and induce transition mutations. In this study, we report that this is indeed the phenotype in the B cell line DT40. Ig gene conversion is almost completely extinguished in the UNG-deficient mutant and large numbers of transition mutations at C/G bases accumulate within the rearranged Ig L chain gene (IgL). The mutation rate of UNG-deficient cells is about seven times higher than that of pseudo V gene-deleted (psiV-) cells in which mutations arise presumably after uracil excision. In addition, UNG-deficient cells show relatively more mutations upstream and downstream of the VJ segment. This suggests that hypermutating B cells process activation-induced cytidine deaminase-induced uracils with approximately one-seventh of uracils giving rise to mutations depending on their position.     

Normal somatic hypermutation of Ig genes in the absence of 8-hydroxyguanine-DNA glycosylase

The hypermutation cascade in Ig V genes can be initiated by deamination of cytosine in DNA to uracil by activation-induced cytosine deaminase and its removal by uracil-DNA glycosylase. To determine whether damage to guanine also contributes to hypermutation, we examined the glycosylase that removes oxidized guanine from DNA, 8-hydroxyguanine-DNA glycosylase (OGG1). OGG1 has been reported to be overexpressed in human B cells from germinal centers, where mutation occurs, and could be involved in initiating Ab diversity by removing modified guanines. In this study, mice deficient in Ogg1 were immunized, and V genes from the H and kappa L chain loci were sequenced. Both the frequency of mutation and the spectra of nucleotide substitutions were similar in ogg1(-/-) and Ogg1(+/+) clones. More importantly, there was no significant increase in G:C to T:A transversions in the ogg1(-/-) clones, which would be expected if 8-hydroxyguanine remained in the DNA. Furthermore, Ogg1 was not up-regulated in murine B cells from germinal centers. These findings show that hypermutation is unaffected in the absence of Ogg1 activity and indicate that 8-hydroxyguanine lesions most likely do not cause V gene mutations.     

Hypermutation at A-T base pairs: the A nucleotide replacement spectrum is affected by adjacent nucleotides and there is no reverse complementarity of sequences flanking mutated A and T nucleotides

Hypermutation is thought to be a two-phase process. The first phase is via the action of activation-induced cytidine deaminase (AID), which deaminates C nucleotides in WRC motifs. This results in the RGYW/WRCY hot spot motifs for mutation from G and C observed in vivo. The resemblance between the hot spot for C mutations and the reverse complement of that for G mutations implies a process acting equally on both strands of DNA. The second phase of hypermutation generates mutations from A and T and exhibits strand bias, with more mutations from A than T. Although this does not concur with the idea of one mechanism acting equally on both strands, it has been suggested that the AT mutator also has a reversible motif; WA/TW. We show here that the motifs surrounding the different substitutions from A vary significantly; there is no single targeting motif for all A mutations. Sequence preferences associated with mutations from A more likely reflect an influence of adjacent nucleotides over what the A mutates "to." This influence tends toward "like" replacements: Purines (A or G) in the 5' position bias toward replacement by another purine (G), whereas replacement with pyrimidines (C or T) is more likely if the preceding base is also a pyrimidine. There is no reverse complementarity in these observations, in that similar influences of nucleotides adjacent to T are not seen. Hence, WA and TW should not be considered as reverse complement hot spot motifs for A and T mutations.     

Analysis of 6912 unselected somatic hypermutations in human VDJ rearrangements reveals lack of strand specificity and correlation between phase II substitution rates and distance to the nearest 3' activation-induced cytidine deaminase target

The initial event of somatic hypermutation (SHM) is the deamination of cytidine residues by activation-induced cytidine deaminase (AID). Deamination is followed by the replication over uracil and/or different error-prone repair events. We sequenced 659 nonproductive human IgH rearrangements (IGHV3-23*01) from blood B lymphocytes enriched for CD27-positive memory cells. Analyses of 6,912 unique, unselected substitutions showed that in vivo hot and cold spots for the SHM of C and G residues corresponded closely to the target preferences reported for AID in vitro. A detailed analysis of all possible four-nucleotide motifs present on both strands of the V(H) gene showed significant correlations between the substitution frequencies in reverse complementary motifs, suggesting that the SHM machinery targets both strands equally well. An analysis of individual J(H) and D gene segments showed that the substitution frequencies in the individual motifs were comparable to the frequencies found in the V(H) gene. Interestingly, J(H)6-carrying sequences were less likely to undergo SHM (average 15.2 substitutions per V(H) region) than sequences using J(H)4 (18.1 substitutions, p = 0.03). We also found that the substitution rates in G and T residues correlated inversely with the distance to the nearest 3' WRC AID hot spot motif on both the nontranscribed and transcribed strands. This suggests that phase II SHM takes place 5' of the initial AID deamination target and primarily targets T and G residues or, alternatively, the corresponding A and C residues on the opposite strand.     

Cutting edge: the G-U mismatch glycosylase methyl-CpG binding domain 4 is dispensable for somatic hypermutation and class switch recombination

Affinity maturation of the humoral response is accomplished by somatic hypermutation and class switch recombination (CSR) of Ig genes. Activation-induced cytidine deaminase likely initiates these processes by deamination of cytidines in the V and switch regions of Ig genes. This activity is expected to produce G-U mismatches that can be substrates for MutS homolog 2/MutS homolog 6 heterodimers and for uracil DNA glycosylase. However, G-T and G-U mismatches are also substrates of the methyl-CpG binding domain 4 (Mbd4) glycosylase. To determine whether Mbd4 functions downstream of activation-induced cytidine deaminase activity, we examined somatic hypermutation and CSR in Mbd4(-/-) mice. In this study, we report that CSR, as analyzed by an in vitro switch assay and by in vivo immunizations, is unaffected in Mbd4(-/-) mice. In addition, the hypermutated JH2 to JH4 region in Peyer's patch B cells showed no effects as a result of Mbd4 deficiency. These data indicate that the Mbd4 glycosylase does not significantly contribute to mechanisms of Ab diversification.     

BCL-6 mutations in pulmonary lymphoproliferative disorders: demonstration of an aberrant immunological reaction in HIV-related lymphoid interstitial pneumonia

We used a PCR and sequence procedure to analyze the Ig V(H) gene and the mutations in the 5' regulatory regions of BCL-6 genes in pulmonary lymphoproliferative disorders (mucosa-associated lymphoid tissue (MALT) lymphoma, HIV-related, EBV-related, and virus-negative lymphocytic interstitial pneumonia (LIP)). Eight of 20 (40%) pulmonary MALT lymphoma and 10 of 20 LIP (5 of 5 (100%) HIV-related, 2 of 5 (40%) EBV-related, and 3 of 10 (30%) virus-negative LIP) cases showed BCL-6 gene mutations. Intraclonal heterogeneity of the BCL-6 mutations was observed only in pulmonary MALT lymphoma cases whose Ig V(H) genes also showed intraclonal heterogeneity. Ongoing BCL-6 mutations might reflect re-entry into a germinal center pathway to further mutations. BCL-6 mutations in pulmonary MALT lymphoma and HIV-negative LIP showed some features (high transition to transversion ratio, standard polarity, and RGYW/WRCY bias) of Ig V(H) gene hypermutation, leading to the view that pulmonary MALT lymphomas and HIV-negative LIP are under the influence of germinal center hypermutation mechanisms. Because BCL-6 mutations in HIV-related LIP cases did not demonstrate features of Ig V(H) gene hypermutation, immunological reactions in HIV-related LIP are the result of a process different from that found in HIV-negative pulmonary lymphoproliferative disorders.     

A role for the MutL mismatch repair Mlh3 protein in immunoglobulin class switch DNA recombination and somatic hypermutation

Class switch DNA recombination (CSR) and somatic hypermutation (SHM) are central to the maturation of the Ab response. Both processes involve DNA mismatch repair (MMR). MMR proteins are recruited to dU:dG mispairs generated by activation-induced cytidine deaminase-mediated deamination of dC residues, thereby promoting S-S region synapses and introduction of mismatches (mutations). The MutL homolog Mlh3 is the last complement of the mammalian set of MMR proteins. It is highly conserved in evolution and is essential to meiosis and microsatellite stability. We used the recently generated knockout mlh3(-/-) mice to address the role of Mlh3 in CSR and SHM. We found that Mlh3 deficiency alters both CSR and SHM. mlh3(-/-) B cells switched in vitro to IgG and IgA but displayed preferential targeting of the RGYW/WRCY (R = A or G, Y = C or T, W = A or T) motif by Sgamma1 and Sgamma3 breakpoints and introduced more insertions and fewer donor/acceptor microhomologies in Smu-Sgamma1 and Smu-Sgamma3 DNA junctions, as compared with mlh3(+/+) B cells. mlh3(-/-) mice showed only a slight decrease in the frequency of mutations in the intronic DNA downstream of the rearranged J(H)4 gene. However, the residual mutations were altered in spectrum. They comprised a decreased proportion of mutations at dA/dT and showed preferential RGYW/WRCY targeting by mutations at dC/dG. Thus, the MMR Mlh3 protein plays a role in both CSR and SHM.     

The specific binding of nuclear protein(s) to the cAMP responsive element (CRE) sequence (TGACGTCA) is reduced by the misincorporation of U and increased by the deamination of C.

Point mutations in the cAMP-responsive element (CRE) of the rat somatostatin gene promoter/enhancer sequence (TGACGTCA) were used as a model for assessing the effect of uracil, deriving either from misincorporation during DNA synthesis (T----U) or cytosine deamination (C----U), on the binding of sequence/specific regulatory proteins. The results show that the T----U conversion in both strands of the CRE palindromic sequence reduces its affinity for the CRE binding factor(s), suggesting the crucial role of the methyl group contributed by T for the correct recognition of the sequence. On the other hand, deamination of C in the CpG central dinucleotide (CpG----UpG) causes an increase of binding affinity which is further enhanced by the contemporary deamination in both strands. Then, both uracil misincorporation and cytosine deamination alter the binding to CRE sequence in vitro, suggesting that uracil, if not removed by uracil DNA-glycosylase, could be dangerous for cellular functions.     

Immunity through DNA deamination

Functional antibody genes assembled by V(D)J joining are subsequently diversified by somatic hypermutation, gene conversion and class-switch recombination. Recent evidence indicates that all three processes are caused by the deamination of cytosine to uracil at sites within the immunoglobulin (Ig) loci, with the pattern of diversification depending on the pathway used for resolving the initiating dU-dG lesion. Whereas DNA deamination targeted to the endogenous Ig locus triggers a program of somatic gene diversification that underpins adaptive immunity, deamination targeted to foreign DNA might have arisen initially as a form of innate immunity. Furthermore, the observation that members of the DNA deaminase family can target inappropriate genes suggests they might also contribute to mutations during genome evolution, as well as in cancer.     

DNA polymerase eta contributes to strand bias of mutations of A versus T in immunoglobulin genes

DNA polymerase (pol) eta participates in hypermutation of A:T bases in Ig genes because humans deficient for the polymerase have fewer substitutions of these bases. To determine whether polymerase eta is also responsible for the well-known preference for mutations of A vs T on the nontranscribed strand, we sequenced variable regions from three patients with xeroderma pigmentosum variant (XP-V) disease, who lack polymerase eta. The frequency of mutations in the intronic region downstream of rearranged J(H)4 gene segments was similar between XP-V and control clones; however, there were fewer mutations of A:T bases and correspondingly more substitutions of C:G bases in the XP-V clones (p < 10(-7)). There was significantly less of a bias for mutations of A compared with T nucleotides in the XP-V clones compared with control clones, whereas the frequencies for mutations of C and G were identical in both groups. An analysis of mutations in the WA sequence motif suggests that polymerase eta generates more mutations of A than T on the nontranscribed strand. This in vivo data from polymerase eta-deficient B cells correlates well with the in vitro specificity of the enzyme. Because polymerase eta inserts more mutations opposite template T than template A, it would generate more substitutions of A on the newly synthesized strand.     

Activity profiles of enzymes that control the uracil incorporation into DNA during neuronal development.

We have shown that DNA polymerase beta, the only nuclear DNA polymerase present in adult neurons, cannot discriminate between dTTP and dUTP, having the same Km for both substrates. This fact suggests that during reparative DNA synthesis, in adult neurons, dUMP residues can be incorporated into DNA. Since uracil DNA-glycosylase functions to prevent the mutagenic effects of uracil in DNA coming as a product of deamination of cytosine residues or as a result of dUMP incorporation by DNA polymerase, we have studied the perinatal activity of uracil DNA-glycosylase and of 2 enzymes (nucleoside diphosphokinase and dUTPase) involved in dUTP metabolism. Our data indicate that during neuronal development there is a rapid decrease in uracil DNA-glycosylase which could impair the removal of uracil present in DNA in adult neurons. However, misincorporation of dUMP into DNA might be kept to a low frequency by the action of dUTPase present at all developmental stages.     

Advantages and disadvantages of cytidine deamination

Cytidine deamination of nucleic acids underlies diversification of Ig genes and inhibition of retroviral infection, and thus, it would appear to be vital to host defense. The host defense properties of cytidine deamination require two distinct but homologous cytidine deaminases-activation-induced cytidine deaminase and apolipoprotein B-editing cytidine deaminase, subunit 3G. Although cytidine deamination has clear benefits, it might well have biological costs. Uncontrolled cytidine deamination might generate misfolded polypeptides, dominant-negative proteins, or mutations in tumor suppressor genes, and thus contribute to tumor formation. How cytidine deaminases target a given nucleic acid substrate at specific sequences is not understood, and what protects cells from uncontrolled mutagenesis is not known. In this paper, I shall review the functions and regulation of activation-induced cytidine deaminase and apolipoprotein B-editing cytidine deaminase, subunit 3G, and speculate about the basis for site specificity vis-à-vis generalized mutagenesis.     

A regulatory role for NBS1 in strand-specific mutagenesis during somatic hypermutation

Activation-induced cytidine deaminase (AID) is believed to initiate somatic hypermutation (SHM) by deamination of deoxycytidines to deoxyuridines within the immunoglobulin variable regions genes. The deaminated bases can subsequently be replicated over, processed by base excision repair or mismatch repair, leading to introduction of different types of point mutations (G/C transitions, G/C transversions and A/T mutations). It is evident that the base excision repair pathway is largely dependent on uracil-DNA glycosylase (UNG) through its uracil excision activity. It is not known, however, which endonuclease acts in the step immediately downstream of UNG, i.e. that cleaves at the abasic sites generated by the latter. Two candidates have been proposed, an apurinic/apyrimidinic endonuclease (APE) and the Mre11-Rad50-NBS1 complex. The latter is intriguing as this might explain how the mutagenic pathway is primed during SHM. We have investigated the latter possibility by studying the in vivo SHM pattern in B cells from ataxia-telangiectasia-like disorder (Mre11 deficient) and Nijmegen breakage syndrome (NBS1 deficient) patients. Our results show that, although the pattern of mutations in the variable heavy chain (V(H)) genes was altered in NBS1 deficient patients, with a significantly increased number of G (but not C) transversions occurring in the SHM and/or AID targeting hotspots, the general pattern of mutations in the V(H) genes in Mre11 deficient patients was only slightly altered, with an increased frequency of A to C transversions. The Mre11-Rad50-NBS1 complex is thus unlikely to be the major nuclease involved in cleavage of the abasic sites during SHM, whereas NBS1 might have a specific role in regulating the strand-biased repair during phase Ib mutagenesis.     

A novel process for mutation detection using uracil DNA-glycosylase.

A novel process is presented for the detection of known mutations and polymorphisms in DNA. This process, termed glycosylase mediated polymorphism detection (GMPD) involves amplification of the target DNA using three normal dNTPs and a fourth modified dNTP, whose base is a substrate for a specific DNA-glycosylase once incorporated into the DNA. The work described here utilises uracil DNA-glycosylase as the specific glycosylase and dUTP as the modified dNTP. Primers are designed so that during extension, the position of the first uracil incorporated into the extended primers differs depending on whether a mutation is present or absent. Subsequent glycosylase excision of the uracil residues followed by cleavage of the apyrimidinic sites allows detection of the mutation in the amplified fragment as a fragment length polymorphism. Variation in the sizes of the fragment length polymorphisms generated, can be readily achieved through the use of inosine bases in place of adenine bases in the upper and/or lower primers. The GMPD process is also adaptable to solid phase analysis. The use of the process for detection of mutations in the RYR1 and CFTR genes is demonstrated. Overall, the simplicity, specificity, versatility and flexibility of the GMPD process make it an attractive candidate for both small and large scale application in mutation detection and genome analysis.     

ATM is not required in somatic hypermutation of VH,but is involved in the introduction of mutations in the switch mu region

Class switch recombination (CSR) and somatic hypermutation (SHM) are mechanistically related processes that share common key factors such as activation-induced cytidine deaminase. We have previously shown a role for ATM (mutated in ataxia-telangiectasia) in CSR. In this paper we show that the frequency, distribution, and nature of base pair substitutions in the Ig variable (V) heavy chain genes in ataxia-telangiectasia patients are largely similar to those in normal donors, suggesting a normal SHM process. Characterization of the third complementarity-determining region in B cells from ataxia-telangiectasia patients also shows a normal V(D)J recombination process. SHM-like mutations could be identified in the switch (S) mu region (up to several hundred base pairs upstream of the S mu -S(alpha) breakpoints) in normal in vivo switched human B cells. In the absence of ATM, mutations can still be found in this region, but at less than half the frequency of that in normal donors. The latter mutations are mainly due to transitions (86% compared with 58% in controls) and are biased to A or T nucleotides. An ATM-dependent mechanism, different from that generating SHM in V genes, is therefore likely to be involved in introducing SHM-like mutations in the S region. ATM may thus be one of the factors that is not shared by the CSR and SHM processes.     

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.     

Roles of endonuclease V, uracil-DNA glycosylase, and mismatch repair in Bacillus subtilis DNA base-deamination-induced mutagenesis

The disruption of ung, the unique uracil-DNA-glycosylase-encoding gene in Bacillus subtilis, slightly increased the spontaneous mutation frequency to rifampin resistance (Rif(r)), suggesting that additional repair pathways counteract the mutagenic effects of uracil in this microorganism. An alternative excision repair pathway is involved in this process, as the loss of YwqL, a putative endonuclease V homolog, significantly increased the mutation frequency of the ung null mutant, suggesting that Ung and YwqL both reduce the mutagenic effects of base deamination. Consistent with this notion, sodium bisulfite (SB) increased the Rif(r) mutation frequency of the single ung and double ung ywqL strains, and the absence of Ung and/or YwqL decreased the ability of B. subtilis to eliminate uracil from DNA. Interestingly, the Rif(r) mutation frequency of single ung and mutSL (mismatch repair [MMR] system) mutants was dramatically increased in a ung knockout strain that was also deficient in MutSL, suggesting that the MMR pathway also counteracts the mutagenic effects of uracil. Since the mutation frequency of the ung mutSL strain was significantly increased by SB, in addition to Ung, the mutagenic effects promoted by base deamination in growing B. subtilis cells are prevented not only by YwqL but also by MMR. Importantly, in nondividing cells of B. subtilis, the accumulations of mutations in three chromosomal alleles were significantly diminished following the disruption of ung and ywqL. Thus, under conditions of nutritional stress, the processing of deaminated bases in B. subtilis may normally occur in an error-prone manner to promote adaptive mutagenesis.