Hypermutation at A/T sites during G.U mismatch repair in vitro by human B-cell lysates

Somatic hypermutation in the variable regions of immunoglobulin genes is required to produce high affinity antibody molecules. Somatic hypermutation results by processing G.U mismatches generated when activation-induced cytidine deaminase (AID) deaminates C to U. Mutations at C/G sites are targeted mainly at deamination sites, whereas mutations at A/T sites entail error-prone DNA gap repair. We used B-cell lysates to analyze salient features of somatic hypermutation with in vitro mutational assays. Tonsil and hypermutating Ramos B-cells convert C-->U in accord with AID motif specificities, whereas HeLa cells do not. Using tonsil cell lysates to repair a G.U mismatch, A/T and G/C targeted mutations occur about equally, whereas Ramos cell lysates make fewer mutations at A/T sites (approximately 24%) compared with G/C sites (approximately 76%). In contrast, mutations in HeLa cell lysates occur almost exclusively at G/C sites (> 95%). By recapitulating two basic features of B-cell-specific somatic hypermutation, G/C mutations targeted to AID hot spot motifs and elevated A/T mutations dependent on error-prone processing of G.U mispairs, these cell free assays provide a practical method to reconstitute error-prone mismatch repair using purified B-cell proteins.     

A mouse kidney cell line with a G:C --> C:G transversion mutator phenotype

We report the identification of a mouse kidney epithelial cell line (K435) in which G:C-->C:G transversion mutations occur at an elevated rate and are the predominant spontaneous events observed at the selectable Aprt locus. Of three genotoxins tested, ultraviolet radiation (UV), ionizing radiation, and hydrogen peroxide, only UV exposure was able to alter the spectrum of small mutational events. To determine if the G:C-->C:G mutator phenotype was due to a deficiency in the mismatch repair pathway, the K435 cells were tested for resistance to 6-thioguanine, cisplatin, and MNNG. Although the K435 cells were as resistant to 6-thioguanine and cisplatin as Pms2 and Mlh1 null kidney cells, they were hypersensitive to MNNG. Moreover, the K435 cells do not exhibit microsatellite instability, a hallmark of mismatch repair deficiency. These results suggest that a novel mechanism, which does not include a classical deficiency in mismatch repair, accounts for the G:C-->C:G mutator phenotype.     

Repair of Single Base-Pair Transversion Mismatches of Escherichia Coli in Vitro: Correction of Certain a/G Mismatches Is Independent of Dam Methylation and Host Muthls Gene Functions

Six different base-pair transversion mismatches are repaired with different efficiencies in an in vitro mismatch repair system. In particular, the T/T and C/C mismatches appear to be less efficiently repaired than the A/A and G/G mismatches. Four A/G and four C/T mismatches at different positions are repaired to different extents. One of the A/G mismatches is repaired equally efficiently when DNA heteroduplexes are fully methylated or hemi-methylated at the d(GATC) sequences. This type of mismatch repair appears to be unidirectional with A to C conversion by acting at A/G mispairs to restore the C/G pairs. This methylation-independent correction is not controlled by the mutH, mutL, mutS, uvrE, uvrB, phr, recA, recF, and recJ gene products. The independence of the transversion mismatch repair of these genes and methylation distinguishes this from the known mismatch repair pathways.     

MSH2 and MSH6 are required for removal of adenine misincorporated opposite 8-oxo-guanine in S. cerevisiae.

Oxidation of G in DNA yields 8-oxo-G (GO), a mutagenic lesion that leads to misincorporation of A opposite GO. In E. coli, GO in GO:C base pairs is removed by MutM, and A in GO:A mispairs is removed by MutY. In S. cerevisiae, mutations in MSH2 or MSH6 caused a synergistic increase in mutation rate in combination with mutations in OGG1, which encodes a MutM homolog, resulting in a 140- to 218-fold increase in the G:C-to-T:A transversion rate. Consistent with this, MSH2-MSH6 complex bound to GO:A mispairs and GO:C base pairs with high affinity and specificity. These data indicate that in S. cerevisiae, MSH2-MSH6-dependent mismatch repair is the major mechanism by which misincorporation of A opposite GO is corrected.     

Efficient repair of A/C mismatches in mouse cells deficient in long-patch mismatch repair

A previously unrecognized mismatch repair activity is described. Extracts of immortalized MSH2-deficient mouse fibroblasts did not correct most single base mispairs. The same extracts carried out efficient repair of A/C mismatches. A/G mispairs were less efficiently corrected and there was no significant repair of A/A. MLH1-defective mouse extracts also repaired an A/C mispair. A/C correction by Msh2(-/-) mouse cell extracts was not affected by antibodies against the PMS2 protein, which inhibited long-patch mismatch repair. A/C repair activity is thus independent of MutSalpha, MutSbeta and MutLalpha. A/C mismatches were corrected 5-fold more efficiently by extracts of Msh2 knockout mouse cells than by comparable extracts prepared from hMSH2- or hMLH1-deficient human cells. MSH2-independent A/C correction by mouse cell extracts did not require a nick in the circular duplex DNA substrate. Repair involved replacement of the A and was associated with the resynthesis of a limited stretch of 相似文献   

Mutational specificity of mice defective in the MTH1 and/or the MSH2 genes

Oxidative damage of nucleotides within DNA or precursor pools caused by oxygen radicals is thought to play an important role in spontaneous mutagenesis, as well as carcinogenesis and aging. In particular, 8-oxodGTP and 2-OHdATP are potent mutagenic substrate for DNA synthesis. Mammalian MTH1 catalyzes hydrolysis of these mutagenic substrates, suggesting that it functions to prevent mutagenesis caused by these oxidized nucleotides. We have established MTH1(-/-) mice lacking the 8-oxodGTPase activity, which were shown to be susceptible to lung, liver and stomach cancers. To examine in vivo mutation events due to the MTH1-deficiency, a reporter gene, rpsL of Escherichia coli, was introduced into MTH1(-/-) mice. Interestingly, the net frequency of rpsL(-) forward mutants showed no apparent increase in MTH1(-/-) mice as compared to MTH1(+/+) mice. However, we found differences between these two genotypes in the class- and site-distributions of the rpsL(-) mutations recovered from the mice. Unlike MutT-deficient E. coli showing 1000-fold higher frequency of A:T-->C:G transversion than the wild type cells, an increase in frequency of A:T-->C:G transversion was not evident in MTH1 nullizygous mice. Nevertheless, the frequency of single-base frameshifts at mononucleotide runs was 5.7-fold higher in spleens of MTH1(-/-) mice than in those of wild type mice. Since the elevated incidence of single-base frameshifts at mononucleotide runs is a hallmark of the defect in MSH2-dependent mismatch repair system, this weak site-specific mutator effect of MTH1(-/-) mice could be attributed to a partial sequestration of the mismatch repair function that may act to correct mispairs with the oxidized nucleotides. Consistent with this hypothesis, a significant increase in the frequency of G:C-->T:A transversions was observed with MTH1(-/-) MSH2(-/-) mice over MSH2(-/-) mice alone. These results suggest a possible involvement of multiple anti-mutagenic pathways, including the MTH1 protein and other repair system(s), in mutagenesis caused by the oxidized nucleotides.     

Methylation in eucaryotes influences the repair of G/T and A/C DNA basepair mismatches

Although methylation of DNA at some sites regulates gene expression, 5mC at many sites does not appear to have any effect. We present evidence that hemimethylation at many different sites can act as a discrimination signal in mismatch repair. Deamination of 5mC in a symmetrically methylated doublet CpG yields the mismatched base pair T/G in a hemi-methylated doublet pair. Because both bases in the mismatched pair are normal constituents of DNA, identifying the incorrect base is problematic. The only apparent distinction of the two is the methylation on the strand opposite the deamination event. Using available methylases we have produced hemi-methylated SV40 DNAs that are mismatched at a single T/G or A/C basepair in a sequence that mimics the lesion resulting from the deamination of a 5mCpG. Methylation at the adjacent cytosine results in the replacement of the T much more frequently than when no methylation is present in the heteroduplex. Cytosine methylation at sites farther removed from the mismatch is equally effective in replacing the incorrect T at the mismatch. Although methylation in vertebrates is almost exclusively on cytosine in the doublet CpG, methylation of cytosines in other doublets, as well as methylation of adenosine, also act as strand discrimination signals. Perhaps some of the excess methylation in vertebrate DNAs may serve to direct mismatch repair.     

Mutational History of a Human Cell Lineage from Somatic to Induced Pluripotent Stem Cells

The accuracy of replicating the genetic code is fundamental. DNA repair mechanisms protect the fidelity of the genome ensuring a low error rate between generations. This sustains the similarity of individuals whilst providing a repertoire of variants for evolution. The mutation rate in the human genome has recently been measured to be 50–70 de novo single nucleotide variants (SNVs) between generations. During development mutations accumulate in somatic cells so that an organism is a mosaic. However, variation within a tissue and between tissues has not been analysed. By reprogramming somatic cells into induced pluripotent stem cells (iPSCs), their genomes and the associated mutational history are captured. By sequencing the genomes of polyclonal and monoclonal somatic cells and derived iPSCs we have determined the mutation rates and show how the patterns change from a somatic lineage in vivo through to iPSCs. Somatic cells have a mutation rate of 14 SNVs per cell per generation while iPSCs exhibited a ten-fold lower rate. Analyses of mutational signatures suggested that deamination of methylated cytosine may be the major mutagenic source in vivo, whilst oxidative DNA damage becomes dominant in vitro. Our results provide insights for better understanding of mutational processes and lineage relationships between human somatic cells. Furthermore it provides a foundation for interpretation of elevated mutation rates and patterns in cancer.     

Incorporation of dUTP does not mediate mutation of A:T base pairs in Ig genes in vivo

Activation-induced cytidine deaminase (AID) protein initiates Ig gene mutation by deaminating cytosines, converting them into uracils. Excision of AID-induced uracils by uracil-N-glycosylase is responsible for most transversion mutations at G:C base pairs. On the other hand, processing of AID-induced G:U mismatches by mismatch repair factors is responsible for most mutation at Ig A:T base pairs. Why mismatch processing should be error prone is unknown. One theory proposes that long patch excision in G1-phase leads to dUTP-incorporation opposite adenines as a result of the higher G1-phase ratio of nuclear dUTP to dTTP. Subsequent base excision at the A:U base pairs produced could then create non-instructional templates leading to permanent mutations at A:T base pairs (1). This compelling theory has remained untested. We have developed a method to rapidly modify DNA repair pathways in mutating mouse B cells in vivo by transducing Ig knock-in splenic mouse B cells with GFP-tagged retroviruses, then adoptively transferring GFP⁺ cells, along with appropriate antigen, into primed congenic hosts. We have used this method to show that dUTP-incorporation is unlikely to be the cause of AID-induced mutation of A:T base pairs, and instead propose that A:T mutations might arise as an indirect consequence of nucleotide paucity during AID-induced DNA repair.     

Mutation spectrum of MSH3-deficient HHUA/chr.2 cells reflects in vivo activity of the MSH3 gene product in mismatch repair

The endometrial tumor cell line HHUA carries mutations in two mismatch repair (MMR) genes MSH3 and MSH6. We have established an MSH3-deficient HHUA/chr.2 cell line by introducing human chromosome 2, which carries wild-type MSH6 and MSH2 genes, to HHUA cells. Introduction of chromosome 2 to HHUA cells partially restored G:G MMR activity to the cell extract and reduced the frequency of mutation at the hypoxanthine-guanine phosphoribosyltransferase (hprt*) locus to about 3% that of the parental HHUA cells, which is five-fold the frequency in MMR-proficient cells, indicating that the residual mutator activity in HHUA/chr.2 is due to an MSH3-deficiency in these cells. The spectrum of mutations occurring at the HPRT locus of HHUA/chr.2 was determined with 71 spontaneous 6TG(r) clones. Base substitutions and +/-1 bp frameshifts were the major mutational events constituting, respectively, 54% and 42% of the total mutations, and more than 70% of them occurred at A:T sites. A possible explanation for the apparent bias of mutations to A:T sites in HHUA/chr.2 is haploinsufficiency of the MSH6 gene on the transferred chromosome 2. Comparison of the mutation spectra of HHUA/chr.2 with that of the MSH6-deficient HCT-15 cell line [S. Ohzeki, A. Tachibana, K. Tatsumi, T. Kato, Carcinogenesis 18 (1997) 1127-1133.] suggests that in vivo the MutSalpha (MSH2:MSH6) efficiently repairs both mismatch and unpaired extrahelical bases, whereas MutSbeta (MSH2:MSH3) efficiently repairs extrahelical bases and repairs mismatch bases to a limited extent.     

Bcl-2 rescues the germinal center response but does not alter the V gene somatic hypermutation spectrum in MSH2-deficient mice

Ab V genes in mice deficient for the postreplication mismatch repair factor MutS homolog (MSH2) have been reported to display an abnormal bias for hypermutations at G and C nucleotides and hotspots. We previously showed that the germinal center (GC) response is severely attenuated in MSH2-deficient mice. This suggested that premature death of GC B cells might preclude multiple rounds of hypermutation necessary to generate a normal spectrum of base changes. To test this hypothesis, we created MSH2-deficient mice in which Bcl-2 expression was driven in B cells from a transgene. In such mice, the elevated levels of intra-GC apoptosis and untimely GC dissolution characteristic of MSH2-deficient mice are suppressed. However, the spectrum of hypermutation is unchanged. These data indicate that the effects of MSH2 deficiency on GC B cell viability and the hypermutation process are distinct.     

Principal causes of hot spots for cytosine to thymine mutations at sites of cytosine methylation in growing cells. A model, its experimental support and implications.

In Escherichia coli and human cells, many sites of cytosine methylation in DNA are hot spots for C to T mutations. It is generally believed that T.G mismatches created by the hydrolytic deamination of 5-methylcytosines (5meC) are intermediates in the mutagenic pathway. A number of hypotheses have been proposed regarding the source of the mispaired thymine and how the cells deal with the mispairs. We have constructed a genetic reversion assay that utilizes a gene on a mini-F to compare the frequency of occurrence of C to T mutations in different genetic backgrounds in exponentially growing E. coli. The results identify at least two causes for the hot spot at a 5meC: (1) the higher rate of deamination of 5meC compared to C generates more T.G than uracil.G (U.G) mismatches, and (2) inefficient repair of T.G mismatches by the very short-patch (VSP) repair system compared to the repair of U. G mismatches by the uracil-DNA glycosylase (Ung). This combination of increased DNA damage when the cytosines are methylated coupled with the relative inefficiency in the post-replicative repair of T.G mismatches can be quantitatively modeled to explain the occurrence of the hot spot at 5meC. This model has implications for mutational hot and cold spots in all organisms.     

Hypermutation in Ig V genes from mice deficient in the MLH1 mismatch repair protein

During somatic hypermutation of Ig V genes, mismatched nucleotide substitutions become candidates for removal by the DNA mismatch repair pathway. Previous studies have shown that V genes from mice deficient for the MSH2 and PMS2 mismatch repair proteins have frequencies of mutation that are comparable with those from wild-type (wt) mice; however, the pattern of mutation is altered. Because the absence of MSH2 and PMS2 produced different mutational spectra, we examined the role of another protein involved in mismatch repair, MLH1, on the frequency and pattern of hypermutation. MLH1-deficient mice were immunized with oxazolone Ag, and splenic B cells were analyzed for mutations in their V kappa Ox1 light chain genes. Although the frequency of mutation in MLH1-deficient mice was twofold lower than in wt mice, the pattern of mutation in Mlh1-/- clones was similar to wt clones. These findings suggest that the MLH1 protein has no direct effect on the mutational spectrum.     

Somatic deletions of genes regulating MSH2 protein stability cause DNA mismatch repair deficiency and drug resistance in human leukemia cells

DNA mismatch repair enzymes (for example, MSH2) maintain genomic integrity, and their deficiency predisposes to several human cancers and to drug resistance. We found that leukemia cells from a substantial proportion of children (～11%) with newly diagnosed acute lymphoblastic leukemia have low or undetectable MSH2 protein levels, despite abundant wild-type MSH2 mRNA. Leukemia cells with low levels of MSH2 contained partial or complete somatic deletions of one to four genes that regulate MSH2 degradation (FRAP1 (also known as MTOR), HERC1, PRKCZ and PIK3C2B); we also found these deletions in individuals with adult acute lymphoblastic leukemia (16%) and sporadic colorectal cancer (13.5%). Knockdown of these genes in human leukemia cells recapitulated the MSH2 protein deficiency by enhancing MSH2 degradation, leading to substantial reduction in DNA mismatch repair and increased resistance to thiopurines. These findings reveal a previously unrecognized mechanism whereby somatic deletions of genes regulating MSH2 degradation result in undetectable levels of MSH2 protein in leukemia cells, DNA mismatch repair deficiency and drug resistance.     

Hypermutability of homonucleotide runs in mismatch repair and DNA polymerase proofreading yeast mutants.

Homonucleotide runs in coding sequences are hot spots for frameshift mutations and potential sources of genetic changes leading to cancer in humans having a mismatch repair defect. We examined frameshift mutations in homonucleotide runs of deoxyadenosines ranging from 4 to 14 bases at the same position in the LYS2 gene of the yeast Saccharomyces cerevisiae. In the msh2 mismatch repair mutant, runs of 9 to 14 deoxyadenosines are 1,700-fold to 51,000-fold, respectively, more mutable for single-nucleotide deletions than are runs of 4 deoxyadenosines. These frameshift mutations can account for up to 99% of all forward mutations inactivating the 4-kb LYS2 gene. Based on results with single and double mutations of the POL2 and MSH2 genes, both DNA polymerase epsilon proofreading and mismatch repair are efficient for short runs while only the mismatch repair system prevents frameshift mutations in runs of > or = 8 nucleotides. Therefore, coding sequences containing long homonucleotide runs are likely to be at risk for mutational inactivation in cells lacking mismatch repair capability.     

Escherichia coli mutator (Delta)polA is defective in base mismatch correction: the nature of in vivo DNA replication errors

We constructed a set of Escherichia coli strains containing deletions in genes encoding three SOS polymerases, and defective in MutS and DNA polymerase I (PolI) mismatch repair, and estimated the rate and specificity of spontaneous endogenous tonB(+)-->tonB- mutations. The rate and specificity of mutations in strains proficient or deficient in three SOS polymerases was compared and found that there was no contribution of SOS polymerases to the chromosomal tonB mutations. MutS-deficient strains displayed elevated spontaneous mutation rates, consisting of dominantly minus frameshifts and transitions. Minus frameshifts are dominated by warm spots at run-bases. Among 57 transitions (both G:C-->A:T and A:T-->G:C), 35 occurred at two hotspot sites. PolI-deficient strains possessed an increased rate of deletions and frameshifts, because of a deficiency in postreplicative deletion and frameshift mismatch corrections. Frameshifts in PolI-deficient strains occurred within the entire tonB gene at non-run and run sequences. MutS and PolI double deficiency indicated a synergistic increase in the rate of deletions, frameshifts and transitions. In this case, mutS-specific hotspots for frameshifts and transitions disappeared. The results suggested that, unlike the case previously known pertaining to postreplicative MutS mismatch repair for frameshifts and transitions and PolI mismatch repair for frameshifts and deletions, PolI can recognize and correct transition mismatches. Possible mechanisms for distinct MutS and PolI mismatch repair are discussed. A strain containing deficiencies in three SOS polymerases, MutS mismatch repair and PolI mismatch repair was also constructed. The spectrum of spontaneous mutations in this strain is considered to represent the spectrum of in vivo DNA polymerase III replication errors. The mutation rate of this strain was 219x10(-8), about a 100-fold increase relative to the wild-type strain. Uncorrected polymerase III replication errors were predominantly frameshifts and base substitutions followed by deletions.     

DNA mismatch repair proteins are required for efficient herpes simplex virus 1 replication

Herpes simplex virus 1 (HSV-1) is a double-stranded DNA virus that replicates in the nucleus of its human host cell and is known to interact with many cellular DNA repair proteins. In this study, we examined the role of cellular mismatch repair (MMR) proteins in the virus life cycle. Both MSH2 and MLH1 are required for efficient replication of HSV-1 in normal human cells and are localized to viral replication compartments. In addition, a previously reported interaction between MSH6 and ICP8 was confirmed by coimmunoprecipitation and extended to show that UL12 is also present in this complex. We also report for the first time that MLH1 associates with ND10 nuclear bodies and that like other ND10 proteins, MLH1 is recruited to the incoming genome. Knockdown of MLH1 inhibits immediate-early viral gene expression. MSH2, on the other hand, which is generally thought to play a role in mismatch repair at a step prior to that of MLH1, is not recruited to incoming genomes and appears to act at a later step in the viral life cycle. Silencing of MSH2 appears to inhibit early gene expression. Thus, both MLH1 and MSH2 are required but appear to participate in distinct events in the virus life cycle. The observation that MLH1 plays an earlier role in HSV-1 infection than does MSH2 is surprising and may indicate a novel function for MLH1 distinct from its known MSH2-dependent role in mismatch repair.     

Functional interaction of proliferating cell nuclear antigen with MSH2-MSH6 and MSH2-MSH3 complexes

Eukaryotic DNA mismatch repair requires the concerted action of several proteins, including proliferating cell nuclear antigen (PCNA) and heterodimers of MSH2 complexed with either MSH3 or MSH6. Here we report that MSH3 and MSH6, but not MSH2, contain N-terminal sequence motifs characteristic of proteins that bind to PCNA. MSH3 and MSH6 peptides containing these motifs bound PCNA, as did the intact Msh2-Msh6 complex. This binding was strongly reduced when alanine was substituted for conserved residues in the motif. Yeast strains containing alanine substitutions in the PCNA binding motif of Msh6 or Msh3 had elevated mutation rates, indicating that these interactions are important for genome stability. When human MSH3 or MSH6 peptides containing the PCNA binding motif were added to a human cell extract, mismatch repair activity was inhibited at a step preceding DNA resynthesis. Thus, MSH3 and MSH6 interactions with PCNA may facilitate early steps in DNA mismatch repair and may also be important for other roles of these eukaryotic MutS homologs.     

Processing of mispaired and unpaired bases in heteroduplex DNA in E. coli

Bacteriophage lambda and phi X 174 DNAs, carrying sequenced mutations, have been used to construct in vitro defined species of heteroduplex DNA. Such heteroduplex DNAs were introduced by transfection, as single copies, into E. coli host cells. The progeny of individual heteroduplex molecules from each infective center was analyzed. The effect of the presence of GATC sequences (phi X 174 system) and of their methylation (lambda system) was tested. The following conclusions can be drawn: some mismatched base pairs trigger the process of mismatch repair, causing a localized strand-to-strand information transfer in heteroduplex DNA: transition mismatches G:T and A:C are efficiently repaired, whereas the six transversion mismatches are not always readily recognized and/or repaired. The recognition of transversion mismatches appears to depend on the neighbouring nucleotide sequence; single unpaired bases (frameshift mutation "mismatches") are recognized and repaired, some equally efficiently on both strands (longer and shorter), some more efficiently on the shorter (-1) strand; large non-homologies (about 800 bases) are not repaired by the Mut H, L, S, U system, but some other process repairs the non-homology with a relatively low efficiency; full methylation of GATC sequences inhibits mismatch repair on the methylated strand: this is the chemical basis of strand discrimination (old/new) in mismatch correction; unmethylated GATC sequences appear to improve mismatch repair of a G:T mismatch in phi X 174 DNA, but there may be some residual mismatch repair in GATC-free phi X 174, at least for some mismatches.(ABSTRACT TRUNCATED AT 250 WORDS)