SOS mutator effect in E. coli mutants deficient in mismatch correction.

We have used bacteriophage lambda to characterize the mutator effect of the SOS response induced by u.v. irradiation of Escherichia coli. Mutagenesis of unirradiated phages grown in irradiated or unirradiated bacteria was detected by measuring forward mutagenesis in the immunity genes or reversion mutagenesis of an amber codon in the R gene. Relative to the wild-type, the SOS mutator effect was higher in E. coli mismatch correction-deficient mutants (mutH, mutL and mutS) and lower in an adenine methylation-deficient mutant ( dam3 ). We conclude that a large proportion of SOS-induced 'untargeted' mutations are removed by the methyl-directed mismatch correction system, which acts on newly synthesized DNA strands. The lower SOS mutator effect observed in E. coli dam mutants may be due to a selective killing of mismatch-bearing chromosomes resulting from undirected mismatch repair. The SOS mutator effect on undamaged lambda DNA, induced by u.v. irradiation of the host, appears to result from decreased fidelity of DNA synthesis.     

Mutator phenotypes conferred by MLH1 overexpression and by heterozygosity for mlh1 mutations

Loss of DNA mismatch repair due to mutation or diminished expression of the MLH1 gene is associated with genome instability and cancer. In this study, we used a yeast model system to examine three circumstances relevant to modulation of MLH1 function. First, overexpression of wild-type MLH1 was found to cause a strong elevation of mutation rates at three different loci, similar to the mutator effect of MLH1 gene inactivation. Second, haploid yeast strains with any of six mlh1 missense mutations that mimic germ line mutations found in human cancer patients displayed a strong mutator phenotype consistent with loss of mismatch repair function. Five of these mutations affect amino acids that are homologous to residues suggested by recent crystal structure and biochemical analysis of Escherichia coli MutL to participate in ATP binding and hydrolysis. Finally, using a highly sensitive reporter gene, we detected a mutator phenotype of diploid yeast strains that are heterozygous for mlh1 mutations. Evidence suggesting that this mutator effect results not from reduced mismatch repair in the MLH1/mlh1 cells but rather from loss of the wild-type MLH1 allele in a fraction of cells is presented. Exposure to bleomycin or to UV irradiation strongly enhanced mutagenesis in the heterozygous strain but had little effect on the mutation rate in the wild-type strain. This damage-induced hypermutability may be relevant to cancer in humans with germ line mutations in only one MLH1 allele.     

Metagenomic DNA fragments that affect Escherichia coli mutational pathways

A multicopy cloning approach was used to search for metagenomic DNA fragments that affect Escherichia coli mutational pathways. Soil metagenomic expression libraries were constructed with DNA samples prepared directly from soil samples collected from the UCLA Botanical Garden. Using frameshift mutator screening, we obtained a total of 26 unique metagenomic fragments that stimulate frameshift rates in an E. coli wild-type host. Mutational enhancer strains such as an ndk-deficient strain and a temperature sensitive mutS strain (mutS60) were used to further verify the mutator phenotype. We found that the presence of multiple copies of certain types of metagenomic DNA sequence repeats cause general genome instability in the wild-type E. coli host and the effect can be suppressed by overproducing a DNA mismatch component MutL. In addition, we identified nine metagenomic mutator genes (designated as smu genes) that encode proteins that have not been linked to mutator phenotypes prior to this study including a putative RNA methyltransferase Smu10A. The strain overproducing Smu10A displays one prominent base substitution hotspot in the rpoB gene, which coincides with the base substitution hotspot we have observed in cells that are partially deficient in the proofreading function carried out by the DNA polymerase III epsilon subunit. Based on the structural conservation of DNA replication/recombination/repair machineries among microorganisms, this approach would allow us to both identify new mutational pathways in E. coli and to find genes involved in DNA replication, recombination or DNA repair from vast unculturable microbes.     

Escherichia Coli Mutator Mutd5 Is Defective in the Muthls Pathway of DNA Mismatch Repair

We have previously reported that the Escherichia coli mutator strain mutD5 was defective in the correction of bacteriophage M13mp2 heteroduplex DNA containing a T.G mismatch. Here, this defect was further investigated with regard to its interaction with the mutHLS pathway of mismatch repair. A set of 15 different M13mp2 heteroduplexes was used to measure the mismatch-repair capability of wild-type, mutL and mutD5 cells. Throughout the series, the mutD5 strain proved as deficient in mismatch repair as the mutL strain, indicating that the repair defect is similar in the two strains in both extent and specificity. [One exception was noted in the case a T.G mispair that was subject to VSP (Very Short Patch) repair. VSP repair was abolished by mutL but not by mutD.] Variation in the dam-methylation state of the heteroduplex molecules clearly affected repair in the wild-type strain but had no effect on either the mutD or mutL strain. Finally, mutDmutL or mutDmutS double-mutator strains were no more deficient in mismatch repair as were the single mutator strains. The combined results strongly argue that the mismatch-repair deficiency of mutD5 cells resides in the mutH,L,S-dependent pathway of mismatch repair and that the high mutation rate of mutD strains derives in part from this defect.     

Spontaneously arising mutL mutators in evolving Escherichia coli populations are the result of changes in repeat length

Over the course of thousands of generations of growth in a glucose-limited environment, 3 of 12 experimental populations of Escherichia coli spontaneously and independently evolved greatly increased mutation rates. In two of the populations, the mutations responsible for this increased mutation rate lie in the same region of the mismatch repair gene mutL. In this region, a 6-bp repeat is present in three copies in the gene of the wild-type ancestor of the experimental populations but is present in four copies in one of the experimental populations and two copies in the other. These in-frame mutations either add or delete the amino acid sequence LA in the MutL protein. We determined that the replacement of the wild-type sequence with either of these mutations was sufficient to increase the mutation rate of the wild-type strain to a level comparable to that of the mutator strains. Complementation of strains bearing the mutator mutations with wild-type copies of either mutL or the mismatch repair gene uvrD rescued the wild-type mutation rate. The position of the mutator mutations-in the region of MutL known as the ATP lid-suggests a possible deficiency in MutL's ATPase activity as the cause of the mutator phenotype. The similarity of the two mutator mutations (despite the independent evolutionary histories of the populations that gave rise to them) leads to a discussion of the potential adaptive role of DNA repeats.     

The mismatch repair system (mutS, mutL and uvrD genes) in Pseudomonas aeruginosa: molecular characterization of naturally occurring mutants

We have recently described the presence of a high proportion of Pseudomonas aeruginosa isolates (20%) with an increased mutation frequency (mutators) in the lungs of cystic fibrosis (CF) patients. In four out of 11 independent P. aeruginosa strains, the high mutation frequency was found to be complemented with the wild-type mutS gene from P. aeruginosa PAO1. Here, we report the cloning and sequencing of two additional P. aeruginosa mismatch repair genes and the characterization, by complementation of deficient strains, of these two putative P. aeruginosa mismatch repair genes (mutL and uvrD). We also describe the alterations in the mutS, mutL and uvrD genes responsible for the mutator phenotype of hypermutable P. aeruginosa strains isolated from CF patients. Seven out of the 11 mutator strains were found to be defective in the MMR system (four mutS, two mutL and one uvrD). In four cases (three mutS and one mutL), the genes contained frameshift mutations. The fourth mutS strain showed a 3.3 kb insertion after the 10th nucleotide of the mutS gene, and a 54 nucleotide deletion between two eight nucleotide direct repeats. This deletion, involving domain II of MutS, was found to be the main one responsible for mutS inactivation. The second mutL strain presented a K310M mutation, equivalent to K307 in Escherichia coli MutL, a residue known to be essential for its ATPase activity. Finally, the uvrD strain had three amino acid substitutions within the conserved ATP binding site of the deduced UvrD polypeptide, showing defective mismatch repair activity. Interestingly, cells carrying this mutant allele exhibited a fully active UvrABC-mediated excision repair. The results shown here indicate that the putative P. aeruginosa mutS, mutL and uvrD genes are mutator genes and that their alteration results in a mutator phenotype.     

Inefficient mismatch repair: genetic defects and down regulation

The mismatch repair system is involved in the maintenance of genomic integrity by editing DNA replication and recombination. However, although most mutations are neutral or deleterious, a mutator phenotype due to an inefficient mismatch repair may generate advantageous variants and may therefore be selected for. We review the evidence for inefficient mismatch repair due either to genetic defects in mismatch repair genes or to physiological conditions. Among natural isolates ofEscherichia coli andSalmonella enterica, about 1% are mutator bacteria, mostly deficient in mismatch repair (most of them defective in themutS gene). Characterization of mutators derived from laboratory strains led also to the isolation of mismatch repair mutants in which the most frequently found defects are inmutL andmutS. The correlation of the size of the antimutator genes with the frequency of their defective alleles amongE. coli andSalmonella strains reveals thatmutU mutants are underrepresented. Analysis of the progeny of a defined M13 phage heteroduplex DNA transfected intoE. coli cells shows that mismatch repair efficiency progressively decreases from the end of the exponential growth in K-12 and is variable among natural isolates. Implications of this defective mismatch repair activity for evolution and tumorigenesis will be discussed.     

Genetic adaptation of Pseudomonas aeruginosa to the airways of cystic fibrosis patients is catalyzed by hypermutation

In previous work (E. E. Smith, D. G. Buckley, Z. Wu, C. Saenphimmachack, L. R. Hoffman, D. A. D'Argenio, S. I. Miller, B. W. Ramsey, D. P. Speert, S. M. Moskowitz, J. L. Burns, R. Kaul, and M. V. Olson, Proc. Natl. Acad. Sci. USA 103:8487-8492, 2006) it was shown that Pseudomonas aeruginosa undergoes intense genetic adaptation during chronic respiratory infection (CRI) in cystic fibrosis (CF) patients. We used the same collection of isolates to explore the role of hypermutation in this process, since one of the hallmarks of CRI is the high prevalence of DNA mismatch repair (MMR) system-deficient mutator strains. The presence of mutations in 34 genes (many of them positively linked to adaptation in CF patients) in the study collection of 90 P. aeruginosa isolates obtained longitudinally from 29 CF patients was not homogeneous; on the contrary, mutations were significantly concentrated in the mutator lineages, which represented 17% of the isolates (87% MMR deficient). While sequential nonmutator lineages acquired a median of only 0.25 mutation per year of infection, mutator lineages accumulated more than 3 mutations per year. On the whole-genome scale, data for the first fully sequenced late CF isolate, which was also shown to be an MMR-deficient mutator, also support these findings. Moreover, for the first time the predicted amplification of mutator populations due to hitchhiking with adaptive mutations in the course of natural human infections is clearly documented. Interestingly, increased accumulation of mutations in mutator lineages was not a consequence of overrepresentation of mutations in genes involved in antimicrobial resistance, the only adaptive trait linked so far to hypermutation in CF patients, demonstrating that hypermutation also plays a major role in P. aeruginosa genome evolution and adaptation during CRI.     

Volatility of Mutator Phenotypes at Single Cell Resolution

Mutator phenotypes accelerate the evolutionary process of neoplastic transformation. Historically, the measurement of mutation rates has relied on scoring the occurrence of rare mutations in target genes in large populations of cells. Averaging mutation rates over large cell populations assumes that new mutations arise at a constant rate during each cell division. If the mutation rate is not constant, an expanding mutator population may contain subclones with widely divergent rates of evolution. Here, we report mutation rate measurements of individual cell divisions of mutator yeast deficient in DNA polymerase ε proofreading and base-base mismatch repair. Our data are best fit by a model in which cells can assume one of two distinct mutator states, with mutation rates that differ by an order of magnitude. In error-prone cell divisions, mutations occurred on the same chromosome more frequently than expected by chance, often in DNA with similar predicted replication timing, consistent with a spatiotemporal dimension to the hypermutator state. Mapping of mutations onto predicted replicons revealed that mutations were enriched in the first half of the replicon as well as near termination zones. Taken together, our findings show that individual genome replication events exhibit an unexpected volatility that may deepen our understanding of the evolution of mutator-driven malignancies.     

Mutagenic and comutagenic effects of ethionine in Escherichia coli K12

A possible mutagenic and comutagenic activity of ethionine, an analog of the amino acid methionine, was investigated in several mutant strains of E. coli K12. Ethionine was found to act as a weak mutagen only in a mismatch repair deficient mutator strain (mutL) and as a comutagen with 2-aminopurine (2AP) in a wild type E. coli. The latter effect was nor observed in a restriction-deficient strain (r-) nor in a recombination or SOS-deficient recA strain. These effects are interpreted as a consequence of restriction-induced double-strand breaks in hypomethylated E. coli DNA resulting in induction of the SOS mutator effect which generates predominantly mismatch correctable untargeted mutations.     

Mismatch repair genes of Streptococcus pneumoniae: HexA confers a mutator phenotype in Escherichia coli by negative complementation.

DNA repair systems able to correct base pair mismatches within newly replicated DNA or within heteroduplex molecules produced during recombination are widespread among living organisms. Evidence that such generalized mismatch repair systems evolved from a common ancestor is particularly strong for two of them, the Hex system of the gram-positive Streptococcus pneumoniae and the Mut system of the gram-negative Escherichia coli and Salmonella typhimurium. The homology existing between HexA and MutS and between HexB and MutL prompted us to investigate the effect of expressing hex genes in E. coli. Complementation of mutS or mutL mutations, which confer a mutator phenotype, was assayed by introducing on a multicopy plasmid the hexA and hexB genes, under the control of an inducible promoter, either individually or together in E. coli strains. No decrease in mutation rate was conferred by either hexA or hexB gene expression. However, a negative complementation effect was observed in wild-type E. coli cells: expression of hexA resulted in a typical Mut- mutator phenotype. hexB gene expression did not increase the mutation rate either individually or in conjunction with hexA. Since expression of hexA did not affect the mutation rate in mutS mutant cells and the hexA-induced mutator effect was recA independent, it is concluded that this effect results from inhibition of the Mut system. We suggest that HexA, like its homolog MutS, binds to mismatches resulting from replication errors, but in doing so it protects them from repair by the Mut system. In agreement with this hypothesis, an increase in mutS gene copy number abolished the hexA-induced mutator phenotype. HexA protein could prevent repair either by being unable to interact with Mut proteins or by producing nonfunctional repair complexes.     

Dominant negative mutator mutations in the mutS gene of Escherichia coli.

The MutS protein of Escherichia coli is part of the dam-directed MutHLS mismatch repair pathway which rectifies replication errors and which prevents recombination between related sequences. In order to more fully understand the role of MutS in these processes, dominant negative mutS mutations on a multicopy plasmid were isolated by screening transformed wild-type cells for a mutator phenotype, using a Lac+ papillation assay. Thirty-eight hydroxylamine- and 22 N-methyl-N'-nitro-N-nitrosoguanidine-induced dominant mutations were isolated. Nine of these mutations altered the P-loop motif of the ATP-binding site, resulting in four amino acid substitutions. With one exception, the remaining sequenced mutations all caused substitution of amino acids conserved during evolution. The dominant mutations in the P-loop consensus caused severely reduced repair of heteroduplex DNA in vivo in a mutS mutant host strain. In a wild-type strain, the level of repair was decreased by the dominant mutations to between 12 to 90% of the control value, which is consistent with interference of wild-type MutS function by the mutant proteins. Increasing the wild-type mutS gene dosage resulted in a reversal of the mutator phenotype in about 60% of the mutant strains, indicating that the mutant and wild-type proteins compete. In addition, 20 mutant isolates showed phenotypic reversal by increasing the gene copies of either mutL or mutH. There was a direct correlation between the levels of recombination and mutagenesis in the mutant strains, suggesting that these phenotypes are due to the same function of MutS.     

The extreme mutator effect of Escherichia coli mutD5 results from saturation of mismatch repair by excessive DNA replication errors.

Escherichia coli mutator mutD5 is the most potent mutator known. The mutD5 mutation resides in the dnaQ gene encoding the proofreading exonuclease of DNA polymerase III holoenzyme. It has recently been shown that the extreme mutability of this strain results, in addition to a proofreading defect, from a defect in mutH, L, S-encoded postreplicational DNA mismatch repair. The following measurements of the mismatch-repair capacity of mutD5 cells demonstrate that this mismatch-repair defect is not structural, but transient. mutD5 cells in early log phase are as deficient in mismatch repair as mutL cells, but they become as proficient as wild-type cells in late log phase. Second, arrest of chromosomal replication in a mutD5-dnaA(Ts) strain at a nonpermissive temperature restores mismatch repair, even from the early log phase of growth. Third, transformation of mutD5 strains with multicopy plasmids expressing the mutH or mutL gene restores mismatch repair, even in rapidly growing cells. These observations suggest that the mismatch-repair deficiency of mutD strains results from a saturation of the mutHLS-mismatch-repair system by an excess of primary DNA replication errors due to the proofreading defect.     

Analysis of conditional mutations in the Saccharomyces cerevisiae MLH1 gene in mismatch repair and in meiotic crossing over

In mismatch repair (MMR), members of the MLH gene family have been proposed to act as key molecular matchmakers to coordinate mismatch recognition with downstream repair functions that result in mispair excision. Two members of this gene family, MLH1 and MLH3, have also been implicated in meiotic crossing over. These diverse roles suggest that a mutational analysis of MLH genes could provide reagents required to identify interactions between gene products and to test whether the different roles ascribed to a subset of these genes can be separated. In this report we show that in Saccharomyces cerevisiae the mlh1Delta mutation confers inviability in pol3-01 strain backgrounds that are defective in the Poldelta proofreading exonuclease activity. This phenotype was exploited to identify four mlh1 alleles that each confer a temperature-sensitive phenotype for viability in pol3-01 strains. In three different mutator assays, strains bearing conditional mlh1 alleles displayed wild-type or nearly wild-type mutation rates at 26 degrees. At 35 degrees, these strains exhibited mutation rates that approached those observed in mlh1Delta mutants. The mutator phenotype exhibited in mlh1-I296S strains was partially suppressed at 35 degrees by EXO1 overexpression. The mlh1-F228S and -I296S mutations conferred a separation-of-function phenotype in meiosis; both mlh1-F228S and -I296S strains displayed strong defects in meiotic mismatch repair but showed nearly wild-type levels of crossing over, suggesting that the conditional mutations differentially affected MLH1 functions. These genetic studies suggest that the conditional mlh1 mutations can be used to separate the MMR and meiotic crossing-over functions of MLH1 and to identify interactions between MLH1 and downstream repair components.     

Establishment and characterization of four human pancreatic carcinoma cell lines. Genetic alterations in the TGFBR2 gene but not in the MADH4 gene

We characterized four pancreatic carcinoma cell lines (designated SNU-213, SNU-324, SNU-410, and SNU-494) established from histopathologically varied primary or liver metastatic tumor samples of Korean patients. Three cell lines grew as adherent monolayers and one as adherent and floating cell clumps. All lines had: (1) relatively high viability; (2) an absence of mycoplasma or bacterial contamination; (3) genetic heterogeneity as assessed by DNA-fingerprinting analysis; (4) an absence of MADH4 mutation. Among the lines, three lines had mutations in codon 12 in K- ras, two lines harbored p53 mutations within the DNA-binding domain; two lines had homozygous deletions in both p16 and p15 genes; and one line had a missense mutation. Two lines (SNU-324 and SNU-410) had genetic alterations in the TGFBR2 gene: the SNU-324 line had a -1-bp or +1-bp mutation in 10-bp polydeoxyadenine repeat tracts; the SNU-410 line had a genomic deletion in this gene. Mutation analysis of mismatch repair genes demonstrated that SNU-324 has two heterozygous missense mutations in different exons of the hMLH1 gene. In addition, this line showed microsatellite instability and harbored frameshift mutations in simple repeated sequences of the coding regions of the TGFBR2, BAX, and hMSH3 genes. These defects of microsatellite instability and mismatch repair genes suggest the possibility of a new mutator phenotype for pancreatic carcinogenesis. These cell lines should be very useful for studying the biology of pancreatic carcinoma, particularly those related to mutator phenotype and genetic alterations in the TGFBR2 gene.     

Bacterial DNA repair genes and their eukaryotic homologues: 2. Role of bacterial mutator gene homologues in human disease. Overview of nucleotide pool sanitization and mismatch repair systems

Since the discovery of the first E. coli mutator gene, mutT, most of the mutations inducing elevated spontaneous mutation rates could be clearly attributed to defects in DNA repair. MutT turned out to be a pyrophosphohydrolase hydrolyzing 8-oxodGTP, thus preventing its incorporation into DNA and suppresing the occurrence of spontaneous AT-->CG transversions. Most of the bacterial mutator genes appeared to be evolutionarily conserved, and scientists were continuously searching for contribution of DNA repair deficiency in human diseases, especially carcinogenesis. Yet a human MutT homologue--hMTH1 protein--was found to be overexpressed rather than inactivated in many human diseases, including cancer. The interest in DNA repair contribution to human diseases exploded with the observation that germline mutations in mismatch repair (MMR) genes predispose to hereditary non-polyposis colorectal cancer (HNPCC). Despite our continuously growing knowledge about DNA repair we still do not fully understand how the mutator phenotype contributes to specific forms of human diseases.     

An Oak Ridge legacy: the specific locus test and its role in mouse mutagenesis.

Mutations in the genes encoding single-strand DNA-specific exonucleases (ssExos) of Escherichia coli were examined for effects on mutation avoidance, UV repair, and conjugational recombination. Our results indicate complex and partially redundant roles for ssExos in these processes. Although biochemical experiments have implicated RecJ exonuclease, Exonuclease I (ExoI), and Exonuclease VII (ExoVII) in the methyl-directed mismatch repair pathway, the RecJ- ExoI- ExoVII- mutant did not exhibit a mutator phenotype in several assays for base substitution mutations. If these exonucleases do participate in mismatch excision, other exonucleases in E. coli can compensate for their loss. Frameshift mutations, however, were stimulated in the RecJ- ExoI- ExoVII- mutant. For acridine-induced frameshifts, this mutator effect was due to a synergistic effect of ExoI- and ExoVII- mutations, implicating both ExoI and ExoVII in avoidance of frameshift mutations. Although no single exonuclease mutant was especially sensitive to UV irradiation, the RecJ- ExoVII- double mutant was extremely sensitive. The addition of an ExoI- mutation augmented this sensitivity, suggesting that all three exonucleases play partially redundant roles in DNA repair. The ability to inherit genetic markers by conjugation was reduced modestly in the ExoI- RecJ- mutant, implying that the function of either ExoI or RecJ exonucleases enhances RecBCD-dependent homologous recombination.     

DNA methylation alters the pattern of spontaneous mutation in Escherichia coli cells (mutD) defective in DNA polymerase III proofreading

We have shown previously that dam mutants of Escherichia coli have a weak mutator phenotype which generates mostly transition mutations in the P22 mnt gene. In contrast, in mutD5 cells, which have a strong mutator phenotype, transversion mutations were the most prevalent. A dam-16 mutD5 strain, defective in both DNA polymerase III associated-proofreading and Dam-directed mismatch repair exhibits a strong mutator phenotype but, surprisingly, its mutation spectrum is similar to that of the dam rather than the mutD parent. The most likely explanation is that Dam-directed mismatch repair in the mutD5 strain corrects most of the potential transition mutations (therefore yielding transversions) in the newly synthesised strand. When the dam-16 allele is present together with mutD5 a reduced efficiency of repair as well as loss of strand discrimination and misdirected repair results in the appearance of transition mutations at high frequency.