Mismatch recognition function of Arabidopsis thaliana MutSγ

Genetic stability depends in part on an efficient DNA lesion recognition and correction by the DNA mismatch repair (MMR) system. In eukaryotes, MMR is initiated by the binding of heterodimeric MutS homologue (MSH) complexes, MSH2–MSH6 and MSH2–MSH3, which recognize and bind mismatches and unpaired nucleotides. Plants encode another mismatch recognition protein, named MSH7. MSH7 forms a heterodimer with MSH2 and the protein complex is designated MutSγ. We here report the effect the expression of Arabidopsis MSH2 and MSH7 alone or in combination exert on the genomic stability of Saccharomyces cerevisiae. AtMSH2 and AtMutSγ proteins failed to complement the hypermutator phenotype of an msh2 deficient strain. However, overexpressing AtMutSγ in MMR proficient strains generated a 4-fold increase in CAN1 forward mutation rate, when compared to wild-type strains. Can^r mutation spectrum analysis of AtMutSγ overproducing strains revealed a substantial increase in the frequency of base substitution mutations, including an increased accumulation of base pair changes from G:C to A:T and T:A to C:G, G:C or A:T. Taken together, these results suggest that AtMutSγ affects yeast genomic stability by recognizing specific mismatches and preventing correction by yeast MutSα and MutSβ, with subsequent inability to interact with yeast downstream proteins needed to complete MMR.     

Characterization of Insertion Mutations in the Saccharomyces Cerevisiae Msh1 and Msh2 Genes: Evidence for Separate Mitochondrial and Nuclear Functions

The MSH1 and MSH2 genes of Saccharomyces cerevisiae are predicted to encode proteins that are homologous to the Escherichia coli MutS and Streptococcus pneumoniae HexA proteins and their homologs. Disruption of the MSH1 gene caused a petite phenotype which was established rapidly. A functional MSH1 gene present on a single-copy centromere plasmid was incapable of rescuing the established msh1 petite phenotype. Analysis of msh1 strains demonstrated that mutagenesis and large-scale rearrangement of mitochondrial DNA had occurred. 4',6-Diamidino-2-phenylindole (DAPI) staining of msh1 yeast revealed an aberrant distribution of mtDNA. Haploid msh2 mutants displayed an increase of 85-fold in the rate of spontaneous mutation to canavanine resistance. Sporulation of homozygous msh2/msh2 diploids gave rise to a high level of lethality which was compounded during increased vegetative growth prior to sporulation. msh2 mutations also affected gene conversion of two HIS4 alleles. The his4x mutation, lying near the 5' end of the gene, was converted with equal frequency in both wild-type and msh2 strains. However, many of the events in the msh2 background were post-meiotic segregation (PMS) events (46.4%) while none (< 0.25%) of the aberrant segregations in wild type were PMS events. The his4b allele, lying 1.6 kb downstream of his4x, was converted at a 10-fold higher frequency in the msh2 background than in the corresponding wild-type strain. Like the his4x allele, his4b showed a high level of PMS (30%) in the msh2 background compared to the corresponding wild-type strain where no (< 0.26%) PMS events were observed. These results indicate that MSH1 plays a role in repair or stability of mtDNA and MSH2 plays a role in repair of 4-bp insertion/deletion mispairs in the nucleus.     

Identification of mismatch repair protein complexes in HeLa nuclear extracts and their interaction with heteroduplex DNA

Deficiencies in DNA mismatch repair (MMR) have been found in hereditary colon cancers (hereditary non-polyposis colon cancer, HNPCC) as well as in sporadic cancers, illustrating the importance of MMR in maintaining genomic integrity. We have examined the interactions of specific mismatch repair proteins in human nuclear extracts. Western blot and co-immunoprecipitation studies indicate two complexes as follows: one consisting of hMSH2, hMSH6, hMLH1, and hPMS2 and the other consisting of hMSH2, hMSH6, hMLH1, and hPMS1. These interactions occur without the addition of ATP. Furthermore, the protein complexes specifically bind to mismatched DNA and not to a similar homoduplex oligonucleotide. The protein complex-DNA interactions occur primarily through hMSH6, although hMSH2 can also become cross-linked to the mismatched substrate when not participating in the MMR protein complex. In the presence of ATP the binding of hMSH6 to mismatched DNA is decreased. In addition, hMLH1, hPMS2, and hPMS1 no longer interact with each other or with the hMutSalpha complex (hMSH2 and hMSH6). However, the ability of hMLH1 to co-immunoprecipitate mismatched DNA increases in the presence of ATP. This interaction is dependent on the presence of the mismatch and does not appear to involve a direct binding of hMLH1 to the DNA.     

Frameshift intermediates in homopolymer runs are removed efficiently by yeast mismatch repair proteins.

A change in the number of base pairs within a coding sequence can result in a frameshift mutation, which almost invariably eliminates the function of the encoded protein. A frameshift reversion assay with Saccharomyces cerevisiae that can be used to examine the types of insertions and deletions that are generated during DNA replication, as well as the editing functions that remove such replication errors, has been developed. Reversion spectra have been obtained in a wild-type strain and in strains defective for defined components of the postreplicative mismatch repair system (msh2, msh3, msh6, msh3 msh6, pms1, and mih1 mutants). Comparison of the spectra reveals that yeast mismatch repair proteins preferentially remove frameshift intermediates that arise in homopolymer tracts and indicates that some of the proteins have distinct substrate or context specificities.     

Msh2 separation of function mutations confer defects in the initiation steps of mismatch repair

In eukaryotes the MSH2-MSH3 and MSH2-MSH6 heterodimers initiate mismatch repair (MMR) by recognizing and binding to DNA mismatches. The MLH1-PMS1 heterodimer then interacts with the MSH proteins at or near the mismatch site and is thought to act as a mediator to recruit downstream repair proteins. Here we analyzed five msh2 mutants that are functional in removing 3' non-homologous tails during double-strand break repair but are completely defective in MMR. Because non-homologous tail removal does not require MSH6, MLH1, or PMS1 functions, a characterization of the msh2 separation of function alleles should provide insights into early steps in MMR. Using the Taq MutS crystal structure as a model, three of the msh2 mutations, msh2-S561P, msh2-K564E, msh2-G566D, were found to map to a domain in MutS involved in stabilizing mismatch binding. Gel mobility shift and DNase I footprinting assays showed that two of these mutations conferred strong defects on MSH2-MSH6 mismatch binding. The other two mutations, msh2-S656P and msh2-R730W, mapped to the ATPase domain. DNase I footprinting, ATP hydrolysis, ATP binding, and MLH1-PMS1 interaction assays indicated that the msh2-S656P mutation caused defects in ATP-dependent dissociation of MSH2-MSH6 from mismatch DNA and in interactions between MSH2-MSH6 and MLH1-PMS1. In contrast, the msh2-R730W mutation disrupted MSH2-MSH6 ATPase activity but did not strongly affect ATP binding or interactions with MLH1-PMS1. These results support a model in which MMR can be dissected into discrete steps: stable mismatch binding and sensing, MLH1-PMS1 recruitment, and recycling of MMR components.     

Identification of factors interacting with hMSH2 in the fetal liver utilizing the yeast two-hybrid system. In vivo interaction through the C-terminal domains of hEXO1 and hMSH2 and comparative expression analysis

Mutations in DNA mismatch repair (MMR) genes have been shown to segregate with Hereditary Nonpolyposis Colorectal Cancer (HNPCC). However, because many HNPCC families fail to display mutations in known MMR genes, we argued that changes in other components of the MMR pathway may be responsible. The increasing number of proteins reported to interact in the MMR pathway suggests that larger complexes are formed, the composition of which may differ among cell types and tissues. In an attempt to identify tissue-specific MMR-associated factors, we employed the yeast two-hybrid system, using the human hMSH2 as bait and a human fetal liver library as prey. We demonstrate that hMSH2 interacts with a human 5'-3' exonuclease 1 (hEXO1/HEX1) and that this interaction is mediated through their C-terminal domains. The hMSH6 protein does not interact with hEXO1 in the two-hybrid system. Dot-blot analysis of multiple tissue RNA revealed that hMSH2 and hEXO1 are coexpressed at high levels in fetal liver as well as in adult testis and thymus. Northern blot analysis also revealed that hEXO1/HEX1 is highly expressed in several liver cancer cell lines as well as in colon and pancreas adenocarcinomas, but not in the corresponding non-neoplastic tissue.     

Yeast mutator phenotype enforced by Arabidopsis PMS1 expression

The DNA mismatch repair (MMR) system is a major DNA repair pathway whose function is critical for the correction of DNA biosynthetic errors. MMR is initiated by the binding of MutS proteins to mismatches and unpaired nucleotides followed by the recruitment of MutL proteins. The major MutL activity in eukaryotes is performed by MutLα, the heterocomplex of MLH1-PMS1 in yeast and plants and MLH1-PMS2 in humans. We here report the effect the expression of Arabidopsis PMS1 protein exerts on Saccharomyces cerevisiae genomic stability. A strain carrying specific microsatellite instability reporter systems was chosen for the study. The plant protein failed to complement the hypermutator phenotype of a pms1 deficient strain but increased approximately 14-fold and 2,000-fold the mutation rates of his7-2 and lys2::InsE-A ₁₄ loci of MMR proficient strains when compared to wild-type strains, respectively. Overexpressing AtMLH1 in the AtPMS1-overproducing strain generated an increase in mutation rate comparable to that of AtPMS1 expression alone. Deletion of the C-terminal residues implicated in protein–protein interaction and including the putative endonuclease sequence of AtPMS1 completely eliminated the mutator phenotype. Taken together, these results indicate that the plant proteins affect yeast genomic stability, very possibly altering protein–protein interactions that are necessary to complete repair.     

Isolation and characterization of new proliferating cell nuclear antigen (POL30) mutator mutants that are defective in DNA mismatch repair

A number of studies have suggested a role for proliferating cell nuclear antigen (PCNA) in DNA mismatch repair (MMR). However, the majority of mutations in the POL30 gene encoding PCNA that cause MMR defects also cause replication and other repair defects that contribute to the increased mutation rate caused by these mutations. Here, 20 new pol30 mutants were identified and screened for MMR and other defects, resulting in the identification of two mutations, pol30-201 and pol30-204, that appear to cause MMR defects but little if any other defects. The pol30-204 mutation altered an amino acid (C81R) in the monomer-monomer interface region and resulted in a partial general MMR defect and a defect in MSH2-MSH6 binding in vitro. The pol30-201 mutation altered an amino acid (C22Y) located on the surface of the PCNA trimer that slides over the DNA but did not cause a defect in MSH2-MSH6 binding in vitro. The pol30-201 mutation caused an intermediate mutator phenotype. However, the pol30-201 mutation caused almost a complete defect in the repair of AC and GT mispairs and only a small defect in the repair of a "+T" insertion, an effect similar to that caused by an msh6Delta mutation, indicating that pol30-201 primarily effects MSH6-dependent MMR. The chromosomal double mutant msh3-FF>AA msh6-FF>AA eliminating the conserved FF residues of the PCNA interacting motif of these proteins caused a small (<10%) defect in MMR but showed synergistic interactions with mutations in POL30, indicating that the FF>AA substitution may not eliminate PCNA interactions in vivo. These results indicate that the interaction between PCNA and MMR proteins is more complex than was previously appreciated.     

Implication of protein kinase C in the regulation of DNA mismatch repair protein expression and function

The DNA mismatch repair (MMR) proteins are essential for the maintenance of genomic stability of human cells. Compared with hereditary or even sporadic carcinomas, MMR gene mutations are very uncommon in leukemia. However, genetic instability, attested by either loss of heterozygosity or microsatellite instability, has been extensively documented in chronic or acute malignant myeloid disorders. This observation suggests that in leukemia some internal or external signals may interfere with MMR protein expression and/or function. We investigated the effects of protein kinase C (PKC) stimulation by 12-O-tetradecanoylphorbol-13-acetate (TPA) on MMR protein expression and activity in human myeloid leukemia cell lines. First, we show here that unstimulated U937 cells displayed low level of PKC activity as well as MMR protein expression and activity compared with a panel of myeloid cell lines. Second, treatment of U937 cells with TPA significantly increased (3-5-fold) hMSH2 expression and, to a lesser extent, hMSH6 and hPMS2 expression, correlated to a restoration of MMR function. In addition, diacylglycerol, a physiological PKC agonist, induced a significant increase in hMSH2 expression, whereas chelerythrine or calphostin C, two PKC inhibitors, significantly decreased TPA-induced hMSH2 expression. Reciprocally, treatment of HEL and KG1a cells that exhibited a high level of PKC expression, with chelerythrine significantly decreased hMSH2 and hMSH6 expression. Moreover, the alteration of MMR protein expression paralleled the difference in microsatellite instability and cell sensitivity to 6-thioguanine. Our results suggest that PKC could play a role in regulating MMR protein expression and function in some myeloid leukemia cells.     

The oxidized deoxynucleoside triphosphate pool is a significant contributor to genetic instability in mismatch repair-deficient cells

Oxidation is a common form of DNA damage to which purines are particularly susceptible. We previously reported that oxidized dGTP is potentially an important source of DNA 8-oxodGMP in mammalian cells and that the incorporated lesions are removed by DNA mismatch repair (MMR). MMR deficiency is associated with a mutator phenotype and widespread microsatellite instability (MSI). Here, we identify oxidized deoxynucleoside triphosphates (dNTPs) as an important cofactor in this genetic instability. The high spontaneous hprt mutation rate of MMR-defective msh2(-/-) mouse embryonic fibroblasts was attenuated by expression of the hMTH1 protein, which degrades oxidized purine dNTPs. A high level of hMTH1 abolished their mutator phenotype and restored the hprt mutation rate to normal. Molecular analysis of hprt mutants showed that the presence of hMTH1 reduced the incidence of mutations in all classes, including frameshifts, and also implicated incorporated 2-oxodAMP in the mutator phenotype. In hMSH6-deficient DLD-1 human colorectal carcinoma cells, overexpression of hMTH1 markedly attenuated the spontaneous mutation rate and reduced MSI. It also reduced the incidence of -G and -A frameshifts in the hMLH1-defective DU145 human prostatic cancer cell line. Our findings indicate that incorporation of oxidized purines from the dNTP pool may contribute significantly to the extreme genetic instability of MMR-defective human tumors.     

Sequence composition and context effects on the generation and repair of frameshift intermediates in mononucleotide runs in Saccharomyces cerevisiae

DNA polymerase slippage occurs frequently in tracts of a tandemly repeated nucleotide, and such slippage events can be genetically detected as frameshift mutations. In long mononucleotide runs, most frameshift intermediates are repaired by the postreplicative mismatch repair (MMR) machinery, rather than by the exonucleolytic proofreading activity of DNA polymerase. Although mononucleotide runs are hotspots for polymerase slippage events, it is not known whether the composition of a run and the surrounding context affect the frequency of slippage or the efficiency of MMR. To address these issues, 10-nucleotide (10N) runs were inserted into the yeast LYS2 gene to create +1 frameshift alleles. Slippage events within these runs were detected as Lys(+) revertants. 10G or 10C runs were found to be more unstable than 10A or 10T runs, but neither the frequency of polymerase slippage nor the overall efficiency of MMR was greatly influenced by sequence context. Although complete elimination of MMR activity (msh2 mutants) affected all runs similarly, analyses of reversion rates in msh3 and msh6 mutants revealed distinct specificities of the yeast Msh2p-Msh3p and Msh2p-Msh6p mismatch binding complexes in the repair of frameshift intermediates in different sequence contexts.     

Different frameshift mutation spectra in non-repetitive DNA of MutSalpha- and MutLalpha-deficient fission yeast cells

A frameshift reversion assay has been established for Schizosaccharomyces pombe, which allows detection of deletions and insertions of nucleotides in a non-repetitive DNA sequence. Compared to wild type, frameshift mutation rates were increased in the mismatch repair (MMR) mutants msh2, msh6, mlh1, and pms1, but not in a swi4 strain (defective in the Msh3 homologue). Rates were also elevated in the DNA nuclease-deficient strains rad2 (defective in the FEN-1 homologue) and exo1. In MutSalpha-deficient strains, msh2 and msh6, most of the reversions were 1bp deletions. In contrast, mlh1 and pms1 mutants, defective in MutLalpha, accumulated significantly more 2bp insertions, preferentially of the type CG to (CG)(2). Such duplications were less frequent in double mutants additionally defective in msh2, msh6, rad2, or exo1. Thus, accumulation of (CG)(2) in MutLalpha-deficient strains depends on the presence of MutSalpha, Rad2 and Exo1.     

Saccharomyces cerevisiae MSH2-MSH3 and MSH2-MSH6 complexes display distinct requirements for DNA binding domain I in mismatch recognition

In eukaryotic mismatch repair (MMR) MSH2-MSH6 initiates the repair of base-base and small insertion/deletion mismatches while MSH2-MSH3 repairs larger insertion/deletion mismatches. Here, we show that the msh2Delta1 mutation, containing a complete deletion of the conserved mismatch recognition domain I of MSH2, conferred a separation of function phenotype with respect to MSH2-MSH3 and MSH2-MSH6 functions. Strains bearing the msh2Delta1 mutation were nearly wild-type in MSH2-MSH6-mediated MMR and in suppressing recombination between DNA sequences predicted to form mismatches recognized by MSH2-MSH6. However, these strains were completely defective in MSH2-MSH3-mediated MMR and recombination functions. This information encouraged us to analyze the contributions of domain I to the mismatch binding specificity of MSH2-MSH3 in genetic and biochemical assays. We found that domain I in MSH2 contributed a non-specific DNA binding activity while domain I of MSH3 appeared important for mismatch binding specificity and for suppressing non-specific DNA binding. These observations reveal distinct requirements for the MSH2 DNA binding domain I in the repair of DNA mismatches and suggest that the binding of MSH2-MSH3 to mismatch DNA involves protein-DNA contacts that appear very different from those required for MSH2-MSH6 mismatch binding.     

A mutation in the MSH6 subunit of the Saccharomyces cerevisiae MSH2-MSH6 complex disrupts mismatch recognition.

In yeast, MSH2 interacts with MSH6 to repair base pair mismatches and single nucleotide insertion/deletion mismatches and with MSH3 to recognize small loop insertion/deletion mismatches. We identified a msh6 mutation (msh6-F337A) that when overexpressed in wild type strains conferred a defect in both MSH2-MSH6- and MSH2-MSH3-dependent mismatch repair pathways. Genetic analysis suggested that this phenotype was due to msh6-F337A sequestering MSH2 and preventing it from interacting with MSH3 and MSH6. In UV cross-linking, filter binding, and gel retardation assays, the MSH2-msh6-F337A complex displayed a mismatch recognition defect. These observations, in conjunction with ATPase and dissociation rate analysis, suggested that MSH2-msh6-F337A formed an unproductive complex that was unable to stably bind to mismatch DNA.     

Separation-of-Function Mutations in Saccharomyces cerevisiae MSH2 That Confer Mismatch Repair Defects but Do Not Affect Nonhomologous-Tail Removal during Recombination

Yeast Msh2p forms complexes with Msh3p and Msh6p to repair DNA mispairs that arise during DNA replication. In addition to their role in mismatch repair (MMR), the MSH2 and MSH3 gene products are required to remove 3' nonhomologous DNA tails during genetic recombination. The mismatch repair genes MSH6, MLH1, and PMS1, whose products interact with Msh2p, are not required in this process. We have identified mutations in MSH2 that do not disrupt genetic recombination but confer a strong defect in mismatch repair. Twenty-four msh2 mutations that conferred a dominant negative phenotype for mismatch repair were isolated. A subset of these mutations mapped to residues in Msh2p that were analogous to mutations identified in human nonpolyposis colorectal cancer msh2 kindreds. Approximately half of the these MMR-defective mutations retained wild-type or nearly wild-type activity for the removal of nonhomologous DNA tails during genetic recombination. The identification of mutations in MSH2 that disrupt mismatch repair without affecting recombination provides a first step in dissecting the Msh-effector protein complexes that are thought to play different roles during DNA repair and genetic recombination.     

Alkylation damage causes MMR-dependent chromosomal instability in vertebrate embryos

S(N)1-type alkylating agents, like N-methyl-N-nitrosourea (MNU) and N-ethyl-N-nitrosourea (ENU), are potent mutagens. Exposure to alkylating agents gives rise to O(6)-alkylguanine, a modified base that is recognized by DNA mismatch repair (MMR) proteins but is not repairable, resulting in replication fork stalling and cell death. We used a somatic mutation detection assay to study the in vivo effects of alkylation damage on lethality and mutation frequency in developing zebrafish embryos. Consistent with the damage-sensing role of the MMR system, mutant embryos lacking the MMR enzyme MSH6 displayed lower lethality than wild-type embryos after exposure to ENU and MNU. In line with this, alkylation-induced somatic mutation frequencies were found to be higher in wild-type embryos than in the msh6 loss-of-function mutants. These mutations were found to be chromosomal aberrations that may be caused by chromosomal breaks that arise from stalled replication forks. As these chromosomal breaks arise at replication, they are not expected to be repaired by non-homologous end joining. Indeed, Ku70 loss-of-function mutants were found to be equally sensitive to ENU as wild-type embryos. Taken together, our results suggest that in vivo alkylation damage results in chromosomal instability and cell death due to aberrantly processed MMR-induced stalled replication forks.     

Mutation rates, spectra and hotspots in mismatch repair-deficient Caenorhabditis elegans

Although it is clear that postreplicative DNA mismatch repair (MMR) plays a critical role in maintaining genomic stability in nearly all forms of life surveyed, much remains to be understood about the genome-wide impact of MMR on spontaneous mutation processes and the extent to which MMR-deficient mutation patterns vary among species. We analyzed spontaneous mutation processes across multiple genomic regions using two sets of mismatch repair-deficient (msh-2 and msh-6) Caenorhabditis elegans mutation-accumulation (MA) lines and compared our observations to mutation spectra in a set of wild-type (WT), repair-proficient C. elegans MA lines. Across most sequences surveyed in the MMR-deficient MA lines, mutation rates were approximately 100-fold higher than rates in the WT MA lines, although homopolymeric nucleotide-run (HP) loci composed of A:T base pairs mutated at an approximately 500-fold greater rate. In contrast to yeast and humans where mutation spectra vary substantially with respect to different specific MMR-deficient genotypes, mutation rates and patterns were overall highly similar between the msh-2 and msh-6 C. elegans MA lines. This, along with the apparent absence of a Saccharomyces cerevisiae MSH3 ortholog in the C. elegans genome, suggests that C. elegans MMR surveillance is carried out by a single Msh-2/Msh-6 heterodimer.     

Mutation rates of TGFBR2 and ACVR2 coding microsatellites in human cells with defective DNA mismatch repair

Microsatellite instability promotes colonic tumorigenesis through generating frameshift mutations at coding microsatellites of tumor suppressor genes, such as TGFBR2 and ACVR2. As a consequence, signaling through these TGFbeta family receptors is abrogated in DNA Mismatch repair (MMR)-deficient tumors. How these mutations occur in real time and mutational rates of these human coding sequences have not previously been studied. We utilized cell lines with different MMR deficiencies (hMLH1-/-, hMSH6-/-, hMSH3-/-, and MMR-proficient) to determine mutation rates. Plasmids were constructed in which exon 3 of TGFBR2 and exon 10 of ACVR2 were cloned +1 bp out of frame, immediately after the translation initiation codon of an enhanced GFP (EGFP) gene, allowing a -1 bp frameshift mutation to drive EGFP expression. Mutation-resistant plasmids were constructed by interrupting the coding microsatellite sequences, preventing frameshift mutation. Stable cell lines were established containing portions of TGFBR2 and ACVR2, and nonfluorescent cells were sorted, cultured for 7-35 days, and harvested for flow cytometric mutation detection and DNA sequencing at specific time points. DNA sequencing revealed a -1 bp frameshift mutation (A9 in TGFBR2 and A7 in ACVR2) in the fluorescent cells. Two distinct fluorescent populations, M1 (dim, representing heteroduplexes) and M2 (bright, representing full mutants) were identified, with the M2 fraction accumulating over time. hMLH1 deficiency revealed 11 (5.91 x 10(-4)) and 15 (2.18 x 10(-4)) times higher mutation rates for the TGFBR2 and ACVR2 microsatellites compared to hMSH6 deficiency, respectively. The mutation rate of the TGFBR2 microsatellite was approximately 3 times higher in both hMLH1 and hMSH6 deficiencies than the ACVR2 microsatellite. The -1 bp frameshift mutation rates of TGFBR2 and ACVR2 microsatellite sequences are dependent upon the human MMR background.     

Analysis of yeast pms1, msh2, and mlh1 mutators points to differences in mismatch correction efficiencies between prokaryotic and eukaryotic cells

Genetic stability relies in part on the efficiency with which post-replicative mismatch repair (MMR) detects and corrects DNA replication errors. In Escherichia coli, endogenous transition mispairs and insertion/deletion (ID) heterologies are corrected with similar efficiencies – but much more efficiently than transversion mispairs – as revealed by mutation rate increases in MMR mutants. To assess the relative efficiencies with which these mismatches are corrected in the yeast Saccharomyces cerevisiae, we examined repair of defined mismatches on heteroduplex plasmids and compared the spectra for >1000 spontaneous SUP4-o mutations arising in isogenic wild-type or MMR-deficient (pms1, mlh1, msh2) strains. Heteroduplexes containing G/T mispairs or ID heterologies were corrected more efficiently than those containing transversion mismatches. However, the rates of single base-pair insertion/deletion were increased much more (82-fold or 34-fold, respectively) on average than the rate of base pair substitutions (4.4-fold), with the rates for total transitions and transversions increasing to similar extents. Thus, the relative efficiencies with which mismatches formed during DNA replication are repaired appear to differ in prokaryotic and eukaryotic cells. In addition, our results indicate that in yeast, and probably other eukaryotes, these efficiencies may not mirror those obtained from an analysis of heteroduplex correction.