Physical and functional interactions between Escherichia coli MutY glycosylase and mismatch repair protein MutS

Escherichia coli MutY and MutS increase replication fidelity by removing adenines that were misincorporated opposite 7,8-dihydro-8-oxo-deoxyguanines (8-oxoG), G, or C. MutY DNA glycosylase removes adenines from these mismatches through a short-patch base excision repair pathway and thus prevents G:C-to-T:A and A:T-to-G:C mutations. MutS binds to the mismatches and initiates the long-patch mismatch repair on daughter DNA strands. We have previously reported that the human MutY homolog (hMYH) physically and functionally interacts with the human MutS homolog, hMutSalpha (Y. Gu et al., J. Biol. Chem. 277:11135-11142, 2002). Here, we show that a similar relationship between MutY and MutS exists in E. coli. The interaction of MutY and MutS involves the Fe-S domain of MutY and the ATPase domain of MutS. MutS, in eightfold molar excess over MutY, can enhance the binding activity of MutY with an A/8-oxoG mismatch by eightfold. The MutY expression level and activity in mutS mutant strains are sixfold and twofold greater, respectively, than those for the wild-type cells. The frequency of A:T-to-G:C mutations is reduced by two- to threefold in a mutS mutY mutant compared to a mutS mutant. Our results suggest that MutY base excision repair and mismatch repair defend against the mutagenic effect of 8-oxoG lesions in a cooperative manner.     

Role of a MutY DNA glycosylase in combating oxidative DNA damage in Helicobacter pylori

MutY is an adenine glycosylase that has the ability to efficiently remove adenines from adenine/7,8-dihydro-8-oxoguanine (8-oxo-G) or adenine/guanine mismatches, and plays an important role in oxidative DNA damage repair. The human gastric pathogen Helicobacter pylori has a homolog of the MutY enzyme. To investigate the physiological roles of MutY in H. pylori, we constructed and characterized a mutY mutant. H. pylori mutY mutants incubated at 5% O2 have a 325-fold higher spontaneous mutation rate than its parent. The mutation rate is further increased by exposing the mutant to atmospheric levels of oxygen, an effect that is not seen in an E. coli mutY mutant. Most of the mutations that occurred in H. pylori mutY mutants, as examined by rpoB sequence changes that confer rifampicin resistance, are GC to TA transversions. The H. pylori enzyme has the ability to complement an E. coli mutY mutant, restoring its mutation frequency to the wild-type level. Pure H. pylori MutY has the ability to remove adenines from A/8-oxo-G mismatches, but strikingly no ability to cleave A/G mismatches. This is surprising because E. coli MutY can more rapidly turnover A/G than A/8-oxo-G. Thus, H. pylori MutY is an adenine glycosylase involved in the repair of oxidative DNA damage with a specificity for detecting 8-oxo-G. In addition, H. pylori mutY mutants are only 30% as efficient as wild-type in colonizing the stomach of mice, indicating that H. pylori MutY plays a significant role in oxidative DNA damage repair in vivo.     

Insight into the functional consequences of inherited variants of the hMYH adenine glycosylase associated with colorectal cancer: complementation assays with hMYH variants and pre-steady-state kinetics of the corresponding mutated E.coli enzymes

The oxidized guanine lesion 7,8-dihydro-8-oxo-2'-deoxyguanosine (OG) is highly mutagenic, resulting in G:C to T:A transversion mutations in the absence of repair. The Escherichia coli adenine glycosylase MutY and its human homolog (hMYH) play an important role in the prevention of mutations associated with OG by removing misincorporated adenine residues from OG:A mismatches. Previously, biallelic mutations of hMYH have been identified in a British family (Family N) with symptoms characteristic of familial adenomatous polyposis (FAP), which is typically associated with mutations in the adenomatous polyposis coli (APC) gene. Afflicted members of this family were compound heterozygotes for two mutations in hMYH, Y165C and G382D. These positions are highly conserved in MutY across phylogeny. The current work reveals a reduced ability of the hMYH variants compared to wild-type (WT) hMYH to complement the activity of E.coli MutY in mutY((-)) E.coli. In vitro analysis of the corresponding mutations in E.coli MutY revealed a reduction in the adenine glycosylase activity of the enzymes. In addition, evaluation of substrate affinity using a substrate analog, 2'-deoxy-2'-fluoroadenosine (FA) revealed that both mutations severely diminish the ability to recognize FA, and discriminate between OG and G. Importantly, adenine removal with both the mutant and WT E.coli enzymes was observed to be less efficient from a mismatch in the sequence context observed to be predominantly mutated in tumors of Family N. Interestingly, the magnitude of the reduced activity of the E.coli mutant enzymes relative to the WT enzyme was magnified in the "hotspot" sequence context. If the corresponding mutations in hMYH cause similar sensitivity to sequence context, this effect may contribute to the specific targeting of the APC gene. The lack of complementation of the hMYH variants for MutY, and the reduced activity of the Y82C and G253D E.coli enzymes, provide additional circumstantial evidence that the somatic mutations in APC, and the occurrence of FAP in Family N, are due to a reduced ability of the Y165C and G382D hMYH enzymes to recognize and repair OG:A mismatches.     

Characterization of a mammalian homolog of the Escherichia coli MutY mismatch repair protein.

A protein homologous to the Escherichia coli MutY protein, referred to as MYH, has been identified in nuclear extracts of calf thymus and human HeLa cells. Western blot (immunoblot) analysis using polyclonal antibodies to the E. coli MutY protein detected a protein of 65 kDa in both extracts. Partial purification of MYH from calf thymus cells revealed a 65-kDa protein as well as a functional but apparently degraded form of 36 kDa, as determined by glycerol gradient centrifugation and immunoblotting with anti-MutY antibodies. Calf MYH is a DNA glycosylase that specifically removes mispaired adenines from A/G, A/7,8-dihydro-8-oxodeoxyguanine (8-oxoG or GO), and A/C mismatches (mismatches indicated by slashes). A nicking activity that is either associated with or copurified with MYH was also detected. Nicking was observed at the first phosphodiester bond 3' to the apurinic or apyrimidinic (AP) site generated by the glycosylase activity. The nicking activity on A/C mismatches was 30-fold lower and the activity on A/GO mismatches was twofold lower than that on A/G mismatches. No nicking activity was detected on substrates containing other selected mismatches or homoduplexes. Nicking activity on DNA containing A/G mismatches was inhibited in the presence of anti-MutY antibodies or upon treatment with potassium ferricyanide, which oxidizes iron-sulfur clusters. Gel shift analysis showed specific binding complex formation with A/G and A/GO substrates, but not with A/A, C.GO, and C.G substrates. Binding is sevenfold greater on A/GO substrates than on A/G substrates. The eukaryotic MYH may be involved in the major repair of both replication errors and oxidative damage to DNA, the same functions as those of the E. coli MutY protein.     

Human MutY homolog, a DNA glycosylase involved in base excision repair, physically and functionally interacts with mismatch repair proteins human MutS homolog 2/human MutS homolog 6.

Adenines mismatched with guanines or 7,8-dihydro-8-oxo-deoxyguanines that arise through DNA replication errors can be repaired by either base excision repair or mismatch repair. The human MutY homolog (hMYH), a DNA glycosylase, removes adenines from these mismatches. Human MutS homologs, hMSH2/hMSH6 (hMutSalpha), bind to the mismatches and initiate the repair on the daughter DNA strands. Human MYH is physically associated with hMSH2/hMSH6 via the hMSH6 subunit. The interaction of hMutSalpha and hMYH is not observed in several mismatch repair-defective cell lines. The hMutSalpha binding site is mapped to amino acid residues 232-254 of hMYH, a region conserved in the MutY family. Moreover, the binding and glycosylase activities of hMYH with an A/7,8-dihydro-8-oxo-deoxyguanine mismatch are enhanced by hMutSalpha. These results suggest that protein-protein interactions may be a means by which hMYH repair and mismatch repair cooperate in reducing replicative errors caused by oxidized bases.     

An Escherichia coli MutY mutant without the six-helix barrel domain is a dimer in solution and assembles cooperatively into multisubunit complexes with DNA

Escherichia coli MutY is an adenine and weak guanine DNA glycosylase involved in reducing the mutagenic effects of 7,8-dihydro-8-oxoguanine (GO). MutY contains three structural domains: an iron-sulfur module, a six-helix barrel module with the helix-hairpin-helix motif, and a C-terminal domain. Here, we demonstrate that the mutant MutY(Delta26-134), which lacks the six-helix barrel domain, cannot complement the mutator phenotype of a mutY mutant in vivo. However, the mutant can still bind DNA and has weak catalytic activity at high enzyme concentrations. The mutant is a dimer in solution and assembled into two and multiple (up to five) complexes with 20- and 44-bp DNA fragments, respectively, in a concentration-dependent manner. Higher order complexes with DNA substrates containing A/GO mismatches were formed at lower protein concentrations than with the A/G mismatch and homoduplex DNA. Measurement of equilibrium binding using fluorescence anisotropy showed that the mutant protein retains some specificity for A/GO-containing DNA substrates and that the binding event is highly cooperative. This is consistent with the MutY structure determined, which indicates that GO specificity is contributed by both the six-helix barrel and C-terminal domains. The nonspecific binding of MutY(Delta26-134) to DNA suggests a model in which the specific binding of mismatched DNA by MutY involves sequential interactions, in which one MutY molecule scans the DNA and enhances binding of another MutY molecule to the A/GO mismatch.     

The active site of the Escherichia coli MutY DNA adenine glycosylase.

Escherichia coli MutY is an adenine DNA glycosylase active on DNA substrates containing A/G, A/C, or A/8-oxoG mismatches. Although MutY can form a covalent intermediate with its DNA substrates, its possession of 3' apurinic lyase activity is controversial. To study the reaction mechanism of MutY, the conserved Asp-138 was mutated to Asn and the reactivity of this mutant MutY protein determined. The glycosylase activity was completely abolished in the D138N MutY mutant. The D138N mutant and wild-type MutY protein also possessed different DNA binding activities with various mismatches. Several lysine residues were identified in the proximity of the active site by analyzing the imino-covalent MutY-DNA intermediate. Mutation of Lys-157 and Lys-158 both individually and combined, had no effect on MutY activities but the K142A mutant protein was unable to form Schiff base intermediates with DNA substrates. However, the MutY K142A mutant could still bind DNA substrates and had adenine glycosylase activity. Surprisingly, the K142A mutant MutY, but not the wild-type enzyme, could promote a beta/delta-elimination on apurinic DNA. Our results suggest that Asp-138 acts as a general base to deprotonate either the epsilon-amine group of Lys-142 or to activate a water molecule and the resulting apurinic DNA then reacts with Lys-142 to form the Schiff base intermediate with DNA. With the K142A mutant, Asp-138 activates a water molecule to attack the C1' of the adenosine; the resulting apurinic DNA is cleaved through beta/delta-elimination without Schiff base formation.     

Molecular cloning and functional analysis of the MutY homolog of Deinococcus radiodurans

The mutY homolog gene (mutY(Dr)) from Deinococcus radiodurans encodes a 39.4-kDa protein consisting of 363 amino acids that displays 35% identity to the Escherichia coli MutY (MutY(Ec)) protein. Expressed MutY(Dr) is able to complement E. coli mutY mutants but not mutM mutants to reduce the mutation frequency. The glycosylase and binding activities of MutY(Dr) with an A/G-containing substrate are more sensitive to high salt and EDTA concentrations than the activities with an A/7,8-dihydro-8-oxoguanine (GO)-containing substrate are. Like the MutY(Ec) protein, purified recombinant MutY(Dr) expressed in E. coli has adenine glycosylase activity with A/G, A/C, and A/GO mismatches and weak guanine glycosylase activity with a G/GO mismatch. However, MutY(Dr) exhibits limited apurinic/apyrimidinic lyase activity and can form only weak covalent protein-DNA complexes in the presence of sodium borohydride. This may be due to an arginine residue that is present in MutY(Dr) at the position corresponding to the position of MutY(Ec) Lys142, which forms the Schiff base with DNA. The kinetic parameters of MutY(Dr) are similar to those of MutY(Ec). Although MutY(Dr) has similar substrate specificity and a binding preference for an A/GO mismatch over an A/G mismatch, as MutY(Ec) does, the binding affinities for both mismatches are slightly lower for MutY(Dr) than for MutY(Ec). Thus, MutY(Dr) can protect the cell from GO mutational effects caused by ionizing radiation and oxidative stress.     

Repair of specific base pair mismatches formed during meiotic recombination in the yeast Saccharomyces cerevisiae.

Heteroduplexes formed between DNA strands derived from different homologous chromosomes are an intermediate in meiotic crossing over in the yeast Saccharomyces cerevisiae and other eucaryotes. A heteroduplex formed between wild-type and mutant genes will contain a base pair mismatch; failure to repair this mismatch will lead to postmeiotic segregation (PMS). By analyzing the frequency of PMS for various mutant alleles in the yeast HIS4 gene, we showed that C/C mismatches were inefficiently repaired relative to all other point mismatches. These other mismatches (G/G, G/A, T/T, A/A, T/C, C/A, A/A, and T/G) were repaired with approximately the same efficiency. We found that in spores with unrepaired mismatches in heteroduplexes, the nontranscribed strand of the HIS4 gene was more frequently donated than the transcribed strand. In addition, the direction of repair for certain mismatches was nonrandom.     

Novel non-isotopic detection of MutY enzyme-recognized mismatches in DNA via ultrasensitive detection of aldehydes.

A highly sensitive method to detect traces of aldehyde-containing apurinic/apyrimidinic (AP) sites in nucleic acids has been developed. Based on this method, a novel approach to detect DNA base mismatches recognized by the mismatch repair glycosylase MutY is demonstrated. Open chain aldehydes generated in nucleic acids due to spontaneous depurination, DNA damage or base excision of mismatched adenine by MutY are covalently trapped by a new linker molecule [fluorescent aldehyde-reactive probe (FARP), a fluorescein-conjugated hydroxylamine derivative]. DNA containing AP sites is FARP-trapped, biotinylated and immobilized onto neutravidin-coated microplates. The number of FARP-trapped aldehydes is then determined via chemiluminescence using a cooled ICCD camera. AP sites induced in plasmid or genomic calf thymus DNA via mild depurination or by simple incubation at physiological conditions (pH 7, 37 degreesC) presented a linear increase in chemiluminescence signal with time. The procedure developed, from a starting DNA material of approximately 100 ng, allows detection of attomole level (10(-18) mol) AP sites, or 1 AP site/2 x 10(7) bases, and extends by 1-2 orders of magnitude the current limit in AP site detection. In order to detect MutY-recognized mismatches, nucleic acids are first treated with 5 mM hydroxylamine to remove traces of spontaneous aldehydes. Following MutY treatment and FARP-labeling, oligonucleotides engineered to have a centrally located A/G mismatch demonstrate a strong chemiluminescence signal. Similarly, single-stranded M13 DNA that forms mismatches via self-complementation (average of 3 mismatches over 7429 bases) and treated with MutY yields a signal approximately 100-fold above background. No signal was detected when DNA without mismatches was used. The current development allows sensitive, non-isotopic, high throughput screening of diverse nucleic acids for AP sites and mismatches in a microplate-based format.     

A DNA repair process in Escherichia coli corrects U:G and T:G mismatches to C:G at sites of cytosine methylation

Escherichia coli contains a base mismatch correction system called VSP repair that is known to correct T:G mismatches to C:G when they occur in certain sequence contexts. The preferred sequence context for this process is the site for methylation by the E. coli DNA cytosine methylase (Dcm). For this reason, VSP repair is thought to counteract potential mutagenic effects of deamination of 5-methylcytosine to thymine. We have developed a genetic reversion assay that quantitates the frequency of C to T mutations at Dcm sites and the removal of such mutations by DNA repair processes. Using this assay, we have studied the repair of U: G mismatches in DNA to C: G and have found that VSP repair is capable of correcting these mismatches. Although VSP repair substantially affects the reversion frequency, it may not be as efficient at correcting U: G mismatches as the uracil DNA glycosylase-mediated repair process.     

A DNA repair process in Escherichia coli corrects U:G and T:G mismatches to C:G at sites of cytosine methylation

Escherichia coli contains a base mismatch correction system called VSP repair that is known to correct T:G mismatches to C:G when they occur in certain sequence contexts. The preferred sequence context for this process is the site for methylation by the E. coli DNA cytosine methylase (Dcm). For this reason, VSP repair is thought to counteract potential mutagenic effects of deamination of 5-methylcytosine to thymine. We have developed a genetic reversion assay that quantitates the frequency of C to T mutations at Dcm sites and the removal of such mutations by DNA repair processes. Using this assay, we have studied the repair of U: G mismatches in DNA to C: G and have found that VSP repair is capable of correcting these mismatches. Although VSP repair substantially affects the reversion frequency, it may not be as efficient at correcting U: G mismatches as the uracil DNA glycosylase-mediated repair process.     

Meiotic Mismatch Repair Quantified on the Basis of Segregation Patterns in Schizosaccharomyces Pombe

Hybrid DNA with mismatched base pairs is a central intermediate of meiotic recombination. Mismatch repair leads either to restoration or conversion, while failure of repair results in post-meiotic segregation (PMS). The behavior of three G to C transversions in one-factor crosses with the wild-type alleles is studied in Schizosaccharomyces pombe. They lead to C/C and G/G mismatches and are compared with closely linked mutations yielding other mismatches. A method is presented for the detection of PMS in random spores. The procedure yields accurate PMS frequencies as shown by comparison with tetrad data. A scheme is presented for the calculation of the frequency of hybrid DNA formation and the efficiency of mismatch repair. The efficiency of C/C repair in S. pombe is calculated to be about 70%. Other mismatches are repaired with close to 100% efficiency. These results are compared with data published on mutations in Saccharomyces cerevisiae and Ascobolus immersus. This study forms the basis for the detailed analysis of the marker effects caused by G to C transversions in two-factor crosses.     

The C-terminal domain of MutY glycosylase determines the 7,8-dihydro-8-oxo-guanine specificity and is crucial for mutation avoidance

Escherichia coli MutY is an adenine DNA glycosylase active on DNA substrates containing A/G, A/8-oxoG, or A/C mismatches and also has a weak guanine glycosylase activity on G/8-oxoG-containing DNA. The N-terminal domain of MutY, residues 1-226, has been shown to retain catalytic activity. Substrate binding, glycosylase, and Schiff base intermediate formation activities of the truncated and intact MutY were compared. MutY has high binding affinity with 8-oxoG when mispaired with A, G, T, C, or inosine. The truncated protein has more than 18-fold lower affinities for binding various 8-oxoG-containing mismatches when compared with intact MutY. MutY catalytic activity toward A/8-oxoG-containing DNA is much faster than that on A/G-containing DNA whereas deletion of the C-terminal domain reduces its catalytic preference for A/8-oxoG-DNA over A/G-DNA. MutY exerts more inhibition on the catalytic activity of MutM (Fpg) protein than does truncated MutY. The tight binding of MutY with GO mispaired with T, G, and apurinic/apyrimidinic sites may be involved in the regulation of MutM activity. An E. coli mutY strain that produces an N-terminal 249-residue truncated MutY confers a mutator phenotype. These findings strongly suggest that the C-terminal domain of MutY determines the 8-oxoG specificity and is crucial for mutation avoidance by oxidative damage.     

Unnatural substrates reveal the importance of 8-oxoguanine for in vivo mismatch repair by MutY

Escherichia coli MutY has an important role in preventing mutations associated with the oxidative lesion 7,8-dihydro-8-oxo-2'-deoxyguanosine (OG) in DNA by excising adenines from OG.A mismatches as the first step of base excision repair. To determine the importance of specific steps in the base pair recognition and base removal process of MutY, we have evaluated the effects of modifications of the OG.A substrate on the kinetics of base removal, mismatch affinity and repair to G-C in an E. coli-based assay. Notably, adenine modification was tolerated in the cellular assay, whereas modification of OG resulted in minimal cellular repair. High affinity for the mismatch and efficient base removal required the presence of OG. Taken together, these results suggest that the presence of OG is a critical feature that is necessary for MutY to locate OG.A mismatches and select the appropriate adenines for excision to initiate repair in vivo before replication.     

Identification of proteins of Escherichia coli and Saccharomyces cerevisiae that specifically bind to C/C mismatches in DNA

The pathways leading to G:C→C:G transversions and their repair mechanisms remain uncertain. C/C and G/G mismatches arising during DNA replication are a potential source of G:C→C:G transversions. The Escherichia coli mutHLS mismatch repair pathway efficiently corrects G/G mismatches, whereas C/C mismatches are a poor substrate. Escherichia coli must have a more specific repair pathway to correct C/C mismatches. In this study, we performed gel-shift assays to identify C/C mismatch-binding proteins in cell extracts of E.coli. By testing heteroduplex DNA (34mers) containing C/C mismatches, two specific band shifts were generated in the gels. The band shifts were due to mismatch-specific binding of proteins present in the extracts. Cell extracts of a mutant strain defective in MutM protein did not produce a low-mobility complex. Purified MutM protein bound efficiently to the C/C mismatch-containing heteroduplex to produce the low-mobility complex. The second protein, which produced a high-mobility complex with the C/C mismatches, was purified to homogeneity, and the amino acid sequence revealed that this protein was the FabA protein of E.coli. The high-mobility complex was not formed in cell extracts of a fabA mutant. From these results it is possible that MutM and FabA proteins are components of repair pathways for C/C mismatches in E.coli. Furthermore, we found that Saccharomyces cerevisiae OGG1 protein, a functional homolog of E.coli MutM protein, could specifically bind to the C/C mismatches in DNA.     

DNA-substrate sequence specificity of human G:T mismatch repair activity.

G:T mispairs in DNA originate spontaneously via deamination of 5-methylcytosine. Such mispairs are restored to normal G:C pairs by both E. coli K strains and human cells. In this study we have analyzed the repair by human cell extracts of G:T mismatches in various DNA contexts. We performed two sets of experiments. In the first, repair was sequence specific in that G:T mispairs at CpG sites at four different CpG sites were repaired, but a G:T mismatch at a GpG site was not. Cytosine hemimethylation did not block repair of a substrate containing a CpG/GpT mismatch. In the second set of experiments, substrates with a G:T mismatch at a fixed position were constructed with an A, T, G, or C 5' to the mismatched G, and alterations in the complementary strand to allow otherwise perfect Watson-Crick pairing. All were incised just 5' to the mismatched T and competed for repair incision with a G:T substrate in which a C was 5' to the mismatched G. Thus human G:T mismatch activity shows sequence specificity, incising G:T mismatched pairs at some DNA sites, but not at others. At an incisable site, however, incision is little influenced by the base 5' to the mismatched G.     

Defective human MutY phosphorylation exists in colorectal cancer cell lines with wild-type MutY alleles

Oxidative DNA damage can generate a variety of cytotoxic DNA lesions such as 8-oxoguanine (8-oxoG), which is one of the most mutagenic bases formed from oxidation of genomic DNA because 8-oxoG can readily mispair with either cytosine or adenine. If unrepaired, further replication of A.8-oxoG mispairs results in C:G to A:T transversions, a form of genomic instability. We reported previously that repair of A.8-oxoG mispairs was defective and that 8-oxoG levels were elevated in several microsatellite stable human colorectal cancer cell lines lacking MutY mutations (human MutY homolog gene, hmyh, MYH MutY homolog protein). In this report, we provide biochemical evidence that the defective repair of A.8-oxoG may be due, at least in part, to defective phosphorylation of the MutY protein in these cell lines. In MutY-defective cell extracts, but not extracts with functional MutY, A.8-oxoG repair was increased by incubation with protein kinases A and C (PKA and PKC) and caesin kinase II. Treatment of these defective cells, but not cells with functional MutY, with phorbol-12-myristate-13-acetate also increased the cellular A.8-oxoG repair activity and decreased the elevated 8-oxoG levels. We show that MutY is serine-phosphorylated in vitro by the action of PKC and in the MutY-defective cells by phorbol-12-myristate-13-acetate but that MutY is already phosphorylated at baseline in proficient cell lines. Finally, using antibody-isolated MutY protein, we show that MutY can be directly phosphorylated by PKC that directly increases the level of MutY catalyzed A.8-oxoG repair.     

Repair of a Mismatch Is Influenced by the Base Composition of the Surrounding Nucleotide Sequence

Heteroduplexes with single base pair mismatches of known sequence were prepared by annealing separated strands of bacteriophage lambda DNA and used to transfect Escherichia coli. A series of transition (G:T and A:C) and transversion (G:A and C:T) mismatches located throughout most of the bacteriophage lambda cI gene has been examined. The results suggest that the transition mismatches are generally better repaired than the transversion mismatches and that, at least for the transversion mismatches studied, repair efficiency increases with increasing G:C content in the neighboring nucleotide sequence. This specificity of the E. coli mismatch repair system can account, in part, for the similar frequencies of base substitution mutations throughout the E. coli genome.     

Heteroduplex DNA correction in Saccharomyces cerevisiae is mismatch specific and requires functional PMS genes.

In vitro-constructed heteroduplex DNAs with defined mismatches were corrected in Saccharomyces cerevisiae cells with efficiencies that were dependent on the mismatch. Single-nucleotide loops were repaired very efficiently; the base/base mismatches G/T, A/C, G/G, A/G, G/A, A/A, T/T, T/C, and C/T were repaired with a high to intermediate efficiency. The mismatch C/C and a 38-nucleotide loop were corrected with low efficiency. This substrate specificity pattern resembles that found in Escherichia coli and Streptococcus pneumoniae, suggesting an evolutionary relationship of DNA mismatch repair in pro- and eucaryotes. Repair of the listed mismatches was severely impaired in the putative S. cerevisiae DNA mismatch repair mutants pms1 and pms2. Low-efficiency repair also characterized pms3 strains, except that correction of single-nucleotide loops occurred with an efficiency close to that of PMS wild-type strains. A close correlation was found between the repair efficiencies determined in this study and the observed postmeiotic segregation frequencies of alleles with known DNA sequence. This suggests an involvement of DNA mismatch repair in recombination and gene conversion in S. cerevisiae.