Contribution of Msh2 and Msh6 subunits to the asymmetric ATPase and DNA mismatch binding activities of Saccharomyces cerevisiae Msh2-Msh6 mismatch repair protein

Previous analyses of both Thermus aquaticus MutS homodimer and Saccharomyces cerevisiae Msh2-Msh6 heterodimer have revealed that the subunits in these protein complexes bind and hydrolyze ATP asymmetrically, emulating their asymmetric DNA binding properties. In the MutS homodimer, one subunit (S1) binds ATP with high affinity and hydrolyzes it rapidly, while the other subunit (S2) binds ATP with lower affinity and hydrolyzes it at an apparently slower rate. Interaction of MutS with mismatched DNA results in suppression of ATP hydrolysis at S1-but which of these subunits, S1 or S2, makes specific contact with the mismatch (e.g., base stacking by a conserved phenylalanine residue) remains unknown. In order to answer this question and to clarify the links between the DNA binding and ATPase activities of each subunit in the dimer, we made mutations in the ATPase sites of Msh2 and Msh6 and assessed their impact on the activity of the Msh2-Msh6 heterodimer (in Msh2-Msh6, only Msh6 makes base specific contact with the mismatch). The key findings are: (a) Msh6 hydrolyzes ATP rapidly, and thus resembles the S1 subunit of the MutS homodimer, (b) Msh2 hydrolyzes ATP at a slower rate, and thus resembles the S2 subunit of MutS, (c) though itself an apparently weak ATPase, Msh2 has a strong influence on the ATPase activity of Msh6, (d) Msh6 binding to mismatched DNA results in suppression of rapid ATP hydrolysis, revealing a "cis" linkage between its mismatch recognition and ATPase activities, (e) the resultant Msh2-Msh6 complex, with both subunits in the ATP-bound state, exhibits altered interactions with the mismatch.     

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.     

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. Received: 15 November 1998 / Accepted: 4 February 1999     

The alternating ATPase domains of MutS control DNA mismatch repair

DNA mismatch repair is an essential safeguard of genomic integrity by removing base mispairings that may arise from DNA polymerase errors or from homologous recombination between DNA strands. In Escherichia coli, the MutS enzyme recognizes mismatches and initiates repair. MutS has an intrinsic ATPase activity crucial for its function, but which is poorly understood. We show here that within the MutS homodimer, the two chemically identical ATPase sites have different affinities for ADP, and the two sites alternate in ATP hydrolysis. A single residue, Arg697, located at the interface of the two ATPase domains, controls the asymmetry. When mutated, the asymmetry is lost and mismatch repair in vivo is impaired. We propose that asymmetry of the ATPase domains is an essential feature of mismatch repair that controls the timing of the different steps in the repair cascade.     

Bi-directional routing of DNA mismatch repair protein human exonuclease 1 to replication foci and DNA double strand breaks

Human exonuclease 1 (hEXO1) is implicated in DNA metabolism, including replication, recombination and repair, substantiated by its interactions with PCNA, DNA helicases BLM and WRN, and several DNA mismatch repair (MMR) proteins. We investigated the sub-nuclear localization of hEXO1 during S-phase progression and in response to laser-induced DNA double strand breaks (DSBs). We show that hEXO1 and PCNA co-localize in replication foci. This apparent interaction is sustained throughout S-phase. We also demonstrate that hEXO1 is rapidly recruited to DNA DSBs. We have identified a PCNA interacting protein (PIP-box) region on hEXO1 located in its COOH-terminal ((788)QIKLNELW(795)). This motif is essential for PCNA binding and co-localization during S-phase. Recruitment of hEXO1 to DNA DSB sites is dependent on the MMR protein hMLH1. We show that two distinct hMLH1 interaction regions of hEXO1 (residues 390-490 and 787-846) are required to direct the protein to the DNA damage site. Our results reveal that protein domains in hEXO1 in conjunction with specific protein interactions control bi-directional routing of hEXO1 between on-going DNA replication and repair processes in living cells.     

Evidence for involvement of HMGB1 protein in human DNA mismatch repair

Defects in human DNA mismatch repair predispose to cancer, but many components of the pathway have not been identified. We report here the identification and characterization of a novel component required for mismatch repair in human cells. A 30-kDa protein was purified to homogeneity by virtue of its ability to complement a depleted HeLa extract in repair of mismatched heteroduplexes. The complementing activity was identified as HMGB1 (the high mobility group box 1 protein), a non-histone chromatin protein that facilitates protein-protein interactions and recognizes DNA damage. Evidence is also presented that HMGB1 physically interacts with MutSalpha and is required at a step prior to the excision of mispaired nucleotide in mismatch repair.     

Interaction of nick-directed DNA mismatch repair and loop repair in human cells

In human cells, large DNA loop heterologies are repaired through a nick-directed pathway independent of mismatch repair. However, a 3'-nick generated by bacteriophage fd gene II protein heterology is not capable of stimulating loop repair. To evaluate the possibility that a mismatch near a loop could induce both repair types in human cell extracts, we constructed and tested a set of DNA heteroduplexes, each of which contains a combination of mismatches and loops. We have demonstrated that a strand break generated by restriction endonucleases 3' to a large loop is capable of provoking and directing loop repair. The repair of 3'-heteroduplexes in human cell extracts is very similar to that of 5'-heteroduplex repair, being strand-specific and highly biased to the nicked strand. This observation suggests that the loop repair pathway possesses bidirectional repair capability similar to that of the bacterial loop repair system. We also found that a nick 5' to a coincident mismatch and loop can apparently stimulate the repair of both. In contrast, 3'-nick-directed repair of a G-G mismatch was reduced when in the vicinity of a loop (33 or 46 bp between two sites). Increasing the distance separating the G-G mismatch and loop by 325 bp restored the efficiency of repair to the level of a single base-base mismatch. This observation suggests interference between 3'-nick-directed large loop repair and conventional mismatch repair systems when a mispair is near a loop. We propose a model in which DNA repair systems avoid simultaneous repair at adjacent sites to avoid the creation of double-stranded DNA breaks.     

Cadmium inhibits human DNA mismatch repair in vivo

The heavy metal cadmium (Cd) is a human carcinogen that inhibits DNA repair activities. We show that DNA mismatch repair (MMR)-mediated cell cycle arrest after alkylation damage is suppressed by exposure to Cd and that this effect is reversed by preincubation with excess of zinc (Zn). We show that Cd-mediated inactivation of MMR activity is not caused by disruption of complex formation between the MMR proteins hEXO1-hMutS alpha and hEXO1-hMutL alpha nor does Cd inhibit 5'-exonuclease activity of hEXO1 in vitro. Thus, our studies show that exposure of human cells to Cd suppresses MMR activity, a repair activity known to play an important role in colon cancer and that this effect can be reversed by Zn treatment.     

Nuclear localization of human DNA mismatch repair protein exonuclease 1 (hEXO1)

Human exonuclease 1 (hEXO1) is implicated in DNA mismatch repair (MMR) and mutations in hEXO1 may be associated with hereditary nonpolyposis colorectal cancer (HNPCC). Since the subcellular localization of MMR proteins is essential for proper MMR function, we characterized possible nuclear localization signals (NLSs) in hEXO1. Using fluorescent fusion proteins, we show that the sequence ⁴¹⁸KRPR⁴²¹, which exhibit strong homology to other monopartite NLS sequences, is responsible for correct nuclear localization of hEXO1. This NLS sequence is located in a region that is also required for hEXO1 interaction with hMLH1 and we show that defective nuclear localization of hEXO1 mutant proteins could be rescued by hMLH1 or hMSH2. Both hEXO1 and hMLH1 form complexes with the nuclear import factors importin β/α1,3,7 whereas hMSH2 specifically recognizes importin β/α3. Taken together, we infer that hEXO1, hMLH1 and hMSH2 form complexes and are imported to the nucleus together, and that redundant NLS import signals in the proteins may safeguard nuclear import and thereby MMR activity.     

DNA mismatch repair and cancer

Five human DNA mismatch repair genes have been identified that, when mutated, cause susceptibility to hereditary nonpolyposis colorectal cancer (HNPCC). Mutational inactivation of both copies of a DNA mismatch repair gene results in a profound repair defect and progressive accumulation of mutations throughout the genome. Some of the mutations confer selective advantage on the cells, giving rise to cancer. Recent discoveries suggest that apart from postreplication repair, DNA mismatch repair proteins have several other functions that are highly relevant to carcinogenesis. These include DNA damage surveillance, prevention of recombination between nonidentical sequences and participation in meiotic processes (chromosome pairing). A brief overview of these different features of the human DNA mismatch repair system will be provided, with the emphasis in their implications in cancer development.     

Oxidative stress inactivates the human DNA mismatch repair system

In the human DNA mismatch repair(MMR) system, hMSH2 forms the hMutS and hMutS complexes withhMSH6 and hMSH3, respectively, whereas hMLH1 and hPMS2 form thehMutL heterodimer. These complexes, together with other componentsin the MMR system, correct single-base mismatches and smallinsertion/deletion loops that occur during DNA replication.Microsatellite instability (MSI) occurs when the loops in DNAmicrosatellites are not corrected because of a malfunctioning MMRsystem. Low-frequency MSI (MSI-L) is seen in some chronicallyinflamed tissues in the absence of genetic inactivation of the MMRsystem. We hypothesize that oxidative stress associated with chronicinflammation might damage protein components of the MMR system, leadingto its functional inactivation. In this study, we demonstrate thatnoncytotoxic levels of H₂O₂ inactivate bothsingle-base mismatch and loop repair activities of the MMR system in adose-dependent fashion. On the basis of in vitro complementation assaysusing recombinant MMR proteins, we show that this inactivation is mostlikely due to oxidative damage to hMutS, hMutS, and hMutLprotein complexes. We speculate that inactivation of the MMR functionin response to oxidative stress may be responsible for the MSI-L seenin nonneoplastic and cancer tissues associated with chronic inflammation.

     

Contribution of the mismatch DNA repair system to the generation of stationary-phase-induced mutants of Bacillus subtilis

A reversion assay system previously implemented to demonstrate the existence of adaptive or stationary-phase-induced mutagenesis in Bacillus subtilis was utilized in this report to study the influence of the mismatch DNA repair (MMR) system on this type of mutagenesis. Results revealed that a strain deficient in MutSL showed a significant propensity to generate increased numbers of stationary-phase-induced revertants. These results suggest that absence or depression of MMR is an important factor in the mutagenesis of nongrowing B. subtilis cells because of the role of MMR in repairing DNA damage. In agreement with this suggestion, a significant decrease in the number of adaptive revertant colonies, for the three markers tested, occurred in B. subtilis cells which overexpressed a component of the MMR system. Interestingly, the single overexpression of mutS, but not of mutL, was sufficient to decrease the level of adaptive mutants in the reversion assay system of B. subtilis. The results presented in this work, as well as in our previous studies, appear to suggest that an MMR deficiency, putatively attributable to inactivation or saturation with DNA damage of MutS, may occur in a subset of B. subtilis cells that differentiate into the hypermutable state.     

DNA template requirements for human mismatch repair in vitro

The human mismatch repair pathway is competent to correct DNA mismatches in a strand-specific manner. At present, only nicks are known to support strand discrimination, although the DNA end within the active site of replication is often proposed to serve this role. We therefore tested the competence of DNA ends or gaps to direct mismatch correction. Eight G.T templates were constructed which contained a nick or gap of 4, 28, or approximately 200 nucleotides situated approximately 330 bp away in either orientation. A competition was established in which the mismatch repair machinery had to compete with gap-filling replication and ligation activities for access to the strand discontinuity. Gaps of 4 or 28 nucleotides were the most effective strand discrimination signals for mismatch repair, whereas double strand breaks did not direct repair to either strand. To define the minimal spatial requirements for access to either the strand signal or mismatch site, the nicked templates were linearized close to either site and assayed. As few as 14 bp beyond the nick supported mismatch excision, although repair synthesis failed using 5'-nicked templates. Finally, asymmetric G.T templates with a remote nick and a nearby DNA end were repaired efficiently.     

DNA mismatch repair detected in human cell extracts.

A system to study mismatch repair in vitro in HeLa cell extracts was developed. Preformed heteroduplex plasmid DNA containing two single base pair mismatches within the SupF gene of Escherichia coli was used as a substrate in a mismatch repair assay. Repair of one or both of the mismatches to the wild-type sequence was measured by transformation of a lac(Am) E. coli strain in which the presence of an active supF gene could be scored. The E. coli strain used was constructed to carry mutations in genes associated with mismatch repair and recombination (mutH, mutU, and recA) so that the processing of the heteroduplex DNA by the bacterium was minimal. Extract reactions were carried out by the incubation of the heteroduplex plasmid DNA in the HeLa cell extracts to which ATP, creatine phosphate, creatine kinase, deoxynucleotides, and a magnesium-containing buffer were added. Under these conditions about 1% of the mismatches were repaired. In the absence of added energy sources or deoxynucleotides, the activity in the extracts was significantly reduced. The addition of either aphidicolin or dideoxynucleotides reduced the mismatch repair activity, but only aphidicolin was effective in blocking DNA polymerization in the extracts. It is concluded that mismatch repair in these extracts is an energy-requiring process that is dependent on an adequate deoxynucleotide concentration. The results also indicate that the process is associated with some type of DNA polymerization, but the different effects of aphidicolin and dideoxynucleotides suggest that the mismatch repair activity in the extracts cannot simply be accounted for by random nick-translation activity alone.     

Truncation of the C-terminus of human MLH1 blocks intracellular stabilization of PMS2 and disrupts DNA mismatch repair

The human DNA mismatch repair (MMR) protein MLH1 has essential roles in the correction of replication errors and the activation of cell cycle checkpoints and cytotoxic responses to DNA damage that contribute to suppression of cancer risk. MLH1 functions as a heterodimer with the PMS2 protein, and steady state levels of PMS2 are very low in MLH1-deficient cells. Unique to MLH1 among MutL-homolog proteins, and conserved in identified eukaryotic MLH1 proteins, is the so-called C-terminal homology domain (CTH). The function of these C-terminal 20-30 amino acids is not known. We investigated the effect of a C-terminal truncation of human MLH1 (MLH1-L749X) on mammalian MMR by testing its activity in MLH1-deficient cells. We found the CTH to be essential for suppression of spontaneous mutation, activation of a cytotoxic response to 6-thioguanine, and maintenance of normal steady state levels of PMS2. Co-expression in doubly mutant Mlh1-/-; Pms2-/- fibroblasts showed that MLH1-L749X was unable to stabilize PMS2. Over-expression of MLH1-L749X did not reduce stabilization of PMS2 mediated by wild-type MLH1, indicating that truncation of the CTH reduces the ability to compete with wild-type MLH1 for interaction with PMS2. Lack of PMS2 stabilization also was observed with a previously reported pathogenic truncation (MLH1-Y750X), but not with two different point mutations in the CTH. Biochemical assays demonstrated that truncation of the CTH reduced the stability of heterodimers, although MLH1-L749X retained significant capacity for interaction with PMS2. Thus, the CTH of human MLH1 is necessary for error correction, checkpoint signaling, and for promoting interaction with, and the stability of, PMS2. Analysis of the CTH role in stabilizing PMS2 was facilitated by a novel intracellular assay for MLH1-PMS2 interaction. This assay should prove useful for identifying additional amino acids in MLH1 and PMS2 necessary for interaction in cells, and for determining the functional consequences of MLH1 mutations identified in human cancers.     

Recognition and repair of compound DNA lesions (base damage and mismatch) by human mismatch repair and excision repair systems.

Nucleotide excision repair and the long-patch mismatch repair systems correct abnormal DNA structures arising from DNA damage and replication errors, respectively. DNA synthesis past a damaged base (translesion replication) often causes misincorporation at the lesion site. In addition, mismatches are hot spots for DNA damage because of increased susceptibility of unpaired bases to chemical modification. We call such a DNA lesion, that is, a base damage superimposed on a mismatch, a compound lesion. To learn about the processing of compound lesions by human cells, synthetic compound lesions containing UV photoproducts or cisplatin 1,2-d(GpG) intrastrand cross-link and mismatch were tested for binding to the human mismatch recognition complex hMutS alpha and for excision by the human excision nuclease. No functional overlap between excision repair and mismatch repair was observed. The presence of a thymine dimer or a cisplatin diadduct in the context of a G-T mismatch reduced the affinity of hMutS alpha for the mismatch. In contrast, the damaged bases in these compound lesions were excised three- to fourfold faster than simple lesions by the human excision nuclease, regardless of the presence of hMutS alpha in the reaction. These results provide a new perspective on how excision repair, a cellular defense system for maintaining genomic integrity, can fix mutations under certain circumstances.     

DNA mismatch repair and Lynch syndrome

The evolutionary conserved mismatch repair proteins correct a wide range of DNA replication errors. Their importance as guardians of genetic integrity is reflected by the tremendous decrease of replication fidelity (two to three orders of magnitude) conferred by their loss. Germline mutations in mismatch repair genes, predominantly MSH2 and MLH1, have been found to underlie the Lynch syndrome (also called hereditary non-polyposis colorectal cancer, HNPCC), a hereditary predisposition for cancer. Lynch syndrome affects predominantly the colon and accounts for 2–5% of all colon cancer cases. During more than 30 years of biochemical, crystallographic and clinical research, deep insight has been achieved in the function of mismatch repair and the diseases that are associated with its loss. We review the biochemistry of mismatch repair and also introduce the clinical, diagnostic and genetic aspects of Lynch syndrome.