Interaction between the Msh2 and Msh6 Nucleotide-binding Sites in the Saccharomyces cerevisiae Msh2-Msh6 Complex

Indirect evidence has suggested that the Msh2-Msh6 mispair-binding complex undergoes conformational changes upon binding of ATP and mispairs, resulting in the formation of Msh2-Msh6 sliding clamps and licensing the formation of Msh2-Msh6-Mlh1-Pms1 ternary complexes. Here, we have studied eight mutant Msh2-Msh6 complexes with defective responses to nucleotide binding and/or mispair binding and used them to study the conformational changes required for sliding clamp formation and ternary complex assembly. ATP binding to the Msh6 nucleotide-binding site results in a conformational change that allows binding of ATP to the Msh2 nucleotide-binding site, although ATP binding to the two nucleotide-binding sites appears to be uncoupled in some mutant complexes. The formation of Msh2-Msh6-Mlh1-Pms1 ternary complexes requires ATP binding to only the Msh6 nucleotide-binding site, whereas the formation of Msh2-Msh6 sliding clamps requires ATP binding to both the Msh2 and Msh6 nucleotide-binding sites. In addition, the properties of the different mutant complexes suggest that distinct conformational states mediated by communication between the Msh2 and Msh6 nucleotide-binding sites are required for the formation of ternary complexes and sliding clamps.     

Saccharomyces cerevisiae Msh2-Msh3 acts in repair of base-base mispairs

DNA mismatch repair is thought to act through two subpathways involving the recognition of base-base and insertion/deletion mispairs by the Msh2-Msh6 heterodimer and the recognition of insertion/deletion mispairs by the Msh2-Msh3 heterodimer. Here, through genetic and biochemical approaches, we describe a previously unidentified role of the Msh2-Msh3 heterodimer in the recognition of base-base mispairs and the suppression of homology-mediated duplication and deletion mutations. Saccharomyces cerevisiae msh3 mutants did not show an increase in the rate of base substitution mutations by the CAN1 forward mutation assay compared to the rate for the wild type but did show an altered spectrum of base substitution mutations, including an increased accumulation of base pair changes from GC to CG and from AT to TA; msh3 mutants also accumulated homology-mediated duplication and deletion mutations. The mutation spectrum of mlh3 mutants paralleled that of msh3 mutants, suggesting that the Mlh1-Mlh3 heterodimer may also play a role in the repair of base-base mispairs and in the suppression of homology-mediated duplication and deletion mutations. Mispair binding analysis with purified Msh2-Msh3 and DNA substrates derived from CAN1 sequences found to be mutated in vivo demonstrated that Msh2-Msh3 exhibited robust binding to specific base-base mispairs that was consistent with functional mispair binding.     

Mispair-specific Recruitment of the Mlh1-Pms1 Complex Identifies Repair Substrates of the Saccharomyces cerevisiae Msh2-Msh3 Complex

DNA mismatch repair is initiated by either the Msh2-Msh6 or the Msh2-Msh3 mispair recognition heterodimer. Here we optimized the expression and purification of Saccharomyces cerevisiae Msh2-Msh3 and performed a comparative study of Msh2-Msh3 and Msh2-Msh6 for mispair binding, sliding clamp formation, and Mlh1-Pms1 recruitment. Msh2-Msh3 formed sliding clamps and recruited Mlh1-Pms1 on +1, +2, +3, and +4 insertion/deletions and CC, AA, and possibly GG mispairs, whereas Msh2-Msh6 formed mispair-dependent sliding clamps and recruited Mlh1-Pms1 on 7 of the 8 possible base:base mispairs, the +1 insertion/deletion mispair, and to a low level on the +2 but not the +3 or +4 insertion/deletion mispairs and not on the CC mispair. The mispair specificity of sliding clamp formation and Mlh1-Pms1 recruitment but not mispair binding alone correlated best with genetic data on the mispair specificity of Msh2-Msh3- and Msh2-Msh6-dependent mismatch repair in vivo. Analysis of an Msh2-Msh6/Msh3 chimeric protein and mutant Msh2-Msh3 complexes showed that the nucleotide binding domain and communicating regions but not the mispair binding domain of Msh2-Msh3 are responsible for the extremely rapid dissociation of Msh2-Msh3 sliding clamps from DNA relative to that seen for Msh2-Msh6, and that amino acid residues predicted to stabilize Msh2-Msh3 interactions with bent, strand-separated mispair-containing DNA are more critical for the recognition of small +1 insertion/deletions than larger +4 insertion/deletions.     

Mismatch recognition-coupled stabilization of Msh2-Msh6 in an ATP-bound state at the initiation of DNA repair

Mismatch repair proteins correct errors in DNA via an ATP-driven process. In eukaryotes, the Msh2-Msh6 complex recognizes base pair mismatches and small insertion/deletions in DNA and initiates repair. Both Msh2 and Msh6 proteins contain Walker ATP-binding motifs that are necessary for repair activity. To understand how these proteins couple ATP binding and hydrolysis to DNA binding/mismatch recognition, the ATPase activity of Saccharomyces cerevisiae Msh2-Msh6 was examined under pre-steady-state conditions. Acid-quench experiments revealed that in the absence of DNA, Msh2-Msh6 hydrolyzes ATP rapidly (burst rate = 3 s(-1) at 20 degrees C) and then undergoes a slow step in the pathway that limits catalytic turnover (k(cat) = 0.1 s(-1)). ATP is hydrolyzed similarly in the presence of fully matched duplex DNA; however, in the presence of a G:T mismatch or +T insertion-containing DNA, ATP hydrolysis is severely suppressed (rate = 0.1 s(-1)). Pulse-chase experiments revealed that Msh2-Msh6 binds ATP rapidly in the absence or in the presence of DNA (rate = 0.1 microM(-1) s(-1)), indicating that for the Msh2-Msh6.mismatched DNA complex, a step after ATP binding but before or at ATP hydrolysis is the rate-limiting step in the pathway. Thus, mismatch recognition is coupled to a dramatic increase in the residence time of ATP on Msh2-Msh6. This mismatch-induced, stable ATP-bound state of Msh2-Msh6 likely signals downstream events in the repair pathway.     

Inhibition of Msh6 ATPase activity by mispaired DNA induces a Msh2(ATP)-Msh6(ATP) state capable of hydrolysis-independent movement along DNA

The Msh2-Msh6 heterodimer plays a key role in the repair of mispaired bases in DNA. Critical to its role in mismatch repair is the ATPase activity that resides within each subunit. Here we show that both subunits can simultaneously bind ATP and identify the Msh6 subunit as containing the high-affinity ATP binding site and Msh2 as containing a high-affinity ADP binding site. Stable binding of ATP to Msh6 causes decreased affinity of Msh2 for ADP, and binding to mispaired DNA stabilized the binding of ATP to Msh6. Our results support a model in which mispair binding encourages a dual-occupancy state with ATP bound to Msh6 and Msh2; this state supports hydrolysis-independent sliding along DNA.     

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.     

Multiple factors insulate Msh2-Msh6 mismatch repair activity from defects in Msh2 domain I

DNA mismatch repair (MMR) is a highly conserved mutation avoidance mechanism that corrects DNA polymerase misincorporation errors. In initial steps in MMR, Msh2-Msh6 binds mispairs and small insertion/deletion loops, and Msh2-Msh3 binds larger insertion/deletion loops. The msh2Δ1 mutation, which deletes the conserved DNA-binding domain I of Msh2, does not dramatically affect Msh2-Msh6-dependent repair. In contrast, msh2Δ1 mutants show strong defects in Msh2-Msh3 functions. Interestingly, several mutations identified in patients with hereditary non-polyposis colorectal cancer map to domain I of Msh2; none have been found in MSH3. To understand the role of Msh2 domain I in MMR, we examined the consequences of combining the msh2Δ1 mutation with mutations in two distinct regions of MSH6 and those that increase cellular mutational load (pol3-01 and rad27). These experiments reveal msh2Δ1-specific phenotypes in Msh2-Msh6 repair, with significant effects on mutation rates. In vitro assays demonstrate that msh2Δ1-Msh6 DNA binding is less specific for DNA mismatches and produces an altered footprint on a mismatch DNA substrate. Together, these results provide evidence that, in vivo, multiple factors insulate MMR from defects in domain I of Msh2 and provide insights into how mutations in Msh2 domain I may cause hereditary non-polyposis colorectal cancer.     

Visualization of eukaryotic DNA mismatch repair reveals distinct recognition and repair intermediates

DNA mismatch repair (MMR) increases replication fidelity by eliminating mispaired bases resulting from replication errors. In Saccharomyces cerevisiae, mispairs are primarily detected by the Msh2-Msh6 complex and corrected following recruitment of the Mlh1-Pms1 complex. Here, we visualized functional fluorescent versions of Msh2-Msh6 and Mlh1-Pms1 in living cells. We found that the Msh2-Msh6 complex is an S phase component of replication centers independent of mispaired bases; this localized pool accounted for 10%-15% of MMR in wild-type cells but was essential for MMR in the absence of Exo1. Unexpectedly, Mlh1-Pms1 formed nuclear foci that, although dependent on Msh2-Msh6 for formation, rarely colocalized with Msh2-Msh6 replication-associated foci. Mlh1-Pms1 foci increased when the number of mispaired bases was increased; in contrast, Msh2-Msh6 foci were unaffected. These findings suggest the presence of replication machinery-coupled and -independent pathways for mispair recognition by Msh2-Msh6, which direct formation of superstoichiometric Mlh1-Pms1 foci that represent sites of active MMR.     

Cadmium inhibits the functions of eukaryotic MutS complexes

Exposure of yeast cells to low concentrations of cadmium results in elevated mutation rates due to loss of mismatch repair (MMR), and cadmium inhibits MMR activity in extracts of human cells. Here we show that cadmium inhibits both Msh2-Msh6- and Msh2-Msh3-dependent human MMR activity in vitro. This inhibition, which occurs at a step or steps preceding repair DNA synthesis, is observed for repair directed by either a 3' or a 5' nick. In an attempt to identify the protein target(s) of cadmium inhibition, we show that cadmium inhibition of MMR is not reversed by addition of zinc to the repair reaction, suggesting that the target is not a zinc metalloprotein. We then show that cadmium inhibits ATP hydrolysis by yeast Msh2-Msh6 but has no effect on ATPase hydrolysis by yeast Mlh1-Pms1. Steady state kinetic analysis with wild type Msh2-Msh6, and with heterodimers containing subunit-specific Glu to Ala replacements inferred to inactivate the ATPase activity of either Msh2 or Msh6, suggest that cadmium inhibits ATP hydrolysis by Msh6 but not Msh2. Cadmium also reduces DNA binding by Msh2-Msh6 and more so for mismatched than matched duplexes. These data indicate that eukaryotic Msh2-Msh3 and Msh2-Msh6 complexes are targets for inhibition of MMR by cadmium, a human lung carcinogen that is ubiquitous in the environment.     

Mlh2 Is an Accessory Factor for DNA Mismatch Repair in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, the essential mismatch repair (MMR) endonuclease Mlh1-Pms1 forms foci promoted by Msh2-Msh6 or Msh2-Msh3 in response to mispaired bases. Here we analyzed the Mlh1-Mlh2 complex, whose role in MMR has been unclear. Mlh1-Mlh2 formed foci that often colocalized with and had a longer lifetime than Mlh1-Pms1 foci. Mlh1-Mlh2 foci were similar to Mlh1-Pms1 foci: they required mispair recognition by Msh2-Msh6, increased in response to increased mispairs or downstream defects in MMR, and formed after induction of DNA damage by phleomycin but not double-stranded breaks by I-SceI. Mlh1-Mlh2 could be recruited to mispair-containing DNA in vitro by either Msh2-Msh6 or Msh2-Msh3. Deletion of MLH2 caused a synergistic increase in mutation rate in combination with deletion of MSH6 or reduced expression of Pms1. Phylogenetic analysis demonstrated that the S. cerevisiae Mlh2 protein and the mammalian PMS1 protein are homologs. These results support a hypothesis that Mlh1-Mlh2 is a non-essential accessory factor that acts to enhance the activity of Mlh1-Pms1.     

Evidence for sequential action of two ATPase active sites in yeast Msh2-Msh6

Bacterial MutS homodimers contain two ATPase active sites that have non-equivalent functions in DNA mismatch repair. The homologous Msh2-Msh6 complex in eukaryotes also has intrinsic ATPase activity that is essential for mismatch repair. Here, we investigate differences in the two putative ATPase active sites by examining the properties of heterodimers containing alanine substituted for an invariant glutamic acid in the active site of either Msh2, Msh6 or both. Mutation rates in wild type versus Glu-->Ala mutant haploid yeast strains indicate that both ATPase active sites are essential for mismatch repair activity in vivo. The properties of purified heterodimers suggest that the ATPase active site in Msh6 binds ATP with higher affinity and hydrolyzes ATP faster and with higher efficiency than does the ATPase active site in Msh2. This suggests sequential action of the two ATPase active sites, in which ATP binds to Msh6 first to trigger downstream events in mismatch repair.     

Functional Studies and Homology Modeling of Msh2-Msh3 Predict that Mispair Recognition Involves DNA Bending and Strand Separation

The Msh2-Msh3 heterodimer recognizes various DNA mispairs, including loops of DNA ranging from 1 to 14 nucleotides and some base-base mispairs. Homology modeling of the mispair-binding domain (MBD) of Msh3 using the related Msh6 MBD revealed that mismatch recognition must be different, even though the MBD folds must be similar. Model-based point mutation alleles of Saccharomyces cerevisiae msh3 designed to disrupt mispair recognition fell into two classes. One class caused defects in repair of both small and large insertion/deletion mispairs, whereas the second class caused defects only in the repair of small insertion/deletion mispairs; mutations of the first class also caused defects in the removal of nonhomologous tails present at the ends of double-strand breaks (DSBs) during DSB repair, whereas mutations of the second class did not cause defects in the removal of nonhomologous tails during DSB repair. Thus, recognition of small insertion/deletion mispairs by Msh3 appears to require a greater degree of interactions with the DNA conformations induced by small insertion/deletion mispairs than with those induced by large insertion/deletions that are intrinsically bent and strand separated. Mapping of the two classes of mutations onto the Msh3 MBD model appears to distinguish mispair recognition regions from DNA stabilization regions.The DNA mismatch repair (MMR) pathway recognizes and repairs mispaired and damaged bases in DNA, which primarily result from replication errors but which also result from recombination and chemical damage to DNA and DNA precursors (16, 22). Repairing mispairs improves the overall fidelity of DNA replication and is important for genome stability (24). Inherited defects in MMR are responsible for most cases of Lynch syndrome (hereditary nonpolyposis colorectal cancer [HNPCC]), and furthermore, the epigenetic silencing of one of the genes involved in MMR, MLH1, underlies most cases of sporadic MMR-defective cancer (19, 29).MMR is initiated by the recognition of base-base mismatches or insertion/deletion mispairs. In bacteria, the homodimeric MutS complex directly binds mispairs, bending the mispair-containing DNA by almost 60 degrees and shifting one of the mispaired bases, such as the thymidine base from G-T or +T mispairs, out of the DNA base stack (17). The mispaired base is stabilized by π stacking with a conserved phenylalanine (17, 26, 26a). DNA binding induces a functional asymmetry to the MutS complex; one subunit directly recognizes the mispair via a mispair-binding domain (MBD), whereas the MBD of the second subunit is primarily involved in nonspecific backbone interactions (17, 26a).In eukaryotes, mitotic MMR utilizes two heterodimeric complexes of MutS homologs: Msh2-Msh6 and Msh2-Msh3 (5, 16, 23, 41). In these asymmetric heterodimers, Msh6 and Msh3 directly recognize the mispair via their MBDs, whereas the Msh2 subunit appears to be functionally equivalent to the MutS subunit that nonspecifically binds the DNA backbone. In wild-type cells, the Msh2-Msh6 heterodimer is thought to primarily recognize and act in the repair of base-base mispairs and small 1- or 2-nucleotide insertion/deletions (12, 16, 20-24). The crystal structure of human Msh2-Msh6 revealed that mispair recognition by Msh6 shares many details with Escherichia coli MutS, including the π-stacking phenylalanine (17, 26a, 39). In contrast, in wild-type cells the Msh2-Msh3 heterodimer is thought to primarily recognize and act in the repair of insertions and deletions from 1 to 14 nucleotides in size (11, 20, 21, 27, 33, 37, 40), although we have previously shown that Msh2-Msh3 also recognizes some base-base mispairs with a preference for those that have weak hydrogen bonding (13). Msh2-Msh3 is also targeted to sites of DNA double-strand breaks (DSBs), potentially before a branched recombination intermediate is formed, where it acts in the processing of 3′ single-stranded tails (10, 28, 36).While no structural information for any Msh3 homolog is available, several lines of evidence suggest that mispairs are recognized by Msh2-Msh3 in a substantially different way than mispairs are recognized by MutS and Msh2-Msh6. First, Msh3 lacks the conserved π-stacking phenylalanine present in both MutS and Msh6, which is required for MMR by these proteins in vivo (9, 18). In contrast, mutagenesis of the Saccharomyces cerevisiae Msh3 residue located at the position equivalent to that of the phenylalanine conserved in MutS and Msh6 (K158, called K187 prior to the identification of the correct start codon [13]) caused only a modest MMR defect (18). Second, when other conserved residues and predicted DNA-backbone-contacting residues in S. cerevisiae Msh3 were mutated to alanine, only msh3-R247A (previously called msh3-R276A) caused a significant defect in the repair of 1-, 2-, and 4-nucleotide-long insertion/deletion mispairs (18).Despite these differences, the Msh3 MBD is likely related to the MBD of Msh6 and MutS. Replacement of the Msh6 MBD with the Msh3 MBD generated a functional chimera possessing Msh3 substrate specificity (32). Moreover, combining the msh3-K158A mutation with K160A gave rise to an msh3 mutant with an MMR defect greater than that for either single mutant alone (18). This double mutant caused a loss of specificity for mispaired DNA (18). Together these data indicate not only that mispair specificity is determined by the Msh3 MBD but also that the critical region of the Msh3 MBD mediating mispair recognition likely overlaps the same region as the MBDs of MutS and Msh6, even if the nature of the recognition is different. We have therefore used homology modeling and site-directed mutagenesis to gain insight into how Msh3 recognizes a diverse array of mispairs.     

(CAG)(n)-hairpin DNA binds to Msh2-Msh3 and changes properties of mismatch recognition

Cells have evolved sophisticated DNA repair systems to correct damaged DNA. However, the human DNA mismatch repair protein Msh2-Msh3 is involved in the process of trinucleotide (CNG) DNA expansion rather than repair. Using purified protein and synthetic DNA substrates, we show that Msh2-Msh3 binds to CAG-hairpin DNA, a prime candidate for an expansion intermediate. CAG-hairpin binding inhibits the ATPase activity of Msh2-Msh3 and alters both nucleotide (ADP and ATP) affinity and binding interfaces between protein and DNA. These changes in Msh2-Msh3 function depend on the presence of A.A mispaired bases in the stem of the hairpin and on the hairpin DNA structure per se. These studies identify critical functional defects in the Msh2-Msh3-CAG hairpin complex that could misdirect the DNA repair process.     

Engineered Disulfide-forming Amino Acid Substitutions Interfere with a Conformational Change in the Mismatch Recognition Complex Msh2-Msh6 Required for Mismatch Repair

ATP binding causes the mispair-bound Msh2-Msh6 mismatch recognition complex to slide along the DNA away from the mismatch, and ATP is required for the mispair-dependent interaction between Msh2-Msh6 and Mlh1-Pms1. It has been inferred from these observations that ATP induces conformational changes in Msh2-Msh6; however, the nature of these conformational changes and their requirement in mismatch repair are poorly understood. Here we show that ATP induces a conformational change within the C-terminal region of Msh6 that protects the trypsin cleavage site after Msh6 residue Arg¹¹²⁴. An engineered disulfide bond within this region prevented the ATP-driven conformational change and resulted in an Msh2-Msh6 complex that bound mispaired bases but could not form sliding clamps or bind Mlh1-Pms1. The engineered disulfide bond also reduced mismatch repair efficiency in vivo, indicating that this ATP-driven conformational change plays a role in mismatch repair.     

Saccharomyces cerevisiae Msh2p and Msh6p ATPase Activities Are Both Required during Mismatch Repair

In the Saccharomyces cerevisiae Msh2p-Msh6p complex, mutations that were predicted to disrupt ATP binding, ATP hydrolysis, or both activities in each subunit were created. Mutations in either subunit resulted in a mismatch repair defect, and overexpression of either mutant subunit in a wild-type strain resulted in a dominant negative phenotype. Msh2p-Msh6p complexes bearing one or both mutant subunits were analyzed for binding to DNA containing base pair mismatches. None of the mutant complexes displayed a significant defect in mismatch binding; however, unlike wild-type protein, all mutant combinations continued to display mismatch binding specificity in the presence of ATP and did not display ATP-dependent conformational changes as measured by limited trypsin protease digestion. Both wild-type complex and complexes defective in the Msh2p ATPase displayed ATPase activities that were modulated by mismatch and homoduplex DNA substrates. Complexes defective in the Msh6p ATPase, however, displayed weak ATPase activities that were unaffected by the presence of DNA substrate. The results from these studies suggest that the Msh2p and Msh6p subunits of the Msh2p-Msh6p complex play important and coordinated roles in postmismatch recognition steps that involve ATP hydrolysis. Furthermore, our data support a model whereby Msh6p uses its ATP binding or hydrolysis activity to coordinate mismatch binding with additional mismatch repair components.     

A dominant mitochondrial mutator phenotype of Saccharomyces cerevisiae conferred by msh1 alleles altered in the sequence encoding the ATP-binding domain

In order to improve our understanding of the role of the yeast MSH1 gene in error avoidance in mitochondrial DNA, two msh1 alleles were constructed, which encode proteins with amino acid substitutions in an ATP-binding domain that is highly conserved among MutS homologs. Here, we report that moderate overexpression of the msh1-R813W or msh1-G776D allele, in strains which also carry the wild-type MSH1 allele, slightly increases the frequency of mutations conferring resistance to erythromycin (E(r)) and elevates the frequency of alterations within a polyGT tract present in mitochondrial DNA (mtDNA). This result indicates that the mutant alleles confer a dominant mitochondrial mutator phenotype and strongly suggests that the ATP-binding domain plays a crucial role in the in vivo function of Msh1p. Interestingly, we have found that overexpression of wild-type MSH1 has opposite effects on the stability of polyGT vs. polyAT tracts present in mtDNA; excess of Msh1p slightly increases the stability of polyGT tracts, whereas the stability of polyAT tracts is dramatically decreased. We show that although overexpression of msh1-R813W or msh1-G776D also results in a marked overall increase in the frequency of alterations in polyAT tracts, the spectrum of alterations differs from that found in cells overexpressing MSH1; large deletions predominate in the latter case, while 2-bp deletions are generated in cells that overproduce the mutant msh1p. This result strongly suggests that the mutations in the ATP binding domain change the specificity of the protein with respect to the recognition of potentially mutagenic structures in mtDNA.     

The N terminus of Saccharomyces cerevisiae Msh6 is an unstructured tether to PCNA

The eukaryotic MutS homolog complexes, Msh2-Msh6 and Msh2-Msh3, recognize mismatched bases in DNA during mismatch repair (MMR). The eukaryote-specific N-terminal regions (NTRs) of Msh6 and Msh3 have not been characterized other than by demonstrating that they contain an N-terminal PCNA-interacting motif. Here we have demonstrated genetically that the NTR of Msh6 has an important role in MMR that is partially redundant with PCNA binding. Small-angle X-ray scattering (SAXS) was used to determine the solution structure of the complex of PCNA with Msh2-Msh6 and with the isolated Msh6 NTR, revealing that the Msh6 NTR is a natively disordered domain that forms an extended tether between Msh6 and PCNA. Moreover, computational analysis of PCNA-interacting motifs in the S. cerevisiae proteome indicated that flexible linkers are a common theme for PCNA-interacting proteins that may serve to localize these binding partners without tightly restraining them to the immediate vicinity of PCNA.     

Application of Stopped-flow Kinetics Methods to Investigate the Mechanism of Action of a DNA Repair Protein

Transient kinetic analysis is indispensable for understanding the workings of biological macromolecules, since this approach yields mechanistic information including active site concentrations and intrinsic rate constants that govern macromolecular function. In case of enzymes, for example, transient or pre-steady state measurements identify and characterize individual events in the reaction pathway, whereas steady state measurements only yield overall catalytic efficiency and specificity. Individual events such as protein-protein or protein-ligand interactions and rate-limiting conformational changes often occur in the millisecond timescale, and can be measured directly by stopped-flow and chemical-quench flow methods. Given an optical signal such as fluorescence, stopped-flow serves as a powerful and accessible tool for monitoring reaction progress from substrate binding to product release and catalytic turnover^1,2.Here, we report application of stopped-flow kinetics to probe the mechanism of action of Msh2-Msh6, a eukaryotic DNA repair protein that recognizes base-pair mismatches and insertion/deletion loops in DNA and signals mismatch repair (MMR)^3-5. In doing so, Msh2-Msh6 increases the accuracy of DNA replication by three orders of magnitude (error frequency decreases from ~10^-6 to10^-9 bases), and thus helps preserve genomic integrity. Not surprisingly, defective human Msh2-Msh6 function is associated with hereditary non-polyposis colon cancer and other sporadic cancers^6-8. In order to understand the mechanism of action of this critical DNA metabolic protein, we are probing the dynamics of Msh2-Msh6 interaction with mismatched DNA as well as the ATPase activity that fuels its actions in MMR. DNA binding is measured by rapidly mixing Msh2-Msh6 with DNA containing a 2-aminopurine (2-Ap) fluorophore adjacent to a G:T mismatch and monitoring the resulting increase in 2-aminopurine fluorescence in real time. DNA dissociation is measured by mixing pre-formed Msh2-Msh6 G:T(2-Ap) mismatch complex with unlabeled trap DNA and monitoring decrease in fluorescence over time⁹. Pre-steady state ATPase kinetics are measured by the change in fluorescence of 7-diethylamino-3-((((2-maleimidyl)ethyl)amino)carbonyl) coumarin)-labeled Phosphate Binding Protein (MDCC-PBP) on binding phosphate (Pi) released by Msh2-Msh6 following ATP hydrolysis^9,10.The data reveal rapid binding of Msh2-Msh6 to a G:T mismatch and formation of a long-lived Msh2-Msh6 G:T complex, which in turn results in suppression of ATP hydrolysis and stabilization of the protein in an ATP-bound form. The reaction kinetics provide clear support for the hypothesis that ATP-bound Msh2-Msh6 signals DNA repair on binding a mismatched base pair in the double helix.F. Noah Biro and Jie Zhai contributed to this paper equally.Download video file.^{(124M, mp4)}     

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.     

Asymmetric recognition of DNA local distortion. Structure-based functional studies of eukaryotic Msh2-Msh6

Crystal structures of bacterial MutS homodimers bound to mismatched DNA reveal asymmetric interactions of the two subunits with DNA. A phenylalanine and glutamate of one subunit make mismatched base-specific interactions, and residues of both subunits contact the DNA backbone surrounding the mismatched base, but asymmetrically. A number of amino acids in MutS that contact the DNA are conserved in the eukaryotic Msh2-Msh6 heterodimer. We report here that yeast strains with amino acids substituted for residues inferred to interact with the DNA backbone or mismatched base have elevated spontaneous mutation rates consistent with defective mismatch repair. Purified Msh2-Msh6 with substitutions in the conserved Phe(337) and Glu(339) in Msh6 thought to stack or hydrogen bond, respectively, with the mismatched base do have reduced DNA binding affinity but normal ATPase activity. Moreover, wild-type Msh2-Msh6 binds with lower affinity to mismatches with thymine replaced by difluorotoluene, which lacks the ability to hydrogen bond. The results suggest that yeast Msh2-Msh6 interacts asymmetrically with the DNA through base-specific stacking and hydrogen bonding interactions and backbone contacts. The importance of these contacts decreases with increasing distance from the mismatch, implying that interactions at and near the mismatch are important for binding in a kinked DNA conformation.