Assembly and molecular activities of the MutS tetramer

Analytical equilibrium ultracentrifugation indicates that Escherichia coli MutS exists as an equilibrating mixture of dimers and tetramers. The association constant for the dimer-to-tetramer transition is 2.1 x 10(7) M-1, indicating that the protein would consist of both dimers and tetramers at physiological concentrations. The carboxyl terminus of MutS is required for tetramer assembly because a previously described 53-amino acid carboxyl-terminal truncation (MutS800) forms a limiting species of a dimer (Obmolova, G., Ban, C., Hsieh, P., and Yang, W. (2000) Nature 407, 703-710; Lamers, M. H., Perrakis, A., Enzlin, J. H., Winterwerp, H. H., de Wind, N., and Sixma, T. K. (2000) Nature 407, 711-717). MutS800 binds a 20-base pair heteroduplex an order of magnitude more weakly than full-length MutS, and at saturating protein concentrations, the heteroduplex-bound mass observed with MutS800 is only half that observed with the full length protein, indicating that the subunit copy number of heteroduplex-bound MutS is twice that of MutS800. Analytical equilibrium ultracentrifugation using a fluorescein-tagged 20-base pair heteroduplex demonstrated that native MutS forms a tetramer on this single site-sized heteroduplex DNA. Equilibrium fluorescence experiments indicated that dimer-to-tetramer assembly promotes mismatch binding by MutS and that the tetramer can bind only a single heteroduplex molecule, implying nonequivalence of the two dimers within the tetramer. Compared with native MutS, the ability of MutS800 to promote MutL-dependent activation of MutH is substantially reduced.     

Interaction of Escherichia coli MutS and MutL at a DNA mismatch

MutS and MutL are both required to activate downstream events in DNA mismatch repair. We examined the rate of dissociation of MutS from a mismatch using linear heteroduplex DNAs or heteroduplexes blocked at one or both ends by four-way DNA junctions in the presence and absence of MutL. In the presence of ATP, dissociation of MutS from linear heteroduplexes or heteroduplexes blocked at only one end occurs within 15 s. When both duplex ends are blocked, MutS remains associated with the DNA in complexes with half-lives of 30 min. DNase I footprinting of MutS complexes is consistent with migration of MutS throughout the DNA duplex region. When MutL is present, it associates with MutS and prevents ATP-dependent migration away from the mismatch in a manner that is dependent on the length of the heteroduplex. The rate and extent of mismatch-provoked cleavage at hemimethylated GATC sites by MutH in the presence of MutS, MutL, and ATP are the same whether the mismatch and GATC sites are in cis or in trans. These results suggest that a MutS-MutL complex in the vicinity of a mismatch is involved in activating MutH.     

Formation of a DNA mismatch repair complex mediated by ATP

The mismatch repair proteins, MutS and MutL, interact in a DNA mismatch and ATP-dependent manner to activate downstream events in repair. Here, we assess the role of ATP binding and hydrolysis in mismatch recognition by MutS and the formation of a ternary complex involving MutS and MutL bound to a mismatched DNA. We show that ATP reduces the affinity of MutS for mismatched DNA and that the modulation of DNA binding affinity by nucleotide is even more pronounced for MutS E694A, a protein that binds ATP but is defective for ATP hydrolysis. Despite the ATP hydrolysis defect, E694A, like WT MutS, undergoes rapid, ATP-dependent dissociation from a DNA mismatch. Furthermore, MutS E694A retains the ability to interact with MutL on mismatched DNA. The recruitment of MutL to a mismatched DNA by MutS is also observed for two mutant MutL proteins, E29A, defective for ATP hydrolysis, and R266A, defective for DNA binding. These results suggest that ATP binding in the absence of hydrolysis is sufficient to trigger formation of a MutS sliding clamp. However, recruitment of MutL results in the formation of a dynamic ternary complex that we propose is the intermediate that signals subsequent repair steps requiring ATP hydrolysis.     

ATP hydrolysis induces expansion of MutS contacts on heteroduplex: a case for MutS treadmilling?

An unsolved problem in E. coli mismatch repair is how the MutS-MutL complex communicates positional information of a mismatch to MutH. MutS is bound to a mismatch in the absence of ATP, exhibiting a short DNase I footprint that is dramatically expanded in ATP hydrolysis. The same is corroborated by restriction enzyme site protection far away from the mismatch. High-resolution gel-shift analyses revealed that super-shifted specific complexes, presumably containing multiple MutS homodimers on the same heteroduplex, were generated during ATP hydrolysis. Such complexes are largely nonspecific in "minus ATP" or in ATP gamma S conditions. Specific ternary complexes of MutS-MutL-heteroduplexes were formed only during ATP hydrolysis. These results suggest that MutS loading onto a mismatch induces the formation of a higher-order complex containing multiple MutS homodimers, presumably through a putative "treadmilling action" that is ATP-hydrolysis dependent. Such a higher-order MutS complex productively interacts with MutL in ATP-hydrolyzing conditions and generates a specific ternary complex, which might communicate with MutH. This model should neither depend on nor give rise to the spooling of DNA. This was corroborated when we observed footprint extension in ATP-hydrolyzing conditions, despite the heteroduplex ends being tethered to agarose beads that block helical rotations.     

MutS mediates heteroduplex loop formation by a translocation mechanism.

Interaction of Escherichia coli MutS and MutL with heteroduplex DNA has been visualized by electron microscopy. In a reaction dependent on ATP hydrolysis, complexes between a MutS dimer and a DNA heteroduplex are converted to protein-stabilized, alpha-shaped loop structures with the mismatch in most cases located within the DNA loop. Loop formation depends on ATP hydrolysis and loop size increases linearly with time at a rate of 370 base pairs/min in phosphate buffer and about 10,000 base pairs/min in the HEPES buffer used for repair assay. These observations suggest a translocation mechanism in which a MutS dimer bound to a mismatch subsequently leaves this site by ATP-dependent tracking or unidimensional movement that is in most cases bidirectional from the mispair. In view of the bidirectional capability of the methyl-directed pathway, this reaction may play a role in determination of heteroduplex orientation. The rate of MutS-mediated DNA loop growth is enhanced by MutL, and when both proteins are present, both are found at the base of alpha-loop structures, and both can remain associated with excision intermediates produced in later stages of the reaction.     

The MutL ATPase is required for mismatch repair

Members of the MutL family contain a novel nucleotide binding motif near their amino terminus, and the Escherichia coli protein has been found to be a weak ATPase (Ban, C., and Yang, W. (1998) Cell 95, 541-552). Genetic analysis has indicated that substitution of Lys for Glu-32 within this motif of bacterial MutL results in a strong dominant negative phenotype (Aronshtam, A., and Marinus, M. G. (1996) Nucleic Acids Res. 24, 2498-2504). By in vitro comparison of MutL-E32K with the wild type protein, we show the mutant protein to be defective in DNA-activated ATP hydrolysis, as well as MutS- and MutL-dependent activation of the MutH d(GATC) endonuclease and the mismatch repair excision system. MutL-E32K also acts in dominant negative manner in the presence of wild type MutL in vitro, inhibiting the overall mismatch repair reaction, as well as MutH activation. As judged by protein affinity chromatography, MutL and MutL-E32K both support formation of ternary complexes that also contain MutS and MutH or MutS and DNA helicase II. These findings imply that the MutL nucleotide binding center is required for mismatch repair and suggest that the dominant negative behavior of the MutL-E32K mutation is due to the formation of dead-end complexes in which the MutL-E32K protein is unable to transduce a signal from MutS that otherwise results in mismatch-dependent activation of the MutH d(GATC) endonuclease or the unwinding activity of helicase II.     

Crystal structure and biochemical analysis of the MutS.ADP.beryllium fluoride complex suggests a conserved mechanism for ATP interactions in mismatch repair

During mismatch repair ATP binding and hydrolysis activities by the MutS family proteins are important for both mismatch recognition and for transducing mismatch recognition signals to downstream repair factors. Despite intensive efforts, a MutS.ATP.DNA complex has eluded crystallographic analysis. Searching for ATP analogs that strongly bound to Thermus aquaticus (Taq) MutS, we found that ADP.beryllium fluoride (ABF), acted as a strong inhibitor of several MutS family ATPases. Furthermore, ABF promoted the formation of a ternary complex containing the Saccharomyces cerevisiae MSH2.MSH6 and MLH1.PMS1 proteins bound to mismatch DNA but did not promote dissociation of MSH2.MSH6 from mismatch DNA. Crystallographic analysis of the Taq MutS.DNA.ABF complex indicated that although this complex was very similar to that of MutS.DNA.ADP, both ADP.Mg(2+) moieties in the MutS. DNA.ADP structure were replaced by ABF. Furthermore, a disordered region near the ATP-binding pocket in the MutS B subunit became traceable, whereas the equivalent region in the A subunit that interacts with the mismatched nucleotide remained disordered. Finally, the DNA binding domains of MutS together with the mismatched DNA were shifted upon binding of ABF. We hypothesize that the presence of ABF is communicated between the two MutS subunits through the contact between the ordered loop and Domain III in addition to the intra-subunit helical lever arm that links the ATPase and DNA binding domains.     

In vitro and in vivo studies of MutS,MutL and MutH mutants: correlation of mismatch repair and DNA recombination

We have used the recently determined crystal structures of Escherichia coli (E. coli) MutS, MutL and MutH to guide construction of 47 amino-acid substitutions in these proteins and analyzed their behavior in mismatch repair and recombination in vitro and in vivo. We find that the active site of the MutH endonuclease is composed of regions from two separate structural domains and that the C-terminal 5 residues of MutH influence both DNA binding and cleavage. We also find that the non-specific DNA-binding activity of MutL is required for mismatch repair and probably functions after strand cleavage by MutH. Alteration of residues in either the mismatch recognition domain, the ATPase active site, or the domain interfaces linking the two activities can diminish the differential binding of MutS to homoduplex versus heteroduplex and results in the loss of mismatch-specific MutH activation. Finally, every mutation that abolishes mismatch repair is deficient in blocking homeologous recombination, suggesting that mismatch repair and prevention of homeologous recombination use the same MutS-MutL complexes for signaling in E. coli.     

Initiation of methyl-directed mismatch repair.

Escherichia coli MutH possesses an extremely weak d(GATC) endonuclease that responds to the state of methylation of the sequence (Welsh, K. M., Lu, A.-L., Clark, S., and Modrich, P. (1987) J. Biol. Chem. 262, 15624-15629). MutH endonuclease is activated in a reaction that requires MutS, MutL, ATP, and Mg2+ and depends upon the presence of a mismatch within the DNA. The degree of activation correlates with the efficiency with which a particular mismatch is subject to methyl-directed repair (G-T greater than G-G greater than A-C greater than C-C), and activated MutH responds to the state of DNA adenine methylation. Incision of an unmethylated strand occurs immediately 5' to a d(GATC) sequence, leaving 5' phosphate and 3' hydroxy termini (pN decreases pGpAp-TpC). Unmethylated d(GATC) sites are subject to double strand cleavage by activated MutH, an effect that may account for the killing of dam- mutants by 2-aminopurine. The mechanism of activation apparently requires ATP hydrolysis since adenosine-5'-O-(3-thiotriphosphate) not only fails to support the reaction but also inhibits activation promoted by ATP. The process has no obligate polarity as d(GATC) site incision by the activated nuclease can occur either 3' or 5' to the mismatch on an unmethylated strand. However, activation is sensitive to DNA topology. Circular heteroduplexes are better substrates than linear molecules, and activity of DNAs of the latter class depends on placement of the mismatch and d(GATC) site within the molecule. MutH activation is supported by a 6-kilobase linear heteroduplex in which the mismatch and d(GATC) site are centrally located and separated by 1 kilobase, but a related molecule, in which the two sites are located near opposite ends of the DNA, is essentially inactive as substrate. We conclude that MutH activation represents the initiation stage of methyl-directed repair and suggest that interaction of a mismatch and a d(GATC) site is provoked by MutS binding to a mispair, with subsequent ATP-dependent translocation of one or more Mut proteins along the helix leading to cleavage at a d(GATC) sequence on either side of the mismatch.     

The coordinated functions of the E. coli MutS and MutL proteins in mismatch repair

The Escherichia coli MutS and MutL proteins have been conserved throughout evolution, although their combined functions in mismatch repair (MMR) are poorly understood. We have used biochemical and genetic studies to ascertain a physiologically relevant mechanism for MMR. The MutS protein functions as a regional lesion sensor. ADP-bound MutS specifically recognizes a mismatch. Repetitive rounds of mismatch-provoked ADP-->ATP exchange results in the loading of multiple MutS hydrolysis-independent sliding clamps onto the adjoining duplex DNA. MutL can only associate with ATP-bound MutS sliding clamps. Interaction of the MutS-MutL sliding clamp complex with MutH triggers ATP binding by MutL that enhances the endonuclease activity of MutH. Additionally, MutL promotes ATP binding-independent turnover of idle MutS sliding clamps. These results support a model of MMR that relies on two dynamic and redundant ATP-regulated molecular switches.     

Modulation of MutS ATP hydrolysis by DNA cofactors

Escherichia coli MutS protein, which is required for mismatch repair, has a slow ATPase activity that obeys Michalelis-Menten kinetics. At 37 degrees C, the steady-state turnover rate for ATP hydrolysis is 1.0 +/- 0.3 min(-1) per monomer equivalent with a K(m) of 33 +/- 6 microM. Hydrolysis is competitively inhibited by the ATP analogues AMPPNP and ATPgammaS, with K(i) values of 4 microM in both cases, and by ADP with a K(i) of 40 microM. The rate of ATP hydrolysis is stimulated 2-5-fold by short hetero- and homoduplex DNAs. The concentration of DNA cofactor that yields half-maximal stimulation is lowest for oligodeoxynucleotide duplexes that contain a mismatched base pair. Pre-steady-state chemical quench analysis has demonstrated a substoichiometric initial burst of ADP formation by free MutS that is governed by a rate constant of 78 min(-1), indicating that the rate-limiting step for the steady-state reaction occurs after hydrolysis. Prebinding of MutS to homoduplex DNA does not alter the burst kinetics or amplitude but only increases the steady-state rate. In contrast, binding of the protein to heteroduplex DNA abolishes the burst of ADP formation, indicating that the rate-limiting step now occurs before hydrolysis. Gel filtration analysis indicates that the MutS dimer assembles into higher order oligomers in a concentration-dependent manner, and that ATP binding shifts this equilibrium to favor assembly. These results, together with kinetic findings, indicate nonequivalence of subunits within a MutS oligomer with respect to ATP hydrolysis and DNA binding.     

Differential and simultaneous adenosine di- and triphosphate binding by MutS

The roles of ATP binding and hydrolysis in the function of MutS in mismatch repair are poorly understood. As one means of addressing this question, we have determined the affinities and number of adenosine di- and triphosphate binding sites within MutS. Nitrocellulose filter binding assay and equilibrium fluorescence anisotropy measurements have demonstrated that MutS has one high affinity binding site for ADP and one high affinity site for nonhydrolyzable ATP analogues per dimer equivalent. Low concentrations of 5'-adenylylimidodiphosphate (AMPPNP) promote ADP binding and a large excess of AMPPNP is required to displace ADP from the protein. Fluorescence energy transfer and filter binding assays indicate that ADP and nonhydrolyzable ATP analogues can bind simultaneously to adjacent subunits within the MutS oligomer with affinities in the low micromolar range. These findings suggest that the protein exists primarily as the ATP.MutS.ADP ternary complex in solution and that this may be the form of the protein that is involved in DNA encounters in vivo.     

Mutations in the signature motif in MutS affect ATP-induced clamp formation and mismatch repair

MutS protein dimer recognizes and co-ordinates repair of DNA mismatches. Mismatch recognition by the N-terminal mismatch recognition domain and subsequent downstream signalling by MutS appear coupled to the C-terminal ATP catalytic site, Walker box, through nucleotide-mediated conformational transitions. Details of this co-ordination are not understood. The focus of this study is a conserved loop in Escherichia coli MutS that is predicted to mediate cross-talk between the two ATP catalytic sites in MutS homodimer. Mutagenesis was employed to assess the role of this loop in regulating MutS function. All mutants displayed mismatch repair defects in vivo . Biochemical characterization further revealed defects in ATP binding, ATP hydrolysis as well as effective mismatch recognition. The kinetics of initial burst of ATP hydrolysis was similar to wild type but the magnitude of the burst was reduced for the mutants. Given its proximity to the ATP bound in the opposing monomer in the crystal and its potential analogy with signature motif of ABC transporters, the results strongly suggest that the loop co-ordinates ATP binding/hydrolysis in trans by the two catalytic sites. Importantly, our data reveal that the loop plays a direct role in co-ordinating conformational changes involved in long-range communication between Walker box and mismatch recognition domains.     

Distinct MutS DNA-binding modes that are differentially modulated by ATP binding and hydrolysis.

The role of MutS ATPase in mismatch repair is controversial. To clarify further the function of this activity, we have examined adenine nucleotide effects on interactions of Escherichia coli MutS with homoduplex and heteroduplex DNAs. In contrast to previous results with human MutS alpha, we find that a physical block at one end of a linear heteroduplex is sufficient to support stable MutS complex formation in the presence of ATP.Mg(2+). Surface plasmon resonance analysis at low ionic strength indicates that the lifetime of MutS complexes with heteroduplex DNA depends on the nature of the nucleotide present when MutS binds. Whereas complexes prepared in the absence of nucleotide or in the presence of ADP undergo rapid dissociation upon challenge with ATP x Mg(2+), complexes produced in the presence of ATP x Mg(2+), adenosine 5'-(beta,gamma-imino)triphosphate (AMPPNP) x Mg(2+), or ATP (no Mg(2+)) are resistant to dissociation upon ATP challenge. AMPPNP x Mg(2+) and ATP (no Mg(2+)) reduce MutS affinity for heteroduplex but have little effect on homoduplex affinity, resulting in abolition of specificity for mispaired DNA at physiological salt concentrations. Conversely, the highest mismatch specificity is observed in the absence of nucleotide or in the presence of ADP. ADP has only a limited effect on heteroduplex affinity but reduces MutS affinity for homoduplex DNA.     

A single mismatch in the DNA induces enhanced aggregation of MutS. Hydrodynamic analyses of the protein-DNA complexes

Changes in the oligomeric status of MutS protein was probed in solution by dynamic light scattering (DLS), and corroborated by sedimentation analyses. In the absence of any nucleotide cofactor, free MutS protein [hydrodynamic radius (Rh) of 10-12 nm] shows a small increment in size (Rh 14 nm) following the addition of homoduplex DNA (121 bp), whereas the same increases to about 18-20 nm with heteroduplex DNA containing a mismatch. MutS forms large aggregates (Rh > 500 nm) with ATP, but not in the presence of a poorly hydrolysable analogue of ATP (ATPgammaS). Addition of either homo- or heteroduplex DNA attenuates the same, due to protein recruitment to DNA. However, the same protein/DNA complexes, at high concentration of ATP (10 mm), manifest an interesting property where the presence of a single mismatch provokes a much larger oligomerization of MutS on DNA (Rh > 500 nm in the presence of MutL) as compared to the normal homoduplex (Rh approximately 100-200 nm) and such mismatch induced MutS aggregation is entirely sustained by the ongoing hydrolysis of ATP in the reaction. We speculate that the surprising property of a single mismatch, in nucleating a massive aggregation of MutS encompassing the bound DNA might play an important role in mismatch repair system.     

ATP hydrolysis-dependent formation of a dynamic ternary nucleoprotein complex with MutS and MutL.

Functional interactions of Escherichia coli MutS and MutL in mismatch repair are dependent on ATP. In this study, we show that MutS and MutL associate with immobilised DNA in a manner dependent on ATP hydrolysis and with an ATP concentration near the solution K m of the ATPase of MutS. After removal of MutS, MutL and ATP, much of the protein in this ternary complex is not stably associated, with MutL leaving the complex more rapidly than MutS. The rapid dissociation reveals a dynamic interaction with concurrent rapid association and dissociation of proteins from the DNA. Analysis by surface plasmon resonance showed that the DNA interacting with dynamically bound protein was more resistant to nuclease digestion than the DNA in MutS-DNA complexes. Non-hydrolysable analogs of ATP inhibit the formation of this dynamic complex, but permit formation of a second type of ternary complex with MutS and MutL stably bound to the immobilised DNA.     

Oligomerization of a MutS mismatch repair protein from Thermus aquaticus.

The MutS DNA mismatch protein recognizes heteroduplex DNAs containing mispaired or unpaired bases. We have examined the oligomerization of a MutS protein from Thermus aquaticus that binds to heteroduplex DNAs at elevated temperatures. Analytical gel filtration, cross-linking of MutS protein with disuccinimidyl suberate, light scattering, and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry establish that the Taq protein is largely a dimer in free solution. Analytical equilibrium sedimentation showed that the oligomerization of Taq MutS involves a dimer-tetramer equilibrium in which dimer predominates at concentrations below 10 microM. The DeltaG(0)(2-4) for the dimer to tetramer transition is approximately -6.9 +/- 0.1 kcal/mol of tetramer. Analytical gel filtration of native complexes and gel mobility shift assays of an maltose-binding protein-MutS fusion protein bound to a short, 37-base pair heteroduplex DNA reveal that the protein binds to DNA as a dimer with no change in oligomerization upon DNA binding.     

Steady-state ATPase activity of E. coli MutS modulated by its dissociation from heteroduplex DNA

The ability of MutS to recognize mismatched DNA is required to initiate a mismatch repair (MMR) system. ATP binding and hydrolysis are essential in this process, but their role in MMR is still not fully understood. In this study, steady-state ATPase activities of MutS from Escherichia coli were investigated using the spectrophotometric method with a double end-blocked heteroduplex containing gapped bases. The ATPase activities of MutS increased as the number of gapped bases increased in a double end-blocked heteroduplex with 2-8 gapped bases in the chain, indicating that MutS dissociates from DNA when it reaches a scission during movement along the DNA. Since movement of MutS along the chain does not require extensive ATP hydrolysis and the ATPase activity is only enhanced when MutS dissociates from a heteroduplex, these results support the sliding clamp model in which ATP binding by MutS induces the formation of a hydrolysis-independent sliding clamp.     

Biochemical characterization of mismatch-binding protein MutS1 and nicking endonuclease MutL from a euryarchaeon Methanosaeta thermophila

In eukaryotes and most bacteria, the MutS1/MutL-dependent mismatch repair system (MMR) corrects DNA mismatches that arise as replication errors. MutS1 recognizes mismatched DNA and stimulates the nicking endonuclease activity of MutL to incise mismatch-containing DNA. In archaea, there has been no experimental evidence to support the existence of the MutS1/MutL-dependent MMR. Instead, it was revealed that a large part of archaea possess mismatch-specific endonuclease EndoMS, indicating that the EndoMS-dependent MMR is widely adopted in archaea. However, some archaeal genomes encode MutS1 and MutL homologs, and their molecular functions have not been revealed. In this study, we purified and characterized recombinant MutS1 and the C-terminal endonuclease domain of MutL from a methanogenic archaeon Methanosaeta thermophila (mtMutS1 and the mtMutL CTD, respectively). mtMutS1 bound to mismatched DNAs with a higher affinity than to perfectly-matched and other structured DNAs, which resembles the DNA-binding specificities of eukaryotic and bacterial MutS1 homologs. The mtMutL CTD showed a Mn²⁺/Ni²⁺/Co²⁺-dependent nicking endonuclease activity that introduces single-strand breaks into a circular double-stranded DNA. The nicking endonuclease activity of the mtMutL CTD was impaired by mutagenizing the metal-binding motif that is identical to those of eukaryotic and bacterial MutL endonucleases. These results raise the possibility that not only the EndoMS-dependent MMR but also the traditional MutS1/MutL-dependent MMR exist in archaea.     

Asymmetric ATP binding and hydrolysis activity of the Thermus aquaticus MutS dimer is key to modulation of its interactions with mismatched DNA

Prokaryotic MutS and eukaryotic Msh proteins recognize base pair mismatches and insertions or deletions in DNA and initiate mismatch repair. These proteins function as dimers (and perhaps higher order oligomers) and possess an ATPase activity that is essential for DNA repair. Previous studies of Escherichia coli MutS and eukaryotic Msh2-Msh6 proteins have revealed asymmetry within the dimer with respect to both DNA binding and ATPase activities. We have found the Thermus aquaticus MutS protein amenable to detailed investigation of the nature and role of this asymmetry. Here, we show that (a) in a MutS dimer one subunit (S1) binds nucleotide with high affinity and the other (S2) with 10-fold weaker affinity, (b) S1 hydrolyzes ATP rapidly while S2 hydrolyzes ATP at a 30-50-fold slower rate, (c) mismatched DNA binding to MutS inhibits ATP hydrolysis at S1 but slow hydrolysis continues at S2, and (d) interaction between mismatched DNA and MutS is weakened when both subunits are occupied by ATP but remains stable when S1 is occupied by ATP and S2 by ADP. These results reveal key MutS species in the ATPase pathway; S1(ADP)-S2(ATP) is formed preferentially in the absence of DNA or in the presence of fully matched DNA, while S1(ATP)-S2(ATP) and S1(ATP)-S2(ADP) are formed preferentially in the presence of mismatched DNA. These MutS species exhibit differences in interaction with mismatched DNA that are likely important for the mechanism of MutS action in DNA repair.