Assembly and Molecular Activities of the MutS Tetramer

Bjornson, Keith P.; Blackwell, Leonard J.; Sage, Harvey J.; Baitinger, Celia; Allen, Dwayne J.; Modrich, Paul

doi:10.1074/jbc.m305513200

Cited by 60 publications

(95 citation statements)

References 37 publications

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“…The simplest interpretation of this value is that it corresponds to the intrinsic ATP hydrolytic rate constant for the mutant protein. This parameter is almost identical to the k cat for steady state ATP hydrolysis by MutS E694A at 30°C (see above), which is 0.08 min Ϫ1 when expressed per dimer, the minimum MutS functional unit (22,26,37,38). The similarity of these values indicates that hydrolytic chemistry is largely rate-limiting for turnover by MutS E694A.…”

Section: Mutssupporting

confidence: 51%

“…ATPase, Mismatch Repair Assays, and Surface Plasmon Resonance Spectroscopy-Steady state MutS ATPase hydrolytic parameters and activation of the MutH d(GATC) endonuclease were determined as described previously (36,37), except that ATPase reactions were performed in 25 mM Tris-HCl, pH 7.6, 100 mM KCl, 5 mM MgCl 2 , 1 mM dithiothreitol, 0.1 mg/ml bovine serum albumin.…”

Section: Methodsmentioning

confidence: 99%

“…MutS E694A Is Defective in the MutL-dependent Activation of the MutH Endonuclease-Initiation of E. coli mismatch repair depends on the mismatch-, MutS-, and MutL-dependent activation of the MutH d(GATC) endonuclease (7). This activity has been scored in vitro using heteroduplexes in which the mismatch and d(GATC) site reside on the same DNA molecule (6,7,37), and by a trans activation assay in which the two DNA sites reside on separate synthetic oligonucleotide duplexes (23,34,40). The finding that a His-tagged version of MutS E694A supports MutH activation in the trans assay has led to the suggestion that ATP binding by MutS is sufficient for activation of downstream activities (23).…”

Section: Mutsmentioning

confidence: 99%

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Hydrolytically Deficient MutS E694A Is Defective in the MutL-dependent Activation of MutH and in the Mismatch-dependent Assembly of the MutS · MutL · Heteroduplex Complex

Baitinger

Burdett

Modrich

2003

Journal of Biological Chemistry

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Mismatch recognition by MutS initiates mismatch repair in bacterial cells (1-3). MutS recruits MutL to the heteroduplex in an ATP-dependent fashion (4 -6), and assembly of the MutL⅐MutS⅐heteroduplex ternary complex is sufficient to activate the MutH endonuclease, which incises the unmethylated strand at a hemimethylated d(GATC) strand signal (7). The ensuing strand break, which may reside either 3Ј or 5Ј to the mismatch, serves as the site for initiation of excision by a system comprised of DNA helicase II and an appropriate 3Ј to 5Ј or 5Ј to 3Ј single-strand specific exonuclease (8 -13). This bidirectional excision capability implies that the mismatch repair system must establish the relative orientation of the mismatch and strand break that directs the reaction. This is necessary to ensure loading of a 3Ј to 5Ј excision system when the nick resides 3Ј to the mispair and a 5Ј to 3Ј system when it is located 5Ј to the mismatch.In addition to its mismatch binding site, MutS has a carboxyl-terminal ATPase that is required for function of the protein in mismatch repair (7,14,15), and this element is conserved in MutS homologs in higher cells (16 -20). Structural studies have shown that MutS is a member of the ABC (adenine nucleotide binding cassette) family (21-23), which is largely comprised of proteins that couple the energy of ATP hydrolysis to transport of molecules across biological membranes (24,25).Several models for ATPase function in MutS homolog action have been suggested. One class of mechanism is based on a variety of observations indicating that in the presence of ATP, MutS homologs can leave a mismatch by movement along the helix (26 -29). This movement is postulated to link mismatch recognition to activation of downstream events at the strand break that directs excision, and can in principle account for the orientation-dependent loading of the excision system at the strand break that is necessitated by the bidirectional nature of the repair system. Two types of mechanisms have been proposed to explain ATP-dependent movement of MutS homologs along the DNA contour. One model posits that movement depends on ATP hydrolysis by the DNA-bound protein. The alternate molecular switch model postulates a G-protein like mechanism whereby binding of a MutS⅐ADP complex to a mismatch promotes ATP exchange for ADP, with the resulting MutS⅐ATP complex diffusing freely along the helix. Evidence consistent with both the hydrolytic model (26, 27, 29 -31) and the molecular switch model (28, 32) is available.A distinct role for ATP binding and hydrolysis has been proposed based on use of a trans assay for MutH activation (23). In this work, a mismatch on one oligonucleotide duplex was shown to lead to MutH activation and d(GATC) incision on a second synthetic duplex in a reaction dependent on MutL and MutS. These observations have led to the suggestion that once mismatch recognition occurs, MutS remains bound to the mispair during the course of repair, with mismatch-strand signal interaction mediated by DNA bending (23)....

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Section: Mutssupporting

confidence: 51%

Section: Methodsmentioning

confidence: 99%

Section: Mutsmentioning

confidence: 99%

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Hydrolytically Deficient MutS E694A Is Defective in the MutL-dependent Activation of MutH and in the Mismatch-dependent Assembly of the MutS · MutL · Heteroduplex Complex

Baitinger

Burdett

Modrich

2003

Journal of Biological Chemistry

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“…Both E. coli and Taq MutS proteins have been shown to exist in an equilibrium of dimers and tetramers (21,37,38). This observation raises the question of whether the bent and unbent populations correlate with the different oligomeric states of MutS proteins.…”

Section: Conformations Of Muts-dna Complexes Are Independent Of Oligo-mentioning

confidence: 90%

DNA bending and unbending by MutS govern mismatch recognition and specificity

Wang

Yang²,

Schofield

et al. 2003

Proc. Natl. Acad. Sci. U.S.A.

175

233

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DNA mismatch repair is central to the maintenance of genomic stability. It is initiated by the recognition of base-base mismatches and insertion͞deletion loops by the family of MutS proteins. Subsequently, ATP induces a unique conformational change in the MutS-mismatch complex but not in the MutS-homoduplex complex that sets off the cascade of events that leads to repair. To gain insight into the mechanism by which MutS discriminates between mismatch and homoduplex DNA, we have examined the conformations of specific and nonspecific MutS-DNA complexes by using atomic force microscopy. Interestingly, MutS-DNA complexes exhibit a single population of conformations, in which the DNA is bent at homoduplex sites, but two populations of conformations, bent and unbent, at mismatch sites. These results suggest that the specific recognition complex is one in which the DNA is unbent. Combining our results with existing biochemical and crystallographic data leads us to propose that MutS: (i) binds to DNA nonspecifically and bends it in search of a mismatch; (ii) on specific recognition of a mismatch, undergoes a conformational change to an initial recognition complex in which the DNA is kinked, with interactions similar to those in the published crystal structures; and (iii) finally undergoes a further conformational change to the ultimate recognition complex in which the DNA is unbent. Our results provide a structural explanation for the long-standing question of how MutS achieves mismatch repair specificity. D NA mismatch repair (MMR) is a highly conserved repair pathway targeting mismatched bases that arise through DNA replication errors and during homologous recombination (1-3). Inactivation of MMR genes results in a significant increase in the spontaneous mutation rate and, in humans, a predisposition to cancer (4). Escherichia coli provides the best-understood MMR system and serves as a prototype for the more complicated but homologous eukaryotic systems (5). In E. coli, the proteins MutS, MutL, and MutH are responsible for the initiation of MMR (6). MutS and MutL function as dimers and have intrinsic ATPase activities that are essential for MMR (7,8). MMR is initiated by the binding of MutS to either a mismatch or a short insertion͞deletion loop (IDL). Subsequently, ATP induces a conformational change in the MutS-mismatch complex and promotes its interaction with MutL. Assembly of the MutS-MutL-heteroduplex complex activates the endonuclease activity of MutH, which incises the newly synthesized (unmethylated) strand at a d(GATC) site. This incision confers strand specificity of MMR, directing repair exclusively to the newly synthesized strand containing the error. Excision repair completes the process.Crystal structures of E. coli and Thermus aquaticus (Taq) MutS dimers complexed with a G͞T base-base mismatch and a 1T-bulge, respectively, shed light on the structural components of mismatch recognition (9-11). Specific interactions include an aromatic ring stack of a conserved phenylalanine (Phe-39 in Taq or Phe-36 in...

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“…coli MutS forms tetramers, with a reported K d for the dimer/ tetramer equilibrium ranging from 210 to 2,200 nM −1 (34,35), that could complicate the analysis of the P(D i,j ) distributions if mixed populations of dimers and tetramers were present. Use of the gold nanocrystals, however, allowed us to make measurements at protein concentrations as low as 50 nM, well below the K d .…”

Section: Resultsmentioning

confidence: 99%

DNA conformations in mismatch repair probed in solution by X-ray scattering from gold nanocrystals

Hura

Tsai

Claridge

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

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DNA metabolism and processing frequently require transient or metastable DNA conformations that are biologically important but challenging to characterize. We use gold nanocrystal labels combined with small angle X-ray scattering to develop, test, and apply a method to follow DNA conformations acting in the Escherichia coli mismatch repair (MMR) system in solution. We developed a neutral PEG linker that allowed gold-labeled DNAs to be flashcooled and stored without degradation in sample quality. The 1,000-fold increased gold nanocrystal scattering vs. DNA enabled investigations at much lower concentrations than otherwise possible to avoid concentration-dependent tetramerization of the MMR initiation enzyme MutS. We analyzed the correlation scattering functions for the nanocrystals to provide higher resolution interparticle distributions not convoluted by the intraparticle distribution. We determined that mispair-containing DNAs were bent more by MutS than complementary sequence DNA (csDNA), did not promote tetramer formation, and allowed MutS conversion to a sliding clamp conformation that eliminated the DNA bends. Addition of second protein responder MutL did not stabilize the MutS-bent forms of DNA. Thus, DNA distortion is only involved at the earliest mispair recognition steps of MMR: MutL does not trap bent DNA conformations, suggesting migrating MutL or MutS/MutL complexes as a conserved feature of MMR. The results promote a mechanism of mismatch DNA bending followed by straightening in initial MutS and MutL responses in MMR. We demonstrate that small angle X-ray scattering with gold labels is an enabling method to examine protein-induced DNA distortions key to the DNA repair, replication, transcription, and packaging. D NA is frequently considered a passive component in interactions with proteins involved in DNA metabolism. Despite this view, many proteins use DNA structural features to mediate catalysis and identify damaged DNA through the effects of damage on DNA rigidity and conformation (1-6). The view of DNA as a passive element is therefore at least in part due to a paucity of robust tools to examine dynamic DNA conformational states during multistep reactions. Gold-labeled DNA enables measurement over length scales sufficient to accommodate several proteins to identify cooperative effects on DNA. Because X-rays scatter predominantly from electrons, using heavy atom labels (7-11) provides high contrast relative to organic molecules. By using labels of moderate size (∼5 nm), the scattering from gold nanocrystals dominates all other scattering signals by three orders of magnitude, thereby reducing analysis complexity while minimizing nanocrystal influence on biological macromolecules. Importantly, small angle X-ray scattering (SAXS) provides global information on conformations adopted by a population of macromolecules in almost any solution condition (12)(13)(14).Mismatch repair (MMR) is an evolutionarily conserved process that corrects mismatches generated during DNA replication (15,16). Despite the i...

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Assembly and Molecular Activities of the MutS Tetramer

Cited by 60 publications

References 37 publications

Hydrolytically Deficient MutS E694A Is Defective in the MutL-dependent Activation of MutH and in the Mismatch-dependent Assembly of the MutS · MutL · Heteroduplex Complex

Hydrolytically Deficient MutS E694A Is Defective in the MutL-dependent Activation of MutH and in the Mismatch-dependent Assembly of the MutS · MutL · Heteroduplex Complex

DNA bending and unbending by MutS govern mismatch recognition and specificity

DNA conformations in mismatch repair probed in solution by X-ray scattering from gold nanocrystals

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