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

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

Functions of the Mismatch Repair Gene mutS from Acinetobacter sp. Strain ADP1

The genus Acinetobacter encompasses a heterogeneous group of bacteria that are ubiquitous in the natural environment due in part to their ability to adapt genetically to novel challenges. Acinetobacter sp. strain ADP1 (also known as strain BD413) is naturally transformable and takes up DNA from any source. Donor DNA can be integrated into the chromosome by recombination provided it possesses sufficient levels of nucleotide sequence identity to the recipient's DNA. In other bacteria, the requirement for sequence identity during recombination is partly due to the actions of the mismatch repair system, a key component of which, MutS, recognizes mismatched bases in heteroduplex DNA and, along with MutL, blocks strand exchange. We have cloned mutS from strain ADP1 and examined its roles in preventing recombination between divergent DNA and in the repair of spontaneous replication errors. Inactivation of mutS resulted in 3- to 17-fold increases in transformation efficiencies with donor sequences that were 8 to 20% divergent relative to the strain ADP1. Strains lacking MutS exhibited increased spontaneous mutation frequencies, and reversion assays demonstrated that MutS preferentially recognized transition mismatches while having little effect on the repair of transversion mismatches. Inactivation of mutS also abolished the marker-specific variations in transforming efficiency seen in mutS(+) recipients where transition and frameshift alleles transformed at eightfold lower frequencies than transversions or large deletions. Comparison of the MutS homologs from five individual Acinetobacter strains with those of other gram-negative bacteria revealed that a number of unique indels are conserved among the Acinetobacter amino acid sequences.     

Interaction of MutS and Vsr: some dominant-negative mutS mutations that disable methyladenine-directed mismatch repair are active in very-short-patch repair

In Escherichia coli and related bacteria, the very-short-patch (VSP) repair pathway uses an endonuclease, Vsr, to correct T-G mismatches that result from the deamination of 5-methylcytosines in DNA to C-G. The products of mutS and mutL, which are required for adenine methylation-directed mismatch repair (MMR), enhance VSP repair. Multicopy plasmids carrying mutS alleles that are dominant negative for MMR were tested for their effects on VSP repair. Some mutS mutations (class I) did not lower VSP repair in a mutS(+) background, and most class I mutations increased VSP repair in mutS cells more than plasmids containing mutS(+). Other plasmid-borne mutS mutations (class II) and mutS(+) decreased VSP repair in the mutS(+) background. Thus, MutS protein lacking functions required for MMR can still participate in VSP repair, and our results are consistent with a model in which MutS binds transiently to the mispair and then translocates away from the mispair to create a specialized structure that enhances the binding of Vsr.     

Mispair specificity of methyl-directed DNA mismatch correction in vitro

To evaluate the substrate specificity of methyl-directed mismatch repair in Escherichia coli extracts, we have constructed a set of DNA heteroduplexes, each of which contains one of the eight possible single base pair mismatches and a single hemimethylated d(GATC) site. Although all eight mismatches were located at the same position within heteroduplex molecules and were embedded within the same sequence environment, they were not corrected with equal efficiencies in vitro. G-T was corrected most efficiently, with A-C, C-T, A-A, T-T, and G-G being repaired at rates 40-80% of that of the G-T mispair. Correction of each of these six mispairs occurred in a methyl-directed manner in a reaction requiring mutH, mutL, and mutS gene products. C-C and A-G mismatches showed different behavior. C-C was an extremely poor substrate for correction while repair of A-G was anomalous. Although A-G was corrected to A-T by the mutHLS-dependent, methyl-directed pathway, repair of A-G to C-G occurred largely by a pathway that is independent of the methylation state of the heteroduplex and which does not require mutH, mutL, or mutS gene products. Similar results were obtained with a second A-G mismatch in a different sequence environment suggesting that a novel pathway may exist for processing A-G mispairs to C-G base pairs. As judged by DNase I footprint analysis, MutS protein is capable of recognizing each of the eight possible base-base mismatches. Use of this method to estimate the apparent affinity of MutS protein for each of the mispairs revealed a rough correlation between MutS affinity and efficiency of correction by the methyl-directed pathway. However, the A-C mismatch was an exception in this respect indicating that interactions other than mismatch recognition may contribute to the efficiency of repair.     

The RecJ DNase strongly suppresses genomic integration of short but not long foreign DNA fragments by homology-facilitated illegitimate recombination during transformation of Acinetobacter baylyi

Homology-facilitated illegitimate recombination (HFIR) promotes genomic integration of foreign DNA with a single segment homologous to the recipient genome by homologous recombination in the segment accompanied by illegitimate fusion of the heterologous sequence. During natural transformation of Acinetobacter baylyi HFIR occurs at about 0.01% of the frequency of fully homologous recombination. The role of the 5' single-strand-specific exonuclease RecJ in HFIR was investigated. Deletion of recJ increased HFIR frequency about 20-fold compared with wild type while homologous recombination was not affected. Illegitimate fusion sites were predominantly located within 360 nucleotides away from the homology whereas in wild type most fusion sites were distal (500-2500 nucleotides away). RecJ overproduction reduced the HFIR frequency to half compared with wild type, and transformants with short foreign DNA segments were diminished, leading to on average 866 foreign nucleotides integrated per event (682 in wild type, 115 in recJ). In recJ always the 3' ends of donor DNA were integrated at the homology whereas in wild type these were 3' or 5'. RecJ apparently suppresses HFIR by degrading 5' non-homologous DNA tails at the post-synaptic stage. We propose that the RecJ activity level controls the HFIR frequency during transformation and the amount of foreign DNA integrated per event.     

The construction of bifunctional fusion proteins consisting of MutS and GFP

MutS as a mismatch binding protein is a promising tool for SNP detection. Green fluorescent protein (GFP) is known as an excellent reporter domain. We constructed chimeric proteins consisting of MutS from Thermus thermophilus and GFPuv from Aequorea victoria by cloning the GFPuv gene into the plasmid vectors carrying the mutS gene. The GFPuv domain fused to the N-terminus of MutS (histag-GFP-MutS) exhibited the same level of green fluorescence as free GFPuv. To obtain the fluorescing histag-GFP-MutS protein the expression at 30 degrees C was required, while free GFPuv fluoresces when expressed both at 30 and 37 degrees C. The chimeric protein where the GFPuv domain was fused to the C-terminus of MutS exhibited much weaker green fluorescence (20-25% compared with those of histag-GFP-MutS or free GFPuv). The insertion of (ProGly)5 peptide linker between the MutS and GFP domains resulted in no significant improvement in GFP fluorescence. No shifts in the excitation and emission spectra have been observed for the GFP domain in the fusion proteins. The fusion proteins with GFP at the N- and C-terminus of MutS recognised DNA mismatches similarly like T. thermophilus MutS. The fluorescent proteins recognising DNA mismatches could be useful for SNP scanning or intracellular DNA analysis. The fusion proteins around 125 kDa were efficiently expressed in E. coli and purified in milligram amounts using metal chellate affinity chromatography.     

Single-molecule multiparameter fluorescence spectroscopy reveals directional MutS binding to mismatched bases in DNA

Mismatch repair (MMR) corrects replication errors such as mismatched bases and loops in DNA. The evolutionarily conserved dimeric MMR protein MutS recognizes mismatches by stacking a phenylalanine of one subunit against one base of the mismatched pair. In all crystal structures of G:T mismatch-bound MutS, phenylalanine is stacked against thymine. To explore whether these structures reflect directional mismatch recognition by MutS, we monitored the orientation of Escherichia coli MutS binding to mismatches by FRET and anisotropy with steady state, pre-steady state and single-molecule multiparameter fluorescence measurements in a solution. The results confirm that specifically bound MutS bends DNA at the mismatch. We found additional MutS-mismatch complexes with distinct conformations that may have functional relevance in MMR. The analysis of individual binding events reveal significant bias in MutS orientation on asymmetric mismatches (G:T versus T:G, A:C versus C:A), but not on symmetric mismatches (G:G). When MutS is blocked from binding a mismatch in the preferred orientation by positioning asymmetric mismatches near the ends of linear DNA substrates, its ability to authorize subsequent steps of MMR, such as MutH endonuclease activation, is almost abolished. These findings shed light on prerequisites for MutS interactions with other MMR proteins for repairing the appropriate DNA strand.     

Differential Mismatch Recognition Specificities of Eukaryotic MutS Homologs,MutSα and MutSβ

In eukaryotes, the recognition of the DNA postreplication errors and initiation of the mismatch repair is carried out by two MutS homologs: MutSα and MutSβ. MutSα recognizes base mismatches and 1 to 2 unpaired nucleotides whereas MutSβ recognizes longer insertion-deletion loops (IDLs) with 1 to 15 unpaired nucleotides as well as certain mismatches. Results from molecular dynamics simulations of native MutSβ:IDL-containing DNA and MutSα:mismatch DNA complexes as well as complexes with swapped DNA substrates provide mechanistic insight into how the differential substrate specificities are achieved by MutSα and MutSβ, respectively. Our simulations results suggest more extensive interactions between MutSβ and IDL-DNA and between MutSα and mismatch-containing DNA that suggest corresponding differences in stability. Furthermore, our simulations suggest more expanded mechanistic details involving a different degree of bending when DNA is bound to either MutSα or MutSβ and a more likely opening of the clamp domains when noncognate substrates are bound. The simulation results also provide detailed information on key residues in MutSβ and MutSα that are likely involved in recognizing IDL-DNA and mismatch-containing DNA, respectively.     

Mechanisms of homology-facilitated illegitimate recombination for foreign DNA acquisition in transformable Pseudomonas stutzeri

Intra- and interspecific natural transformation has been observed in many prokaryotic species and is considered a fundamental mechanism for the generation of genetic variation. Recently, it has been described in detail how, in transformable Acinetobacter BD413 and Streptococcus pneumoniae, long stretches of nucleotides lacking homology were integrated into recipient genomes when they were linked on one side to a small piece of DNA with homology to resident DNA serving as a recA-dependent recombination anchor. Now, such homology-facilitated illegitimate recombination (HFIR) has also been detected in transformable Pseudomonas stutzeri. However, analysis of the recombinants revealed qualitative and quantitative differences in their generation compared with that in Acinetobacter BD413. In P. stutzeri, foreign DNA with an anchor sequence was integrated 105- to 106-fold less frequently than fully homologous DNA, but still at least 200-fold more frequently than without the anchor. The anchor sequence could be as small as 311 bp. Remarkably, in 98% of the events, the 3' end was integrated within the homologous anchor, whereas the 5' end underwent illegitimate fusion. Moreover, about one-third of the illegitimate fusion sites shared no or only a single identical basepair in foreign and resident DNA. The other fusions occurred within microhomologies of up to 6 bp with a higher GC content on average than the interacting nucleotide sequences. Foreign DNA of 69-1903 bp was integrated, and resident DNA of 22-2345 bp was lost. In a recA mutant, HFIR was not detectable. The findings suggest that genomic acquisition of foreign DNA by HFIR during transformation occurs widely in prokaryotes, but that details of the required recombination and strand fusion mechanisms may differ between organisms from different genera.     

Role of the 5´ → 3´ exonuclease and Klenow fragment of <Emphasis Type="Italic">Escherichia coli</Emphasis> DNA polymerase I in base mismatch repair

We have previously demonstrated that the Escherichia coli strain mutS ΔpolA had a higher rate of transition and minus frameshift mutations than mutS or ΔpolA strains. We argued that DNA polymerase I (PolI) corrects transition mismatches. PolI, encoded by the polA gene, possesses Klenow and 5′ → 3′ exonuclease domains. In the present study, rates of mutation were found to be higher in Klenow-defective mutS strains and 5′ → 3′ exonuclease-defective mutS strains than mutS or polA strains. The Klenow-defective or 5′ → 3′ exonuclease-defective mutS strains showed a marked increase in transition mutations. Sites of transition mutations in mutS, Klenow-defective mutS and 5′ → 3′ exonuclease-defective mutS strains are different. Thus, it is suggested that, in addition to mutS function, both the Klenow and 5′ → 3′ exonuclease domains are involved in the decrease of transition mutations. Transition hot and warm spots in mutS ⁺ polA ⁺ strains were found to differ from those in mutS and mutS ΔpolA strains. We thus argue that all the spontaneous transition mutations in the wild-type strain do not arise from transition mismatches left unrepaired by the MutS system or MutS PolI system.     

Functional characterization of the DNA mismatch binding protein MutS from Haemophilus influenzae

This investigation demonstrates DNA mismatch repair activity in Haemophilus influenzae cell free extracts. The mutS gene as well as purified protein of H. influenzae restored repair activity in complementation assays performed with mutS deficient Escherichia coli strain. The difference in affinity for GT and AC mismatched bases by H. influenzae MutS was reflected in the efficiency with which these DNA heteroduplexes were repaired in vitro, with GT being repaired well and AC the least. Unlike E. coli MutS, the H. influenzae homolog failed to give protein-DNA complex with homoduplex DNA. Interestingly, MutS was found to bind single-stranded DNA but with lesser affinity as compared to heteroduplex DNA. Apart from the nucleotide- and DNA-mediated conformational transitions, as monitored by circular dichroism and limited proteolysis, our data suggest a functional role when H. influenzae MutS encounters single-stranded DNA during exonucleolytic step of DNA repair process. We propose that, conformational changes in H. influenzae MutS not only modulate mismatch recognition but also trigger some of the down stream processes involved in the DNA mismatch repair process.     

The Helicobacter pylori MutS protein confers protection from oxidative DNA damage

The human gastric pathogenic bacterium Helicobacter pylori lacks a MutSLH-like DNA mismatch repair system. Here, we have investigated the functional roles of a mutS homologue found in H. pylori, and show that it plays an important physiological role in repairing oxidative DNA damage. H. pylori mutS mutants are more sensitive than wild-type cells to oxidative stress induced by agents such as H2O2, paraquat or oxygen. Exposure of mutS cells to oxidative stress results in a significant ( approximately 10-fold) elevation of mutagenesis. Strikingly, most mutations in mutS cells under oxidative stress condition are G:C to T:A transversions, a signature of 8-oxoguanine (8-oxoG). Purified H. pylori MutS protein binds with a high specific affinity to double-stranded DNA (dsDNA) containing 8-oxoG as well as to DNA Holliday junction structures, but only weakly to dsDNA containing a G:A mismatch. Under oxidative stress conditions, mutS cells accumulate higher levels (approximately threefold) of 8-oxoG DNA lesions than wild-type cells. Finally, we observe that mutS mutant cells have reduced colonization capacity in comparison to wild-type cells in a mouse infection model.     

Reduction of GC --> TA transversion mutation by overexpression of MutS in Escherichia coli K-12

Overexpression of the MutS repair protein significantly decreased the rate of lacZ GC --> TA transversion mutation in stationary-phase and exponentially growing bacteria and in mutY and mutM mutants, which accumulate mismatches between 8-oxoguanine (8-oxoG) and adenine residues in DNA. Conversely, GC --> TA transversion increased in mutL or mutS mutants in stationary phase. In contrast, overexpression of MutS did not appreciably reduce lacZ AT --> CG transversion mutation in a mutT mutant. These results suggest that MutS-dependent repair can correct 8-oxoG:A mismatches in Escherichia coli cells but may not be able to compete with mutation fixation by MutY in mutT mutants.     

Mismatch repair genes of Streptococcus pneumoniae: HexA confers a mutator phenotype in Escherichia coli by negative complementation.

DNA repair systems able to correct base pair mismatches within newly replicated DNA or within heteroduplex molecules produced during recombination are widespread among living organisms. Evidence that such generalized mismatch repair systems evolved from a common ancestor is particularly strong for two of them, the Hex system of the gram-positive Streptococcus pneumoniae and the Mut system of the gram-negative Escherichia coli and Salmonella typhimurium. The homology existing between HexA and MutS and between HexB and MutL prompted us to investigate the effect of expressing hex genes in E. coli. Complementation of mutS or mutL mutations, which confer a mutator phenotype, was assayed by introducing on a multicopy plasmid the hexA and hexB genes, under the control of an inducible promoter, either individually or together in E. coli strains. No decrease in mutation rate was conferred by either hexA or hexB gene expression. However, a negative complementation effect was observed in wild-type E. coli cells: expression of hexA resulted in a typical Mut- mutator phenotype. hexB gene expression did not increase the mutation rate either individually or in conjunction with hexA. Since expression of hexA did not affect the mutation rate in mutS mutant cells and the hexA-induced mutator effect was recA independent, it is concluded that this effect results from inhibition of the Mut system. We suggest that HexA, like its homolog MutS, binds to mismatches resulting from replication errors, but in doing so it protects them from repair by the Mut system. In agreement with this hypothesis, an increase in mutS gene copy number abolished the hexA-induced mutator phenotype. HexA protein could prevent repair either by being unable to interact with Mut proteins or by producing nonfunctional repair complexes.     

Structural and functional divergence of MutS2 from bacterial MutS1 and eukaryotic MSH4-MSH5 homologs

MutS homologs, identified in nearly all bacteria and eukaryotes, include the bacterial proteins MutS1 and MutS2 and the eukaryotic MutS homologs 1 to 7, and they often are involved in recognition and repair of mismatched bases and small insertion/deletions, thereby limiting illegitimate recombination and spontaneous mutation. To explore the relationship of MutS2 to other MutS homologs, we examined conserved protein domains. Fundamental differences in structure between MutS2 and other MutS homologs suggest that MutS1 and MutS2 diverged early during evolution, with all eukaryotic homologs arising from a MutS1 ancestor. Data from MutS1 crystal structures, biochemical results from MutS2 analyses, and our phylogenetic studies suggest that MutS2 has functions distinct from other members of the MutS family. A mutS2 mutant was constructed in Helicobacter pylori, which lacks mutS1 and mismatch repair genes mutL and mutH. We show that MutS2 plays no role in mismatch or recombinational repair or deletion between direct DNA repeats. In contrast, MutS2 plays a significant role in limiting intergenomic recombination across a range of donor DNA tested. This phenotypic analysis is consistent with the phylogenetic and biochemical data suggesting that MutS1 and MutS2 have divergent functions.     

DNA错配修复基因mutS的高效表达及表达产物活性鉴定

将DNA错配修复基因mutS(2.56kb)克隆于分泌型原核表达载体pET32a( )上,以N端融合6个组氨酸的形式在E.col AD494(DE3)中进行了IPTG诱导表达。SDS－PAGE分析证实有一与预期分子量相应的诱导表达条带,其表达量占全菌蛋白质的35％左右,且表达蛋白以可溶形式存在。利用固定化金属离子（Ni^2 )配体亲和层析柱纯化目的蛋白,其纯度为90％以上。与含有错配碱基DNA双链的结合反应证明该蛋白具有特异性识别,结合含有错配碱基DNA双链的生物活性。     

Mechanism of MutS searching for DNA mismatches and signaling repair

DNA mismatch repair is initiated by the recognition of mismatches by MutS proteins. The mechanism by which MutS searches for and recognizes mismatches and subsequently signals repair remains poorly understood. We used single-molecule analyses of atomic force microscopy images of MutS-DNA complexes, coupled with biochemical assays, to determine the distributions of conformational states, the DNA binding affinities, and the ATPase activities of wild type and two mutants of MutS, with alanine substitutions in the conserved Phe-Xaa-Glu mismatch recognition motif. We find that on homoduplex DNA, the conserved Glu, but not the Phe, facilitates MutS-induced DNA bending, whereas at mismatches, both Phe and Glu promote the formation of an unbent conformation. The data reveal an unusual role for the Phe residue in that it promotes the unbending, not bending, of DNA at mismatch sites. In addition, formation of the specific unbent MutS-DNA conformation at mismatches appears to be required for the inhibition of ATP hydrolysis by MutS that signals initiation of repair. These results provide a structural explanation for the mechanism by which MutS searches for and recognizes mismatches and for the observed phenotypes of mutants with substitutions in the Phe-Xaa-Glu motif.     

Interaction between Mismatch Repair and Genetic Recombination in Saccharomyces Cerevisiae

The yeast Saccharomyces cerevisiae encodes a set of genes that show strong amino acid sequence similarity to MutS and MutL, proteins required for mismatch repair in Escherichia coli. We examined the role of MSH2 and PMS1, yeast homologs of mutS and mutL, respectively, in the repair of base pair mismatches formed during meiotic recombination. By using specifically marked HIS4 and ARG4 alleles, we showed that msh2 mutants displayed a severe defect in the repair of all base pair mismatches as well as 1-, 2- and 4-bp insertion/deletion mispairs. The msh2 and pms1 phenotypes were indistinguishable, suggesting that the wild-type gene products act in the same repair pathway. A comparison of gene conversion events in wild-type and msh2 mutants indicated that mismatch repair plays an important role in genetic recombination. (1) Tetrad analysis at five different loci revealed that, in msh2 mutants, the majority of aberrant segregants displayed a sectored phenotype, consistent with a failure to repair mismatches created during heteroduplex formation. In wild type, base pair mismatches were almost exclusively repaired toward conversion rather than restoration. (2) In msh2 strains 10-19% of the aberrant tetrads were Ab4:4. (3) Polarity gradients at HIS4 and ARG4 were nearly abolished in msh2 mutants. The frequency of gene conversion at the 3' end of these genes was increased and was nearly the frequency observed at the 5' end. (4) Co-conversion studies were consistent with mismatch repair acting to regulate heteroduplex DNA tract length. We favor a model proposing that recombination events occur through the formation and resolution of heteroduplex intermediates and that mismatch repair proteins specifically interact with recombination enzymes to regulate the length of symmetric heteroduplex DNA.     

MutS recognition: Multiple mismatches and sequence context effects

Escherichia coli MutS is a versatile repair protein that specifically recognizes not only various types of mismatches but also single stranded loops of up to 4 nucleotides in length. Specific binding, followed by the next step of tracking the DNA helix that locates hemi-methylated sites, is regulated by the conformational state of the protein as a function of ATP binding/hydrolysis. Here, we study how various molecular determinants of a heteroduplex regulate mismatch recognition by MutS, the critical first step of mismatch repair. Using classical DNase I footprinting assays, we demonstrate that the hierarchy of MutS binding to various types of mismatches is identical whether the mismatches are present singly or in multiples. Moreover, this unique hierarchy is indifferent both to the differential level of DNA helical flexibility and to the unpaired status of the mismatched bases in a heteroduplex. Surprisingly, multiple mismatches exhibit reduced affinity of binding to MutS, compared to that of a similar single mismatch. Such a reduction in the affinity might be due to sequence context effects, which we established more directly by studying two identical single mismatches in an altered sequence background. A mismatch, upon simply being flipped at the same location, elicits changes in MutS specific contacts, thereby underscoring the importance of sequence context in modulating MutS binding to mismatches.     

Alpha-shaped DNA loops induced by MutS

DNA mismatch repair (MMR) is critical for the maintenance of genomic stability. MMR is initiated by recognition of DNA mismatches by the protein, MutS, which subsequently recruits downstream repair factors. To better understand the mechanism by which MutS identifies and specifically binds mismatched basepairs embedded in random DNA sequences, we monitored the interaction between MutS and DNA substrates using atomic force microscopy (AFM). An α-shaped DNA loop formed by the interaction between MutS and DNA, which was independent of whether or not a mismatch was present in the DNA substrate. These data indicate that MutS associates with DNA non-specifically and forms an α-loop interaction with the DNA substrate. In this conformation, MutS is able to scan two arms of DNA simultaneously for each MutS dimer formed.