Partial reconstitution of DNA large loop repair with purified proteins from Saccharomyces cerevisiae

Small looped mispairs are corrected by DNA mismatch repair. In addition, a distinct process called large loop repair (LLR) corrects heteroduplexes up to several hundred nucleotides in bacteria, yeast and human cells, and in cell-free extracts. Only some LLR protein components are known, however. Previous studies with neutralizing antibodies suggested a role for yeast DNA polymerase δ (Pol δ), RFC and PCNA in LLR repair synthesis. In the current study, biochemical fractionation studies identified FEN1 (Rad27) as another required LLR component. In the presence of purified FEN1, Pol δ, RFC and PCNA, repair occurred on heteroduplexes with loops ranging from 8 to 216 nt. Repair utilized a 5′ nick, with correction directed to the nicked strand, irrespective of which strand contained the loop. In contrast, repair of a G/T mismatch occurred at low levels, suggesting specificity of the reconstituted system for looped mispairs. The presence of RPA enhanced reactivity on some looped substrates, but RPA was not required for activity. Although additional LLR factors remain to be identified, the excision and resynthesis steps of LLR from a 5′ nick can be reconstituted in a purified system with FEN1 and Pol δ, together with PCNA and its loader RFC.     

DNA polymerase delta, RFC and PCNA are required for repair synthesis of large looped heteroduplexes in Saccharomyces cerevisiae

Small looped mispairs are corrected by DNA mismatch repair (MMR). In addition, a distinct process called large loop repair (LLR) corrects loops up to several hundred nucleotides in extracts of bacteria, yeast or human cells. Although LLR activity can be readily demonstrated, there has been little progress in identifying its protein components. This study identified some of the yeast proteins responsible for DNA repair synthesis during LLR. Polyclonal antisera to either Pol31 or Pol32 subunits of polymerase δ efficiently inhibited LLR in extracts by blocking repair just prior to gap filling. Gap filling was inhibited regardless of whether the loop was retained or removed. These experiments suggest polymerase δ is uniquely required in yeast extracts for LLR-associated synthesis. Similar results were obtained with antisera to the clamp loader proteins Rfc3 and Rfc4, and to PCNA, i.e. LLR was inhibited just prior to gap filling for both loop removal and loop retention. Thus PCNA and RFC seem to act in LLR only during repair synthesis, in contrast to their roles at both pre- and post-excision steps of MMR. These biochemical experiments support the idea that yeast polymerase δ, RFC and PCNA are required for large loop DNA repair synthesis.     

The Prevention of Repeat-Associated Deletions in Saccharomyces Cerevisiae by Mismatch Repair Depends on Size and Origin of Deletions

We have investigated the effects of mismatch repair on 1- to 61-bp deletions in the yeast Saccharomyces cerevisiae. The deletions are likely to involve unpaired loop intermediates resulting from DNA polymerase slippage. The mutator effects of mutations in the DNA polymerase δ (POL3) gene and the recombinational repair RAD52 gene were studied in combination with mismatch repair defects. The pol3-t mutation increased up to 1000-fold the rate of extended (7-61 bp) but not of 1-bp deletions. In a rad52 null mutant only the 1-bp deletions were increased (12-fold). The mismatch repair mutations pms1, msh2 and msh3 did not affect 31- and 61-bp deletions in the pol3-t but increased the rates of 7- and 1-bp deletions. We propose that loops less than or equal to seven bases generated during replication are subject to mismatch repair by the PMS1, MSH2, MSH3 system and that it cannot act on loops >=31 bases. In contrast to the pol3-t, the enhancement of 1-bp deletions in a rad52 mutant is not altered by a pms1 mutation. Thus, mismatch repair appears to be specific to errors of DNA synthesis generated during semiconservative replication.     

Efficient repair of A/C mismatches in mouse cells deficient in long-patch mismatch repair

A previously unrecognized mismatch repair activity is described. Extracts of immortalized MSH2-deficient mouse fibroblasts did not correct most single base mispairs. The same extracts carried out efficient repair of A/C mismatches. A/G mispairs were less efficiently corrected and there was no significant repair of A/A. MLH1-defective mouse extracts also repaired an A/C mispair. A/C correction by Msh2(-/-) mouse cell extracts was not affected by antibodies against the PMS2 protein, which inhibited long-patch mismatch repair. A/C repair activity is thus independent of MutSalpha, MutSbeta and MutLalpha. A/C mismatches were corrected 5-fold more efficiently by extracts of Msh2 knockout mouse cells than by comparable extracts prepared from hMSH2- or hMLH1-deficient human cells. MSH2-independent A/C correction by mouse cell extracts did not require a nick in the circular duplex DNA substrate. Repair involved replacement of the A and was associated with the resynthesis of a limited stretch of 相似文献   

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

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

Novel PMS1 alleles preferentially affect the repair of primer strand loops during DNA replication

Null mutations in DNA mismatch repair (MMR) genes elevate both base substitutions and insertions/deletions in simple sequence repeats. Data suggest that during replication of simple repeat sequences, polymerase slippage can generate single-strand loops on either the primer or template strand that are subsequently processed by the MMR machinery to prevent insertions and deletions, respectively. In the budding yeast Saccharomyces cerevisiae and mammalian cells, MMR appears to be more efficient at repairing mispairs comprised of loops on the template strand compared to loops on the primer strand. We identified two novel yeast pms1 alleles, pms1-G882E and pms1-H888R, which confer a strong defect in the repair of "primer strand" loops, while maintaining efficient repair of "template strand" loops. Furthermore, these alleles appear to affect equally the repair of 1-nucleotide primer strand loops during both leading- and lagging-strand replication. Interestingly, both pms1 mutants are proficient in the repair of 1-nucleotide loop mispairs in heteroduplex DNA generated during meiotic recombination. Our results suggest that the inherent inefficiency of primer strand loop repair is not simply a mismatch recognition problem but also involves Pms1 and other proteins that are presumed to function downstream of mismatch recognition, such as Mlh1. In addition, the findings reinforce the current view that during mutation avoidance, MMR is associated with the replication apparatus.     

Efficient repair of large DNA loops in Saccharomyces cerevisiae

Small looped mispairs are efficiently corrected by mismatch repair. The situation with larger loops is less clear. Repair activity on large loops has been reported as anywhere from very low to quite efficient. There is also uncertainty about how many loop repair activities exist and whether any are conserved. To help address these issues, we studied large loop repair in Saccharomyces cerevisiae using in vivo and in vitro assays. Transformation of heteroduplexes containing 1, 16 or 38 nt loops led to >90% repair for all three substrates. Repair of the 38 base loop occurred independently of mutations in key genes for mismatch repair (MR) and nucleotide excision repair (NER), unlike other reported loop repair functions in yeast. Correction of the 16 base loop was mostly independent of MR, indicating that large loop repair predominates for this size heterology. Similarities between mammalian and yeast large loop repair were suggested by the inhibitory effects of loop secondary structure and by the role of defined nicks on the relative proportions of loop removal and loop retention products. These observations indicate a robust large loop repair pathway in yeast, distinct from MR and NER, and conserved in mammals.     

Construction and characterization of mismatch-containing circular DNA molecules competent for assessment of nick-directed human mismatch repair in vitro

The ability of cell-free extracts to correct DNA mismatches has been demonstrated in both prokaryotes and eukaryotes. Such an assay requires a template containing both a mismatch and a strand discrimination signal, and the multi-step construction process can be technically difficult. We have developed a three-step procedure for preparing DNA heteroduplexes containing a site-specific nick. The mismatch composition, sequence context, distance to the strand signal, and the means for assessing repair in each strand are adjustable features built into a synthetic oligonucleotide. Controlled ligation events involving three of the four DNA strands incorporate the oligonucleotide into a circular template and generate the repair-directing nick. Mismatch correction in either strand of a prototype G·T mismatch was achieved by placing a nick 10–40 bp away from the targeted base. This proximity of nick and mismatch represents a setting where repair has not been well characterized, but the presence of a nick was shown to be essential, as was the MSH2/MSH6 heterodimer, although low levels of repair occurred in extract defective in each protein. All repair events were inhibited by a peptide that interacts with proliferating cell nuclear antigen and inhibits both mismatch repair and long-patch replication.     

Isolation and Characterization of Point Mutations in Mismatch Repair Genes That Destabilize Microsatellites in Yeast

The stability of simple repetitive DNA sequences (microsatellites) is a sensitive indicator of the ability of a cell to repair DNA mismatches. In a genetic screen for yeast mutants with elevated microsatellite instability, we identified strains containing point mutations in the yeast mismatch repair genes, MSH2, MSH3, MLH1, and PMS1. Some of these mutations conferred phenotypes significantly different from those of null mutations in these genes. One semidominant MSH2 mutation was identified. Finally we showed that strains heterozygous for null mutations of mismatch repair genes in diploid strains in yeast confer subtle defects in the repair of small DNA loops.     

Mismatch repair in human nuclear extracts: effects of internal DNA-hairpin structures between mismatches and excision-initiation nicks on mismatch correction and mismatch-provoked excision

DNA mismatch repair (MMR) couples recognition of base mispairs by MSH2.MSH6 heterodimers to initiation, hundreds of nucleotides away, of nascent strand 3'-5' or 5'-3' excision through the mispair. Mismatch-recognition complexes have been hypothesized to move along DNA to excision-initiation signals, in eukaryotes, perhaps ends of nascent DNA, or to remain at mismatches and search through space for initiation signals. Subsequent MMR excision, whether simple processive digestion of the targeted strand or tracking of an excision complex, remains poorly understood. In human cell-free extracts, we analyzed correction of a mismatch in a 2.2-kilobase pair (kbp) circular plasmid containing a pre-existing excision-initiation nick for initiation, and measured MMR excision (in the absence of exogenous dNTPs) at specific locations. Excision specificities were approximately 100:1 for nicked versus continuous strands, 80:1 for mismatched versus homoduplex DNA, and 30:1 for shorter (0.3-kbp) versus longer (1.9-kbp) nick-mispair paths. To test models for recognition-excision coupling and excision progress, we inserted potential blockades, 20-bp hairpins, into nick-mispair paths, using a novel technique to first generate gapped plasmid. Continuous strand longer-path hairpins did not affect mismatch correction, but shorter-path hairpins reduced correction 4-fold, and both together eliminated it. Shorter-path hairpins had little effect on initiation of (3'-5') excision, measured 30-60 nucleotides 5' to the nick, but blocked subsequent progress of excision to the mismatch; longer-path hairpins blocked the (lower level) 5'-3' excision to the mismatch. Thus, (a) MMR excision protein(s) cannot move past DNA hairpins. Hairpins at both ends of substrate-derived 0.5-kbp DNA fragments did not prevent ATP-induced dissociation of mismatch-bound human MSH2.MSH6, so recognition complexes at mismatches might provoke excision at nicks beyond hairpins, or loosely sliding MSH2.MSH6 dimers might move to the nicks.     

DNA loop repair by Escherichia coli cell extracts

The nick-directed DNA repair efficiency of a set of M13mp18-derived heteroduplexes containing 8-, 12-, 16-, 22-, 27-, 45-, and 429-nucleotide loops was determined by in vitro assay. Unpaired nucleotides of each heteroduplex reside within overlapping recognition sites for two restriction endonucleases, permitting independent evaluation of repair occurring on either DNA strand. Our results show that a strand break located either 3' or 5' to the loop is sufficient to direct heterology repair to the nicked strand in Escherichia coli extracts. Strand-specific repair by this system requires Mg2+ and the four dNTPs and is equally efficient on insertions and deletions. This activity is distinct from the MutHLS mismatch repair pathway. Strand specificity and repair efficiency are largely independent of the GATC methylation state of the DNA and presence of the products of mismatch repair genes mutH, mutL, and mutS. This study provides evidence for a loop repair pathway in E. coli that is distinct from conventional mismatch repair.     

Characterization of palindromic loop mismatch repair tracts in mammalian cells

Single- and multi-base (loop) mismatches can arise in DNA by replication errors, during recombination, and by chemical modification of DNA. Single-base and loop mismatches of several nucleotides are efficiently repaired in mammalian cells by a nick-directed, MSH2-dependent mechanism. Larger loop mismatches (> or =12 bases) are repaired by an MSH2-independent mechanism. Prior studies have shown that 12- and 14-base palindromic loops are repaired with bias toward loop retention, and that repair bias is eliminated when five single-base mismatches flank the loop mismatch. Here we show that one single-base mismatch near a 12-base palindromic loop is sufficient to eliminate loop repair bias in wild-type, but not MSH2-defective mammalian cells. We also show that palindromic loop and single-base mismatches separated by 12 bases are repaired independently at least 10% of the time in wild-type cells, and at least 30% of the time in MSH2-defective cells. Palindromic loop and single-base mismatches separated by two bases were never repaired independently. These and other data indicate that loop repair tracts are variable in length. All tracts extend at least 2 bases, some extend <12 bases, and others >12 bases, on one side of the loop. These properties distinguish palindromic loop mismatch repair from the three known excision repair pathways: base excision repair which has one to six base tracts, nucleotide excision repair which has approximately 30 base tracts, and MSH2-dependent mismatch repair, which has tracts that extend for several hundred bases.     

Molecular cloning of zebrafish (Danio rerio) MutS homolog 6(MSH6) and noncoordinate expression of MSH6 gene activity and G-T mismatch binding proteins in zebrafish larvae

Eukaryotic MutS homolog 6(MSH6) is a DNA mismatch recognition protein associated with mismatch repair of simple base-base mispairs and small insertion-deletion loops. As replication or recombination errors generated during embryonic development of living organisms should be efficiently corrected to maintain the integrity of genetic materials, we attempted to study MSH6 gene expression in developing zebrafish (Danio rerio) and the influence of MSH6 expression on the production of mismatch binding factors. A full-length cDNA encoding zebrafish MSH6 (zMSH6) was first obtained by rapid amplification of cDNA ends (RACE). The deduced amino acid sequence of zMSH6 shares 57% and 56% identity with human and mouse MSH6, respectively. The 190-kDa recombinant zMSH6 containing 1,369 amino acids bound preferentially to a heteroduplex than to a homoduplex DNA. Northern blot and semiquantitative RT-PCR analysis detected apparent levels of zMSH6 mRNA expression in 12 and 36-hr-old zebrafish embryos, while this expression in 84-hr-old larvae was dramatically reduced to 23% of that in 12-hr-old embryos when beta-actin mRNA was constitutively synthesized. Incubation of G-T and G-G heteroduplex probes with 12 to 60-hr-old zebrafish extracts produced predominantly high-shifting binding complexes with very similar band intensity. Although low in zMSH6 mRNA production, the extracts of 84-hr-old larvae interacted significantly stronger than the embryonic extracts with both G-T and G-G mispairs, producing high and low-shifting complexes. Heteroduplex-recognition proteins in 108-hr-old larvae gave a similar pattern of mismatch binding. The intensities of G-T complexes produced by 84 and 108-hr-old zebrafish extracts were 2.5 to 3-fold higher than those of G-G complexes. Our data indicate that the production of efficient MSH6-independent binding factors, particularly G-T-specific recognition proteins, is upregulated in zebrafish at the larval stage when MSH6 gene activity is downregulated.     

Bi-directional processing of DNA loops by mismatch repair-dependent and -independent pathways in human cells

Previous work has shown that small DNA loop heterologies are repaired not only through the mismatch repair (MMR) pathway but also via an MMR-independent pathway in human cells. However, how DNA loop repair is partitioned between these pathways and how the MMR-independent repair is processed are not clear. Using a novel construct that completely and specifically inhibits MMR in HeLa extracts, we demonstrate here that although MMR is capable of bi-directionally processing DNA loops of 2, 4, 5, 8, 10, or 12 nucleotides in length, the repair activity decreases with the increase of the loop size. Evidence is presented that the largest loop that the MMR system can process is 16 nucleotides. We also show that strand-specific MMR-independent loop repair occurs for all looped substrates tested and rigorously demonstrate that this repair is bi-directional. Analysis of repair intermediates generated by the MMR-independent pathway revealed that although the processing of looped substrates with a strand break 5' to the heterology occurred similarly to MMR (i.e. excision is conducted by exonucleases from the pre-existing strand break to the heterology), the processing of the heterology in substrates with a 3' strand break is consistent with the involvement of endonucleases.     

Analysis of yeast MSH2-MSH6 suggests that the initiation of mismatch repair can be separated into discrete steps

The yeast MSH2-MSH6 complex is required to repair both base-pair and single base insertion/deletion mismatches. MSH2-MSH6 binds to mismatch substrates and displays an ATPase activity that is modulated by mispairs that are repaired in vivo. To understand early steps in mismatch repair, we analyzed mismatch repair (MMR) defective MSH2-msh6-F337A and MSH2-msh6-340 complexes that contained amino acid substitutions in the MSH6 mismatch recognition domain. While both heterodimers were defective in forming stable complexes with mismatch substrates, only MSH2-msh6-340 bound to homoduplex DNA with an affinity that was similar to that observed for MSH2-MSH6. Additional analyses suggested that stable binding to a mispair is not sufficient to initiate recruitment of downstream repair factors. Previously, we observed that MSH2-MSH6 forms a stable complex with a palindromic insertion mismatch that escapes correction by MMR in vivo. Here we show that this binding is not accompanied by either a modulation in MSH2-MSH6 ATPase activity or an ATP-dependent recruitment of the MLH1-PMS1 complex. Together, these observations suggest that early stages in MMR can be divided into distinct recognition, stable binding, and downstream factor recruitment steps.     

DNA mismatch repair and mutation avoidance pathways

Unpaired and mispaired bases in DNA can arise by replication errors, spontaneous or induced base modifications, and during recombination. The major pathway for correction of mismatches arising during replication is the MutHLS pathway of Escherichia coli and related pathways in other organisms. MutS initiates repair by binding to the mismatch, and activates together with MutL the MutH endonuclease, which incises at hemimethylated dam sites and thereby mediates strand discrimination. Multiple MutS and MutL homologues exist in eukaryotes, which play different roles in the mismatch repair (MMR) pathway or in recombination. No MutH homologues have been identified in eukaryotes, suggesting that strand discrimination is different to E. coli. Repair can be initiated by the heterodimers MSH2-MSH6 (MutSalpha) and MSH2-MSH3 (MutSbeta). Interestingly, MSH3 (and thus MutSbeta) is missing in some genomes, as for example in Drosophila, or is present as in Schizosaccharomyces pombe but appears to play no role in MMR. MLH1-PMS1 (MutLalpha) is the major MutL homologous heterodimer. Again some, but not all, eukaryotes have additional MutL homologues, which all form a heterodimer with MLH1 and which play a minor role in MMR. Additional factors with a possible function in eukaryotic MMR are PCNA, EXO1, and the DNA polymerases delta and epsilon. MMR-independent pathways or factors that can process some types of mismatches in DNA are nucleotide-excision repair (NER), some base excision repair (BER) glycosylases, and the flap endonuclease FEN-1. A pathway has been identified in Saccharomyces cerevisiae and human that corrects loops with about 16 to several hundreds of unpaired nucleotides. Such large loops cannot be processed by MMR.     

Nick-dependent and -independent processing of large DNA loops in human cells

DNA loop heterologies are products of normal DNA metabolism and can lead to severe genomic instability if unrepaired. To understand how human cells process DNA loop structures, a set of circular heteroduplexes containing a 30-nucleotide loop were constructed and tested for repair in vitro by human cell nuclear extracts. We demonstrate here that, in addition to the previously identified 5' nick-directed loop repair pathway (Littman, S. J., Fang, W. H., and Modrich, P. (1999) J. Biol. Chem. 274, 7474-7481), human cells can process large DNA loop heterologies in a loop-directed manner. The loop-directed repair specifically removes the loop structure and occurs only in the looped strand, and appears to require limited DNA synthesis. Like the nick-directed loop repair, the loop-directed repair is independent of many known DNA repair pathways, including DNA mismatch repair and nucleotide excision repair. In addition, our data also suggest that an aphidicolin-sensitive DNA polymerase is involved in the excision step of the nick-directed loop repair pathway.     

DNA Mismatch Repair Catalyzed by Extracts of Mitotic, Postmitotic, and Senescent Drosophila Tissues and Involvement of mei-9 Gene Function for Full Activity

Extracts of Drosophila embryos and adults have been found to catalyze highly efficient DNA mismatch repair, as well as repair of 1- and 5-bp loops. For mispairs T · G and G · G, repair is nick dependent and is specific for the nicked strand of heteroduplex DNA. In contrast, repair of A · A, C · A, G · A, C · T, T · T, and C · C is not nick dependent, suggesting the presence of glycosylase activities. For nick-dependent repair, the specific activity of embryo extracts was similar to that of extracts derived from the entirely postmitotic cells of young and senescent adults. Thus, DNA mismatch repair activity is expressed in Drosophila cells during both development and aging, suggesting that there may be a function or requirement for mismatch repair throughout the Drosophila life span. Nick-dependent repair was reduced in extracts of animals mutant for the mei-9 gene. mei-9 has been shown to be required in vivo for certain types of DNA mismatch repair, nucleotide excision repair (NER), and meiotic crossing over and is the Drosophila homolog of the yeast NER gene rad1.     

Repair of large insertion/deletion heterologies in human nuclear extracts is directed by a 5' single-strand break and is independent of the mismatch repair system

The repair of 12-, 27-, 62-, and 216-nucleotide unpaired insertion/deletion heterologies has been demonstrated in nuclear extracts of human cells. When present in covalently closed circular heteroduplexes or heteroduplexes containing a single-strand break 3' to the heterology, such structures are subject to a low level repair reaction that occurs with little strand bias. However, the presence of a single-strand break 5' to the insertion/deletion heterology greatly increases the efficiency of rectification and directs repair to the incised DNA strand. Because nick direction of repair is independent of the strand in which a particular heterology is placed, the observed strand bias is not due to asymmetry imposed on the heteroduplex by the extrahelical DNA segment. Strand-specific repair by this system requires ATP and the four dNTPs and is inhibited by aphidicolin. Repair is independent of the mismatch repair proteins MSH2, MSH6, MLH1, and PMS2 and occurs by a mechanism that is distinct from that of the conventional mismatch repair system. Large heterology repair in nuclear extracts of human cells is also independent of the XPF gene product, and extracts of Chinese hamster ovary cells deficient in the ERCC1 and ERCC4 gene products also support the reaction.     

Gap formation is associated with methyl-directed mismatch correction under conditions of restricted DNA synthesis

A covalently closed, circular heteroduplex containing a G-T mismatch and a single hemimethylated d(GATC) site is subject to efficient methyl-directed mismatch correction in Escherichia coli extracts when repair DNA synthesis is severely restricted by limiting the concentration of exogenously supplied deoxyribonucleoside-5'-triphosphates or by supplementing reactions with chain-terminating 2',3'-dideoxynucleoside triphosphates. However, repair under these conditions results in formation of a single-strand gap in the region of the molecule containing the mismatch and the d(GATC) site. These findings indicate that repair DNA synthesis required for methyl-directed correction can initiate in the vicinity of the mispair, and they are most consistent with a repair reaction involving 3'----5' excision (or strand displacement) from the d(GATC) site followed by 5'----3' repair DNA synthesis initiating in the vicinity of the mismatch.