Transformation with oligonucleotides creating clustered changes in the yeast genome

We have studied single-strand oligonucleotide (oligo) transformation of yeast by using 40-nt long oligos that create multiple base changes to the yeast genome spread throughout the length of the oligos, making it possible to measure the portions of an oligo that are incorporated during transformation. Although the transformation process is greatly inhibited by DNA mismatch repair (MMR), the pattern of incorporation is essentially the same in the presence or absence of MMR, whether the oligo anneals to the leading or lagging strand of DNA replication, or whether phosphorothioate linkages are used at either end. A central core of approximately 15 nt is incorporated with a frequency of >90%; the ends are incorporated with a lower frequency, and loss of the two ends appears to be by different mechanisms. Bases that are 5-10 nt from the 5' end are generally lost with a frequency of >95%, likely through a process involving flap excision. On the 3' end, bases 5-10 nt from the 3' end are lost about 1/3 of the time. These results indicate that oligos can be used to create multiple simultaneous changes to the yeast genome, even in the presence of MMR.     

Conditional DNA repair mutants enable highly precise genome engineering

Oligonucleotide-mediated multiplex genome engineering is an important tool for bacterial genome editing. The efficient application of this technique requires the inactivation of the endogenous methyl-directed mismatch repair system that in turn leads to a drastically elevated genomic mutation rate and the consequent accumulation of undesired off-target mutations. Here, we present a novel strategy for mismatch repair evasion using temperature-sensitive DNA repair mutants and temporal inactivation of the mismatch repair protein complex in Escherichia coli. Our method relies on the transient suppression of DNA repair during mismatch carrying oligonucleotide integration. Using temperature-sensitive control of methyl-directed mismatch repair protein activity during multiplex genome engineering, we reduced the number of off-target mutations by 85%, concurrently maintaining highly efficient and unbiased allelic replacement.     

Mismatch repair in human nuclear extracts. Quantitative analyses of excision of nicked circular mismatched DNA substrates,constructed by a new technique employing synthetic oligonucleotides

Mammalian mismatch repair (MMR) systems respond to broad ranges of DNA mismatches and lesions. Kinetic analyses of MMR processing in vitro have focused on base mismatches in a few sequence contexts, because of a lack of general and quantitative MMR assays and because of the difficulty of constructing a multiplicity of MMR substrates, particularly those with DNA lesions. We describe here simple and efficient construction of 11 different MMR substrates, by ligating synthetic oligomers into gapped plasmids generated using sequence-specific N.BstNBI nicking endonuclease, then using sequence-specific nicking endonuclease N.AlwI to introduce single nicks for initiation of 3' to 5' or 5' to 3' excision. To quantitatively assay MMR excision gaps in base-mispaired substrates, generated in human nuclear extracts lacking exogenous dNTPs, we used position- and strand-specific oligomer probes. Mispair-provoked excision along the shorter path from the pre-existing nick toward the mismatch, either 3' to 5' or 5' to 3', predominated over longer path excision by roughly 10:1 to 20:1. MMR excision was complete within 7 min, was highly specific (90:1) for the nicked strand, and was strongly mispair-dependent (at least 40:1). Nonspecific (mismatch-independent) 5' to 3' excision was considerably greater than nonspecific 3' to 5' excision, especially at pre-existing gaps, but was not processive. These techniques can be used to construct and analyze MMR substrates with DNA mismatches or lesions in any sequence context.     

Probing cellular processes with oligo-mediated recombination and using the knowledge gained to optimize recombineering

Recombination with single-strand DNA oligonucleotides (oligos) in Escherichia coli is an efficient and rapid way to modify replicons in vivo. The generation of nucleotide alteration by oligo recombination provides novel assays for studying cellular processes. Single-strand exonucleases inhibit oligo recombination, and recombination is increased by mutating all four known exonucleases. Increasing oligo concentration or adding nonspecific carrier oligo titrates out the exonucleases. In a model for oligo recombination, λ Beta protein anneals the oligo to complementary single-strand DNA at the replication fork. Mismatches are created, and the methyl-directed mismatch repair (MMR) system acts to eliminate the mismatches inhibiting recombination. Three ways to evade MMR through oligo design include, in addition to the desired change (1) a C·C mismatch  6 bp from that change; (2) four or more adjacent mismatches; or (3) mismatches at four or more consecutive wobble positions. The latter proves useful for making high-frequency changes that alter only the target amino acid sequence and even allows modification of essential genes. Efficient uptake of DNA is important for oligo-mediated recombination. Uptake of oligos or plasmids is dependent on media and is 10,000-fold reduced for cells grown in minimal versus rich medium. Genomewide engineering technologies utilizing recombineering will benefit from both optimized recombination frequencies and a greater understanding of how biological processes such as DNA replication and cell division impact recombinants formed at multiple chromosomal loci. Recombination events at multiple loci in individual cells are described here.     

Role of the DNA repair nucleases Rad13, Rad2 and Uve1 of Schizosaccharomyces pombe in mismatch correction.

Repair of mismatched DNA occurs mainly by the long-patch mismatch repair (MMR) pathway, requiring Msh2 and Pms1. In Schizosaccharomyces pombe mismatches can be repaired by a short-patch repair system, containing nucleotide excision repair (NER) factors. We studied mismatch correction efficiency in cells with inactivated DNA repair nucleases Rad13, Rad2 or Uve1 in MMR proficient and deficient background. Rad13 incises 3' of damaged DNA during NER. Rad2 has a function in the Uve1-dependent repair of DNA damages and in replication. Loss of Rad13 caused a strong reduction of short-patch processing of mismatches formed during meiotic recombination. Mitotic mutation rates were increased, but not to the same extent as in the NER mutant swi10, which is defective in 5' incision. The difference might be caused by an additional role of Rad13 in base excision repair or due to partial redundancy with other 3' endonucleases. Meiotic mismatch repair was not or only slightly affected in rad2 and uve1 mutants. In addition, inactivation of uve1 caused only weak effects on mutation avoidance. Mutation rates were elevated when rad2 was mutated, but not further increased in swi10 rad2 and rad13 rad2 double mutants, indicating an epistatic relationship. However, the mutation spectra of rad2 were different from that of swi10 and rad13. Thus, the function of Rad2 in mutation avoidance is rather independent of NER. rad13, swi10 and rad2, but not uve1 mutants were sensitive to the DNA-damaging agent methyl methane sulphonate. Cell survival was further reduced in the double mutants swi10 rad2, rad13 rad2 and, surprisingly, swi10 rad13. These data confirm that NER and Rad2 act in distinct damage repair pathways and further indicate that the function of Rad13 in repair of alkylated bases is partially independent of NER.     

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.     

Multiplicity of strand incision at G:T base mismatches in DNA by human cell extracts

Cell extract from the HT29 human colon carcinoma cell line (lacking mutator phenotype) was used to study the ATP-dependent G:T mismatch repair. We found that when a 45-bp (model) DNA with a single CpG/TpG mispair was incubated with the cell extract and ATP, it was incised immediately 5' and 3' to the mismatched T, and we noted that the actual 5'- and 3'-labeled fragments were similar to the cleaved products of thymine DNA glycosylase (TDG). This TDG-like cleavage product was enhanced (5-fold) with stimulation of several novel fragments, as inferred from the effect on incision at CpG/TpG site of the addition of G:U competitor DNA and ATP to the HT29 extract. The novel fragments were compatible with a strand incision on both sides of the mismatch (the third phosphodiester bond 5' and the second phosphodiester bond 3' to the mismatched T) and an incision 3' to the mismatched T, respectively. This suggests that while the ATP-dependent (TDG-like) incision activity, contrary to expectation, shows a lack of substrate competition, its catalytic property is likely modified by an interaction with G:U mispair. These multiple ATP-dependent incision events were not detected when extracts of the mismatch repair (MMR) defective HCT15 or HCT116 cell line were augmented with ATP and G:U. We postulate that these multiple ATP-dependent incision events possibly require the same MMR factors, and together they constitute a modified single ATP-dependent G:T incision activity. This activity toward the CpG/TpG was competitively inhibited by a 45-bp DNA with an ApG/TpT mispair; incision at a single site 5' to the latter mismatch compares with one of the multiple sites incised 5' to the former mismatch. These results suggest that one of several mismatch-incision factors is required by the human ATP-dependent G:T incision activity, in addition to MMR factors and ATP.     

Transient overexpression of DNA adenine methylase enables efficient and mobile genome engineering with reduced off-target effects

Homologous recombination of single-stranded oligonucleotides is a highly efficient process for introducing precise mutations into the genome of E. coli and other organisms when mismatch repair (MMR) is disabled. This can result in the rapid accumulation of off-target mutations that can mask desired phenotypes, especially when selections need to be employed following the generation of combinatorial libraries. While the use of inducible mutator phenotypes or other MMR evasion tactics have proven useful, reported methods either require non-mobile genetic modifications or costly oligonucleotides that also result in reduced efficiencies of replacement. Therefore a new system was developed, Transient Mutator Multiplex Automated Genome Engineering (TM-MAGE), that solves problems encountered in other methods for oligonucleotide-mediated recombination. TM-MAGE enables nearly equivalent efficiencies of allelic replacement to the use of strains with fully disabled MMR and with an approximately 12- to 33-fold lower off-target mutation rate. Furthermore, growth temperatures are not restricted and a version of the plasmid can be readily removed by sucrose counterselection. TM-MAGE was used to combinatorially reconstruct mutations found in evolved salt-tolerant strains, enabling the identification of causative mutations and isolation of strains with up to 75% increases in growth rate and greatly reduced lag times in 0.6 M NaCl.     

Mutations in Haemophilus influenzae mismatch repair genes increase mutation rates of dinucleotide repeat tracts but not dinucleotide repeat-driven pilin phase variation rates

High-frequency, reversible switches in expression of surface antigens, referred to as phase variation (PV), are characteristic of Haemophilus influenzae. PV enables this bacterial species, an obligate commensal and pathogen of the human upper respiratory tract, to adapt to changes in the host environment. Phase-variable hemagglutinating pili are expressed by many H. influenzae isolates. PV involves alterations in the number of 5' TA repeats located between the -10 and -35 promoter elements of the overlapping, divergently orientated promoters of hifA and hifBCDE, whose products mediate biosynthesis and assembly of pili. Dinucleotide repeat tracts are destabilized by mismatch repair (MMR) mutations in Escherichia coli. The influence of mutations in MMR genes of H. influenzae strain Rd on dinucleotide repeat-mediated PV rates was investigated by using reporter constructs containing 20 5' AT repeats. Mutations in mutS, mutL, and mutH elevated rates approximately 30-fold, while rates in dam and uvrD mutants were increased 14- and 3-fold, respectively. PV rates of constructs containing 10 to 12 5' AT repeats were significantly elevated in mutS mutants of H. influenzae strains Rd and Eagan. An intact hif locus was found in 14 and 12% of representative nontypeable H. influenzae isolates associated with either otitis media or carriage, respectively. Nine or more tandem 5' TA repeats were present in the promoter region. Surprisingly, inactivation of mutS in two serotype b H. influenzae strains did not alter pilin PV rates. Thus, although functionally analogous to the E. coli MMR pathway and active on dinucleotide repeat tracts, defects in H. influenzae MMR do not affect 5' TA-mediated pilin PV.     

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.     

The interaction of DNA mismatch repair proteins with human exonuclease I.

Exonucleolytic degradation of DNA is an essential part of many DNA metabolic processes including DNA mismatch repair (MMR) and recombination. Human exonuclease I (hExoI) is a member of a family of conserved 5' --> 3' exonucleases, which are implicated in these processes by genetic studies. Here, we demonstrate that hExoI binds strongly to hMLH1, and we describe interaction regions between hExoI and the MMR proteins hMSH2, hMSH3, and hMLH1. In addition, hExoI forms an immunoprecipitable complex with hMLH1/hPMS2 in vivo. The study of interaction regions suggests a biochemical mechanism of the involvement of hExoI as a downstream effector in MMR and/or DNA recombination.     

Mispair-bound human MutS–MutL complex triggers DNA incisions and activates mismatch repair

DNA mismatch repair (MMR) relies on MutS and MutL ATPases for mismatch recognition and strand-specific nuclease recruitment to remove mispaired bases in daughter strands. However, whether the MutS–MutL complex coordinates MMR by ATP-dependent sliding on DNA or protein–protein interactions between the mismatch and strand discrimination signal is ambiguous. Using functional MMR assays and systems preventing proteins from sliding, we show that sliding of human MutSα is required not for MMR initiation, but for final mismatch removal. MutSα recruits MutLα to form a mismatch-bound complex, which initiates MMR by nicking the daughter strand 5′ to the mismatch. Exonuclease 1 (Exo1) is then recruited to the nick and conducts 5′ → 3′ excision. ATP-dependent MutSα dissociation from the mismatch is necessary for Exo1 to remove the mispaired base when the excision reaches the mismatch. Therefore, our study has resolved a long-standing puzzle, and provided new insights into the mechanism of MMR initiation and mispair removal.Subject terms: Molecular biology     

The Escherichia coli methyl-directed mismatch repair system repairs base pairs containing oxidative lesions

A major role of the methyl-directed mismatch repair (MMR) system of Escherichia coli is to repair postreplicative errors. In this report, we provide evidence that MMR also acts on oxidized DNA, preventing mutagenesis. When cells deficient in MMR are grown anaerobically, spontaneous mutation frequencies are reduced compared with those of the same cells grown aerobically. In addition, we show that a dam mutant has an increased sensitivity to hydrogen peroxide treatment that can be suppressed by mutations that inactivate MMR. In a dam mutant, MMR is not targeted to newly replicated DNA strands and therefore mismatches are converted to single- and double-strand DNA breaks. Thus, base pairs containing oxidized bases will be converted to strand breaks if they are repaired by MMR. This is demonstrated by the increased peroxide sensitivity of a dam mutant and the finding that the sensitivity can be suppressed by mutations inactivating MMR. We demonstrate further that this repair activity results from MMR recognition of base pairs containing 8-oxoguanine (8-oxoG) based on the finding that overexpression of the MutM oxidative repair protein, which repairs 8-oxoG, can suppress the mutH-dependent increase in transversion mutations. These findings demonstrate that MMR has the ability to prevent oxidative mutagenesis either by removing 8-oxoG directly or by removing adenine misincorporated opposite 8-oxoG or both.     

Visualization of mismatch repair complexes using fluorescence microscopy

DNA mismatch repair (MMR) is a surveillance mechanism present in most living organisms, which repairs errors introduced by DNA polymerases. Importantly, loss of MMR function due to inactivating mutations and/or epigenetic silencing results in the accumulation of mutations and as consequence increased cancer susceptibility, as observed in Lynch syndrome patients.During the past decades important progress has been made in the MMR field resulting in the identification and characterization of essential MMR components, culminating in the in vitro reconstitution of 5′ and 3′ nick-directed MMR. However, several mechanistic aspects of the MMR reaction remain not fully understood, therefore alternative approaches and further investigations are needed.Recently, the use of imaging techniques and, more specifically, visualization of MMR components in living cells, has broadened our mechanistic understanding of the repair reaction providing more detailed information about the spatio-temporal organization of MMR in vivo. In this review we would like to comment on mechanistic aspects of the MMR reaction in light of these and other recent findings. Moreover, we will discuss the current limitations and provide future perspectives regarding imaging of mismatch repair components in diverse organisms.     

Evidence for preferential mismatch repair of lagging strand DNA replication errors in yeast

Duplex DNA is replicated in the 5'-3' direction by coordinated copying of leading and lagging strand templates with somewhat different proteins and mechanics, providing the potential for differences in the fidelity of replication of the two strands. We previously showed that in Saccharomyces cerevisiae, active replication origins establish a strand bias in the rate of base substitutions resulting from replication of unrepaired 8-oxo-guanine (GO) in DNA. Lower mutagenesis was associated with replicating lagging strand templates. Here, we test the hypothesis that this bias is due to more efficient repair of lagging stand mismatches by measuring mutation rates in ogg1 strains with a reporter allele in two orientations at loci on opposite sides of a replication origin on chromosome III. We compare a MMR-proficient strain to strains deleted for the MMR genes MSH2, MSH6, MLH1, or EXOI. Loss of MMR reduces the strand bias by preferentially increasing mutagenesis for lagging strand replication. We conclude that GO-A mismatches generated during lagging strand replication are more efficiently repaired. This is consistent with the hypothesis that 5' ends of Okazaki fragments and PCNA, present at high density during lagging strand replication, are used as strand discrimination signals for mismatch repair in vivo.     

Mismatch repair proteins: key regulators of genetic recombination

Mismatch repair (MMR) systems are central to maintaining genome stability in prokaryotes and eukaryotes. MMR proteins play a fundamental role in avoiding mutations, primarily by removing misincorporation errors that occur during DNA replication. MMR proteins also act during genetic recombination in steps that include repairing mismatches in heteroduplex DNA, modulating meiotic crossover control, removing 3' non-homologous tails during double-strand break repair, and preventing recombination between divergent sequences. In this review we will, first, discuss roles for MMR proteins in repairing mismatches that occur during recombination, particularly during meiosis. We will also explore how studying this process has helped to refine models of double-strand break repair, and particularly to our understanding of gene conversion gradients. Second, we will examine the role of MMR proteins in repressing homeologous recombination, i.e. recombination between divergent sequences. We will also compare the requirements for MMR proteins in preventing homeologous recombination to the requirements for these proteins in mismatch repair.     

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   

Generation of DNA nanocircles containing mismatched bases

The DNA mismatch repair (MMR) system recognizes and repairs errors that escaped the proofreading function of DNA polymerases. To study molecular details of the MMR mechanism, in vitro biochemical assays require specific DNA substrates carrying mismatches and strand discrimination signals. Current approaches used to generate MMR substrates are time-consuming and/or not very flexible with respect to sequence context. Here we report an approach to generate small circular DNA containing a mismatch (nanocircles). Our method is based on the nicking of PCR products resulting in single-stranded 3' overhangs, which form DNA circles after annealing and ligation. Depending on the DNA template, one can generate mismatched circles containing a single hemimethylated GATC site (for use with the bacterial system) and/or nicking sites to generate DNA circles nicked in the top or bottom strand (for assays with the bacterial or eukaryotic MMR system). The size of the circles varied (323 to 1100 bp), their sequence was determined by the template DNA, and purification of the circles was achieved by ExoI/ExoIII digestion and/or gel extraction. The quality of the nanocircles was assessed by scanning-force microscopy and their suitability for in vitro repair initiation was examined using recombinant Escherichia coli MMR proteins.     

Stoichiometry of MutS and MutL at unrepaired mismatches in vivo suggests a mechanism of repair

Mismatch repair (MMR) is an evolutionarily conserved DNA repair system, which corrects mismatched bases arising during DNA replication. MutS recognizes and binds base pair mismatches, while the MutL protein interacts with MutS-mismatch complex and triggers MutH endonuclease activity at a distal-strand discrimination site on the DNA. The mechanism of communication between these two distal sites on the DNA is not known. We used functional fluorescent MMR proteins, MutS and MutL, in order to investigate the formation of the fluorescent MMR protein complexes on mismatches in real-time in growing Escherichia coli cells. We found that MutS and MutL proteins co-localize on unrepaired mismatches to form fluorescent foci. MutL foci were, on average, 2.7 times more intense than the MutS foci co-localized on individual mismatches. A steric block on the DNA provided by the MutHE56A mutant protein, which binds to but does not cut the DNA at the strand discrimination site, decreased MutL foci fluorescence 3-fold. This indicates that MutL accumulates from the mismatch site toward strand discrimination site along the DNA. Our results corroborate the hypothesis postulating that MutL accumulation assures the coordination of the MMR activities between the mismatch and the strand discrimination site.