Heteroduplex deoxyribonucleic acid base mismatch repair in bacteria

Molecular mechanisms of genetic adaptation to xenobiotic compounds

Microorganisms in the environment can often adapt to use xenobiotic chemicals as novel growth and energy substrates. Specialized enzyme systems and metabolic pathways for the degradation of man-made compounds such as chlorobiphenyls and chlorobenzenes have been found in microorganisms isolated from geographically separated areas of the world. The genetic characterization of an increasing number of aerobic pathways for degradation of (substituted) aromatic compounds in different bacteria has made it possible to compare the similarities in genetic organization and in sequence which exist between genes and proteins of these specialized catabolic routes and more common pathways. These data suggest that discrete modules containing clusters of genes have been combined in different ways in the various catabolic pathways. Sequence information further suggests divergence of catabolic genes coding for specialized enzymes in the degradation of xenobiotic chemicals. An important question will be to find whether these specialized enzymes evolved from more common isozymes only after the introduction of xenobiotic chemicals into the environment. Evidence is presented that a range of genetic mechanisms, such as gene transfer, mutational drift, and genetic recombination and transposition, can accelerate the evolution of catabolic pathways in bacteria. However, there is virtually no information concerning the rates at which these mechanisms are operating in bacteria living in nature and the response of such rates to the presence of potential (xenobiotic) substrates. Quantitative data on the genetic processes in the natural environment and on the effect of environmental parameters on the rate of evolution are needed.

Isolation and characterization of two Saccharomyces cerevisiae genes encoding homologs of the bacterial HexA and MutS mismatch repair proteins

Homologs of the Escherichia coli (mutL, S and uvrD) and Streptococcus pneumoniae (hexA, B) genes involved in mismatch repair are known in several distantly related organisms. Degenerate oligonucleotide primers based on conserved regions of E. coli MutS protein and its homologs from Salmonella typhimurium, S. pneumoniae and human were used in the polymerase chain reaction (PCR) to amplify and clone mutS/hexA homologs from Saccharomyces cerevisiae. Two DNA sequences were amplified whose deduced amino acid sequences both shared a high degree of homology with MutS. These sequences were then used to clone the full-length genes from a yeast genomic library. Sequence analysis of the two MSH genes (MSH = mutS homolog), MSH1 and MSH2, revealed open reading frames of 2877 bp and 2898 bp. The deduced amino acid sequences predict polypeptides of 109.3 kD and 109.1 kD, respectively. The overall amino acid sequence identity with the E. coli MutS protein is 28.6% for MSH1 and 25.2% for MSH2. Features previously found to be shared by MutS homologs, such as the nucleotide binding site and the helix-turn-helix DNA binding motif as well as other highly conserved regions whose function remain unknown, were also found in the two yeast homologs. Evidence presented in this and a companion study suggest that MSH1 is involved in repair of mitochondrial DNA and that MSH2 is involved in nuclear DNA repair.

Restoration of the wild-type locus in an RuBP carboxylase/oxygenase mutant of Synechocystis PCC 6803 via targeted gene recombination

The interaction between homologous DNA sequences, distant from each other in the chromosome, was examined in the cyanobacterium Synechocystis PCC 6803. Most of the rbcL gene encoding the large subunit of ribulose bisphosphate carboxylase/oxygenase (Rubisco) was duplicated in the genome by a targeted insertion of a 3'-truncated gene copy into the psb A-I locus. Both rbcL genes, in the psb A-I region and at the rbc locus, were non-functional; The former due to the 3' truncation, and the latter due to a deletion in the 5'-region (creating a 5' truncation) and a mutation associated with an insertion of the Rhodospirillum rubrum rbc gene, yielding a high-CO2-requiring mutant ('cyanorubrum'). The 3' and the 5' truncated rbcL genes were linked to chloramphenicol and kanamycin resistance markers, respectively. Decreasing the kanamycin selective pressure concomitantly with exposure of the double resistance mutant to air, resulted in air-growing colonies. Analysis of their genomes, Rubisco proteins, and their ultrastructure revealed: 1) Reconstitution of a full-length cyanobacterial rbcL gene at the rbc locus; 2) simultaneous synthesis of the cyanobacterial (L8S8) and R. rubrum (L2) enzymes in meroploids containing both mutated and reconstituted rbcL genes; 3) reappearance of carboxysomes. Our results indicate extensive recombinatorial interactions between the homologous sequences at both loci leading to reconstitution of the cyanobacterial rbcL gene.

Transfection of heteroduplexes containing uracil.guanine or thymine.guanine mispairs into plant cells

We have compared the fate of U.G mispairs or analogous T.G mispairs in DNA heteroduplexes transfected into tobacco protoplasts. The heteroduplex DNA consisted of tomato golden mosaic virus DNA sequences in the Escherichia coli vectors pUC118 or pUC119. After transfection, the mismatched U residues were lost with an efficiency of greater than 95%, probably as a result of the uracil-DNA glycosylase pathway for excision of U residues in any sequence context. In contrast to the preferential removal of the mispaired U residues, biased removal of T residues from analogous heteroduplexes was not seen in the transfected plant cells. Also, we investigated the effect of extensively methylating one strand of the heteroduplex DNA used for transfection. Surprisingly, such methylation resulted in highly biased loss of the mismatched base from the 5-methylcytosine-rich strand of T.G-containing heteroduplexes.

Escherichia coli MutY protein has both N-glycosylase and apurinic/apyrimidinic endonuclease activities on A.C and A.G mispairs

In Escherichia coli the mutY (or micA)-dependent DNA mismatch repair pathway can convert A degrees G and A degrees C mismatches to C.G and G.C base pairs, respectively, through a short repair-tract mechanism. The MutY protein has been purified to near homogeneity from an E. coli overproducer strain. Purified MutY has been shown to contain both N-glycosylase and 3' apurinic/apyrimidinic (AP) endonuclease activities. The N-glycosylase removes the mispaired adenines of A degrees G and A degrees C mismatches, and the AP endonuclease acts on the first phosphodiester bond 3' to the AP sites. The N-glycosylase and the nicking (combined N-glycosylase and AP endonuclease) activities copurified through multiple chromatographic steps without a change in relative specific activities. Furthermore, both N-glycosylase and AP endonuclease activities can be recovered by renaturation of a single polypeptide band from an SDS/polyacrylamide gel. Renaturation required the presence of iron and sulfide. These findings suggest that the MutY protein, like endonuclease III, is an iron-sulfur protein. DNA fragments with A degrees C mismatches were 20-fold less active than DNA with A degrees G mispairs as a substrate for purified MutY.

Recombination between similar but not identical DNA sequences during yeast transformation occurs within short stretches of identity

Interactions between similar but not identical (homeologous) DNA sequences play an important biological role in the evolution of genes and genomes. To gain insight into the underlying molecular mechanism(s) of genetic recombination, we have studied inter- and intramolecular homeologous recombination in S. cerevisiae during transformation. We found that homeologous DNAs recombine efficiently. Hybrid sequences were obtained between two mammalian cytochrome P450 cDNAs, sharing 73% identity, and between the yeast ARG4 gene and its human homeologous cDNA, sharing 52% identity. Sequencing data showed that the preferred recombination events are those corresponding to the overall alignment of the DNA sequences and that the junctions are within stretches of identity of variable length (2-21 nt). We suggest that these events occur by a conventional homologous recombination mechanism.

A highly conserved repeated DNA element located in the chromosome of Streptococcus pneumoniae

We report the discovery of a group of highly conserved DNA sequences located, in those cases studied, within intergenic regions of the chromosome of the Gram positive Streptococcus pneumoniae. The S. pneumoniae genome contains about 25 of these elements called BOX. From 5' to 3', BOX elements are composed of three subunits (boxA, boxB, and boxC) which are 59, 45 and 50 nucleotides long, respectively. BOX elements containing one, two and four copies of boxB have been observed; boxB alone was also detected in one instance. These elements are unrelated to the two most thoroughly documented families of repetitive DNA sequences present in the genomes of enterobacteria. BOX sequences have the potential to form stable stem-loop structures and one of these, at least, is transcribed. Most of these elements are located in the immediate vicinity of genes whose product has been implicated at some stage in the process of genetic transformation or in virulence of S. pneumoniae. This location raises the intriguing possibility that BOX sequences are regulatory elements shared by several coordinately controlled genes, including competence-specific and virulence-related genes.

Highly efficient gene targeting in embryonic stem cells through homologous recombination with isogenic DNA constructs

A vast amount of data suggests that homologous recombination in mammalian cells is relatively rare as compared to random integration, imposing the need for sophisticated selection protocols to enrich for cells in which homologous recombination has occurred. We here show that one of the key factors in efficient homologous recombination is the use of isogenic DNA to prepare the targeting vectors. Homologous recombination at the retinoblastoma susceptibility gene (Rb) in embryonic stem cells derived from mouse strain 129 was 20-fold more efficient with a 129-derived targeting construct than with a BALB/c-derived construct. The two constructs were identical, except for a number of base sequence divergences between 129 and BALB/c DNA, including base-pair substitutions, small deletions/insertions, and a polymorphic CA repeat. Transfection with an isogenic DNA construct, containing 17 kilobases of homology, yielded a targeting frequency of 78% (of a total of 20,000 drug-resistant colonies), without the use of an enrichment protocol for homologous recombination. This result indicates that, also in mammalian cells, homologous recombination rather than random integration can be the predominant event.

An Escherichia coli dnaE mutation with suppressor activity toward mutator mutD5

The Escherichia coli mutator mutD5 is a conditional mutator whose strength is moderate when the strain is growing in minimal medium but very strong when it is growing in rich medium. The primary defect of this strain resides in the dnaQ gene, which encodes the epsilon (exonucleolytic proofreading) subunit of the DNA polymerase III holoenzyme. In one of our mutD5 strains we discovered a mutation that suppressed the mutability of mutD5. Interestingly, the level of suppression was strong in minimal medium but weak in rich medium. The mutation was localized to the dnaE gene, which encodes the alpha (polymerase) subunit of the DNA polymerase III holoenzyme. This mutation, termed dnaE910, also conferred improved growth of the mutD5 strain and caused increased temperature sensitivity in both wild-type and dnaQ49 backgrounds. The reduction in mutator strength by dnaE910 was also observed when this allele was placed in a mutL, a mutT, or a dnaQ49 background. The results suggest that dnaE910 encodes an antimutator DNA polymerase whose effect might be mediated by improved insertion fidelity or by increased proofreading via its effect on the exonuclease activity.

Repair of DNA heteroduplexes containing small heterologous sequences in Escherichia coli

Plasmid heteroduplexes were constructed that contain 1, 2, 3, 4, or 5 unpaired bases within the mnt gene. These were used to assess the efficiency of repair of small heterologous sequences ("heterologies") in DNA by the Escherichia coli Dam-directed mismatch repair system. Heteroduplexes in defined states of methylation at d(GATC) sites were used to transform a repair-proficient indicator strain (which has a mnt-lac fusion coding for a nonfunctional mnt repressor) and its isogenic mutH, -L, and -S derivatives. Using this in vivo transformation system, we scored for repair on the basis of colony color: correction in favor of the strand bearing mnt+ coding information gives rise to colonies that are white, whereas correction on the opposite strand (mnt-) yields colonies that are red when grown on MacConkey agar. Failure to repair a heterology yields colonies that are both red and white ("mixed"). The correction efficiencies of two heteroduplexes, each containing a single G.T mismatch within mnt, were also monitored for purposes of comparison. Our results show that mutHLS-dependent, methyl-directed repair of heteroduplexes with 1-, 2-, and 3-base deletions is as highly efficient as the repair of G.T mismatches. Heteroduplexes with a 4-base deletion are marginally repaired and DNA with a 5-base deletion is not detectably repaired. In addition, we show that purified MutS protein from Salmonella typhimurium, which can substitute for E. coli MutS in vivo, binds to oligonucleotide duplexes containing 1, 2, 3, and 4 unpaired bases of a sequence identical with that used for the in vivo studies. Specific binding of MutS to homoduplex DNA and to DNA that had undergone a 5-base deletion was not observed.

Gene localization, size, and physical map of the chromosome of Streptococcus pneumoniae

A physical map of the Streptococcus (Diplococcus) pneumoniae chromosome, which is circular and 2,270 kbp in circumference, has been constructed. The restriction enzymes ApaI, SmaI, and SacII were used to digest intact chromosomes, and the fragments were resolved by field inversion gel electrophoresis (FIGE). The digests produced 22, 20, and 29 fragments, respectively. The order of the fragments was deduced from Southern blot hybridization of isolated labeled fragments to separated fragments of the various restriction digests. Genetic markers were correlated with the physical map by transformation of recipient cells with FIGE-isolated DNA fragments derived from genetically marked S. pneumoniae strains. In addition, markers were mapped by the hybridization of cloned genes to FIGE-separated restriction fragments. Six rRNA gene (rrn) clusters were mapped by hybridization to rrn-containing fragments of Haemophilus influenzae.

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.

The spectrum of spontaneous mutations in a Saccharomyces cerevisiae uracil-DNA-glycosylase mutant limits the function of this enzyme to cytosine deamination repair

Uracil-DNA-glycosylase has been proposed to function as the first enzyme in strand-directed mismatch repair in eukaryotic organisms, through removal of uracil from dUMP residues periodically inserted into the DNA during DNA replication (Aprelikova, O. N., V. M. Golubovskaya, T. A. Kusmin, and N. V. Tomilin, Mutat. Res. 213:135-140, 1989). This hypothesis was investigated with Saccharomyces cerevisiae. Mutation frequencies and spectra were determined for an ung1 deletion strain in the target SUP4-o tRNA gene by using a forward selection scheme. Mutation frequencies in the SUP4-o gene increased about 20-fold relative to an isogenic wild-type S. cerevisiae strain, and the mutator effect was completely suppressed in the ung1 deletion strain carrying the wild-type UNG1 gene on a multicopy plasmid. Sixty-nine independently derived mutations in the SUP4-o gene were sequenced. All but five of these were due to GC----AT transitions. From this analysis, we conclude that the mutator phenotype of the ung1 deletion strain is the result of a failure to repair spontaneous cytosine deamination events occurring frequently in S. cerevisiae and that the UNG1 gene is not required for strand-specific mismatch repair in S. cerevisiae.

Uracil-DNA glycosylase affects mismatch repair efficiency in transformation and bisulfite-induced mutagenesis in Streptococcus pneumoniae

The generalized mismatch repair system of Streptococcus pneumoniae (the Hex system) can eliminate base pair mismatches arising in heteroduplex DNA during transformation or by DNA polymerase errors during replication. Mismatch repair is most likely initiated at nicks or gaps. The present work was started to examine the hypothesis that strand discontinuities arising after removal of uracil by uracil DNA-glycosylase (Ung) can be utilised as strand discrimination signals. We show that mismatch repair efficiency is enhanced 3- to 6-fold when using uracil-containing DNA as donor in transformation. In order to assess the contribution of Ung to nascent strand discrimination for postreplication mismatch repair, we developed a positive selection procedure to isolate S. pneumoniae Ung- mutants. We succeeded in isolating Ung- mutants using this procedure based on chromosomal integration of uracil-containing hybrid DNA molecules. Cloning and characterization of the ung gene was achieved. Comparison of spontaneous mutation rates in strains either proficient or deficient in mismatch and/or uracil repair gave no support to the hypothesis that Ung plays a major role in targeting the Hex system to neosynthesized DNA strands. However Ung activity is responsible for the increased efficiency of mismatch repair observed in transformation with uracil-containing DNA. In addition Ung is involved in repair of bisulfite-treated transforming DNA.

Spontaneous mutation in the Escherichia coli lacI gene

To gain more detailed insight into the nature and mechanisms of spontaneous mutations, we undertook a DNA sequence analysis of a large collection of spontaneous mutations in the N-terminal region of the Escherichia coli lacI gene. This region of circa 210 base pairs is the target for dominant lacI mutations (i-d) and is suitable for studies of mutational specificity since it contains a relatively high density of detectable mutable sites. Among 414 independent i-d mutants, 70.8% were base substitutions, 17.2% deletions, 7.7% additions and 4.3% single-base frameshifts. The base substitutions were both transitions (60%) and transversions (40%), the largest single group being G.C----A.T (47% of base substitutions). All four transversions were observed. Among the 71 deletions, a hotspot (37 mutants) was present: an 87-bp deletion presumably directed by an 8-bp repeated sequence at its endpoints. The remaining 34 deletions were distributed among 29 different mutations, either flanked (13/34) or not flanked (21/34) by repeated sequences. The 32 additions comprised 29 different events, with only two containing a direct repeat at the endpoints. The single-base frameshifts were the loss of a single base from either repeated (67%) or nonrepeated (33%) bases. A comparison with the spectrum obtained previously in strains defective in DNA mismatch correction (mutH, mutL, mutS strains) yielded information about the apparent efficiency of mismatch repair. The overall effect was 260-fold but varied substantially among different classes of mutations. An interesting asymmetry was uncovered for the two types of transitions, A.T----G.C and G.C----A.T being reduced by mismatch repair 1340- and 190-fold, respectively. Explanations for this asymmetry and its possible implications for the origins of spontaneous mutations are discussed.

Base mismatch-specific endonuclease activity in extracts from Saccharomyces cerevisiae

An endonuclease activity (called MS-nicking) for all possible base mismatches has been detected in the extracts of yeast, Saccharomyces cerevisiae. DNAs with twelve possible base mismatches at one defined position are cleaved at different efficiencies. DNA fragments with A/G, G/A, T/G, G/T, G/G, or A/A mismatches are nicked with greater efficiencies than C/T, T/C, C/A, and C/C. DNA with an A/C or T/T mismatch is nicked with an intermediate efficiency. The MS-nicking is only on one particular DNA strand, and this strand disparity is not controlled by methylation, strand break, or nature of the mismatch. The nicks have been mapped at 2-3 places at second, third, and fourth phosphodiester bonds 5' to the mispaired base; from the time course study, the fourth phosphodiester bond probably is the primary incision site. This activity may be involved in mismatch repair during genetic recombination.

Heteroduplex DNA formation is associated with replication and recombination in poxvirus-infected cells

Poxviruses are large DNA viruses that replicate in the cytoplasm of infected cells and recombine at high frequencies. Calcium phosphate precipitates were used to cotransfect Shope fibroma virus-infected cells with different DNA substrates and the recombinant products assayed by genetic and biochemical methods. We have shown previously that bacteriophage lambda DNAs can be used as substrates in these experiments and recombinants assayed on Escherichia coli following DNA recovery and in vitro packaging. Using this assay it was observed that 2-3% of the phage recovered from crosses between point mutants retained heteroduplex at at least one of the mutant sites. The reliability of this genetic analysis was confirmed using DNA substrates that permitted the direct detection of heteroduplex molecules by denaturant gel electrophoresis and Southern blotting. It was further noted that heteroduplex formation coincided with the onset of both replication and recombination suggesting that poxviruses, like certain bacteriophage, make no clear biochemical distinction between these three processes. The fraction of heteroduplex molecules peaked about 12-hr postinfection then declined later in the infection. This decline was probably due to DNA replication rather than mismatch repair because, while high levels of induced DNA polymerase persisted beyond the time of maximal heteroduplex recovery, we were unable to detect any type of mismatch repair activity in cytoplasmic extracts. These results suggest that, although heteroduplex molecules are formed during the progress of poxviral infection, gene conversion through mismatch repair probably does not produce most of the recombinants. The significance of these observations are discussed considering some of the unique properties of poxviral biology.

Counterselection of GATC sequences in enterobacteriophages by the components of the methyl-directed mismatch repair system

Weak to severe deficit of GATC sequences in the DNA of enterobacteriophages appears to be correlated with their undermethylation during growth in dam+ (GATC ade-methylase) bacteria. This observation is corroborated by the sequence analysis showing no evidence for site-specific mutagenicity of 6meAde. The MutH protein of the methyl-directed mismatch repair system recognizes and cleaves the undermethylated GATC sequences in the course of mismatch repair. To enquire whether the MutH function of the methyl-directed mismatch repair system participates in counterselection of GATC sequences in enterobacteriophages, we have studied the yield of bacteriophage phi X174 containing either 0, 1, or 2 GATC sequences, in wild type, dam, and mut (H, L, S, U) Escherichia coli. Following transfection with unmethylated DNA containing two GATC sequences, a net decrease in the yield of infective particles was observed in all bacterial mutH+ dam- strains, whereas no detectable decrease was observed in bacteria infected by DNA without GATC sequence. This effect of the MutH function is maximum in wild type and mutL and mutS bacteria whereas the effect is not significant in mutU bacteria, suggesting an interaction of the helicase II with the MutH protein. However, in dam+ bacteria, the presence of GATC sequences leads to an increased yield of infective particles. The effect of GATC sequence and its Dam methylation system on phage yield in mutH- bacteria reveals that methylated GATC sequences are advantageous to the phage.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of uracil situated in the vicinity of a mispair on the directionality of mismatch correction in Escherichia coli

We wanted to establish whether strand breaks and gaps, arising during the removal of uracil from newly-synthesized DNA, can be utilized as strand discrimination signals by the methyl-directed mismatch repair system of Escherichia coli. For this purpose, we constructed a series of M13 heteroduplexes that contained a single uracil residue situated either upstream or downstream from a G/T or an A/C mispair. Transfections of these constructs into E. coli strains, either proficient of deficient in mismatch or uracil repair, allowed us to follow the fate of these mispairs in vivo. Our data show that the intermediates of uracil repair cannot substitute for the strand-discrimination signals generated by the MutH protein, which is thought to initiate the methyl-directed mismatch repair process by nicking the unmethylated strand of a newly-synthesized DNA duplex at d(GATC) sites. However, processing of uracil residues situated upstream from the mispair was shown to reduce the yield of the progeny phage arising from the uracil-containing strand, presumably as a result of co-repair of the base analogue and the mispair.

Mismatch-stimulated plasmid integration in yeast

A single base pair mismatch (G:T or A:C) in the CYC1 gene of the integrative plasmid pAB218 stimulates up to a five-fold integration into the yeast chromosome. Analysis of chromosomal sites of plasmid integration suggests that the mismatch-stimulated integration is not targeted as would be expected if crossovers, localised in the region of the mismatch, were a necessary step in mismatch repair. Instead, the observed mismatch-stimulated plasmid integration could be due to potentially recombinogenic structures formed during mismatch repair, such as single-stranded gaps or denatured DNA regions extending around the plasmid molecule.

Nucleotide sequence of the Escherichia coli micA gene required for A/G-specific mismatch repair: identity of micA and mutY

The Escherichia coli methylation-independent repair pathway specific for A/G mismatches has been shown to require the gene product of micA. Extracts prepared from micA mutants do not form an A/G mismatch-specific DNA-protein complex and do not contain an A/G mismatch-specific nicking activity. Moreover, a partially purified protein fraction containing both A/G mismatch-specific nicking and binding activities restores repair activity in micA mutant extracts. The DNA sequence of a 2.3-kb fragment containing the micA gene has been determined. There are two open reading frames (ORF) in this DNA fragment: one ORF encodes a 25.7-kDa protein whose function is still unknown, the other ORF codes for a protein with an Mr of 39,147, but this ORF can be transcribed and the mRNA can be translated to yield a protein with an apparent Mr of 36 kDa on a sodium dodecyl sulfate-polyacrylamide gel. Deletion analysis showed that this 39.1-kDa ORF is the micA gene as judged by the capacity of the encoded protein to restore the A/G mismatch-specific nicking activity of micA mutant extracts. Furthermore, our results suggest that micA is the same gene as the closely mapped mutY, which encodes the A/G mismatch-specific glycosylase.

A novel extrachromosomally maintained transformation vector for the lignin-degrading basidiomycete Phanerochaete chrysosporium

A stable extrachromosomally maintained transformation vector (pG12-1) for the lignin-degrading filamentous fungus Phanerochaete chrysosporium is described. The vector is 6.3 kb and contains a Kanr marker, pBR322 ori, and a 2.2-kb fragment (ME-1) derived from an endogenous extrachromosomal DNA element of P. chrysosporium. Vector pG12-1 was able to transform P. chrysosporium to G418 resistance and was readily and consistently recoverable from the total DNA of transformants via Escherichia coli transformation. Southern blot analyses indicated that pG12-1 is maintained at a low copy number in the fungal transformants. The vector is demonstrable in the total DNA of individual G418-resistant basidiospore progeny of the transformants only after amplification by polymerase chain reaction. Exonuclease III and dam methylation analyses, respectively, indicated that pG12-I undergoes replication in P. chrysosporium and that it is maintained extrachromosomally in a circular form. The vector is stably maintained in the transformants even after long-term nonselective growth. There is no evidence for integration of the vector into the chromosome at any stage.

Role of uracil-DNA glycosylase in mutation avoidance by Streptococcus pneumoniae

Uracil-DNA glycosylase activity was found in Streptococcus pneumoniae, and the enzyme was partially purified. An ung mutant lacking the activity was obtained by positive selection of cells transformed with a plasmid containing uracil in its DNA. The effects of the ung mutation on mutagenic processes in S. pneumoniae were examined. The sequence of several malM mutations revertible by nitrous acid showed them to correspond to A.T----G.C transitions. This confirmed a prior deduction that nitrous acid action on transforming DNA gave only G.C----A.T mutations. Examination of malM mutant reversion frequencies in ung strains indicated that G.C----A.T mutation rates generally were 10-fold higher than in wild-type strains, presumably owing to lack of repair of deaminated cytosine residues in DNA. No effect of ung on mutation avoidance by the Hex mismatch repair system was observed, which means that uracil incorporation and removal from nascent DNA cannot be solely responsible for producing strand breaks that target nascent DNA for correction after replication. One malM mutation corresponding to an A.T----G.C transition showed a 10-fold-higher spontaneous reversion frequency than other such transitions in a wild-type background. This "hot spot" was located in a directly repeated DNA sequence; it is proposed that transient slippage to the wild-type repeat during replication accounts for the higher reversion frequency.

The single-stranded DNA-binding protein of Escherichia coli

The single-stranded DNA-binding protein (SSB) of Escherichia coli is involved in all aspects of DNA metabolism: replication, repair, and recombination. In solution, the protein exists as a homotetramer of 18,843-kilodalton subunits. As it binds tightly and cooperatively to single-stranded DNA, it has become a prototypic model protein for studying protein-nucleic acid interactions. The sequences of the gene and protein are known, and the functional domains of subunit interaction, DNA binding, and protein-protein interactions have been probed by structure-function analyses of various mutations. The ssb gene has three promoters, one of which is inducible because it lies only two nucleotides from the LexA-binding site of the adjacent uvrA gene. Induction of the SOS response, however, does not lead to significant increases in SSB levels. The binding protein has several functions in DNA replication, including enhancement of helix destabilization by DNA helicases, prevention of reannealing of the single strands and protection from nuclease digestion, organization and stabilization of replication origins, primosome assembly, priming specificity, enhancement of replication fidelity, enhancement of polymerase processivity, and promotion of polymerase binding to the template. E. coli SSB is required for methyl-directed mismatch repair, induction of the SOS response, and recombinational repair. During recombination, SSB interacts with the RecBCD enzyme to find Chi sites, promotes binding of RecA protein, and promotes strand uptake.

DNA mismatch repair in Xenopus egg extracts: repair efficiency and DNA repair synthesis for all single base-pair mismatches

Repair of all 12 single base-pair mismatches by Xenopus egg extracts was measured by a physical assay with a sequence containing four overlapping restriction sites. The heteroduplex substrates, derivatives of M13 phage DNA, differed in sequence at the mismatch position only and permitted measurement of repair to both strands. The efficiency of repair varied about 4-fold between the most and least effectively repaired mismatches. Repair was most active with C/A and T/C mismatches but the efficiency varied depending on the orientation of the mismatch. Mismatch-specific DNA repair synthesis was also observed but the extent of repair was not always predictive of the extent of synthesis, suggesting the presence of different repair systems or different modes of mismatch recognition.

Strand-specific mismatch correction in nuclear extracts of human and Drosophila melanogaster cell lines

Nuclear extracts derived from HeLa and Drosophila melanogaster KC cell lines have been found to correct single base-base mispairs within open circular DNA heteroduplexes containing a strand-specific, site-specific incision located 808 base pairs from the mismatch. Correction in both extract systems is strand specific, being highly biased to the incised DNA strand. Different mispairs within a homologous set of heteroduplexes were processed with different efficiencies (G.T greater than G.G approximately equal to A.C greater than C.C), and correction was accompanied by mismatch-dependent DNA synthesis localized to the region spanning the mispair and the strand break, thus demonstrating that mismatch recognition is associated with the repair reaction. Correction of each of these heteroduplexes was abolished by aphidicolin but was relatively insensitive to the presence of high concentrations of ddTTP, indicating probable involvement of alpha and/or delta class DNA polymerase(s). These findings suggest that higher eukaryotic cells possess a general, strand-specific mismatch repair system analogous to the Escherichia coli mutHLS and the Streptococcus pneumoniae hexAB pathways, systems that contribute in a major way to the genetic stability of these bacterial species.

MutY, an adenine glycosylase active on G-A mispairs, has homology to endonuclease III

The mutY gene of Escherichia coli, which codes for an adenine glycosylase that excises the adenine of a G-A mispair, has been cloned and sequenced. The mutY gene codes for a protein of 350 amino acids (Mr = 39,123) and the clone genetically complements the mutY strain. The protein shows significant sequence homology to E. coli endonuclease III, an enzyme that has previously been shown to have glycosylase activity on damaged base pairs. Sequence analysis suggests that, like endonuclease III, MutY is an iron-sulfur protein with a [4Fe-4S]2+ cluster.

Chromosome replication pattern in dam mutants of Escherichia coli

The replication cycle of Escherichia coli dam mutants was analysed and compared with that of isogenic Dam+ strains. Marker frequency analyses indicated no gross difference between the strains. In the Dam- as well as in the Dam+ bacteria, initiation most likely occurs at oriC, replication forks move at a constant and invariant velocity, and termination takes place in the terC region. An analysis of replication terminator activity indicated that this activity is unaffected by the methylation status. Taken together with previous results, our data are compatible with Dam methylation controlling initiation timing but no subsequent step of the replication process.

Specific A/G-to-C.G mismatch repair in Salmonella typhimurium LT2 requires the mutB gene product

An assay has been developed that permits analysis of repair of A/G mismatches to C.G base pairs in cell extracts of Salmonella typhimurium LT2. This A/G mismatch repair is independent of ATP, dam methylation, and mutS gene function. The gene product of mutB has been shown to be involved in the dam-independent pathway through the in vitro assay. Moreover, specific DNA-protein complexes and an endonuclease can be detected in S. typhimurium extracts by using DNA fragments containing an A/G mismatch. These activities are not observed with substrates which have a T/G mismatch or no mismatch. The S. typhimurium endonuclease, like the A/G endonuclease found in Escherichia coli (A-L. Lu and D.-Y. Chang, Cell 54:805-812, 1988), makes incisions at the first phosphodiester bond 3' to and the the second phosphodiester bond 5' to the dA of the A/G mismatch. No incision site was detected on the other DNA strand. Extracts prepared from mutB mutants cannot form A/G mismatch-specific DNA-protein complexes and do not contain the A/G endonuclease activity. Thus the A/G mismatch specific binding and nicking activities are probably involved in the A/G mismatch repair pathway. Preliminary analysis of the mutational spectrum of the mutB strain has indicated that this mutator allele causes an increase in C.G-to-A.T transversions without affecting the frequencies of other transversion or transition events. In addition, the mutB gene has been mapped to the 64-min region of the S. typhimurium chromosome. Together, this biochemical and genetic evidence suggests that the mutB gene product of S. typhimurium is the homolog of the E. coli micA (and/or mutY) gene product.

Heteroduplex DNA correction in Saccharomyces cerevisiae is mismatch specific and requires functional PMS genes

In vitro-constructed heteroduplex DNAs with defined mismatches were corrected in Saccharomyces cerevisiae cells with efficiencies that were dependent on the mismatch. Single-nucleotide loops were repaired very efficiently; the base/base mismatches G/T, A/C, G/G, A/G, G/A, A/A, T/T, T/C, and C/T were repaired with a high to intermediate efficiency. The mismatch C/C and a 38-nucleotide loop were corrected with low efficiency. This substrate specificity pattern resembles that found in Escherichia coli and Streptococcus pneumoniae, suggesting an evolutionary relationship of DNA mismatch repair in pro- and eucaryotes. Repair of the listed mismatches was severely impaired in the putative S. cerevisiae DNA mismatch repair mutants pms1 and pms2. Low-efficiency repair also characterized pms3 strains, except that correction of single-nucleotide loops occurred with an efficiency close to that of PMS wild-type strains. A close correlation was found between the repair efficiencies determined in this study and the observed postmeiotic segregation frequencies of alleles with known DNA sequence. This suggests an involvement of DNA mismatch repair in recombination and gene conversion in S. cerevisiae.

Methyl-directed repair of frameshift heteroduplexes in cell extracts from Escherichia coli

The methyl-directed DNA repair efficiency of a series of M13mp9 frameshift heteroduplexes 1, 2, or 3 unpaired bases was determined by using an in vitro DNA mismatch repair assay. Repair of hemimethylated frameshift heteroduplexes in vitro was directed to the unmethylated strand; was dependent on MutH, MutL, and MutS; and was equally efficient on base insertions and deletions. However, fully methylated frameshift heteroduplexes were resistant to repair, while totally unmethylated substrates were repaired with no strand bias. Hemimethylated 1-, 2-, or 3-base insertion and deletion heteroduplexes were repaired by the methyl-directed mismatch repair pathway as efficiently as the G.T mismatch. These results are consistent with earlier in vivo studies and demonstrate the involvement of methyl-directed DNA repair in the efficient prevention of frameshift mutations.

Horizontal transfer of penicillin-binding protein genes in penicillin-resistant clinical isolates of Streptococcus pneumoniae

Resistance to penicillin in clinical isolates of Streptococcus pneumoniae has occurred by the development of altered penicillin-binding proteins (PBPs) that have greatly decreased affinity for the antibiotic. We have investigated the origins of penicillin-resistant strains by comparing the sequences of the transpeptidase domain of PBP2B from 6 penicillin-sensitive and 14 penicillin-resistant strains. In addition we have sequenced part of the amylomaltase gene from 2 of the sensitive and 6 of the resistant strains. The sequences of the amylomaltase gene of all of the strains and of the PBP2B gene of the penicillin-sensitive strain show that S. pneumoniae is genetically very uniform. In contrast the PBP2B genes of the penicillin-resistant strains show approximately equal to 14% sequence divergence from those of the penicillin-sensitive strains and the development of penicillin resistance has involved the replacement, presumably by transformation, of the original PBP2B gene by a homologous gene from an unknown source. This genetic event has occurred on at least two occasions, involving different sources, to produce the two classes of altered PBP2B genes found in penicillin-resistant strains of S. pneumoniae. There is considerable variation among the PBP2B genes of the resistant strains that may have arisen by secondary transformation events accompanied by mismatch repair subsequent to their original introductions into S. pneumoniae.

The extreme mutator effect of Escherichia coli mutD5 results from saturation of mismatch repair by excessive DNA replication errors

Escherichia coli mutator mutD5 is the most potent mutator known. The mutD5 mutation resides in the dnaQ gene encoding the proofreading exonuclease of DNA polymerase III holoenzyme. It has recently been shown that the extreme mutability of this strain results, in addition to a proofreading defect, from a defect in mutH, L, S-encoded postreplicational DNA mismatch repair. The following measurements of the mismatch-repair capacity of mutD5 cells demonstrate that this mismatch-repair defect is not structural, but transient. mutD5 cells in early log phase are as deficient in mismatch repair as mutL cells, but they become as proficient as wild-type cells in late log phase. Second, arrest of chromosomal replication in a mutD5-dnaA(Ts) strain at a nonpermissive temperature restores mismatch repair, even from the early log phase of growth. Third, transformation of mutD5 strains with multicopy plasmids expressing the mutH or mutL gene restores mismatch repair, even in rapidly growing cells. These observations suggest that the mismatch-repair deficiency of mutD strains results from a saturation of the mutHLS-mismatch-repair system by an excess of primary DNA replication errors due to the proofreading defect.

Heteroduplex DNA correction in Saccharomyces cerevisiae is mismatch specific and requires functional PMS genes

In vitro-constructed heteroduplex DNAs with defined mismatches were corrected in Saccharomyces cerevisiae cells with efficiencies that were dependent on the mismatch. Single-nucleotide loops were repaired very efficiently; the base/base mismatches G/T, A/C, G/G, A/G, G/A, A/A, T/T, T/C, and C/T were repaired with a high to intermediate efficiency. The mismatch C/C and a 38-nucleotide loop were corrected with low efficiency. This substrate specificity pattern resembles that found in Escherichia coli and Streptococcus pneumoniae, suggesting an evolutionary relationship of DNA mismatch repair in pro- and eucaryotes. Repair of the listed mismatches was severely impaired in the putative S. cerevisiae DNA mismatch repair mutants pms1 and pms2. Low-efficiency repair also characterized pms3 strains, except that correction of single-nucleotide loops occurred with an efficiency close to that of PMS wild-type strains. A close correlation was found between the repair efficiencies determined in this study and the observed postmeiotic segregation frequencies of alleles with known DNA sequence. This suggests an involvement of DNA mismatch repair in recombination and gene conversion in S. cerevisiae.

Nucleotide sequence of the Streptococcus pneumoniae hexB mismatch repair gene: homology of HexB to MutL of Salmonella typhimurium and to PMS1 of Saccharomyces cerevisiae

The Hex mismatch repair system of Streptococcus pneumoniae acts both during transformation (a recombination process that directly produces heteroduplex DNA) to correct donor strands and after DNA replication to remove misincorporated nucleotides. The hexB gene product is one of at least two proteins required for mismatch repair in this organism. The nucleotide sequence of a 2.7-kilobase segment from the S. pneumoniae chromosome that includes the 1.95-kilobase hexB gene was determined. The gene encodes a 73.5-kilodalton protein (649 residues). The spontaneous hex Rx chromosomal mutant allele with which a mutator phenotype has been associated is shown to result from a single base substitution (TAC to TAA) leading to a truncated HexB polypeptide (484 residues). The HexB protein is homologous to the MutL protein, which is required for methyl-directed mismatch repair in Salmonella typhimurium and Escherichia coli, and to the PMS1 gene product, which is likely to be involved in a mismatch correction system in Saccharomyces cerevisiae. The conservation of HexB-like proteins among procaryotic and eucaryotic organisms indicates that these proteins play an important common role in the repair process. This finding also suggests that the Hex, Mut, and PMS systems evolved from a common ancestor and that functionally similar mismatch repair systems could be widespread among procaryotic as well as eucaryotic organisms.

Cloning and nucleotide sequence of DNA mismatch repair gene PMS1 from Saccharomyces cerevisiae: homology of PMS1 to procaryotic MutL and HexB

The PMS1 gene from Saccharomyces cerevisiae, implicated in DNA mismatch repair in yeast cells (M. S. Williamson, J. C. Game, and S. Fogel, Genetics 110:609-646, 1985), was cloned, and the nucleotide sequence was determined. The nucleotide sequence showed a 2,712-base-pair open reading frame; the predicted molecular mass of the deduced protein is 103 kilodaltons. Deletion mutants of the open reading frame were constructed and genetically characterized. The deduced amino acid sequence of the PMS1 gene exhibited homology to those of the mutL gene from Salmonella typhimurium and the hexB gene from Streptococcus pneumoniae, genes required for DNA mismatch repair in these organisms. The homology suggests an evolutionary relationship of DNA mismatch repair in procaryotes and eucaryotes.

Nucleotide sequence of the Salmonella typhimurium mutL gene required for mismatch repair: homology of MutL to HexB of Streptococcus pneumoniae and to PMS1 of the yeast Saccharomyces cerevisiae

The mutL gene of Salmonella typhimurium LT2 is required for dam-dependent methyl-directed DNA mismatch repair. We have cloned and sequenced the mutL gene of S. typhimurium LT2 and compared its sequence with those of the hexB gene product of the gram-positive bacterium Streptococcus pneumoniae and the PMS1 gene product of the yeast Saccharomyces cerevisiae. MutL was found to be quite similar to the HexB mismatch repair protein of S. pneumoniae and to the mismatch repair protein PMS1 of the yeast S. cerevisiae. The significant similarities among these proteins were confined to their amino-terminal regions and suggest common evolution of the mismatch repair machinery in those organisms. The DNA sequence for mutL predicted a gene encoding a protein of 618 amino acid residues with a molecular weight of 67,761. The assignment of reading frame was confirmed by the construction of a chimeric protein consisting of the first 30 amino acids of LacZ fused to residues 53 through 618 of MutL. Interestingly, the presence of excess amounts of this fusion protein in wild-type mutL+ cells resulted in a trans-dominant effect causing the cell to exhibit a high spontaneous mutation frequency.

Cloning and characterization of mutL and mutS genes of Vibrio cholerae: nucleotide sequence of the mutL gene

The mutL and mutS genes of Vibrio cholerae have been identified using interspecific complementation of Escherichia coli mutL and mutS mutants with plasmids containing the gene bank of V. cholerae. The recombinant plasmid pJT470, containing a 4.7 kb fragment of V. cholerae DNA codes for a protein of molecular weight 92,000. The product of this gene reduces the spontaneous mutation frequency of the E. coli mutS mutant. The plasmid, designated pJT250, containing a 2.5 kb DNA fragment of V. cholerae and coding for a protein of molecular weight 62,000, complements the mutL gene function of E. coli mutL mutants. These gene products are involved in the repair of mismatches in DNA. The complete nucleotide sequence of mutL gene of V. cholerae has been determined.

Saturation of mismatch repair in the mutD5 mutator strain of Escherichia coli

The mutD (dnaQ) gene of Escherichia coli codes for the proofreading activity of DNA polymerase III. The very strong mutator phenotype of mutD5 strains seems to indicate that their postreplicational mismatch repair activity is also impaired. We show that the mismatch repair system of mutD5 strains is functional but saturated, presumably by the excess of DNA replication errors, since it is recovered by inhibiting chromosomal DNA replication. This recovery depends on de novo protein synthesis.

DNA mismatch correction in a defined system

DNA mismatch correction is a strand-specific process involving recognition of noncomplementary Watson-Crick nucleotide pairs and participation of widely separated DNA sites. The Escherichia coli methyl-directed reaction has been reconstituted in a purified system consisting of MutH, MutL, and MutS proteins, DNA helicase II, single-strand DNA binding protein, DNA polymerase III holoenzyme, exonuclease I, DNA ligase, along with ATP (adenosine triphosphate), and the four deoxynucleoside triphosphates. This set of proteins can process seven of the eight base-base mismatches in a strand-specific reaction that is directed by the state of methylation of a single d(GATC) sequence located 1 kilobase from the mispair.

Mismatch repair involving localized DNA synthesis in extracts of Xenopus eggs

Repair of heteroduplex DNA containing G.T or A.C mismatches or containing two tandem unpaired bases occurred in vitro with Xenopus egg extracts as detected by a physical assay. The repair was accompanied by a mismatch-stimulated and mismatch-localized DNA synthesis. Repaired molecules, separated from unrepaired molecules, showed a 20- to 100-fold increase in DNA synthesis in the region of the mismatch compared to regions distant from the mismatch. The remaining unrepaired heteroduplex DNA included molecules that also displayed mismatch-stimulated DNA synthesis in the mismatch-proximal regions. These may represent intermediates in the repair process. The patterns of DNA synthesis suggest that repair begins at some distance from the mismatch and that as much as 1 kilobase or more can be involved in the mismatch-stimulated synthesis.

Insertional mutagenesis by random cloning of antibiotic resistance genes into the genome of the cyanobacterium Synechocystis strain PCC 6803

The facultative heterotrophic cyanobacterium Synechocystis sp. strain PCC 6803 was transformed by HaeII Cmr fragments ligated at random to HaeII DNA fragments of the host genome. A similar transformation was done with an AvaII Kmr marker ligated to AvaII host DNA fragments. Integration of the resistance markers into the host genome led to a high frequency of stable Kmr and Cmr transformants. Physical analysis of individual transformants indicated that this result was due to homologous recombination by conversionlike events leading to insertion of the Cmr (or Kmr) gene between two HaeII (or AvaII) sites of the host genome, with precise deletion of the host DNA between these sites. In contrast, integrative crossover of circular DNA molecules with homology to the host DNA is very rare in this cyanobacterium. Strain PCC 6803 was shown to have about 12 genomic copies per cell in standard growth conditions, which complicates the detection of recessive mutations induced by chemical or UV mutagenesis. Random disruption of the host DNA by insertional transformation provides a convenient alternative to transposon mutagenesis in cyanobacteria and may help to overcome the difficulties encountered in generating recessive mutants by classical mutagenesis.

Gene conversion in Escherichia coli: the recF pathway for resolution of heteroduplex DNA

The independent repair of mismatched nucleotides present in heteroduplex DNA has been used to explain gene conversion and map expansion after general genetic recombination. We have constructed and purified heteroduplex plasmid DNAs that contain heteroallelic 10-base-pair insertion-deletion mismatches. These DNA substrates are similar in structure to the heteroduplex DNA intermediates that have been proposed to be produced during the genetic recombination of plasmids. These DNA substrates were transformed into wild-type and mutant Escherichia coli strains, and the fate of the heteroduplex DNA was determined by both restriction mapping and genetic tests. Independent repair events that yielded a wild-type Tetr gene were observed at a frequency of approximately 1% in both wild-type and recB recC sbcB mutant E. coli strains. The independent repair of small insertion-deletion-type mismatches separated by 1,243 base pairs was found to be reduced by recF, recJ, and ssb single mutations in an otherwise wild-type genetic background and reduced by recF, recJ, and recO mutations in a recB recC sbcB genetic background (the ssb mutation was not tested in the latter background). Independent repair of small insertion-deletion-type mismatched nucleotides that were as close as 312 nucleotides apart was observed. There was no apparent bias in favor of the insertion or deletion of mutant sequences.

Escherichia coli mutator mutD5 is defective in the mutHLS pathway of DNA mismatch repair

We have previously reported that the Escherichia coli mutator strain mutD5 was defective in the correction of bacteriophage M13mp2 heteroduplex DNA containing a T.G mismatch. Here, this defect was further investigated with regard to its interaction with the mutHLS pathway of mismatch repair. A set of 15 different M13mp2 heteroduplexes was used to measure the mismatch-repair capability of wild-type, mutL and mutD5 cells. Throughout the series, the mutD5 strain proved as deficient in mismatch repair as the mutL strain, indicating that the repair defect is similar in the two strains in both extent and specificity. [One exception was noted in the case a T.G mispair that was subject to VSP (Very Short Patch) repair. VSP repair was abolished by mutL but not by mutD.] Variation in the dam-methylation state of the heteroduplex molecules clearly affected repair in the wild-type strain but had no effect on either the mutD or mutL strain. Finally, mutDmutL or mutDmutS double-mutator strains were no more deficient in mismatch repair as were the single mutator strains. The combined results strongly argue that the mismatch-repair deficiency of mutD5 cells resides in the mutH,L,S-dependent pathway of mismatch repair and that the high mutation rate of mutD strains derives in part from this defect.