Heteroduplex deoxyribonucleic acid base mismatch repair in bacteria

Barriers to genetic exchange between bacterial species: Streptococcus pneumoniae transformation

Interspecies genetic exchange is an important evolutionary mechanism in bacteria. It allows rapid acquisition of novel functions by transmission of adaptive genes between related species. However, the frequency of homologous recombination between bacterial species decreases sharply with the extent of DNA sequence divergence between the donor and the recipient. In Bacillus and Escherichia, this sexual isolation has been shown to be an exponential function of sequence divergence. Here we demonstrate that sexual isolation in transformation between Streptococcus pneumoniae recipient strains and donor DNA from related strains and species follows the described exponential relationship. We show that the Hex mismatch repair system poses a significant barrier to recombination over the entire range of sequence divergence (0.6 to 27%) investigated. Although mismatch repair becomes partially saturated, it is responsible for 34% of the observed sexual isolation. This is greater than the role of mismatch repair in Bacillus but less than that in Escherichia. The remaining non-Hex-mediated barrier to recombination can be provided by a variety of mechanisms. We discuss the possible additional mechanisms of sexual isolation, in view of earlier findings from Bacillus, Escherichia, and Streptococcus.

Adaptation to the environment: Streptococcus pneumoniae, a paradigm for recombination-mediated genetic plasticity?

Genetic plasticity plays a central role in the biology of the human pathogen Streptococcus pneumoniae. This is illustrated by the existence of at least 90 different capsular types (the polysaccharide capsule has an essential antiphagocytic function) as well as by the rapid emergence of penicillin-resistant (PenR) pneumococcal isolates. Natural genetic transformation is believed to be essential for this genetic plasticity; capsular types can be switched by intraspecies transformation, whereas interspecies transformation is responsible for the appearance, in the PenR isolates, of mosaic pbp genes, which encode proteins with reduced affinity for penicillin. Data on the regulation of competence for transformation in S. pneumoniae, on the control of intra- and interspecies genetic exchange and on the shuffling and capture of exogenous sequences during transformation are reviewed. Possible links between transformation and changes in environmental conditions are discussed, and the adaptive 'strategy' deduced for S. pneumoniae is compared with that of Escherichia coli.

Multiple heterologies increase mitotic double-strand break-induced allelic gene conversion tract lengths in yeast

Spontaneous and double-strand break (DSB)-induced allelic recombination in yeast was investigated in crosses between ura3 heteroalleles inactivated by an HO site and a +1 frameshift mutation, with flanking markers defining a 3.4-kbp interval. In some crosses, nine additional phenotypically silent RFLP mutations were present at approximately 100-bp intervals. Increasing heterology from 0.2 to 1% in this interval reduced spontaneous, but not DSB-induced, recombination. For DSB-induced events, 75% were continuous tract gene conversions without a crossover in this interval; discontinuous tracts and conversions associated with a crossover each comprised approximately 7% of events, and 10% also converted markers in unbroken alleles. Loss of heterozygosity was seen for all markers centromere distal to the HO site in 50% of products; such loss could reflect gene conversion, break-induced replication, chromosome loss, or G2 crossovers. Using telomere-marked strains we determined that nearly all allelic DSB repair occurs by gene conversion. We further show that most allelic conversion results from mismatch repair of heteroduplex DNA. Interestingly, markers shared between the sparsely and densely marked interval converted at higher rates in the densely marked interval. Thus, the extra markers increased gene conversion tract lengths, which may reflect mismatch repair-induced recombination, or a shift from restoration- to conversion-type repair.

The role of the mismatch repair machinery in regulating mitotic and meiotic recombination between diverged sequences in yeast

Nonidentical recombination substrates recombine less efficiently than do identical substrates in yeast, and much of this inhibition can be attributed to action of the mismatch repair (MMR) machinery. In this study an intron-based inverted repeat assay system has been used to directly compare the rates of mitotic and meiotic recombination between pairs of 350-bp substrates varying from 82% to 100% in sequence identity. The recombination rate data indicate that sequence divergence impacts mitotic and meiotic recombination similarly, although subtle differences are evident. In addition to assessing recombination rates as a function of sequence divergence, the endpoints of mitotic and meiotic recombination events involving 94%-identical substrates were determined by DNA sequencing. The endpoint analysis indicates that the extent of meiotic heteroduplex DNA formed in a MMR-defective strain is 65% longer than that formed in a wild-type strain. These data are consistent with a model in which the MMR machinery interferes with the formation and/or extension of heteroduplex intermediates during recombination.

Polarity of recombination in transformation of Streptococcus pneumoniae

In transformation of Streptococcus pneumoniae DNA enters the cell as single-strand fragments and integrates into the chromosome by homologous recombination. Deletions and insertions of a few hundred base pairs frequently stop the recombination process of a donor strand. In this work we took advantage of such interruptions of recombination to compare the transformation efficiencies of the segments 5'- and 3'-ward from a deletion. The deletion was created in the center of a fragment of the ami locus, and sites around the deletion were labeled by a frameshift generating a restriction site. Heteroduplexes were constructed containing two restriction sites on one strand and two different ones on the complementary strand. ami+ bacteria were transformed with such heteroduplexes. ami- transformants were isolated and individually underwent amplification of the transformed ami region. We have obtained two kinds of amplification products: short when the deletion was integrated, long when recombination stops at the deletion. Each long fragment was tested by the four restriction enzymes to detect which strand and which side of the deletion had recombined. We found that 80% of the cuts were located 5' to the deletion, showing that, in vivo, the 5' side is strongly favored by recombination. Further results suggest that exchanges occurring from 5' to 3' relative to the donor strand are more efficient than in the opposite direction, thus accounting for the 5' preference.

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.

Recognition of DNA alterations by the mismatch repair system

Misincorporation of non-complementary bases by DNA polymerases is a major source of the occurrence of promutagenic base-pairing errors during DNA replication or repair. Base-base mismatches or loops of extra bases can arise which, if left unrepaired, will generate point or frameshift mutations respectively. To counteract this mutagenic potential, organisms have developed a number of elaborate surveillance and repair strategies which co-operate to maintain the integrity of their genomes. An important replication-associated correction function is provided by the post-replicative mismatch repair system. This system is highly conserved among species and appears to be the major pathway for strand-specific elimination of base-base mispairs and short insertion/deletion loops (IDLs), not only during DNA replication, but also in intermediates of homologous recombination. The efficiency of repair of different base-pairing errors in the DNA varies, and appears to depend on multiple factors, such as the physical structure of the mismatch and sequence context effects. These structural aspects of mismatch repair are poorly understood. In contrast, remarkable progress in understanding the biochemical role of error-recognition proteins has been made in the recent past. In eukaryotes, two heterodimers consisting of MutS-homologous proteins have been shown to share the function of mismatch recognition in vivo and in vitro. A first MutS homologue, MSH2, is present in both heterodimers, and the specificity for mismatch recognition is dictated by its association with either of two other MutS homologues: MSH6 for recognition of base-base mismatches and small IDLs, or MSH3 for recognition of IDLs only. Mismatch repair deficiency in cells can arise through mutation, transcriptional silencing or as a result of imbalanced expression of these genes.

The mutK gene of Vibrio cholerae: a new gene involved in DNA mismatch repair

A new gene, mutK, of Vibrio cholerae, encoding a 19-kDa protein which is involved in repairing mismatches in DNA via a presumably methyl-independent pathway, has been identified. The product of the mutK gene cloned in either high- or low-copy-number vectors can reduce the spontaneous mutation frequency of Escherichia coli mutS, mutL, mutU, and dam mutants. The spontaneous mutation frequency of a chromosomal mutK knockout mutant was almost identical to that of wild-type V. cholerae cells, indicating that when the methyl-directed mismatch repair is blocked, the repair potential of MutK becomes apparent. The complete nucleotide sequence of the mutK gene has been determined, and the deduced amino acid sequence showed three open reading frames (ORFs), of which the ORF3 represents the mutK gene product. The mutK gene product has no significant homology with any of the proteins deposited in the EMBL data bank. ORF2, located upstream of mutK, encodes a 14-kDa protein which has more than 70% homology with a hypothetical protein found only downstream of the E. coli vsr gene. ORF1, located farther upstream of mutK, has more than 80% homology with a major cold shock protein found in several bacteria. Downstream of mutK, a partial ORF having 60% homology with an RNA methyltransferase has been identified. The mutK gene has recently been positioned in the ordered cloned DNA map of the genome of the V. cholerae strain from which the gene was isolated (10).

Eukaryotic mismatch repair: an update

The discovery that mutations in mismatch repair genes segregate with hereditary nonpolyposis colon cancer has awakened a great deal of interest in the study of the process of postreplicative mismatch repair. The characterisation of the principal players involved in this important metabolic pathway has been greatly facilitated by the amino acid sequence conservation among functional homologues of bacteria, yeast and mammals. The phenotypes of mismatch repair deficient mutants are also similar in many ways. In humans, mismatch repair malfunction demonstrates itself in the form of a mutator phenotype of the affected cells, an instability of microsatellite sequences and increased levels of somatic recombination. Moreover, mismatch repair deficient cells display also varying levels of tolerance to DNA damaging agents and are thought to be involved in the cell killing mediated by these agents. This article discusses some recent developments in this fast-moving field.

Fidelity levels of DNA polymerases in tumorigenic state cells and serially transplantable tumor cells

It is well known that point mutations exist in oncogenes and tumor suppressor genes of tumor cells, and one of the causes of these mutations may be misincorporation by error-prone DNA polymerases. This hypothesis is supported by the observation of decreased fidelity levels of DNA polymerases in mouse spleen containing tumorigenic cells after infection with Friend virus, and in aged animals that suffer high rates of tumorigenesis. However, this decrease in fidelity is disadvantageous for tumor cells maintained by serial transplantation. Therefore, we measured the fidelity levels of DNA polymerases in tumor cells transplanted through many passages. The fidelity levels of DNA polymerases from Yoshida ascites hepatoma, Rhodamine sarcoma, mouse ascites hepatoma-134, and Ehrlich ascites carcinoma cells derived from rats and mice are very high for in-vitro DNA synthesis on synthetic polynucleotides. These results suggest that many kinds of mutant cells arise during tumorigenesis. Among these mutant cells, cells showing decreased DNA polymerase(s) fidelities are present and these cells may undergo cell death. On the other hand, cells with mutations in various oncogenes and tumor suppressor genes and without mutations in DNA polymerase genes may survive as serially transplantable tumor cells.

DNA-dependent activation of the hMutSalpha ATPase

ATP hydrolysis by MutS homologs is required for function of these proteins in mismatch repair. However, the function of ATP hydrolysis in the repair reaction is controversial. In this paper we describe a steady-state kinetic analysis of the DNA-activated ATPase of human MutSalpha. Comparison of salt concentration effects on mismatch repair and mismatch-provoked excision in HeLa nuclear extracts with salt effects on the DNA-activated ATPase suggests that ATP hydrolysis by MutSalpha is involved in the rate determining step in the repair pathway. While the ATPase is activated by homoduplex and heteroduplex DNA, the half-maximal concentration for activation by heteroduplex DNA is significantly lower under physiological salt concentrations. Furthermore, at optimal salt concentration, heteroduplex DNA increases the kcat for ATP hydrolysis to a greater extent than does homoduplex DNA. We also demonstrate that the degree of ATPase activation is dependent on DNA chain length, with the kcat for hydrolysis increasing significantly with chain length of the DNA cofactor. These results are discussed in terms of the translocation (Allen, D. J., Makhov, A., Grilley, M., Taylor, J., Thresher, R., Modrich, P., and Griffith, J. D. (1997) EMBO J. 16, 4467-4476) and the molecular switch (Gradia, S., Acharya, S., and Fishel, R. (1997) Cell 91, 995-1005) models that invoke distinct roles for ATP hydrolysis in MutS homolog function.

Mismatch repair proteins regulate heteroduplex formation during mitotic recombination in yeast

Mismatch repair (MMR) proteins actively inhibit recombination between diverged sequences in both prokaryotes and eukaryotes. Although the molecular basis of the antirecombination activity exerted by MMR proteins is unclear, it presumably involves the recognition of mismatches present in heteroduplex recombination intermediates. This recognition could be exerted during the initial stage of strand exchange, during the extension of heteroduplex DNA, or during the resolution of recombination intermediates. We previously used an assay system based on 350-bp inverted-repeat substrates to demonstrate that MMR proteins strongly inhibit mitotic recombination between diverged sequences in Saccharomyces cerevisiae. The assay system detects only those events that reverse the orientation of the region between the recombination substrates, which can occur as a result of either intrachromatid crossover or sister chromatid conversion. In the present study we sequenced the products of mitotic recombination between 94%-identical substrates in order to map gene conversion tracts in wild-type versus MMR-defective yeast strains. The sequence data indicate that (i) most recombination occurs via sister chromatid conversion and (ii) gene conversion tracts in an MMR-defective strain are significantly longer than those in an isogenic wild-type strain. The shortening of conversion tracts observed in a wild-type strain relative to an MMR-defective strain suggests that at least part of the antirecombination activity of MMR proteins derives from the blockage of heteroduplex extension in the presence of mismatches.

Electrotransformation and natural transformation of Streptococcus pneumoniae: requirement of DNA processing for recombination

Electrotransformation has been used as a tool to introduce genes carried on replicative vectors in hundreds of bacterial species. In this study, the technique was used to try to obtain recombination of markers in the chromosome of the naturally transformable bacterium Streptococcus pneumoniae. Recombination was not observed even using naturally competent cultures. Both chromosomal and cloned DNA, denatured or native, were without effect. These results suggest that it is not sufficient to introduce DNA into the cell to obtain recombinants in this bacterium. The integration of markers into the chromosome in naturally competent cells must require DNA processing during entry. Electrotransformation of replicating plasmids is recA-independent but can be facilitated by a recA-dependent process. This facilitation required the induction of the natural competence machinery, probably involving partial homologous pairing.

Age dependent decline in the 3'-->5' exonuclease activity involved in proofreading during DNA synthesis

A 3'-->5' exonuclease found in rat liver excises mispaired nucleotides at the 3'-hydroxyl end of primer chains such as poly dA-d(T9-C). Consequently, the priming activity of the chain from which the mispaired base was cut is greatly increased during DNA synthesis. These results suggest that the 3'-->5' exonuclease acts as a proofreading enzyme during DNA synthesis. The activity of this 3'-->5' exonuclease in the liver of 24-month-old rats is approximately 30% lower than the activity found in 4-month-old rats. Furthermore, non-complementary nucleotide incorporations by DNA polymerases from aged rats are observed during DNA synthesis on poly dA-dT10. The number of misincorporations decreases in the presence of the 3'-->5' exonuclease, but not all errors are prevented even when DNA polymerase and 3'-->5' exonuclease are added at an activity ratio similar to that found in vivo. The data suggest that declines in both the fidelity of DNA polymerase and the 3'-->5' exonuclease activity related to proofreading during the aging process lead to a higher frequency of base misincorporations during DNA replication.

Effect of a 3'-->5' exonuclease with a proofreading function on the fidelity of error-prone DNA polymerase alpha from regenerating liver of aged rats

A nuclease that releases noncomplementary nucleotides from the 3'-end of DNA was isolated and highly purified from rat liver extract. The d(T9-C) priming activities for DNA synthesis in vitro by DNA polymerases alpha and beta were recovered by the addition of this enzyme, which itself does not contain a DNA polymerase activity. This nuclease hydrolysed nucleotides from the 3'-end, but did not remove [32P]-labeled nucleotides from the 5'-terminus of specifically labeled DNA. Also, the reaction products released from the 3'-end of DNA were all mononucleotides. These results indicate that the exonuclease is a 3'-->5' exonuclease with properties the same as those of DNase VII from human placenta. Rat DNase VII requires 4 mM MgCl2 or 0.125 mM MnCl2 for maximum activity, and shows a pH optimum of 7.5. These optimal conditions are similar to those of DNA polymerases, and indicate that both rat DNase VII and DNA polymerases are able to act under same conditions. Non-complementary nucleotide incorporation by DNA polymerase alpha from aged rat has been observed during in vitro DNA synthesis on poly dA-dT10. The amount of this mis-incorporation is decreased by the coexistence of the 3'-->5' exonuclease, but not all errors are edited out. Thus, this rat DNase VII is suggested to play an important role in proofreading during DNA synthesis.

The effect of mismatch repair and heteroduplex formation on sexual isolation in Bacillus

In Bacillus transformation, sexual isolation is known to be an exponential function of the sequence divergence between donor and recipient. Here, we have investigated the mechanism under which sequence divergence results in sexual isolation. We tested the effect of mismatch repair by comparing a wild-type strain and an isogenic mismatch-repair mutant for the relationship between sexual isolation and sequence divergence. Mismatch repair was shown to contribute to sexual isolation but was responsible for only a small fraction of the sexual isolation observed. Another possible mechanism of sexual isolation is that more divergent recipient and donor DNA strands have greater difficulty forming a heteroduplex because a region of perfect identity between donor and recipient is required for initiation of the heteroduplex. A mathematical model showed that this heteroduplex-resistance mechanism yields an exponential relationship between sexual isolation and sequence divergence. Moreover, this model yields an estimate of the size of the region of perfect identity that is comparable to independent estimates for Escherichia coli. For these reasons, and because all other mechanisms of sexual isolation may be ruled out, we conclude that resistance to heteroduplex formation is predominantly responsible for the exponential relationship between sexual isolation and sequence divergence in Bacillus transformation.

Competence-specific induction of recA is required for full recombination proficiency during transformation in Streptococcus pneumoniae

Transcriptional activation of the recA gene of Streptococcus pneumoniae was previously shown to occur at competence. A 5.7 kb recA-specific transcript that contained at least two additional genes, cinA and dinF, was identified. We now report the complete characterization of the recA operon and investigation of the role of the competence-specific induction of recA. The 5.7 kb competence-specific recA transcript is shown to include lytA, which encodes the pneumococcal autolysin, a protein previously shown to contribute to virulence of S. pneumoniae. Uncoupling (denoted Ind-) of recA and/or the downstream genes was achieved through the placement of transcription terminators within the operon, either upstream or downstream of recA. Prevention of the competence-specific induction of recA severely affected spontaneous transformation. Transformation efficiencies of recA+ (Ind-) and of wild-type cells were compared under various conditions and with different donor DNA. Chromosomal transformation was reduced 17-(chromosomal donor) to 45-fold (recombinant plasmid donor), depending on the donor DNA, and plasmid establishment was reduced 129-fold. Measurement of uptake of radioactively labelled donor DNA in transformed cells in parallel with scoring for transformants (chromosomal donor) revealed normal uptake, but a 21-fold reduction in recombination in a recA+ (Ind-) strain, indicating that the transformation defect was primarily in recombination. Strikingly enough, a much larger (460-fold) reduction in recombination was observed for the shortest homologous donor fragment used (878 nucleotides long). Possible interpretations of the observation that basal RecA appears unable to promote efficient recombination whatever the number and the length of donor fragments taken up are proposed. The role of recA induction is discussed in view of the potential contribution of transformation to genome plasticity in this pathogen.

Changes in fidelity levels of DNA polymerases alpha-1, alpha-2, and beta during ageing in rats

DNA polymerases (deoxynucleoside-triphosphate:DNA deoxynucleotidyltransferase EC 2.7.7.7.) were extracted from the regenerating livers of rats of various ages. The extracts were separated into three DNA polymerase fractions (alpha-1, alpha-2, and beta) by phosphocellulose column chromatography, and their fidelity levels were then monitored with the synthetic template-primer, poly (dA-dT), poly dA-dT10, or poly dC-poly dG. The fidelity levels of the three DNA polymerases from regenerating liver of rats younger than 20 months were high, while those of DNA polymerases from rats older than 20 months were significantly lower with similar profiles on all three template-primers. On the other hand, the fidelity levels of enzymes from 23- and 26-month-old rats were similar. These results indicate that the levels of error-prone DNA polymerases increase rapidly in the regenerating liver of rats from ages 20 to 23 months. This may due to the amplification of DNA polymerase gene mutations by an error-prone enzyme itself. However, the cells in which mutations in the functional gene occur may undergo cell death because the fidelity levels of the DNA polymerases in the older animals did not increase.

Constitution of the metabolic type of streptomycetes during the first hours of cultivation

Using the examples of biosynthesis of streptomycin, bialaphos, actinorhodin, oligoketides and autoregulators during the first hours of streptomycete cultivation, it is stressed that the external environment in cooperation with the internal metabolic abilities of the cell determines the metabolic type that would develop during the life cycle of the producing streptomycetes. If we accept that a certain metabolic type (from the point of view of the production of secondary metabolites) was determined already during the first hours of cultivation of the microorganisms, we must also admit that the availability of primary metabolites in the so-called production phase of growth (stationary phase, idiophase, etc.) is to a certain extent determined by the very early stages of strain development.

Methyl-directed repair of mismatched small heterologous sequences in cell extracts from Escherichia coli

The methyl-directed DNA repair efficiency of a set of M13mp18 heteroduplexes containing 1-8 or 22 unpaired bases was determined by using an in vitro DNA mismatch repair assay. The unpaired bases of each heteroduplex residing at overlapping recognition sites of two restriction endonucleases allow independent assay of repair on either DNA strand. Our results showed that the repair of small nucleotide heterologies in Escherichia coli extracts was very similar to base-base mismatch repair, being strand-specific and highly biased to the unmethylated strand. The in vitro activity was also dependent on products of mutH, mutL, mutS, and uvrD loci and was equally efficient on nucleotide insertions and deletions. The repair levels of small heterologies were affected by base composition of the heterologies. However, the extent of repair of heteroduplexes containing small heterologous sequences was found to decrease with an increase in the number of unpaired bases. Heteroduplexes containing an extra nucleotide of 22 bases provoked very low level of methyl-directed repair.

Characterization of Lactococcus lactis UV-sensitive mutants obtained by ISS1 transposition

Studies of cellular responses to DNA-damaging agents, mostly in Escherichia coli, have revealed numerous genes and pathways involved in DNA repair. However, other species, particularly those which exist under different environmental conditions than does E. coli, may have rather different responses. Here, we identify and characterize genes involved in DNA repair in a gram-positive plant and dairy bacterium, Lactococcus lactis. Lactococcal strain MG1363 was mutagenized with transposition vector pG+host9::ISS1, and 18 mutants sensitive to mitomycin and UV were isolated at 37 degrees C. DNA sequence analyses allowed the identification of 11 loci and showed that insertions are within genes implicated in DNA metabolism (polA, hexB, and deoB), cell envelope formation (gerC and dltD), various metabolic pathways (arcD, bglA, gidA, hgrP, metB, and proA), and, for seven mutants, nonidentified open reading frames. Seven mutants were chosen for further characterization. They were shown to be UV sensitive at 30 degrees C (the optimal growth temperature of L. lactis); three (gidA, polA, and uvs-75) were affected in their capacity to mediate homologous recombination. Our results indicate that UV resistance of the lactococcal strain can be attributed in part to DNA repair but also suggest that other factors, such as cell envelope composition, may be important in mediating resistance to mutagenic stress.

Gene targeting by linear duplex DNA frequently occurs by assimilation of a single strand that is subject to preferential mismatch correction

To study targeted recombination, a single linear 2-kb fragment of LEU2 DNA was liberated from a chromosomal site within the nucleus of Saccharomyces cerevisiae, by expression of the site-specific HO endonuclease. Gene targeting was scored by gene conversion of a chromosomal leu2 mutant allele by the liberated LEU2 fragment. This occurred at a frequency of only 2 x 10(-4), despite the fact that nearly all cells successfully repaired, by single-strand annealing, the chromosome break created by liberating the fragment. The frequency of Leu+ recombinants was 6- to 25-fold higher in pms1 strains lacking mismatch repair. In 70% of these cases, the colony was sectored for Leu+/Leu-. Similar results were obtained when a 4. 1-kb fragment containing adjacent LEU2 and ADE1 genes was liberated, to convert adjacent leu2 and ade1 mutations on the chromosome. These results suggest that a linear fragment is not assimilated into the recipient chromosome by two crossovers each close to the end of the fragment; rather, heteroduplex DNA between the fragment and the chromosome is apparently formed over the entire region, by the assimilation of one of the two strands of the linear duplex DNA. Moreover, the recovery of Leu+ transformants is frequently defeated by the cell's mismatch repair machinery; more than 85% of mismatches in heteroduplex DNA are corrected in favor of the resident, unbroken (mutant) strand.

The rnhB gene encoding RNase HII of Streptococcus pneumoniae and evidence of conserved motifs in eucaryotic genes

A single RNase H enzyme was detected in extracts of Streptococcus pneumoniae. The gene encoding this enzyme was cloned and expressed in Escherichia coli, as demonstrated by its ability to complement a double-mutant rnhA recC strain. Sequence analysis of the cloned DNA revealed an open reading frame of 290 codons that encodes a polypeptide of 31.9 kDa. The predicted protein exhibits a low level of homology (19% identity of amino acid residues) to RNase HII encoded by rnhB of E. coli. Identification of the S. pneumoniae RNase HII translation start site by amino-terminal sequencing of the protein and of mRNA start sites by primer extension with reverse transcriptase showed that the major transcript encoding rnhB begins at the protein start site. Comparison of the S. pneumoniae and E. coli RNase HII sequences and sequences of other, putative bacterial rnhB gene products surmised from sequencing data revealed three conserved motifs. Use of these motifs to search for homologous genes in eucaryotes demonstrated the presence of rnhB genes in a yeast and a roundworm. Partial rnhB gene sequences were detected among expressed sequences of mouse and human cells. From these data, it appears that RNase HII is universally present in living cells.

Age-associated changes in the template-reading fidelity of DNA polymerase alpha from regenerating rat liver

DNA polymerases (deoxynucleosidetriphosphate: DNA deoxynucleotidyltransferase EC 2.7.7.7.) were extracted from regenerating livers from young and aged rats. DNA polymerase alpha was separated and partially purified by DEAE-cellulose column chromatography, polyethyleneglycol precipitation, and phosphocellulose column chromatography, and fidelity levels were then monitored with the synthetic template-primer poly (dG-dC). The fidelity level of the DNA polymerase from regenerating liver a 4-month-old rat was very high, while that of the DNA polymerase from a 24-month-old rat was significantly decreased. To confirm this result, DNA was synthesized on poly (dG-dC) in a reaction mixture containing [32P]dTTP, and the synthetic polynucleotide was purified and digested with HhaI restriction endonuclease. After hydrolysis, the oligonucleotides were developed by two dimensional thin layer chromatography on PEI cellulose plates. Spots containing [32P]dTMP were observed when DNA polymerase from a 24 month-old rat was used, but none was found in polynucleotides synthesized using DNA polymerase from a 4 month-old rat. Nearest neighbor analysis suggested that dG-dT and dC-dT pairs were constructed by mis-incorporation due to DNA polymerase alpha.

Mismatch repair in Xenopus egg extracts: DNA strand breaks act as signals rather than excision points

In Xenopus egg extracts, DNA strand breaks (nicks) located 3' or 5' to a mismatch cause an overall 3-fold stimulation of the repair of the mismatch in circular heteroduplex DNA molecules. The increase in mismatch repair is almost entirely due to an increase in repair of the nicked strand, which is stimulated 5-fold. Repair synthesis is centered to the mismatch site, decreases symmetrically on both sides, and its position is not significantly altered by the presence of the nick. Therefore, it appears that in the Xenopus germ cells, the mismatch repair system utilizes nicks as signals for the induction and direction of mismatch repair, but not as the start or end point for excision and resynthesis.

Transcription of mutS and mutL-homologous genes in Saccharomyces cerevisiae during the cell cycle

Transcription of the Saccharomyces cerevisiae DNA mismatch repair genes PMS1, MSH2, and MSH6, a recently discovered homolog of the Escherichia coli mutS gene, was shown to be cell cycle regulated. In contrast, transcription of the MSH1, MSH3 and MLH1 genes was not regulated during the cell cycle. The MSH1 gene, which is thought to be involved in DNA mismatch repair in mitochondria, was also not induced under aerobic growth conditions. Regulation of the PMS1 gene was dependent on intact MluI cell cycle boxes, as demonstrated by analysis of a promoter mutant. Both reduced and increased expression of PMS1 resulted in a mitotic mutator phenotype. Analysis of mRNA levels was performed with a newly developed reverse transcription-PCR (polymerase chain reaction) approach using fluorescently labeled primers and an automated DNA sequencer for detection of PCR products.

Exclusion of long heterologous insertions and deletions from the pairing synapsis in pneumococcal transformation

We have studied the mode of recombination of six insertions during genetic transformation of Streptococcus pneumoniae. The six heterologous insertions are located at the same site in the ami locus of the pneumococcal chromosome; insertion sizes range from 4 to 1374 bp. With respect to single-point markers we found that the number of transformants in one-point crosses is reduced, while the number of wild-type transformants in two-point crosses is drastically increased, what we call hyper-recombination. The magnitude of the shift is correlated with the size of the insert. This effect could result either from a special repair pathway of multibase heteroduplexes or from the exclusion of multibase heterologous insertions out of the pairing synapsis. To test these hypotheses we have used insertions in two kinds of three-point crosses. The repair model predicts that the excess of wild-type transformants remains in one set of crosses but is suppressed in the second set. The results we obtained are reversed, ruling out the hypothesis of a repair process, but in agreement with predictions based on the exclusion model. Moreover, we have re-examined the situation of deletions, our previous results suggesting that deletions were likely to be converted at the heteroduplex step. Genetic evidence we obtained in this work no longer supports this hypothesis. Thus, long heterologous insertions are partly excluded at the pairing step.

Identification and characterization of a thermostable MutS homolog from Thermus aquaticus

Recognition of mispaired or unpaired bases during DNA mismatch repair is carried out by the MutS protein family. Here, we describe the isolation and characterization of a thermostable MutS homolog from Thermus aquaticus YT-1. Sequencing of the mutS gene predicts an 89.3-kDa polypeptide sharing extensive amino acid sequence homology with MutS homologs from both prokaryotes and eukaryotes. Expression of the T. aquaticus mutS gene in Escherichia coli results in a dominant mutator phenotype. Initial biochemical characterization of the thermostable MutS protein, which was purified to apparent homogeneity, reveals two thermostable activities, an ATP hydrolysis activity in which ATP is hydrolyzed to ADP and Pi and a specific DNA mismatch binding activity with affinities for heteroduplex DNAs containing either an insertion/deletion of one base or a GT mismatch. The ATPase activity exhibits a temperature optimum of approximately 80 degrees C. Heteroduplex DNA binding by the T. aquaticus MutS protein requires Mg2+ and occurs over a broad temperature range from 0 degrees C to at least 70 degrees C. The thermostable MutS protein may be useful for further biochemical and structural studies of mismatch binding and for applications involving mutation detection.

Homeologous recombination and mismatch repair during transformation in Streptococcus pneumoniae: saturation of the Hex mismatch repair system

The ability of the Hex generalized mismatch repair system to prevent recombination between partially divergent (also called homeologous) sequences during transformation in Streptococcus pneumoniae was investigated. By using as donor in transformation cloned fragments 1.7-17.5% divergent in DNA sequence from the recipient, it was observed that the Hex system prevents chromosomal integration of the least and the most divergent fragments but frequently fails to do so for other fragments. In the latter case, the Hex system becomes saturated (inhibited) due to an excess of mismatches: it is unable to repair a single mismatch located elsewhere on the chromosome. Further investigation with chromosomal donor DNA, carrying only one genetically marked divergent region, revealed that a single divergent fragment can lead to saturation of the Hex system. Increase in cellular concentration of either HexA, the MutS homologue that binds mismatches, or HexB, the MutL homologue for which the essential role in repair as yet remains obscure, was shown to restore repair ability in previously saturating conditions. Investigation of heterospecific transformation by chromosomal DNA from two related streptococcal species, Streptococcus oralis and Streptococcus mitis, also revealed complete saturation of the Hex system. Therefore the Hex system is not a barrier to interspecies recombination in S. pneumoniae. These results are discussed in light of those described for the Mut system of Escherichia coli.

Lethal and mutagenic actions of N-methyl-N'-nitro-N-nitrosoguanidine potentiated by oxidized glutathione, a seemingly harmless substance in the cellular environment

Both the lethal and the mutagenic actions of N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) on cells of Streptococcus pneumoniae were greatly potentiated by a component of yeast extract added to the cellular environment. This component was found to be an oxidation product of glutathione, glutathione disulfide (GSSG). At low concentrations in the medium, both GSSG and glutathione potentiated MNNG action, but at high concentrations, glutathione (and other sulfhydryl compounds) abolished the effect. Point mutations in a cellular gene conferred resistance to the potentiating effect, and they blocked uptake of either GSSG or glutathione into the cells as well. This gene apparently encodes a component of the system for glutathione transport in S. pneumoniae. The mechanism by which GSSG, an apparently innocuous substance in the environment, renders low levels of MNNG genotoxic and cytotoxic thus depends on its transport into the cell, where it is reduced by glutathione reductase and then activates intracellular MNNG. Also, it was observed that mutants of S. pneumoniae defective in DNA mismatch repair are more resistant to MNNG than are wild-type cells by a factor of 2.5.

Identification of mismatch repair genes and their role in the development of cancer

Mismatched base pairs are generated by damage to DNA, by damage to nucleotide precursors, by errors that occur during DNA replication, and during the formation of intermediates in genetic recombination. Enzyme systems that faithfully repair these DNA aberrations have been identified in a wide variety of organisms. At lease some of the components of these repair systems have been conserved, both structurally and functionally, throughout evolutionary time. In humans, defective mismatch repair genes have been linked to hereditary nonpolyposis colon cancer as well as to sporadic cancers that exhibit length polmorphisms in simple repeat (microsatellite) DNA sequences. The involvement of mismatch repair defects in microsatellite instability and tumorigenesis suggests that a generalized mutator phenotype is responsible for the large number of genetic alterations observed in tumors.

Characterization of a mammalian homolog of the Escherichia coli MutY mismatch repair protein

A protein homologous to the Escherichia coli MutY protein, referred to as MYH, has been identified in nuclear extracts of calf thymus and human HeLa cells. Western blot (immunoblot) analysis using polyclonal antibodies to the E. coli MutY protein detected a protein of 65 kDa in both extracts. Partial purification of MYH from calf thymus cells revealed a 65-kDa protein as well as a functional but apparently degraded form of 36 kDa, as determined by glycerol gradient centrifugation and immunoblotting with anti-MutY antibodies. Calf MYH is a DNA glycosylase that specifically removes mispaired adenines from A/G, A/7,8-dihydro-8-oxodeoxyguanine (8-oxoG or GO), and A/C mismatches (mismatches indicated by slashes). A nicking activity that is either associated with or copurified with MYH was also detected. Nicking was observed at the first phosphodiester bond 3' to the apurinic or apyrimidinic (AP) site generated by the glycosylase activity. The nicking activity on A/C mismatches was 30-fold lower and the activity on A/GO mismatches was twofold lower than that on A/G mismatches. No nicking activity was detected on substrates containing other selected mismatches or homoduplexes. Nicking activity on DNA containing A/G mismatches was inhibited in the presence of anti-MutY antibodies or upon treatment with potassium ferricyanide, which oxidizes iron-sulfur clusters. Gel shift analysis showed specific binding complex formation with A/G and A/GO substrates, but not with A/A, C.GO, and C.G substrates. Binding is sevenfold greater on A/GO substrates than on A/G substrates. The eukaryotic MYH may be involved in the major repair of both replication errors and oxidative damage to DNA, the same functions as those of the E. coli MutY protein.

Editing DNA replication and recombination by mismatch repair: from bacterial genetics to mechanisms of predisposition to cancer in humans

A hereditary form of colon cancer, hereditary non-polyposis colon cancer (HNPCC), is characterized by high instability of short repeated sequences known as microsatellites. Because the genes controlling microsatellite stability were known in bacteria and yeast, as was their evolutionary conservation, the search for human genes responsible for HNPCC became a 'targeted' search for known sequences. Mismatch-repair deficiency in bacteria and yeast produces multiple phenotypes as a result of its dual involvement in the editing of both replication errors and recombination intermediates. In addition, mismatch-repair functions are specialized in eukaryotes, characterized by specific mitotic (versus meiotic) functions, and nuclear (versus mitochondrial) localization. Given the number of phenotypes observed so far, we predict other links between mismatch-repair deficiency and human genetic disorders. For example, a similar type of sequence instability has been found in HNPCC tumours and in a number of neuro-muscular genetic disorders. Several human mitochondrial disorders display genomic instabilities reminiscent of yeast mitochondrial mismatch-repair mutants. In general, the process of mismatch repair is responsible for the constant maintenance of genome stability and its faithful transmission from one generation to the next. However, without genetic alteration, species would not be able to adapt to changing environments. It appears that nature has developed both negative and positive controls for genetic diversity. In bacteria, for example, an inducible system (sos) exists which generates genetic alterations in response to environmental stress (e.g. radiation, chemicals, starvation). Hence, the cost of generating diversity to adapt to changing conditions might be paid as sporadic gene alterations associated with disease.

Mismatch repair, genetic stability and tumour avoidance

Escherichia coli methyl-directed mismatch repair eliminates premutagenic lesions that arise via DNA biosynthetic errors; components of the repair system also block ectopic recombination between diverged DNA sequences. A mismatch-dependent, methyl-directed excision reaction that accounts for function of the system in replication fidelity has been reconstituted in a purified system dependent on ten activities. The reaction displays a broad specificity for mismatched base pairs and is characterized by an unusual bidirectional excision capability. Human cell nuclear extracts support strand-specific mismatch correction in a reaction that is similar to bacterial repair, with respect to both mismatch specificity and unusual features of mechanism. Like the bacterial system, the human pathway also functions in mutation avoidance because several classes of mutator human cells are deficient in the reaction. These include an alkylation-tolerance cell line that is resistant to the cytotoxic action of N-methyl-N'-nitro-nitrosoguanidine, as well as hypermutable RER+ tumour cells such as those associated with hereditary non-polyposis colon cancer. In vitro experiments indicate that the human repair reaction is dependent on at least six activities, excluding DNA ligase, and that distinct defects in the system can lead to the RER+ phenotype.

Hyperrecombination in pneumococcus: A/G to C.G repair and requirement for DNA polymerase I

During pneumococcal transformation, we had previously described that the ami36 mutation, which results from a C.G to A.T transversion, induces a large excess of wild-type recombinants in two point crosses. Upon donor-recipient DNA recombination, two heteroduplexes are generated by this mutation: A36/G+ and C+/T36. In two point crosses, hyperrecombination is observed only when transformation leads to the A/G mismatch. Here, we have studied the separate evolution of A36/G+ and C+/T36 heterozygotes created upon transformation of an ami36 mutant strain with artificial heteroduplex DNAs. We found that the A36/G+ mismatch leads to a preferential generation of wild-type progeny as compared with the complementary C+/T36 mismatch. This result suggests that A/G carrying transformants partly behave as wild-type homozygotes. The only way to account for such behavior is an excision repair correcting some A/G mispairs created upon transformation into C.G pairs. Moreover, we show that hyperrecombination triggered by ami36 is strongly reduced in a DNA polymerase I deficient strain. This strengthens the fact of DNA repair synthesis, which should be therefore prominently due to DNA polymerase I.

Bacterial gene transfer by natural genetic transformation in the environment

Natural genetic transformation is the active uptake of free DNA by bacterial cells and the heritable incorporation of its genetic information. Since the famous discovery of transformation in Streptococcus pneumoniae by Griffith in 1928 and the demonstration of DNA as the transforming principle by Avery and coworkers in 1944, cellular processes involved in transformation have been studied extensively by in vitro experimentation with a few transformable species. Only more recently has it been considered that transformation may be a powerful mechanism of horizontal gene transfer in natural bacterial populations. In this review the current understanding of the biology of transformation is summarized to provide the platform on which aspects of bacterial transformation in water, soil, and sediments and the habitat of pathogens are discussed. Direct and indirect evidence for gene transfer routes by transformation within species and between different species will be presented, along with data suggesting that plasmids as well as chromosomal DNA are subject to genetic exchange via transformation. Experiments exploring the prerequisites for transformation in the environment, including the production and persistence of free DNA and factors important for the uptake of DNA by cells, will be compiled, as well as possible natural barriers to transformation. The efficiency of gene transfer by transformation in bacterial habitats is possibly genetically adjusted to submaximal levels. The fact that natural transformation has been detected among bacteria from all trophic and taxonomic groups including archaebacteria suggests that transformability evolved early in phylogeny. Probable functions of DNA uptake other than gene acquisition will be discussed. The body of information presently available suggests that transformation has a great impact on bacterial population dynamics as well as on bacterial evolution and speciation.

Induction of recombination between homologous and diverged DNAs by double-strand gaps and breaks and role of mismatch repair

Sequence homology is expected to influence recombination. To further understand mechanisms of recombination and the impact of reduced homology, we examined recombination during transformation between plasmid-borne DNA flanking a double-strand break (DSB) or gap and its chromosomal homolog. Previous reports have concentrated on spontaneous recombination or initiation by undefined lesions. Sequence divergence of approximately 16% reduced transformation frequencies by at least 10-fold. Gene conversion patterns associated with double-strand gap repair of episomal plasmids or with plasmid integration were analyzed by restriction endonuclease mapping and DNA sequencing. For episomal plasmids carrying homeologous DNA, at least one input end was always preserved beyond 10 bp, whereas for plasmids carrying homologous DNA, both input ends were converted beyond 80 bp in 60% of the transformants. The system allowed the recovery of transformants carrying mixtures of recombinant molecules that might arise if heteroduplex DNA--a presumed recombination intermediate--escapes mismatch repair. Gene conversion involving homologous DNAs frequently involved DNA mismatch repair, directed to a broken strand. A mutation in the PMS1 mismatch repair gene significantly increased the fraction of transformants carrying a mixture of plasmids for homologous DNAs, indicating that PMS1 can participate in DSB-initiated recombination. Since nearly all transformants involving homeologous DNAs carried a single recombinant plasmid in both Pms+ and Pms- strains, stable heteroduplex DNA appears less likely than for homologous DNAs. Regardless of homology, gene conversion does not appear to occur by nucleolytic expansion of a DSB to a gap prior to recombination. The results with homeologous DNAs are consistent with a recombinational repair model that we propose does not require the formation of stable heteroduplex DNA but instead involves other homology-dependent interactions that allow recombination-dependent DNA synthesis.

Induction of recombination between homologous and diverged DNAs by double-strand gaps and breaks and role of mismatch repair

Sequence homology is expected to influence recombination. To further understand mechanisms of recombination and the impact of reduced homology, we examined recombination during transformation between plasmid-borne DNA flanking a double-strand break (DSB) or gap and its chromosomal homolog. Previous reports have concentrated on spontaneous recombination or initiation by undefined lesions. Sequence divergence of approximately 16% reduced transformation frequencies by at least 10-fold. Gene conversion patterns associated with double-strand gap repair of episomal plasmids or with plasmid integration were analyzed by restriction endonuclease mapping and DNA sequencing. For episomal plasmids carrying homeologous DNA, at least one input end was always preserved beyond 10 bp, whereas for plasmids carrying homologous DNA, both input ends were converted beyond 80 bp in 60% of the transformants. The system allowed the recovery of transformants carrying mixtures of recombinant molecules that might arise if heteroduplex DNA--a presumed recombination intermediate--escapes mismatch repair. Gene conversion involving homologous DNAs frequently involved DNA mismatch repair, directed to a broken strand. A mutation in the PMS1 mismatch repair gene significantly increased the fraction of transformants carrying a mixture of plasmids for homologous DNAs, indicating that PMS1 can participate in DSB-initiated recombination. Since nearly all transformants involving homeologous DNAs carried a single recombinant plasmid in both Pms+ and Pms- strains, stable heteroduplex DNA appears less likely than for homologous DNAs. Regardless of homology, gene conversion does not appear to occur by nucleolytic expansion of a DSB to a gap prior to recombination. The results with homeologous DNAs are consistent with a recombinational repair model that we propose does not require the formation of stable heteroduplex DNA but instead involves other homology-dependent interactions that allow recombination-dependent DNA synthesis.

Homologous recombination of monkey alpha-satellite repeats in an in vitro simian virus 40 replication system: possible association of recombination with DNA replication

To study homologous recombination between repeated sequences in an in vitro simian virus 40 (SV40) replication system, we constructed a series of substrate DNAs that contain two identical fragments of monkey alpha-satellite repeats. Together with the SV40-pBR322 composite vector encoding Apr and Kmr, the DNAs also contain the Escherichia coli galactokinase gene (galK) positioned between two alpha-satellite fragments. The alpha-satellite sequence used consists of multiple units of tandem 172-bp sequences which differ by microheterogeneity. The substrate DNAs were incubated in an in vitro SV40 DNA replication system and used to transform the E. coli galK strain DH10B after digestion with DpnI. The number of E. coli galK Apr Kmr colonies which contain recombinant DNAs were determined, and their structures were analyzed. Products of equal and unequal crossovers between identical 172-bp sequences and between similar but not identical (homeologous) 172-bp sequences, respectively, were detected, although those of the equal crossover were predominant among all of the galK mutant recombinants. Similar products were also observed in the in vivo experiments with COS1 cells. The in vitro experiments showed that these recombinations were dependent on the presence of both the SV40 origin of DNA replication and SV40 large T antigen. Most of the recombinant DNAs were generated from newly synthesized DpnI-resistant DNAs. These results suggest that the homologous recombination observed in this SV40 system is associated with DNA replication and is suppressed by mismatches in heteroduplexes formed between similar but not identical sequences.

Homologous recombination of monkey alpha-satellite repeats in an in vitro simian virus 40 replication system: possible association of recombination with DNA replication

To study homologous recombination between repeated sequences in an in vitro simian virus 40 (SV40) replication system, we constructed a series of substrate DNAs that contain two identical fragments of monkey alpha-satellite repeats. Together with the SV40-pBR322 composite vector encoding Apr and Kmr, the DNAs also contain the Escherichia coli galactokinase gene (galK) positioned between two alpha-satellite fragments. The alpha-satellite sequence used consists of multiple units of tandem 172-bp sequences which differ by microheterogeneity. The substrate DNAs were incubated in an in vitro SV40 DNA replication system and used to transform the E. coli galK strain DH10B after digestion with DpnI. The number of E. coli galK Apr Kmr colonies which contain recombinant DNAs were determined, and their structures were analyzed. Products of equal and unequal crossovers between identical 172-bp sequences and between similar but not identical (homeologous) 172-bp sequences, respectively, were detected, although those of the equal crossover were predominant among all of the galK mutant recombinants. Similar products were also observed in the in vivo experiments with COS1 cells. The in vitro experiments showed that these recombinations were dependent on the presence of both the SV40 origin of DNA replication and SV40 large T antigen. Most of the recombinant DNAs were generated from newly synthesized DpnI-resistant DNAs. These results suggest that the homologous recombination observed in this SV40 system is associated with DNA replication and is suppressed by mismatches in heteroduplexes formed between similar but not identical sequences.

Unrepaired heteroduplex DNA in Saccharomyces cerevisiae is decreased in RAD1 RAD52-independent recombination

A direct repeat recombination assay between SUP4 heteroalleles detects unrepaired heteroduplex DNA (hDNA) as sectored colonies. The frequency of unrepaired heteroduplex is dependent on the mismatch and is highest in a construct that generates C:C or G:G mispairs and lowest in one that generates T:G or C:A mispairs. In addition, unrepaired hDNA increases for all mismatches tested in pms1 mismatch repair-deficient strains. These results support the notion that hDNA is formed across the SUP4 repeats during the recombination event and is then subject to mismatch repair. The effects of various repair and recombination defective mutations on this assay were examined. Unrepaired heteroduplex increases significantly only in rad52 mutant strains. In addition, direct repeat recombination is reduced 2-fold in rad52 mutant strains, while in rad51, rad54, rad55 and rad57 mutants direct repeat recombination is increased 3-4-fold. Mutations in the excision repair gene, RAD1, do not affect the frequency of direct repeat recombination. However, the level of unrepaired heteroduplex is slightly decreased in rad1 mutant strains. Similar to previous studies, rad1 rad52 double mutants show a synergistic reduction in direct repeat recombination (35-fold). Interestingly, unrepaired heteroduplex is reduced 4-fold in the double mutants. Experiments with shortened repeats suggest that the reduction in unrepaired heteroduplex is due to decreased hDNA tract length in the double mutant strain.

Mismatch repair proteins MutS and MutL inhibit RecA-catalyzed strand transfer between diverged DNAs

Bacterial mutS and mutL mutations confer large increases in recombination between sequences that are divergent by several percent at the nucleotide level, an effect attributed to a role for products of these genes in control of recombination fidelity. Since MutS and MutL are proteins involved in the earliest steps of mismatch repair, including mismatch recognition by MutS, we have tested the possibility that they may affect strand exchange in response to occurrence of mispairs within the recombination heteroduplex. We show that MutS abolishes RecA-catalyzed strand transfer between fd and M13 bacteriophage DNAs, which vary by 3% at the nucleotide level, but is without effect on M13-M13 or fd-fd exchange. Although MutL alone has no effect on M13-fd heteroduplex formation, the protein dramatically enhances the inhibition of strand transfer mediated by MutS. Analysis of strand-transfer intermediates that accumulate in the presence of MutS and MutL indicates that the proteins block branch migration, presumably in response to occurrence of mispairs within newly formed heteroduplex.

Some features of base pair mismatch repair and its role in the formation of genetic recombinants

For the formation of recombinants involving closely linked markers, two distinct processes play a role. The recombinational interaction between homologous DNA molecules results in the presence of heteroduplex DNA joining the parental components of the recombinant. The presence of markers distinguishing the parents in the region of heteroduplex DNA can result in base pair mismatches. The post recombination repair of such mismatches can contribute to the separation of closely linked markers. The processes responsible for such repair also play roles in mutation avoidance. The specificities, functions and contribution to the formation of recombinants for closely linked markers of the processes in Escherichia coli are described.

Characterization of the mutX gene of Streptococcus pneumoniae as a homologue of Escherichia coli mutT, and tentative definition of a catalytic domain of the dGTP pyrophosphohydrolases

We show that deletion of a gene of Streptococcus pneumoniae, which we call mutX, confers a mutator phenotype to resistance to streptomycin. Analysis of the DNA sequence changes that occurred in several streptomycin-resistant mutants showed that mutations are unidirectional AT to CG transversions. The mutX gene is located immediately downstream of the previously identified ung gene and genetic evidence suggests that the two genes are co-ordinately regulated. Nucleotide sequence determination reveals that the mutX gene encodes a 17,870 Da protein (154 residues) which exhibits significant homology with the MutT protein of Escherichia coli, a nucleoside triphosphatase (dGTP pyrophosphohydrolase). The mutX gene complements the E. coli mutT mutator phenotype when introduced on a plasmid. Site-directed mutagenesis and analysis of nitrosoguanidine-induced mutT mutants suggest that a small region of high homology between the two proteins (61% identity over 23 residues) is part of the catalytic site of the nucleoside triphosphatase. Computer searching for sequence homology to MutX uncovered a second E. coli protein, the product of orf17, a gene of unknown function located near the ruvC gene. The region of high homology between MutX and MutT is also conserved in this protein, which raises the interesting possibility that the orf17 gene plays some role in determining mutation rates in E. coli. Finally, a small set of proteins, including a family of virus-encoded proteins and two evolutionarily conserved proteins encoded by an antisense transcript from the Xenopus laevis and human bFGF genes, were also found to harbour significant homology to this highly conserved region.

Patch length of localized repair events: role of DNA polymerase I in mutY-dependent mismatch repair

In vivo experiments with heteroduplex lambda genomes show that the MutY mismatch repair system of Escherichia coli defines an average repair tract that is shorter than 27 nucleotides and longer than 9 nucleotides and extends 3' from the corrected adenine. The phenotype of a mutant defective in DNA polymerase I shows that this enzyme plays a significant, though not an essential, role in the in vivo repair of apurinic sites generated by this system. Evidence is presented that in the absence of polymerase I the repair tracts are modestly longer than in the polA+ extending in the 5' direction from the corrected adenine, suggesting a role for another DNA polymerase.

Analysis of the genetic requirements for viability of Escherichia coli K-12 DNA adenine methylase (dam) mutants

RecBCD protein, necessary for Escherichia coli dam mutant viability, is directly required for DNA repair. Recombination genes recF+, recN+, recO+, and recQ+ are not essential for dam mutant viability; they are required for recBC sbcBC dam mutant survival. mutH, mutL, or mutS mutations do not suppress subinduction of SOS genes in dam mutants.

Mismatch recognition in chromosomal interactions and speciation

Homologous chromosomes interact during meiosis by means of proteins involved in recombination and in the recognition and repair of mismatched base pairs. Recombination proteins bring homologous chromosomes or chromosomal regions together by facilitating the search for DNA homology and by catalyzing strand exchange between homologous molecules or regions. Mismatch recognition and repair proteins act as editors of recombination and appear to disrupt those DNA associations that contain mismatched base pairs. Thus, it may be that, as chromosomes diverge in their primary sequence and become increasingly polymorphic, recombinational interactions leading to chromosome pairing and recombination tend to be inhibited. Decreasing homologous interactions within and between chromosomes will clearly contribute to maintaining the integrity of individual chromosomes and may ultimately lead, as a result of sterile meioses, to the reproductive isolation of closely related species.