The role of Schizosaccharomyces pombe DNA repair enzymes Apn1p and Uve1p in the base excision repair of apurinic/apyrimidinic sites

In Schizosaccharomyces pombe the repair of apurinic/apyrimidinic (AP) sites is mainly initiated by AP lyase activity of DNA glycosylase Nth1p. In contrast, the major AP endonuclease Apn2p functions by removing 3'-alpha,beta-unsaturated aldehyde ends induced by Nth1p, rather than by incising the AP sites. S. pombe possesses other minor AP endonuclease activities derived from Apn1p and Uve1p. In this study, we investigated the function of these two enzymes in base excision repair (BER) for methyl methanesulfonate (MMS) damage using the nth1 and apn2 mutants. Deletion of apn1 or uve1 from nth1Delta cells did not affect sensitivity to MMS. Exogenous expression of Apn1p failed to suppress the MMS sensitivity of nth1Delta cells. Although Apn1p and Uve1p incised the oligonucleotide containing an AP site analogue, these enzymes could not initiate repair of the AP sites in vivo. Despite this, expression of Apn1p partially restored the MMS sensitivity of apn2Delta cells, indicating that the enzyme functions as a 3'-phosphodiesterase to remove 3'-blocked ends. Localization of Apn1p in the nucleus and cytoplasm hints at an additional function of the enzyme other than nuclear DNA repair. Heterologous expression of Saccharomyces cerevisiae homologue of Apn1p completely restored the MMS resistance of the nth1Delta and apn2Delta cells. This result confirms a difference in the major pathway for processing the AP site between S. pombe and S. cerevisiae cells.     

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

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

HIM1, a new yeast Saccharomyces cerevisiae gene playing a role in control of spontaneous and induced mutagenesis

We have identified a new Saccharomyces cerevisiae gene, HIM1, mapped on the right arm of the chromosome IV (ORF YDR317w), mutations in which led to an increase in spontaneous mutation rate and elevated the frequencies of mutations, induced by UV-light, nitrous acid, ethylmethane sulfonate and methylmethane sulfonate. At the same time, him1 mutation did not result in the increase of the sensitivity to the lethal action of these DNA-damaging agents. We tested the induced mutagenesis in double mutants carrying him1 mutation and mutations in other repair genes: apn1, blocking base excision repair; rad2, rev3, and rad54, blocking three principal DNA repair pathways; pms1, blocking mismatch repair; hsm2 and hsm3 mutations, which lead to a mutator effect. Epistatic analysis showed a synergistic interaction of him1 with pms1, apn1, and rad2 mutations, and epistasis with the rev3, the rad54, the hsm2, and the hsm3. To elucidate the role of the HIM1 in control of spontaneous mutagenesis, we checked the repair of DNA mispaired bases in the him1 mutant and discovered that it was not altered in comparison to the wild-type strain. In our opinion, our results suggest that HIM1 gene participates in the control of processing of mutational intermediates appearing during error-prone bypass of DNA damage.     

Deletion of the MAG1 DNA glycosylase gene suppresses alkylation-induced killing and mutagenesis in yeast cells lacking AP endonucleases.

DNA base excision repair (BER) is initiated by DNA glycosylases that recognize and remove damaged bases. The phosphate backbone adjacent to the resulting apurinic/apyrimidinic (AP) site is then cleaved by an AP endonuclease or glycosylase-associated AP lyase to invoke subsequent BER steps. We have used a genetic approach in Saccharomyces cerevisiae to address whether AP sites are blocks to DNA replication and the biological consequences if AP sites persist in the genome. We found that yeast cells deficient in the two AP endonucleases (apn1 apn2 double mutant) are extremely sensitive to killing by methyl methanesulfonate (MMS), a model DNA alkylating agent. Interestingly, this sensitivity can be reduced up to 2500-fold by deleting the MAG1 3-methyladenine DNA glycosylase gene, suggesting that Mag1 not only removes lethal base lesions, but also benign lesions and possibly normal bases, and that the resulting AP sites are highly toxic to the cells. This rescuing effect appears to be specific for DNA alkylation damage, since the mag1 mutation reduces killing effects of two other DNA alkylating agents, but does not alter the sensitivity of apn cells to killing by UV, gamma-ray or H(2)O(2). Our mutagenesis assays indicate that nearly half of spontaneous and almost all MMS-induced mutations in the AP endonuclease-deficient cells are due to Mag1 DNA glycosylase activity. Although the DNA replication apparatus appears to be incapable of replicating past AP sites, Polzeta-mediated translesion synthesis is able to bypass AP sites, and accounts for all spontaneous and MMS-induced mutagenesis in the AP endonuclease-deficient cells. These results allow us to delineate base lesion flow within the BER pathway and link AP sites to other DNA damage repair and tolerance pathways.     

Abasic sites linked to dUTP incorporation in DNA are a major cause of spontaneous mutations in absence of base excision repair and Rad17-Mec3-Ddc1 (9-1-1) DNA damage checkpoint clamp in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, inactivation of base excision repair (BER) AP endonucleases (Apn1p and Apn2p) results in constitutive phosphorylation of Rad53p and delay in cell cycle progression at the G2/M transition. These data led us to investigate genetic interactions between Apn1p, Apn2p and DNA damage checkpoint proteins. The results show that mec1 sml1, rad53 sml1 and rad9 is synthetic lethal with apn1 apn2. In contrast, apn1 apn2 rad17, apn1 apn2 ddc1 and apn1 apn2 rad24 triple mutants are viable, although they exhibit a strong Can(R) spontaneous mutator phenotype. In these strains, high Can(R) mutation rate is dependent upon functional uracil DNA N-glycosylase (Ung1p) and mutation spectra are dominated by AT to CG events. The results point to a role for Rad17-Mec3-Ddc1 (9-1-1) checkpoint clamp in the prevention of mutations caused by abasic (AP) sites linked to incorporation of dUTP into DNA followed by the excision of uracil by Ung1p. The antimutator role of the (9-1-1) clamp can either rely on its essential function in the induction of the DNA damage checkpoint or to another function that specifically impacts DNA repair and/or mutagenesis at AP sites. Here, we show that the abrogation of the DNA damage checkpoint is not sufficient to enhance spontaneous mutagenesis in the apn1 apn2 rad9 sml1 quadruple mutant. Spontaneous mutagenesis was also explored in strains deficient in the two major DNA N-glycosylases/AP-lyases (Ntg1p and Ntg2p). Indeed, apn1 apn2 ntg1 ntg2 exhibits a strong Ung1p-dependent Can(R) mutator phenotype with a spectrum enriched in AT to CG, like apn1 apn2 rad17. However, genetic analysis reveals that ntg1 ntg2 and rad17 are not epistatic for spontaneous mutagenesis in apn1 apn2. We conclude that under normal growth conditions, dUTP incorporation into DNA is a major source of AP sites that cause high genetic instability in the absence of BER factors (Apn1p, Apn2p, Ntg1p and Ntg2p) and Rad17-Mec3-Ddc1 (9-1-1) checkpoint clamp in yeast.     

The Saccharomyces cerevisiae ETH1 gene, an inducible homolog of exonuclease III that provides resistance to DNA-damaging agents and limits spontaneous mutagenesis

The recently sequenced Saccharomyces cerevisiae genome was searched for a gene with homology to the gene encoding the major human AP endonuclease, a component of the highly conserved DNA base excision repair pathway. An open reading frame was found to encode a putative protein (34% identical to the Schizosaccharomyces pombe eth1(+) [open reading frame SPBC3D6.10] gene product) with a 347-residue segment homologous to the exonuclease III family of AP endonucleases. Synthesis of mRNA from ETH1 in wild-type cells was induced sixfold relative to that in untreated cells after exposure to the alkylating agent methyl methanesulfonate (MMS). To investigate the function of ETH1, deletions of the open reading frame were made in a wild-type strain and a strain deficient in the known yeast AP endonuclease encoded by APN1. eth1 strains were not more sensitive to killing by MMS, hydrogen peroxide, or phleomycin D1, whereas apn1 strains were approximately 3-fold more sensitive to MMS and approximately 10-fold more sensitive to hydrogen peroxide than was the wild type. Double-mutant strains (apn1 eth1) were approximately 15-fold more sensitive to MMS and approximately 2- to 3-fold more sensitive to hydrogen peroxide and phleomycin D1 than were apn1 strains. Elimination of ETH1 in apn1 strains also increased spontaneous mutation rates 9- or 31-fold compared to the wild type as determined by reversion to adenine or lysine prototrophy, respectively. Transformation of apn1 eth1 cells with an expression vector containing ETH1 reversed the hypersensitivity to MMS and limited the rate of spontaneous mutagenesis. Expression of ETH1 in a dut-1 xthA3 Escherichia coli strain demonstrated that the gene product functionally complements the missing AP endonuclease activity. Thus, in apn1 cells where the major AP endonuclease activity is missing, ETH1 offers an alternate capacity for repair of spontaneous or induced damage to DNA that is normally repaired by Apn1 protein.     

Yeast MPH1 gene functions in an error-free DNA damage bypass pathway that requires genes from Homologous recombination, but not from postreplicative repair

The MPH1 gene from Saccharomyces cerevisiae, encoding a member of the DEAH family of proteins, had been identified by virtue of the spontaneous mutator phenotype of respective deletion mutants. Genetic analysis suggested that MPH1 functions in a previously uncharacterized DNA repair pathway that protects the cells from damage-induced mutations. We have now analyzed genetic interactions of mph1 with a variety of mutants from different repair systems with respect to spontaneous mutation rates and sensitivities to different DNA-damaging agents. The dependence of the mph1 mutator phenotype on REV3 and REV1 and the synergy with mutations in base and nucleotide excision repair suggest an involvement of MPH1 in error-free bypass of lesions. However, although we observed an unexpected partial suppression of the mph1 mutator phenotype by rad5, genetic interactions with other mutations in postreplicative repair imply that MPH1 does not belong to this pathway. Instead, mutations from the homologous recombination pathway were found to be epistatic to mph1 with respect to both spontaneous mutation rates and damage sensitivities. Determination of spontaneous mitotic recombination rates demonstrated that mph1 mutants are not deficient in homologous recombination. On the contrary, in an sgs1 background we found a pronounced hyperrecombination phenotype. Thus, we propose that MPH1 is involved in a branch of homologous recombination that is specifically dedicated to error-free bypass.     

A Uve1p-Mediated Mismatch Repair Pathway in Schizosaccharomyces pombe

UV damage endonuclease (Uve1p) from Schizosaccharomyces pombe was initially described as a DNA repair enzyme specific for the repair of UV light-induced photoproducts and proposed as the initial step in an alternative excision repair pathway. Here we present biochemical and genetic evidence demonstrating that Uve1p is also a mismatch repair endonuclease which recognizes and cleaves DNA 5' to the mispaired base in a strand-specific manner. The biochemical properties of the Uve1p-mediated mismatch endonuclease activity are similar to those of the Uve1p-mediated UV photoproduct endonuclease. Mutants lacking Uve1p display a spontaneous mutator phenotype, further confirming the notion that Uve1p plays a role in mismatch repair. These results suggest that Uve1p has a surprisingly broad substrate specificity and may function as a general type of DNA repair protein with the capacity to initiate mismatch repair in certain organisms.     

Overlapping specificities of base excision repair, nucleotide excision repair, recombination, and translesion synthesis pathways for DNA base damage in Saccharomyces cerevisiae

The removal of oxidative damage from Saccharomyces cerevisiae DNA is thought to be conducted primarily through the base excision repair pathway. The Escherichia coli endonuclease III homologs Ntg1p and Ntg2p are S. cerevisiae N-glycosylase-associated apurinic/apyrimidinic (AP) lyases that recognize a wide variety of damaged pyrimidines (H. J. You, R. L. Swanson, and P. W. Doetsch, Biochemistry 37:6033-6040, 1998). The biological relevance of the N-glycosylase-associated AP lyase activity in the repair of abasic sites is not well understood, and the majority of AP sites in vivo are thought to be processed by Apn1p, the major AP endonuclease in yeast. We have found that yeast cells simultaneously lacking Ntg1p, Ntg2p, and Apn1p are hyperrecombinogenic (hyper-rec) and exhibit a mutator phenotype but are not sensitive to the oxidizing agents H2O2 and menadione. The additional disruption of the RAD52 gene in the ntg1 ntg2 apn1 triple mutant confers a high degree of sensitivity to these agents. The hyper-rec and mutator phenotypes of the ntg1 ntg2 apn1 triple mutant are further enhanced by the elimination of the nucleotide excision repair pathway. In addition, removal of either the lesion bypass (Rev3p-dependent) or recombination (Rad52p-dependent) pathway specifically enhances the hyper-rec or mutator phenotype, respectively. These data suggest that multiple pathways with overlapping specificities are involved in the removal of, or tolerance to, spontaneous DNA damage in S. cerevisiae. In addition, the fact that these responses to induced and spontaneous damage depend upon the simultaneous loss of Ntg1p, Ntg2p, and Apn1p suggests a physiological role for the AP lyase activity of Ntg1p and Ntg2p in vivo.     

MPH1, a yeast gene encoding a DEAH protein, plays a role in protection of the genome from spontaneous and chemically induced damage

We have characterized the MPH1 gene from Saccharomyces cerevisiae. mph1 mutants display a spontaneous mutator phenotype. Homologs were found in archaea and in the EST libraries of Drosophila, mouse, and man. Mph1 carries the signature motifs of the DEAH family of helicases. Selected motifs were shown to be necessary for MPH1 function by introducing missense mutations. Possible indirect effects on translation and splicing were excluded by demonstrating nuclear localization of the protein and splicing proficiency of the mutant. A mutation spectrum did not show any conspicuous deviations from wild type except for an underrepresentation of frameshift mutations. The mutator phenotype was dependent on REV3 and RAD6. The mutant was sensitive to MMS, EMS, 4-NQO, and camptothecin, but not to UV light and X rays. Epistasis analyses were carried out with representative mutants from various repair pathways (msh6, mag1, apn1, rad14, rad52, rad6, mms2, and rev3). No epistatic interactions were found, either for the spontaneous mutator phenotype or for MMS, EMS, and 4-NQO sensitivity. mph1 slightly increased the UV sensitivity of mms2, rad6, and rad14 mutants, but no effect on X-ray sensitivity was observed. These data suggest that MPH1 is not part of a hitherto known repair pathway. Possible functions are discussed.     

Normal processing of AP sites in Apn1-deficient Saccharomyces cerevisiae is restored by Escherichia coli genes expressing either exonuclease III or endonuclease III

Escherichia coli exonuclease III and endonuclease III are two distinct DNA-repair enzymes that can cleave apurinic/apyrimidinic (AP) sites by different mechanisms. While the AP endonuclease activity of exonuclease III generates a 3'-hydroxyl group at AP sites, the AP lyase activity of endonuclease III produces a 3'-α,β unsaturated aldehyde that prevents DNA-repair synthesis. Saccharomyces cerevisiae Apn1 is the major AP endonuclease/3'-diesterase that also produces a 3'-hydroxyl group at the AP site, but it is unrelated to either exonuclease III or endonuclease III. apn1 deletion mutants are unable to repair AP sites generated by the alkylating agent methyl methane sulphonate and display a spontaneous mutator phenotype. This work shows that either exonuclease III or endonuclease III can functionally replace yeast Apn1 in the repair of AP sites. Two conclusions can be derived from these findings. The first of these conclusions is that yeast cells can complete the repair of AP sites even though they are cleaved by AP lyase. This implies that AP lyase can contribute significantly to the repair of AP sites and that yeast cells have the ability to process the α,β unsaturated aldehyde produced by endonuclease III. The second of these conclusions is that unrepaired AP sites are strictly the cause of the high spontaneous mutation rate in the apn1 deletion mutant.     

Abrogation of the Chk1-Pds1 checkpoint leads to tolerance of persistent single-strand breaks in Saccharomyces cerevisiae

In budding yeast, Apn1, Apn2, Tpp1, and Rad1/Rad10 are important enzymes in the removal of spontaneous DNA lesions. apn1 apn2 rad1 yeast are inviable due to accumulation of abasic sites and strand breaks with 3' blocking lesions. We found that tpp1 apn1 rad1 yeast exhibited slow growth but frequently gave rise to spontaneous slow growth suppressors that segregated as single-gene mutations. Using a candidate gene approach, we identified several tpp1 apn1 rad1 suppressors. Deleting uracil glycosylase suppressed both tpp1 apn1 rad1 and apn1 apn2 rad1 growth defects by reducing the abasic site burden. Mutants affecting the Chk1-Pds1 metaphase-anaphase checkpoint only suppressed tpp1 apn1 rad1 slow growth. In contrast, most S-phase checkpoint mutants were synthetically lethal in a tpp1 apn1 rad1 background. Epistasis analyses showed an additive effect between chk1 and ung1, indicating different mechanisms of suppression. Loss of Chk1 partially restored cell-growth parameters in tpp1 apn1 rad1 yeast, but at the same time exacerbated chromosome instability. We propose a model in which recombinational repair during S phase coupled with failure of the metaphase-anaphase checkpoint allows for tolerance of persistent single-strand breaks at the expense of genome stability.     

Polynucleotide kinase/phosphatase, Pnk1, is involved in base excision repair in Schizosaccharomyces pombe

We previously reported that Schizosaccharomyces pombe pnk1 cells are more sensitive than wild-type cells to γ-radiation and camptothecin, indicating that Pnk1 is required for DNA repair. Here, we report that pnk1pku70 and pnk1rhp51 double mutants are more sensitive to γ-radiation than single mutants, from which we infer that Pnk1's primary role is independent of either homologous recombination or non-homologous end joining mechanisms. We also report that pnk1 cells are more sensitive than wild-type cells to oxidizing and alkylating agents, suggesting that Pnk1 is involved in base excision repair. Mutational analysis of Pnk1 revealed that the DNA 3'-phosphatase activity is necessary for repair of DNA damage, whereas the 5'-kinase activity is dispensable. A role for Pnk1 in base excision repair is supported by genetic analyses which revealed that pnk1apn2 is synthetically lethal, suggesting that Pnk1 and Apn2 may function in parallel pathways essential for the repair of endogenous DNA damage. Furthermore, the nth1pnk1apn2 and tdp1pnk1apn2 triple mutants are viable, implying that single-strand breaks with 3'-blocked termini produced by Nth1 and Tdp1 contribute to synthetic lethality. We also examined the sensitivity to methyl methanesulfonate of all single and double mutant combinations of nth1, apn2, tdp1 and pnk1. Together, our results support a model where Tdp1 and Pnk1 act in concert in an Apn2-independent base excision repair pathway to repair 3'-blocked termini produced by Nth1; and they also provide evidence that Pnk1 has additional roles in base excision repair.     

RAD29 and RAD31--new genes from Saccharomyces cerevisiae yeasts, participating in control of DNA repair. II. Clarification of possible functions of these genes

Possible functions of previously described genes RAD29 and RAD31 involved in DNA repair were determined by analyzing the interaction between these genes and mutations in the genes of the three basic epistatic groups: RAD3 (nucleotide excision repair), RAD6 (error-prone mutagenic repair system), RAD52 (recombination repair pathway), and also the apn1 mutation that blocks the synthesis of major AP endonuclease (base excision repair). The results obtained in these studies and the estimation of the capability for excision repair of lesions induced by 8-metoxipsoralen and subsequent exposure to long-wavelength UV light in mutants for these genes led to the assumption that the RAD29 and RAD31 genes are involved in yeast DNA repair control.     

Endogenous DNA abasic sites cause cell death in the absence of Apn1, Apn2 and Rad1/Rad10 in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, mutations in APN1, APN2 and either RAD1 or RAD10 genes are synthetic lethal. In fact, apn1 apn2 rad1 triple mutants can form microcolonies of approximately 300 cells. Expression of Nfo, the bacterial homologue of Apn1, suppresses the lethality. Turning off the expression of Nfo induces G(2)/M cell cycle arrest in an apn1 apn2 rad1 triple mutant. The activation of this checkpoint is RAD9 dependent and allows residual DNA repair. The Mus81/Mms4 complex was identified as one of these back-up repair activities. Furthermore, inactivation of Ntg1, Ntg2 and Ogg1 DNA N-glycosylase/AP lyases in the apn1 apn2 rad1 background delayed lethality, allowing the formation of minicolonies of approximately 10(5) cells. These results demonstrate that, under physiological conditions, endogenous DNA damage causes death in cells deficient in Apn1, Apn2 and Rad1/Rad10 proteins. We propose a model in which endogenous DNA abasic sites are converted into 3'-blocked single-strand breaks (SSBs) by DNA N-glycosylases/AP lyases. Therefore, we suggest that the essential and overlapping function of Apn1, Apn2, Rad1/Rad10 and Mus81/Mms4 is to repair 3'-blocked SSBs using their 3'-phosphodiesterase activity or their 3'-flap endonuclease activity, respectively.     

MutS and MutL Are Dispensable for Maintenance of the Genomic Mutation Rate in the Halophilic Archaeon Halobacterium salinarum NRC-1

Background

The genome of the halophilic archaeon Halobacterium salinarum NRC-1 encodes for homologs of MutS and MutL, which are key proteins of a DNA mismatch repair pathway conserved in Bacteria and Eukarya. Mismatch repair is essential for retaining the fidelity of genetic information and defects in this pathway result in the deleterious accumulation of mutations and in hereditary diseases in humans.

Methodology/Principal Findings

We calculated the spontaneous genomic mutation rate of H. salinarum NRC-1 using fluctuation tests targeting genes of the uracil monophosphate biosynthesis pathway. We found that H. salinarum NRC-1 has a low incidence of mutation suggesting the presence of active mechanisms to control spontaneous mutations during replication. The spectrum of mutational changes found in H. salinarum NRC-1, and in other archaea, appears to be unique to this domain of life and might be a consequence of their adaption to extreme environmental conditions. In-frame targeted gene deletions of H. salinarum NRC-1 mismatch repair genes and phenotypic characterization of the mutants demonstrated that the mutS and mutL genes are not required for maintenance of the observed mutation rate.

Conclusions/Significance

We established that H. salinarum NRC-1 mutS and mutL genes are redundant to an alternative system that limits spontaneous mutation in this organism. This finding leads to the puzzling question of what mechanism is responsible for maintenance of the low genomic mutation rates observed in the Archaea, which for the most part do not have MutS and MutL homologs.     

Mutants with temperature-sensitive defects in the Escherichia coli mismatch repair system: sensitivity to mispairs generated in vivo

We have used direct selections to generate large numbers of mutants of Escherichia coli defective in the mismatch repair system and have screened these to identify mutants with temperature-sensitive defects. We detected and sequenced mutations that give rise to temperature-sensitive MutS, MutL, and MutH proteins. One mutation, mutS60, results in almost normal levels of spontaneous mutations at 37 degrees C but above this temperature gives rise to higher and higher levels of mutations, reaching the level of null mutations in mutS at 43 degrees C. However, at 37 degrees C the MutS60 protein can be much more easily titrated by mispairs than the wild-type MutS, as evidenced by the impaired ability to block homologous recombination in interspecies crosses and the increased levels of mutations from weak mutator alleles of mutD (dnaQ), mutC, and ndk. Strains with mutS60 can detect mispairs generated during replication that lead to mutation with much greater sensitivity than wild-type strains. The findings with ndk, lacking nucleotide diphosphate kinase, are striking. An ndk mutS60 strain yields four to five times the level of mutations seen in a full knockout of mutS. These results pose the question of whether similar altered Msh2 proteins result from presumed polymorphisms detected in tumor lines. The role of allele interactions in human disease susceptibility is discussed.     

Hydrogen peroxide induced mutations at the HPRT locus in primary human T-lymphocytes

Reactive oxygen species (ROS) produced by intracellular metabolism are believed to contribute to spontaneous mutagenesis in somatic cells. Hydrogen peroxide (H(2)O(2)) has been shown to induce a variety of genetic alterations, probably by the generation of hydroxyl radicals via the Fenton reaction. The kinds of DNA sequence alterations caused by H(2)O(2) in prokaryotic cells have been studied extensively, whereas relatively little is known about the mutational spectrum induced by H(2)O(2) in mammalian genes. We have used the T-cell cloning assay to study the ability of H(2)O(2) to induce mutations at the hypoxanthine guanine phosphoribosyltransferase (HPRT) locus in primary human lymphocytes. Treatment of cells for 1 h with 0.34-1.35 mM of H(2)O(2) caused a dose dependent decrease of cell survival and increase of the HPRT mutant frequency (MF). After 8 days of expression time, the highest dose of H(2)O(2) caused a 5-fold increase of MF compared to the untreated control cells. Mutant clones were collected and the genomic rearrangements at the T-cell receptor (TCR) gamma-locus were studied to identify independent mutations. RT-PCR and DNA sequencing was used to identify mutations in the HPRT coding region. Due to a relatively high frequency of sibling clones, only six independent mutations were obtained among the controls, and 20 among the H(2)O(2) treated cells. In both sets, single base pair substitutions were the most common type of mutation (5/6 and 13/20, respectively), with a predominance of transitions at GC base pairs, which is also the most common type of HPRT mutation in T-cells in vivo. Among the single base pair substitutions, five were new mutations not previously reported in the human HPRT mutation database. Overall, the kinds of mutation occurring in T-cells in vivo and H(2)O(2) treated cells were similar, albeit the number of mutants was too small to allow a meaningful statistical comparison. These results demonstrate that H(2)O(2) is mutagenic to primary human T-lymphocytes in vitro and induces mutations of the same kind that is observed in the background spectrum of HPRT mutation in T-cells in vivo.     

Role of a MutY DNA glycosylase in combating oxidative DNA damage in Helicobacter pylori

MutY is an adenine glycosylase that has the ability to efficiently remove adenines from adenine/7,8-dihydro-8-oxoguanine (8-oxo-G) or adenine/guanine mismatches, and plays an important role in oxidative DNA damage repair. The human gastric pathogen Helicobacter pylori has a homolog of the MutY enzyme. To investigate the physiological roles of MutY in H. pylori, we constructed and characterized a mutY mutant. H. pylori mutY mutants incubated at 5% O2 have a 325-fold higher spontaneous mutation rate than its parent. The mutation rate is further increased by exposing the mutant to atmospheric levels of oxygen, an effect that is not seen in an E. coli mutY mutant. Most of the mutations that occurred in H. pylori mutY mutants, as examined by rpoB sequence changes that confer rifampicin resistance, are GC to TA transversions. The H. pylori enzyme has the ability to complement an E. coli mutY mutant, restoring its mutation frequency to the wild-type level. Pure H. pylori MutY has the ability to remove adenines from A/8-oxo-G mismatches, but strikingly no ability to cleave A/G mismatches. This is surprising because E. coli MutY can more rapidly turnover A/G than A/8-oxo-G. Thus, H. pylori MutY is an adenine glycosylase involved in the repair of oxidative DNA damage with a specificity for detecting 8-oxo-G. In addition, H. pylori mutY mutants are only 30% as efficient as wild-type in colonizing the stomach of mice, indicating that H. pylori MutY plays a significant role in oxidative DNA damage repair in vivo.     

The fission yeast UVDR DNA repair pathway is inducible.

In addition to nucleotide excision repair (NER), the fission yeast Schizosaccharomyces pombe possesses a UV damage endonuclease (UVDE) for the excision of cyclobutane pyrimidine dimers and 6-4 pyrimidine pyrimidones. We have previously described UVDE as part of an alternative excision repair pathway, UVDR, for UV damage repair. The existence of two excision repair processes has long been postulated to exist in S.pombe, as NER-deficient mutants are still proficient in the excision of UV photoproducts. UVDE recognizes the phosphodiester bond immediately 5'of the UV photoproducts as the initiating event in this process. We show here that UVDE activity is inducible at both the level of uve1+ mRNA and UVDE enzyme activity. Further, we show that UVDE activity is regulated by the product of the rad12 gene.