The human OGG1 gene: structure, functions, and its implication in the process of carcinogenesis

A particularly important stress for all cells is the one produced by reactive oxygen species (ROS) that are formed as byproducts of cell metabolism. Among DNA damages induced by ROS, 8-hydroxyguanine (8-OH-G) is certainly the product that has retained most of the attention in the past few years. The biological relevance of 8-OH-G in DNA has been unveiled by the study of Escherichia coli and Saccharomyces cerevisiae genes involved in the neutralization of the mutagenic effects of 8-OH-G. These genes, fpg and mutY for E. coli and OGG1 for yeast, code for DNA glycosylases. Inactivation of any of those genes leads to a spontaneous mutator phenotype, characterized by the increase in GC to TA transversions. In yeast, the OGG1 gene encodes a DNA glycosylase/AP lyase that excises 8-OH-G from DNA. In human cells, the OGG1 gene is localized on chromosome 3p25 and encodes two forms of hOgg1 protein which result from an alternative splicing of a single messenger RNA. The alpha-hOgg1 protein has a nuclear localization whereas the beta-hOgg1 is targeted to the mitochondrion. Biochemical studies on the alpha-hOgg1 protein show that it is a DNA glycosylase/AP lyase that excises 8-OH-G and Fapy-G from gamma-irradiated DNA. Several approaches have been used to study the biological role of OGG1 in mammalian cells, ranging from its overexpression in cell lines to the generation of homozygous ogg1-/- null mice. Furthermore, to explore a possible role in the prevention of cancer, the cDNA coding for alpha-hOgg1 has been sequenced in human tumors. All these results point to 8-OH-G as an endogenous source of mutations in eukaryotes and to its likely involvement in the process of carcinogenesis. A review of the recent literature on the mammalian Ogg1 proteins, the main repair system involved in the elimination of this mutagenic lesion, is presented.     

Expression of the Fpg protein of Escherichia coli in Saccharomyces cerevisiae: effects on spontaneous mutagenesis and sensitivity to oxidative DNA damage

The biological relevance of oxidative DNA damage has been unveiled by the identification of genes such as fpg of E. coli or OGG1 of Saccharomyces cerevisiae. Both Fpg and Ogg1 proteins are DNA glycosylases/AP lyases that excise 7,8-dihydro-8-oxoguanine (8-OxoG) and 2,6-diamino-4-hydroxy-5-N-methylformamidopyrimidine (Me-FapyG) from damaged DNA. Although similar, the enzymatic and biological properties of Fpg and Ogg1 proteins are not identical. Furthermore, the Fpg and Ogg1 proteins do not show significant sequence homologies. In this study, we investigated the ability of the Fpg protein of E. coli to complement phenotypes thought to be due to oxidative DNA damage in Saccharomyces cerevisiae. To express Fpg in yeast, the coding sequence of the fpg gene was placed under the control of a strong yeast promoter in the expression vector pCM190 to generate the pFPG240 plasmid. The Ogg1-deficient yeast strain CD138, ogg1::TRP1, was transformed with pFPG240 and the expression of Fpg was measured. Expression of Fpg in yeast harboring pFPG240 was revealed by efficient release of Me-FapyG and cleavage of 8-OxoG-containing duplexes by cell free protein extracts. The production of the Fpg protein in yeast cells was further demonstrated by immunoblotting analysis using anti-Fpg antibodies. Fpg expression suppresses the spontaneous mutator phenotype of ogg1- yeast for the production of canavanin resistant mutants (CanR) and Lys+ revertants. Fpg expression also restores the capacity of plasmid DNA treated with methylene blue plus visible light (MB-light) to transform the yeast ogg1- rad1- double mutant.     

Modulation of oxidative mutagenesis and carcinogenesis by polymorphic forms of human DNA repair enzymes

Chromosome DNA is continuously exposed to various endogenous and exogenous mutagens. Among them, oxidation is one of the most common threats to genetic stability, and multiple DNA repair enzymes protect chromosome DNA from the oxidative damage. In Escherichia coli, three repair enzymes synergistically reduce the mutagenicity of oxidized base 8-hydroxy-guanine (8-OH-G). MutM DNA glycosylase excises 8-OH-G from 8-OH-G:C pairs in DNA and MutY DNA glycosylase removes adenine incorporated opposite template 8-OH-G during DNA replication. MutT hydrolyzes 8-OH-dGTP to 8-OH-dGMP in dNTP pool, thereby reducing the chance of misincorporation of 8-OH-dGTP by DNA polymerases. Simultaneous inactivation of MutM and MutY dramatically increases the frequency of spontaneous G:C to T:A mutations, and the deficiency of MutT leads to the enhancement of T:A to G:C transversions more than 1000-fold over the control level. In humans, the functional homologues of MutM, MutY and MutT, i.e., OGG1, MUTYH (MYH) and MTH1, contribute to the protection of genomic DNA from oxidative stress. Interestingly, several polymorphic forms of these proteins exist in human populations, and some of them are suggested to be associated with cancer susceptibility. Here, we review the polymorphic forms of OGG1, MUTYH and MTH1 involved in repair of 8-OH-G and 8-OH-dGTP, and discuss the significance of the polymorphisms in the maintenance of genomic integrity. We also summarize the polymorphic forms of human DNA polymerase eta, which may be involved in damage tolerance and mutagenesis induced by oxidative stress.     

Genomic structure and chromosomal localization of the mouse Ogg1 gene that is involved in the repair of 8-hydroxyguanine in DNA damage

8-Hydroxyguanine (7,8-dihydro-8-oxoguanine: oh⁸Gua) is a damaged form of guanine induced by oxygen-free radicals and causes GC to TA transversions. Previously we isolated the hOGG1 gene, a human homolog of the yeast OGG1 gene, which encodes a DNA glycosylase and lyase to excise oh⁸Gua in DNA. In this study, we isolated a mouse homolog (Ogg1) of the OGG1 gene, characterized oh⁸Gua-specific DNA glycosylase/AP lyase activities of its product, and determined chromosomal localization and exon-intron organization of this gene. A predicted protein possessed five domains homologous to human and yeast OGG1 proteins. Helix-hairpin-helix and C₂H₂ zinc finger-like DNA-binding motifs found in human and yeast OGG1 proteins were also retained in mouse Ogg1 protein. The properties of a GST fusion protein were identical to human and yeast OGG1 proteins in glycosylase/lyase activities, their substrate specificities, and suppressive activities against the spontaneous mutagenesis of an Escherichia coli mutM mutY double mutant. The mouse Ogg1 gene was mapped to Chromosome (Chr) 6, and consisted of 7 exons approximately 6 kb long. Two DNA-binding motifs were encoded in exons 4 through 5. These data will facilitate the investigation of the OGG1 gene to elucidate the relationship between oxidative DNA damage and carcinogenesis. Received: 17 July 1997 / Accepted: 15 September 1997     

Effects of base excision repair proteins on mutagenesis by 8-oxo-7,8-dihydroguanine (8-hydroxyguanine) paired with cytosine and adenine

8-Oxo-7,8-dihydroguanine (8-oxo-Gua, also known as 8-hydroxyguanine) is a major base lesion that is generated by reactive oxygen species in both the DNA and nucleotide pool. The role of DNA glycosylases, which initiate base excision repair, in the mutagenic processes of 8-oxo-Gua in DNA and 8-oxo-7,8-dihydro-2′-deoxyguanosine 5′-triphosphate (8-oxo-dGTP, also known as 8-hydroxy-2′-deoxyguanosine 5′-triphosphate) were investigated using supF shuttle plasmids propagated in human cells. The DNA glycosylases, OGG1, MUTYH, NTH1, and NEIL1, in 293T cells were individually knocked-down by siRNAs and plasmid DNAs containing an 8-oxo-Gua:C/8-oxo-Gua:A pair, and 8-oxo-dGTP plus unmodified plasmid DNA were then introduced into the knocked-down cells. The knock-down of OGG1, MUTYH, NTH1, and NEIL1 resulted in a significant increase in G:C → T:A transversions caused by the 8-oxo-Gua:C pair in the shuttle plasmid. The knock-down of MUTYH resulted in a reduction in A:T → C:G transversions induced by 8-oxo-dGTP and the 8-oxo-Gua:A pair, but the knockdown of OGG1, NTH1, and NEIL1 had no effect on mutagenesis. These results indicate that all of the above DNA glycosylases suppress mutations caused by 8-oxo-Gua:C in DNA. In contrast, it appears that MUTYH enhances A:T → C:G mutations caused by 8-oxo-dGTP.     

Rat 7,8-dihydro-8-oxoguanine DNA glycosylase: substrate specificity, kinetics and cleavagemechanism at an apurinic site.

Reactive oxygen species produce different lesions in DNA. Among them, 7,8-dihydro-8-oxoguanine (8-oxoG) is one of the major oxidative products implicated in mutagenesis. This lesion is removed from damaged DNA by base excision repair, and genes coding for 8-oxoG-DNA glycosylases have been isolated from bacteria, yeast and human cells. We have isolated and characterized the cDNA encoding the rat 8-oxoG-DNA glycosylase (rOGG1). Expression of the cDNA in the fgp mutY Escherichia coli double mutant allowed the purification of the untagged rOGG1 protein. It excises 8-oxoG from DNA with a strong preference for duplex DNA containing 8-oxoG:C base pairs. rOGG1 also acts on formamidopyrimidine (FaPy) residues, and the K m values on 8-oxoG and FaPy residues are 18.8 and 9.7 nM, respectively. When acting on an oligonucleotide containing an 8-oxoG residue, rOGG1 shows a beta-lyase activity that nicks DNA 3' to the lesion. However, rOGG1 acts on a substrate containing an apurinic site by a beta-delta elimination reaction and proceeds through a Schiff base intermediate. Expression of rOGG1 in E.coli fpg mutY suppresses its spontaneous mutator phenotype.     

Involvement of mammalian OGG1(MMH) in excision of the 8-hydroxyguanine residue in DNA

8-Hydroxyguanine (7,8-dihydro-8-oxoguanine, abbreviated as 8-OH-G or 8-oxoG) is the site of a frequent mutagenic DNA lesion produced by oxidative damage. MutM of E. coli and OGG1 of Saccharomyces cervisiae are known to possess 8-OH-G glycosylase and apurinic (AP) site lyase activity. cDNA clones of four isoforms (types 1a, 1b, 1c, and 2) of human OGG1 homologs (hMMH) were isolated. In order to examine whether expression of hMMH (hOGG1) protein actually occurs in human cells, we prepared type 1a specific antibody, and by using this antibody, we showed that type 1a protein isolated from HeLaS3 has 8-OH-G glycosylase/lyase activity. Furthermore, we showed that type 1a protein is a major enzyme for repair of the 8-OH-G lesion in human cells. In our second study, we generated a mouse line carrying an inactivated mutant Mmh allele by targeted gene disruption. Liver extracts of Mmh homozygous mutant mice were found to have loss of the nicking activity for the 8-OH-G site. In addition, the amount of endogenous 8-OH-G in liver DNA of the homozygous mice increased linearly with age, reaching 7-fold increase in 14 week old mice, over that of wild-type or heterozygous mice. Furthermore, when homozygous mice were fed the oxygen radical-forming agent KBrO3, to provide oxidative stress, the level of 8-OH-G in kidney DNA was tremendously increased: more than 200-fold as that of control mice without oxidative stress after 12 weeks of age. These results indicate that Ogg1/Mmh plays an essential role in the repair of the 8-OH-G residue in DNA produced by oxidative stress.     

Human DNA glycosylases of the bacterial Fpg/MutM superfamily: an alternative pathway for the repair of 8-oxoguanine and other oxidation products in DNA

The mild phenotype associated with targeted disruption of the mouse OGG1 and NTH1 genes has been attributed to the existence of back-up activities and/or alternative pathways for the removal of oxidised DNA bases. We have characterised two new genes in human cells that encode DNA glycosylases, homologous to the bacterial Fpg (MutM)/Nei class of enzymes, capable of removing lesions that are substrates for both hOGG1 and hNTH1. One gene, designated HFPG1, showed ubiquitous expression in all tissues examined whereas the second gene, HFPG2, was only expressed at detectable levels in the thymus and testis. Transient transfections of HeLa cells with fusions of the cDNAs to EGFP revealed intracellular sorting to the nucleus with accumulation in the nucleoli for hFPG1, while hFPG2 co-localised with the 30 kDa subunit of RPA. hFPG1 was purified and shown to act on DNA substrates containing 8-oxoguanine, 5-hydroxycytosine and abasic sites. Removal of 8-oxoguanine, but not cleavage at abasic sites, was opposite base-dependent, with 8-oxoG:C being the preferred substrate and negligible activity towards 8-oxoG:A. It thus appears that hFPG1 has properties similar to mammalian OGG1 in preventing mutations arising from misincorporation of A across 8-oxoG and could function as a back-up repair activity for OGG1 in ogg1(-/-) mice.     

A Novel Role for Escherichia coli Endonuclease VIII in Prevention of Spontaneous G→T Transversions

In the bacterium Escherichia coli, oxidized pyrimidines are removed by two DNA glycosylases, endonuclease III and endonuclease VIII (endo VIII), encoded by the nth and nei genes, respectively. Double mutants lacking both of these activities exhibit a high spontaneous mutation frequency, and here we show that all of the mutations observed in the double mutants were G:C-->A:T transitions; no thymine mutations were found. These findings are in agreement with the preponderance of C-->T transitions in the oxidative and spontaneous mutational databases. The major oxidized purine lesion in DNA, 7,8-dihydro-8-oxoguanine (8-oxoG), is processed by two DNA glycosylases, formamidopyrimidine DNA glycosylase (Fpg), which removes 8-oxoG opposite C, and MutY DNA glycosylase, which removes misincorporated A opposite 8-oxoG. The high spontaneous mutation frequency previously observed in fpg mutY double mutants was significantly enhanced by the addition of the nei mutation, suggesting an overlap in the substrate specificities between endo VIII and Fpg/MutY. When the mutational specificity was examined, all of the mutations observed were G:C-->T:A transversions, indicating that in the absence of Fpg and MutY, endo VIII serves as a backup activity to remove 8-oxoG. This was confirmed by showing that, indeed, endo VIII can recognize 8-oxoG in vitro.     

Bacterial DNA repair genes and their eukaryotic homologues: 2. Role of bacterial mutator gene homologues in human disease. Overview of nucleotide pool sanitization and mismatch repair systems

Since the discovery of the first E. coli mutator gene, mutT, most of the mutations inducing elevated spontaneous mutation rates could be clearly attributed to defects in DNA repair. MutT turned out to be a pyrophosphohydrolase hydrolyzing 8-oxodGTP, thus preventing its incorporation into DNA and suppresing the occurrence of spontaneous AT-->CG transversions. Most of the bacterial mutator genes appeared to be evolutionarily conserved, and scientists were continuously searching for contribution of DNA repair deficiency in human diseases, especially carcinogenesis. Yet a human MutT homologue--hMTH1 protein--was found to be overexpressed rather than inactivated in many human diseases, including cancer. The interest in DNA repair contribution to human diseases exploded with the observation that germline mutations in mismatch repair (MMR) genes predispose to hereditary non-polyposis colorectal cancer (HNPCC). Despite our continuously growing knowledge about DNA repair we still do not fully understand how the mutator phenotype contributes to specific forms of human diseases.     

An OGG1 orthologue encoding a functional 8-oxoguanine DNA glycosylase/lyase in Arabidopsis thaliana

Repair of the ubiquitous mutagenic lesion 7,8-dihydro-8-oxoguanine (8-oxoG) is initiated in eukaryotes by DNA glycosylases/lyases, such as yeast Ogg1, that do not share significant sequence identity with their prokaryotic counterparts, typified by Escherichia coli MutM (Fpg) protein. The unexpected presence of a functional mutM orthologue in the model plant Arabidopsis thaliana has brought into question the existence of functional OGG1 orthologues in plants. We report here the cDNA cloning, expression and functional characterization of AtOGG1, an Arabidopsis thaliana gene widely expressed in different plant tissues which encodes a 40.3 kDa protein with significant sequence identity to yeast and human Ogg1 proteins. Purified AtOgg1 enzyme specifically cleaves duplex DNA containing an 8-OxoG:C mispair, and the repair reaction proceeds through an imine intermediate characteristic of all bifunctional DNA glycosylases/lyases. Consistent with its in vitro activity, expression of AtOGG1 suppresses the mutator phenotype of an E. coli strain deficient in 8-oxoG repair. Our results suggest that AtOgg1 is an structural and functional homologue of Ogg1 and establish the presence of two distinct 8-oxoG repair enzymes in Arabidopsis.     

Human MMH (OGG1) type 1a protein is a major enzyme for repair of 8-hydroxyguanine lesions in human cells.

8-Hydroxyguanine (8-OH-G) is the site of a frequent mutagenic lesion of DNA, produced by oxidative damage. MutM of E. coli and OGG1 of Saccharomyces cervisiae are known to possess 8-OH-G glycosylase activity and apurinic (AP) site lyase activity to repair 8-OH-G lesions. Recently, cDNA clones of human OGG1 homologues (hMMH) of four isoforms (type 1a, type 1b, type 1c, and type 2) were isolated. However, it is unknown whether expression of endogenous hMMH proteins actually occurs in mammalian cells. Here using hMMH type 1a-specific antibody and cells overexpressing tag-fused hMMH type 1a, we show the expression of hMMH type 1a protein in many types of human cells and show that endogenous hMMH type 1a protein has 8-OH-G glycosylase/AP lyase activity. Furthermore, we show that upon depletion of hMMH type 1a protein in a whole cell extract by its antibody, most of the AP lyase activity is lost, indicating that hMMH type 1a protein is a major enzyme for repair of 8-OH-G lesions in human cells.     

Helicobacter pylori genes involved in avoidance of mutations induced by 8-oxoguanine

Chromosomal rearrangements and base substitutions contribute to the large intraspecies genetic diversity of Helicobacter pylori. Here we explored the base excision repair pathway for the highly mutagenic 8-oxo-7,8-dihydroguanine (8-oxoG), a ubiquitous form of oxidized guanine. In most organisms, 8-oxoG is removed by a specific DNA glycosylase (Fpg in bacteria or OGG1 in eukaryotes). In the case where replication of the lesion yields an A/8-oxoG base pair, a second DNA glycosylase (MutY) can excise the adenine and thus avoid the fixation of the mutation in the next round of replication. In a genetic screen for H. pylori genes complementing the hypermutator phenotype of an Escherichia coli fpg mutY strain, open reading frame HP0142, a putative MutY coding gene, was isolated. Besides its capacity to complement E. coli mutY strains, HP0142 expression resulted in a strong adenine DNA glycosylase activity in E. coli mutY extracts. Consistently, the purified protein also exhibited such an activity. Inactivation of HP0142 in H. pylori resulted in an increase in spontaneous mutation frequencies. An Mg-dependent AP (abasic site) endonuclease activity, potentially allowing the processing of the abasic site resulting from H. pylori MutY activity, was detected in H. pylori cell extracts. Disruption of HP1526, a putative xth homolog, confirmed that this gene is responsible for the AP endonuclease activity. The lack of evidence for an Fpg/OGG1 functional homolog is also discussed.     

Repair of 8-oxoguanine in Saccharomyces cerevisiae: interplay of DNA repair and replication mechanisms

8-Oxo-7,8-dihydroguanine (8-oxoG) is produced abundantly in DNA exposed to free radicals and reactive oxygen species. The biological relevance of 8-oxoG has been unveiled by the study of two mutator genes in Escherichia coli, fpg, and mutY. Both genes code for DNA N-glycosylases that cooperate to prevent the mutagenic effects of 8-oxoG in DNA. In Saccharomyces cerevisiae, the OGG1 gene encodes a DNA N-glycosylase/AP lyase, which is the functional homologue of the bacterial fpg gene product. The inactivation of OGG1 in yeast creates a mutator phenotype that is specific for the generation of GC to TA transversions. In yeast, nucleotide excision repair (NER) also contributes to the release of 8-oxoG in damaged DNA. Furthermore, mismatch repair (MMR) mediated by MSH2/MSH6/MLH1 plays a major role in the prevention of the mutagenic effect of 8-oxoG. Indeed, MMR acts as the functional homologue of the MutY protein of E. coli, excising the adenine incorporated opposite 8-oxoG. Finally, the efficient and accurate replication of 8-oxoG by the yeast DNA polymerase η also prevents 8-oxoG-induced mutagenesis. The aim of this review is to summarize recent literature dealing with the replication and repair of 8-oxoG in Saccharomyces cerevisiae, which can be used as a paradigm for DNA repair in eukaryotes.     

Excision repair of 8-hydroxyguanine in mammalian cells: the mouse Ogg1 protein as a model

8-Hydroxyguanine (8-OH-Gua) is a major mutagenic lesion produced on DNA by the oxidative stress induced by either the endogen metabolism or the exposure to external agents. In bacteria and yeast this modified base can be removed by specific DNA glycosylases. Recently a human gene coding for an 8-OH-Gua DNA glycosylase/AP lyase has been identified by its homology to the yeast OGG1. This gene is located in human chromosome 3p25, a region commonly rearranged in various cancers, specially in lung tumor cells. We report here the cloning, by sequence homology to the yeast OGG1, of a mouse cDNA coding for a 8-OH-Gua DNA glycosylase with 84% and 38% identity to the human and yeast relevant proteins, respectively. The Ogg1 gene is localized to the mouse chromosome 6E. The mouse Ogg1 cDNA, when expressed in Escherichia coli, is capable of suppressing the spontaneous mutator phenotype of a DNA repair deficient fpg mutY strain. The mouse Ogg1 protein acts efficiently on duplexes in which the 8-OH-Gua is paired with a cytosine but is inactive on 8-OH-Gua:Ade pair, consistently with its proposed biological role in the avoidance of mutations. A comparison of the mouse enzyme with other eukaryotic Ogg1 enzymes is also presented. The isolation of this gene will allow the development of an animal model to study the effects of oxidative stress on carcinogenesis and degenerative diseases.     

The influence of combined Fpg- and MutY-deficiency on the spontaneous and gamma-radiation-induced mutation spectrum in the lacZalpha gene of m13mp10

One of the most predominating oxidative DNA damages, both spontaneously formed and after gamma-radiation is 7, 8-dihydro-8-oxoguanine (8oxoG). This 8oxoG is a mutagenic lesion because it can mispair with adenine instead of the correct cytosine leading to G:C to T:A transversions. In Escherichia coli (E. Coli) base excision repair (BER) is one of the most important repair systems for the repair of 8oxoG and other oxidative DNA damage. An important part of BER in E. coli is the so-called GO system which consists of three repair enzymes, MutM (Fpg), MutY and MutT which are all involved in repair of 8oxoG or 8oxoG mispairs. The aim of this study is to determine the effect of combined Fpg- and MutY-deficiency on the spontaneous and gamma-radiation-induced mutation spectrum of the lacZalpha gene. For that purpose, non-irradiated or gamma-irradiated double-stranded (ds) M13mp10 DNA, with the lacZalpha gene inserted as mutational target sequence was transfected into an E. coli strain which is deficient in both Fpg and MutY (BH1040). The resulting mutation spectra were compared with the mutation spectra of a fpg(-) E. coli strain (BH410) and a wild type E. coli strain (JM105) which were determined in an earlier study. The results of the present study indicate that combined Fpg- and MutY-deficiency induces a large increase in G:C to T:A transversions in both the spontaneous and gamma-radiation-induced mutation spectra of BH1040 (fpg(-)mutY(-)) as compared to the fpg(-) and the wild type strain. Besides the increased levels of G:C to T:A transversions, there is also an increase in G:C to C:G transversions and frameshift mutations in both the spontaneous and gamma-radiation-induced mutation spectra of BH1040 (fpg(-)mutY(-)).     

Fission yeast (Schizosaccharomyces pombe) cells defective in the MutY-homologous glycosylase activity have a mutator phenotype and are sensitive to hydrogen peroxide

The modified base 7,8-dihydro-8-oxo-guanine (8-oxoG) is one of the most stable deleterious products of oxidative DNA damage because it mispairs with adenine during DNA replication. In the fission yeast Schizosaccharomyces pombe, the MutY homolog (SpMYH) is responsible for removing misincorporated adenines from A/8-oxoG or A/G mismatches and thus preventing G:C to T:A mutations. In order to study the functional role of SpMYH, an SpMYH knockout strain was constructed. The SpMYH knockout strain, which does not express SpMYH and has no A/8-oxoG glycosylase activity, displays a 36-fold higher frequency of spontaneous mutations than the wild type strain. Disruption of SpMYH causes increased sensitivity to H2O2 but not to UV-irradiation. Expression of SpMYH in the mutant cells restores the adenine glycosylase activity, reduces the mutation frequency, and elevates the resistance to H2O2. Asp172 of SpMYH is conserved in a helix-hairpin-helix superfamily of glycosylases. The SpMYHA strain expressing D172N SpMYH retained the mutator phenotype. Moreover, when D172N mutant SpMYH was expressed in the wild-type cells, the mutation frequency observed was even higher than that of the parental strains. Thus, a mutant SpMYH that retains substrate-binding activity but is defective in glycosylase activity exhibits a dominant negative effect. This is the first demonstration that a MutY homolog plays an important role in protecting cells against oxidative DNA damage in eukaryotes.     

Arabidopsis ZDP DNA 3′‐phosphatase and ARP endonuclease function in 8‐oxoG repair initiated by FPG and OGG1 DNA glycosylases

Oxidation of guanine in DNA generates 7,8‐dihydro‐8‐oxoguanine (8‐oxoG), an ubiquitous lesion with mutagenic properties. 8‐oxoG is primarily removed by DNA glycosylases distributed in two families, typified by bacterial Fpg proteins and eukaryotic Ogg1 proteins. Interestingly, plants possess both Fpg and Ogg1 homologs but their relative contributions to 8‐oxoG repair remain uncertain. In this work we used Arabidopsis cell‐free extracts to monitor 8‐oxoG repair in wild‐type and mutant plants. We found that both FPG and OGG1 catalyze excision of 8‐oxoG in Arabidopsis cell extracts by a DNA glycosylase/lyase mechanism, and generate repair intermediates with blocked 3′‐termini. An increase in oxidative damage is detected in both nuclear and mitochondrial DNA from double fpg ogg1 mutants, but not in single mutants, which suggests that a single deficiency in one of these DNA glycosylases may be compensated by the other. We also found that the DNA 3′‐phosphatase ZDP (zinc finger DNA 3′‐phosphoesterase) and the AP(apurinic/apyirmidinic) endonuclease ARP(apurinic endonuclease redox protein) are required in the 8‐oxoG repair pathway to process the 3′‐blocking ends generated by FPG and OGG1. Furthermore, deficiencies in ZDP and/or ARP decrease germination ability after seed deteriorating conditions. Altogether, our results suggest that Arabidopsis cells use both FPG and OGG1 to repair 8‐oxoG in a pathway that requires ZDP and ARP in downstream steps.     

The yeast HSM3 gene acts in one of the mismatch repair pathways.

Mutants with enhanced spontaneous mutability (hsm) to canavanine resistance were induced by N-methyl-N-nitrosourea in Saccharomyces cerevisiae. One bearing the hsm3-1 mutation was used for this study. This mutation does not increase sensitivity to the lethal action of different mutagens. The hsm3-1 mutation produces a mutator phenotype, enhancing the rates of spontaneous mutation to canavanine resistance and reversions of lys1-1 and his1-7. This mutation increases the rate of intragenic mitotic recombination at the ADE2 gene. The ability of the hsm3 mutant to correct DNA heteroduplex is reduced in comparison with the wild-type strain. All these phenotypes are similar to ones caused by pms1, mlhl and msh2 mutations. In contrast to these mutations, hsm3-1 increases the frequency of ade mutations induced by 6-HAP and UV light. Epistasis analysis of double mutants shows that the PMS1 and HSM3 genes control different mismatch repair systems. The HSM3 gene maps to the right arm of chromosome II, 25 cM distal to the HIS7 gene. Strains that bear a deleted open reading frame YBR272c have the genetic properties of the hsm3 mutant. The HSM3 product shows weak similarity to predicted products of the yeast MSH genes (homologs of the Escherichia coli mutS gene). The HSM3 gene may be a member of the yeast MutS homolog family, but its function in DNA metabolism differs from the functions of other yeast MutS homologs.     

The contribution of endogenous sources of DNA damage to the multiple mutations in cancer

There is increasing evidence that most human cancers contain multiple mutations. By the time a tumor is clinically detectable it may have accumulated tens of thousands of mutations. In normal cells, mutations are rare events occurring at a rate of 10(-10) mutations per nucleotide per cell per generation. We have argued that the mutation rates exhibited by normal human cells are insufficient to account for the large number of mutations found in human cancers, and therefore, that an early event in tumorigenesis is the development of a mutator phenotype. In normal cells, spontaneous and induced DNA damage is balanced by multiple pathways for DNA repair, and most DNA damage is repaired without error. However, in tumor cells this balance may be shifted such that damage overwhelms the repair capacity, resulting in the accumulation of multiple mutations. Our hypothesis is that multiple random mutations occur during carcinogenesis. The sequential mutations that are observed in some human tumors result from selective events required for tumor progression. We consider the possibility that endogenous sources of DNA damage, in particular oxidative DNA damage, may contribute to genomic instability and to a mutator phenotype in some tumors. Endogenous and environmental sources of reactive oxygen species (ROS) are abundant. In tumor cells, antioxidant or DNA repair capacity may be insufficient to compensate for the production of ROS, and these endogenous ROS may be capable of damaging DNA and inducing mutations in critical DNA stability genes. The possibility that oxidative DNA damage could be a significant source of the genomic instability characteristic of human cancers is exciting, because it may be feasible to modulate the extent of oxidative damage through antioxidant therapy. The use of antioxidants to reduce the extent of molecular damage by ROS could delay the progression of cancer.