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A Yeast Homologue of the Human Phosphotyrosyl Phosphatase Activator PTPA Is Implicated in Protection against Oxidative DNA Damage Induced by the Model Carcinogen 4-Nitroquinoline 1-Oxide

1998; Elsevier BV; Volume: 273; Issue: 34 Linguagem: Inglês

10.1074/jbc.273.34.21489

1083-351X

Dindial Ramotar, Edith Bélanger, Isabelle Brodeur, Jean‐Yves Masson, Elliot Drobetsky,

Carcinogens and Genotoxicity Assessment

The model carcinogen 4-nitroquinoline 1-oxide (4-NQO) has historically been characterized as "UV-mimetic" with respect to its genotoxic properties. However, recent evidence indicates that 4-NQO, unlike 254-nm UV light, may exert significant cytotoxic and/or mutagenic potential via the generation of reactive oxygen species. To elucidate the response of eukaryotic cells to 4-NQO-induced oxidative stress, we isolated Saccharomyces cerevisiae mutants exhibiting hypersensitivity to the cytotoxic effects of this mutagen. One such mutant, EBY1, was cross-sensitive to the oxidative agents UVA and diamide while retaining parental sensitivities to 254-nm UV light, methyl methanesulfonate, and ionizing radiation. A complementing gene (designated yPTPA1), restoring full UVA and 4-NQO resistance to EBY1 and encoding a protein that shares 40% identity with the human phosphotyrosyl phosphatase activator hPTPA, has been isolated. Targeted deletion ofyPTPA1 in wild type yeast engendered the identical pattern of mutagen hypersensitivity as that manifested by EBY1, in addition to a spontaneous mutator phenotype that was markedly enhanced upon exposure to either UVA or 4-NQO but not to 254-nm UV or methyl methanesulfonate. Moreover, the yptpa1 deletion mutant exhibited a marked deficiency in the recovery of high molecular weight DNA following 4-NQO exposure, revealing a defect at the level of DNA repair. These data (i) strongly support a role for active oxygen intermediates in determining the genotoxic outcome of 4-NQO exposure and (ii) suggest a novel mechanism in yeast involving yPtpa1p-mediated activation of a phosphatase that participates in the repair of oxidative DNA damage, implying that hPTPA may exert a similar function in humans. The model carcinogen 4-nitroquinoline 1-oxide (4-NQO) has historically been characterized as "UV-mimetic" with respect to its genotoxic properties. However, recent evidence indicates that 4-NQO, unlike 254-nm UV light, may exert significant cytotoxic and/or mutagenic potential via the generation of reactive oxygen species. To elucidate the response of eukaryotic cells to 4-NQO-induced oxidative stress, we isolated Saccharomyces cerevisiae mutants exhibiting hypersensitivity to the cytotoxic effects of this mutagen. One such mutant, EBY1, was cross-sensitive to the oxidative agents UVA and diamide while retaining parental sensitivities to 254-nm UV light, methyl methanesulfonate, and ionizing radiation. A complementing gene (designated yPTPA1), restoring full UVA and 4-NQO resistance to EBY1 and encoding a protein that shares 40% identity with the human phosphotyrosyl phosphatase activator hPTPA, has been isolated. Targeted deletion ofyPTPA1 in wild type yeast engendered the identical pattern of mutagen hypersensitivity as that manifested by EBY1, in addition to a spontaneous mutator phenotype that was markedly enhanced upon exposure to either UVA or 4-NQO but not to 254-nm UV or methyl methanesulfonate. Moreover, the yptpa1 deletion mutant exhibited a marked deficiency in the recovery of high molecular weight DNA following 4-NQO exposure, revealing a defect at the level of DNA repair. These data (i) strongly support a role for active oxygen intermediates in determining the genotoxic outcome of 4-NQO exposure and (ii) suggest a novel mechanism in yeast involving yPtpa1p-mediated activation of a phosphatase that participates in the repair of oxidative DNA damage, implying that hPTPA may exert a similar function in humans. Treatment with the agent 4-nitroquinoline 1-oxide (4-NQO) 1The abbreviations used are: 4-NQO4-nitroquinoline 1-oxideNERnucleotide excision repairAPapurinicMMSmethyl methanesulfonatekbkilobase(s). has been widely employed in mammalian systems as a paradigm for DNA damage-induced carcinogenesis. To exert its neoplastic effect, 4-NQO must first undergo metabolic activation to the proximate carcinogen 4-hydroxyaminoquinoline 1-oxide, which, following acylation, reacts with DNA to form stable quinoline-purine monoadducts, i.e. at the exocyclic N-2 and N-6 positions of guanine and adenine, respectively (1Sugimura T. Okabe K. Nagao M. Cancer Res. 1966; 26: 1717-1721PubMed Google Scholar, 2Galiègue-Zouitina S. Bailleul B. Ginot Y. Perly B. Vigny P. Loucheux-Lefebvre M.-H. Cancer Res. 1986; 46: 1858-1863PubMed Google Scholar). In bacteria, yeast, and mammalian cells, these genotoxic "bulky" DNA lesions are processed largely by the nucleotide excision repair (NER) pathway in a manner analogous to classical dipyrimidine photoproducts (viz. cyclobutane pyrimidine dimers and (6-4) pyrimidine-pyrimidone photoproducts) generated by the model DNA-damaging agent 254-nm UV light (3Prakash S. Sung P. Prakash L. Annu. Rev. Genet. 1993; 27: 33-70Crossref PubMed Scopus (257) Google Scholar, 4Hoeijmakers J.H.J. Trends Genet. 1993; 9: 173-177Abstract Full Text PDF PubMed Scopus (109) Google Scholar). As such, mutants that are deficient in NER are hypersensitive to the genotoxic effects of 254-nm UV light, as well as 4-NQO (3Prakash S. Sung P. Prakash L. Annu. Rev. Genet. 1993; 27: 33-70Crossref PubMed Scopus (257) Google Scholar, 4Hoeijmakers J.H.J. Trends Genet. 1993; 9: 173-177Abstract Full Text PDF PubMed Scopus (109) Google Scholar, 5Van Houten B. Microbiol. Rev. 1990; 54: 18-51Crossref PubMed Google Scholar, 6Svoboda D.L. Taylor J.-S. Hearst J.E. Sancar A. J. Biol. Chem. 1993; 268: 1931-1936Abstract Full Text PDF PubMed Google Scholar). The apparent strong similarity in modes of cellular processing for 254-nm UV light- and 4-NQO-induced DNA damage in diverse prokaryotic and eukaryotic systems has often resulted in categorization of the latter agent as "UV-mimetic" (7Felkner I.C. Kadlubar F. J. Bacteriol. 1968; 96: 1448-1449Crossref PubMed Google Scholar). 4-nitroquinoline 1-oxide nucleotide excision repair apurinic methyl methanesulfonate kilobase(s). However, this designation may be inappropriate, because several recent investigations have clearly demonstrated that 4-NQO, unlike 254-nm UV light, can generate a substantial degree of intracellular oxidative stress. This may herald significant consequences for 4-NQO-exposed cells at the level of cell killing and mutagenesis. Indeed, it was shown that 4-NQO is a potent inducer of the Escherichia colisoxR/S regulon that responds to intracellular superoxide imbalances (8Nunoshiba T. Demple B. Cancer Res. 1993; 53: 3250-3252PubMed Google Scholar). It is believed that 4-NQO undergoes redox cycling to produce superoxide anion, which can be further converted into genotoxic reactive oxygen species (e.g. singlet oxygen and hydroxyl radicals) that engender modified bases and DNA strand breaks (8Nunoshiba T. Demple B. Cancer Res. 1993; 53: 3250-3252PubMed Google Scholar, 9Yamamoto K. Inoue S. Kawanishi S. Carcinogenesis. 1993; 14: 1397-1401Crossref PubMed Scopus (38) Google Scholar). In fact, it has been shown in vitro that activated 4-hydroxyaminoquinoline 1-oxide can generate the highly premutagenic product 8-oxo-guanine, as well as strand breaks, in the presence of Cu(II) (9Yamamoto K. Inoue S. Kawanishi S. Carcinogenesis. 1993; 14: 1397-1401Crossref PubMed Scopus (38) Google Scholar, 10Kohda K. Tada M. Kasai H. Nishimura S. Kawazoe Y. Biochem. Biophys. Res. Commun. 1986; 139: 626-632Crossref PubMed Scopus (87) Google Scholar). In E. coli, 8-oxoguanine is removed by the formamidopyrimidine-DNA glycosylase (Fpg), which in turn generates apurinic (AP) sites as secondary lesions (11Boiteux S. O'Connor T.R. Lederer F. Gouyette A. Laval J. J. Biol. Chem. 1990; 265: 3916-3922Abstract Full Text PDF PubMed Google Scholar). AP sites are also highly premutagenic but can be efficiently removed from cellular DNA by AP endonucleases (12Loeb L.A. Preston B.D. Annu. Rev. Genet. 1986; 20: 201-230Crossref PubMed Scopus (860) Google Scholar, 13Ramotar D. Biochem. Cell Biol. 1997; 75: 327-336Crossref PubMed Scopus (55) Google Scholar). It is therefore not surprising that bacterial mutants lacking either Fpg or AP endonucleases are hypersensitive to the mutagenic effects of 4-NQO (but not of 254-nm UV light) (8Nunoshiba T. Demple B. Cancer Res. 1993; 53: 3250-3252PubMed Google Scholar,14Ruiz-Laguna J. Ariza R.R. Prieto-Alamo M.J. Boiteux S. Pueyo C. Carcinogenesis. 1994; 15: 425-429Crossref PubMed Scopus (12) Google Scholar). Based on the demonstrated ability of 4-NQO to induce oxidative stress that contributes to cell killing and mutagenesis in bacteria, we postulated that this agent may act similarly in eukaryotic cells. As such, using the model organism Saccharomyces cerevisiae, the aim of the present investigation was to identify novel eukaryotic genes implicated in the cellular response to 4-NQO-induced oxidative DNA damage. Our strategy involved, sequentially (i) isolation of a large panel of yeast mutants exhibiting hypersensitivity to the cytotoxic effects of 4-NQO, (ii) categorical preclusion from further analysis of any mutants showing full cross-sensitivity to 254-nm UV light, because these are likely to carry mutations in previously identified DNA repair genes, e.g. comprising the NER pathway known to participate in the processing of UV-type dipyrimidine photoproducts, as well as classical 4-NQO-induced bulky DNA adducts, and (iii) appropriate characterization of any remaining mutants expressing putative defects specifically in the processing of 4-NQO-induced oxidative DNA damage. In this manner, we identified a novel 4-NQO-sensitive yeast mutant that retains parental resistance to 254-nm UV light, while displaying certain hallmarks consistent with a deficiency in the repair of oxidative DNA lesions. A gene complementing this defective phenotype was isolated from a yeast genomic library, and was shown to correspond to a previously identified, but functionally uncharacterized, yeast gene with a predicted amino acid sequence that manifests significant identity with the human phosphotyrosyl phosphatase activator hPTPA. Our data strongly support a genotoxic role for reactive oxygen species in 4-NQO-exposed yeast, and provide novel in vivo evidence for the participation of cellular phosphatases in the repair of oxidative DNA damage in eukaryotic cells. The wild type S. cerevisiae strains used in this study were DBY747 (MATa, leu2-3, 112, his3-Δ1, trp1-289a, ura3-52, laboratory stock), DBY747-1 (isogenic to DBY747, excepttrp1::hisG), W303a (MATa, ade2-1, his3-11, leu2-3, 112, trp1-1, ura3-1, provided by Dr. M. Stark, University of Dundee, UK), FY86 (MATα; his3Δ 200, ura3-52, leu2Δ1, provided by Dr. Fred Winston, Harvard University), and MKp-o (MATa, can1-1000, ade2-1, lys2-1, ura3-52, leu2-3, 112, his3Δ200, trp1-Δ901, provided by Dr. Bernard Kunz, Deakin University, Australia). The mutant strain EBY1 is isogenic to DBY747, except that it bears a mutated copy of the yPTPA1gene (see below). EBY2, EBY3, and EBY4 were derived, respectively, from DBY747-1, MKp-o, and W303a by deleting a portion of theyPTPA1 coding region and replacing it with the selective marker LEU2 (see below). Likewise, CHY26 and CHY27 were derived, respectively, from DBY747-1 and EBY2 by deleting a portion of the coding region of the yPTPA2 gene and replacing it with the selective marker TRP1 (see below). The yeast strains DEY10-2C (isogenic to W303a, exceptpph22Δ1::URA3), DEY142-4D (isogenic to W303a, except MATα, pph21Δ1::HIS3), and DEY22-12 (isogenic to W303a, except pph21Δ1::HIS3, pph22-12) were all generously provided by Dr. M. Stark (University of Dundee, UK). Yeast cells were grown in either complete yeast peptone dextrose (YPD) or minimal synthetic (SC) medium, to which nutritional supplements were added at 20 μg/ml (15Sherman F. Fink G. Hicks J. Methods in Yeast Genetics. Cold Spring Harbor Laboratory, Cold Spring Harbor, NY1983Google Scholar). Standard genetic analysis and transformation were carried out as described previously (16Guthrie C. Fink G.R. Methods Enzymol. 1991; : 194Google Scholar, 17Gietz R.D. Schiestl R.H. Yeast. 1992; 7: 253-263Crossref Scopus (368) Google Scholar). The E. coli strain used for plasmid maintenance was HB101. Exponentially growing wild type yeast (strain DBY747) were treated with 0.1% MMS for 1 h, and surviving colonies were streaked onto YPD agar plates containing 0.4 μg/ml of 4-NQO. This drug concentration permits 90–95% growth of wild type, and strains that did not sustain growth at this drug concentration were scored as mutant. A 1.5-kb SmaI/HindIII yeast DNA fragment bearing the yPTPA1 coding region and flanking 5′- and 3′-untranslated regions was derived from pDR1022 (see below) and subcloned into the pBluescript vector K/S to produce the plasmid pTV3. This plasmid was digested with SalI/PstI to release a 125-base pair fragment from within the coding region of theyPTPA1 gene. The released fragment was substituted with theS. cerevisiae LEU2 selective marker, which was obtained as a 2.5-kb SalI/PstI fragment from the plasmid YEp13 (16Guthrie C. Fink G.R. Methods Enzymol. 1991; : 194Google Scholar), to produce plasmid pTV4. A linear 3.2-kb fragment,yptpa1Δ::LEU2, was obtained from pTV4 by digestion with HindIII and ScaI and transformed directly into the wild type haploid strains DBY747, FY86, and MKp-o using the lithium acetate procedure (17Gietz R.D. Schiestl R.H. Yeast. 1992; 7: 253-263Crossref Scopus (368) Google Scholar). Leu2+transformants bearing a chromosomal deletion of the yPTPA1gene were verified by Southern blot analysis (16Guthrie C. Fink G.R. Methods Enzymol. 1991; : 194Google Scholar), using a32P-labeled 1.0-kb fragment of the yPTPA1 coding region as probe. To construct a yptap2 deletion mutant, the entire yPTPA2 gene was first isolated from strain DBY747 by polymerase chain reaction amplification using the upstream (5′-TCTTTTAAAGCTTAAGAAAATCG-3′) and downstream (5′-GGAAAAAGTACGTACCG-3′) primers containing the restriction sites HindIII and SnaBI (18Ramotar D. Mol. Cell. Biochem. 1995; 145: 185-187Crossref PubMed Scopus (7) Google Scholar). These primers amplified a 1.9-kb HindIII/SnaBI DNA fragment, which was then subcloned into pBluescript digested withHindIII and SmaI to produce pCH1. pCH1 was in turn digested with EcoRI, which removes 160 nucleotides from the N-terminal end of the yPTPA2 coding region, and a 1.2-kbEcoRI fragment containing the TRP1 selective marker gene was inserted at the EcoRI site to produce pCH2. Digestion of pCH2 with HindIII and BamHI produced the yptpa2Δ::TRP1 3.0-kb DNA fragment, which was transformed into strains DBY747 and EBY2. yptpa2 deletion mutants were confirmed by Southern blot analysis. The sensitivities of the various yeast strains to 4-NQO, diamide, and methyl methanesulfonate (all purchased from Sigma) were measured using exponential phase cultures. Overnight cultures grown to saturation at 30 °C in YPD were diluted into fresh medium at an A600 of 0.2 (∼2 × 106 cells/ml) and incubated to anA600 of 1.0. Aliquots were then treated with various concentrations of drugs at 30 °C with shaking (250 rpm) for 1 h. Relative survival was determined by immediately diluting the samples in sterile 20 mm potassium phosphate buffer (pH 7.0) and plating onto YPD agar. Colonies were counted after 3–4 days of growth at 30 °C. In the case of γ-irradiation treatment, exponential cells were irradiated in cold YPD medium using a Co60 source at a dose rate of 55.5 radians/s (experiments carried out in the laboratory of Dr. Michael Resnick, NIEHS, NIH). For exposure to defined regions of the UV wavelength spectrum, mid-log phase yeast were irradiated in sterile distilled water using fluorescent 25-W lamps emitting either UVA (GE model F25T8-BL), UVB (Spectroline model XX25B), or 254-nm UV light (GE model G25T8). Cells were treated at relatively low density (105 cells/ml in 35-mm Petri dishes) and with constant shaking to avoid cellular shielding. The incident light was rigorously purified using 2-mm-thick glass filters (Schott, Mainz, Germany) to virtually eliminate contaminating wavelengths below 290 nm in the case of UVB (filter WG 305) and below 320 nm for UVA (filter WG 345). The incident UVB (λ > 290 nm), UVA (λ > 320 nm), and 254-nm UV light dose rates were measured using a Spectroline DRC 100X digital radiometer equipped with DIX 300, DIX 365, and DIX 254 sensors, respectively. This assay was performed as described previously (19Masson J.-Y. Ramotar D. Can. J. Microbiol. 1996; 42: 835-843Crossref PubMed Scopus (10) Google Scholar). Briefly, cells were replicated as a thin line along the drug gradient, and after 2 days of growth at 30 °C the distance of growth of each strain is expressed as a percentage of the wild type. Growth all along the gradient is considered to be 100%. Spontaneous mutation rates were determined using a fluctuation test as described previously (20Ramotar D. Demple B. J. Biol. Chem. 1996; 271: 7368-7374Abstract Full Text Full Text PDF PubMed Scopus (17) Google Scholar). The measurement of the drug-induced mutation rate was done by directly adding the appropriate concentration of drug to the selective medium. For UVA treatment, a 24-well plate containing the culture was irradiated with UVA 2 days after the cells were exhausted of adenine, by which time they had grown from an initial inoculum of ∼5,000 to a final density of ∼1.0 × 106 cells. Chromosomal DNA from either untreated or 4-NQO-treated cells were isolated and analyzed as described previously (21Masson J.-Y. Ramotar D. Mol. Cell. Biol. 1996; 16: 2091-2100Crossref PubMed Scopus (41) Google Scholar). The plasmids pEB1 and pEB2 were constructed by subcloning the 1.5-kb SmaI/HindIII DNA fragment carrying the yPTPA1 gene into the single copy vector YCplac33 and the 2μ multicopy vector YEplac195, respectively, cut with SmaI and HindIII (22Gietz R.D. Sugino A. Gene ( Amst. ). 1988; 74: 527-534Crossref PubMed Scopus (2528) Google Scholar). Similarly, the plasmids pEB3 and pEB4 were constructed by subcloning the 1.9-kbHindIII/SnaBI polymerase chain reaction fragment of the yPTPA2 gene into YCplac33 and YEplac195, respectively, also cut with HindIII and SmaI. The multicopy plasmids pPPH21 and pPPH22, respectively, bearing the entirePPH21 and PPH22 genes were provided by Dr. M. Stark. Total RNA was prepared by the rapid glass bead method (23Schmitt M.E. Brown T.A. Trumpower B.L. Nucleic Acids Res. 1990; 18: 3091-3092Crossref PubMed Scopus (1155) Google Scholar). The nitrocellulose blot was probed with a random primed 32P-labeled 1.1-kbHindIII/SnaBI fragment derived from the coding region of the yPTPA1 gene. The primers, 5′-CCCTGTGGCCGAATTCCATCTGCTC-3′and 5′-ATCTACAGGATCCAGAGACAT-3′containing, respectively, the restriction sites EcoRI and BamHI (underlined), were used to amplify a 632-base pair fragment consisting of the promoter region of yPTPA1 gene from −615 to +17 base pairs. The EcoRI/BamHI fragment was subcloned into the multicopy vector YEP356R (provided by Dr. Fred Winston, Harvard Medical School, Boston, MA), such that the ATG start codon of theyPTPA1 gene forms the initiation codon for the E. coli reporter lacZ gene encoding β-galactosidase. To determine the location of the mutation in the yPTPA1 gene derived from the mutant EBY1, the primers 5′-CCCTGTGGCCGAATTCCATCTGCTC-3′ and 5′-TAATGCTTGGGATCCACATTTATA-3′ were used to isolate a 1.5-kb DNA fragment of the yPTPA1 gene, with the underlinedEcoRI/BamHI sites, respectively, from strain EBY1 carrying the mutant allele. The fragment was subcloned into pBluescript, and only one strand of the mutant allele of theyPTPA1 gene was entirely sequenced by the dideoxy chain termination method (24Sanger F. Nicklen S. Coulson A.R. Proc. Natl. Acad. Sci. U. S. A. 1977; 74: 543-5467Crossref Scopus (52771) Google Scholar). All additional DNA fragments isolated by polymerase chain reaction were also sequenced by this method. In an attempt to identify novel eukaryotic genes implicated in the repair of 4-NQO-induced oxidative DNA damage, a panel of 55 S. cerevisiae mutants exhibiting hypersensitivity to the cytotoxic effects of this agent was initially isolated. Fifty of the mutants among this collection were excluded from further analysis, because they displayed strong cross-sensitivity to 254-nm UV light, i.e.reflecting the UV-mimetic character of 4-NQO, therefore indicating the involvement in the observed 4-NQO hypersensitivity of previously identified genes comprising, e.g. the NER pathway (3Prakash S. Sung P. Prakash L. Annu. Rev. Genet. 1993; 27: 33-70Crossref PubMed Scopus (257) Google Scholar, 4Hoeijmakers J.H.J. Trends Genet. 1993; 9: 173-177Abstract Full Text PDF PubMed Scopus (109) Google Scholar, 5Van Houten B. Microbiol. Rev. 1990; 54: 18-51Crossref PubMed Google Scholar). The remaining five 4-NQO-sensitive mutants all retained parental resistance to 254-nm UV light and MMS and were therefore deemed potentially deficient in the processing of oxidative DNA damage. One of these 4-NQO-sensitive, 254-nm UV light-resistant mutants, designated EBY1, was shown to be highly cross-sensitive to the oxidizing agents UVA (320–400 nm) and diamide (Fig. 1). Moreover, EBY1 displayed only marginal sensitivity to UVB (290–320 nm), which has a much smaller oxidative component relative to UVA (Fig.1), as well as to hydrogen peroxide (data not shown). Finally, EBY1 also manifested parental resistance to ionizing radiation (Fig. 1) and bleomycin (data not shown), providing evidence that it is not defective in the Rad52 recombinational/double-strand break repair pathway (25Paques F. Haber J.E. Mol. Cell. Biol. 1997; 17: 6765-6771Crossref PubMed Scopus (179) Google Scholar). The mutation conferring 4-NQO and UVA sensitivity to EBY1 was recessive, because a diploid strain constructed by crossing EBY1 (MATa) with a wild type strain FY86 (MATα) showed wild type resistance to 4-NQO (data not shown). Dissection of eight tetrads derived by sporulating the diploid EBY1 X FY86 produced 2:2 segregation of the 4-NQO sensitivity in the progeny, indicating that EBY1 carries a single mutation. Because UVA, 4-NQO, and diamide all generate free radicals, we reasoned that the hypersensitivity of EBY1 to these agents may be because of a defect in a pathway that signals the repair of, or itself repairs, oxidatively damaged DNA. Furthermore, the fact that the mutagen-hypersensitive phenotype of EBY1 was clearly distinct from that of other known yeast DNA repair-deficient mutants suggested that this strain may harbor a mutation at an uncharacterized locus. To isolate the complementing gene, a yeast genomic library constructed in the single copy vector YCp50, and bearing the URA3 selective marker, was introduced into strain EBY1. At least 10,000 Ura+ colonies were replica plated onto YPD agar containing 0.4 μg/ml of 4-NQO, a drug concentration that completely suppressed growth of the mutant but not the parental strain. Two Ura+ colonies, EBY1/pDR1022 and EBY1/pDR1023, were found to be resistant to 4-NQO and UVA (data not shown). The plasmids isolated from the two independent Ura+colonies were identical, because each contained a 12-kb DNA fragment bearing the same restriction enzyme pattern. The portion of the pDR1022 plasmid that conferred 4-NQO or UVA resistance to strain EBY1 was traced to a 1.5-kb SmaI/HindIII DNA fragment derived from chromosome IX. The fragment contained a single open reading frame (designated YIL153w in accordance with theS. cerevisiae gene data base nomenclature) and predicted to encode a polypeptide of 394 amino acids in length. Comparison with protein sequences in the GenBankTM data base revealed thatYIL153w encodes a protein that shares 31, 54, 38, and 40% identity with proteins encoded by, respectively, a S. cerevisiae gene yPL152w (accession number z73508), a fission Schizosaccharomyces pombe gene (accession number z98980), a Drosophila gene (accession number x98401), and the human PTPA (hPTPA) gene (accession number x73478) (26Cayla X. Van Hoof C. Bosch M. Waelkens E. Vandekerckhove J. Peeters B. Merlevede W. Goris J. J. Biol. Chem. 1994; 269: 15668-15675Abstract Full Text PDF PubMed Google Scholar). This latter gene encodes the human phosphotyrosyl phosphatase activator PTPA that modulates the weak tyrosyl phosphatase activity of PP2A (26Cayla X. Van Hoof C. Bosch M. Waelkens E. Vandekerckhove J. Peeters B. Merlevede W. Goris J. J. Biol. Chem. 1994; 269: 15668-15675Abstract Full Text PDF PubMed Google Scholar, 27Cayla X. Goris J. Hermann J. Hendrix P. Ozon R. Merlevede W. Biochemistry. 1990; 29: 658-667Crossref PubMed Scopus (77) Google Scholar). For simplicity, we refer to the yeast genes YIL153w andYPL152w as yPTPA1 and yPTPA2 and the encoded proteins as yPtpa1p and yPtpa2p, respectively. No homologue of yPtpa1p has yet been isolated from prokaryotic cells. A detailed comparison between S. cerevisiae yPtpa1p and human hPTPA1 is shown in Fig. 2. These proteins share four highly conserved regions (I, II, III, and IV) that are also present in yPtpa2p and in the proteins predicted by the S. pombe and Drosophila genes, suggesting that they play an important role in cellular metabolism. A computer search for functional motifs revealed that only region II contains the consensus sequence of an ATP binding site (28Saraste M. Sibbald P.R. Wittinghofer A. Trends Biochem. Sci. 1990; 15: 430-434Abstract Full Text PDF PubMed Scopus (1756) Google Scholar). Because yPtpa2p shares significant identity with yPtpa1p, it is possible that the observed phenotype of strain EBY1 might also arise from a genetic defect in the yPTPA2 gene. To test this, we isolated the yPTPA1 and yPTPA2 genes from strain EBY1 using polymerase chain reaction and subjected both to DNA sequence analysis (18Ramotar D. Mol. Cell. Biochem. 1995; 145: 185-187Crossref PubMed Scopus (7) Google Scholar). No alteration was found in the nucleotide sequence of the yPTPA2 gene, as compared with DNA sequences in theS. cerevisiae data base. In contrast, a single base pair substitution was found in the yPTPA1 gene derived from strain EBY1. The mutation was located at codon 60, where TAC was mutated to the TAA stop codon. Thus, the phenotypes associated with EBY1 are because of a defective yPTPA1 gene and not its homologue yPTPA2. To directly confirm that the yPTPA1 gene is responsible for the observed phenotypes in strain EBY1, we replaced a portion of theyPTPA1 coding region, with the selective markerLEU2 in the parental strain DBY747. The resulting mutant EBY2 (yptpa1Δ::LEU2) showed identical sensitivity to UVA and 4-NQO, as compared with EBY1 (Fig.3, A and B). Deletion of the yPTPA1 gene in three additional parent strains FY86, MKp-o, and W303 also produced mutants with marked sensitivities to UVA and 4-NQO (data not shown), eliminating the possibility that the observed phenotypes were strain-specific. Like EBY1, none of the deletion mutants showed sensitivies to other DNA-damaging agents including MMS, γ-rays, and 254-nm UV light. Full parental UVA and 4-NQO resistance was restored to EBY2 by the single copy centromeric plasmid, pEB1, carrying the entire yPTPA1gene (positions −615 to +1400), including its putative promoter, the entire coding region, and 200 nucleotides downstream from the stop codon (Fig. 3, A and B). IncreasingyPTPA1 gene dosage by using a multicopy plasmid pEB2 conferred no further mutagen resistance, suggesting that yPtpa1p is not limiting in the cell (Fig. 3 B). Although the above data confirm that yPtpa1p is essential for cellular resistance to UVA and 4-NQO, they do not completely exclude a role for yPtpa2p. To directly test this, a mutant was constructed by deleting the yPTPA2 gene from the parent strain DBY747 by replacing it with the auxothropic marker gene TRP1. The resulting mutant CHY26 retained parental resistance to UVA, to 4-NQO, and to other DNA-damaging agents such as MMS (Fig. 3 B; data shown only for 4-NQO). Furthermore, a yptpa1 yptpa2 double mutant CHY27 was no more sensitive to 4-NQO than the single yptpa1mutant EBY2 (Fig. 3 B). These data confirm that yPTPA1 and not yPTPA2 is required for UVA and 4-NQO tolerance. It should also be noted that 4-NQO resistance could not be restored to strain CHY27 by the plasmid pEB3, which bears a single copy of the yPTPA2 gene (Fig.3 B). Interestingly, however, if the yPTPA2 gene was inserted into the multicopy vector YEplac195, and the resulting plasmid pEB4 was introduced into strain CHY27, full parental 4-NQO resistance was restored (Fig. 3 B). This latter observation may not be surprising in view of the high degree of homology between yPtpa1p and yPtpa2p, but nonetheless confirms that the endogenous level or activity of yPtpa2p is insufficient to compensate for complete loss of yPtpa1p. To determine whether yPtpa1p is inducible by cellular stress, the putative yPTPA1promoter region (spanning positions −615 to +1) was fused to the reporter gene lacZ, encoding β-galactosidase. Upon introduction of the fusion plasmid construct into either EBY2 or the wild type strain, each expressed the same basal level of β-galactosidase activity (120 units/mg protein). This activity could not be induced by exposure to either UVA or 4-NQO nor by stress conditions including heat and osmotic shock. It would therefore appear that the endogenous level of yPtpa1p is sufficient for its biological function. Mutants deficient in any of the three major DNA repair pathways,i.e. the nucleotide excision, post-replicational, and recombinational pathways, show hypermutability in response to a wide spectrum of DNA-damaging agents including 4-NQO. We therefore tested whether the hypersensitivity of EBY2 to 4-NQO might be attributable to a defect in DNA repair. The parental and mutant strains were challenged, or not, with 0.5 μg/ml of 4-NQO for 1 h, followed by isolation of chromosomal DNA and quantitation of strand breaks by alkaline sucrose density gradient analysis (21Masson J.-Y. Ramotar D. Mol. Cell. Biol. 1996; 16: 2091-2100Crossref PubMed Scopus (41) Google Scholar). Undamaged DNA isolated from either the parent or the mutan