Novel nuclear and mitochondrial glycosylases revealed by disruption of the mouse Nth1 gene encoding an endonuclease III homolog for repair of thymine glycols

Endonuclease III, encoded by nth in Escherichia coli, removes thymine glycols (Tg), a toxic oxidative DNA lesion. To determine the biological significance of this repair in mammals, we established a mouse model with mutated mNth1, a homolog of nth, by gene targeting. The homozygous mNth1 mutant mice showed no detectable phenotypical abnormality. Embryonic cells with or without wild-type mNth1 showed no difference in sensitivity to menadione or hydrogen peroxide. Tg produced in the mutant mouse liver DNA by X-ray irradiation disappeared with time, though more slowly than in the wild-type mouse. In extracts from mutant mouse liver, we found, instead of mNTH1 activity, at least two novel DNA glycosylase activities against Tg. One activity is significantly higher in the mutant than in wild-type mouse in mitochondria, while the other is another nuclear glycosylase for Tg. These results underscore the importance of base excision repair of Tg both in the nuclei and mitochondria in mammals.     

Increased DNA double strand breakage is responsible for sensitivity of the pso3-1 mutant of Saccharomyces cerevisiae to hydrogen peroxide

Escherichia coli endonuclease III (endo III) is the key repair enzyme essential for removal of oxidized pyrimidines and abasic sites. Although two homologues of endo III, Ntgl and Ntg2, were found in Saccharomyces cerevisiae, they do not significantly contribute to repair of oxidative DNA damage in vivo. This suggests that an additional activity(ies) or a regulatory pathway(s) involved in cellular response to oxidative DNA damage may exist in yeast. The pso3-1 mutant of S. cerevisiae was previously shown to be specifically sensitive to toxic effects of hydrogen peroxide (H2O2) and paraquat. Here, we show that increased DNA double strand breakage is very likely the basis of sensitivity of the pso3-1 mutant cells to H2O2. Our results, thus, indicate an involvement of the Pso3 protein in protection of yeast cells from oxidative stress presumably through its ability to prevent DNA double strand breakage. Furthermore, complementation of the repair defects of the pso3-1 mutant cells by E. coli endo III has been examined. It has been found that expression of the nth gene in the pso3-1 mutant cells recovers survival, decreases mutability and protects yeast genomic DNA from breakage following H2O2 treatment. This might suggest some degree of functional similarity between Pso3 and Nth.     

Transfection of the Escherichia coli nth gene into radiosensitive Chinese hamster cells: effects on sensitivity to radiation, hydrogen peroxide, and bleomycin sulfate.

The Escherichia coli nth gene encodes endonuclease III, which catalyses the glycolytic removal of various oxidized thymine residues from DNA. A truncated version of nth, with the prokaryotic regulatory sequences removed, was ligated into the retrovirus-based vector pZipneoSV(X)1 and transfected into the radiosensitive Chinese hamster ovary cell line, xrs7. Following selection with G418, two clones (x7nth1 and x7nth6) were shown by Southern analysis to contain the nth gene. No substantial difference in gamma-ray sensitivity was detected between xrs7, clones x7nth1 and x7nth6, and the parent vector transfected clone (x7neo1). However, clones containing the nth gene were more resistant to hydrogen peroxide cytotoxicity [D0's for x7nth1 and x7nth6 were 0.072 microgram/ml (4 microM) and 0.046 microgram/ml, respectively, compared with D0's of 0.034 and 0.027 microgram/ml for xrs7 and x7neo1, respectively] but markedly more sensitive to bleomycin sulfate cytotoxicity than xrs7 and x7neo1 (e.g., 1D0's for x7nth6 and xrs7 were 0.05 and 0.12 microgram/ml, while 2D0's for x7nth1 and xrs7 were 0.35 and 0.48 microgram/ml, respectively). Alterations in sensitivity to hydrogen peroxide and bleomycin sulfate could not be explained by differences in the distribution of the cell-cycle phases and growth rate of nth-containing clones and control cell lines. These results are consistent with the hypothesis that modified thymine lesions are potentially cytotoxic. Hence, when cells incur a high level of endonuclease III-repairable damage relative to strand breakage, such as after treatment with hydrogen peroxide, increased repair capacity increases survival. Gamma radiation produces a lower level of endonuclease III-repairable damage relative to all the other types of lesions produced; hence increased repair capacity has no measurable effect on cell survival. The increased sensitivity of x7nth1 and x7nth6 to bleomycin sulfate toxicity may indicate that, when thymine damage and single-strand breaks are in close proximity on opposite strands of the DNA, endonuclease III, which incises DNA at the site of damaged residues, can increase the number of double-strand breaks and hence decrease the level of cell survival.     

Escherichia coli endonuclease VIII: cloning, sequencing, and overexpression of the nei structural gene and characterization of nei and nei nth mutants.

Escherichia coli possesses two DNA glycosylase/apurinic lyase activities with overlapping substrate specificities, endonuclease III and endonuclease VIII, that recognize and remove oxidized pyrimidines from DNA. Endonuclease III is encoded by the nth gene. Endonuclease VIII has now been purified to apparent homogeneity, and the gene, nei, has been cloned by using reverse genetics. The gene nei is located at 16 min on the E. coli chromosome and encodes a 263-amino-acid protein which shows significant homology in the N-terminal and C-terminal regions to five bacterial Fpg proteins. A nei partial deletion replacement mutant was constructed, and deletion of nei was confirmed by genomic PCR, activity analysis, and Western blot analysis. nth nei double mutants were hypersensitive to ionizing radiation and hydrogen peroxide but not as sensitive as mutants devoid of base excision repair (xth nfo). Single nth mutants exhibited wild-type sensitivity to X rays, while nei mutants were consistently slightly more sensitive than the wild type. Double mutants lacking both endonucleases III and VIII exhibited a strong spontaneous mutator phenotype (about 20-fold) as determined by a rifampin forward mutation assay. In contrast to nth mutants, which showed a weak mutator phenotype, nei single mutants behaved as the wild type.     

Multiple pathways for repair of oxidative DNA damages caused by X rays and hydrogen peroxide in Escherichia coli.

The responses of Escherichia coli to X rays and hydrogen peroxide were examined in mutants which are deficient in one or more DNA repair genes. Mutant cells deficient in either exonuclease III (xthA) or endonuclease IV (nfo) had normal resistance to X rays, but an xthA-nfo double mutant showed a sensitivity increased over that of either parental strain. A DNA polymerase I mutant (polA) was more sensitive than the xthA-nfo mutant. Cells bearing mutations in all of the polA, xthA, and nfo genes were more sensitive to X rays than polA and xthA-nfo mutants. Similar repair responses were obtained by exposing these mutant cells to hydrogen peroxide, with the exception of the xthA mutant, which was hypersensitive to this agent. The DNA polymerase III mutant (polC(Ts)) was slightly more sensitive to the agents than the wild-type strain at the restrictive temperature. The sensitivity of the polC-xthA-nfo mutant to X rays and hydrogen peroxide was greater than that of polC but almost the same as that of the xthA-nfo mutant. From these results it appears that there are at least four repair pathways, the DNA polymerase I-, exonuclease III/endonuclease IV and DNA polymerase I-, exonuclease III/endonuclease IV and DNA polymerase III-, and exonuclease III/endonuclease IV-dependent pathways, for the repair of oxidative DNA damages in E. coli.     

Mode of inhibition of short-patch base excision repair by thymine glycol within clustered DNA lesions

Clustered DNA damage, where two or more lesions are located proximally to each other, is frequently induced by ionizing radiation. Individual base lesions within a cluster are repaired by base excision repair. In this study we addressed the question of how thymine glycol (Tg) within a cluster would affect the repair of opposing lesions by human cell extracts. We have found that Tg located opposite to an abasic site does not affect cleavage of this site by apurinic/apyrimidinic (AP) endonuclease. However, Tg significantly compromised the next step of the repair. Although purified DNA polymerase beta was able to incorporate the correct nucleotide (dAMP) opposite to Tg, the rate of incorporation was reduced by 3-fold. Tg does not affect 5'-sugar phosphate removal by the 2-deoxyribose-5-phosphate (dRP) lyase activity of DNA polymerase beta, but further processing of the strand break by purified DNA ligase III was slightly diminished. In agreement with these findings, although an AP site located opposite to Tg was efficiently incised in human cell extract, only a limited amount of fully repaired product was observed, suggesting that such clustered DNA lesions may have a significantly increased lifetime in human cells compared with similar single-standing lesions.     

Excision repair of thymine glycols, urea residues, and apurinic sites in Escherichia coli

The genetic requirements for the excision repair of thymine glycols, urea residues, and apurinic (AP) sites were examined by measuring the survival in Escherichia coli mutants of phi X174 replicative form (RF) I transfecting DNA containing selectively introduced lesions. phi X RF I DNA containing thymine glycols was inactivated at a greater rate in mutants deficient in endonuclease III (nth) than in wild-type hosts, suggesting that endonuclease III is involved in the repair of thymine glycols in vivo. phi X RF I DNA containing thymine glycols was also inactivated at a greater rate in mutants that were deficient in both exonuclease III and endonuclease IV (xth nfo) than in wild-type hosts, suggesting that a class II AP endonuclease is required for the in vivo processing of thymine glycols. phi X duplex-transfecting DNA containing urea residues or AP sites was inactivated at a greater rate in xth nfo double mutants than in wild-type, but not single-mutant, hosts, suggesting that exonuclease III or endonuclease IV is required for the repair of these damages and that either activity can substitute for the other. These data are in agreement with the known in vitro substrate specificities of endonuclease III, exonuclease III, and endonuclease IV.     

Endonuclease III and endonuclease IV protect Escherichia coli from the lethal and mutagenic effects of near-UV irradiation.

In contrast to the DNA damage caused by far-UV (lambda < 290 nm), near-UV (290 < lambda < 400 nm) induced DNA damage is partially oxygen dependent, suggesting the involvement of reactive oxygen species. To test the hypothesis that enzymes that protect cells from oxidative DNA damage are also involved in preventing near-UV mediated DNA damage, isogenic strains deficient in one or more of exonuclease III (xthA), endonuclease IV (nfo), and endonuclease III (nth) were exposed to increasing levels of far-UV and near-UV. All strains, with the exception of the nth single mutant, were found to be hypersensitive to the lethal effects of near-UV relative to a wild-type strain. A triple mutant strain (nth nfo xthA) exhibited the greatest sensitivity to near-UV-mediated lethality. The triple mutant was more sensitive than the nfo xthA double mutant to the lethal effects of near-UV, but not far-UV. A forward mutation assay also revealed a significantly increased sensitivity for the triple mutant compared to the nfo xthA deficient strain in the presence of near-UV. However, the triple mutant was no more sensitive to the mutagenic effects of far-UV than a nfo xthA double mutant. These data suggest that exonuclease III, endonuclease IV, and endonuclease III are important in protection against near-UV-induced DNA damage.     

Nucleotide excision repair 3' endonuclease XPG stimulates the activity of base excision repairenzyme thymine glycol DNA glycosylase.

An ionizing radiation-induced DNA lesion, thymine glycol, is removed from DNA by a thymine glycol DNA glycosylase with an apurinic/apyrimidinic (AP) lyase activity encoded by the Escherichia coli endonuclease III ( nth ) gene and its homolog in humans. Cells from Cockayne syndrome patients with mutations in the XPG gene show approximately 2-fold reduced global repair of thymine glycol. Hence, I decided to investigate the molecular mechanism of the effect of XPG protein observed in vivo on thymine glycol removal by studying the interactions of XPG protein and human endonuclease III (HsNTH) protein in vitro and the effect of XPG protein on the activity of HsNTH protein on a substrate containing thymine glycol. The XPG protein stimulates the binding of HsNTH protein to its substrate and increases its glycosylase/AP lyase activity by a factor of approximately 2 through direct interaction between the two proteins. These results provide in vitro evidence for a second function of XPG protein in DNA repair and a mechanistic basis for its stimulatory activity on HsNTH protein.     

Stereoselective excision of thymine glycol from oxidatively damaged DNA

DNA damage created by reactive oxygen species includes the prototypic oxidized pyrimidine, thymine glycol (Tg), which exists in oxidatively damaged DNA as two diastereoisomeric pairs. In Escherichia coli, Saccharomyces cerevesiae and mice, Tg is preferentially excised by endonuclease III (Endo III) and endonuclease VIII (Endo VIII), yNTG1 and yNTG2, and mNTH and mNEIL1, respectively. We have explored the ability of these DNA glycosylases to discriminate between Tg stereoisomers. Oligonucleotides containing a single, chromatographically pure (5S,6R) or (5R,6S) stereoisomer of Tg were prepared by oxidation with osmium tetroxide. Steady-state kinetic analyses of the excision process revealed that Endo III, Endo VIII, yNTG1, mNTH and mNEIL1, but not yNTG2, excise Tg isomers from DNA in a stereoselective manner, as reflected in the parameter of catalytic efficiency (k_cat/K_m). When DNA glycosylases occur as complementary pairs, failure of one or both enzymes to excise their cognate Tg stereoisomer from oxidatively damaged DNA could have deleterious consequences for the cell.     

Base excision repair enzyme endonuclease III suppresses mutagenesis caused by 8-hydroxy-dGTP

To examine whether base excision repair suppresses mutations induced by oxidized deoxyribonucleotide 5'-triphosphates in the nucleotide pool, 8-hydroxy-dGTP (8-OH-dGTP) and 2-hydroxy-dATP were introduced into Escherichia coli strains deficient in endonucleases III (Nth) and VIII (Nei) and MutY, and mutations in the chromosomal rpoB gene were analyzed. The spontaneous rpoB mutant frequency was also examined in mutT/nth and mutT/nei strains, to assess the influence on the mutations induced by the endogenous 8-OH-dGTP accumulated in the mutT mutant. The mutations induced by exogenous 2-hydroxy-dATP were similar in all of the strains tested. Exogenous 8-OH-dGTP increased the rpoB mutant frequency more efficiently in the nth strain than that in the wild-type strain. The spontaneous mutant frequency in the mutT/nth strain was 2-fold higher than that in the mutT strain. These results suggest that E. coli endonuclease III also acts as a defense against the mutations caused by 8-OH-dGTP in the nucleotide pool.     

Genetic mapping of nth, a gene affecting endonuclease III (thymine glycol-DNA glycosylase) in Escherichia coli K-12.

The nth gene of Escherichia coli affects the production of endonuclease III, a glycosylase-endonuclease that attacks DNA damaged by oxidizing agents or by ionizing radiation. An nth insertion mutant and a deletion mutant were studied. nth is located between add and tyrS on the linkage map of E. coli K-12 and was 97% linked to tyrS in a transduction with phage P1.     

Recognition of formamidopyrimidine by Escherichia coli and mammalian thymine glycol glycosylases. Distinctive paired base effects and biological and mechanistic implications

The activity of prokaryotic and mammalian thymine glycol (Tg) glycosylases including Escherichia coli endonuclease III (Endo III) and endonuclease VIII (Endo VIII) and mouse Endo III homologue (mNth1) for formamidopyrimidine (Fapy) has been investigated using defined oligonucleotide substrates. 2, 6-Diamino-4-hydroxy-5-N-methylformamidopyrimidine, a methylated Fapy derived from guanine, was site specifically incorporated in the oligonucleotide. The substrates containing Fapy:N pairs (N = A, G, C, T) as well as a Tg:A pair, a physiological substrate of Endo III, Endo VIII, and mNth1, were treated by the enzymes and nicked products were quantified by gel electrophoresis. The activity of Endo III and Endo VIII for Fapy varied markedly depending on the paired base, being the highest with G (activity relative to Tg = 0. 55 (Endo III) and 0.41 (Endo VIII)) and the lowest with C (0.05 (Endo III) and 0.06 (Endo VIII)). In contrast, mNth1 recognized all Fapy pairs equally well and the activity was comparable to Tg. The results obtained in the nicking assay were further substantiated by the analysis of the Schiff base intermediate using NaBH(4) trapping assays. These results indicate that Escherichia coli and mammalian Tg glycosylases have a potential activity to recognize Fapy. However, as demonstrated for Fapy:C pairs, their distinctive activities implicate unequal participation in the repair of Fapy lesions in cells.     

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.     

Multiple pathways for repair of hydrogen peroxide-induced DNA damage in Escherichia coli.

The repair response of Escherichia coli to hydrogen peroxide has been examined in mutants which show increased sensitivity to this agent. Four mutants were found to show increased in vivo sensitivity to hydrogen peroxide compared with wild type. These mutants, in order of increasing sensitivity, were recA, polC, xthA, and polA. The polA mutants were the most sensitive, implying that DNA polymerase I is required for any repair of hydrogen peroxide damage. Measurement of repair synthesis after hydrogen peroxide treatment demonstrated normal levels for recA mutants, a small amount for xthA mutants, and none for polA mutants. This is consistent with exonuclease III being required for part of the repair synthesis seen, while DNA polymerase I is strictly required for all repair synthesis. Sedimentation analysis of cellular DNA after hydrogen peroxide treatment showed that reformation was absent in xthA, polA, and polC(Ts) strains but normal in a recA cell line. By use of a lambda phage carrying a recA-lacZ fusion, we found hydrogen peroxide does not induce the recA promoter. Our findings indicate two pathways of repair for hydrogen peroxide-induced DNA damage. One of these pathways would utilize exonuclease III, DNA polymerase III, and DNA polymerase I, while the other would be DNA polymerase I dependent. The RecA protein seems to have little or no direct function in either repair pathway.     

Targeted deletion of mNth1 reveals a novel DNA repair enzyme activity

DNA N-glycosylase/AP (apurinic/apyrimidinic) lyase enzymes of the endonuclease III family (nth in Escherichia coli and Nth1 in mammalian organisms) initiate DNA base excision repair of oxidized ring saturated pyrimidine residues. We generated a null mouse (mNth1(-/-)) by gene targeting. After almost 2 years, such mice exhibited no overt abnormalities. Tissues of mNth1(-/-) mice contained an enzymatic activity which cleaved DNA at sites of oxidized thymine residues (thymine glycol [Tg]). The activity was greater when Tg was paired with G than with A. This is in contrast to Nth1, which is more active against Tg:A pairs than Tg:G pairs. We suggest that there is a back-up mammalian repair activity which attacks Tg:G pairs with much greater efficiency than Tg:A pairs. The significance of this activity may relate to repair of oxidized 5-methyl cytosine residues (5meCyt). It was shown previously (S. Zuo, R. J. Boorstein, and G. W. Teebor, Nucleic Acids Res. 23:3239-3243, 1995) that both ionizing radiation and chemical oxidation yielded Tg from 5meCyt residues in DNA. Thus, this previously undescribed, and hence novel, back-up enzyme activity may function to repair oxidized 5meCyt residues in DNA while also being sufficient to compensate for the loss of Nth1 in the mutant mice, thereby explaining the noninformative phenotype.