Repair of N-methyl-N''-nitro-N-nitrosoguanidine-induced DNA damage by ABC excinuclease.

Escherichia coli has several overlapping DNA repair pathways which act in concert to eliminate the DNA damage caused by a diverse array of physical and chemical agents. The ABC excinuclease which is encoded by the uvrA, uvrB, and uvrC genes mediates both the incision and excision steps of nucleotide excision repair. Traditionally, this repair pathway has been assumed to be active against DNA adducts that cause major helical distortions. To determine the level of helical deformity required for recognition and repair by ABC excinuclease, we have evaluated the substrate specificity of this enzyme by using DNA damaged by N-methyl-N'-nitro-N-nitrosoguanidine. ABC excinuclease incised methylated DNA in vitro in a dose-dependent manner in a reaction that was ATP dependent and specific for the fully reconstituted enzyme. In vivo studies with various alkylation repair-deficient mutants indicated that the excinuclease participated in the repair of DNA damage induced by N-methyl-N'-nitro-N-nitrosoguanidine.     

(A)BC excinuclease: the Escherichia coli nucleotide excision repair enzyme

Nucleotide excision repair is the major pathway for removing damage from DNA. (A)BC excinuclease is the nuclease activity which initiates nucleotide excision repair in Escherichia coli. In this review, we focus on current understanding of the structure-function of the enzyme and the reaction mechanism of the repair pathway. In addition, recent biochemical studies on preferential repair of actively transcribed genes in E. coli are summarized.     

Repair of deaminated bases in DNA

Deamination of DNA bases can occur spontaneously, generating highly mutagenic lesions such as uracil, hypoxanthine, and xanthine. When cells are under oxidative stress that is induced either by oxidizing agents or by mitochondrial dysfunction, additional deamination products such as 5-hydroxymethyluracil (5-HMU) and 5-hydroxyuracil (5-OH-Ura) are formed. The cellular level of these highly mutagenic lesions is increased substantially when cells are exposed to DNA damaging agent, such as ionizing radiation, redox reagents, nitric oxide, and others. The cellular repair of deamination products is predominantly through the base excision repair (BER) pathway, a major cellular repair pathway that is initiated by lesion specific DNA glycosylases. In BER, the lesions are removed by the combined action of a DNA glycosylase and an AP endonuclease, leaving behind a one-base gap. The gapped product is then further repaired by the sequential action of DNA polymerase and DNA ligase. DNA glycosylases that recognize uracil, 5-OH-Ura, 5-HMU (derived from 5-methylcytosine) and a T/G mismatch (derived from a 5-methylcytosine/G pair) are present in most cells. Many of these glycosylases have been cloned and well characterized. In yeast and mammalian cells, hypoxanthine is efficiently removed by methylpurine N-glycosylase, and it is thought that BER might be an important pathway for the repair of hypoxanthine. In contrast, no glycosylase that can recognize xanthine has been identified in either yeast or mammalian cells. In Escherichia coli, the major enzyme activity that initiates the repair of hypoxanthine and xanthine is endonuclease V. Endonuclease V is an endonuclease that hydrolyzes the second phosphodiester bond 3' to the lesion. It is hypothesized that the cleaved DNA is further repaired through an alternative excision repair (AER) pathway that requires the participation of either a 5' endonuclease or a 3'-5' exonuclease to remove the damaged base. The repair process is then completed by the sequential actions of DNA polymerase and DNA ligase. Endonuclease V sequence homologs are present in all kingdoms, and it is conceivable that endonuclease V might also be a major enzyme that initiates the repair of hypoxanthine and xanthine in mammalian cells.     

The repair patch of E. coli (A)BC excinuclease.

The size of repair patch made by E. coli DNA polymerase I (Poll) following the removal of a thymine-psoralen monoadduct by E. coli (A)BC excinuclease was determined by using an M13mp19 DNA with a single psoralen monoadduct at the polylinker region. Incubation of this substrate with (A)BC excinuclease, Poll and a combination of 3 dnTP plus 1 dNTP(alpha S) for each nucleotide, and DNA ligase resulted in a repair patch with phosphorothioate linkages. The preferential hydrolysis of phosphorothioate bonds by heating in iodoethanol revealed a patch size--with minimal nick translation--equal in length to the 12 nucleotide gap generated by this excision nuclease.     

Substrate specificity of a mammalian DNA repair endonuclease that recognizes oxidative base damage.

The substrate specificity of a calf thymus endonuclease on DNA damaged by UV ligh, ionizing radiation, and oxidizing agents was investigated. End-labeled DNA fragments of defined sequence were used as substrates, and the enzyme-generated scission products were analyzed by using DNA sequencing methodologies. The enzyme was shown to incise damaged DNA at pyrimidine sites. The enzyme incised DNA damaged with UV light, ionizing radiation, osmium tetroxide, potassium permanganate, and hydrogen peroxide at cytosine and thymine sites. The substrate specificity of the calf thymus endonuclease was compared to that of Escherichia coli endonuclease III. Similar pyrimidine base damage specificities were found for both enzymes. These results define a highly conserved class of enzymes present in both procaryotes and eucaryotes that may mediate an important role in the repair of oxidative DNA damage.     

Sequence effect on incision by (A)BC excinuclease of 4NQO adducts and UV photoproducts.

Nucleotide excision repair in Escherichia coli is initiated by (A)BC excinuclease, an enzyme which incises DNA on both sides of bulky adducts and removes the damaged nucleotide as a 12-13 base long oligomer. The incision pattern of the enzyme was examined using DNA modified by 4-nitroquinoline 1-oxide (4NQO) and UV light. Similar to the cleavage pattern of UV photoproducts and other bulky adducts, the enzyme incises the 8th phosphodiester bond 5' and 5th phosphodiester bond 3' to the 4NQO-modifed base, primarily guanine. The extent of DNA damage by these agents was determined using techniques which quantitatively cleave the DNA or stop at the site of the adduct. By comparison of the intensity of gel bands created by (A)BC excinuclease and the specific cleavage at the damaged site, the efficiency of (A)BC excinuclease incision at 13 different 4NQO-induced adducts and 13 different photoproducts was determined by densitometric scanning. In general, incisions made at 4NQO-induced adducts are proportional to the extent of damage, though the efficiency of cutting throughout the sequence tested varies from 25 to 75%. Incisions made at pyrimidine dimers are less efficient than at 4NQO-adducts, ranging from 13 to 65% incision relative to modification, though most are around 50%. The two (6-4) photoproducts within the region tested are incised more efficiently than any pyrimidine dimer.     

Substrate overlap and functional competition between human nucleotide excision repair and Escherichia coli photolyase and (a)BC excision nuclease

Human cell free extract prepared by the method of Manley et al. (1980) carries out repair synthesis on UV-irradiated DNA. Removal of pyrimidine dimers by photoreactivation with DNA photolyase reduces repair synthesis by about 50%. With excess enzyme in the reaction mixture photolyase reduced the repair signal by the same amount even in the absence of photoreactivating light, presumably by binding to pyrimidine dimers and interfering with the binding of human damage recognition protein. Similarly, the UvrB subunit of Escherichia coli (A)BC excinuclease when loaded onto UV-irradiated or psoralen-adducted DNA inhibited repair synthesis by cell-free extract by 75-80%. The opposite was true also as HeLa cell free extract specifically inhibited the photorepair of a thymine dimer by DNA photolyase and its removal by (A)BC excinuclease. Cell-free extracts from xeroderma pigmentosum (XP) complementation groups A and C were equally effective in blocking the E. coli repair proteins, while extracts from complementation groups D and E were ineffective in blocking the E. coli enzyme. These results suggest that XP-D and XP-E cells are defective in the damage recognition subunit(s) of human excision nuclease.     

Repair of cis-platinum-DNA adducts by ABC excinuclease in vivo and in vitro.

cis-Platinum compounds, which are used in cancer chemotherapy, are thought to exert their effect by damaging DNA. It is known that this damage is partially repaired in Escherichia coli. Using cis-Pt-treated pBR322 DNA as a probe, we investigated the role of nucleotide excision repair in the removal of Pt-DNA adducts. We found that the nucleotide excision pathway was the major mechanism for repairing Pt adducts in transforming plasmid DNA but that a recA-dependent pathway also contributed to plasmid survival. When cis-Pt-damaged pBR322 was treated with the purified nucleotide excision enzyme ABC excinuclease in vitro, a fraction of the adducts was removed by the enzyme; this removal resulted in a corresponding increase in transformation efficiency.     

Noncovalent drug-DNA binding interactions that inhibit and stimulate (A)BC excinuclease.

(A)BC excinuclease from Escherichia coli catalyzes the initial step of nucleotide excision repair. It recognizes and binds to many types of covalent modifications in DNA and incises the damaged strand on both sides of the lesion. We employed a variety of noncovalent DNA binding drugs to examine in vitro the mechanisms and the nature of the DNA-drug interactions responsible for two phenomena: inhibition of excision repair by caffeine and other noncovalent DNA binding compounds; incision of undamaged DNA produced by (A)BC excinuclease in the presence of the bisintercalating drug ditercalinium. All of the chemicals examined (e.g., actinomycin D, caffeine, ethidium bromide, and Hoechst 33258) inhibited incision of a covalent adduct by (A)BC excinuclease, and direct evidence is given for a common mechanism in which UvrA is depleted by binding to drug-undamaged DNA complexes. In the absence of significant amounts of undamaged DNA, another mechanism of inhibition was observed, in which enzyme bound to noncovalent drug-DNA complexes in the vicinity of the lesion prevents formation of preincision complexes at the lesion. Ditercalinium and unexpectedly all of the other drugs examined promoted the incision of undamaged DNA when the enzyme was present at high concentration. Thus, this activity contrary to previous assumptions is not unique to bisintercalators. Another unexpected finding was stimulation of incision at certain sites of photodamage in DNA produced by low concentrations of noncovalent DNA binding chemicals.(ABSTRACT TRUNCATED AT 250 WORDS)     

DNA excision repair at telomeres

DNA damage is caused by either endogenous cellular metabolic processes such as hydrolysis, oxidation, alkylation, and DNA base mismatches, or exogenous sources including ultraviolet (UV) light, ionizing radiation, and chemical agents. Damaged DNA that is not properly repaired can lead to genomic instability, driving tumorigenesis. To protect genomic stability, mammalian cells have evolved highly conserved DNA repair mechanisms to remove and repair DNA lesions. Telomeres are composed of long tandem TTAGGG repeats located at the ends of chromosomes. Maintenance of functional telomeres is critical for preventing genome instability. The telomeric sequence possesses unique features that predispose telomeres to a variety of DNA damage induced by environmental genotoxins. This review briefly describes the relevance of excision repair pathways in telomere maintenance, with the focus on base excision repair (BER), nucleotide excision repair (NER), and mismatch repair (MMR). By summarizing current knowledge on excision repair of telomere damage and outlining many unanswered questions, it is our hope to stimulate further interest in a better understanding of excision repair processes at telomeres and in how these processes contribute to telomere maintenance.     

The role of nucleotide excision repair of Escherichia coli in repair of spontaneous and gamma-radiation-induced DNA damage in the lacZalpha gene

Base excision repair (BER) is a very important repair mechanism to remove oxidative DNA damage. A major oxidative DNA damage after exposure to ionizing radiation is 7,8-dihydro-8-oxoguanine (8oxoG). 8oxoG is a strong mutagenic lesion, which may cause G:C to T:A transversions if not repaired correctly. Formamidopyrimidine-DNA glycosylase (Fpg), a repair enzyme which is part of BER, is the most important enzyme to repair 8oxoG. In the past years, evidence evolved that nucleotide excision repair (NER), a repair system originally thought to repair only bulky DNA lesions, can also repair some oxidative DNA damages. Examples of DNA damages which are recognized by NER are thymine glycol and abasic sites (AP sites). The main objective of this study is to determine if NER can act as a backup system for the repair of spontaneous and gamma-radiation-induced damages when Fpg is deficient. For that purpose, the effect of a NER-deficiency on the spontaneous and gamma-radiation-induced mutation spectrum in the lacZ gene was determined, using double-stranded (ds) M13 DNA, with the lacZalpha gene inserted as mutational target sequence. Subsequently the DNA was transfected into a fpg(-)uvrA(-) Escherichia coli strain (BH420) and the mutational spectra were compared with the spectra of a fpg(-) E. coli strain (BH410) and a wild type E. coli strain (JM105), which were determined in an earlier study. Furthermore, to examine effects which are caused by UvrA-deficiency, and not by Fpg-deficiency, the spontaneous and gamma-radiation-induced mutation spectra of an E. coli strain in which only UvrA is deficient (BH430) were also determined and compared with a wild type E. coli strain (JM105). The results of this study indicate that if only UvrA is deficient, there is an increase in spontaneous G:C to T:A transversions as compared to JM105 and a decrease in A:T to G:C transitions. The gamma-radiation-induced mutation spectrum of BH420 (fpg(-)uvrA(-)) shows a significant decrease in G:C to A:T and G:C to T:A mutations, as compared to BH410 where only Fpg is deficient. Based on these results, we conclude that in our experiments NER is not acting as a backup system if Fpg is deficient. Instead, NER seems to make mistakes, leading to the formation of mutations.     

A highly conserved endonuclease activity present in Escherichia coli, bovine, and human cells recognizes oxidative DNA damage at sites of pyrimidines.

We have compared the sites of nucleotide incision on DNA damaged by oxidizing agents when cleavage is mediated by either Escherichia coli endonuclease III or an endonuclease present in bovine and human cells. E. coli endonuclease III, the bovine endonuclease isolated from calf thymus, and the human endonuclease partially purified from HeLa and CEM-C1 lymphoblastoid cells incised DNA damaged with osmium tetroxide, ionizing radiation, or high doses of UV light at sites of pyrimidines. For each damaging agent studied, regardless of whether the E. coli, bovine, or human endonuclease was used, the same sequence specificity of cleavage was observed. We detected this endonuclease activity in a variety of human fibroblasts derived from normal individuals as well as individuals with the DNA repair deficiency diseases ataxia telangiectasia and xeroderma pigmentosum. The highly conserved nature of such a DNA damage-specific endonuclease suggests that a common pathway exists in bacteria, humans, and other mammals for the reversal of certain types of oxidative DNA damage.     

Closely opposed apurinic/apyrimidinic sites are converted to double strand breaks in Escherichia coli even in the absence of exonuclease III, endonuclease IV, nucleotide excision repair and AP lyase cleavage

Multiply damaged sites (MDSs) consist of two or more damages within 20 base pairs (bps) and are introduced into DNA by ionizing radiation. Using a plasmid assay, we previously demonstrated that repair in Escherichia coli generated a double strand break (DSB) from two closely opposed uracils when uracil DNA glycosylase initiated repair. To identify the enzymes that converted the resulting apurinic/apyrimidinic (AP) sites to DSBs, repair was examined in bacteria deficient in AP site cleavage. Since exonuclease III (xth) and endonuclease IV (nfo) mutant bacteria were able to introduce DSBs at the MDSs, we generated unique bacterial mutants deficient in UvrA, Xth and Nfo. However, the additional disruption of nucleotide excision repair (NER) did not prevent DSB formation. xth- nfo- nfi- bacteria also converted the MDSs to DSBs, ruling out endonuclease V as the candidate AP endonuclease. By using MDSs containing tetrahydrofuran (an AP site analog), it was determined that even in the absence of Xth, Nfo, NER and AP lyase cleavage, DSBs were formed from closely opposed AP sites. This finding implies that there is an unknown enzyme/repair pathway for MDSs, and multiple underlying repair systems in cells that can process closely opposed DNA damage into lethal lesions following exposure to ionizing radiation.     

Base excision repair by hNTH1 and hOGG1: a two edged sword in the processing of DNA damage in gamma-irradiated human cells

Using siRNA technology, we down-regulated in human B-lymphoblastoid TK6 cells the two major oxidative DNA glycosylases/AP lyases that repair free radical-induced base damages, hNTH1 and hOGG1. The down-regulation of hOGG1, the DNA glycosylase whose main substrate is the mutagenic but not cytotoxic 8-oxoguanine, resulted in reduced radiation cytotoxicity and decreased double strand break (DSB) formation post-irradiation. This supports the idea that the oxidative DNA glycosylases/AP lyases convert radiation-induced clustered DNA lesions into lethal DSBs and is in agreement with our previous finding that overexpression of hNTH1 and hOGG1 in TK6 cells increased radiation lethality, mutant frequency at the thymidine kinase locus and the enzymatic production of DSBs post-irradiation [N. Yang, H. Galick, S.S. Wallace, Attempted base excision repair of ionizing radiation damage in human lymphoblastoid cells produces lethal and mutagenic double strand breaks, DNA Repair (Amst) 3 (2004) 1323-1334]. Interestingly, cells deficient in hNTH1, the DNA glycosylase that repairs a major lethal single free radical damage, thymine glycol, were more radiosensitive but at the same time fewer DSBs were formed post-irradiation. These results indicate that hNTH1 plays two roles in the processing of radiation damages: repair of potentially lethal single lesions and generation of lethal DSBs at clustered damage sites. In contrast, in hydrogen peroxide-treated cells where the majority of free radical DNA damages are single lesions, the base excision repair pathway functioned to protect the cells. Here, overexpression of hNTH1 and hOGG1 resulted in reduced cell killing while suppression of glycosylase expression resulted in elevated cell death.     

The post-incision steps of the DNA base excision repair pathway in Escherichia coli: studies with a closed circular DNA substrate containing a single U:G base pair.

The DNA base excision repair pathway is responsible for removal of oxidative and endogenous DNA base damage in both prokaryotes and eukaryotes. This pathway involves formation of an apurinic/apyrimidinic (AP) site in the DNA, which is further processed to restore the integrity of the DNA. In Escherichia coli it has been suggested that the major mode of repair involves replacement of a single nucleotide at the AP site, based on repair synthesis studies using oligonucleotide substrates containing a unique uracil base. The mechanism of the post-incision steps of the bacterial base excision repair pathway was examined using a DNA plasmid substrate containing a single U:G base pair. Repair synthesis carried out by repair-proficient ung, recJ and xon E.coli cell extracts was analyzed by restriction endonuclease cleavage of the DNA containing the uracil lesion. It was found that replacement of the uracil base was always accompanied by replacement of several nucleotides ( approximately 15) 3' of the uracil and this process was absolutely dependent on initial removal of the uracil base by the action of uracil-DNA glycosylase. In contrast to findings with oligonucleotide substrates, replacement of just a single nucleotide at the lesion site was not detected. These results suggest that repair patch length may be substrate dependent and a re-evaluation of the post-incision steps of base excision repair is suggested.     

The Drosophila S3 multifunctional DNA repair/ribosomal protein protects Fanconi anemia cells against oxidative DNA damaging agents

Cells harvested from Fanconi anemia (FA) patients show an increased hypersensitivity to the multifunctional DNA damaging agent mitomycin C (MMC), which causes cross-links in DNA as well as 7,8-dihydro-8-oxoguanine (8-oxoG) adducts indicative of escalated oxidative DNA damage. We show here that the Drosophila multifunctional S3 cDNA, which encodes an N-glycosylase/apurinic/apyrimidinic (AP) lyase activity was found to correct the FA Group A (FA(A)) and FA Group C (FA(C)) sensitivity to MMC and hydrogen peroxide (H2O2). Furthermore, the Drosophila S3 cDNA was shown to protect AP endonuclease deficient E. coli cells against H(2)O(2) and MMC, and also protect 8-oxoG repair deficient mutM E. coli strains against MMC and H2O2 cell toxicity. Conversely, the human S3 protein failed to complement the AP endonuclease deficient E. coli strain, most likely because it lacks N-glycosylase activity for the repair of oxidatively-damaged DNA bases. Although the human S3 gene is clearly not the genetic alteration in FA cells, our results suggest that oxidative DNA damage is intimately involved in the overall FA phenotype, and the cytotoxic effect of selective DNA damaging agents in FA cells can be overcome by trans-complementation with specific DNA repair cDNAs. Based on these findings, we would predict other oxidative repair proteins, or oxidative scavengers, could serve as protective agents against the oxidative DNA damage that occurs in FA.     

Major oxidative products of cytosine are substrates for the nucleotide incision repair pathway

Most common point mutations occurring spontaneously or induced by ionizing radiation are C-->T transitions implicating cytosine as the target. Oxidative cytosine derivatives are the most abundant and mutagenic DNA damage induced by oxidative stress. Base excision repair (BER) pathway initiated by DNA glycosylases is thought to be the major pathway for the removal of these lesions. However, in alternative nucleotide incision repair (NIR) pathway the apurinic/apyrimidinic (AP) endonucleases incise DNA duplex 5' to an oxidatively damaged base in a DNA glycosylase-independent manner. Here, we characterized the substrate specificity of human major AP endonuclease, Ape1, towards 5-hydroxy-2'-deoxycytidine (5ohC) and alpha-anomeric 2'-deoxycytidine (alphadC) residues. The apparent kinetic parameters of the reactions suggest that Ape1 and the DNA glycosylases/AP lyases, hNth1 and hNeil1 repair 5ohC with a low efficiency. Nevertheless, due to the extremely high cellular concentration of Ape1, NIR was the major activity towards 5ohC in cell-free extracts. To address the physiological role of NIR function, we have characterized naturally occurring Ape1 variants including amino acids substitutions (E126A, E126D and D148E) and N-terminal truncated forms (NDelta31, NDelta35 and NDelta61). As expected, all Ape1 mutants had proficient AP endonuclease activity, however, truncated forms showed reduced NIR and 3'-->5' exonuclease activities indicating that these two functions are genetically linked and governed by the same amino acid residues. Furthermore, both Ape1-catalyzed NIR and 3'-->5' exonuclease activities generate a single-strand gap at the 5' side of a damaged base but not at an AP site in duplex DNA. We hypothesized that biochemical coupling of the nucleotide incision and exonuclease degradation may serve to remove clustered DNA damage. Our data suggest that NIR is a backup system for the BER pathway to remove oxidative damage to cytosines in vivo.     

Oxidative damage to DNA: formation, measurement and biochemical features

Emphasis is placed in the first part of this survey on mechanistic aspects of the formation of 8-oxo-7,8-dihydroguanine (8-oxoGua) as the result of exposure to z.rad;OH radical, one-electron oxidants and singlet oxygen (1O(2)) oxidation. It was found that 8-oxoGua, which is generated by either hydration of the guanine radical cation or .OH addition at C8 of the imidazole ring, is a preferential target for further reactions with 1O(2) and one-electron oxidants, including the highly oxidizing oxyl-type guanine radical. Interestingly, tandem base lesions that involve 8-oxoGua and a vicinal formylamine residue were found to be generated within DNA as the result of a single .OH radical hit. The likely mechanism of formation of the latter lesions involves the transient generation of 5-(6)-peroxy-6-(5)-hydroxy-5,6-dihydropyrimidyl radicals that may add to the C8 of a vicinal guanine base before undergoing rearrangement. Another major topic which is addressed deals with recent developments in the measurement of oxidative base damage to cellular DNA. This was mostly achieved using the accurate and highly specific HPLC method coupled with the tandem mass spectrometry detection technique. Interestingly, optimized conditions of DNA extraction and subsequent work-up allow the accurate measurement of 11 modified nucleosides and bases within cellular DNA upon exposure to oxidizing agents including UVA and ionizing radiations. Finally, recently available data on the substrate specificity of DNA repair enzymes belonging to the base excision and nucleotide excision pathways are briefly reviewed. For this purpose modified oligonucleotides in which cyclopurine, and cyclopyrimidine nucleosides were site-specifically inserted were synthesized.     

A New DNA Break Repair Pathway Involving PARP3 and Base Excision Repair Proteins

Poly(ADP-ribosyl)ation, which is catalyzed by PARP family proteins, is one of the main reactions in the cell response to genomic DNA damage. Massive impact of DNA-damaging agents (such as oxidative stress and ionizing radiation) causes numerous breaks in DNA. In this case, the development of a fast cell response, which allows the genomic DNA integrity to be retained, may be more important than the repair by more accurate but long-term restoration of the DNA structure. This is the first study to show the possibility of eliminating DNA breaks through their PARP3-dependent mono(ADP-ribosyl)ation followed by ligation and repair of the formed ribo-AP sites by the base excision repair (BER) enzyme complex. Taken together, the results of the studies on ADP-ribosylation of DNA and the data obtained in this study suggest that PARP3 may be a component of the DNA break repair system involving the BER enzyme complex.