Absence of DNA repair replication after chemical mutagen damage in Vicia faba

Exposure of human (Hela) cells to the mutagens 4-nitroquinoline-1-oxide (4NQO) and N-methyl-N′-nitro-nitrosoguanidine (MNNG) produces damage in DNA that is repaired by a mechanism involving the insertion of new bases into DNA (repair replication). Vicia faba root tips, either from soaked seeds containing non-proliferating cells or from growing roots, do not perform detectable amounts of repair replication even though the mutagens inhibit DNA synthesis and cause chromosome aberrations. In view of similar failures to resolve excision in Chlamydomonas, Haplopappus, and Nicotiana after irradiation with UV light and in Vicia faba after X-irradiation it appears that plants in general might lack this repair process.     

Repair of lesions induced in human liver cell DNA by N-nitroso compounds as measured by the bromodeoxyuridine photolysis method

Chang human liver cells were treated with the carcinogens N-methyl-N′-nitrosoguanidine (MNNG) and nitrosomorpholine (NM). In addition, cells were exposed to the folic acid analog, 2-hydroxy-N¹⁰ nitrosofolic acid. Repair of the damage to DNA was estimated by selective photolysis of BUdR-containing repaired regions with 313 nm radiation. The influence of the co-carcinogen Arlacel A was estimated with the three compounds. Results indicated significant repair synthesis with MNNG- and NM-treated cells. 2-Hydroxy-N¹⁰ nitrosofolic acid elicited no damage to the liver DNA. Arlacel A prevented repair synthesis in cells treated with NM and MNNG.     

Exonuclease 1 (Exo1) is required for activating response to SN1 DNA methylating agents

S_N1 DNA methylating agents are genotoxic agents that methylate numerous nucleophilic centers within DNA including the O⁶ position of guanine (O⁶meG). Methylation of this extracyclic oxygen forces mispairing with thymine during DNA replication. The mismatch repair (MMR) system recognizes these O⁶meG:T mispairs and is required to activate DNA damage response (DDR). Exonuclease I (EXO1) is a key component of MMR by resecting the damaged strand; however, whether EXO1 is required to activate MMR-dependent DDR remains unknown. Here we show that knockdown of the mouse ortholog (mExo1) in mouse embryonic fibroblasts (MEFs) results in decreased G2/M checkpoint response, limited effects on cell proliferation, and increased cell viability following exposure to the S_N1 methylating agent N-methyl-N′-nitro-N-nitrosoguanidine (MNNG), establishing a phenotype paralleling MMR deficiency. MNNG treatment induced formation of γ-H2AX foci with which EXO1 co-localized in MEFs, but mExo1-depleted MEFs displayed a significant diminishment of γ-H2AX foci formation. mExo1 depletion also reduced MSH2 association with DNA duplexes containing G:T mismatches in vitro, decreased MSH2 association with alkylated chromatin in vivo, and abrogated MNNG-induced MSH2/CHK1 interaction. To determine if nuclease activity is required to activate DDR we stably overexpressed a nuclease defective form of human EXO1 (hEXO1) in mExo1-depleted MEFs. These experiments indicated that expression of wildtype and catalytically null hEXO1 was able to restore normal response to MNNG. This study indicates that EXO1 is required to activate MMR-dependent DDR in response to S_N1 methylating agents; however, this function of EXO1 is independent of its nucleolytic activity.     

The impact of 6-thioguanine incorporation into DNA on the function of DNA methyltransferase Dnmt3a

The incorporation of chemotherapeutic agent 6-thioguanine (^SG) into DNA is a prerequisite for its cytotoxic action. This modification of DNA impedes the activity of enzymes involved in DNA repair and replication. Here, using hemimethylated DNA substrates we demonstrated that DNA methylation by Dnmt3a-CD is reduced if DNA is damaged by the incorporation of ^SG into one or two CpG sites separated by nine base pairs. An increase in the number of ^SG substitutions did not enhance the effect. Dnmt3a-CD binding to either of ^SG-containing DNA substrates was not distorted. Our results suggest that ^SG incorporation into DNA may influence epigenetic regulation via DNA methylation.     

MutS inhibits RecA-mediated strand transfer with methylated DNA substrates

DNA mismatch repair (MMR) sensitizes human and Escherichia coli dam cells to the cytotoxic action of N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) while abrogation of such repair results in drug resistance. In DNA methylated by MNNG, MMR action is the result of MutS recognition of O⁶-methylguanine base pairs. MutS and Ada methyltransferase compete for the MNNG-induced O⁶-methylguanine residues, and MMR-induced cytotoxicity is abrogated when Ada is present at higher concentrations than normal. To test the hypothesis that MMR sensitization is due to decreased recombinational repair, we used a RecA-mediated strand exchange assay between homologous phiX174 substrate molecules, one of which was methylated with MNNG. MutS inhibited strand transfer on such substrates in a concentration-dependent manner and its inhibitory effect was enhanced by MutL. There was no effect of these proteins on RecA activity with unmethylated substrates. We quantified the number of O⁶-methylguanine residues in methylated DNA by HPLC-MS/MS and 5–10 of these residues in phiX174 DNA (5386 bp) were sufficient to block the RecA reaction in the presence of MutS and MutL. These results are consistent with a model in which methylated DNA is perceived by the cell as homeologous and prevented from recombining with homologous DNA by the MMR system.     

Escherichia coli Fpg glycosylase is nonrendundant and required for the rapid global repair of oxidized purine and pyrimidine damage in vivo

Endonuclease (Endo) III and formamidopyrimidine-N-glycosylase (Fpg) are two of the predominant DNA glycosylases in Escherichia coli that remove oxidative base damage. In cell extracts and purified form, Endo III is generally more active toward oxidized pyrimidines, while Fpg is more active towards oxidized purines. However, the substrate specificities of these enzymes partially overlap in vitro. Less is known about the relative contribution of these enzymes in restoring the genomic template following oxidative damage. In this study, we examined how efficiently Endo III and Fpg repair their oxidative substrates in vivo following treatment with hydrogen peroxide. We found that Fpg was nonredundant and required to rapidly remove its substrate lesions on the chromosome. In addition, Fpg also repaired a significant portion of the lesions recognized by Endo III, suggesting that it plays a prominent role in the global repair of both purine damage and pyrimidine damage in vivo. By comparison, Endo III did not affect the repair rate of Fpg substrates and was only responsible for repairing a subset of its own substrate lesions in vivo. The absence of Endo VIII or nucleotide excision repair did not significantly affect the global repair of either Fpg or Endo III substrates in vivo. Surprisingly, replication recovered after oxidative DNA damage in all mutants examined, even when lesions persisted in the DNA, suggesting the presence of an efficient mechanism to process or overcome oxidative damage encountered during replication.     

Further studies on the induction of mutation in Haemophilus influenzae by N-methyl-N′-nitro-N-nitrosoguanidine: Lack of an inducible error-free repair system and the effect of exposure medium

Haemophilis influenzae is shown to lack the inducible, error-free repair system for alkylation damage that others have found in Escherichia coli. Prior growth in a low concentration of N-methyl-N′-nitro-N-nitrosoguanidine had only an additive effect on a subsequent brief exposure to a high concentration. Furthermore, chloramphenicol did not significantly modify the mutagenic response. In both respects, H. influenzae differs from E. coli. Experiments carried out in preparation for these tests showed that exposure to N-methyl-N′-nitro-N-nitrosoguanidine in complex growth medium was more effective by about an order of magnitude than exposure in pH 6.0 tris-maelare buffer in inducing mutations, in killing the cells, and in causing strand breaks in the preexisting DNA and gaps in newly synthesized DNA. Thus the effect of the medium is on the amount of initial damage rather than on some special feature of the mutation process. Part but not all of the effect can be accounted for by the difference in pH of the 2 media. The nature of the mutagenic process is the same under the 2 exposure conditions; i.e., reparable pre-mutational damage is produced by the agent and subsequently converted to final mutation by replication. The dose—effect curves have a non-linear initial portion under both exposure conditions, and possible reasons for this non-linearity are discussed.     

Base excision repair is efficient in cells lacking poly(ADP-ribose) polymerase 1

Poly(ADP-ribose) polymerase 1 (PARP-1) is a nuclear enzyme that is activated by binding to DNA breaks induced by ionizing radiation or through repair of altered bases in DNA by base excision repair. Mice lacking PARP-1 and, in certain cases, the cells derived from these mice exhibit hypersensitivity to ionizing radiation and alkylating agents. In this study we investigated base excision repair in cells lacking PARP-1 in order to elucidate whether their augmented sensitivity to DNA damaging agents is due to an impairment of the base excision repair pathway. Extracts prepared from wild-type cells or cells lacking PARP-1 were similar in their ability to repair plasmid DNA damaged by either X-rays (single-strand DNA breaks) or by N-methyl-N′-nitro-N-nitrosoguanidine (methylated bases). In addition, we demonstrated in vivo that PARP-1-deficient cells treated with N-methyl-N′-nitro-N-nitrosoguanidine repaired their genomic DNA as efficiently as wild-type cells. Therefore, we conclude that cells lacking PARP-1 have a normal capacity to repair single-strand DNA breaks inflicted by X-irradiation or breaks formed during the repair of modified bases. We propose that the hypersensitivity of PARP-1 null mutant cells to γ-irradiation and alkylating agents is not directly due to a defect in DNA repair itself, but rather results from greatly reduced poly(ADP-ribose) formation during base excision repair in these cells.     

Repair of O6-methyl-guanine residues in DNA takes place by a similar mechanism in extracts from hela cells,human liver,and rat liver

Extracts from HeLa S₃ cells, human liver, and rat liver were found to contain an activity that transfers the methyl group from O⁶-methyl-guanine residues in DNA to a cysteine residue of an acceptor protein. The molecular weights of the acceptor proteins in HeLA cells and human liver are 24,000 ± 1,000 and 23,000 ± 1,000. respectively. Assuming that each acceptor molecule is used only once, the average number of acceptor molecules in HeLa cells was calculated to be about 50,000. The extracts also contained 3-methyl-adenine-DNA glycosylase activity and 7-methyl-guanine-DNA glycosylase activity, although the latter activity was not detected in extracts from human liver in our assay system. Thus, the three major alkylation products resulting from the effect of methylating agents, such as N-methyl-N-nitroso urea, can all be repaired in animal cells. Pretreatment of HeLa cells with N-methyl-N′-nitro-N-nitrosoguanidinc (0.1 μg/ml) strongly reduced the capacity of HeLa cell extracts to repair O⁶-methyl-guanine residues, while the activity of three DNA-N-glycosylases was essentially unaltered. This inactivation was not caused by a direct methylation of the enzyme by the carcinogen. The results demonstrate that the mechanism of repair of O⁶-methyl-guaninc residues, in DNA is strikingly similar in E coli and animal cells, including humans.     

Inhibition of the puromycin reaction with benzamidine and related compounds

Incubation of mouse cells with N-methyl-N′-nitro-N-nitrosoguanidine causes a strong inhibition of DNA replication the extent of which varies with the cell line used. Analysis of the products synthesized in drug-treated cells indicates a particularly severe effect on the joining of replicons while other steps in DNA synthesis like initiation and chain elongation are much less affected. The data indicate that replicon fusion may be extremely sensitive to changes in the topology of DNA induced by the introduction of rare single-strand breaks during repair of N-methylated purines produced by incubation of cells with small amounts of the methylating agent     

The repair of G-quadruplex-induced DNA damage

G4 DNA motifs, which can form stable secondary structures called G-quadruplexes, are ubiquitous in eukaryotic genomes, and have been shown to cause genomic instability. Specialized helicases that unwind G-quadruplexes in vitro have been identified, and they have been shown to prevent genetic instability in vivo. In the absence of these helicases, G-quadruplexes can persist and cause replication fork stalling and collapse. Translesion synthesis (TLS) and homologous recombination (HR) have been proposed to play a role in the repair of this damage, but recently it was found in the nematode Caenorhabditis elegans that G4-induced genome alterations are generated by an error-prone repair mechanism that is dependent on the A-family polymerase Theta (Pol θ). Current data point towards a scenario where DNA replication blocked at G-quadruplexes causes DNA double strand breaks (DSBs), and where the choice of repair pathway that can act on these breaks dictates the nature of genomic alterations that are observed in various organisms.     

Differential repair of etheno-DNA adducts by bacterial and human AlkB proteins

AlkB proteins are evolutionary conserved Fe(II)/2-oxoglutarate-dependent dioxygenases, which remove alkyl and highly promutagenic etheno(ɛ)-DNA adducts, but their substrate specificity has not been fully determined. We developed a novel assay for the repair of ɛ-adducts by AlkB enzymes using oligodeoxynucleotides with a single lesion and specific DNA glycosylases and AP-endonuclease for identification of the repair products. We compared the repair of three ɛ-adducts, 1,N⁶-ethenoadenine (ɛA), 3,N⁴-ethenocytosine (ɛC) and 1,N²-ethenoguanine (1,N²-ɛG) by nine bacterial and two human AlkBs, representing four different structural groups defined on the basis of conserved amino acids in the nucleotide recognition lid, engaged in the enzyme binding to the substrate.Two bacterial AlkB proteins, MT-2B (from Mycobacterium tuberculosis) and SC-2B (Streptomyces coelicolor) did not repair these lesions in either double-stranded (ds) or single-stranded (ss) DNA. Three proteins, RE-2A (Rhizobium etli), SA-2B (Streptomyces avermitilis), and XC-2B (Xanthomonas campestris) efficiently removed all three lesions from the DNA substrates. Interestingly, XC-2B and RE-2A are the first AlkB proteins shown to be specialized for ɛ-adducts, since they do not repair methylated bases. Three other proteins, EcAlkB (Escherichia coli), SA-1A, and XC-1B removed ɛA and ɛC from ds and ssDNA but were inactive toward 1,N²-ɛG. SC-1A repaired only ɛA with the preference for dsDNA. The human enzyme ALKBH2 repaired all three ɛ-adducts in dsDNA, while only ɛA and ɛC in ssDNA and repair was less efficient in ssDNA. ALKBH3 repaired only ɛC in ssDNA. Altogether, we have shown for the first time that some AlkB proteins, namely ALKBH2, RE-2A, SA-2B and XC-2B can repair 1,N²-ɛG and that ALKBH3 removes only ɛC from ssDNA. Our results also suggest that the nucleotide recognition lid is not the sole determinant of the substrate specificity of AlkB proteins.     

Repair of O4-Alkylthymine by O6-Alkylguanine-DNA Alkyltransferases

O⁶-Alkylguanine-DNA alkyltransferase (AGT) plays a major role in repair of the cytotoxic and mutagenic lesion O⁶-methylguanine (m⁶G) in DNA. Unlike the Escherichia coli alkyltransferase Ogt that also repairs O⁴-methylthymine (m⁴T) efficiently, the human AGT (hAGT) acts poorly on m⁴T. Here we made several hAGT mutants in which residues near the cysteine acceptor site were replaced by corresponding residues from Ogt to investigate the basis for the inefficiency of hAGT in repair of m⁴T. Construct hAGT-03 (where hAGT sequence -V¹⁴⁹CSSGAVGN¹⁵⁷- was replaced with the corresponding Ogt -I¹⁴³GRNGTMTG¹⁵¹-) exhibited enhanced m⁴T repair activity in vitro compared with hAGT. Three AGT proteins (hAGT, hAGT-03, and Ogt) exhibited similar protection from killing by N-methyl-N′-nitro-N-nitrosoguanidine and caused a reduction in m⁶G-induced G:C to A:T mutations in both nucleotide excision repair (NER)-proficient and -deficient Escherichia coli strains that lack endogenous AGTs. hAGT-03 resembled Ogt in totally reducing the m⁴T-induced T:A to C:G mutations in NER-proficient and -deficient strains. Surprisingly, wild type hAGT expression caused a significant but incomplete decrease in NER-deficient strains but a slight increase in T:A to C:G mutation frequency in NER-proficient strains. The T:A to C:G mutations due to O⁴-alkylthymine formed by ethylating and propylating agents were also efficiently reduced by either hAGT-03 or Ogt, whereas hAGT had little effect irrespective of NER status. These results show that specific alterations in the hAGT active site facilitate efficient recognition and repair of O⁴-alkylthymines and reveal damage-dependent interactions of base and nucleotide excision repair.     

Hydrazine and methylhydrazine as recA+-independent mutagens in Escherichia coli

The ultimate cause of both physical and chemical mutagenesis is assumed in most cases, to be some inducible error-prone repair process acting on the lesions caused by the mutagenic agent [7]. In Escherichia coli this mutagenic pathway seems to be dependent on both recA⁺ and lexA⁺ loci [10]. There are some mutagens, however, such as simple base analogs or some strong alkylating agents, such as N-methyl-N′-nitro-N′-nitrosoguanidine, that probably act by simply causing mis-pairing of bases in DNA. There is some evidence, based on work done with bacteriophages [2] or with Haemophilus influenzae [6], that hydrazine also acts by producing errors in base pairing. In this paper, further evidence is reported in support of this theory by showing that the recA lexA genotype does not affect the mutagenic properties of either hydrazine or methylhydrazine in Escherichia coli.     

Differential sensitivity of DNA replication and repair in permeable Escherichia coli exposed to various monofunctional methylating or ethylating agents.

Escherichia coli cells made permeable to deoxynucleoside triphosphates by brief treatment with toluene (permeablized) were used to measure the effect of the following chemical alkylating agents on either DNA replication or DNA repair synthesis: methyl methanesulfonate (MMS), ethyl methanesulfonate (EMS), N-methyl-N-nitrosourea (MNU), N-ethyl-N-nitrosourea (ENU), N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) and N-ethyl-N′-nitro-N-nitrosoguanidine (ENNG). Replication of DNA in this pseudo-in vivo system was completely inhibited 10–15 min after exposure to MMS at concentrations of 5 mM or higher or to MNU or MNNG at concentrations of 1 mM or higher. The ethyl derivatives of the alkylating agents were less inhibitory than their corresponding methyl derivatives, and inhibition of DNA replication occurred in the following order: EMS < ENNG < ENU. Maximum inhibition of DNA replication by all of the alkylating agents tested except EMS occurred at a concentration of 20 mM or lower. The extent of replication in cells exposed to EMS continued to decrease with concentrations of EMS up to 100 mM (the highest concentration tested).The experiments in which the inhibition of DNA replication by MMS, MNU, or MNNG was measured were repeated under similar assay conditions except that a density label was included and the DNA was banded in CsCl gradients. The bulk of the newly synthesized DNA from the untreated cells was found to be of the replicative (semi-conservative) type. The amount of replicative DNA decreased with increasing concentration of methylating agent in a manner similar to that observed in the incorporation experiments.Polymerase I (Pol I)-directed DNA repair synthesis induced by X-irradiation of permeablized cells was assayed under conditions that blocked the activity of DNA polymerases II and III. Exposure of cells to MNNG or ENNG at a concentration of 20 mM resulted in reductions in Pol I activity of 40 and 30%, respectively, compared with untreated controls. ENU was slightly inhibitory to Pol I activity, while MMS, EMS, and MNU all caused some enhancement of Pol I activity.These data show that DNA replication in a pseudo-in vivo bacterial system is particularly sensitive to the actions of known chemical mutagens, whereas DNA repair carried out by the Pol I repair enzyme is much less sensitive and in some cases apparently unaffected by such treatment. Possible mechanisms for this differential effect on DNA metabolism and its correlation with current theories of chemically induced mutagenesis and carcinogenesis are discussed.     

High-resolution Digital Mapping of N-Methylpurines in Human Cells Reveals Modulation of Their Induction and Repair by Nearest-neighbor Nucleotides

N-Methylpurines (NMPs), including N⁷-methylguanine (7MeG) and N³-methyladenine (3MeA), can be induced by environmental methylating agents, chemotherapeutics, and natural cellular methyl donors. In human cells, NMPs are repaired by the multi-step base excision repair pathway initiated by human alkyladenine glycosylase. Repair of NMPs has been shown to be affected by DNA sequence contexts. However, the nature of the sequence contexts has been poorly understood. We developed a sensitive method, LAF-Seq (Lesion-Adjoining Fragment Sequencing), which allows nucleotide-resolution digital mapping of DNA damage and repair in multiple genomic fragments of interest in human cells. We also developed a strategy that allows accurate measurement of the excision kinetics of NMP bases in vitro. We demonstrate that 3MeAs are induced to a much lower level by the S_N2 methylating agent dimethyl sulfate and repaired much faster than 7MeGs in human fibroblasts. Induction of 7MeGs by dimethyl sulfate is affected by nearest-neighbor nucleotides, being enhanced at sites neighbored by a G or T on the 3′ side, but impaired at sites neighbored by a G on the 5′ side. Repair of 7MeGs is also affected by nearest-neighbor nucleotides, being slow if the lesions are between purines, especially Gs, and fast if the lesions are between pyrimidines, especially Ts. Excision of 7MeG bases from the DNA backbone by human alkyladenine glycosylase in vitro is similarly affected by nearest-neighbor nucleotides, suggesting that the effect of nearest-neighbor nucleotides on repair of 7MeGs in the cells is primarily achieved by modulating the initial step of the base excision repair process.     

Analysis of Ribonucleotide Removal from DNA by Human Nucleotide Excision Repair

Ribonucleotides are incorporated into the genome during DNA replication. The enzyme RNase H2 plays a critical role in targeting the removal of these ribonucleotides from DNA, and defects in RNase H2 activity are associated with both genomic instability and the human autoimmune/inflammatory disorder Aicardi-Goutières syndrome. Whether additional general DNA repair mechanisms contribute to ribonucleotide removal from DNA in human cells is not known. Because of its ability to act on a wide variety of substrates, we examined a potential role for canonical nucleotide excision repair in the removal of ribonucleotides from DNA. However, using highly sensitive dual incision/excision assays, we find that ribonucleotides are not efficiently targeted by the human nucleotide excision repair system in vitro or in cultured human cells. These results suggest that nucleotide excision repair is unlikely to play a major role in the cellular response to ribonucleotide incorporation in genomic DNA in human cells.     

Correlation between lethality and DNA single-strand breaks in Bacillus subtilis cells treated with N-methyl-N'-nitro-N-nitrosoguanidine

The effects of N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) treatment two Bacillus subtilis strains which exhibit different UV sensitivities were monitored at both the cellular (survival) and subcellular (DNA strand break) levels. The MNNG-induced single strand DNA breaks (SSB) in either strain, as measured by alkaline sucrose gradient centrifugation, were shown to be well correlated with lethality. These DNA lesions were shown by a computer simulation to be randomly induced. Cell survival after MNNG treatment is inversely related to the number of replication forks per cell which in turn depends upon the doubling time of the culture and the growth phase. The production of single-strand breaks and cell killing are proportional to the log of the initial MNNG concentration and may imply that decomposition of the mutagen is (pseudo) second order.