In vitro DNA replication implicates O2-ethyldeoxythymidine in transversion mutagenesis by ethylating agents.

A 36-nucleotide oligomer containing a single O2-ethyldeoxythymidine (O2-Et-dT) adduct at a specific site was synthesized. The oligomer, which corresponds to a specific DNA sequence in gene G of bacteriophage phi X174, was used as a template by T7 DNA polymerase to investigate the in vitro mutagenic specificity of O2-Et-dT. At 10 microM dNTP and 5 mM Mg++, the progress of T7 DNA polymerase was interrupted by O2-Et-dT: 80% 3' to O2-Et-dT and 14% after incorporating a nucleotide opposite O2-Et-dT (incorporation-dependent blocked product). DNA synthesis past the lesion was low (6%). Incorporation of a nucleotide opposite O2-Et-dT and subsequent postlesion synthesis were enhanced by increasing the dNTP concentration, with postlesion synthesis reaching 30% at 200 microM. Postlesion synthesis was further increased to 45% by addition of 10 mM dAMP to the polymerization reactions. DNA sequencing revealed that both dA and dT were incorporated opposite O2-Et-dT with dA incorporation impeding the progress of DNA synthesis. dT incorporation was efficiently extended implicating O2-Et-dT in transversion mutagenesis in vivo. These studies provide a basis for understanding the molecular mechanisms by which ethylating agents contribute to cytotoxicity, A.T transversion mutagenesis and activation of the oncogene neu by an A.T----T.A transversion event in rat neuroblastomas.     

The role of N3-ethyldeoxythymidine in mutagenesis and cytotoxicity by ethylating agents

The significance of DNA ethylation at the central hydrogen-bonding site (N3) of thymine was investigated using an in vitro DNA replication system. The system utilized a primed template in which the 3'-end of the primer is eight nucleotides away from N3-ethyldeoxythymidine (N3-Et-dT), present at template position 26 from the 3'-end. The 34-nucleotide template corresponds to a specific DNA sequence at gene G of bacteriophage phi X174. DNA synthesis products were quantitated by electrophoretic separation and autoradiography. At 10 microM dNTP and 0.5 mM Mn2+, N3-Et-dT blocked DNA synthesis by Escherichia coli polymerase I (Klenow fragment): 60% after incorporating a nucleotide opposite N3-Et-dT (incorporation-dependent blocked product) and 39% 3' to N3-Et-dT. DNA replication past the lesion (post-lesion synthesis) was negligible. Post-lesion synthesis increased using higher concentrations of dNTP, reaching 68% at 200 microM dNTP. DNA sequencing revealed that dA was incorporated opposite N3-Et-dT in the incorporation-dependent blocked product. In the post-lesion synthesis product, dT was exclusively incorporated opposite N3-Et-dT. Formation of the N3-Et-dT.dA base pair at the replication fork terminated DNA synthesis, while the N3-Et-dT.dT base pair formed at the 3'-end of the growing chain was extended, leading to an A.T----T.A transversion mutation. The results suggest a dual role for the N3-Et-dT lesion, contributing in part to the cytotoxicity and mutagenicity of ethylating agents. These studies provide a basis for understanding the activation of oncogene neu by A.T----T.A transversion mutation in rat neuroblastomas induced by N-ethyl-N-nitrosourea.     

DNA adduct formation by alachlor metabolites

The extent of DNA adduct formation by alachlor [ArN(CH2OCH3)C(O)CH2Cl wherein Ar is 2,6-diethylphenyl] and its metabolites is used as a guide to deduce the causal agent(s) in the carcinogenicity of this major herbicide. [14C-phenyl]Alachlor is compared to its two metabolic cleavage products, [14C-phenyl]2-chloro-N-(2,6-diethylphenyl)acetamide (CDEPA) [ArNHC(O)CH2Cl] and [14C-phenyl]2,6-diethylaniline (DEA) (ArNH2), and to [14C-methoxy]alachlor in various in vitro and in vivo systems. Horseradish peroxidase and hydrogen peroxide activate DEA, but not CDEPA or alachlor, for formation of adducts with calf thymus DNA, which probably involves 2,6-diethylnitrosobenzene (ArNO) as an intermediate. Mouse liver microsomes and NADPH are both required to enhance the binding from each labeled preparation to calf thymus DNA; 4-fold higher labeling is observed from [14C-methoxy]- than from [14C-phenyl]alachlor. This 4-fold preferential DNA labeling from the 14C-methoxy compound is likewise found in the liver of mice treated intraperitoneally. Mouse liver protein and hemoglobin are also labeled, in vivo, with [14C-phenyl]alachlor, -CDEPA and -DEA, and, as with the DNA, the labeling of these proteins is 1.5- to 2-fold higher with [14C-methoxy]alachlor. Metabolic studies indicate that ArN(CH2OCH2OH)C(O)CH2Cl is an intermediate in forming CDEPA and presumably formaldehyde in the mouse liver microsomal mixed-function oxidase system and in yielding the O-glucuronide of ArN(CH2OH)C(O)CH2Cl in the urine of alachlor-treated mice. These findings point to the N-CH2OCH2OH metabolite or formaldehyde as a reactive intermediate in forming a DNA-adduct and as a candidate proximate carcinogen.     

Micronucleated reticulocyte induction by ethylating agents in mice.

Six model ethylating agents were tested for clastogenic potency by means of a new technique of the micronucleus assay with mouse peripheral blood cells using acridine orange (AO)-coated slides, to evaluate the test. The alkylating agents were: N-ethyl-N'-nitro-N-nitrosoguanidine (ENNG), N-ethyl-N-nitrosourea (ENU), diethylsulfate (DES), ethyl methanesulfonate (EMS), epichlorohydrin (ECH) and ethylene dibromide (EDB). The animals were given a single intraperitoneal injection of the following doses of the chemicals: ENNG and ENU, 25, 50 and 100 mg/kg; EMS and DES, 100, 200 and 400 mg/kg body weight. For EDB and ECH, the doses were 50, 100 and 200 mg/kg, given twice, 24 h apart. Before and after the injection, blood samples were taken from the tails at 24-h intervals up to 72 h and preparations were made on AO-coated slides. For each dose group, 4 animals were used and 1000 reticulocytes were examined per slide for the presence of micronuclei. At the optimum induction time of 48 h, ENU induced micronucleated reticulocytes (MNRETs) at all 3 doses. ENNG and EMS induced MNRETs significantly at 2 dose levels each and DES only at the highest dose. ECH and EDB failed to induce MNRETs. On the basis of the dose of chemical needed to double the spontaneous frequency, the order of clastogenic potency was ENU greater than ENNG greater than EMS greater than DES. The results obtained compared favorably with those from other in vivo methods. The present technique proves to be simple, flexible and relatively sensitive. Shifts in the optimum induction peak in individual animals and by some chemicals can be picked up easily which is important when testing weak mutagens and chemicals with an unknown mechanism of action.     

Genotoxicity and DNA adduct formation of incense smoke condensates: comparison with environmental tobacco smoke condensates

Indoor air pollution has now been recognized as a potentially important problem for public health, since people spend most of their day in closed environments. Incense burning is possibly associated with elevated risks of leukemia and brain tumor in children from the epidemiological studies. Thus, evaluation of the genotoxicity of smoke condensates from incense burning is needed. We examined the genotoxicity of incense smoke condensates (ISC) using the Ames test in S. typhimurium strains with different mutagenic specificity and level of metabolic enzyme, the SOS chromotest in E. coli PQ37, and sister chromatid exchange assay in Chinese hamster ovary cells (SCE/CHO). The genotoxicity of environmental tobacco smoke condensates (TSC) was also evaluated by the three assays to compare with the genotoxicity of ISC, ISC showed a positive response in TA98, but not in TA100. It suggested that ISC only contained frame shift mutagens. The mutagenicity of ISC in both strains of TA98NR with deficient nitroreductase and TA98/1,8-DNP₆ with deficient O-acetyl-transferase was markedly decreased compared to that in TA98 strain. However, the mutagenicity was enhanced in YG1024 with overexpression of O-acetyltransferase activity. Thus, nitroarenes seemed to be responsible in part for the mutagenicity of ISC. Interestingly, all of the four ISC and two TSC samples showed a dose-dependent genotoxic response in the SOS chromotest with E. coli PQ37 but a low SCE induction of those samples were observed in CHO cells. When the genotoxicity was analyzed based on the condensates per one gram of original samples, the genotoxicity of two TSC condensates in prokaryotic cells was higher than that of four ISC samples except for the genotoxicity of TSC-2 in TA98 strain. However, the genotoxicity of certain ISC in eukaryotic cells based on the SCE/CHO assay was higher than that of TSC. To compare the covalent binding of DNA reactive intermediates of ISC and TSC to S. typhimurium TA98, the DNA adducts were evaluated by the ³²P-postlabeling method with butanol extraction version. Similar diagonal radioactive zone (DRZ) was observed between ISC and CSC. However, DNA adduct levels induced by TSC were much greater than that of ISC.     

Evidence for AP site formation related to DNA-oxygen alkylation in CHO cells treated with ethylating agents

DNA single-strand breaks (ssb) induced by N-ethyl-N-nitrosourea (ENU) in CHO cells are quickly resealed within 10 min after treatment. This rapid repair kinetics is not explained by the rate of base excision repair which removes the main ethyl products with a half-life in the order of hours. We have explored the potential use of methoxyamine (MX), a chemical that reacts at neutral pH with AP sites in DNA in vitro, to clarify the origin of ENU-induced ssb. The presence of 50 mM MX during cell treatment with diethyl sulfate (DES) caused selective inhibition of the repair of AP sites generated during base excision repair and inhibited alkaline cleavage at these sites. The treatment of CHO cells with ENU in the presence of MX clearly showed that the burst of ssb observed immediately after treatment was due to AP site formation. Plasmid DNA treated in vitro with ENU did not present AP endonuclease-sensitive sites; therefore, the AP sites produced in CHO cells by ENU treatment are not due to the chemical hydrolysis of a very unstable ethyl adduct but rather are intermediates of an as yet undefined enzymatic pathway. This process occurs specifically after treatment with SN1-type ethylating agents (ENU and N-ethyl-N'-nitro-N-nitrosoguanidine) suggesting an association between this phenomenon and DNA-oxygen alkylation. We suggest that these breaks are generated by a mechanism of O6-ethylguanine processing without removal of the modified base.     

DNA adduct formation in human hepatoma cells treated with 3-nitrobenzanthrone: analysis by the P-postlabeling method

3-Nitrobenzanthrone (3-nitro-7H-benz[d,e]anthracen-7-one, 3-NBA) is a powerful mutagen and a suspected human carcinogen existing in diesel exhaust and airborne particulates. Recently, one of the major presumed metabolites of 3-NBA, 3-aminobenzanthrone (3-ABA), was detected in human urine samples. Here we analyzed DNA adducts formed in 3-NBA-exposed human hepatoma HepG2 cells by a ³²P-postlabeling/thin layer chromatography (TLC) method and a ³²P-postlabeling/polyacrylamide gel electrophoresis (PAGE) method. With HepG2 cells exposed to 3-NBA (0.36–36.4 μM) for 3 h, we obtained three spots or bands corresponding to adducted nucleotides. Two were assigned as 2-(2′-deoxyadenosin-N⁶-yl)-3-aminobenzanthrone-3′-phosphate (dA3′p-N⁶-C2-ABA) and 2-(2′-deoxyguanosin-N²-yl)-3-aminobenzanthrone-3′-phosphate (dG3′p-N²-C2-ABA), with identical mobilities to those of synthetic standards on PAGE analysis. The chemical structure of the substance corresponding to the other spot or band could not be identified. Quantitative analyses revealed that the major adduct was dA3′p-N⁶-C2-ABA and its relative adduct labeling (RAL) value at 36.4 μM of 3-NBA was 200.8 ± 86.1/10⁸ nucleotide.     

Preparation and characterization of a viral DNA molecule containing a site-specific 2-aminofluorene adduct: a new probe for mutagenesis by carcinogens

The synthetic oligonucleotide heptamer 5'-ATCCGTC-3' was reacted in vitro with N-acetoxy-N-(trifluoroacetyl)-2-aminofluorene and the resulting product isolated by reverse-phase high-performance liquid chromatography (HPLC). This purified oligonucleotide, which was shown by chemical and enzymatic analysis to be a heptamer containing a single N-(deoxyguanin-8-yl)-2-aminofluorene adduct, was then used to situate the putatively mutagenic aminofluorene lesion within the genome of M13 mp9 by ligating it into a complementary single-stranded region located at a specific site in the negative strand of the duplex M13 mp9 DNA molecule. The presence of the adduct at the anticipated location was confirmed by taking advantage of the facts that AF adducts inhibit many restriction enzymes when located in or near their restriction sites and that the AF moiety should be contained within the HincII recognition sequence on M13 mp9 DNA. Upon attempted cleavage of the M13 DNA containing the site-specific AF adduct with HincII, we find that the large majority of the DNA remained circular, demonstrating the incorporation of the AF adduct in high yield into the DNA molecule at this location. This system should prove useful in vivo for the study of mutagenesis by chemical carcinogens and in vitro to study the interaction of purified DNA metabolizing proteins with a template containing a site-specific lesion.     

Expression of DNA damage-inducible genes of Escherichia coli upon treatment with methylating, ethylating and propylating agents

Several alkylation-inducible genes have been identified by construction of Mu-d1 (Apr lac) fusions to genes whose expression is increased in response to alkylation treatment, but not UV treatment. We have examined the induction of 4 different alkylation-inducible genes by treatment with a variety of methylating and ethylating agents, and a propylating agent. We have compared the induction of the alkylation-inducible genes with the induction of the sulA gene, which is a component of the SOS response to DNA damage. We find that the Ada-regulated adaptive response genes (ada-alkB, alkA and aidB) are induced primarily in response to methylation treatment. The ada-independent aidC gene is induced upon treatment with agents that alkylate predominantly by SN1 nucleophilic attack. aidC induction occurs only when cells are not aerated during treatment. The SOS response, as indicated by sulA induction, is strongly induced by all types of alkylating agents used.     

DNA adduct formation by Fusarium culture extracts: lack of role of fusarin C

Fusarium fungi have been shown to infect corn and other crops worldwide, and have a significant impact on human health through loss of crops or contamination of food with mycotoxins. Isolates of Fusarium fungi from an area of South Africa with high incidence of esophageal cancer have been shown to induce esophageal and liver cancer in rats. Several isolates of Fusarium fungi were grown on corn to determine if genotoxic products were produced. We report the incubation of methanol extracts of Fusarium verticillioides cultures with DNA in the presence of rat liver fractions (S9) resulted in the formation of a unique DNA adduct that was detected by (32)P-postlabeling. Fusarin C was purified from cultures of Fusarium verticillioides RRC 415, and was not responsible for the formation of the DNA adduct. Treatment of the methanolic extracts with ultraviolet B radiation reduced the fusarin C content in the extract; however, this had no effect on the formation of the DNA adduct following incubation of the extract with DNA and S9. The unique DNA adduct was formed following the incubation of several Fusarium verticillioides isolates from the US and South Africa, while extracts of cultures of Fusarium graminearium and Fusarium sacchari isolates formed very little of the DNA adduct when incubated with DNA and S9. These data suggest that neither fusarin C nor any of its metabolites are responsible for formation of the DNA adduct, and that an unidentified compound is present in F. verticillioides cultures that forms a DNA adduct, and may be important in the etiology of human esophageal cancer.     

The inactivation of bacteriophage R17 by ethylating agents: the lethal lesions.

The biological inactivation of bacteriophage R17 by ethyl methanesulphonate (EMS) and N-ethyl-N-nitrosourea (ENUA) has been studied. At the mean lethal dose for the first compound 8 moles ethyl are bound/mole RNA and with the nitroso compound 3.5 moles ethyl are bound. Analysis of the amounts of the different ethylated derivatives formed shows that the toxicity of the sulphonate can be accounted for by the formation of 3-ethylcytosine, O6-ethylguanine, 1-ethyladenine and chain breaks produced on the hydrolysis of ethyl phosphotriesters. With the nitroso derivative on the other hand, the sum of chain breaks and of bases alkylated on a position involved in specific hydrogen bonding between base pairs only accounts for 65% of the observed toxicity. The possibility that 3-ethyladenine may constitute a lethal lesion is discussed.     

DNA adduct formation by 12 chemicals with populations potentially suitable for molecular epidemiological studies.

DNA adduct formation, route of absorption, metabolism and chemistry of 12 hazardous chemicals are reviewed. Methods for adduct detection are also reviewed and approaches to sensitivity and specificity are identified. The selection of these 12 chemicals from the Environmental Protection Agency list of genotoxic chemicals was based on the availability of information and on the availability of populations potentially suitable for molecular epidemiological study. The 12 chemicals include ethylene oxide, styrene, vinyl chloride, epichlorohydrin, propylene oxide, 4,4'-methylenebis-2-chloroaniline, benzidine, benzidine dyes (Direct Blue 6, Direct Black 38 and Direct Brown 95), acrylonitrile and benzyl chloride. While some of these chemicals (styrene and benzyl chloride, possibly Direct Blue 6) give rise to unique DNA adducts, others do not. Potentially confounding factors include mixed exposures in the work place, as well the formation of common DNA adducts. Additional research needs are identified.     

Temporally controlled site-specific mutagenesis in the germ cell lineage of the mouse testis

We have obtained a PrP-Cre-ER(T) transgenic mouse line (28.8) that selectively expresses in testis the tamoxifen-inducible Cre-ER(T) recombinase under the control of a mouse Prion protein (PrP) promoter-containing genomic fragment. Cre-ER(T) is expressed in spermatogonia and spermatocytes, but not in Sertoli and Leydig cells. We also established reporter PrP-L-EGFP-L transgenic mice harboring a LoxP-flanked enhanced green fluorescent protein (EGFP) Cre reporter cassette under the control of the same PrP promoter-containing genomic fragment that exhibits prominent EGFP expression in brain and testis. Using the PrP-L-EGFP-L as well as other Cre-reporter mice, we demonstrate that tamoxifen administration efficiently and selectively induces Cre-mediated recombination in the germ cell lineage. The established PrP-Cre-ER(T) line should provide a valuable tool for studying functions of germ cell-expressed genes involved in spermatogenesis.     

DNA adduct formation in human hepatoma cells treated with 3-nitrobenzanthrone: analysis by the (32)P-postlabeling method

3-Nitrobenzanthrone (3-nitro-7H-benz[d,e]anthracen-7-one, 3-NBA) is a powerful mutagen and a suspected human carcinogen existing in diesel exhaust and airborne particulates. Recently, one of the major presumed metabolites of 3-NBA, 3-aminobenzanthrone (3-ABA), was detected in human urine samples. Here we analyzed DNA adducts formed in 3-NBA-exposed human hepatoma HepG2 cells by a (32)P-postlabeling/thin layer chromatography (TLC) method and a (32)P-postlabeling/polyacrylamide gel electrophoresis (PAGE) method. With HepG2 cells exposed to 3-NBA (0.36-36.4 microM) for 3h, we obtained three spots or bands corresponding to adducted nucleotides. Two were assigned as 2-(2'-deoxyadenosin-N(6)-yl)-3-aminobenzanthrone-3'-phosphate (dA3'p-N(6)-C2-ABA) and 2-(2'-deoxyguanosin-N(2)-yl)-3-aminobenzanthrone-3'-phosphate (dG3'p-N(2)-C2-ABA), with identical mobilities to those of synthetic standards on PAGE analysis. The chemical structure of the substance corresponding to the other spot or band could not be identified. Quantitative analyses revealed that the major adduct was dA3'p-N(6)-C2-ABA and its relative adduct labeling (RAL) value at 36.4 microM of 3-NBA was 200.8+/-86.1/10(8)nucleotide.     

Formation of DNA adducts by microsomal and peroxidase activation of p-cresol: role of quinone methide in DNA adduct formation.

We have investigated the activation of p-cresol to form DNA adducts using horseradish peroxidase, rat liver microsomes and MnO(2). In vitro activation of p-cresol with horseradish peroxidase produced six DNA adducts with a relative adduct level of 8.03+/-0.43 x 10(-7). The formation of DNA adducts by oxidation of p-cresol with horseradish peroxidase was inhibited 65 and 95% by the addition of either 250 or 500 microM ascorbic acid to the incubation. Activation of p-cresol with phenobarbital-induced rat liver microsomes with NADPH as the cofactor; resulted in the formation of a single DNA adduct with a relative adduct level of 0.28+/-0.08 x 10(-7). Similar incubations of p-cresol with microsomes and cumene hydroperoxide yielded three DNA adducts with a relative adduct level of 0.35+/-0.03 x 10(-7). p-Cresol was oxidized with MnO(2) to a quinone methide. Reaction of p-cresol (QM) with DNA produced five major adducts and a relative adduct level of 20.38+/-1.16 x 10(-7). DNA adducts 1,2 and 3 formed by activation of p-cresol with either horseradish peroxidase or microsomes, are the same as that produced by p-cresol (QM). This observation suggests that p-cresol is activated to a quinone methide intermediate by these activation systems. Incubation of deoxyguanosine-3'-phosphate with p-cresol (QM) resulted in a adduct pattern similar to that observed with DNA; suggesting that guanine is the principal site for modification. Taken together these results demonstrate that oxidation of p-cresol to the quinone methide intermediate results in the formation of DNA adducts. We propose that the DNA adducts formed by p-cresol may be used as molecular biomarkers of occupational exposure to toluene.     

A comparison of in vitro platinum-DNA adduct formation between carboplatin and cisplatin

• 1.1. DNA damage induced by carboplatin [cis-diammine-(1,1-cyclobutanedi-carboxylato)platinum(II)] was studied in vitro in comparison with cisplatin [cis-diammine-dichloroplatinum(II)]. The drug-induced DNA damage monitored by conformational change of pUC18 plasmid DNA showed that carboplatin required 10 times higher drug concentration and 7.5 times longer incubation time than those of cisplatin to induce the same degree of conformational change on plasmid DNA.
• 2.2. The carboplatin-induced DNA damage was promoted by the increase of pH of the reaction mixture for platinum-DNA adduct formation.
• 3.3. Sequence gel analysis of carboplatin-damaged DNA indicated that carboplatin attacked preferentially the sequence of GG > AG > GA > GNG in the order, similarly to the case of cisplatin.
• 4.4. DNA adducts formed by carboplatin were analyzed by HPLC after a sequential digestion of carboplatin-treated DNA with deoxyribonuclease I and S1 nuclease. A single peak having the same retention time as that of bifunctional adduct of (dGMP)₂Pt(NH₃)₂ appeared by treating DNA with carboplatin. The adduct was assigned to be d(pGpG) > Pt(NH₃)₂.
• 5.5. These results suggested that carboplatin induces the same platinum-DNA adducts as those induced by cisplatin, and that the difference in efficiency or kinetics of DNA damage between carboplatin and cisplatin is due to difference of aquation rate between them.