Mammalian cell mutagenesis of the DNA adducts of vinyl chloride and crotonaldehyde

Vinyl chloride and crotonaldehyde are known mutagens and carcinogens that, through their reaction with DNA, form specific deoxyguanosine adducts. To investigate the mutagenic potential of a subset of the possible deoxyguanosine lesions, site-specific adducts of vinyl chloride and crotonaldehyde were synthesized, inserted into a shuttle vector, and replicated in mammalian cells. Mutation yields of the DNA adducts of vinyl chloride and crotonaldehyde were found to be 2% and 5-6%, respectively, thus suggesting that these adducts could contribute to the overall genotoxicity and carcinogenicity associated with exposure to these chemicals.     

Mutagenic potential of adenine N(6) adducts of monoepoxide and diolepoxide derivatives of butadiene

To determine the biological effects of specific DNA adducts resulting from the interaction of 1,3-butadiene metabolites with DNA, deoxyoligonucleotides have been synthesized with four different adducts at the N(6) position of adenine, centrally located within the human N-ras codon 61. The adducts are those arising from adduction by either the R or S stereoisomer of the monoepoxide (BDO) or the (R,R) or (S,S) isomer of the diolepoxide (BDE). The diolepoxide can arise from partial hydrolysis of the diepoxide (BDO(2)) or from epoxidation of hydrolyzed monoepoxide. These adducted oligonucleotides were used in in vivo and in vitro assays designed both to determine their mutagenic potency and to examine specific interactions with Escherichia coli polymerases. Each adducted oligonucleotide was ligated into a single-stranded vector M13mp7L2 that was subsequently used to transfect E. coli. The resulting mutagenic spectrum for these modified DNAs was stereoisomer specific. Both monoepoxide lesions were nonmutagenic, but the mutagenic spectra for the modified DNAs containing BDE adducts were stereoisomer specific. The mutations generated by adducts of the R,R enantiomer of the diolepoxide were exclusively A --> G, whereas adducts of the S,S enantiomer of the diolepoxide yielded exclusively A --> C mutations. None of the four modifications resulted in significant blocks to in vivo phage replication, as evidenced by no decrease in plaque-forming ability. Consistent with these data, when each of three purified E. coli polymerases was used to replicate DNAs containing these adducted deoxyoligonucleotides, the individual polymerases appeared to be virtually unaffected, such that all lesions were readily bypassed. Whereas previous animal model studies identified the mutagenic spectrum related to butadiene exposure, these studies begin to establish the specific lesions responsible for mutagenesis. This is the first report of stereoselectivity related to butadiene-induced mutagenesis.     

Point mutations induced by 1,2-epoxy-3-butene N1 deoxyinosine adducts.

The National Toxicology Program has recently classified 1,3-butadiene (BD) as a human carcinogen. BD is metabolized to the intermediates 1,2-epoxy-3-butene (EB), 1,2:3,4-diepoxybutane (DEB), and 1,2-dihydroxy-3,4-epoxybutane. All three metabolites have been implicated in producing specific types of DNA damage and as genotoxic agents in mice, rat, and human cells. This study has focused on EB-induced N1 deoxyinosine lesions that are formed by deamination of deoxyadenosine following reaction of the epoxide at the N(1) position. The R and S stereoisomers of this lesion were incorporated site-specifically within the context of an 11-mer oligodeoxynucleotide, incorporated into M13mp7L2 single-stranded DNA, and transfected into E. coli. Both stereoisomers modestly reduced plaque-forming ability, indicating that neither lesion presents a base modification that cannot be bypassed. The resulting plaques were assessed for point mutations using differential hybridization and DNA sequence analyses. The overall mutagenic spectrum revealed that the N1 adducts were highly mutagenic (approximately 90% per replication cycle), causing a predominance of A --> G transitions.     

Comparison of mutagenicity and calf thymus DNA adducts formed by the particulate and semivolatile fractions of vehicle exhausts

In this study we compared the ability of extractable organic material from particulate and semivolatile fractions of gasoline emission to induce mutations in bacteria and form adducts with calf thymus (CT) DNA with corresponding data obtained from diesel exhaust. Exhaust particles from gasoline-powered passenger cars were collected on filters and semivolatile compounds were collected on polyurethane foam (PUF). The mutagenicity of the soluble organic fraction (SOF) was determined in Salmonella typhimurium strain TA98 and the DNA binding of aromatic compounds in the extracts was assessed by in vitro incubations with CT DNA and rat liver S9 (oxidative activation) or xanthine oxidase (reductive activation) followed by butanol-enhanced (32)P-postlabeling analysis. Semivolatile fractions of gasoline emission collected on PUF formed more CT DNA adducts than filter extracts under all reaction conditions, but showed a lower mutagenic potential than the corresponding particulate samples. This suggests that the capacity of PUF to collect exhaust particle-derived compounds and/or the efficiency of xanthine oxidase and enzymes in the rat liver S9 to activate these compounds to DNA binding metabolites was higher than expected. Gasoline extracts, benzo[a]pyrene and diesel particulate matter (SRM 1650) formed more S9-mediated DNA adducts as their dose increased, although a linear dose-response was not observed for the gasoline exhausts. Lower concentrations of gasoline and diesel extracts bound to DNA with greater efficiency than did 8-fold higher doses, suggesting complex interactions and/or an inhibition of S9 enzyme activities by the high doses. Diesel extracts formed higher levels of adducts than gasoline extracts, especially with the reductive activation system, suggesting that diesel extracts contain high levels of nitro-polycyclic aromatic hydrocarbons (nitro-PAHs). The higher direct-acting Salmonella mutagenicity in diesel extracts in comparison with gasoline extracts is consistent with diesel extracts containing higher concentrations of nitro-PAHs. The results of this study indicate that diesel extracts are more mutagenic and form more DNA adducts than gasoline extracts and that the effects of extract dose on DNA adduct formation are complex.     

Pathological significance of oxidative cellular damage in human alcoholic liver disease

AIMS: To investigate the pathological significance of oxidative stress-induced lipid peroxidation and oxidative DNA damage in alcoholic liver disease. METHODS AND RESULTS: Hepatic expression of 4-hydroxy-2'-nonenal (HNE) adducts and 8-hydroxydeoxyguanosine (8-OHdG) as reliable markers of lipid peroxidation and oxidative DNA damage, respectively, was analysed immunohistochemically and compared with histological findings in alcoholic liver disease. While no HNE adducts were observed in control livers, HNE adducts were frequently (37 of 40 cases, 92.5%) detected in alcoholic liver disease. The localization of HNE adducts was the cytoplasm of hepatocytes and sinusoidal cells in zone 3. As for 8-OHdG, 29 of 40 cases (72.5%) with alcoholic liver disease exhibited positive immunolabelling for 8-OHdG, while 8-OHdG expression was not evident in control livers. The nuclear expression of 8-OHdG was mainly detected in the hepatocytes within the areas of active inflammation. Among histological parameters, the grade of necro-inflammation activity as well as the presence of Mallory bodies were significantly associated with the expression of HNE adducts and 8-OHdG. In addition, the severity of steatosis also correlated with HNE adduct expression. CONCLUSIONS: Lipid peroxidation and oxidative DNA damage occur widely and may be associated with certain pathological features in human alcoholic liver disease.     

Genotoxicity of naturally occurring indole compounds: correlation between covalent DNA binding and other genotoxicity tests

3-Methylindole (3MI), melatonin (Mel), serotonin (Ser), and tryptamine (Tryp) were evaluated in vitro for their potential to induce DNA adducts, DNA strand breaks, chromosomal aberrations (Abs), inhibition of DNA synthesis, and mutations. All compounds produced DNA adducts in calf thymus DNA in the presence of rat liver S9. In cultured rat hepatocytes, all produced DNA adducts but none induced DNA strand breaks. In Chinese hamster ovary cells, 3MI and Mel produced DNA adducts, Abs, and inhibition of DNA synthesis with and without S9, except that Mel without S9 did not form adducts. Ser formed DNA adducts, was an equivocal Abs inducer, and suppressed DNA synthesis. Tryp induced neither adducts nor Abs, but did suppress DNA synthesis with S9. Ser and Tryp were less cytotoxic than 3MI and Mel. Mel, Ser, and Tryp failed to induce mutations in Salmonella and E. coli strains with or without S9. 3MI and Mel produced DNA adducts but not mutations in Salmonella TA100 with S9. 3MI and its metabolite indole 3-carbinol also did not induce mutations in a shuttle vector system in human cells. The lack of correlation between DNA adducts and other genotoxicity endpoints for these indole compounds may be due to the higher sensitivity of the (32)P-postlabeling adduct assay or it may indicate that the indole-DNA adducts per se are not mutagenic and are not able to induce strand breaks or alkali-labile lesions. The indole-induced Abs may result from cytotoxicity and suppression of DNA synthesis with minimal if any contribution from DNA adducts.     

Evidence for the presence of mutagenic arylamines in human breast milk and DNA adducts in exfoliated breast ductal epithelial cells

Aromatic and heterocyclic amines are ubiquitous environmental mutagens present in combustion emissions, fried meats, and tobacco smoke, and are suspect human mammary carcinogens. To determine the presence of arylamines in breast tissue and fluid, we examined exfoliated breast ductal epithelial cells for DNA adducts and matched human milk samples for mutagenicity. Breast milk was obtained from 50 women who were 4-6 weeks postpartum, and exfoliated epithelial-cell DNA was evaluated for bulky, nonpolar DNA adducts by (32)P-postlabeling and thin-layer chromatography. Milk was processed by acid hydrolysis, and the extracted organics were examined in the standard plate-incorporation Ames Salmonella assay using primarily strain YG1024, which detects frameshift mutations and overexpresses aryl amine N-acetyltransferase. DNA adducts were identified in 66% of the specimens, and bulky adducts migrated in a pattern similar to that of 4-aminobiphenyl standards. The distribution of adducts did not vary by NAT2 genotype status. Of whole milk samples, 88% (22/25) had mutagenic activity. Among the samples for which we had both DNA adduct and mutagenicity data, 58% (14/19) of the samples with adducts were also mutagenic, and 85% (11/13) of the mutagenic samples had adducts. Quantitatively, no correlation was observed between the levels of adducts and the levels of mutagenicity. Separation of the milk showed that mutagenic activity was found in 69% of skimmed milk samples but in only 29% of the corresponding milk fat samples, suggesting that the breast milk mutagens were moderately polar molecules. Chemical fractionation showed that mutagenic activity was found in 67% (4/6) of the basic fractions but in only 33% (2/6) of acidic samples, indicating that the mutagens were primarily basic compounds, such as arylamines. Although pilot in nature, this study corroborates previous findings of significant levels of DNA adducts in breast tissue and mutagenicity in human breast milk and indicates that breast milk mutagens may be moderately polar basic compounds, such as arylamines.     

Propylene oxide mutagenesis at template cytosine residues

Propylene oxide (PO) is a widely used industrial reagent which is mutagenic and carcinogenic. We have recently shown that a variety of aliphatic epoxides, including propylene oxide, can react with DNA to form hydroxyalkyl adducts at N-3 of cytosine which rapidly undergo hydrolytic deamination to produce uracil adducts. These 3-hydroxyalkyl uracil adducts are stable in DNA and are postulated to be an important class of potentially mutagenic lesions. Mutagenesis at cytosine residues due to PO modification of single-stranded M13mp2/C141 DNA was studied by transfection of modified DNA into SOS and non-SOS induced E. coli host cells. Mutations of the proline (CCC) codon at C141 which result in reversion of the lacZ phenotype (blue plaques) were scored. It was found that PO treatment of single-stranded DNA results in dose-dependent mutagenesis that is highly SOS dependent. The spectrum of base-substitution mutations found at this site differed when PO-modified DNA was transfected into E. coli with different DNA repair backgrounds. These results indicate that propylene oxide induced DNA adducts at template cytosine residues are mutagenic in E. coli and that this mutagenesis is greatly increased by SOS processing. They also show that these lesions may be repaired by one or more mechanisms.     

Uranyl acetate induces hprt mutations and uranium-DNA adducts in Chinese hamster ovary EM9 cells

Questions about possible adverse health effects from exposures to uranium have arisen as a result of uranium mining, residual mine tailings and use of depleted uranium in the military. The purpose of the current study was to measure the toxicity of depleted uranium as uranyl acetate (UA) in mammalian cells. The activity of UA in the parental CHO AA8 line was compared with that in the XRCC1-deficient CHO EM9 line. Cytotoxicity was measured by clonogenic survival. A dose of 200 microM UA over 24 h produced 3.1-fold greater cell death in the CHO EM9 than the CHO AA8 line, and a dose of 300 microM was 1.7-fold more cytotoxic. Mutagenicity at the hypoxanthine (guanine) phosphoribosyltransferase (hprt) locus was measured by selection with 6-thioguanine. A dose of 200 microM UA produced approximately 5-fold higher averaged induced mutant frequency in the CHO EM9 line relative to the CHO AA8 line. The generation of DNA strand breaks was measured by the alkaline comet assay at 40 min and 24 h exposures. DNA strand breaks were detected in both lines; however a dose response may have been masked by U-DNA adducts or crosslinks. Uranium-DNA adducts were measured by inductively coupled plasma optical emission spectroscopy (ICP-OES) at 24 and 48 h exposures. A maximum adduct level of 8 U atoms/10(3) DNA-P for the 300 microM dose was found in the EM9 line after 48 h. This is the first report of the formation of uranium-DNA adducts and mutations in mammalian cells after direct exposure to a depleted uranium compound. Data suggest that uranium could be chemically genotoxic and mutagenic through the formation of strand breaks and covalent U-DNA adducts. Thus the health risks for uranium exposure could go beyond those for radiation exposure.     

Interaction between cadmium and aromatic DNA adducts in hprt mutagenesis during foetal development

The foetus is exposed to multiple xenobiotics through the mother's circulation and this is possibly involved in the development of diseases in later life. Heavy metals and lipophilic genotoxins in umbilical cord blood of newborns may have synergistic effects on mutagenesis in the hypoxanthine-phosphoribosyltransferase (HPRT) reporter gene. Concentrations of zinc (Zn), lead (Pb) and cadmium (Cd) were determined in the peripheral and cord blood of 16 non-smoking and 9 smoking healthy mothers by atomic absorption spectrometry. Lipophilic DNA adducts in lymphocytes were determined in the same subjects by 32P-postlabelling and the HPRT-variant frequency was assessed by the evaluation of 6-thioguanine resistant cells. Although the Cd/Zn ratio was 2.5-fold higher in the blood of smoking women than in non-smoking women (1.0 +/- 0.2 and 0.4 +/- 0.1, respectively, P = 0.007), this difference could not be observed in umbilical cord blood (0.3 +/- 0.1 and 0.3 +/- 0.1, respectively, P = 0.66). Similarly, mean DNA adduct levels were increased in the lymphocytes of smoking women compared with non-smoking controls (0.99 +/- 0.31 adducts/10(8) nt and 0.43 +/- 0.12, respectively, P = 0.009), but were only marginally higher in the neonates of smokers than in their non-smoking counterparts (0.57 +/- 0.29 and 0.24 +/- 0.09, respectively, P = 0.38). Since Cd is known to effectively inhibit DNA repair, we hypothesized that concomitant exposure of neonates to Cd and genotoxic compounds may result in an increased fixation of DNA damage into somatic mutations. Indeed, the number of HPRT-variants per adduct (i.e. the mutagenic efficiency of adducts) correlated positively with the Cd concentrations in cord blood (r = 0.61, P = 0.001). These data suggest a molecular link between DNA damage, inhibition of DNA repair by Cd and in vivo mutagenesis during foetal development. Thus, exposure to heavy metals may enhance the mutagenic potential of DNA-damaging compounds and results in biologically relevant genotoxic effects in neonates.     

Metabolism of 2-acetylaminofluorene in the Chinese hamster ovary cell mutation assay

Chinese hamster ovary (CHO) cells were exposed to 2-acetylaminofluorene (2-AAF) and 2-aminofluorene (2-AF), and several of their N-oxidized metabolites in order to study the mechanisms by which arylamides and arylamines produce mutations in mammalian cells. The number of mutations induced at the hypoxanthine-guanine phosphoribosyl transferase locus by each compound (mutants/10(6) CHO cells/nmol compound/ml) was estimated to be: N-acetoxy-2-AAF, 310; N-hydroxy-2-AF, 3; N-hydroxy-2-AAF (with and without hepatic S9 activation), 0.7; 2-AAF (with S9), 0.1; and 2-AF (with S9), 0.09. With each compound, DNA adducts were also identified and quantified, and in all cases the major adduct was N-(deoxyguanosin-8-yl)-2-AF. 2-AAF and N-hydroxy-2-AAF also formed minor amounts of N-(deoxyguanosin-8-yl)-2-AAF and 3-(deoxyguanosin-N2-yl)-2-AAF. The relationship between mutation induction and adduct formation for each of the derivatives was similar to that previously reported for N-hydroxy-2-AF. Inclusion of the deacetylase inhibitor, paraoxon, reduced the mutagenicity of 2-AAF, N-hydroxy-2-AAF and N-acetoxy-2-AAF, and the DNA adducts produced by N-acetoxy-2-AAF to background levels. Acetyl coenzyme A increased the mutations and CHO cytosol-mediated DNA binding of N-hydroxy-2-AAF, but did not substantially increase these responses from N-hydroxy-2-AF. N-Hydroxy-2-AAF was not detectably metabolized by CHO cells. Taken together, these data indicate that CHO cells metabolized N-acetoxy-2-AAF to a reactive derivative by N-deacetylation to N-acetoxy-2-AF, while N-hydroxy-2-AF reacted directly with DNA. The major pathway of N-hydroxy-2-AAF activation appeared to be an initial O-acetylation to N-acetoxy-2-AAF and this occurred to only a limited extent in the CHO cells. N-Hydroxy-2-AAF also seemed to form an additional unknown ester intermediate that gave rise to acetylated DNA adducts. The initial step in the activation of 2-AAF and 2-AF was an N-oxidation to N-hydroxy-2-AAF and N-hydroxy-2-AF, respectively. The limited O-acetylase activity in CHO cells appeared to contribute to the low sensitivity of these cells toward mutation induction by arylamines and arylamides.     

Mutagenicity and induction of sister chromatid exchange by optically active enantiomers of secondary butyl methanesulfonate

This report describes experiments in which a chiral alkyl methanesulfonate was used to investigate possible mechanisms by which alkylating agents cause their mutagenic, cytotoxic, and clastogenic effects. Optically active enantiomers and the racemic mixture of 2-butyl methanesulfonate (2-BMS) were cytotoxic and mutagenic in Chinese hamster V79 cells and in AS52 cells and mutagenic in Salmonella typhimurium strains TA100 and TA1535 (without the addition of exogenous metabolizing systems). Within the experimental uncertainties, the cytotoxicity and mutagenicity curves were the same for the R and S enantiomers and for the racemic mixture. The 2-BMS isomers were cytotoxic and induced sister chromatid exchanges (SCE) in CHO-K1-BH4 cells. The cytotoxicity curve was similar to that observed with V79 and AS52 cells. The induction of SCE was linear between 1 and 6 mM 2-BMS with no differences discernable between the isomers. The results can be interpreted two ways. The first interpretation is that 2-BMS reacts via a carbocation, and the second interpretation involves an SN2 reaction of 2-BMS with DNA. The latter interpretation suggests that the mechanisms of mutagenesis, cytotoxicity, or the induction of SCE cannot distinguish between small (four-carbon) optically active DNA adducts. We favor the second interpretation because of solvolysis experiments showing the complete inversion of configuration of optically active 2-octyl methanesulfonate (2-OMS, Weiner and Sneen: J American Chemical Society 87:287-291, 1965). While we assume that optically active 2-BMS will react using the same mechanism as chiral 2-OMS, we cannot exclude the possibility that 2-BMS reacts via a carbocation intermediate.     

Molecular dosimetry of DNA adducts in Chinese hamster ovary cells and C3H10T1/2 mouse embryo fibroblast cells treated with benzo[a]pyrene

Chromatographic profiles of DNA adducts formed following treatment of Chinese hamster ovary (CHO) cells or C3H10T1/2 mouse embryo fibroblast cells with benzo[a]pyrene (BP), in the presence or absence of rat liver S9 fraction, have been obtained by both direct labelling ([3H]BP) and 32P-post-labelling methods. The principal adduct formed in both cell lines was (+)-N2-(7R,8S,9R-trihydroxy-7,8,9,10-tetrahydrobenzo[a]pyrene- 10S-yl) 2'-deoxyguanosine (detected as its 3',5'-bisphosphate by 32P-post-labelling). In both cell lines significantly higher levels of adducts were observed in the presence of S9 fraction. The results of these studies provide useful reference data on the genotoxic metabolism of BP in these widely used cell culture systems and allow comparisons with data obtained in other experimental mammalian systems. Valid comparisons of metabolism in experimental systems used as extrapolative models for man are particularly important where multiple bioactivation pathways are possible, such as in the case of polycyclic aromatic hydrocarbons.     

Mutagenic potency at the Na+/K+ ATPase locus correlates with cycle-dependent killing of 10T1/2 cells

Perturbation of DNA replication by chemical-DNA adducts produced by exposure to mutagenic/carcinogenic chemicals results in mutagenic or cytotoxic damage in the DNA. Demonstration of a correlation between cell cycle dependency of cytotoxicity and point mutation at the Na+/K+ ATPase gene could suggest that the two consequences of chemical exposure are caused by the same damage in the template DNA and that both are mediated through DNA replication-associated mechanisms. N-methyl-N'-nitro-N-nitrosoguanidine, N-ethyl-N'-nitro-N-nitrosoguanidine, 4-nitroquinoline-1-oxide, and benzo(a)pyrene-trans-7,8-dihydrodiol-9,10-epoxide demonstrated cell cycle-related patterns of cytotoxicity in 10T1/2 cells, with maximal cell killing produced by exposure in early S phase, and were highly efficient mutagens of the Na+/K+ ATPase gene relative to their cytotoxic potential. In contrast, methyl methanesulfonate and N-acetoxy-N-2-fluorenylacetamide were maximally cytotoxic in cell populations exposed in early G1 phase and were weak mutagens of the Na+/K+ ATPase gene at comparable levels of cytotoxicity. These data suggest that mutagenic/carcinogenic chemicals that are effective at producing mutations by misreplication kill cells by a related mechanism that may be associated with the perturbation of DNA replication.     

Effects of O (6)-alkylguanine-DNA alkyltransferase deficiency in Escherichia coli as the host for the detection of mutations in lacI transgenic mice.

Transgenic mice are widely used to detect gene mutations in vivo induced by a variety of chemicals. It is known, however, that no mutagenicity of methyl methanesulfonate (MMS) is detected in epididymal sperm in various transgenic mice assays, although MMS induces the dominant lethal and specific locus mutations in male mice. To investigate the issue of whether unrepaired lesions in DNA of mature sperm can be transformed into mutations during replication of the lambda phage in Escherichia coli cells, we developed an E. coli strain YG5152, which is a derivative of strain SCS-8 but is deficient in the genes encoding O (6)-alkylguanine-DNA alkyltransferases. When lambda LIZalpha phages were treated with MMS or N-ethyl-N-nitrosourea (ENU) in vitro and infected to the E. coli strains, the mutant frequencies of lacI were markedly higher in strain YG5152 than in strain SCS-8. When Big Blue(trade mark) mice were treated with MMS (160 mg/kg) or ENU (125 or 250 mg/kg) and the phages rescued from mature sperm were infected to the strains, the mutation frequency (MF) of phages from ENU-treated mice at a dose of 250 mg/kg in strain YG5152 was about two times higher than that in strain SCS-8. However, no increase in the MF was observed in the MMS-treated mice even in strain YG5152. These results suggest that, although strain YG5152 efficiently detects ex vivo mutations caused by mutagenic alkyl adducts formed by MMS in lambda phage DNA, no detectable levels of mutagenic methyl adducts are present in mature sperm of MMS-treated mice. Possible reasons for this lack of mutagenicity of MMS in mature sperm using transgenic mice assays are discussed.     

Metabolic activation of organic extracts from diesel, coke oven, roofing tar, and cigarette smoke emissions in the Ames assay

Four environmental emissions samples were ranked by their genotoxic potency in several bioassays. Although the relative potency of a series of automotive emissions (diesel and gasoline) in the Ames assay correlated well with the relative potency in mammalian cell and mouse skin, this was not the case for the coke oven, roofing tar, and cigarette smoke condensate (CSC) emissions. This study examines the role of metabolic activation in determining the difference between a microbial and a mammalian bioassay in ranking the genotoxic potency of these environmental emissions. Uninduced and Aroclor 1254-induced S9 from both rat and hamster liver were compared as the metabolic activator in the Ames assay with Salmonella typhimurium TA98. The diesel emissions sample was direct-acting while the other samples required activation. The standard S9 concentration (only Aroclor-induced rat, approximately 1.25 mg protein/plate) also produced the maximum mutagenic activity. Induced S9s produced higher mutagenic activity than uninduced. The hamster S9 gave significantly higher mutagenic activities than rat S9 for the coke oven and CSC. The relative potency of these four samples was not significantly different between the microbial (Ames), mammalian cell (mouse lymphoma), and tumor initiation (mouse skin) assays. These results suggest that the differences observed between the relative mutagenic activity of these emissions in the mammalian cell and microbial assays was not due to a lack of optimization of the S9 system but may be inherent in the different response of the indicator cells to different chemical classes.     

Synthesis of chiral 3-methyl- and 3-methyl-N-propargyl-1,2,3,4-tetrahydroisoquinoline and prevention of MPP+ -induced cytotoxicity

The chemical structure of selegiline, a commercially available drug for Parkinson's disease (PD), resembles that of 1,2,3,4-tetrahydroisoquinoline (TIQ), an endogenous parkinsonism-inducing compound. In the present study, we evaluated the direct cytotoxicity of (R)- and (S)-3-methyl-TIQ (3-MeTIQ) and (R)- and (S)-3-methyl-N-propargyl-TIQ (3-Me-N-propargyl-TIQ), as selegiline-mimetic TIQ derivatives, and their ability to prevent 1-methyl-4-phenylpyridinium iodide (MPP(+))-induced cell death. Synthesis of optically-pure 3-MeTIQs was achieved via the super acid-induced cyclization of chiral N-benzyl-N-[1-methyl-2-(phenylsulfinyl)ethyl]formamide using a Pummerer-type cyclization reaction as the key step in producing excellent yields. Subsequent N-propargylation of chiral 3-MeTIQs using propynylbromide gave the corresponding 3-Me-N-propargyl-TIQs. In our in vitro experiments, the direct cytotoxicity of chiral 3-MeTIQs and 3-Me-N-propargyl-TIQs was almost identical, with no relationship to optical chirality except for (S)-3-Me-N-propargyl-TIQ, which had significantly weaker direct cytotoxicity than the other 3-MeTIQ derivatives. However, the decreased viability of PC12 cells induced by treatment with MPP(+) was accelerated by the coexistence of 3-MeTIQs and inhibited by 3-Me-N-propargyl-TIQs without any participation of the stereochemistry at the 3-position. These results suggest that the N-propargyl group is necessary for protection of cells against the toxicity of MPP(+). Furthermore, the stereochemistry of the 3-position appears to partially participate in the direct cytotoxicity of 3-Me-N-propargyl-TIQs.     

Evaluation of the genotoxicity of gentian violet in bacterial and mammalian cell systems

Previous studies indicate that gentian violet (GV), a triphenylmethane dye used in agriculture and human medicine, is a clastogen in vitro and a carcinogen in chronically exposed mice and rats. Data on its genotoxic activity, however, have been incomplete and partly contradictory. Mutagenesis and DNA damage experiments were conducted to re-evaluate the genotoxic potential of GV in both bacterial and mammalian cell systems. GV was mutagenic in Salmonella typhimurium tester strains TA97 and TA104, but there was little mutagenic activity detected in strains TA98 and TA100. A rat liver homogenate fraction (S9) tended to increase mutagenicity. The major microsomal metabolites of GV, pentamethylpararosaniline and N,N,N',N'-tetramethylpararosaniline were less mutagenic in TA97 and TA104, while N,N,N',N"-tetramethylpararosaniline was a weak mutagen in Salmonella. GV was not mutagenic in Chinese hamster ovary (CHO) cell strain CHO-K1-BH4, and was a questionable mutagen in CHO-AS52 cells. While GV produced DNA damage as measured by sedimentation of nucleotids derived from B6C3F1 mouse lymphocytes treated in vitro, no damage was found in lymphocytes isolated from mice dosed with GV. GV was also a weak producer of gene amplification in an SV40-transformed Chinese hamster cell line. The results indicate that GV is a point mutagen in bacteria; however, since similar exposure conditions produced weak mutagenic activity in mammalian cells, GV may be carcinogenic by virtue of its clastogenic activity.     

In vitro genotoxicity of dyes present in colored smoke munitions

Genetic toxicology studies were conducted on organic dyes and mixtures used in colored smoke munitions. The dyes studied included Solvent Red 1; two different batches (Lot 1 and Lot 2) of Disperse Red 11; terephthalic acid; and a mixture of 25 parts Solvent Red 1, 5 parts Disperse Red 11, and 16 parts terephthalic acid. The dyes were evaluated for their ability to produce mutations in Salmonella bacterial strains and in Chinese hamster ovary (CHO) cells. The dyes were also tested in CHO cells to determine cytotoxicity and the induction of sister chromatid exchanges and chromosome aberration. None of the dyes were genotoxic in the standard Ames assay using bacterial strain TA1535 or TA100 with or without the addition of S-9 or in TA98 and TA1538 without S-9. With S-9, Disperse Red 11 (Lot 2) showed significant mutagenic activity in TA98 and TA1538 which increased as a function of S-9 concentration. However, the maximum level of mutagenic activity detected was low (3.8 revertants/micrograms). The azo dye Solvent Red 1 was also negative in a pre-incubation assay designed to reduce azo compounds to free amines. Solvent Red 1 was cytotoxic to mammalian cells, caused a significant increase in SCE, but was not mutagenic or clastogenic. Disperse Red 11 (Lot 1 and Lot 2) were not cytotoxic or clastogenic but produced an increase in cell cycle time and SCE frequency. Only Disperse Red 11 (Lot 2) increased mutations in the CHO/hypoxanthine-guanine phosphoribosyltransferase (HGPRT) assay. The mutagenic activity of the dye mixture was not significant, suggesting no synergistic interaction between the dyes. These studies demonstrated that none of the dyes was clastogenic and that a contaminant in Disperse Red 11 (Lot 2) may be responsible for the weak mutagenic activity in both mammalian and bacterial cell systems.