Diethylstilbestrol and 11 derivatives: a mutagenicity study with Salmonella typhimurium.

Diethylstilbestrol was tested for mutagenicity with his- S. typhimurium strains under 10 different matabolic situations (no exogenous metabolizing system; S9 mix from liver homogenate of rats induced with Aroclor 1254, with or without inhibition of epoxide hydratase; liver and/or kidney S9 mix from control or hamsters treated with Aroclor 1254; horse-radish peroxidase + H2O2). Under none of these conditions did diethylstilbestrol give any indication of a mutagenic effect. Furthermore, 11 metabolites and other derivatives of diethylstilbestrol, 2 of them potent inducers of sister-chromatid exchange in cultured fibroblasts, were not mutagenic with any of the 4 tester strains (S. typhimurium TA100, TA98, TA1537, TA1535) in the presence or absence of S9 mix from liver homogenate of rats induced with Aroclor 1254. Thus, one of the few known human carcinogens is very resistant to detection by the mammalian enzyme-mediated Salmonella typhimurium mutagenicity test (Ames test). This is especially remarkable since the metabolizing systems used included: (1) some of very high metabolic activity (S9 mix from liver homogenate of rats and hamsters induced with Aroclor 1254); (2) metabolizing systems from organs susceptible to the carcinogenic activity of diethylstilbestrol (hamster kidney); as well as (3) a mixture of (1) and (2) in case both activities are required for the carcinogenic effect in the whole animal.     

Genotoxicity of six pesticides by Salmonella mutagenicity test and SOS chromotest

Two in vitro tests (Ames test and SOS chromotest), one for bacterial mutagenicity and one for primary DNA damage, were assayed to determine the genotoxic activity of 6 pesticides (atrazine, captafol, captan, chlorpyrifosmethyl, molinate and tetrachlorvinphos). Assays were carried out both in the absence and presence of S9 fractions of liver homogenate from rat (Sprague–Dawley) pretreated with Aroclor 1254. Captan and captafol were genotoxic on both the Ames test and the SOS chromotest. Comparisons with mutagenesis data in Salmonella indicated that the SOS assay detected as genotoxic the pesticides that were mutagenic on the Salmonella test. Non-genotoxic effects were not detected in vitro either in the Salmonella/microsome assay nor in the SOS chromotest when bacterial tester strains were exposed to atrazine, molinate, chlorpyrifosmethyl and tetrachlorvinphos in the absence or presence of S9 mix.     

Diesel emissions revisited: is the carcinogenicity due to a genotoxic mechanism?

The induction of recA, umuC and sfiA genes by quercetin was studied in the presence and in the absence of S9 mix. The inducing activity of quercetin is higher for sfiA than for recA and umuC genes in the absence of S9 mix. The putative genotoxic metabolites of quercetin produced by S9 mix display different inducing activities of the three SOS genes as compared to quercetin. The induction of sfiA gene is decreased by the presence of S9 mix, whereas an opposite effect was observed concerning umuC and recA. These data suggest that the error-prone repair pathway participates in mutagenesis by quercetin and its metabolites. Moreover, the type of DNA damage exerted by quercetin seems to be determined by its metabolic fate. The importance of testing for the induction of other SOS genes, together with sfiA, in the study of SOS functions as a genotoxic index is emphasized.     

The genotoxicity of lucidin,a natural component of Rubia tinctorum L., and lucidinethylether,a component of ethanolic Rubia extracts

The genotoxic activity of lucidin (1,3-dihydroxy-2-hydroxymethyl-9,10-anthraquinone), a natural component of Rubia tinctorum L., was tested in a battery of short-term tests. The compound was mutagenic in five Salmonella typhimurium strains without metabolic activation, but the mutagenicity was increased after addition of rat liver S9 mix. In V79 cells, lucidin was mutagenic at the hypoxanthine-guanine phosphoribosyl transferase gene locus and active at inducing DNA single-strand breaks and DNA protein cross-links as assayed by the alkaline elution method. Lucidin also induced DNA repair synthesis in primary rat hepatocytes and transformed C3HI M2-mouse fibroblasts in culture. We also investigated lucidinethylether, which is formed from lucidin by extraction of madder roots with boiling ethanol. This compound was also mutagenic in Salmonella, but only after addition of rat liver S9 mix. Lucidinethylether was weakly mutagenic to V79 cells which were cocultivated with rat hepatocytes. The compound did not induce DNA repair synthesis in hepatocytes from untreated rats, but positive results were obtained when hepatocytes from rats pretreated with phenobarbital were used. We conclude that lucidin and its derivatives are genotoxic.Abbreviations DMBA 7,12-dimethylbenz(a)anthracene - HA hydroxyanthraquinones - LUE lucidinethylether - PRH primary rat hepatocytes - UDS unscheduled DNA synthesis     

Genotoxicity evaluation of sesamin and episesamin

Sesamin is a major lignan that is present in sesame seeds and oil. Sesamin is partially converted to its stereoisomer, episesamin, during the refining process of non-roasted sesame seed oil. We evaluated the genotoxicity of these substances through the following tests: a bacterial reverse mutation assay (Ames test), a chromosomal aberration test in cultured Chinese hamster lung cells (CHL/IU), a bone marrow micronucleus (MN) test in Crlj:CD1 (ICR) mice, and a comet assay using the liver of Sprague-Dawley (SD) rats. Episesamin showed negative results in the Ames test with and without S9 mix, in the in vitro chromosomal aberration test with and without S9 mix, and in the in vivo comet assay. Sesamin showed negative results in the Ames test with and without S9 mix. In the in vitro chromosomal aberration test, sesamin did not induce chromosomal aberrations in the absence of S9 mix, but induced structural abnormalities at cytotoxic concentrations in the presence of S9 mix. Oral administration of sesamin at doses up to 2.0g/kg did not cause a significant increase in either the percentage of micronucleated polychromatic erythrocytes in the in vivo bone marrow MN test or in the % DNA in the comet tails in the in vivo comet assay of liver cells. These findings indicate that sesamin does not damage DNA in vivo and that sesamin and episesamin have no genotoxic activity.     

Cytogenetic studies on 1,1-dichloroethylene and its two isomers in mammalian cells in vitro and in vivo

Chromosomal aberration and sister-chromatid exchange (SCE) tests in vitro on 1,1-dichloroethylene (1,1-DCE), its two isomers, cis- and trans-1,2-DCE, and two possible metabolites of 1,1-DCE, chloroacetyl chloride and chloroacetic acid, were carried out using a Chinese hamster cell line, CHL. 1,1-DCE induced chromosomal aberrations in the presence of S9 mix prepared from the rat liver, but not in the absence of S9 mix. SCEs were also slightly induced by 1,1-DCE only in the presence of S9 mix. On the other hand, two isomers and two metabolites of 1,1-DCE induced neither chromosomal aberrations nor SCEs with and without S9 mix. 1,1-DCE, however, was negative even at a sublethal dose in the micronucleus test using mouse bone marrow, fetal liver and blood.     

Terbutryn resistance in Vaucheria dichotoma

Infestations of Vaucheria dichotoma have been reported to become resistant to the herbicide terbutryn after successful control by annual or biennial applications for 11 years. V. dichotoma was isolated from a site where terbutryn treatment gave good control and from a site where terbutryn treatment had failed. The isolate from the latter was resistant to terbutryn in laboratory toxicity tests. The resistant strain was not killed until the dose of terbutryn was increased to more than double the concentration approved for use in British waters. The shape of the resistance curve indicated that the resistance mechanism was not by modification of the protein binding site, suggesting that differential uptake, translocation and/or degradation is involved.     

Genotoxicity of apomorphine and various catecholamines in the Salmonella mutagenicity test (Ames test) and in tests for primary DNA damage using DNA repair-deficient B. subtilis strains (rec assay)

Apomorphine, N-nor-N-propyl-apomorphine, dopamine, L-DOPA, 6-hydroxydopamine and adrenaline were evaluated for genotoxicity using the Ames test and DNA repair-deficient and DNA repair-proficient Bacillus subtilis strains (rec assay, H17/M45; HLL3g/HJ-15). In the absence of an S9 liver homogenate, apomorphine induced frame-shift mutations in Salmonella typhimurium, mainly in strain TA1537; no indication of DNA-damaging effects in B. subtilis was observed. N-Nor-N-propyl-apomorphine was tested using strain TA1537 only and found to be mutagenic. Dopamine, L-DOPA, 6-hydroxydopamine and adrenaline were non-mutagenic when tested without S9, whereas they were all more toxic for DNA repair-deficient than for DNA repair-proficient B. subtilis strains, indicating a DNA-damaging potential. In a second set of experiments the mode of action of apomorphine and the relevance of the positive Ames test data were investigated. Glutathione in physiological concentrations reduced the mutagenic effect of apomorphine in a dose-dependent way, both in the presence and the absence of S9. S9 also reduced the mutagenicity of apomorphine. By comparing the effects of a complete S9 mix with those of a preparation without glucose-6-phosphate and NADP, it became clear that S9 also had an activating effect, overshadowed under standard conditions by its deactivating activity. Apomorphine was not mutagenic under anaerobic conditions. Superoxide dismutase and catalase reduced the mutagenic effect of apomorphine. All test conditions which reduced the mutagenic effect also inhibited the dark discoloration of the tester plates, indicating a retardation of apomorphine oxidation. It can, therefore, be concluded that oxidation of apomorphine leads to mutagenic products which induce frame-shift mutations in Salmonella typhimurium. This oxidation was prevented both by glutathione in concentrations well below physiological levels and/or by catalase and superoxide dismutase. Under these conditions, apomorphine was non-mutagenic in therapeutic concentrations as well as at higher dose levels. The possibility of genotoxic side effects occurring in patients treated with apomorphine as an emetic drug is therefore considered to be very unlikely.     

Influence of the microsomal inducer and the incubation system on mutagenicity of complex mixtures

The mutagenicity of SRM 1649 and 1650 was tested in the presence of rat liver S9 mix which was induced by polychlorinated biphenyl (PCB) or by the combination of phenobarbital and 5,6-benzoflavone. The S9 mix induced by PCB activated benzo[a]pyrene strongly. The S9 mix induced by phenobarbital-5,6-benzoflavone activated the complex mixtures to approximately the same extent as that induced by PCB. This finding indicates that phenobarbital-5,6-benzoflavone instead of PCB may be suitable as an inducer under some conditions.The preincubation procedure for the mutagenicity test was performed by preincubating the test compound, S9 mix and bacteria for 20 min in a water bath. This procedure was as effective as the plate incorporation test.     

Structures of mutagens produced by the co-mutagen norharman with o- and m-toluidine isomers

Norharman, abundantly present in cigarette smoke and cooked foods, is not mutagenic to Salmonella typhimurium strains. However, norharman shows mutagenicity to S. typhimurium TA98 and YG1024 in the presence of S9 mix when coexisting with aromatic amines, including aniline, o- and m-toluidines. We previously reported that the mutagenicity from norharman and aniline in the presence of S9 mix was due to the formation of a mutagenic compound, 9-(4'-aminophenyl)-9H-pyrido[3,4-b]indole (aminophenylnorharman). In the present study, we analyzed the mutagens produced by norharman with o- or m-toluidine in the presence of S9 mix. When norharman and o-toluidine were reacted at 37 degrees C for 20 min, two mutagenic compounds, which were mutagenic with and without S9 mix, respectively, were produced, and these were isolated by HPLC. The former mutagen was deduced to be 9-(4'-amino-3'-methylphenyl)-9H-pyrido[3,4-b]indole (amino-3'-methylphenylnorharman) on the basis of various spectral data, and this new heterocyclic amine was confirmed by its chemical synthesis. The latter mutagen was identified to be the hydroxyamino derivative. Amino-3'-methylphenylnorharman induced 41,000 revertants of TA98, and 698,000 revertants of YG1024 per microg with S9 mix. Formation of the same DNA adducts was observed in YG1024 when amino-3'-methylphenylnorharman or a mixture of norharman plus o-toluidine was incubated with S9 mix. These observations suggest that norharman reacts with o-toluidine in the presence of S9 mix to produce amino-3'-methylphenylnorharman, and this compound is metabolically activated to yield its hydroxyamino derivative. After activation by O-acetyltransferase, it might bind to DNA and exert mutagenicity in S. typhimurium TA98 and YG1024. When norharman and m-toluidine were reacted in the presence of S9 mix, 9-(4'-amino-2'-methylphenyl)-9H-pyrido[3,4-b]indole (amino-2'-methylphenylnorharman) was identified as a mutagen. Thus, the mutagenicity of norharman with m-toluidine may follow a mechanism similar to that with o-toluidine.     

A comparison of alternative distributions of postimplantation death in the dominant lethal assay

The action of beta-aminoethylisothiouronium bromide hydrobromide (AET) and sodium fluoride (NaF) on the clastogenic activity of Trenimon, cyclophosphamide, and bleomycin was tested on cultures of human peripheral lymphocytes with and without the addition of rat liver S9 mix. In addition, the influence of both anticlastogens on the SCE-inducing activity of Trenimon and cyclophosphamide was examined under the same conditions. In the absence of S9 mix both substances displayed the known anticlastogenic action when TR was the standard clastogen but acted coclastogenically in the experiments with BM. Under the influence of rat-liver S9 mix this action on TR-induced chromosome damage was decreased and only a slight anticlastogenic effect was observed in the experiments with activated cyclophosphamide. S9-activated BM lost some of its strong chromosome-damaging effect and AET proved clearly anticlastogenic under these test conditions. AET displayed a slight decreasing effect on SCE induced by TR, but had no effect on CP-induced SCE. No anti-SCE effect at all was found in the experiments with NaF. Detailed analyses revealed different actions of both anticlastogens on the different types of structural chromosome damage.     

Genotoxic potential of medroxyprogesterone acetate in cultured human peripheral blood lymphocytes

Medroxyprogesterone acetate was studied at three different concentrations (1, 5 and 10 microM), for its genotoxic effects in human peripheral blood lymphocyte culture using chromosomal aberrations and sister chromatid exchanges as parameters. Duplicate peripheral blood cultures were treated with three different concentrations (1, 5 and 10 microM) of medroxyprogesterone acetate. The study was carried out both in the absence as well as in the presence of metabolic activation (S9 mix) with and without NADP. Medroxyprogesterone acetate was found genotoxic at 5 and 10 microM in the presence of S9 mix with NADP. To study the possible mechanism of the genotoxicity of medroxyprogesterone acetate, superoxide dismutase and catalase at different doses were used separately and in combination with 10 microM of medroxyprogesterone at different doses in the presence of S9 mix with NADP. Superoxide dismutase treatment results in an increase of the genotoxic damage but catalase treatment reduce the genotoxic damage of medroxyprogesterone acetate. Catalase treatment in combination with superoxide dismutase also results in the further reduction of the genotoxic damage. The results of the present study reveal that medroxyprogesterone acetate is genotoxic only in the presence of metabolic activation (S9 mix) with NADP. Treatments with superoxide dismutase and catalase suggests the possible generation of reactive oxygen species by redox cycling of various forms of quinones, similar to estrogens, that are the results of aromatic hydroxylation by cytochrome P450s.     

Standardization of conditions for the metabolic activation of N-nitrosodiethylamine in mutagenicity tests

Like all nitrosamines, N-nitrosodiethylamine (NDEA) requires metabolic activation in order to exert its carcinogenic effects. This activation involves cytochrome P450s (CYP), which generates unstable metabolites that react with the DNA of cells in the immediate vicinity of metabolite formation. Although NDEA is carcinogenic, it has been considered a weak mutagen in classic genotoxicity assays. We used optimized Salmonella/mammalian microsome genotoxicity assays to assess the mutagenicity and toxicity of low concentrations of NDEA. Using a fixed concentration of NDEA (36.5 mg/ml), we varied the length of preincubation in the presence of different concentrations of an S9 metabolic activation mixture. Salmonella typhimurium strains TA97 and TA102 were resistant to NDEA-induced mutagenesis, even after a preincubation of up to 120 min and the use of different concentrations of the S9 mix. Strain TA98 was susceptible to mutagenesis by NDEA in the absence of the S9 mix and after preincubation with NDEA for 90 min. When bacteria of this strain were preincubated with NDEA for 60 min, mutagenesis was detected at an S9 mix concentration >9.55 mg/ml. NDEA also induced mutagenesis in strain TA100 after preincubation for 90 or 120 min, and this effect was dependent on the S9 concentration. E. coli strain BH990 also showed a concentration-dependent response, with only 60% of the cells surviving after a 120-min preincubation with NDEA in the presence of 19.1 mg S9 mix/ml.     

Influence of the microsomal inducer and the incubation system on mutagenicity of complex mixtures.

The mutagenicity of SRM 1649 and 1650 was tested in the presence of rat liver S9 mix which was induced by polychlorinated biphenyl (PCB) or by the combination of phenobarbital and 5,6-benzoflavone. The S9 mix induced by PCB activated benzo[a]pyrene strongly. The S9 mix induced by phenobarbital-5,6-benzoflavone activated the complex mixtures to approximately the same extent as that induced by PCB. This finding indicates that phenobarbital-5,6-benzoflavone instead of PCB may be suitable as an inducer under some conditions. The preincubation procedure for the mutagenicity test was performed by preincubating the test compound, S9 mix and bacteria for 20 min in a water bath. This procedure was as effective as the plate incorporation test.     

Studies on the mutagenicity of p-phenylenediamine in Salmonella typhimurium. Presence of PCB's in rat-liver microsomal fraction induced by Aroclor.

The mutagenicity of fresh solutions of p-phenylenediamine (PPD) and Aroclor 1254 was investigated. The histidine-requiring strains of Salmonella typhimurium were used in the absence and presence of uninduced and/or Aroclor-induced rat-liver homogenate. The presence of polychlorinated biphenyls (PCBs) was also examined by chromatographic methods in Aroclor-induced rat-liver homogenate. In the absence of metabolic activation, as well as in the presence of uninduced rat-liver homogenate, PPD was not mutagenic in the strains used. In the presence of Aroclor-induced S9 a twofold increase (or less) was observed in the number of revertant colonies over those of the controls in TA1538 and TA98. There was no increase in the number of revertant colonies over those of the controls when PPD was dissolved in NH4OH solution and the solution mixed with H2O2 before the addition of S9 mix. Aroclor 1254 was not mutagenic in TA1538 or TA98. However, the presence of PCBs in Aroclor-induced rat-liver homogenate (induced S9) was identified by gas-liquid chromatography (GLC), high-performance liquid chromatography (HPLC) and gas--liquid chromatography/mass spectrometry (GC/MS).     

Effect of 10-aza-substitution on benzo[a]pyrene mutagenicity in vivo and in vitro

Benzo[a]pyrene (BaP), an environmental carcinogen, shows genotoxicity after metabolic transformation into the bay-region diol epoxide, BaP-7,8-diol 9,10-epoxide. 10-Azabenzo[a]pyrene (10-azaBaP), in which a ring nitrogen is located in the bay-region, is also a carcinogen and shows mutagenicity in the Ames test in the presence of the rat liver microsomal enzymes. In order to evaluate the effect of aza-substitution on in vivo genotoxicity, BaP and 10-azaBaP were assayed for their in vivo mutagenicity using the lacZ-transgenic mouse (Muta™Mouse). BaP was potently mutagenic in all of the organs examined (liver, lung, kidney, spleen, forestomach, stomach, colon, and bone marrow), as described in our previous report, whereas, 10-azaBaP was slightly mutagenic only in the liver and colon. The in vitro mutagenicities of BaP and 10-azaBaP were evaluated by the Ames test using liver homogenates prepared from several sources, i.e. CYP1A-inducer-treated rats, CYP1A-inducer-treated and non-treated mice, and humans. BaP showed greater mutagenicities than 10-azaBaP in the presence of a liver homogenate prepared from CYP1A-inducer-treated rodents. However, 10-azaBaP showed mutagenicities similar to or more potent than BaP in the presence of a liver homogenate or S9 from non-treated mice and humans. These results indicate that 10-aza-substitution markedly modifies the nature of mutagenicity of benzo[a]pyrene in both in vivo and in vitro mutagenesis assays.     

Formation of adducts by bisphenol A, an endocrine disruptor, in DNA in vitro and in liver and mammary tissue of mice

Endocrine disruptors (EDs) represent a major toxicological and public health issue, and the xenoestrogen bisphenol A (BPA) has received much attention due to its high production volume and widespread human exposure. Also, due to its similarity to diethylstilbestrol, a known human carcinogen, BPA has been investigated for its genotoxic and carcinogenic properties, but the results have been either inconclusive or controversial. Metabolically activated BPA has previously been shown to form DNA adducts both in vitro and in rat liver. The present study was designed (a) to assess the sensitivity threshold of DNA-adduct detection by ³²P-postlabelling in an acellular system and (b) to evaluate the formation of DNA adducts in both liver and mammary cells of female CD-1 mice receiving BPA in their drinking water (200 mg/kg body weight) for eight consecutive days. The reaction of BPA with calf thymus DNA, in the presence of S9 mix, resulted in a dose-dependent formation of multiple DNA adducts, with a detection limit of 10 ng of this ED under our experimental conditions. Administration of BPA to mice confirmed that DNA adducts are formed in liver (3.4-fold higher levels than in controls). In addition, new evidence is provided that DNA adducts are formed in target mammary cells (4.7-fold higher than in controls). Although DNA adducts do not necessarily evolve into tumours or other chronic degenerative diseases, the formation of these molecular lesions in target mammary cells may bear relevance for the potential involvement of BPA in breast carcinogenesis.     

Genetic effects of isoniazid and the relationship to in vivo and in vitro biotransformation

The mutagenic activity of isoniazid, N-acetyl-isoniazid and hydrazine dihydrochloride was investigated in S. typhimurium. Isoniazid was found to possess a weak mutagenic activity only in repair-deficient strains TA1535 and TA100 as well as in the plasmid-containing strain TA92 (10-30 mg/plate) in the Ames test without metabolic activation. Addition of microsomal enzymes by S9 mix decreased this direct mutagenic activity. In contrast, preincubation of isoniazid with crude liver homogenate from mice, rats or Syrian golden hamsters for 4 h prior to plating with bacteria liberated a mutagenic compound which is equally active in both repair-deficient and repair wild-type strains (0.5-5 mg/plate). This activation pathway is independent of NADPH, is heat-sensitive and is operative only in a total liver homogenate in suspension. The highest capacity for mutagenic activation was achieved with liver homogenate from hamsters, followed by that from mice and rats. Furthermore, this mutagenic activation is paralleled by formation of hydrazine, as demonstrated in colorimetric measurements with p-dimethylaminobenzaldehyde. N-Acetyl-isoniazid is without mutagenic activity under similar conditions, and liberation of hydrazine was never detected. This means that, besides having a weak direct genetic activity, isoniazid is a promutagen, and formation of hydrazine is the first step in metabolic activation. It is concluded that the genotoxic properties of isoniazid in mammals are primarily determined by the pharmacokinetic behavior of the ultimate reactive metabolite. This result must be taken into consideration in risk assessment performed for mutagenic and carcinogenic properties of isoniazid in man.     

Mutagenicity of thiol compounds in Escherichia coli WP2 tester strain IC203, deficient in OxyR: effects of S9 fractions from rat liver and kidney

Low doses of -cysteine (CYS), cysteinyl-glycine (CYSGLY) and reduced glutathione (GSH) activated by γ-glutamyl transpeptidase (GGT) were mutagenic in strain IC203 (oxyR), whereas higher doses were required to observe a weak mutagenicity in the oxyR⁺ strain WP2 uvrA/pKM101 (denoted IC188). This indicates that thiol mutagenesis is suppressed by OxyR-regulated antioxidant defenses and confirms its oxidative character. The mutagenesis by low doses of CYS, CYSGLY and GSH+GGT detected in IC203 was abolished by rat liver S9, through the activity of catalase, as well as by the metal chelator diethyldithiocarbamate (DETC), supporting the dependence of this mutagenesis on H₂O₂ production, probably in thiol autoxidation reactions in which transition metals are involved. Surprisingly, low DETC concentrations greatly potentiate the mutagenicity of low CYS doses. Mutagenesis by high doses of CYS and CYSGLY occurred in both IC203 and IC188 in the presence of liver S9, and was resistant to inhibition by catalase, although it was prevented by DETC. Mutagenesis by GSH activated by rat kidney S9, rich in GGT, was detected in IC203 and IC188 only at high doses since catalase and glutathione peroxidase, both present in kidney S9, might inhibit its induction by low GSH doses. In the presence of liver S9, almost deficient in GGT, GSH was not mutagenic. The mutagenicity of a high GSH dose occurring in the presence either of GGT plus liver S9 or of kidney S9 was weakly prevented by DETC.     

Genotoxic potential of ethinylestradiol in cultured mammalian cells

Ethinylestradiol, a steroidal estrogen, is widely used with various progestogens in oral contraceptives formulations. There are sufficient evidences for the carcinogenicity of ethinylestradiol in experimental animals. The reports on the genotoxic potential of ethinylestradiol are contradictory. Here in the present study we have tested the genotoxicity of ethinylestradiol in human lymphocytes using chromosomal aberrations (CAs), mitotic index (MI) and sister chromatid exchanges (SCEs) as a parameter. The study was carried out in the absence, as well as in the presence, of rat liver microsomal fraction, with and without NADP. Ethinylestradiol was studied at three different concentrations (1, 5 and 10 microM) and was found non-genotoxic in the absence of metabolic activation (S9 mix) and in S9 mix without NADP. Ethinylestradiol was found to be genotoxic at 5 and 10 microM in the presence of S9 mix with NADP. To study the possible mechanism of the genotoxicity of ethinylestradiol, superoxide dismutase (SOD) and catalase (CAT) were used separately and in combination along with 10 microM of ethinylestradiol at different doses. SOD treatment increased CAs and SCEs and decreases MI as compared with treatment with 10 microM of ethinylestradiol alone in the presence of S9 mix with NADP at both of the tested doses. CAT treatment decreased the frequencies of CAs and SCEs and increased MI, as compared with treatment with 10 microM of ethinylestradiol alone in the presence of S9 mix with NADP. CAT treatment in combination with SOD also decreased the frequencies of CAs and SCEs and increased MI suggesting a possible role of reactive oxygen species for the genotoxic damage.