Assessment of genotoxic potential of fragrance materials in the chicken egg assays.

The genotoxic and clastogenic/aneugeneic potentials of four α,ß-unsaturated aldehydes, 2-phenyl-2-butenal, nona-2-trans-6-cis-dienal, 2-methyl-2-pentenal, and p-methoxy cinnamaldehyde, which are used as fragrance materials, were assessed using the Chicken Egg Genotoxicity Assay (CEGA) and the Hen's egg micronucleus (HET-MN) assay, respectively. Selection of materials was based on their chemical structures and the results of their previous assessment in the regulatory in vitro and/or in vivo genotoxicity test battery. Three tested materials, 2-phenyl-2-butenal, nona-2-trans-6-cis-dienal, and 2-methyl-2-pentenal, were negative in both, CEGA and HET-MN assays. These findings were congruent with the results of regulatory in vivo genotoxicity assays. In contrast, p-methoxy cinnamaldehyde, which was also negative in the in vivo genotoxicity assays, produced evidence of DNA damage, including DNA strand breaks and DNA adducts in CEGA. However, no increase in the micronucleus formation in blood was reported in the HET-MN study. Such variation in responses between the CEGA and HET-MN assay can be attributed to differences in the dosing protocols. Pretreatment with a glutathione precursor, N-acetyl cysteine, negated positive outcomes produced by p-methoxy cinnamaldehyde in CEGA, indicating that difference in response observed in the chicken egg and rodent models can be attributed to rapid glutathione depletion. Overall, our findings support the conclusion that CEGA and/or HET-MN can be considered as a potential alternative to animal testing as follow-up strategies for assessment of genotoxic potential of fragrance materials with evidence of genotoxicity in vitro.

Assessment of no-observed-effect-levels for DNA adducts formation by genotoxic carcinogens in fetal turkey livers.

For genotoxic carcinogens, covalent binding to DNA is a critical initiating event in tumorigenesis. The present research investigated dose-effect relationships of three genotoxic carcinogens representing different structural classes, 2-acetylaminofluorene (2-AAF), benzo[a]pyrene (B[a]P) and quinoline (QUI), to assess the existence of no-observed-effect-levels (NOELs) for the formation of DNA adducts. Carcinogens were administered into the air sac of fertilized turkey eggs over wide dose ranges in three daily injections on days 22 to 24 of incubation. DNA adducts were measured in the fetal turkey livers by the 32P-nucleotide postlabeling (NPL) assay. B[a]P and QUI produced DNA adducts in a dosage-related manner and exhibited NOELs at 0.65 and 0.35 mg/kg bw/day, respectively. In contrast, 2-AAF formed DNA adducts at all tested dosages down to 0.005 mg/kg bw/day. Benchmark dose (BMD) analysis identified the potencies of 2-AAF and QUI to be similar, while B[a]P was the least potent compound. Overall, findings in fetal turkey livers demonstrated that exposure levels to genotoxic compounds that do not result in DNA adducts can exist but are not evident with all carcinogens of this type. The use of mechanistic dose-effect studies for genotoxic endpoints can provide critical information for prioritization of concerns for risk assessment.

Evaluation of Pharmaceuticals for DNA Damage in the Chicken Egg Genotoxicity Assay (CEGA).

DNA damage is an established initiating event in the mutagenicity and carcinogenicity of genotoxic chemicals. Accordingly, assessment of this endpoint is critical for chemicals which are being developed for use in humans. To assess the ability of the Chicken Egg Genotoxicity Assay (CEGA) to detect genotoxic pharmaceuticals, a set of 23 compounds with different pharmacological and reported genotoxic effects was tested for the potential to produce nuclear DNA adducts and strand breaks in the embryo-fetal livers using the 32P-nucleotide postlabeling (NPL) and comet assays, respectively. Due to high toxicity, two aneugens, colchicine and vinblastine, and an autophagy inhibitor, hydroxychloroquine, could not be evaluated. Out of the 20 remaining pharmaceuticals, 10 including estrogen modulators, diethylstilbestrol and tamoxifen, antineoplastics cyclophosphamide, etoposide, and mitomycin C, antifungal griseofulvin, local anesthetics lidocaine and prilocaine, and antihistamines diphenhydramine and doxylamine, yielded clear positive outcomes in at least one of the assays. The antihypertensive vasodilator hydralazine and antineoplastics streptozotocin and teniposide, produced only DNA strand breaks, which were not dose-dependent, and thus, the results with these 3 pharmaceuticals were considered equivocal. No DNA damage was detected for 7 compounds, including the purine antagonist 6-thioguanine, antipyretic analgesics acetaminophen and phenacetin, antibiotic ciprofloxacin, antilipidemic clofibrate, anti-inflammatory ibuprofen, and sedative phenobarbital. However, low solubility of these compounds limited dosages tested in CEGA. Overall, results in CEGA were largely in concordance with the outcomes in other systems in vitro and in vivo, indicating that CEGA provides reliable detection of DNA damaging activity of genotoxic compounds. Further evaluations with a broader set of compounds would support this conclusion.

DNA-damaging activities of twenty-four structurally diverse unsubstituted and substituted cyclic compounds in embryo-fetal chicken livers.

DNA-damaging activities of twenty-four structurally diverse unsubstituted and substituted cyclic compounds were assessed in embryo-fetal chicken livers. Formation of DNA adducts and strand breaks were measured using the nucleotide 32P-postlabelling (NPL) and comet assays, respectively. Unsubstituted monocyclic benzene, polycyclic fused ring compound naphthalene, covalently connected polycyclic ring compound biphenyl, and heterocyclic ring compound fluorene did not produce DNA damage. Amino-substituted monocyclic compounds, aniline and p-phenylenediamine, as well as polycyclic 1-naphthylamine were also negative. In contrast, carcinogenic monocyclic methyl-substituted anilines: o-toluidine, 2,6-xylidine, 3,4-dimethylaniline, 4-chloro-o-toluidine; 2 methoxy-substituted methylaniline: p-cresidine; 2,4 and 2,6 diamino- or dinitro- substituted toluenes all produced DNA damage. Genotoxic polycyclic amino-substituted 2-naphthylamine, 4-aminobiphenyl, benzidine, methyl-substituted 3,2'-dimethyl-4-aminobiphenyl and 4-dimethylaminoazobenzene as well as amino- and nitro- fluorenes substituted at the 1 or 2 positions also were positive in at least one of the assays. Overall, the DNA damaging activity of cyclic compounds in embryo-fetal chicken livers reflected the type and position of the substitution on the aromatic ring. Additionally, substituted polycyclic compounds exhibited higher DNA-damaging potency compared to monocyclic chemicals. These results are congruent with in vivo findings in other species, establishing chicken eggs as a reliable system for structure-activity assessment of members of groups of related chemicals.

Assessment and characterization of DNA adducts produced by alkenylbenzenes in fetal turkey and chicken livers.

Formation of DNA adducts by five alkenylbenzenes, safrole, methyl eugenol, eugenol, and asarone with either α- or ß-conformation, was analyzed in fetal avian livers in two in ovo models. DNA reactivity of the carcinogens safrole and methyl eugenol was previously demonstrated in the turkey egg model, whereas non-genotoxic eugenol was negative. In the current study, alkenylbenzenes were also tested in the chicken egg model. Injections with alkenylbenzenes were administered to fertilized turkey or chicken eggs for three consecutive days. Three hours after the last injection, liver samples were evaluated for DNA adduct formation using the 32P-nucleotide postlabeling assay. DNA samples from turkey livers were also analyzed for adducts using mass spectrometry. In both species, genotoxic alkenylbenzenes safrole, methyl eugenol, α- and ß-asarone produced DNA adducts, the presence and nature of which, with exception of safrole, were confirmed by mass spectrometry, validating the sensitivity of the 32P-postlabeling assay. Overall, the results of testing were congruent between fetal turkey and chicken livers, confirming that these organisms can be used interchangeably. Moreover, data obtained in both models is comparable to genotoxicity findings in other species, supporting the usefulness of avian models for the assessment of genotoxicity as a potential alternative to animal models.

In ovo testing of flavor and fragrance materials in Turkey Egg Genotoxicity Assay (TEGA), comparison of results to in vitro and in vivo data.

Genotoxicity of flavor and fragrance materials was assessed in Turkey Egg Genotoxicity Assay (TEGA) using 32P-nucleotide postlabeling (NPL) and comet assays to detect hepatic DNA adducts and strand breaks. Twenty materials having results in GADD45a-Gluc 'BlueScreen HC' genotoxicity assay, and standard in vitro and in vivo tests, were selected to evaluate the accuracy of TEGA. Quinoline (QUI) and 2-acetylaminofluorene (AAF) served as positive comparators. Two materials, p-tert-butyldihydrocinnamaldehyde (BDHCA) and methyl eugenol (MEU) produced DNA adducts. BDHCA, p-t-butyl-α-methylhydrocinnamic aldehyde (BMHCA), trans-2-hexenal (HEX) and maltol (MAL) produced DNA strand breaks. Fifteen other materials were negative in both assays. Based on reports of oxidative DNA damage induction by MAL and 4-hydroxy-2.5-dimethyl-3(2H) furanone (HDMF), modified comet assays were conducted. Positive comet findings for MAL were not confirmed, and only equivocal evidence of oxidative damage was found. Accordingly, MAL was judged to have equivocal genotoxicity in TEGA. HDMF was positive in modified comet assay, indicating an ability to produce oxidative DNA damage. TEGA showed modest concordance with results in regulatory in vitro assays. Findings in TEGA, with few exceptions, were concordant with the results of in vivo genotoxicity and carcinogenicity testing. Thus, TEGA is an attractive alternative model for the assessment of genotoxic potential of chemicals in vivo.

Assessment of DNA Binding and Oxidative DNA Damage by Acrylonitrile in Two Rat Target Tissues of Carcinogenicity: Implications for the Mechanism of Action.

Exposure to acrylonitrile induces formation of tumors at multiple sites in rats, with females being more sensitive. The present study assessed possible mechanisms of acrylonitrile tumorigenicity, covalent DNA binding, DNA breakage, and oxidative DNA damage, in two target tissues, the brain and Zymbal's glands, of sensitive female Fischer (F344) and Sprague-Dawley (SD) rats. One group received acrylonitrile in drinking water at 100 ppm for 28 days. Two other groups were administered either acrylonitrile in drinking water at 100 ppm or drinking water alone for 27 days, followed by a single oral gavage dose of 11 mg/kg bw 14C-acrylonitrile on day 28. A positive control group received a single dose of 5 mg/kg bw of 7-14C-benzo[a]pyrene, on day 27 following the administration of drinking water for 26 days. Using liquid scintillation counting, no association of radiolabeled acrylonitrile with brain DNA was found. In accelerator mass spectrometry analysis, the association of 14C of acrylonitrile with DNA in brains was detected and was similar in both strains, which may reflect acrylonitrile binding to protein as well as to DNA. Nucleotide 32P-postlabeling assay analysis of brain samples from rats of both strains yielded no evidence of acrylonitrile DNA adducts. Negative conventional comet assay results indicate the absence of direct DNA strand breaks in the brain and Zymbal's gland in both strains of rats dosed with acrylonitrile. In both rat strains, positive results in an enhanced comet assay were found only in brain samples digested with formamidopyrimidine-DNA glycosylase but not with human 8-hydroxyguanine-DNA glycosylase, indicating possible oxidative DNA damage, other than 8-oxodG formation. In conclusion, definitive evidence of DNA binding of acrylonitrile in the brain and Zymbal's gland was not obtained under the test conditions. A role for oxidative stress in tumorigenesis in the brain but not Zymbal's gland may exist.

GRAS determination scientific procedures and possible alternatives.

The use of a food substance is Generally Recognized as Safe (GRAS) through scientific procedures or experience based on common use in food. The pivotal data used for GRAS determination must be of common knowledge and should include evidence for safety under the conditions of intended use of the substance. Such evidence includes data on the identity and specifications of the substance, its properties of absorption, distribution, metabolism and excretion, and depending on the level of concern, data on genotoxicity, acute and subchronic toxicity, reproductive and developmental toxicity and carcinogenicity. Several alternative procedures can be used as the replacement for standard scientific procedures in order to improve the GRAS process.

Structure-Activity Relationships for DNA Damage by Alkenylbenzenes in Turkey Egg Fetal Liver.

Certain alkenylbenzenes (AB), flavoring chemicals naturally occurring in spices and herbs, are established to be cytotoxic and hepatocarcinogenic in rodents. The purpose of the present study was to determine the DNA damaging potential of key representatives of this class using the Turkey Egg Genotoxicity Assay. Medium white turkey eggs with 22- to 24-day-old fetuses received three injections of nine AB with different carcinogenic potentials: safrole (1, 2 mg/egg), methyl eugenol (2, 4 mg/egg), estragole (20, 40 mg/egg), myristicin (25, 50 mg/egg), elemicin (20, 50 mg/egg), anethole (5, 10 mg/egg), methyl isoeugenol (40, 80 mg/egg), eugenol (1, 2.5 mg/egg), and isoeugenol (1, 4 mg/egg). Three hours after the last injection, fetal livers were harvested for measurement of DNA strand breaks, using the comet assay and DNA adducts formation, using the nucleotide(3) (2)P-postlabeling assay. Estragole, myristicin, and elemicin induced DNA stand breaks. These compounds as well as safrole, methyl eugenol and anethole, at the highest doses tested, induced DNA adduct formation. Methyl isoeugenol, eugenol, and isoeugenol did not induce genotoxicity. The genotoxic AB all had the structural features of either a double bond in the alkenyl side chain at the terminal 2',3'-position, favorable to formation of proximate carcinogenic 1'-hydroxymetabolite or terminal epoxide, or the absence of a free phenolic hydroxyl group crucial for formation of a nontoxic glucuronide conjugate. In contrast, methyl isoeugenol, eugenol and isoeugenol, which were nongenotoxic, possessed chemical features, unfavorable to activation.

Sex differences in DNA damage produced by the carcinogen 2-acetylaminofluorene in cultured human hepatocytes compared to rat liver and cultured rat hepatocytes.

Male rats are more susceptible to the induction of liver cancer by the aromatic amine 2-acetylaminofluorene (AAF) than are females. To assess the basis for this difference and to determine whether sex differences in susceptibility to AAF are present in human liver cells, the DNA reactivity of AAF was measured in livers of male and female Sprague-Dawley (SD) rats and in cultured SD rat and human hepatocytes of both sexes. In livers of rats administered oral doses of AAF, the total levels of adducts measured by nucleotide postlabelling at up to 8 weeks were about twofold greater in males than in females. Similarly, the level of AAF-DNA adducts formed in cultured male rat hepatocytes dosed with AAF was about twofold greater than in female rat hepatocytes. Also, the level of DNA repair synthesis was about threefold greater in AAF-dosed cultured male rat hepatocytes compared with female, indicating that the greater adduct levels in males was not due to lesser repair. In contrast, in cultured human hepatocytes of both sexes, AAF produced similar levels of adducts and DNA repair synthesis, which were intermediate between those produced in male and female rat hepatocytes. Thus, the greater susceptibility of male rats to AAF hepatocarcinogenicity is due at least in part to greater bioactivation and formation of AAF-DNA adducts in hepatocytes. Moreover, the data from human hepatocytes suggest that human liver could be less susceptible than male rat liver to the carcinogenic effects of aromatic amine carcinogens of the AAF type.

In vivo genotoxicity of estragole in male F344 rats.

Estragole, a naturally occurring constituent of various herbs and spices, is a rodent liver carcinogen which requires bio-activation. To further understand the mechanisms underlying its carcinogenicity, genotoxicity was assessed in F344 rats using the comet, micronucleus (MN), and DNA adduct assays together with histopathological analysis. Oxidative damage was measured using human 8-oxoguanine-DNA-N-glycosylase (hOGG1) and EndonucleaseIII (EndoIII)-modified comet assays. Results with estragole were compared with the structurally related genotoxic carcinogen, safrole. Groups of seven-week-old male F344 rats received corn oil or corn oil containing 300, 600, or 1,000 mg/kg bw estragole and 125, 250, or 450 mg/kg bw safrole by gavage at 0, 24, and 45 hr and terminated at 48 hr. Estragole-induced dose-dependent increases in DNA damage following EndoIII or hOGG1 digestion and without enzyme treatment in liver, the cancer target organ. No DNA damage was detected in stomach, the non-target tissue for cancer. No elevation of MN was observed in reticulocytes sampled from peripheral blood. Comet assays, both without digestion or with either EndoIII or hOGG1 digestion, also detected DNA damage in the liver of safrole-dosed rats. No DNA damage was detected in stomach, nor was MN elevated in peripheral blood following dosing with safrole suggesting that, as far both safrole and estragole, oxidative damage may contribute to genotoxicity. Taken together, these results implicate multiple mechanisms of estragole genotoxicity. DNA damage arises from chemical-specific interaction and is also mediated by oxidative species.

Chicken fetal liver DNA damage and adduct formation by activation-dependent DNA-reactive carcinogens and related compounds of several structural classes.

The chicken egg genotoxicity assay (CEGA), which utilizes the liver of an intact and aseptic embryo-fetal test organism, was evaluated using four activation-dependent DNA-reactive carcinogens and four structurally related less potent carcinogens or non-carcinogens. In the assay, three daily doses of test substances were administered to eggs containing 9-11-day-old fetuses and the fetal livers were assessed for two endpoints, DNA breaks using the alkaline single cell gel electrophoresis (comet) assay and DNA adducts using the (32)P-nucleotide postlabeling (NPL) assay. The effects of four carcinogens of different structures requiring distinct pathways of bioactivation, i.e., 2-acetylaminofluorene (AAF), aflatoxin B1 (AFB1), benzo[a]pyrene (B[a]P), and diethylnitrosamine (DEN), were compared with structurally related non-carcinogens fluorene (FLU) and benzo[e]pyrene (B[e]P) or weak carcinogens, aflatoxin B2 (AFB2) and N-nitrosodiethanolamine (NDELA). The four carcinogens all produced DNA breaks at microgram or low milligram total doses, whereas less potent carcinogens and non-carcinogens yielded borderline or negative results, respectively, at higher doses. AAF and B[a]P produced DNA adducts, whereas none was found with the related comparators FLU or B[e]P, consistent with comet results. DEN and NDELA were also negative for adducts, as expected in the case of DEN for an alkylating agent in the standard NPL assay. Also, AFB1 and AFB2 were negative in NPL, as expected, due to the nature of ring opened aflatoxin adducts, which are resistant to enzymatic digestion. Thus, the CEGA, using comet and NPL, is capable of detection of the genotoxicity of diverse DNA-reactive carcinogens, while not yielding false positives for non-carcinogens.

Relationship of cellular topoisomerase IIα inhibition to cytotoxicity and published genotoxicity of fluoroquinolone antibiotics in V79 cells.

Fluoroquinolone (FQ) antibiotics are bacteriocidal through inhibition of the bacterial gyrase and at sufficient concentrations in vitro, they can inhibit the homologous eukaryotic topoisomerase (TOPO) II enzyme. FQ exert a variety of genotoxic effects in mammalian systems through mechanisms not yet established, but which are postulated to involve inhibition of TOPO II enzymes. To assess the relationship of inhibition of cell nuclear TOPO II to cytotoxicity and reported genotoxicity, two FQ, clinafloxacin (CLFX) and lomefloxacin (LOFX), having available genotoxicity data showing substantial differences with CLFX being more potent than LOFX, were selected for study. The relative inhibitory activities of these FQ on nuclear TOPO IIα in cultured Chinese hamster lung fibroblasts (V79 cells) over dose ranges and at equimolar concentrations were assessed by measuring nuclear stabilized cleavage complexes of TOPO IIα-DNA. Cytotoxicity was measured by relative cell counts. Both FQ inhibited V79 cell nuclear TOPO IIα. The lowest-observed-adverse-effect levels for TOPO IIα inhibition were 55 µM for CLFX, and 516 µM for LOFX. The no-observed-adverse-effect-levels were 41 µM for CLFX, and 258 µM for LOFX. At equimolar concentrations (175 µM), CLFX was more potent than LOFX. Likewise, CLFX was more cytotoxic than LOFX. Thus, the two FQ, inhibited TOPO IIα in intact V79 cells, differed in their potencies and exhibited no-observed-adverse-effect levels. These findings are in concordance with published genotoxicity data and observed cytotoxicity.

Methyleugenol hepatocellular cancer initiating effects in rat liver.

Methyleugenol (MEG), a constituent of plants used in the human diet, is hepatocarcinogenic in rodents. In an experiment to elucidate its mode of action in rat liver, male F344 rats were administered MEG intragastrically at 3 doses per week for up to 16 weeks in an initiation phase, after which half the rats were fed 500 ppm phenobarbital (PB) in the diet to promote liver neoplasia and the other half were maintained on control diet for 24 weeks. At 8 and 16 week interim terminations, (32)P-nucleotide postlabeling assay revealed 3 adducts in livers of all MEG groups. The hepatocellular replicating fractions, measured by proliferating cell nuclear antigen immunohistochemistry, were doubled or more in all MEG groups. Hepatocellular altered foci, detected by glutathione S-transferase-placental type (π) immunohistochemistry, were present beginning with the high dose group at 8 weeks and extending to all MEG groups at 16 weeks. At the end of maintenance/promotion phase, the incidences, multiplicity and size of foci was similar between control and low dose groups, while those of mid and high dose groups were increased. Hepatocellular adenomas occurred in the mid and high dose groups, attaining higher multiplicity and size with PB. Thus, MEG had rapid initiating activity, reflecting the formation of DNA adducts and possibly cell proliferation.

Furan induction of DNA cross-linking and strand breaks in turkey fetal liver in comparison to 1,3-propanediol.

Furan, a food contaminant formed by heating, is hepatocarcinogenic to rats and mice. Conflicting genotoxicity data exist on furan and its metabolite, cis-2-butene-1,4-dial and there are few data for the target organ, the liver. We assessed the abilities of furan and, as a positive control, 1,3-propanediol (PDO), to cause DNA damage in the livers of turkey fetuses in ovo using the alkaline comet assay. Single injections of furan (2-20 µmoles) into turkey eggs, at 23 days of incubation, when the liver is well developed, reduced the %DNA in the comet tail (%DNA-CT) in hepatocytes isolated from fetuses 24 h later indicating DNA cross links. Treatment of the hepatocytes with proteinase K, digest DNA-protein cross links (DPXLs), increased the %DNA-CT compared to the corresponding controls, indicating the presence of DNA single or double stand breaks (SB). PDO showed little toxicity and was used at high doses (up to 300 µmoles/egg), where it induced DPXLs at about 20 times the furan dose. Thus, furan produced dose proportional reductions in %DNA-CT in turkey liver fetal hepatocytes indicating the presence of DPXLs and, after proteinase K treatment, an increase in %DNA-CT, indicating the presence of DNA single and/or double SB.

Assessment of the medicines lidocaine, prilocaine, and their metabolites, 2,6-dimethylaniline and 2-methylaniline, for DNA adduct formation in rat tissues.

The local anesthetics lidocaine (lido) and prilocaine (prilo) are metabolized to their constituent aromatic amines 2,6-dimethylaniline (DMA, 2,6-xylidine) and 2-methylaniline (MA, o-toluidine), respectively, which are both tumorigenic in rats. The capacity of lido and prilo to form DNA adducts was assessed in major target tissues for aromatic amines in male F344 rats in comparison to equimolar doses of DMA and MA using the (32)P-postlabeling assay. Direct reaction of putative DNA-reactive metabolites N-hydroxy-DMA and N-hydroxy-MA with isolated DNA yielded reference adducts. Rats were dosed by p.o. gavage with 0.5 mmol/kg b.wt. of each test substance or the vehicle either once or daily for 7 days. After repeat administrations of either prilo or lido, DNA adducts were detected in the liver and nasal mucosa. Urinary bladder DNA adducts were detected only in lido and DMA repeat dosed rats. Groups dosed with DMA or MA showed adducts in both single- and multiple-dose groups, except for the single-dose DMA liver and urinary bladder samples, which were below the level of detection. No DNA adducts were detected in any of the white blood cell samples under either dosing regimen. The lido- and prilo-DNA adducts detected were chromatographically indistinguishable from those formed either in DMA- or MA-dosed rats, respectively, or by chemical reaction of the corresponding N-hydroxy derivatives with DNA. Thus, lido and prilo can generate DNA adducts in rats via their aromatic amine metabolites, although at lower levels than equal molar quantities of their amine metabolites.

Inhibition by acetaminophen of neoplastic initiation elicited in rat liver by the DNA-reactive hepatocarcinogen N-acetyl-2-aminofluorene.

Acetaminophen, a monocyclic phenolic compound and analgesic, when fed at 8900 p.p.m. in the diet, was reported to inhibit the hepatocarcinogenicity in rats of the aromatic amine proximate carcinogen N-hydroxy-N-acetyl-2-aminofluorene. To elucidate the mechanism(s) of this anticarcinogenicity, the present study examined whether acetaminophen at lower doses has the ability to inhibit the initiating effects in the rat liver of the precursor hepatocarcinogen N-acetyl-2-aminofluorene. Male F344 rats were allocated to six groups, which were maintained under reverse light cycle conditions to assure acetaminophen ingestion at the time of N-acetyl-2-aminofluorene administration during the dark phase, which was imposed from 07.00 to 19.00 h. Group 1 served as vehicle control (0.5% carboxymethylcellulose) for N-acetyl-2-aminofluorene, which was administered intragastrically 3 days per week at 2.6 mg/kg for 8 weeks (group 4) to achieve initiation. Acetaminophen was given in the diet either alone at 2400 or 4800 p.p.m. for 9 weeks (groups 2 and 3), or with N-acetyl-2-aminofluorene (groups 5 and 6), starting 1 week before N-acetyl-2-aminofluorene administration. Acetaminophen blood levels were about 1 and 4 microg/ml at the two dietary concentrations. N-acetyl-2-aminofluorene induced hepatocellular preneoplastic lesions measured as hepatocellular altered foci expressing glutathione S-transferase-P, reflecting initiation. Induced foci were reduced with administration of both concentrations of acetaminophen. Acetaminophen by itself produced no DNA adducts nor did it alter the high formation of N-acetyl-2-aminofluorene-DNA adducts, about 200 in 10 nucleotides, measured by nucleotide postlabeling. Acetaminophen did not affect background liver cell proliferation, but significantly reduced N-acetyl-2-aminofluorene-induced increased proliferation measured by proliferating cell nuclear antigen immunostaining. Thus, acetaminophen effectively protected hepatocytes from the initiating effects of N-acetyl-2-aminofluorene, possibly through a cytoprotective effect resulting from slowing the rate of induced cell turnover.

Inhibition by dietary hydroquinone of acetylaminofluorene induction of initiation of rat liver carcinogenesis.

Monocyclic phenolics (MPs) occur widely in foods, both naturally and as synthetic antioxidant additives. Several have been shown to inhibit the carcinogenicity of a variety of genotoxic carcinogens in various tissues. Hydroquinone (HQ), one of the simplest of the MPs, which occurs naturally as the glucose conjugate arbutin, was studied for its ability, at low dietary levels, to inhibit the initiating effects in the rat liver of the DNA-reactive carcinogen 2-acetylaminofluorene (AAF). Male Fischer 344 rats (F344), 8 weeks old at the start of the study, were allocated to six groups. HQ was fed daily ad libitum in PMI certified diet at either 0.05% (approximately 25 mg/kg bw/d) or 0.2% (approximately 100 mg/kg bw/d) for 13 weeks, starting one week before AAF administration was initiated, and at the same doses to two groups not receiving AAF. AAF was given intragastrically three times a week for 12 weeks at doses of 3mg/kg bw in 0.5% carboxymethyl cellulose (CMC) to a basal diet group and two of the groups receiving HQ in the diet. Vehicle controls were fed basal diet and administered 0.5% CMC intragastrically three times a week. The rats were observed daily and body weights were taken before initial dosing and at weekly intervals thereafter. Body weight gain over time, terminal body weights and absolute (mg) and relative liver weights (relative to body weight) were measured. At the end of the study (13 weeks), DNA adducts ((32)P-postlabeling), cell proliferation (PCNA immunohistochemistry) and preneoplastic hepatocellular altered foci (HAF) (glutathione S-transferase-placental type immuno-histochemistry) were measured. No significant differences were observed in body weight gains or liver weights. AAF produced liver DNA adducts and at the low dose of HQ adduct levels were 90% of that for AAF alone, whereas at the high dose adducts were reduced by 33% (p<0.05). AAF exposure yielded about a 50% increase in hepatocellular proliferation and both HQ doses reduced the AAF-induced increases in proliferation by about 25%. Likewise, the AAF-induced GST-P-positive HAF per cm(2) of liver tissue were decreased by both doses of HQ by about 50%. Thus, under the conditions of this experiment, HQ at both 0.05% and 0.2% in the diet diminished AAF-induced cancer initiating effects in rat liver.

Embryonic turkey liver: activities of biotransformation enzymes and activation of DNA-reactive carcinogens.

Avian embryos are a potential alternative model for chemical toxicity and carcinogenicity research. Because the toxic and carcinogenic effects of some chemicals depend on bioactivation, activities of biotransformation enzymes and formation of DNA adducts in embryonic turkey liver were examined. Biochemical analyses of 22-day in ovo turkey liver post-mitochondrial fractions revealed activities of the biotransformation enzymes 7-ethoxycoumarin de-ethylase (ECOD), 7-ethoxyresorufin de-ethylase (EROD), aldrin epoxidase (ALD), epoxide hydrolase (EH), glutathione S-transferase (GST), and UDP-glucuronyltransferase (GLUT). Following the administration of phenobarbital (24 mg/egg) on day 21, enzyme activities of ECOD, EROD, ALD, EH and GLUT, but not of GST, were increased by two-fold or higher levels by day 22. In contrast, acute administration of 3-methylcholanthrene (5 mg/egg) induced only ECOD and EROD activities. Bioactivation of structurally diverse pro-carcinogens was also examined using (32)P-postlabeling for DNA adducts. In ovo exposure of turkey embryos on day 20 of gestation to 2-acetylaminofluorene (AAF), 4,4'-methylenebis(2-chloroaniline) (MOCA), benzo[a]pyrene (BaP), and 2-amino-3,8-dimethylimidazo[4,5- f]quinoxaline (MeIQx) resulted in the formation of DNA adducts in livers collected by day 21. Some of the DNA adducts had (32)P-postlabeling chromatographic migration patterns similar to DNA adducts found in livers from Fischer F344 rats exposed to the same pro-carcinogens. We conclude that 21-day embryonic turkey liver is capable of chemical biotransformation and activation of genotoxic carcinogens to form DNA adducts. Thus, turkey embryos could be utilized to investigate potential chemical toxicity and carcinogenicity.