Detection of DNA damage in primary cultures of rat hepatocytes following in vivo and in vitro exposure to genotoxic agents

Evaluating genotoxicity data to identify a mode of action and its application in estimating cancer risk at low doses: A case study involving carbon tetrachloride

In the new USEPA cancer risk assessment guidelines, mode of action (MoA) information, combined with a determination of whether or not a chemical is mutagenic, plays an important role in determining whether a linear or nonlinear approach should be used to estimate cancer risks at low doses. In this article, carbon tetrachloride (CT) is used as an example to illustrate how mixed genotoxicity data can be evaluated and used to identify a likely MoA. CT is essentially negative in inducing gene mutations in Salmonella, but is consistently positive in inducing recombination and aneuploidy in fungi. Negative or equivocal results were seen in most in vitro and in vivo studies in mammals, including mutation studies in transgenic mice. However, DNA adducts, primarily those derived from oxidation- and lipid-peroxidation-derived products as well as DNA double-strand breaks and micronucleated cells, have been seen repeatedly in the liver of CT-treated animals. On the basis of the weight of evidence, CT should not be considered a directly mutagenic agent. Mutagenic as well as other genotoxic effects, as they occur, will most likely be generated through indirect mechanisms resulting from oxidative and lipid peroxidative damage and/or damage occurring during necrosis or apoptosis. As key events in this process are expected to occur in a nonlinear fashion, the expected relationship between CT dose and carcinogenic response in the liver is likely to be nonlinear with a steep dose response. This conclusion is consistent with rodent cancer bioassay results in which steep nonlinear dose responses have been seen.

Postulated carbon tetrachloride mode of action: a review

Under the 2005 U.S. EPA Guidelines for Carcinogen Risk Assessment (1), evaluations of carcinogens rely on mode of action data to better inform dose response assessments. A reassessment of carbon tetrachloride, a model hepatotoxicant and carcinogen, provides an opportunity to incorporate into the assessment biologically relevant mode of action data on its carcinogenesis. Mechanistic studies provide evidence that metabolism of carbon tetrachloride via CYP2E1 to highly reactive free radical metabolites plays a critical role in the postulated mode of action. The primary metabolites, trichloromethyl and trichloromethyl peroxy free radicals, are highly reactive and are capable of covalently binding locally to cellular macromolecules, with preference for fatty acids from membrane phospholipids. The free radicals initiate lipid peroxidation by attacking polyunsaturated fatty acids in membranes, setting off a free radical chain reaction sequence. Lipid peroxidation is known to cause membrane disruption, resulting in the loss of membrane integrity and leakage of microsomal enzymes. By-products of lipid peroxidation include reactive aldehydes that can form protein and DNA adducts and may contribute to hepatotoxicity and carcinogenicity, respectively. Natural antioxidants, including glutathione, are capable of quenching the lipid peroxidation reaction. When glutathione and other antioxidants are depleted, however, opportunities for lipid peroxidation are enhanced. Weakened cellular membranes allow sufficient leakage of calcium into the cytosol to disrupt intracellular calcium homeostasis. High calcium levels in the cytosol activate calcium-dependent proteases and phospholipases that further increase the breakdown of the membranes. Similarly, the increase in intracellular calcium can activate endonucleases that can cause chromosomal damage and also contribute to cell death. Sustained cell regeneration and proliferation following cell death may increase the likelihood of unrepaired spontaneous, lipid peroxidation- or endonuclease-derived mutations that can lead to cancer. Based on this body of scientific evidence, doses that do not cause sustained cytotoxicity and regenerative cell proliferation would subsequently be protective of liver tumors if this is the primary mode of action. To fulfill the mode of action framework, additional research may be necessary to determine alternative mode(s) of action for liver tumors formed via carbon tetrachloride exposure.

Selective induction of micronuclei in the rat/mouse colon and liver by 1,2-dimethylhydrazine: a seven-tissue comparative study

1,2-Dimethylhydrazine (DMH) was administered to both genders of mice and rats by oral gavage for 3 days. Twenty-four hours later, an assessment of the incidence of micronucleated cells was made in the bone marrow and sections of the gastrointestinal tract. An increase in micronucleated cells was observed in the colon of both genders of both species of rodent. Negative responses were observed in the forestomach, stomach, duodenum, intestine of both species. The bone marrow micronucleus assays were essentially negative, but the absence of a precise definition of the MTD precludes a definitive conclusion from being drawn. These results are consistent with the selective carcinogenicity of DMH to the colon of the rodent GI-tract. DMH is also known to be carcinogenic to rat and mouse liver and, although it is known to induce micronuclei in the hepatocytes of rats, no such data exist for the mouse. Consequently, mice were administered DMH on 13 successive days, followed by 2/3 partial hepatectomy and assessment of micronucleated hepatocytes. A strong positive liver micronucleus assay response was observed. Thus, DMH selectively induces micronuclei in the colon and liver of rats and mice, consistent with its carcinogenicity to these two tissues. No qualitative differences between the genders was observed in any of the assays. These results indicate that the assessment of genetic toxicity in rodents should not rely solely on assays made in bone marrow.

Genetic toxicity of 2-acetylaminofluorene, 2-aminofluorene and some of their metabolites and model metabolites

2-Acetylaminofluorene and 2-aminofluorene are among the most intensively studied of all chemical mutagens and carcinogens. Fundamental research findings concerning the metabolism of 2-acetylaminofluorene to electrophilic derivatives, the interaction of these derivatives with DNA, and the carcinogenic and mutagenic responses that are associated with the resulting DNA damage have formed the foundation upon which much of genetic toxicity testing is based. The parent compounds and their proximate and ultimate mutagenic and carcinogenic derivatives have been evaluated in a variety of prokaryotic and eukaryotic assays for mutagenesis and DNA damage. The reactive derivatives are active in virtually all systems, while 2-acetylaminofluorene and 2-aminofluorene are active in most systems that provide adequate metabolic activation. Knowledge of the structures of the DNA adducts formed by 2-acetylaminofluorene and 2-aminofluorene, the effects of the adducts on DNA conformation and synthesis, adduct distribution in tissues, cells and DNA, and adduct repair have been used to develop hypotheses to understand the genotoxic and carcinogenic effects of these compounds. Molecular analysis of mutations produced in cell-free, bacterial, in vitro mammalian, and intact animal systems have recently been used to extend these hypotheses.

Lack of DNA single-strand breaks in rat liver cells exposed to 4-acetylaminofluorene, in vivo and in vitro

The induction of primary DNA damage by the non-carcinogen 4-AAF was reinvestigated in liver cells by comparison with the carcinogen 2-AAF. DNA alkaline elution showed the appearance of single-strand breaks in total liver DNA of rats 4 h after gavage with 200 mg/kg of 4-AAF. The decrease in hepatocyte viability and yield observed in these livers after collagenase perfusion indicated a cytotoxic effect of 4-AAF treatment. Viable hepatocytes isolated from 4-AAF-treated rats as well as hepatocytes from normal rats treated with 4-AAF in vitro did not present DNA single-strand breaks.

The induction of DNA-strand breaks and unscheduled DNA synthesis in F-344 rat hepatocytes following in vivo administration of caprolactam or benzoin

Benzoin (ZOIN) and caprolactam (CAP) were administered by gavage to Fischer 344 rats at a dose of 750 mg/kg and the hepatocytes isolated 12, 24 or 48 h after treatment. The isolated hepatocytes were subsequently examined for the induction of DNA-strand breaks (SB) and unscheduled DNA synthesis (UDS). Neither ZOIN nor CAP induced SB or UDS in hepatocytes, however ZOIN did induce an increase in the fraction of cells in S-phase 24 h after treatment. These results correlate well with the observed lack of carcinogenicity of these compounds.

Biomonitoring of DNA damage by alkaline filter elution

The majority of DNA lesions resulting from interactions of carcinogens with DNA are usually either single strand breaks or lesions which are converted to single strand breaks by treatment of DNA with alkaline solutions. A sensitive method of detecting DNA single strand breaks is the alkaline filter elution of DNA. We started to test this method for biomonitoring occupational exposure with sensitive experimental conditions using pH 12.6, where most alkali-labile DNA lesions are converted to single strand breaks. Under our conditions statistically significant differences can be detected between the elution rates of untreated V79 cells and cells treated with [3H]-thymidine 24 h prior to the elution. Statistically significant increases were detected in the elution rates of male smoking automobile mechanics and male smoking painters compared to non-smoking controls. No statistically significant differences were detected in the elution rates of male non-smoking automobile mechanics and male workers with a suspected exposure to halogenated aromatics compared to male controls. No statistically significant differences were observed in the elution rates of female smoking dry-cleaning workers compared to female smoking controls. Our experience showed that the alkaline elution technique can be a valuable tool for monitoring DNA damage in peripheral lymphocytes in man.

Automated determination of DNA using the fluorochrome Hoechst 33258

An automated method for the determination of DNA content in fractions from the alkaline filter elution assay of DNA damage has been developed. DNA-containing fractions are mixed with a fluorochrome (Hoechst 33258) and the DNA concentration is measured fluorometrically in a continuous-flow system. The lower limit of detection is 0.05 micrograms DNA/ml, and the linearity range under the conditions used is 0-8 micrograms DNA/ml. The standard deviation (n = 10) was found to be +/- 0.83%. The results are compared with the manual method.

An assessment of the in vivo rat hepatocyte DNA-repair assay

The in vivo rat hepatocyte autoradiographic assay for unscheduled DNA synthesis (UDS) described by Mirsalis et al, and its in vitro counterpart described earlier by Williams have been employed by us for 4 years. Our experience is that the in vivo assay performs as described in the literature. We have therefore concentrated in this initial paper on the key practical factors we have found to govern the assay sensitivity and reproducibility. This has been achieved by a discussion of the assay performance with two potent rat hepatocarcinogens [the novel azo compound 6-dimethylaminophenylazobenzthiazole (6BT) and the reference agent 2-acetylaminofluorene (2AAF)] and a non-carcinogen of similar structure to 6BT [5-dimethylaminophenylazoindazole (51)]. Assay responses were compared with the effect of these chemicals in the Salmonella mutation assay. We conclude that the in vivo liver UDS assay has a critical role to play as a complement to rodent bone marrow cytogenic assays when conducting assessment studies on agents defined as genotoxic in vitro. However, the in vivo assay is resource-consuming and false results could consequently arise due to incomplete evaluations. Methods to counteract this danger are discussed and criteria for assessing weak UDS responses are suggested.

Assessment of the genotoxic effects of methyl chloride in human lymphoblasts

The activity of methyl chloride was measured in 4 genotoxicity assays. In an established human lymphoblast line, a 3-h treatment with 0-5% methyl chloride resulted in a dose-related increase in mutant fraction at the thymidine kinase locus and induction of sister-chromatid exchange. No increase in DNA damage, as measured by alkaline elution, was detected in the lymphoblasts at concentrations of methyl chloride shown to be mutagenic. Also, a concentration-related increase in 8-azaguanine-resistant fraction in Salmonella typhimurium was observed following a 3-h treatment with atmospheres containing 0-20% methyl chloride. Thus, methyl chloride is a weak, direct-acting mutagen for bacteria and human cells in culture.

An in vivo-in vitro alkaline DNA unwinding assay for hepatic DNA damage: comparison with the alkaline sucrose gradient centrifugation technique

An in vivo-in vitro alkaline DNA unwinding assay for single-strand breaks and/or alkali-labile lesions in hepatic DNA is described. The assay involves isolation of hepatic nuclei from mice, alkaline denaturation and unwinding of hepatic DNA, separation of single- and double-stranded DNA by hydroxylapatite batch chromatography, and quantitation of DNA in chromatographic fractions by a fluorometric assay. The method allows for the sensitive detection of hepatic DNA damage following in vivo administration of xenobiotics. Using this procedure, DNA fragmentation was demonstrated in alkali after administration of as little as 0.5 mg/kg of N-nitrosodimethylamine (DMN) to male B6C3F1 mice. A comparison of this technique with a similar alkaline sucrose density gradient centrifugation assay demonstrated comparable limits of sensitivity for the two procedures.

Dinitrotoluene: acute toxicity, oncogenicity, genotoxicity, and metabolism

Dinitrotoluene (DNT) is a major commodity chemical; over six hundred million pounds of DNT were used in the chemical industry in 1980. Interest in the toxicology of this important chemical was greatly increased when separate oncogenicity assays yielded the conflicting results that DNT was either not hepatocarcinogenic or produced a 100% incidence of hepatocellular carcinomas in male rats in one year. Research revealed pronounced differences in the activity of the DNT isomers and provided the reason for the dissimilar results of the various carcinogenicity studies. Cell culture genetic toxicology assays failed to predict the potent carcinogenic activity of any isomer of DNT. Only when the complex pattern of metabolic activation of DNT began to unfold and genotoxic activity was assessed in the appropriate target organ in the intact treated animal was the potent genotoxic activity of DNT revealed, and the reasons for the negative in vitro results understood. The DNTs have been extensively tested for reproductive effects in animals and humans, and the metabolism and disposition of each of the six possible isomers have been studied. This work has provided valuable information in establishing the risk of these compounds to humans.