Induction of DNA repair in human and rat hepatocytes by 1,6-dinitropyrene

Species-specific differences in peroxisome proliferation, catalase, and SOD2 upregulation as well as toxicity in human, mouse, and rat hepatoma cells induced by the explosive and environmental pollutant 2,4,6-trinitrotoluene

2,4,6-Trinitrotoluene (TNT) has been widely used as an explosive substance and its toxicity is still of interest as it persisted in polluted areas. TNT is metabolized in hepatocytes which are prone to its toxicity. Since analysis of the human liver or hepatocytes is restricted due to ethical reasons, we investigated the effects of TNT on cell viability, reactive oxygen species (ROS) production, peroxisome proliferation, and antioxidative enzymes in human (HepG2), mouse (Hepa 1-6), and rat (H4IIEC3) hepatoma cell lines. Under control conditions, hepatoma cells of all three species were highly comparable exhibiting identical proliferation rates and distribution of their cell cycle phases. However, we found strong differences in TNT toxicity with the lowest IC₅₀ values (highest cell death rate) for rat cells, whereas human and mouse cells were three to sevenfold less sensitive. Moreover, a strong decrease in cellular dehydrogenase activity (MTT assay) and increased ROS levels were noted. TNT caused peroxisome proliferation with rat hepatoma cells being most responsive followed by those from mouse and human. Under control conditions, rat cells contained fivefold higher peroxisomal catalase and mitochondrial SOD2 activities and a twofold higher capacity to reduce MTT than human and mouse cells. TNT treatment caused an increase in catalase and SOD2 mRNA and protein levels in human and mouse, but not in rat cells. Similarly, human and mouse cells upregulated SOD2 activity, whereas rat cells failed therein. We conclude that TNT induced oxidative stress, peroxisome proliferation and mitochondrial damage which are highest in rat cells rendering them most susceptible toward TNT. © 2016 Wiley Periodicals, Inc. Environ Toxicol 32: 989-1006, 2017.

Recommendations for the performance of UDS tests in vitro and in vivo

The Working Group (WG) dealt with the harmonization of routine methodologies of tests for unscheduled DNA synthesis (UDS) both in vitro and in vivo. In contrast to the existing guidelines from OECD, EPA and EC on in vitro UDS tests (there is no Japanese UDS guideline), the Working Group recommends that in general in vitro UDS tests should be performed with primary hepatocytes. For routine applications any other cell types would need special justification. Hepatocytes from male rats are preferable, unless there are contra-indications on the basis of e.g. toxicokinetic data. According to the OECD, EPA and EC guidelines, UDS may be analysed by means of autoradiography (AR) or liquid scintillation counting (LSC). The WG recommends use of AR. LSC is less suitable due to the problem of differentiation between UDS activity and replicative DNA synthesis, and the disadvantage that cells cannot be analysed individually. Since a specific cell type was recommended by the WG, methodological aspects could be described in more detail than in the present guidelines. For in vitro tests, it was agreed that the initial viability of freshly isolated hepatocytes should be at least 70%. With regard to the need for confirmatory experiments in the event of a clear-cut negative result, the majority view was that confirmation by a second (normally not identical) experiment is still needed; this is in line with the present OECD and EC guidelines. Evaluation of results from UDS tests should be based primarily on net nuclear grain (NNG) values, although it is recognised that nuclear and cytoplasmic grains result from different biological processes. Since grain counts are influenced by a number of methodological parameters, no global threshold NNG value can be recommended for discrimination of positive and negative UDS results. For in vitro assays, the criteria for positive findings go beyond those of the present guidelines and two alternative approaches are given which are based on (1) dose-dependent increases in NNG values and (2) reproducibility, dose-effect relationship and cytotoxicity. At present there is no official guideline on the performance of in vivo UDS tests. Some fundamental recommendations given for in vitro methodology also apply to the in vivo assay. For routine testing with the in vivo UDS test, again the general use of hepatocytes from male rats is recommended. However, concerning the requirement to use one or two sexes, consistency with other in vivo genotoxicity assays (e.g. the micronucleus assay) would be preferable. As for the in vitro methodology, AR is preferred rather than LSC.(ABSTRACT TRUNCATED AT 400 WORDS)

Detection of genotoxic effects in human gastric and nasal mucosa cells isolated from biopsy samples

To assess genotoxic burdens from chemicals, it is necessary to relate observations in experimental animals to humans. The success of this extrapolation would be increased by including data on chemical activities in human tissues. Therefore, we have developed techniques to assess DNA damage in human gastric and nasal mucosa (GM, NM) cells. Biopsy samples were obtained during gastroscopy from macroscopically healthy tissue of the stomach or from healthy nasal epithelia during surgery. The specimens were incubated for 30-45 min at 37 degrees C with a digestive solution. We obtained 1.5-8 x 10(6) GM cells and 5-10 x 10(5) NM cells per donor, both with viabilities of 80-95%. The cells were incubated in vitro for 1 hr at 37 degrees C with the test compounds added in their appropriate solvents. In GM cells, we studied N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), sodium dichromate (Na2Cr2O7), nickel sulphate (NiSO4), cadmium sulphate (CdSO4), and lindane. In NM cells, lindane was investigated. Each compound was assessed for DNA damaging activity in cells of at least three different human donor samples using the microgel single cell assay. Similar studies were performed with GM and NM cells obtained from Sprague-Dawley rats. We have found human GM cells to be more sensitive to the genotoxic activity of MNNG than rat GM cells (low effective concentration [LEC] = 0.16 and 0.625 micrograms/ml for human and rat, respectively). Human cells were also more sensitive to the cytotoxic/genotoxic activity of NiSO4 (LEC = 5 and 19 mumoles/ml for human and rat, respectively). CdSO4 was genotoxic in human GM cells (LEC = 0.03-0.125 mumoles/ml), whereas no dose-related genotoxicity was observed in rat GM at concentrations up to 0.5 mumoles/ml. In contrast, approximately equal responses regarding genotoxicity and cytotoxicity were observed in rat and human GM for Na2Cr2O7 (0.25-1 mumoles/ml). Lindane, however, was genotoxic in three out of four rat GM but not in human GM cells (0.5-1 mumoles/ml), whereas it was active in both rat and human NM cells. Together with other recently published in vivo findings, our results with lindane can be interpreted according to a parallelogram approach. In view of possible human exposure situations and the sensitivities of the two target tissues from both species, the data imply that lindane will pose a health risk to humans by inhalation but not by ingestion.

Genotoxicity of pyrene oxide and 1-nitropyrene oxides in hepatocyte primary culture/DNA repair test

The genotoxicity of a pyrene oxide, 1-nitropyrene (NP) oxides and other related compounds was examined in the hepatocyte primary culture (HPC)/DNA repair test. Pyrene 4,5-oxide and both 1-NP-4,5-oxide and 1-NP-9,10-oxide elicited clearly positive responses of DNA repair. In this assay, 1-NP itself was weakly positive. However, other related chemicals such as pyrene, 1-nitro-3-hydroxypyrene, 1-nitro-6-hydroxypyrene, and 1-nitro-8-hydroxypyrene did not generate positive responses.

Structure-activity relationships in the rat hepatocyte DNA-repair test for 300 chemicals

312 chemicals/mixtures were tested for genotoxicity in the rat hepatocyte/DNA-repair test. A variety of structure-activity relationships was evident. Of the 309 pure chemicals, 142 were positive. Of these, 43 were judged by IARC to have sufficient or limited evidence of carcinogenicity and none of the remainder was a proven noncarcinogen. Among the 167 negative chemicals, 44 were carcinogens. Some of these are known to be genotoxic in other systems, but based on several lines of evidence, many are considered to be epigenetic carcinogens that lack the ability to react with DNA and rather lead to neoplasia by nongenotoxic mechanisms.

The clastogenic activity of 1,6-dinitropyrene in peripheral human lymphocytes

The ability of 1,6-dinitropyrene to induce chromosome damage in peripheral human lymphocyte cultures has been demonstrated. Low levels of clastogenic activity were detected following 3-h treatments with 1,6-dinitropyrene in the presence of a rat-liver cytosol fraction. The clastogenic activity reached a peak at a concentration of 1.25 micrograms/ml of 1,6-dinitropyrene after which the frequency of aberrations decreased. This unusual genotoxic dose response is similar to that found previously in yeast and rat-liver cells. The fact that a positive result was obtained using human lymphocytes shows that, in the presence of the appropriate activation system, dinitropyrene is genotoxic in human cells.

Genotoxicity of carcinogens in human hepatocytes: application in hazard assessment

Evaluation of chemical genotoxicity has been used in assessing human cancer hazard, based on the observation that most human carcinogens are known to be DNA-reactive. The availability of data on the DNA-reactivity of compounds in metabolically competent human cells would assist hazard assessment by providing direct information of human genotoxicity. To evaluate the reliability of human hepatocytes for this purpose, the induction of DNA repair by DNA-reactive carcinogens of several structural classes and related noncarcinogens was studied. All the carcinogens elicited DNA repair synthesis, whereas the noncarcinogens did not. These studies provide additional support for the use of human hepatocytes in a DNA repair test in the investigation of genotoxicity. The demonstration of genotoxicity in human cells is suggested to provide important information for hazard assessment.

Induction of unscheduled DNA synthesis in primary cultures of rat, mouse, hamster, monkey, and human hepatocytes

Variation in hepatic metabolism between species may be an important factor in the differences observed in chemical carcinogenesis. We examined 6 chemicals representative of 4 chemical classes in the in vitro hepatocyte DNA repair assay using cells isolated from the Fischer-344 rat, B6C3F1 mouse, Syrian golden hamster, cynomolgus monkey and from human liver. Hepatocytes were isolated by in situ or biopsy liver perfusion and incubated with [3H]-thymidine and the test chemical. Unscheduled DNA synthesis (UDS) was measured as net grains/nucleus (NG) by quantitative autoradiography. Qualitative and quantitative differences in UDS responses were observed for every chemical. Liver cultures isolated from the rat, mouse, hamster, human, and monkey and treated with aflatoxin B1 or dimethylnitrosamine all yielded dose-related increases in NG. Human, rat, and hamster hepatocyte cultures yielded positive responses following exposure to the aromatic amines 2-acetylaminofluorene, 4-aminobiphenyl, and benzidine, whereas cultures isolated from the monkey and mouse yielded less than 0 NG. Treatment with benzo[a]pyrene (BAP) produced strong positive responses in monkey and human hepatocyte cultures, weak positive responses in hamster cultures, and equivocal or negative responses in rat and mouse hepatocyte cultures. Hepatocyte function was assessed by measurement of DNA content, glutathione content, BAP hydroxylase activity, p-nitroanisole-O-demethylase activity, p-nitrophenol conjugation, and urea synthesis rates. The functional capabilities of isolated hamster, monkey, and human hepatocyte cultures do not appear to correlate with UDS responses observed for any compound; however, they indicate that the cultures were metabolically competent at the time of chemical exposure. These studies suggest that rat hepatocytes are a suitable model for human hepatocytes, whereas mouse and male monkey hepatocytes may be insensitive to aromatic amines.

Application of a cellular test battery in the decision point approach to carcinogen identification

The assessment of the potential carcinogenicity of a chemical requires a systematic approach taking into account various types of data. Important information on the DNA reactivity and other genetic effects of chemicals can be obtained from a battery of cellular tests. A battery is described which includes DNA repair in hepatocytes, mutagenesis in Salmonella typhimurium, mutagenesis, chromosome alterations, and transformation in mammalian cells. The interpretation of findings in this battery for the identification of potential carcinogenicity of chemicals is discussed.

A protocol and guide for the in vivo rat hepatocyte DNA-repair assay

The in vivo rat hepatocyte DNA-repair assay is a valuable tool in assessing the genotoxic activity of chemical agents. An advantage of the system is that it reflects the complex patterns of uptake, distribution, metabolism, detoxification and excretion that actually occur in the whole animal. This article provides a typical procedure and guidelines for conducting the rat in vivo hepatocyte DNA-repair assay.

A protocol and guide for the in vitro rat hepatocyte DNA-repair assay

The in vitro rat-hepatocyte DNA-repair assay is a valuable tool in assessing the genotoxic activity of chemical agents. An advantage of the assay is that the target cells themselves are metabolically competent, so that the patterns of metabolic activation and detoxification closely reflect those in the whole animal. This article provides a typical procedure and guidelines for conducting the rat in vitro hepatocyte DNA-repair assay.

Induction of DNA fragmentation and DNA repair synthesis in human and rat hepatocytes by diethylstilbestrol

The synthetic estrogen diethylstilbestrol (DES), a known human carcinogen, was examined for cytotoxicity, and the induction of DNA damage and repair in primary cultures of human and rat hepatocytes. In both species concentrations of DES ranging from 5.6 to 18 micrograms/ml constantly produced reduction of cell viability and DNA fragmentation in dose-related amounts. However, large individual quantitative differences in the sensitivity to the cytotoxic and DNA-damaging activities of DES were observed among cultures derived from the 5 human donors. DES capability of eliciting DNA-excision repair was weak but statistically significant in both human and rat hepatocytes. Taken as a whole these results contribute to support the hypothesis of a genotoxic mechanism in DES-induced carcinogenesis.

The hepatocyte primary culture/DNA repair test using hepatocytes from several species

The hepatocyte primary culture/DNA repair test, originally validated with rat hepatocytes, has been extended to use hepatocytes from other species including mouse, hamster, guinea pig, rabbit, monkey and human. Both qualitative and quantitative differences have been observed when chemicals are examined in the hepatocyte primary culture/DNA repair test using hepatocytes from more than one species. Examples are discussed that illustrate that the genotoxicity of a chemical can be a species-specific response and that multi-species testing permits a more complete assessment of genotoxicity.

Nitropyrenes are inducers of polyoma viral DNA synthesis

The biological activity of a series of nitropyrenes was assayed by measuring their ability to induce the asynchronous replication of viral DNA in rat fibroblasts transformed by a ts-a mutant of polyoma virus. Concentrations of 10-30 micrograms/ml of 1-nitropyrene (1-NP) induced viral replication, and this effect was enhanced by addition of rat-liver S9 microsomal fraction (300 micrograms/ml) to the culture medium. The response was less than that obtained with 0.1 micrograms/ml of the activated metabolite of benzo[a]pyrene (BP), BP trans-7,8-dihydrodiol-9,10 epoxide (anti) (BPDE). A series of di-, tri-, and tetra-nitropyrenes were also found to induce polyoma DNA replication, in the absence of exogenous microsomal activation, displaying strongly positive effects at 0.5-2.0 microgram/ml. Dose-response curves with 1,6-dinitropyrene (1,6-DNP) from 0.01 to 0.5 microgram/ml indicated that this compound was approximately equipotent with BPDE for induction of polyoma DNA synthesis. Studies of drug metabolism, DNA binding and DNA adduct formation indicate that 1,6-DNP is metabolized in this cell line, binds to DNA, and forms stable adducts. The level of DNA modification seen with 1,6-DNP is higher than that observed under comparable conditions with an equivalent dose of BPDE. These findings provide additional evidence that the nitropyrene class of compounds can exert biological effects in mammalian cells, and that the dinitropyrenes are more potent than 1-NP.

Use of in vivo/in vitro unscheduled DNA synthesis for identification of organ-specific carcinogens

There are still only a few in vivo short-term assay methods for predicting potential organ-specific carcinogens and mutagens in mammals, although such methods are required for evaluating the in vivo effects of in vitro mutagens. In the in vivo/in vitro UDS assay methods described here, chemicals are given to experimental animals and induction of UDS in target organs is determined by in vitro organ culture or primary cell culture in the presence of [3H]dThd. Incorporation of [3H]dThd into DNA is measured with a liquid scintillation counter or by autoradiography. These methods have now been applied to the glandular stomach, forestomach, colon, liver, kidney, pancreas, tracheal epithelium, nasal epithelium, and spermatocytes. With minor modifications, they may also be applied to other organs. The present review shows that induction of UDS in various organs correlated well with the induction of cancer in these organs. The present authors have used the present methods to identify some potential organ-specific mutagens and carcinogens in mammals. The present authors found that three dicarbonyl compounds, glyoxal, methylglyoxal, and diacetyl, induced apparent UDS and TDS in the glandular stomach, and other groups found that 2-NT, MA6BT, and CNEt6BT induced UDS in the liver. These in vivo/in vitro UDS assays are better than in vitro UDS assay for identification of potential organ-specific mutagens and carcinogens in mammals and are especially useful for identifying potential mutagens and carcinogens that are specific for certain organs, such as the stomach, liver, and kidney. They are also useful for examining the potential mutagenicities and carcinogenicities of carcinogen analogs. However, these methods are not suitable for general in vivo screening because they are not yet available for all organs. A further advantage of the methods is that they can be used to examine larger numbers of animals at one time than other methods for detecting DNA damage, such as alkaline elution or alkaline sucrose density gradient centrifugation. Glyoxal enhanced cancer induction in the glandular stomach by the administration of a limited amount of MNNG and then glyoxal afterward in the two-stage stomach carcinogenesis.

Nitropyrene-induced DNA repair in Clara cells and alveolar type-II cells isolated from rabbit lung

DNA excision repair, as measured by unscheduled DNA synthesis (UDS), was examined in different cell types of rabbit lung exposed to nitropolycyclic aromatic hydrocarbons (NO-PAH) in vitro. Dose-related increases in UDS were observed. 1,6-Dinitropyrene (1,6-DNP) and 1,8-dinitropyrene (1,8-DNP) induced UDS more effectively in alveolar type-II cells compared with Clara cells. On the other hand, 1-nitropyrene (1-NP) caused a weak UDS response in Clara cells but no DNA repair in alveolar type-II cells.

A study of the potential genotoxicity of cimetidine using human hepatocyte primary cultures: discrepancy from results obtained in rat hepatocytes

The genotoxicity of cimetidine, a drug widely used in the treatment of peptic ulcer, was examined in human hepatocyte primary cultures. No induction of unscheduled DNA synthesis, as detected by autoradiography, or of DNA fragmentation, as measured by alkaline elution, was seen in metabolically competent human hepatocytes exposed for 20 h to cimetidine concentrations ranging from 0.33 to 9 mM. These findings, which are in contrast with the previously observed capability of cimetidine to induce DNA damage and repair in rat hepatocyte primary cultures, suggest that for some chemicals the rat hepatocyte model might be an inappropriate predictor of potential genotoxic effects in the analogous human cells.

DNA damage induced by nitropyrenes in primary mouse hepatocytes and in rat H4-II-E hepatoma cells

The capacity of nitropyrenes to cause DNA damage in primary mouse hepatocytes (C57BL/6N mice) and rat H4-II-E hepatoma cells was studied by estimating single-strand breaks using the alkaline elution technique. 1-Nitropyrene (10-200 microM) caused clear dose-dependent increases in DNA strand breaks in both cell types, whereas no increase in DNA strand breaks was observed in hepatocytes treated with 1.3-, 1,6-, 1,8-dinitropyrene, 1,3,6-trinitropyrene and 1,3,6,8-tetranitropyrene under standard assay conditions (5-20 microM 30-min incubation). However, 1,8-dinitropyrene (1,8-DNP) caused dose-dependent increases in DNA strand breaks when incubated with the H4-II-E cells for 48 h, while no single-strand breaks were observed following treatment with 1,6-dinitropyrene (1,6-DNP) under the same conditions. Neither 1,6-DNP nor 1,8-DNAP induced DNA crosslinks in the H4-II-E cells. These data indicate that substrate specificity exists in the metabolic activation of nitropyrenes in murine liver.

Assessment of chemically induced DNA repair in primary cultures of human bronchial epithelial cells

A procedure has been developed to assess chemically induced DNA repair in freshly isolated, primary cultures of human bronchial epithelial (HBE) cells. HBE cells were isolated from eight samples of autopsy material or surgical specimens and incubated with test chemicals and [3H]thymidine. Viability as measured by trypan blue exclusion averaged 90%. Chemically induced DNA repair was assessed as unscheduled DNA synthesis (UDS) by quantitative autoradiography. The direct-acting agent methyl methanesulfonate induced DNA repair in HBE cells in all eight cases studied, indicating that the cultures were viable and capable of DNA repair in response to DNA damage. Benzo(a)pyrene induced DNA repair in all cultures whereas dimethylnitrosamine failed to induce UDS in any culture, suggesting an organ-specific pattern of metabolic activation. 1,6-Dinitropyrene was positive in cultures prepared from autopsy material but negative in cultures prepared from surgical specimens. Formaldehyde did not induce UDS in any sample examined. This system may be useful in assessing the genotoxic potential of environmental chemicals in human bronchial epithelial cells, give an indication of interindividual variability, and provide valuable information for comparison to proposed animal models for the human bronchus.

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.