DNA damage induced by 4,4'-methylenedianiline in primary cultures of hepatocytes and thyreocytes from rats and humans

4,4'-Methylenedianiline (MDA), an aromatic amine used in various industrial processes and previously found to induce tumor development in liver and thyroid of mice and rats, was evaluated for its DNA-damaging activity in primary cultures of hepatocytes and thyreocytes from rat and human donors. After exposure for 4 and 20 h to MDA concentrations ranging from 10 to 180 microM, a statistically significant increase in the frequency of DNA lesions was revealed by the Comet assay in primary hepatocytes and thyreocytes from donors of both species, the response being dose dependent up to 56-100 microM MDA. DNA fragmentation was more marked after 4 than after 20 h exposure in all four cell types. DNA was damaged to a lesser extent in human hepatocytes and thyreocytes than in corresponding rat cells and in both species in hepatocytes than in thyreocytes. In both rat and human hepatocytes a 20-h exposure to the same MDA concentrations elicited a modest amount of DNA repair synthesis, as evaluated by autoradiography. Evidence of a partial reduction of DNA damage, and therefore of only partial DNA repair, was observed in rat hepatocytes and in rat and human thyreocytes incubated for 16 h in MDA-free medium after a 4-h MDA treatment. A 4-h exposure to 56, 100, and 180 microM MDA did not induce DNA lesions in primary cultures of cells from three rat organs, kidney, urinary bladder mucosa, and brain, which are resistant to MDA carcinogenic activity. Under the same experimental conditions any evidence of DNA damage was absent in primary kidney and urinary bladder cells from human donors. Taken as a whole the results of this work indicate that MDA is specifically activated to DNA-damaging reactive species by hepatocytes and thyreocytes in both rats and humans and thus suggest that liver and thyroid might be the targets of the carcinogenic activity of MDA also in humans.     

Correlation between induction of DNA fragmentation in urinary bladder cells from rats and humans and tissue-specific carcinogenic activity

Seven chemicals, six of which are known to induce epithelial neoplasms of the urinary bladder in rats, were assayed for their ability to induce DNA damage in primary cultures of rat and human cells from urinary bladder mucosa, and in urinary bladder, liver and kidney of intact rats. Significant dose-dependent increases of DNA fragmentation, as measured by the Comet assay, were obtained in cells from both rats and humans with the following concentrations of five test compounds: 2-naphthylamine and N-nitrosodi-n-butylamine 0.5 and 1 mM, phenacetin 2 and 4 mM, cyclophosphamide from 2 to 8 mM, and o-toluidine 16 and 32 mM. Nitrilotriacetic acid (1-4 mM), a rat bladder carcinogen, and 4-aminobiphenyl (0.125-0.5 mM), a bladder carcinogen in humans but not in rats, gave a weak positive response in rats cells and a more marked response in humans cells. In terms of DNA-damaging potency, 4-aminobiphenyl, cyclophosphamide, phenacetin and 4 nitrilotriacetic acid were more active in human than in rat cells, whereas the converse occurred with 2-naphthylamine. Consistently with the results observed in vitro statistically significant dose-dependent increases in the average frequency of DNA breaks were detected in the urinary bladder mucosa of rats given p.o. single doses corresponding to 14 and 12 LD50 of six of the seven test compounds; the only one which gave a substantially negative response was 4-aminobiphenyl. With the exception of N-nitrosodi-n-butylamine which caused DNA damage in liver and of phenacetin and nitrilotriacetic acid which caused damage in kidney in agreement with their tumorigenic activity, any substantial evidence of DNA lesions in these two organs was absent in rats treated with 12 LD50 of the other 4 test compounds. These findings give evidence that urinary bladder genotoxic carcinogens may be identified by the DNA damage/Comet assay using as targets cells of urinary bladder mucosa, and show that the effect may be quantitatively different in cells from rats and from human donors.     

Evaluation of flutamide genotoxicity in rats and in primary human hepatocytes

Flutamide, an effective competitive inhibitor of the androgen receptor used orally for palliative treatment of prostatic carcinoma and regulation of prostatic hyperplasia was evaluated for its genotoxic effects in the intact rat and in primary cultures of human hepatocytes. Negative responses were obtained in all the in vivo assays as well as in the in vitro assay. In rats given a single oral dose of 500 mg/kg flutamide, fragmentation and repair of liver DNA were absent, and no increase was observed in the frequency of micronucleated hepatocytes. In the liver of rats given flutamide as initiating agent at the dose of 500 mg/kg/week for 6 successive weeks, gamma-glutamyltraspeptidase-positive foci were detected only in 3 of 10 rats. There was no evidence of a promoting effect on the development of aberrant crypt foci in rats given 100 mg/kg flutamide on alternate days for 8 successive weeks. In primary cultures of human hepatocytes from one male and one female donor DNA fragmentation as measured by the Comet assays, and DNA repair synthesis as revealed by quantitative autoradiography, were absent after a 20 hr exposure to flutamide concentrations ranging from 18 to 56 microM. Taken as a whole, our results seem to indicate that flutamide is a non-genotoxic drug.     

Comparison of the sensitivity of human and rat hepatocytes to the genotoxic effects of metronidazole

Metronidazole (MNZ), an antiprotozoan and antibacterial agent, has been shown to yield DNA-damaging reactive species after nitroreductive biotransformation. The genotoxic effect of MNZ was studied in primary cultures of both rat and human hepatocytes. In millimolar concentrations MNZ produced DNA fragmentation, as measured by the alkaline elution technique, and unscheduled DNA synthesis, as evaluated by quantitative autoradiography, in rat hepatocytes. The amount of DNA damage was directly related to the dose and the length of exposure, was increased by hypoxia and GSH depletion, and was markedly reduced by inhibition of cytochrome P-450 activity. In the same experimental conditions human hepatocytes resulted constantly more resistant than rat hepatocytes to the genotoxic activity of MNZ. These findings suggest that the rat hepatocyte model might be an inappropriate predictor of nitroimidazoles genotoxicity.     

Genotoxicity of N-nitrosochlordiazepoxide in cultured mammalian cells

Chlordiazepoxide, a benzodiazepine derivative commonly used for the treatment of anxiety, was found to react with sodium nitrite in HCl aqueous solution yielding, at pH ranging from 0.5 to 5,N-nitrosochlordiazepoxide (NO-CDE). In the absence of a metabolic activation system, a dose-dependent frequency of DNA single-strand breaks was revealed by the alkaline elution technique in V79 cells exposed to subtoxic NO-CDE concentrations ranging from 33 to 330 microM. DNA lesions were only partially repaired within 48 hr, and their promutagenic character was demonstrated by the induction of 6-thioguanine resistance in the same cells. The genotoxicity of NO-CDE was confirmed by results obtained in metabolically competent primary cultures of both rat and human hepatocytes, which displayed similar dose-related amounts of DNA fragmentation and of DNA repair synthesis after treatment with concentrations ranging from 33 to 1000 microM. In conclusions similar to those which might occur in the stomach of a patient taking chlordiazepoxide the concentration of NO-CDE in the reaction mixture (50 microM) was of the same order as the concentrations found to induce a genotoxic effect in cultured mammalian cells.     

DNA breaks induced by micromolar concentrations of dimethylnitrosamine in liver primary cell cultures from untreated and phenobarbital treated rats

Direct genotoxic effects of the alkylating agent dimethylnitrosamine (DMN) have been difficult to detect in several short-term tests. We simplified our method to detect DNA breaks induced by DMN in rat liver primary cell cultures, and increased its sensitivity about 150 times by changing the conditions of ultracentrifugation and exposure to DMN. Additionally we increased 4 times the sensitivity of the improved assay by isolating hepatocytes from rats treated with phenobarbital (PB). Treatment for 24 h with 60 microM and 13.5 microM DMN of hepatocytes isolated from untreated and PB-treated rats, respectively, decreased the molecular weight of DNA by 50%. After 24 h exposure to 13.5 microM [14C]DMN, hepatocytes from PB-treated rats incorporated 3 times more radioactivity into trichloroacetic acid precipitable material than hepatocytes from untreated rats. Also PB-treatment increased remarkably cytotoxic effects of DMN while it did not modify the cytotoxicity nor the genotoxicity of the direct-acting alkylating agent N-methyl-N'-nitro-N-nitrosoguanidine. These results show that DMN is more genotoxic for hepatocytes from PB-treated rats, and suggest that the enhanced genotoxicity is probably due to an augmented metabolism of DMN by these cultures. Our improved assay of DNA breaks as an indicator of DMN genotoxicity is now as sensitive but faster to perform than hepatocyte-mediated mutagenesis. It could be used to explore genotoxic effects of other alkylating agents and the action of microsomal enzyme modifiers on genotoxicity.     

DNA damage in tissues of rat treated with potassium canrenoate

Potassium canrenoate (PC), a competitive aldosterone antagonist previously found to increase tumor incidence in rats and to produce genotoxic effects in in vitro systems, was examined in rats to acquire information on its genotoxic activity in vivo. Intragastric administration of 1/2 LD50 produced, as revealed by the Comet assay, a modest but statistically significant increase in the frequency of DNA lesions in liver but not in thyroid and bone marrow of male rats, and in thyroid and bone marrow but not in liver of female rats. In contrast with the frankly positive responses observed in primary cultures of rat hepatocytes (Martelli et al., Mutagenesis 14 (1999) 463-472) any evidence of DNA repair and micronuclei formation was absent in liver of rats treated with 1/2 LD50, and initiation of enzyme-altered liver preneoplastic lesions did not occur in the liver of rats given 100 mg/kg PC once a week for 6 successive weeks. A high and dose-dependent frequency of DNA lesions was found to occur in testes and ovaries of rats given single doses ranging from 1/8 to 1/2 LD50.     

DNA damage and micronuclei induced in rat and human kidney cells by six chemicals carcinogenic to the rat kidney

Six chemicals, known to induce kidney tumors in rats, were examined for their ability to induce DNA fragmentation and formation of micronuclei in primary cultures of rat and human kidney cells, and in the kidney of intact rats. Significant dose-dependent increases in the frequency of DNA single-strand breaks and alkali-labile sites, as measured by the Comet assay, and in micronuclei frequency, were obtained in primary kidney cells from both male rats and humans of both genders with the following subtoxic concentrations of five of the six test compounds: bromodichlorometane (BDCM) from 0.5 to 4 mM, captafol (CF) from 0.5 to 2 microM, nitrobenzene (NB) from 0.062 to 0.5 mM, ochratoxin A (OTA) from 0.015 to 1.215 microM, and trichloroethylene (TCE) from 1 to 4 mM. Benzofuran (BF), consistent with its carcinogenic activity for the kidney of female, but not of male rats, at concentrations from 0.125 to 0.5 mM gave positive responses in cells from females but did not induce DNA damage and increased the frequency of micronuclei in cells from males to a lower extent; in contrast, it was active in cells from humans of both genders. DNA-damaging and micronuclei-inducing potencies were similar in the two species. In agreement with these findings, statistically significant increases in the average frequency of both DNA breaks and micronucleated cells were obtained in the kidney of rats, given p.o. a single dose (1/2 LD50) of the six compounds, BF in this assay being more genotoxic in female than in male rats. Taken as a whole, these findings give further evidence that kidney carcinogens may be identified by short-term genotoxicity assays, using as target kidney cells, and show that the six chemicals tested produce, in primary cultures of kidney cells from human donors, effects similar to those observed in rats.     

Primary cultures of human urothelial cells for genotoxicity testing

A cell culture system with human-derived urothelial cells was established based upon previous experience with cultures of porcine urinary bladder epithelial cells. Human tissue specimens used were derived from urinary bladders (n = 17) or ureters (n = 50) of patients undergoing urological operations. The epithelial origin and differentiation status was evaluated by an immunohistochemical staining for cytokeratins 7, 8, 18, 19, and 20 for isolated and cultured cells. Specimens from human ureters were better suited for primary cell cultures of the urothelium than specimens from human urinary bladders. Successful attachment and proliferation were reached by 98% of the ureter specimens (urinary bladder: 71%) and confluency was reached by 78% of the ureter cultures (urinary bladder: 18%). In the first 14 d of culture the cytokeratin patterns of cultured cells were comparable to those of native mucosa cells. During prolonged cell culture the cytokeratin patterns of the human urothelial cells (HUC) changed into a beginning dedifferentiation: Cytokeratin (CK) 18 was only detectable in cell cultures cultured for more than 29 d, whereas CK 19 was not detectable at d 29. Cell cultures of primary human urothelial cells may be used for in vitro testing of cytotoxic or genotoxic effects.     

Investigations on organ-specific metabolism and genotoxic effects of the urinary bladder carcinogen N-nitrosobutyl-3-carboxypropylamine (BCPN) and its analogs N-nitrosodibutylamine (NDBA) and N-nitrosobutyl-4-hydroxybutylamine (4-OH-NDBA)

N-Nitrosodibutylamine (NDBA) and its omega-oxidized metabolites N-nitrosobutyl-4-hydroxybutylamine (4-OH-NDBA) and N-nitrosobutyl-3-carboxypropylamine (BCPN) are potent urinary bladder carcinogens. To study putative organ specific activation of BCPN, its alpha-oxidation by liver and urinary bladder microsomal fractions was investigated in comparison to NDBA and 4-OH-NDBA. Additionally, induction of DNA single strand breaks (SSB) was monitored in hepatocytes and in a human lymphoblastoid cell line (Namalva) in the presence and absence of external metabolic activation, including N-nitroso-t-butyl-n-butylamine as a negative control. BCPN was alpha-hydroxylated and dealkylated at both alkyl chains in small rates (about 1 nmol x mg protein-1 x 60 min-1) by microsomes from rat liver and pig urinary bladder epithelium. NDBA and 4-OH-NDBA were dealkylated at similarly low rates by pig urinary bladder microsomes, in strong contrast to the high debutylation rates observed for rat liver microsomes. Correspondingly, SSB induction by NDBA and 4-OH-NDBA was observed in Namalva cells with NDBA and 4-OH-NDBA in the presence of PB-induced rat liver microsomes but not with urinary bladder microsomes or without external activation. BCPN did not induce DNA-damage in Namalva cells (with or without external activation) or in rat hepatocytes. Significant induction of sister chromatid exchanges (SCEs) and micronuclei, however, was observed in Namalva cells after incubation with NDBA and BCPN. Our data suggest activation of BCPN via alpha-oxidation in the urinary bladder, even though activation rate in-vitro is so low that a positive response is not detectable by several short-term tests.     

Peroxisome proliferators induce apoptosis and decrease DNA synthesis in hepatoma cell lines

We examined the effects of various peroxisome proliferators (PPs) such as the hypolipidaemic agents clofibric acid (CLO), bezafibrate (BEZA), ciprofibrate (CIPRO) and nafenopin (NAFE) and the plasticizer di-(2-ethylhexyl)phthalate (DEHP) on peroxisomal enzyme activities, apoptosis and DNA synthesis in rat FaO and human HepG2 hepatoma cell lines. Both growing and confluent cultures were treated with PPs (250 microM) for 48 or 72 h. In accordance with our previous observations in PP-treated primary hepatocyte cultures of rat and human origin, the various PPs increased peroxisomal enzyme activities in rat FaO cells but not in human HepG2 cells. PPs strongly induced apoptosis in FaO cells. They did not affect TGFbeta-induced apoptosis, with the exception of DEHP and NAFE, respectively blocking and increasing induced apoptosis in confluent cultures. Moreover, PPs produced a minor, but significant, decrease in DNA synthesis in FaO cells. PPs also decreased DNA synthesis in growing HepG2 cells, and CLO, CIPRO and NAFE induced apoptosis in confluent HepG2 cultures. This is in opposition with the effects of PPs on primary hepatocyte cultures, i.e. inhibition of both spontaneous and TGFbeta-induced apoptosis and increases in DNA synthesis in rat hepatocytes, and unchanged mitosis-apoptosis balance in human hepatocytes.     

Regulation of mRNA expression of MDR1, MRP1, MRP2 and MRP3 by prototypical microsomal enzyme inducers in primary cultures of human and rat hepatocytes

The mRNA induction of various transporters by rifampicin (Rif), dexamethasone (Dex) and omeprazole (Ome) was investigated in primary cultures of cryopreserved human and rat hepatocytes. Analysis was performed by quantitative real-time RT-PCR using primers and TaqMan probes. In primary cultures of human hepatocytes, mRNA levels of MDR and MRP1 were increased by about 1.5 fold and 1.3 fold, respectively, by exposure to Rif at 2 to 50 microM as compared with 0.1% DMSO-treated controls. MRP2 mRNA levels in the same human hepatocytes were significantly increased by 1.2 to 1.8 fold by exposure to Rif at 50 microM as compared with controls. In primary cultures of rat hepatocytes, Mdr1a and Mdr1b mRNA levels were not increased or only slightly increased at 24 hr by exposure to any of the inducers at 2, 10 or 50 microM. Mrp2 mRNA levels in the same rat hepatocytes were significantly increased by 7 to 45 fold by exposure to Dex at 2 microM as compared with controls. Based on the species differences observed in the present study, primary cultures of cryopreserved hepatocytes from both the human and rat should be useful in preclinical drug development for evaluating candidate drugs for transporter induction.     

Immunohistochemistry of γ‐H2AX as a method of early detection of urinary bladder carcinogenicity in mice

Phosphorylated histone H2AX (γ‐H2AX) has been demonstrated as a DNA damage marker both in vitro and in vivo. We previously reported the effects of genotoxic carcinogens in the urinary bladder of rats by immunohistochemical analysis of γ‐H2AX using samples from 28‐day repeated‐dose tests. To evaluate the application of γ‐H2AX as a biomarker of carcinogenicity in the bladder, we examined species differences in γ‐H2AX formation in the urinary bladder of mice. Six‐week‐old male B6C3F₁ mice were treated orally with 12 chemicals for 4 weeks. Immunohistochemical analysis demonstrated that N‐butyl‐N‐(4‐hydroxybutyl)nitrosamine, p‐cresidine and 2‐acetylaminofluorene (2‐AAF), classified as genotoxic bladder carcinogens, induced significant increases in γ‐H2AX levels in the bladder urothelium. In contrast, genotoxic (2‐nitroanisole, glycidol, N‐nitrosodiethylamine and acrylamide) and non‐genotoxic (dimethylarsinic acid and melamine) non‐bladder carcinogens did not upregulate γ‐H2AX. Importantly, 2‐nitroanisole, a potent genotoxic bladder carcinogen in rats, significantly increased the proportion of γ‐H2AX‐positive cells in rats only, reflecting differences in carcinogenicity in the urinary bladder between rats and mice. Significant upregulation of γ‐H2AX was also induced by uracil, a non‐genotoxic bladder carcinogen that may be associated with cell proliferation, as demonstrated by increased Ki67 expression. 2‐AAF caused γ‐H2AX formation mainly in the superficial layer, together with reduced and disorganized expression of uroplakin III, unlike in rats, suggesting the mouse‐specific cytotoxicity of 2‐AAF in umbrella cells. These results suggest γ‐H2AX is a useful biomarker reflecting species differences in carcinogenicity in the urinary bladder.     

Assessment of unscheduled and replicative DNA synthesis in hepatocytes treated in vivo and in vitro with unleaded gasoline or 2,2,4-trimethylpentane

In a recent chronic inhalation exposure study, unleaded gasoline (UG) produced kidney tumors in male rats and liver tumors in female mice, but did not increase the incidence of liver tumors in male mice or rats of either sex. To examine the possible basis for this pattern of hepatocarcinogenesis, unscheduled DNA synthesis (UDS) as an indicator of genotoxic activity and replicative DNA synthesis (RDS) as an indicator of cell proliferation were measured in rat and mouse hepatocytes following in vivo and in vitro exposures to UG and 2,2,4-trimethylpentane (TMP), a nephrotoxic component of UG. Primary hepatocyte cultures, prepared from cells isolated from Fischer-344 rats, B6C3F1 mice, or human surgical material, were incubated with [3H]thymidine and the test agent. UDS was measured by quantitative autoradiography as net nuclear grains (NG). By similar methods, UDS and RDS (S-phase cells) were measured in hepatocytes isolated from rats and mice treated by gavage with TMP (500 mg/kg) or UG (100 to 5,000 mg/kg). A dose-related increase in UDS activity was observed in rat hepatocytes treated in vitro with 0.05 to 0.10% (v/v) UG. These doses were, however, toxic in both mouse and human hepatocyte cultures. Weak UDS activity was observed in hepatocytes isolated from male and female mice treated 12 hr previously with UG. No UDS was induced in rat hepatocytes treated in vivo or in vitro with TMP. Twenty- and fourfold increases in the percentage of cells in S-phase were observed 24 hr after treatment with TMP in male and female mice, respectively, as compared to a fivefold increase in male rats. UG increased the percentage of S-phase cells in male mice by ninefold but failed to induce RDS in females. Thus, there appears to be genotoxic compounds in UG that can be detected in cultured hepatocytes and in the livers of exposed mice. The lack of UDS activity in rat liver was consistent with the reported lack of liver tumors in chronically exposed rats. However, neither the UDS nor the RDS responses in mice exposed by gavage correlated to the sex-specific pattern of liver tumors observed in the 2-year bioassay.     

Comparison of 2,2-bis(bromomethyl)-1,3-propanediol induced genotoxicity in UROtsa cells and primary rat hepatocytes: Relevance of metabolism and oxidative stress

2,2-Bis(bromomethyl)-1,3-propanediol (BMP) is a brominated flame retardant used in urethane foams and polyester resins. In a two year dietary study, BMP caused neoplastic lesions at multiple sites including the urinary bladder of both rats and mice. However, liver was not a target tissue. We previously reported that BMP elicited oxidative DNA damage in a human uroepithelial cell line (UROtsa). The present in vitro study investigated the susceptibility of target (UROtsa cells) and non-target cells (primary rat hepatocytes) to BMP-induced genotoxicity. In contrast to hepatocytes, BMP exhibited greater genotoxic potential in UROtsa cells as evidenced by the concentration dependent increase in DNA strand breaks and DNA binding. Total content of intracellular GSH quantified in UROtsa cells (2.7 ± 1.0 nmol/mg protein) was 4 fold lower than that in hepatocytes (10.7 ± 0.3 nmol/mg protein). HPLC analysis indicated BMP was not metabolized and/or consumed in UROtsa cells at any of the concentrations tested (10–250 μM) but was extensively converted to a mono-glucuronide in hepatocytes. These results demonstrate that a target cell line such as UROtsa cells are more susceptible to BMP-induced DNA damage when compared to non-target cells. This increased susceptibility may relate to the deficiency of antioxidant and/or metabolic capabilities in UROtsa cells.     

Effect of Rodent Hepatocarcinogenic Peroxisome Proliferators on Fatty Acyl-CoA Oxidase, DNA Synthesis, and Apoptosis in Cultured Human and Rat Hepatocytes

The effects of the rodent hepatocarcinogens clofibric acid and ciprofibrate on the activity of the peroxisomal fatty acyl-CoA oxidase, DNA synthesis, and apoptosis were compared in cultured rat and human hepatocytes. Rat hepatocytes expressed a 10-fold greater level of the peroxisomal fatty acyl-CoA oxidase compared to human hepatocytes. At the highest concentration (1.0 mM), both drugs induced a two- to threefold increase in this enzyme activity in both rat and human hepatocytes. Ciprofibrate (0.1 and 0.2 mM) caused a twofold increase in DNA synthesis in rat hepatocytes, whereas clofibric acid had no effect on DNA synthesis in these cells. In contrast, increasing concentrations of both clofibric acid and ciprofibrate produced inhibition of DNA synthesis in human hepatocytes. By using the terminal transferase dUTP–biotin nick end labeling technique, it was observed that 0.1 and 0.2 mM clofibric acid and ciprofibrate suppressed transforming growth factor-β (TGFβ)-induced apoptosis by 50% in rat hepatocytes, but they had no effect on TGFβ-induced apoptosis in human hepatocytes. Although clofibric acid and ciprofibrate diminished TGFβ-induced apoptosis, they had no effect on the basal apoptotic levels in the rat hepatocyte cultures. However, both drugs significantly increased the percent of apoptotic cells in the human hepatocyte cultures. It is concluded that primary rat and human hepatocyte cultures respond differently to peroxisome proliferators. The differences in effects on DNA synthesis and apoptosis support the hypothesis that human liver cells are refractory to peroxisome proliferator-induced hepatocarcinogenesis.     

Human hepatocytes in genotoxicity assays

Human hepatocyte primary cultures, because of their comprehensive biotransformation capability, represent an experimental model particularly useful to gain direct information on the genotoxic risk of chemicals to humans. For this purpose they have been used in the last few years either as target cells to evaluate the induction of DNA damage and/or DNA repair synthesis, or as metabolic activation system in mutagenicity assays. The number of compounds so far tested is rather limited, and for the large majority of them the assays have been performed only on hepatocytes from a few donors. A comparison with the data obtained in rat hepatocytes indicates that quantitative differences in the genotoxic effects induced in cultures derived from different donors of the same species are usually greater than interspecies differences. However, the results.provided by some chemicals suggest the possibility that in certain cases rat hepatocytes might be inappropriate predictors of the genotoxic hazard for humans.     

Bgugaine, a pyrrolidine alkaloid from Arisarum vulgare, is a strong hepatotoxin in rat and human liver cell cultures

Toxicity of bgugaine, a pyrrolidine alkaloid extracted from the tubers of Arisarum vulgare, was studied in three different liver cell culture models: (1) the rat hepatocyte primary culture; (2) a liver epithelial cell line; and (3) the human hepatoblastoma cell line HepG2. Cytotoxicity was evaluated by LDH release, MTT reduction and MDA production. DNA fragmentation was analysed by flow cytometry or DNA gel-electrophoresis. In hepatocyte and epithelial cell cultures, drug toxicity appeared at 30 microM and was evaluated by an increase in LDH release, a decrease in MTT reduction and a higher level of MDA production. Bgugaine concentrations lower than 30 microM did not induce changes in these parameters. In HepG2 cells, bgugaine treatment also induced LDH release at concentrations of 40 and 50 microM. DNA fragmentation, analysed in the HepG2 cell line by flow cytometry, was observed in cultures exposed to 50 microM bgugaine. However, using DNA gel-electrophoresis, we demonstrated that lower bgugaine concentrations (10, 20 and 30 microM) also induced DNA damage. Our results show that: (1) bgugaine induces an important hepatotoxicity; (2) bgugaine toxicity is not mediated by a metabolic derivative; and (3) bgugaine induces a significant DNA damage. Therefore, our data suggest that the alkaloid bgugaine contained in Arisarum vulgarae may be involved in the toxicologic symptoms observed after consumption of this plant tubers by humans and animals.     

Correlation between induction of DNA fragmentation and micronuclei formation in kidney cells from rats and humans and tissue-specific carcinogenic activity

Five chemicals, known to induce kidney tumors in rats, were assayed for their ability to induce DNA damage and formation of micronuclei in primary cultures of rat and human kidney cells and in the kidney of intact rats. Significant dose-dependent increases of DNA fragmentation, as measured by the Comet assay, and of micronuclei frequency were obtained in primary kidney cells from both rats and humans with the following concentrations of the five test compounds: lead acetate (not tested for micronuclei induction) and potassium bromate from 0.56 to 1.8 mM, phenacetin from 1 to 3.2 mM, and 1, 4-dichlorobenzene and nitrilotriacetic acid from 1.8 to 5.6 mM. In terms of DNA-damaging potency all the five chemicals were more active in rat than in human kidney cells, whereas the potencies in inducing micronuclei formation were similar in the two species with the exception of 1,4-dichlorobenzene, which was slightly more potent in human than in rat cells. Consistently with the results observed in vitro, statistically significant increases in the average frequency of both DNA breaks and micronucleated cells were detected in the kidney of rats given po a single (12 LD50) or three successive daily doses (13 LD50) of the five test compounds. 4, 4'-Methylenedianiline, a carcinogen which does not induce kidney tumors in rats, gave negative responses in both in vitro and in vivo assays. These findings give evidence that kidney carcinogens may be identified by short-term genotoxicity assays using as target kidney cells and show that the five chemicals tested produce in primary cultures of kidney cells from human donors effects similar to those observed in rats.     

A comparative study of chemically induced DNA damage in isolated nasal mucosa cells of humans and rats assessed by the alkaline comet assay

Single-cell microgel electrophoresis (comet) assay was used to study genotoxic effects in human nasal mucosa cells and rat nasal and ethmoidal mucosa cells in vitro. Human cells were obtained from tissue samples of 10 patients (3 females/7 males), who underwent surgery (conchotomy) for treatment of nasal airway obstruction. Rat nasal mucosa cells were derived from male Sprague-Dawley rats. Cells were exposed for 1 h to either N-nitrosodiethanolamine (NDELA), epichlorohydrin (EPI), 1,2-epoxybutane (EPB), ethylene dibromide (EDB), or 1,2-dibromo-3-chloropropane (DBCP). Dimethyl sulfoxide (DMSO) was used as negative control. Alkaline comet assay was performed according to a standard protocol and DNA damage was quantified as Olive tail moment using image analysis system. All test substances induced an increase in DNA damage in human and rat cells. The absolute amount of DNA damage in rat nasal mucosa cells was usually higher than in ethmoidal mucosa cells. Human nasal mucosa cells were found to be less sensitive than rat mucosa cells to the genotoxic activities of DBCP (lowest effective concentration in human cells [LEC(human)]: 1.5, in rat cells [LEC(rat)]: 0.01 mM) and NDELA (LEC(human): 25, LEC(rat): 12.5 mM), whereas EPB-treated cells were almost equal (LEC(human) and LEC(rat) 0.78 mM). NDELA induced a marked concomitant cytotoxicity. For EPI (LEC(human) and LEC(rat): 0.097 mM) and EDB (LEC(human): 0.195, LEC(rat): 0.048 mM), pronounced interindividual differences were observed in human samples.