A new hepatoma cell line for toxicity testing at repeated doses.

Many cell models that are used to assess basic cytotoxicity show a good correlation with acute toxicity. However, their correlation with the toxicity seen following chronic in vivo exposure is less evident. The new human hepatoma cell line HBG BC2 possesses the capacity of being reversibly differentiated in vitro and of maintaining a relatively higher metabolic rate when in the differentiated state (3 weeks) as compared to HepG2 cells, and thus may allow the conduct of repeated toxicity testing on cells in culture. In order to evaluate the genetic background of HBG BC2 cells, the expression of selected genes was analyzed in untreated cultures and, in addition, the behavior of HBG BC2 cultures under conditions of repeated treatment was studied with acetaminophen as a test substance and coupled with the use of standard staining techniques to demonstrate toxicity. Results showed that cultures of HBG BC2 cells retained a capacity to undergo apoptosis and proliferation, allowing probable replacement of damaged cells in the culture monolayer. MTT reduction was used to evaluate the toxicity of acetaminophen, acetylsalicylic acid, perhexiline, and propranolol, after both single and repeated (3 times/week for 2 weeks) administration. Under the conditions of repeated treatment, cytotoxicity was observed at lower doses as compared to single administration. In addition, the lowest nontoxic doses were in the same range as plasma concentrations measured in humans under therapeutic use. Our results suggest that the new human hepatoma HBG BC2 cell line is of interest for the evaluation of cell toxicity under conditions of repeated administration.

Induction of DNA synthesis in mouse liver following increases of DNA adduct levels elicited by very low cumulative doses of the genotoxic hepatocarcinogen 7H-dibenzo[c,g]carbazole.

The purpose of this work was to investigate the administration of very low but repeated doses of a genotoxic carcinogen and an eventual correlation with cellular DNA synthesis. The compound 7H-dibenzo[c,g]carbazole is a genotoxic carcinogen in the mouse liver and was administered topically at the dose of 13.35 microg per animal every 2 days to give a total of 13 applications. Animals were sacrificed 48 hours after every 2 applications until the 10th treatment, then 48 hours after every treatment. Postulated genotoxic effects such as DNA adduct formation were detected by the 32P-post labeling assay. Liver sections were examined for microscopic changes and DNA synthesis. Results showed an increase of the total DNA adduct level in the liver throughout the study with a slowing down in the level after the sixth application of the compound. This change could correspond to the onset of DNA synthesis and to the moderate hepatocellular apoptosis which was observed. The DNA synthesis, which was considered to be secondary to the cytotoxicity induced by the high level of DNA adducts altering normal cellular activity, could also be the opportunity to fix the DNA adducts into heritable mutations. These results raise the question regarding the risk assessment in humans exposed regularly to very low doses of chemicals in the environment: for non-proliferating tissue, the regular accumulation of DNA adducts could remain silent until a "threshold level" is reached from which stimulation of the DNA synthesis may fix the DNA adducts into heritable mutations, eventually leading to tumors.

Use of primary cultures of rat hepatocytes to predict toxicity in the early development of new chemical entities.

The new strategies for development of pharmacologically interesting compounds pose some limitations for standard toxicity assessment approaches due to: (1) increase in the number of compounds to be tested and (2) decrease in the amount of substance available for testing. In vitro methods are thus the only way to overcome such limitations. In this communication we present a cell-based model, using primary rat hepatocyte cultures, which we have validated using 23 compounds of the MEIC list as well as several Synthélabo proprietary products, covering a wide range of therapeutic indications. Our results show that our in vitro model gives a sufficient prediction for general toxicity by the oral route of administration (up to 2-4 weeks of treatment) in the rat to aid in decisions during early development. We also suggest that the comparative evaluation of the different parameters of cell toxicity examined may point to potential organ-related toxicity which could be further studied either with more complex in vitro or in vivo models. In conclusion, our results show that cell-based models for toxicity can be used for general screening purposes to predict in vivo toxicity in the early development of new chemical entities.