Activation of estrogen receptor alpha and ERbeta by 4-methylbenzylidene-camphor in human and rat cells: comparison with phyto- and xenoestrogens.

4-Methylbenzylidene-camphor (4-MBC) is an organic sunscreen that protects against UV radiation and may therefore help in the prevention of skin cancer. Recent results on the estrogenicity of 4-MBC have raised concerns about a potential of 4-MBC to act as an endocrine disruptor. Here, we investigated the direct interaction of 4-MBC with estrogen receptor (ER) alpha and ERbeta in a series of studies including receptor binding, ER transactivation and functional tests in human and rat cells. 4-MBC induced alkaline phosphatase activity, a surrogate marker for estrogenic activity, in human endometrial Ishikawa cells. Interestingly, 4-MBC induced weakly ERalpha and with a higher potency ERbeta mediated transactivation in Ishikawa cells at doses more than 1 microM, but showed no distinct binding affinity to ERalpha or ERbeta. In addition, 4-MBC was an effective antagonist for ERalpha and ERbeta. In an attempt to put 4-MBC's estrogenic activity into perspective we compared binding affinity and potency to activate ER with phyto- and xenoestrogens. 4-MBC showed lower estrogenic potency than genistein, coumestrol, resveratrol, bisphenol A and also camphor. Analysis of a potential metabolic activation of 4-MBC that could account for 4-MBC's more distinct estrogenic effects observed in vivo revealed that no estrogenic metabolites of 4-MBC are formed in primary rat or human hepatocytes. In conclusion, we were able to show that 4-MBC is able to induce ERalpha and ERbeta activity. However, for a hazard assessment of 4-MBC's estrogenic effects, the very high doses of 4-MBC required to elicit the reported effects, its anti-estrogenic properties as well as its low estrogenic potency compared to phytoestrogens and camphor has to be taken into account.

Species-specific toxicity of diclofenac and troglitazone in primary human and rat hepatocytes.

Troglitazone was withdrawn from the market shortly after approval for diabetes type II therapy because of strong hepatotoxic effects in man that could not be predicted from regulatory animal or in vitro studies. Another pharmaceutical that is regularly associated with adverse effects on the liver, sometimes leading to acute liver failure, is the widely used non-steroidal anti-inflammatory drug (NSAID) diclofenac. Since the underlying molecular mechanisms are not yet fully known, we treated primary rat and human hepatocyte monolayer cultures for 24h with different doses of troglitazone and diclofenac to analyze species differences related to toxicity in vitro. Metformin an antidiabetic drug which does not cause severe adverse reactions served as negative control. Human hepatocytes showed a higher sensitivity to troglitazone than rat hepatocytes, while diclofenac-induced cytotoxicity at fairly similar concentrations. By co-treatment with specific inhibitors for cytochrome P450 (CYP) 2C and CYP3A - the major phase I enzymes involved in liver xenobiotic metabolism - we could confirm the prominent role of CYP3A in the bioactivation of troglitazone as well as the role of CYP3A and CYP2C in the activation of diclofenac. Inhibition of these enzymes increased the viability of treated cells in both species. Furthermore, we were able to demonstrate marked species differences in gene expression patterns of troglitazone treated rat and human hepatocytes. In contrast to rat hepatocytes, human cells showed distinct upregulation of various CYPs, regulators of xenobiotic metabolism and marker genes for oxidative stress. In contrast, gene expression alterations in rat and human hepatocytes treated with Diclofenac were rather similar. Altogether our study showed that species-specific effects as well as indications for the mode of action of compounds can be addressed by the use of primary hepatocyte cultures from various species in combination with gene expression profiling.

Alternatives in pharmaceutical toxicology: global and focussed approaches--two case studies.

Safety testing of potential drugs has been and will continue to be a challenging task for the toxicologist in the pharmaceutical industry. We present two examples for the use of target-specific cell models to detect and assess species-specific toxicity. In the first example, adrenal models based on primary cells as well as a permanent human adrenal cell line were used. Both cell systems enabled a good prediction of adrenal effects in rodents, non-rodents and humans. The second example made use of primary hepatocytes. In this project, a potential drug candidate showed unexpected toxicity in vitro as well as species-specific cytochrome P450 (CYP) induction in vivo. We therefore analysed CYP induction and gene expression signatures in rat and human hepatocytes as well as in samples from in vivo animal toxicity studies. By this approach, the rat hepatocyte model correctly predicted the effects observed in rats and the in vitro/in vivo comparison enabled a solid extrapolation of consequences in humans. These examples demonstrate that an intelligent testing strategy, using alternative methods, can enable a meaningful safety assessment for humans by adding a ''tailor-made'' range of technologies to ''classic'' toxicological methods.