Hepatotoxic effects of cyproconazole and prochloraz in wild-type and hCAR/hPXR mice.

The agricultural fungicides cyproconazole and prochloraz exhibit hepatotoxicity in rodent studies and are tumorigenic following chronic exposure. Both substances are suspected to act via a CAR (constitutive androstane receptor)/PXR (pregnane-X-receptor)-dependent mechanism. Human relevance of these findings is under debate. A 28-day toxicity study was conducted in mice with humanized CAR and PXR (hCAR/hPXR) with two dose levels (50 or 500 ppm) of both substances, using the model CAR activator phenobarbital as a reference. Results were compared to wild-type mice. A treatment-related increase in liver weights was observed for all three substances at least at the high-dose level. Changes in the expression of classic CAR/PXR target genes such as Cyp2b10 were induced by cyproconazole and phenobarbital in both genotypes, while prochloraz treatment resulted in gene expression changes indicative of additional aryl hydrocarbon receptor activation, e.g. by up-regulation of Cyp1a1 expression. Cyproconazole-induced effects on CAR-dependent gene expression, liver weight, and hepatic lipid accumulation were more prominent in wild-type mice, where significant genotype differences were observed at the high-dose level. Moreover, high-dose cyproconazole-treated mice from the wild-type group responded with a marked increase in hepatocellular proliferation, while hCAR/hPXR mice did not. In conclusion, our data demonstrate that cyproconazole and PB induce CAR/PXR downstream effects in hepatocytes in vivo via both, the murine and human receptors. At high doses of cyproconazole, however, the responses were clearly more pronounced in wild-type mice, indicating increased sensitivity of rodents to CAR agonist-induced effects in hepatocytes.

The time point of ß-catenin knockout in hepatocytes determines their response to xenobiotic activation of the constitutive androstane receptor.

The constitutive androstane receptor (CAR) controls the expression of drug-metabolizing enzymes and regulates hepatocyte proliferation. Studies with transgenic mice with an early postnatal conditional hepatocyte-specific knockout of the ß-catenin gene Ctnnb1 revealed that ß-catenin deficiency decreases the magnitude of induction of drug-metabolizing enzymes by CAR activators, abrogates zonal differences in the hepatocytes' susceptibility to these compounds, and impacts on hepatocyte proliferation. These data, however, do not allow distinguishing between effects caused by ß-catenin deficiency during postnatal liver development and acute effects of ß-catenin deficiency in the adult animal at the time point of CAR activation. Therefore, CAR activation was now studied in a different mouse model allowing for the hepatocyte-specific knockout of ß-catenin in adult mice. Treatment of these mice with 3mg/kg body weight of the model CAR activator 1,4-bis-[2-(3,5-dichloropyridyloxy)]benzene (TCPOBOP) confirmed previous findings related to the coordinate regulation of drug metabolism by ß-catenin and CAR. More importantly, the present study clarified that the impact of ß-catenin signaling on CAR-mediated enzyme induction in the liver is not merely due to developmental defects caused by a postnatal lack of ß-catenin, but depends on the presence of ß-catenin at the time point of xenobiotic treatment. The study also revealed interesting differences between the two mouse models: hepatic zonation of TCPOBOP-dependent induction of drug-metabolizing enzymes was restored in mice with late knockout of ß-catenin, and the strong proliferative response of female mice was exclusively abolished when using animals with a late ß-catenin knockout. This suggests a ß-catenin-dependent postnatal priming of hepatocytes during postnatal liver development, later affecting the proliferative response of adult animals to CAR-activating xenobiotics.