Effects of triclocarban on the transcription of estrogen, androgen and aryl hydrocarbon receptor responsive genes in human breast cancer cells.

Triclocarban (TCC) is an antimicrobial agent that is used in detergents, soaps and other personal hygiene products. Similarly to triclosan the widespread use of TCC has raised concerns about its endocrine potential. In luciferase-based reporter assays TCC has been shown to enhance estrogenic and androgenic activities following cellular coexposure with estrogen or dihydrotestosterone, respectively. The present study demonstrates that although coexposure with TCC enhances the estrogenic and androgenic readout of luciferase-based reporter cell lines such as HeLa9908 and MDA-kb2, it fails to act as a xenoandrogen on transcriptional level, nor does it induce cell proliferation in the estrogen sensitive E-screen. In addition TCC did not alter the expression of estrogen responsive genes in human mammary carcinoma MCF-7 cells exposed to 17ß-estradiol, bisphenol A, butylparaben or genistein. However, TCC was shown to interfere with the regulon of the aryl hydrocarbon receptor (AhR) as TCC showed a costimulatory effect on transcription of CYP1A1 and CYP1B1, effectively lowering the transcriptional threshold for both genes in the presence of estrogens. It thus seems, that while the induction of the respective luciferase reporter assays by TCC is an unspecific false positive signal caused by luciferase stabilisation, TCC has the potential to interfere with the regulatory crosstalk of the estrogen receptor (ER) and the AhR regulon.

MYC-regulated genes involved in liver cell dysplasia identified in a transgenic model of liver cancer.

Foci of liver cell dysplasia (LCD) are distinct morphological entities and may evolve into hepatocellular carcinomas (HCCs). While most HCCs overexpress c-Myc, its role in LCD remains uncertain. Therefore, a c-Myc transgenic model of HCC was investigated to understand the genetic events forcing liver cells into dysplasia and subsequent malignant transformation. Specifically, whole genome scans enabled fingerprinting of genes at different stages of disease, ie LCD and HCC, while laser microdissected LCD lesions were used to validate regulation of candidate genes by quantitative real-time RT-PCR, ie Mybbp1a, Rps7, Rps19, Rpl10a, Skp1a, Tfdp1, Nhp2, and Bola2. EMSA band shift assays confirmed c-Myc DNA binding at regulatory sequences of candidate gene-specific promoters. Additionally, published ChIP-seq data helped to define the candidate genes as c-Myc bona fide targets. Treatment of the human hepatoma cell line HepG2 with hepatic growth factor (Hgf) caused c-Myc protein induction and transcriptional up-regulation of candidate genes, albeit at different levels when individual genes were compared. A significant increase of HepG2 entering the G1-phase was associated with up-regulation of the candidate genes in an Hgf concentration-dependent matter. Finally, we confirmed regulation of candidate genes in patients' samples with low- and high-grade dysplasia and HCC staged T1 to T3, while their expression was unchanged in focal nodular hyperplasia and hepatic adenoma, therefore asserting the diagnostic value and clinical significance of these candidate genes. Overall, novel c-Myc targeted genes were identified and may contribute to hepatocyte transformation by altering cell cycle control, thereby contributing to c-Myc's oncogenic activity.