Deriving and testing of dysplastic murine hepatocytes: A new platform in liver cancer research.

Dysplastic hepatocytes (DH) represent altered hepatocytes with potential for malignant transformation. To date, most research on pathways to hepatocarcinogenesis has focused on use of "hepatoma" cell lines derived from hepatocellular carcinoma (HCC). We describe a novel technique for deriving/culturing DH and demonstrate their utility for functional studies in vitro, compared to primary hepatocytes (PH) and HCC. PH and DH were prepared by portal vein collagenase perfusion from C57BL/6J mice. DH were subsequently subjected to FACS. HCC from diethylnitrosamine (DEN)-injected mice were mechanically isolated. Cell cycle analyses were performed by flow cytometry and PCNA immunohistochemistry. To establish utility of DH, we studied pathways of p53 turnover, apoptosis and cell proliferation using pfithrin-α (PFT) and nutlin-3. Like PH, DH were minimally proliferative compared to HCC. Only 30±0.03% of DH were in G2/M phase versus 51±0.01% of HCC; this difference corroborated with PCNA-immunostaining of dysplastic nodules from DEN-injected mice. In DH and HCC, nutlin-3 suppressed p53 mRNA, induced p53 and mdm2 activation but paradoxically resulted in increased anti-apoptotic and proliferative activity. Primary murine DH display distinctive biological characteristics compared with PH and HCC. As an intermediate cell type to HCC, they offer a new pathobiologically relevant primary cell culture system with which to interrogate the molecular changes in hepatocarcinogenesis.

Testosterone regulation of cyclin E kinase: A key factor in determining gender differences in hepatocarcinogenesis.

BACKGROUND AND AIM: While gender differences in hepatocellular carcinoma (HCC) are profound, the mechanism is unclear. Using castration and hormone replacement strategies, we tested whether these gender differences are attributable to testosterone or estradiol/progesterone effects on cell cycle regulators and p53. METHODS: We studied dysplastic liver and HCCs in intact and castrated diethylnitrosamine-injected C57BL/6J male and female mice, with or without hormonal replacement. Effects of sex steroids on proliferation and survival of primary hepatocytes and primary HCC cells were also characterized. RESULTS: Diethylnitrosamine-injected female mice displayed fewer dysplastic foci and slower onset of HCC than male mice, with smaller/more differentiated tumors and fewer metastases. Castration of diethylnitrosamine-injected male mice reduced cyclin E kinase and augmented hepatocyte apoptosis compared with intact male mice; estradiol/progesterone enhanced these effects. In intact female mice, cyclin E kinase activity was less than in males; testosterone administered to ovariectomized female mice upregulated cyclin E, increased cyclin E kinase, and accelerated hepatocarcinogenesis. In vitro, testosterone increased expression of cell cycle regulators (cyclin D1, cyclin E, and cyclin-dependent kinase 2) and reduced p53 and p21, which enhanced hepatocyte viability. In contrast, estradiol both suppressed hepatocyte cell cycle markers, upregulated p53 and reduced viability of hepatocytes and HCC cells. CONCLUSIONS: Testosterone is the positive regulator of hepatocyte cell cycle via cyclin E, while estradiol plays a negative role by effects of p53 and p21. Together, both sex hormones determine the male predominance of gender differences in hepatocarcinogenesis.