HGF-, EGF-, and dexamethasone-induced gene expression patterns during formation of tissue in hepatic organoid cultures.

Corticosteroids, hepatocyte growth factor (HGF), and epidermal growth factor (EGF) play important roles in hepatic biology. We have previously shown that these molecules are required for formation of tissue with specific histology in complex organoid cultures. Dexamethasone suppresses growth and induces hepatocyte maturation; HGF and EGF are needed for formation of the nonepithelial elements. All three are needed for formation of the biliary epithelium. The gene expression patterns by which corticosteroids, HGF, and EGF mediate their effects in hepatic tissue formation are distinct. These patterns affect many gene families and are described in detail. In terms of main findings, dexamethasone induces expression of both HNF4 and C/EBPalpha, essential transcription factors for hepatocyte differentiation. It suppresses hepatocyte growth by suppressing many molecules associated with growth in liver and other tissues, including IL-6, CXC-chemokine receptor, amphiregulin, COX-2, HIF, etc. HGF and EGF induce all members of the TGF-beta family. They also induced multiple CNS-related genes, probably associated with stellate cells. Dexamethasone, as well as HGF and EGF, induces expression of HNF6-beta, associated with biliary epithelium formation. Combined addition of all three molecules is associated with mature histology in which hepatocyte and biliary lineages are separate and HNF4 is expressed only in hepatocyte nuclei. In conclusion, the results provide new and surprising information on the gene expression alterations by which corticosteroids, HGF, and EGF exert their effects on formation of hepatic tissue. The results underscore the usefulness of the organoid cultures for generating information on histogenesis, which cannot be obtained by other culture or whole animal models.

Beta-catenin antisense studies in embryonic liver cultures: role in proliferation, apoptosis, and lineage specification.

BACKGROUND & AIMS: Wnt/beta-catenin pathway activation occurs during liver growth in hepatoblastomas, hepatocellular cancers, and liver regeneration. The aim of this study was to investigate the role of beta-catenin, a key component of the Wnt pathway, in liver development as well as its normal distribution in developing liver. METHODS: Embryonic liver cultures and beta-catenin antisense phosphorodiamidate morpholino oligomer (PMO) were used to elucidate the role of beta-catenin in liver development. Livers from embryos at 10 days of gestational development were cultured in the presence of antisense or control PMO for 72 hours and analyzed. RESULTS: Beta-catenin shows stage-specific localization and distinct distribution compared with known markers in developing liver. A substantial decrease in beta-catenin protein was evident in the organs cultured in the presence of antisense. Beta-catenin inhibition decreased cell proliferation and increased apoptosis in these organ cultures. Presence of antisense resulted in loss of CK19 immunoreactivity of the bipotential stem cells. Beta-catenin inhibition also promoted c-kit immunoreactivity of the hepatocytes. CONCLUSIONS: We conclude that the PMO antisense to beta-catenin effectively inhibits synthesis of its protein. Beta-catenin modulates cell proliferation and apoptosis in developing liver. It may play a significant role in early biliary lineage commitment of the bipotential stem cells and also seems to be important in hepatocyte maturation.

Hepatocytes undergo phenotypic transformation to biliary epithelium in organoid cultures.

Organoid cultures of hepatocytes in the presence of hepatocyte growth factor (HGF) and epidermal growth factor (EGF) display characteristic histologic organization. Biliary epithelium covers the surface of the tissue exposed to the culture medium. Hepatocytes, stellate cells and endothelial cells compose the underlying structures. In order to investigate the origin of the biliary epithelial cells in the organoid cultures, we utilized the retrorsine/DPPIV system of hepatocyte transplantation to create hybrid livers in which clones of DPPIV hepatocytes colonize variable portions of the lobules. We demonstrate that, as others have shown, biliary epithelium in this in vivo system remains that of the recipient (DPPIV negative) rat. Hepatocytes are the only cells positive for the DPPIV marker enzyme in the hybrid livers. Organoid cultures were prepared from the hybrid livers. Overall, 46.82% of the hepatocytes placed into culture were positive for DPPIV at time zero (after isolation). At 21 days in culture, 47.54% of the biliary epithelium on the surface of the organoid cultures was positive for DPPIV. Since the only DPPIV cells inoculated in the cultures were hepatocytes, this finding demonstrates that, in the conditions of the organoid cultures, hepatocytes do undergo phenotypic transition to biliary epithelial cells.

Hepatocyte growth factor induces Wnt-independent nuclear translocation of beta-catenin after Met-beta-catenin dissociation in hepatocytes.

Hepatocyte growth factor (HGF) and Wnt signaling pathways have been shown to be important in embryogenesis and carcinogenesis. The aim of this study was to elucidate the mechanism of functional similarities observed in the two pathways. We used normal rat liver, primary hepatocyte cultures and a dominant-negative Met expression system to study the effect of HGF on Wnt pathway components. We demonstrate novel association of beta-catenin and Met, a tyrosine kinase receptor of HGF, at the inner surface of the hepatocyte membrane. HGF induces dose-dependent nuclear translocation of beta-catenin in primary hepatocyte cultures that is Wnt independent. The source of beta-catenin for translocation in hepatocytes is the Met-beta-catenin complex, which appears to be independent of the E-cadherin-beta-catenin complex. To test the functionality of this association, we used a dominant-negative Met expression system that expresses only the extracellular and transmembrane regions of the beta-subunit of Met. A loss of Met-beta-catenin association resulted in abrogation of nuclear translocation of beta-catenin upon HGF stimulation. This event is tyrosine phosphorylation dependent, and the association of Met and beta-catenin is crucial for this event. We conclude that the HGF causes similar redistribution of beta-catenin as Wnt-1 in the hepatocytes and that this effect is attributable to subcellular association of Met and beta-catenin. The intracellular kinase domain of Met is essential for tyrosine phosphorylation and nuclear translocation of beta-catenin. Part of the multifunctionality of HGF might be attributable to nuclear beta-catenin and the resulting target gene expression.