In order to elucidate whether GH resistance plays a causal role in the establishment and
development of liver fibrosis, or rather represents a major consequence thereof, we challenged mice lacking the Growth hormone receptor gene (Ghr-/-, a model for GH resistance) by crossing them with Mdr2 knockout mice (Mdr2-/-), a mouse model of inflammatory cholestasis and liver fibrosis. Ghr-/-;Mdr2-/- mice showed elevated serum markers associated with liver damage and cholestasis, extensive bile duct proliferation and increased collagen deposition relative to Mdr2 -/- mice, thus suggesting a more severe liver fibrosis phenotype. Additionally, Ghr-/-;Mdr2-/- mice had a pronounced down-regulation of hepato-protective genes Hnf6, Egfr and Igf-1, and significantly
increased levels of ROS STA-9090 solubility dmso and apoptosis in hepatocytes, compared to control mice. Moreover, single knockout mice (Ghr-/-) fed with a diet containing 1% cholic acid displayed an increase in hepatocyte ROS production, hepatocyte apoptosis and bile infarcts compared to their wildtype littermates, indicating that loss of Ghr renders hepatocytes more susceptible to toxic bile acid accumulation. Surprisingly, and despite their severe fibrotic phenotype, Ghr-/-;Mdr2-/- mice displayed a significant decrease in tumour incidence compared to Mdr2-/- mice, indicating that loss of Ghr signaling may slow the progression from fibrosis/cirrhosis to cancer
in the liver. Conclusion: Our findings suggest that GH resistance ZD1839 molecular weight dramatically exacerbates liver L-gulonolactone oxidase fibrosis in a mouse model of inflammatory cholestasis, therefore suggesting that GH resistance plays a causal role in the disease and provides a novel target for the development of liver fibrosis treatments. (Hepatology 2014;) “
“Bissig KD, Wieland SF, Tran P, Isogawa M, Le TT, Chisari FV, et al. Human liver chimeric mice provide a model for hepatitis B and C virus infection and treatment. J Clin Invest 2010;120:924-930. (Reprinted with permission.) A paucity of versatile small animal models of hepatitis B virus (HBV) and hepatitis C virus (HCV) infection has been an impediment to both furthering understanding of virus biology and testing antiviral therapies. We recently described a regulatable system for repopulating the liver of immunodeficient mice (specifically mice lacking fumaryl acetoacetate hydrolase [Fah], recombination activating gene 2 [Rag2], and the γ-chain of the receptor for IL-2 [Il-2rγ]) with human hepatocytes. Here we have shown that a high transplantation dose (3 × 106 to 5 × 106 human hepatocytes/mouse) generates a higher rate of liver chimerism than was previously obtained in these mice, up to 95% human hepatocyte chimerism. Mice with a high level of human liver chimerism propagated both HBV and HCV, and the HCV-infected mice were responsive to antiviral treatment.