Inappropriate activation of the Wnt/b-catenin signaling has been implicated in the development of hepatocellular carcinoma (HCC), but exactly how b-catenin works remains to be elucidated. To identify, in vivo, the target genes of b-catenin in the liver, we have used the suppression subtractive hybridization technique and transgenic mice expressing an activated b-catenin in the liver that developed hepatomegaly. We identified three genes involved in glutamine metabolism, encoding glutamine synthetase (GS), ornithine aminotransferase (OAT) and the glutamate transporter GLT-1. By Northern blot and immunohistochemical analysis we demonstrated that these three genes were specifically induced by activation of the b-catenin pathway in the liver. In different mouse models bearing an activated bcatenin signaling in the liver known to be associated with hepatocellular proliferation we observed a marked upregulation of these three genes. The cellular distribution of GS and GLT-1 parallels b-catenin activity. By contrast no up-regulation of these three genes was observed in the liver in which hepatocyte proliferation was induced by a signal-independent of b-catenin. In addition, the GS promoter was activated in the liver of GS +/LacZ mice by adenovirus vector-mediated b-catenin overexpression. Strikingly, the overexpression of the GS gene in human HCC samples was strongly correlated with b-catenin activation. Together, our results indicate that GS is a target of the Wnt/b-catenin pathway in the liver. Because a linkage of the glutamine pathway to hepatocarcinogenesis has already been demonstrated, we propose that regulation of these three genes of glutamine metabolism by b-catenin is a contributing factor to liver carcinogenesis.
We examined the interplay between the insulin/IGF-1-and b-catenin-regulated pathways, both of which are suspected to play a role in hepatocarcinogenesis. Insulin and IGF-1 stimulated the transcription of a Lef/Tcfdependent luciferase reporter gene by 3 ± 4-fold in HepG2 cells. This stimulation was mediated through the activation of phosphatidylinositol 3-kinase (PI 3-K)/Akt and the inhibition of glycogen synthase kinase-3b (GSK3b) since the eects of insulin and IGF-1 were inhibited by dominant-negative mutants of PI 3-K or Akt and an uninhibitable GSK-3b. Together with inhibiting GSK-3b, insulin and IGF-1 increased the cytoplasmic levels of bcatenin. The PI 3-K/Akt/GSK-3b pathway was not the sole to mediate insulin and IGF-1 stimulation of Lef/Tcfdependent transcription. The Ras signalling pathway was also required as (i) the stimulatory eects of insulin and IGF-1 were inhibited by dominant-negative Ras or the MEK1 inhibitor PD98059 and (ii) activated Ha-Ras or constitutively active MEK1 synergized with catalytically inactive GSK-3b to stimulate Lef/Tcf-dependent transcription. This study provides the ®rst evidence that insulin and IGF-1 stimulate the b-catenin pathway through two signalling cascades bifurcating downstream of PI 3-K and involving GSK-3b inhibition and Ras activation. These ®ndings demonstrate for the ®rst time the ability of insulin and IGF-1 to activate the b-catenin pathway in hepatoma cells and thereby provide new insights into the role of these factors in hepatocarcinogenesis. Oncogene (2001) 20, 252 ± 259.
Inhibition of receptor-interacting protein kinase 1 improves experimental non-alcoholic fatty liver disease
Background & Aims: In non-alcoholic fatty liver disease (NAFLD), hepatocytes can undergo necroptosis, a regulated form of necrotic cell death mediated by the receptorinteracting protein kinase (RIPK) 1. We herein assessed the potential of RIPK1 and its downstream effector mixed lineage kinase domain-like protein (MLKL), as therapeutic targets and markers of activity in NAFLD. Methods: C57/BL6J-mice were fed a normal chow diet (NCD) or high fat diet (HFD). The effect of RIPA-56, a highly specific inhibitor of RIPK1, was evaluated in either a prophylactic or a curative treatment of HFD-fed mice, and in primary human steatotic hepatocytes. RIPK1 and MLKL concentrations were measured in the serum of patients with NAFLD. Results: Both prophylactic and curative treatments of HFD-fed mice with RIPA-56, caused a down-regulation of MLKL and a reduction of liver injury, inflammation and fibrosis, characteristic of non-alcoholic steatohepatitis (NASH), as well as of steatosis. This latter effect was reproduced by treating primary human steatotic hepatocytes with RIPA-56 or necrosulfonamide (NSA), a specific inhibitor of human MLKL, and by knocking out (KO) MLKL in fat-loaded AML-12 mouse hepatocytes. MLKL KO in steatotic hepatocytes, caused an activation of the mitochondrial respiration, and an increase in b-oxidation. Along with MLKL decreased activation, RIPK3-KO mice exhibited increased activities of the liver mitochondrial respiratory chain complexes in experimental NASH. In patients with NAFLD, serum concentrations of RIPK1 and MLKL increased in correlation with the activity. Conclusion: The inhibition of RIPK1 improves NASH features in HFD-fed mice and reverses steatosis by an MLKL-dependent mechanism that involves at least partly an increase in mitochondrial respiration. RIPK1 and MLKL are potential serum markers of activity and promising therapeutic targets in NAFLD.
Origins and functions of liver myofibroblasts
Myofibroblasts combine the matrix-producing functions of fibroblasts and the contractile properties of smooth muscle cells. They are the main effectors of fibrosis in all tissues and make a major contribution to other aspects of the wound healing response, including regeneration and angiogenesis. They display the de novo expression of α-smooth muscle actin. Myofibroblasts, which are absent from the normal liver, are derived from two major sources: hepatic stellate cells (HSCs) and portal mesenchymal cells in the injured liver. Reliable markers for distinguishing between the two subpopulations at the myofibroblast stage are currently lacking, but there is evidence to suggest that both myofibroblast cell types, each exposed to a particular microenvironment (e.g. hypoxia for HSC-MFs, ductular reaction for portal mesenchymal cell-derived myofibroblasts (PMFs)), expand and exert specialist functions, in scarring and inflammation for PMFs, and in vasoregulation and hepatocellular healing for HSC-MFs. Angiogenesis is a major mechanism by which myofibroblasts contribute to the progression of fibrosis in liver disease. It has been clearly demonstrated that liver fibrosis can regress, and this process involves a deactivation of myofibroblasts, although probably not to a fully quiescent phenotype. This article is part of a Special Issue entitled: Fibrosis: Translation of basic research to human disease.
Liver fibrosis expanding from portal tracts and vascular remodeling are determinant factors in the progression of liver diseases to cirrhosis. In the present study, we examined the potential contribution of portal myofibroblasts (PMFs) to the vascular changes leading to cirrhosis. The analyses of liver cells based on the transcriptome of rat PMFs, compared to hepatic stellate cell HSC‐derived myofibroblasts in culture, identified collagen, type XV, alpha 1 (COL15A1) as a marker of PMFs. Normal liver contained rare COL15A1‐immunoreactive cells adjacent to the bile ducts and canals of Hering in the portal area. A marked increase in COL15A1 expression occurred together with that of the endothelial marker, von Willebrand factor, in human and rat liver tissue, at advanced stages of fibrosis caused by either biliary or hepatocellular injury. In cirrhotic liver, COL15A1‐expressing PMFs adopted a perivascular distribution outlining vascular capillaries proximal to reactive ductules, within large fibrotic septa. The effect of PMFs on endothelial cells (ECs) was evaluated by in vitro and in vivo angiogenesis assays. PMF‐conditioned medium increased the migration and tubulogenesis of liver ECs as well as human umbilical vein ECs and triggered angiogenesis within Matrigel plugs in mice. In coculture, PMFs developed intercellular junctions with ECs and enhanced the formation of vascular structures. PMFs released vascular endothelial growth factor (VEGF)A‐containing microparticles, which activated VEGF receptor 2 in ECs and largely mediated their proangiogenic effect. Cholangiocytes potentiated the angiogenic properties of PMFs by increasing VEGFA expression and microparticle shedding in these cells. Conclusion: PMFs are key cells in hepatic vascular remodeling. They signal to ECs through VEGFA‐laden microparticles and act as mural cells for newly formed vessels, driving scar progression from portal tracts into the parenchyma. (Hepatology 2015;61:1041–1055)
A Role for Nuclear Factor κB in the Antiapoptotic Function of Insulin
We previously reported that insulin activates nuclear factor B (NF-B) in Chinese hamster ovary (CHO)-R cells overexpressing wild-type insulin receptors (IRs) through a pathway requiring IR tyrosine kinase and Raf-1 kinase activities. We now investigated whether the activation of NF-B by insulin could serve an antiapoptotic function. Insulin (10 ؊9 -10 ؊7 M) inhibited apoptosis induced by serum withdrawal in CHO-R cells in a concentration-dependent manner. Insulin antiapoptotic signaling: (i) was dependent on IR number and IR tyrosine kinase activity since it was reduced in parental CHO cells and was abolished in CHO-Y2 cells overexpressing IRs mutated at Tyr 1162/1163 ; (ii) was, like insulin activation of NF-B, dependent on Raf-1 but not on mitogen-activated protein kinase activity since both processes were decreased by the dominant-negative Raf-1 mutant Raf-C4 whereas they persisted in mitogen-activated protein kinase-depleted cells; and (iii) required NF-B activation since it was decreased by proteasome inhibitors and the dominant-negative IB-␣ (A32/36) mutant and was mimicked by overexpression of the NF-B c-Rel subunit. We also show that insulin antiapoptotic signaling but not insulin activation of NF-B involved phosphatidylinositol 3-kinase (PI 3-kinase), as supported by the inhibition of the former but not of the latter process by the PI 3-kinase inhibitor LY294002. Inhibition of both NF-B and PI 3-kinase totally abolished insulin antiapoptotic signaling. Thus insulin exerts a specific antiapoptotic function which is dependent on IR tyrosine kinase activity and is mediated by both a Raf-1-dependent pathway that leads to NF-B activation and a PI 3-kinase-dependent pathway.
Recent evidence indicates that growth hormone (GH) is involved in liver regeneration. To test whether insulin-like growth factor I (IGF-I) mediates this effect, we studied liver regeneration induced by partial hepatectomy in liver-specific IGF type 1 receptor knockout (LIGFREKO) mice. The absence of IGF-1R caused a significant decrease in hepatocyte proliferation in males (-52%), but not in females, as assessed by Ki67 immunohistochemistry. Cyclin D1 and cyclin A protein levels in the livers of LIGFREKO males were only half those in controls, indicating that cyclin induction during liver regeneration is dependent on IGF-1R signaling. Analyzing the signaling cascade initiated by IGF-1R, we observed a lack of IRS-1 induction in LIGFREKO livers. In contrast, the induction of IRS-2 synthesis was similar in LIGFREKO and control groups, suggesting the existence of differential regulation of IRS synthesis during liver regeneration. Regenerating livers from LIGFREKO animals also showed significantly less activated ERKs than controls. Our findings demonstrate that IGF-1R makes a significant contribution to liver regeneration. Using the LIGFREKO model, we provide new evidence that IGF-1R/IRS-1/ERK signaling may be the intracellular pathway controlling the cell cycle via cyclin D1 and cyclin A in the regenerating liver.
Constitutive activation of the ras proto-oncogene is a frequent and early event in colon cancers, but the downstream nuclear targets are not fully understood. The Cdx-1 and Cdx-2 homeobox genes play crucial roles in intestinal cell proliferation and di erentiation. In addition, Cdx-2 is a colonic tumour-suppressor gene, whereas Cdx-1 has oncogenic potential. Here, we show that constitutive activation of ras alters Cdx-1 and Cdx-2 expression in human colonic Caco-2 and HT-29 cells that harbour a normal ras proto-oncogene. Oncogenic ras downregulates Cdx-2 through activation of the PKC pathway and a decline in activity of the Cdx-2 promoter AP-1 site. This decline results from a PKC-dependent decrease in the relative expression of c-Jun, an activator of Cdx-2 transcription, compared to c-Fos, an inhibitor of Cdx-2. Unlike Cdx-2, Cdx-1 is upregulated by oncogenic ras and this e ect is mediated by activation of the MEK1 pathway. These results indicate that oncogenic ras activation has opposite e ects on Cdx-1 and Cdx-2 expression through distinct signalling pathways and they provide the ®rst evidence for a functional link between ras activation and the downregulation of the Cdx-2 tumour-suppressor gene in colon cancer cells.
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