The present study examined the roles of peroxisome proliferator-activated receptors (PPAR) in activation of hepatic stellate cells (HSC), a pivotal event in liver fibrogenesis. RNase protection assay detected mRNA for PPAR␥1 but not that for the adipocyte-specific ␥2 isoform in HSC isolated from sham-operated rats, whereas the transcripts for neither isoforms were detectable in HSC from cholestatic liver fibrosis induced by bile duct ligation (BDL). Semi-quantitative reverse transcriptasepolymerase chain reaction confirmed a 70% reduction in PPAR␥ mRNA level in HSC from BDL. Nuclear extracts from BDL cells showed an expected diminution of binding to PPAR-responsive element, whereas NF-B and AP-1 binding were increased. Treatment of culturedactivated HSC with ligands for PPAR␥ (10 M 15-deoxy-⌬ 12,14 -PGJ 2 (15dPGJ 2 ); 0.1ϳ10 M BRL49653) inhibited DNA and collagen synthesis without affecting the cell viability. Suppression of HSC collagen by 15dPGJ 2 was abrogated 70% by the concomitant treatment with a PPAR␥ antagonist (GW9662). HSC DNA and collagen synthesis were inhibited by WY14643 at the concentrations known to activate both PPAR␣ and ␥ (>100 M) but not at those that only activate PPAR␣ (<10 M) or by a synthetic PPAR␣-selective agonist (GW9578). 15dPGJ 2 reduced ␣1(I) procollagen, smooth muscle ␣-actin, and monocyte chemotactic protein-1 mRNA levels while inducing matrix metalloproteinase-3 and CD36. 15dPGJ 2 and BRL49653 inhibited ␣1(I) procollagen promoter activity. Tumor necrosis factor ␣ (10 ng/ml) reduced PPAR␥ mRNA, and this effect was prevented by the treatment with 15dPGJ 2 . These results demonstrate that HSC activation is associated with the reductions in PPAR␥ expression and PPAR-responsive element binding in vivo and is reversed by the treatment with PPAR␥ ligands in vitro. These findings implicate diminished PPAR␥ signaling in molecular mechanisms underlying activation of HSC in liver fibrogenesis and the potential therapeutic value of PPAR␥ ligands for liver fibrosis.
Depletion of peroxisome proliferator-activated receptor ␥ (PPAR␥) accompanies myofibroblastic transdifferentiation of hepatic stellate cells (HSC), the primary cellular event underlying liver fibrogenesis. The treatment of activated HSC in vitro or in vivo with synthetic PPAR␥ ligands suppresses the fibrogenic activity of HSC. However, it is uncertain whether PPAR␥ is indeed a molecular target of this effect, because the ligands are also known to have receptor-independent actions. To test this question, the present study examined the effects of forced expression of PPAR␥ via an adenoviral vector on morphologic and biochemical features of culture-activated HSC. The vector-mediated expression of PPAR␥ itself is sufficient to reverse the morphology of activated HSC to the quiescent phenotype with retracted cytoplasm, prominent dendritic processes, reduced stress fibers, and accumulation of retinyl palmitate. These effects are abrogated by concomitant expression of a dominant negative mutant of PPAR␥ that prevents transactivation of but not binding to the PPAR response element. PPAR␥ expression also inhibits the activation markers such as the expression of ␣-smooth muscle actin, type I collagen, and transforming growth factor 1; DNA synthesis; and JunD binding to the activator protein-1 (AP-1) site and AP-1 promoter activity. Inhibited JunD activity by PPAR␥ is not due to reduced JunD expression or JNK activity or to a competition for p300. But it is due to a JunD-PPAR␥ interaction as demonstrated by co-immunoprecipitation and glutathione S-transferase pull-down analysis. Further, the use of deletion constructs reveals that the DNA binding region of PPAR␥ is the JunD interaction domain. In summary, our results demonstrate that the restoration of PPAR␥ reverses the activated HSC to the quiescent phenotype and suppresses AP-1 activity via a physical interaction between PPAR␥ and JunD.
Liver fibrosis, a wound-healing response to a variety of chronic stimuli, is characterized by excessive deposition of extracellular matrix (ECM) proteins, of which type I collagen predominates. This alters the structure of the liver leading to organ dysfunction. The activated hepatic stellate cell (HSC) is primarily responsible for excess collagen deposition during liver fibrosis. Two important aspects are involved in mediating the fibrogenic response: first the HSC becomes directly fibrogenic by synthesizing ECM proteins; second, the activated HSC proliferates, effectively amplifying the fibrogenic response. Although the precise mechanisms responsible for HSC activation remain elusive, substantial insight is being gained into the molecular mechanisms responsible for ECM production and cell proliferation in the HSC. The activated HSC becomes responsive to both proliferative (platelet-derived growth factor) and fibrogenic (transforming growth factor-beta[TGF-beta]) cytokines. It is becoming clear that these cytokines activate both mitogen-activated protein kinase (MAPK) signaling, involving p38, and focal adhesion kinase-phosphatidylinositol 3-kinase-Akt-p70 S6 kinase (FAK-PI3K-Akt-p70(S6K)) signaling cascades. Together, these regulate the proliferative response, activating cell cycle progression as well as collagen gene expression. In addition, signaling by both TGF-beta, mediated by Smad proteins, and p38 MAPK influence collagen gene expression. Smad and p38 MAPK signaling have been found to independently and additively regulate alpha1(I) collagen gene expression by transcriptional activation while p38 MAPK, but not Smad signaling, increases alpha1(I) collagen mRNA stability, leading to increased synthesis and deposition of type I collagen. It is anticipated that by understanding the molecular mechanisms responsible for HSC proliferation and excess ECM production new therapeutic targets will be identified for the treatment of liver fibrosis.
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