Hepatocytic AP-1 and STAT3 contribute to chemotaxis in alphanaphthylisothiocyanate-induced cholestatic liver injury.

The development of cholestatic liver injury (CLI) involves inflammation, but the dominant pathway mediating the chemotaxis is not yet established. This work explored key signaling pathway mediating chemotaxis in CLI and the role of Kupffer cells in the inflammatory liver injury. Probe inhibitors T-5224 (100 mg/kg) for AP-1 and C188-9 (100 mg/kg) for STAT3 were used to validate key inflammatory pathways in alpha-naphthylisothiocyanate (ANIT, 100 mg/kg)-induced CLI. Two doses of GdCl3 (10 mg/kg and 40 mg/kg) were used to delete Kupffer cells and explore their role in CLI. Serum and liver samples were collected for biochemical and mechanism analysis. The liver injury in ANIT-treated mice were significantly increased supported by biochemical and histopathological changes, and neutrophils gathering around the necrotic loci. Inhibitor treatments down-regulated liver injury biomarkers except the level of total bile acid. The chemokine Ccl2 increased by 170-fold and to a less degree Cxcl2 by 45-fold after the ANIT treatment. p-c-Jun and p-STAT3 were activated in the group A but inhibited by the inhibitors in western blot analysis. The immunofluorescence results showed AP-1 not STAT3 responded to inhibitors in ANIT-induced CLI. With or without GdCl3, there was no significant difference in liver injury among the CLI groups. In necrotic loci in CLI, CXCL2 colocalized with hepatocyte biomarker Albumin, not with the F4/80 in Kupffer cells. Conclusively, AP-1 played a more critical role in the inflammation cascade than STAT3 in ANIT-induced CLI. Hepatocytes, not the Kupffer cells released chemotactic factors mediating the chemotaxis in CLI.

Fenofibrate reverses liver fibrosis in cholestatic mice induced by alpha-naphthylisothiocyanate.

Cholestatic liver fibrosis occurs in liver injuries accompanied by inflammation, which develops into cirrhosis if not effectively treated in early stage. The aim of the study is to explore the effect of fenofibrate on liver fibrosis in chronic cholestatic mice. In this study, wild-type (WT) and Pparα-null (KO) mice were dosed alpha-naphthylisothiocyanate (ANIT) diet to induce chronic cholestasis. Induced liver fibrosis was determined by pathological biomarkers. Then fenofibrate 25 mg/kg was orally administrated to mice twice/day for 14 days. Serum and liver samples were collected for analysis of biochemistry and fibrosis. In WT mice, cholestatic biomarkers were increased by 5-8-fold and the expression of tissue inhibitors of metalloproteinases 1 (TIMP-1), Monocyte chemoattractant protein 1 (MCP-1), Collagen protein I (Collagen I) was increased by more than 10-fold. Fenofibrate significantly downgraded the biochemical and fibrotic biomarkers. In Western blot analysis, levels of collagenI and alpha-smooth muscle actin (α-SMA) were strongly inhibited by fenofibrate. In KO mice, liver fibrosis was induced successfully, but no improvement after fenofibrate treatment was observed. These data showed low-dose fenofibrate reverses cholestatic liver fibrosis in WT mice but not in KO mice, suggesting the dependence of therapeutic action on peroxisome proliferator-activated receptor alpha (PPARα). The study offers an additional therapeutic strategy for cholestatic liver fibrosis in practice.

PPARα mediates night neon light-induced weight gain: role of lipid homeostasis.

Rationale: Light pollution leads to high risk of obesity but the underlying mechanism is not known except for the influence of altered circadian rhythm. Peroxisome proliferator-activated receptor α (PPARα) regulates lipid metabolism, but its role in circadian-related obesity is not clear. Methods: Wild-type (WT) and Ppara-null (KO) mice on a high-fat diet (HFD) were treated with neon light at night for 6 weeks. Body weights were recorded and diet consumption measured. The hypothalamus, liver, adipose and serum were collected for mechanism experimentation. Results: WT mice on a HFD and exposed to night neon light gained about 19% body weight more than the WT control mice without light exposure and KO control mice on a HFD and exposed to night neon light. The increase in adipose tissue weight and adipocyte size led to the differences in body weights. Biochemical analysis suggested increased hepatic lipid accumulated and increased transport of lipid from the liver to peripheral tissues in the WT mice that gained weight under neon light exposure. Unlike KO mice, the expression of genes involved in lipid metabolism and the circadian factor circadian locomotor output cycles kaput (CLOCK) in both liver and adipose tissues were elevated in WT mice under neon light exposure. Conclusions: PPARα mediated weight gain of HFD-treated mice exposed to night neon light. More lipids were synthesized in the liver and transported to peripheral tissue leading to adaptive metabolism and lipid deposition in the adipose tissue. These data revealed an important mechanism of obesity induced by artificial light pollution where PPARα was implicated.

[The cholestatic fibrosis induced by α-naphthylisothiocyanate in mice and the inflammation pathway].

Objective: To explore the development of cholestatic fibrosis induced by α-naphthylisothiocyanate (ANIT) and the inflammation pathways. Methods: Fifteen 129/Sv mice weighing (23±2) g were randomly divided into 2 groups: control group (n=5) and experiment group (n=10). The control group was fed commercial chow diet and the experiment group was fed the same diet supplemented with 0. 05% ANIT. Five mice in the experiment group were sacrificed on day 14 and 28 respectively. The gallbladder, serum and liver samples were collected. Biochemical indicators of cholestasis were detected following the procedures in the kit. Liver injury was evaluated by histopathological. Hepatic fibrosis and inflammatory response were analyzed by Q-PCR and WB. Results: Compared with the control group, total bile acid (TBA), the main cholestasis biomarker, was increased from (3. 2±0. 9) µmol/L to (31. 6±4. 3) µmol/L in A-D14 group. AST and ALT, the biomarkers of liver injury, were also increased significantly (P＜0. 05). The expression levels of fibrotic factor tissue inhibitors of metalloproteinases 1 (TIMP-1), monocyte chemoattractant protein 1 (MCP-1) and collagen protein I (Collagen I) were higher than those of control group (P＜0. 05). The expressions of fibrosis protein Collagen I and α-SMA were also up-regulated. The collagen fibers of the liver were largely deposited and the liver fibrosis occurred (P＜0. 05). The expression of inflammatory factors was higher than the control group, JNK, c-Jun and STAT3 were activated (P＜0. 05). In A-D28 group, except AST, matrix metalloproteinases 2 (MMP-2) and Collagen I indicators were slightly decreased, other indicators of cholestasis, liver injury, liver fibrosis and inflammation continued to be up-regulated or stable (P＜0. 05). Conclusion: After 14-day treatment with 0. 05% ANIT diet, significant cholestatic liver fibrosis occurred in mice. After 28 days of treatment, cholestasis liver fibrosis kept stable. The JNK inflammatory pathway played a crucial role in the development of liver fibrosis.

Therapeutic action against chronic cholestatic liver injury by low-dose fenofibrate involves anti-chemotaxis via JNK-AP1-CCL2/CXCL2 signaling.

BACKGROUND: Fenofibrate was reported to be beneficial for cholestasis in combination with ursodeoxycholic acid. However, its therapeutic action as single therapy for chronic cholestasis and the underlying mechanism are not known. METHODS: In the present study, wild-type (WT) mice were administered a 0.05% ANIT diet to mimic chronic cholestatic liver injury. Mice were dosed fenofibrate 25 mg/kg twice every day for 10 days to investigate the therapeutic action of fenofibrate on chronic cholestatic liver injury. Ppara-null (KO) mice were used to explore PPARα's role in the therapeutic outcome. RESULTS: Fenofibrate, administered at 25 mg/kg twice daily, substantially reversed ANIT-induced chronic cholestatic liver injury shown by biochemical and pathological end points. The modifications of bile acid metabolism were found to be adaptive responses. The JNK-AP1-CCL2/CXCL2 axis was activated in all the mice administered ANIT which developed chronic cholestatic liver injury. But it was substantially decreased by fenofibrate in WT mice rather than that in KO mice. CONCLUSIONS: Low-dose fenofibrate reversed chronic cholestatic liver injury in mice. The therapeutic action was dependent on PPARα activation and occurred by inhibiting chemotaxis via the JNK-AP1-CCL2/CXCL2 signaling. These data provided an exciting basis for optimization of therapeutic fenofibrate regimen in the clinic. Additionally, they suggested anti-chemotaxis of low-dose fenofibrate in single therapy to treat cholestatic liver diseases.

Basal PPARα inhibits bile acid metabolism adaptation in chronic cholestatic model induced by α-naphthylisothiocyanate.

Cholestasis is one of the most challenging diseases to be treated in current hepatology. However little is known about the adaptation difference and the underlying mechanism between acute and chronic cholestasis. In this study, wild-type and Pparα-null mice were orally administered diet containing 0.05% ANIT to induce chronic cholestasis. Biochemistry, histopathology and serum metabolome analysis exhibited the similar toxic phenotype between wild-type and Pparα-null mice. Bile acid metabolism was strongly adapted in Pparα-null mice but not in wild-type mice. The Shp and Fxr mRNA was found to be doubled in cholestatic Pparα-null mice compared with the control group. Western blot confirmed the up-regulated expression of FXR in Pparα-null mice treated with ANIT. Inflammation was found to be stronger in Pparα-null mice than those in wild-type mice in chronic cholestasis. These data chain indicated that bile acid metabolism and inflammation signaling were different between wild-type and Pparα-null mice developing chronic cholestasis, although their toxic phenotypes could not be discriminated. So basal PPARα cross-talked with FXR and inhibited bile acid metabolism adaptation in chronic cholestasis.