Protective effects of tiopronin against high fat diet-induced non-alcoholic steatohepatitis in rats

The role of the microsomal ethanol-oxidizing system (MEOS) in hepatic ethanol metabolism is reviewed, with focus on its constitutive, ethanol-inducible cytochrome P-4502E1 (2E1). The MEOS was purified and reconstituted using 2E1, phospholipids, and cytochrome P-450 reductase and shown to oxidize ethanol to acetaldehyde, mainly as a monooxygenase and secondarily via hydroxyl radicals, with transcriptional and posttranscriptional regulation. Polymorphism of 2E1 was recognized, and enzymology (including cofactors, role of lipids, inducers, and inhibitors) as well as cellular and tissue distribution were chartered. Physiological functions involve lipid metabolism and ketone utilization in starvation, obesity, and diabetes. The most significant role of 2E1 is its adaptive response to high blood ethanol levels with a corresponding acceleration of ethanol metabolism. The associated free radical production, however, contributes to liver injury in the alcoholic. Most importantly, 2E1 has a unique capacity to activate many xenobiotics (85 of which are listed) to hepatotoxic or carcinogenic products. Induction of 2E1 also results in enhanced production of acetaldehyde, a highly reactive and toxic metabolite. The proliferation of the endoplasmic reticulum associated with 2E1 induction is also accompanied by enhanced activity of other cytochrome P-450s, resulting in accelerated metabolism of, and tolerance to, other drugs, as well as increased degradation of retinol and its hepatic depletion. Some substrates and metabolites, however, are innocuous and may eventually be used as markers of heavy drinking. Recently discovered effective 2E1 inhibitors also have great therapeutic potential.

Non-alcohol-induced steatohepatitis (NASH) is characterized by elevated serum aminotransferase activities with hepatic steatosis, inflammation, and occasionally fibrosis that may progress to cirrhosis. No established treatment exists for this potentially serious disorder. Our aim was to conduct a pilot study to evaluate the safety and estimate the efficacy of ursodeoxycholic acid (UDCA) and clofibrate in the treatment of NASH. Forty patients were diagnosed with NASH based on a compatible liver biopsy with other causes of liver disease, including alcohol abuse, excluded by history, serum tests, and use of ultrasound. Twenty-four patients received 13 to 15 mg/kg/d of UDCA for 12 months. Sixteen patients with hypertriglyceridemia were placed on clofibrate, 2 g/day for 12 months. Twenty-five women and 15 men entered the study. Six of 40 patients (15%) withdrew because of side effects. Four additional patients were withdrawn because of noncompliance; one of them later required liver transplantation. In the UDCA group, the decreases in mean serum levels of alkaline phosphatase, alanine transaminase (ALT), and gamma-glutamyl transpeptidase (GGT) as well as histological grade of steatosis were significant. Among the patients treated with clofibrate, no change from baseline was found in mean ALT, aspartate transaminase (AST), GGT, bilirubin, triglycerides, and cholesterol, or in histological grade of steatosis, inflammation, or fibrosis after 12 months of treatment as compared with entry. Alkaline phosphatase activities decreased significantly from baseline. Despite the known lipid-lowering effects of clofibrate, it did not appear to be of clinical benefit in the treatment of NASH in this 1-year pilot study. However, treatment of NASH with UDCA for 12 months resulted in significant improvement in alkaline phosphatase, ALT, GGT, and hepatic steatosis. The possible benefit of UDCA therapy should be further investigated in the context of a randomized, controlled trial.