Cholestatic liver diseases are characterized by impaired hepatocellular secretion of bile, resulting in intracellular accumulation of bilirubin, bile acids and cholesterol. Bile duct ligation (BDL) causes complete blockage of cholesterol excretion, and it is well known that hyperlipidemia develops in obstructive jaundice. Bile acids are the major products of cholesterol metabolism in the liver, and act as physiological detergents that facilitate absorption, transport, disruption of lipid-soluble fats and vitamins; furthermore it also aids in the excretion of lipids. Retention and accumulation of toxic, hydrophilic bile salts stimulates the production of proinflammatory cytokines and enhances apoptosis which leads to hepatocellular damage 12. Apoptosis is an integral part of many biological processes, including embryonic development, metamorphosis, hormone-dependent atrophy, and in chemical-induced cell death 34.

Fibrates are frequently used in the treatment of hyperlipidemia and are generally effective in lowering elevated plasma triglyceride and cholesterol levels 5. They exert multiple effects on lipid metabolism pathways by activating peroxisome proliferator-activated receptor alpha (PPARα), a specific ligand inducible transcription factor which controls gene expression through peroxisome proliferators response elements (PPREs) 6. PPARα agonists modulate cholesterol metabolism pathways in the liver 7. Indeed, fibrates suppress bile acid synthesis, the major pathway of cholesterol elimination from the body 89. Induction of PPARα increases the size and the number of hepatocytes within the first few days of exposure. During this time, spontaneous hepatocyte apoptosis is suppressed within the intact liver 10. Rodent primary hepatocytes successfully recapitulate the early response to PP exposure observed in vivo. This shows suppression of spontaneous apoptosis after PP exposure, as well as apoptosis induced TGF beta and fas is PPARα dependent 1112. Therefore, long-term induction of PPARα results in hepatomegaly and increases hepatocellular hyperplasia and consequently carcinogenesis in liver 1012. PPARα activation leads to the enhanced apoptosis in normal liver 1314. But its effects on apoptosis in cholestatic liver are unknown.

Though the reduction of bile salts by induction of PPARα has been evaluated in variety of studies, there is no evidence about the effects of short-term PPARα induction in cholestatic liver. It can be assumed that bile salt retention and altered cholesterol metabolism play central roles in obstructive jaundice. Therefore, PPARα induction may attenuate hepatocellular damage. The aim of the present study is to investigate the effects of short term fenofibrate treatment, a PPARα receptor agonist, on hepatocellular damage, oxidative stress, apoptosis and the levels of proinflammatory cytokines.

No deaths were observed during the experiment. All animals with BDL were obviously jaundiced 3 days after the operation. The jaundice was confirmed by measuring the serum total bilirubin concentration on 7^th day after BDL (Table 1). BDL results in severe bile acid-induced liver injury. BDL is associated with intrahepatic bile acid overload and consequent liver injury.

The administration of peroxisome proliferators results in a marked increase in the number and size of peroxisomes and size of the liver 51011. Furthermore; long-term administration of peroxisome proliferators causes hepatocellular carcinoma in rats and mice 51219. Long-term pharmacologic exposure of patients to the hypolipidemic drugs gemfibrosil, and clofibrate, which are potent rodent peroxisome proliferators, has not revealed any increased risk of hepatocellular cancer or others 520. For this reason, we designed this experiment in order to evaluate the short term effects of fenofibrate treatment for its effects in decreasing bile production and cholesterol synthesis.

The most important factors for obstructive jaundice are accumulation of bilirubin, bile acids, and cholesterol in liver 1. Bile acid synthesis has been reported to increase after BDL in animals. Weis and Dietschy 21 showed that after acute bile duct obstruction, cholesterol synthesis increased five fold. It has been demonstrated that cholesterol 7α-hydroxylase activities, catalyzes the first and rate-limiting step in the major pathway for bile acid biosynthesis from cholesterol homeostasis, increased significantly after obstructive jaundice 22. Fibrates inhibit bile acid synthesis, the major pathway of cholesterol elimination from the body, by reducing cholesterol 7α-hydoxylase gene (CYP7A1) and sterol 27-hydoxylase gene (CYP27A1) expression in rodents 8 and 7α-hydroxylation rate in humans 9. Le Jossic-Corcos et al. 7 showed that fibrates decreased cholesterol efflux, cholesterol conversion into bile acids and cholesterol ester storage in rat hepatocytes. In our study, TBA levels in fenofibrate treatment group were significantly lower than control group. In addition, the fibrates exerted their effects through lowering serum total bilirubin levels (P < 0.01). It's well known that fenofibrates increases the conjugation of bilirubin and glucoronoid. Fenofibrates might have decreased the direct bilirubin levels.

In our study, liver enzymes increased after BDL. Although fenofibrate treatment decreased the levels of these enzymes, the levels have still remained high when compared with sham group. This might be a result of short treatment period with fenofibrate.

In histological examination, fenofibrate mediated PPARα activation significantly decreased lobar and confluent necrosis. Nevertheless, histological parameters remained high when compared to sham operated group.

Hepatocellular apoptosis is a common result of accumulation of bile, bile salts and cholesterol 123. Apoptosis occurs at a constant rate in the liver and this process is believed to be a means by which old and damaged cells are eliminated. If not eliminated, cells having DNA damage could potentially become transformed by further mitogenic stimulation and DNA mutations 2223. Nevertheless; inappropriate apoptosis plays an important role in many diseases. In our study enhanced apoptosis is observed following BDL.

There are various studies stating that PPARα activation may increase 14 or decrease apoptosis 1011. On the other hand, according to our knowledge, the effects of fenofibrate on enhanced apoptosis in the setting of cholestasis have not been studied. Our study shows that PPARα activation decreases apoptosis in an experimental model of cholestasis. PPARα agonists activate nuclear factor kappa B (NF-κB) in the rat and mouse liver, but not in the hamster. Rats and mice are sensitive to hepatocellular hyperplastic effects of PPARα ligands. It has also been shown that NF-κB has an anti-apoptotic activity in several cell types, including hepatic cell lines. Cosulich et al. 2425 demonstrated that the response of NF-κB to peroxisome proliferators by inhibiting apoptosis in hepatocytes was provided by use of a dominant negative form of a subunit IkappaB kinase (IKK)-2 complex that is critical for activity of the IκB kinase. Ductal proliferation is the one of the changes occurred in obstructive jaundice 26. In our study the number of bile ducts significantly increased in rats with obstructive jaundice. The number of bile ducts increased with fenofibrate treatment. Activation of PPAR-α might have affected the tolerability of cholestasis in the increase of the number of bile ducts which may due to hepatocellular proliferation.

Proinflammatory cytokines, such as TNF-α, and IL-1 beta enhance liver damage in cholestasis. In our study, fenofibrate treatment resulted in a significant decrease in proinflammatory cytokine levels. Portal inflammation and interface hepatitis significantly increased 7 day following the BDL. At the same time serum levels of TNF-α and IL-1 β in rats with obstructive jaundice showed significant increases. Fenofibrate treatment decreased histopathological findings of inflammation, and decreased the cytokine levels significantly. PPARα has been demonstrated to act as a negative regulator of genes involved in the inflammatory response by antagonizing the activity of transcription factors, such as activated protein-1 expression, partly by direct interaction with proteins such as p65 and c-Jun 27. The induction of PPARα may have resulted in decreased inflammation through altered acute phase reactants.

Increased activation of Kupffer cells after obstructive jaundice affects not only inflammation but also the oxidative injury. MDA which is the end product of oxidative injury and lipid peroxidation increased in obstructive jaundice. In our study MDA levels significantly increased after BDL, also. This increase significantly decreased after fenofibrate treatment. Oxidative injury has decreased due to the increased level of antioxidant enzymes 28 as a result of PPAR-α activation.

Short-term induction of nuclear receptor PPARα by fenofibrate decreases hepatocellular necrosis, oxidative damage and inflammation and consequently hepatic damage. Furthermore, although these results suggest a beneficial effect of fenofibrate, the administration of these drugs in the treatment of cholestatic patients still remains to be a matter of debate 293031 and needs further experimental and clinical studies. Especially; the alteration in the bile production and induction of bile duct proliferation are important points that the researchers should pay attention for the use of these drugs in the treatment of obstructive jaundice.

The author(s) declare that they have no competing interests.

MC, MK and TK participated in the conception and design of the study, preparation of the manuscript and practical performance. BS carried out collection and analysis of data and practical performance. SU performed critical review process of the manuscript. OA carried out biochemical study. MA and OE carried out pathological examination. All authors read and approved the manuscript.