Role of oxidative stress in the pathogenesis of alcohol-induced liver disease.

Chronic alcohol consumption is a well-known risk factor for liver disease, which represents a major cause of morbidity and mortality worldwide. The pathological process of alcohol-induced liver disease is characterized by a broad spectrum of morphological changes ranging from steatosis with minimal injury to more advanced liver damage, including steato-hepatitis and fibrosis/cirrhosis. Experimental and clinical studies increasingly show that the oxidative damage induced by ethanol contribute in many ways to the pathogenesis of alcohol hepatotoxicity. This article describes the contribution of oxidative mechanisms to liver damage by alcohol.

Molecular chaperone Hsp90 as a target for oxidant-based anticancer therapies.

Hsp90 is a molecular chaperone involved in the stabilization of many oncoproteins that are required for the acquisition and maintenance of the so-called six major hallmarks of cancer cells. Various strategies have, therefore, been developed to inhibit the chaperone activity of Hsp90 and induce cancer cell death through the destabilization of its client proteins. Among these strategies, we have shown that generation of oxidative stress leads to the cleavage and deactivation of Hsp90. Because cancer cells are often deficient in antioxidant enzymes and exhibit higher basal levels of reactive oxygen species (ROS) than their normal counterparts, inducing a selective oxidative stress may be a promising approach for cancer treatment. Thus, many redox-modulating agents have, therefore, been developed or are undergoing clinical trials and Hsp90 represents a new target for oxidative stress-generating agents. The purpose of this article is to review the current state of knowledge about Hsp90 and the use of oxidative stress-generating agents in cancer treatment. We will illustrate the review with some of our results concerning the effects of oxidative stress on Hsp90 using various oxidative stress-generating systems based on different quinones in combination with a well-known reducing agent (i.e., ascorbate). Our results show that oxidative stress provokes the cleavage of Hsp90 in CML cells, as well as the degradation of its client protein Bcr-Abl and the deactivation of its downstream signaling pathways, namely MAPK and STAT5. Overall, these results highlight the potential interest of using oxidative stress to target Hsp90.

Cryopreservation of rat precision-cut liver slices by ultrarapid freezing: influence on phase I and II metabolism and on cell viability upon incubation for 24 hours.

Several cryopreservation methods for precision-cut rat liver slices (PCLS) have been proposed, allowing a short-term (a few hours) maintainance of viability and functionality upon thawing. The aim of the present study was to test the metabolic capacity of PCLS cryopreserved by an ultrarapid method. The biotransformation of paracetamol to its glucuronide and sulfate conjugates and of midazolam to its hydroxylated metabolites was studied in thawed PCLS incubated for 24 hours at 37 degrees C in Williams' medium E. In addition, protein levels of the key enzymes involved in these metabolic reactions, i.e. UGT1A1, ST1A1, CYP2E1 and CYP3A2 were determinated. In addition, biological markers of cell function (ATP and glycogen levels) and toxicity (LDH leakage in the medium) were also measured. Compared to controls (non cryopreserved PCLS), CYP3A2 activity and content and CYP2E1 content were maintained at the same level all along the incubation, whereas paracetamol glucuronidation and sulfation dropped to 24 and 21% of the control value, respectively, immediately after thawing. Freezing-thawing conditions also modified cell functionality, leading to a lower intracellular ATP and glycogen content, and an increase in cell lysis, as shown by LDH released in the medium. The results of this study suggest that cryopreserved PCLS are able to maintain some phase I activities for 24 hours after thawing whereas some phase II metabolic capacities are not maintained.

Role of protein phosphorylation in the inhibition of protein synthesis caused by hypoxia in rat hepatocytes.

Hypoxia causes a rapid and reversible inhibition of translation in freshly isolated rat hepatocytes. This inhibition is neither due to an ATP loss nor to an increase in cell death. Because protein synthesis is mainly regulated by reversible phosphorylation of initiation and/or elongation factors, we investigated whether translation inhibition by hypoxia may be related to changes in the phosphorylation status of proteins. Whatever the incubation conditions, three phosphoreactive bands (molecular weights 220, 129, and 83 kDa) were detected by antiphosphotyrosine antibodies. The phosphorylation in the 129- and 83-kDa bands, however, was significantly and progressively decreased under hypoxia. Although this time-dependent decrease was sensitive to changes in oxygen tension, it occurred after the early protein synthesis inhibition caused by hypoxia. Moreover, sodium orthovanadate prevented tyrosine dephosphorylation in hypoxic cells, but did not restore the depressed protein synthesis caused by hypoxia. Under aerobic conditions, orthovanadate inhibited the synthesis of proteins, confirming that protein phosphorylation is a major mechanism involved in translational regulation. Once again, this inhibitory effect occurred only after 90 minutes of incubation whereas hypoxia inhibits the protein synthesis at the beginning of the incubation. Labeling cells with [33-32P]-ortho-phosphoric acid allowed detection of several phosphorylated proteins that appeared under hypoxia. Because they were not recognized by the phosphotyrosine antibodies, we suggest that serine/threonine residues of key proteins may be the putative hypoxic targets.

Reoxygenation after cold hypoxic storage of cultured precision-cut rat liver slices: effects on cellular metabolism and drug biotransformation.

Cultured rat precision-cut liver slices (PCLS) were used to study the influence of hypothermic preservation and reoxygenation at 37 degrees C on cellular metabolism and drug biotransformation. Cold hypoxic storage caused a depressed metabolism in rat liver slices, but reoxygenation for 8 h at 37 degrees C partially restored the levels of both ATP and GSH and totally restored the capacity to synthesize proteins. Metabolism of midazolam (CYP3A-dependent oxidation) by cold preserved liver slices was decreased by 30% but no further affected by reoxygenation, showing the same profile as freshly cut slices. Such a reoxygenation at 37 degrees C is accompanied by a dramatic loss of CYP3A2 protein while CYP3A1 protein was unaffected. These results suggest that CYP3A2 did not play a major role in midazolam oxidation. Such results are not consistent with a putative reoxygenation injury but rather with cold hypoxic damage. Since cold preserved liver slices did not respond to bacterial endotoxin stimulation (lipopolysaccharides), a minor role of non-parenchymal cells is suggested as mediators for deleterious effects developed during the cold storage.

Comparative hepatotoxicity of cholic acid, deoxycholic acid and lithocholic acid in the rat: in vivo and in vitro studies.

Until now, the cytotoxicity of the bile acids was mostly seen as being inversely associated with their degree of lipophilicity. The present study aimed at comparing the hepatotoxicity of cholic acid (CA), deoxycholic acid (DCA) and lithocholic acid (LCA), which are respectively, tri-, di- and monohydroxylated bile acids. For in vivo studies, the bile acids have been given at the dose of 0.5% or 1% in the diet of male Wistar rats for 2 weeks. The histological analysis of the liver, and the measurement of serum parameters of cytotoxicity and cholestasis (aminotransferases activity, bilirubin and total bile acids concentration), indicate that, among the bile acids tested, DCA is the most hepatotoxic, at both doses, while CA is the least hepatotoxic and cholestatic compound. Moreover, DCA is the only bile acid which, when given at the dose of 0.5%, induces lipid peroxidation in the liver, as evidenced by the measurement of thiobarbituric reactive substances in liver homogenates. The analysis of bile acids in liver homogenates by gas liquid chromatography revealed that feeding the animals with DCA results in its hepatic accumulation. Feeding rats with LCA or CA only slightly modifies the proportion of tri-, di- and monohydroxylated bile acids in the liver, as compared to controls. An in vitro experiment aimed at studying the hepatocellular lysis induced in vitro by the three bile acids by measuring the release of lactate dehydrogenase in the incubation medium of surviving hepatocytes in suspension. At a concentration of 1 mM, only DCA induces a significant cellular lysis, while at this concentration the lytic effects of CA and LCA are progressive and time-dependent. From this study, we gather that the hepatotoxicity of bile acids does not necessarily depend on their degree of hydroxylation. Our results are in accordance with some studies in rat hepatocarcinogenesis, showing a predominant initiating and promoting effects of DCA, as compared to LCA.

A new class of free radical scavengers reducing adriamycin mitochondrial toxicity.

Beef heart mitochondria were incubated with ADM and NADH. An adriamycin semiquinone radical was detected using ESR spectroscopy. The semiquinone radical production rate is decreased upon addition of a scavenger (AD 20) in the reaction medium. NMRI mice were treated with AD 20 (70 mg/kg, i.p.) 15 min prior ADM injection (20 mg/kg, i.p.) or with ADM alone. Heart mitochondria were isolated 48 hr later. The enzymatic activities of complex I-III and complex IV of the mitochondrial respiratory chain were strongly depressed in animals receiving ADM alone, whereas these activities were almost completely restored in animals receiving AD 20 and ADM. Fluorescence depolarization measurements indicated that only mice treated with ADM alone presented a decreased fluidity of their cardiac mitochondrial membrane.