Osvaldo R. Koch

Increased chemiluminescence and superoxide production in the liver of chronically ethanol-treated rats

Rats fed ethanol (1.74 +/- 0.12 g/day/100 g body wt for 12 weeks) showed a 45% increased microsomal production of O-2 (2.23 +/- 0.14 nmol/min/mg protein) and a 28% increased content of endoplasmic reticulum protein (26.8 +/- 1.4 mg/g liver). This could lead, at substrate saturation, to a 86% increased cytosolic production of O-2 which is not compensated by cytosolic superoxide dismutase levels that remain normal. It is claimed that this unbalance between O-2 production and superoxide dismutase leads to a peroxidative stress in agreement with the 54% increased spontaneous liver chemiluminescence (37 +/- 2 cps/cm2) measured in the ethanol-treated rats. Hydroperoxide-induced chemiluminescence was 57, 43, and 28% higher, respectively, in homogenates, mitochondria, and microsomes isolated from ethanol-treated rats as compared with controls. Vitamins E and A were more effective inhibitors of the hydroperoxide-stimulated chemiluminescence in the liver homogenates from ethanol-treated rats as compared with the effect on the homogenates from control animals. The results are consistent with a peroxidative stress in chronic alcoholism leading to increased lipoperoxidation and decreased levels of antioxidants.

Increased biliary glutathione disulfide release in chronically ethanol-treated rats.

tion was: carbohydrate, 54%; lipid, 193; and protein 27%. Glutathione &sulfide (GSSG) release frc3 liver [I ] has been evaluated as an indicator of oxidative stress, including lipid peroxidation (cf. hydroperoxide metabolism review in [2] )_ At present, the occurrence of enhanced rates of lipid peroxidation or of Ns02 production in the liver of rats c!lronically treated with ethanol is controversial (cf. review in ]3] and references therein) but appears to be a central concept in experimental pathology_ Therefore, we have applied a non-invasive approach and have examined the release of both oxidized and reduced ghrtathione from the liver of rats chronically treated, i.e., for 6 weeks with ethanol, essentially as in [4]. According to the finding that GSSG release occurs into bile [5], measurements were carried out in bile samples obtained from anesthetized rats. The calory percentages of the ingredients in th: final regimen, i.e., basal diet plus ethanol solution, consumed by the animals of the alcohol group were as follows:-ethanol, 41.5%; carbohydrate> 42.6%; lipid, 6.6% and protein, 9.3%. The composition of the diet of the control group was the same except that the ethanol-derived calories were replaced by sucrose. The animals in the ethanol group \lere kept witbhout ethanol for 18 h prior to the experiment but were allowed access to the basal diet and to drinking water.

Pro- and anti-oxidant parameters in rat liver after short term exposure to hexachlorobenzene

The association between an in vivo oxidative stress condition of the liver and hepatic porphyria during HCB intoxication is postulated. After 30 days of treatment, HCB (25 mg/kg b.w.) promotes an induction of microsomal cytochrome P450 system, increase in microsomal super oxide anion generation accompanied by increased levels of liver lipid peroxidation, as measured by the production of thiobarbituric acid reactants and by spontaneous visible chemiluminescence. Concomitantly, liver antiox idant defenses are slightly modified, with decreased activity of glutathione peroxidase, superoxide dismutase and glucose-6-phosphate dehydrogenase contributing to an oxidative stress condition of the liver. These liver biochemical alterations are closely related to increased levels of urinary coproporphyrin, plasma AST and ALT activities and to the onset of liver morphological lesions

Lindane-Induced Oxidative Stress. I. Time Course of Changes in Hepatic Microsomal Parameters, Antioxidant Enzymes, Lipid Peroxidative Indices and Morphological Characteristics

1. Lindane (60 mg/kg) administered orally to rats increased liver cytochrome P-450 content and superoxide radical (O2-.) generation 24 h after treatment, while formation of thiobarbituric acid reactants and NADPH/ADP-supported microsomal chemiluminescence were significantly increased 4 h after treatment. 2. Hepatic superoxide dismutase (SOD) and catalase decreased 6 h after lindane treatment and SOD/O2-. ratio progressively decreased during 4 to 24 h after lindane treatment. 3. Morphological evidence of hepatic cell injury after lindane treatment was seen at all times studied, and appeared to increase with time. 4. Lindane administration results in time-dependent oxidative stress in liver which involves an early component (4-6 h) related to the reductive metabolism of lindane, and a late component (24 h) associated with the induction of cytochrome P-450; the biochemical changes correlated with the observed morphological lesions.

Role of the life span determinant P66 shcA in ethanol-induced liver damage

Mice lacking the 66 kDa isoform of the adapter molecule shcA (p66shcA) display increased resistance to oxidative stress and delayed aging. In cultured cell lines, p66 promotes formation of Reactive Oxygen Species (ROS) in mitochondria, and apoptotic cell death in response to a variety of pro-oxidant noxious stimuli. As mitochondrial ROS and oxidative cell damage are clearly involved in alcohol-induced pathology, we hypothesized that p66 may also have a role in ethanol. In vivo, changes observed in p66+/+ mice after 6-week exposure to ethanol in the drinking water, including elevated serum alanine aminotransferase (ALT), liver swelling and evident liver steatosis, were significantly attenuated in p66−/− mutant mice. Biochemical analysis of liver tissues revealed induction of the p66 protein by ethanol, whereas p66-deficient livers responded to alcohol with a significant upregulation of the mitochondrial antioxidant enzyme MnSOD, nearly absent in control mice. Evidence of an inverse correlation between expression level of p66 and protection from alcohol-induced oxidative stress was also confirmed in vitro in primary hepatocytes and in HepG2-E47 cells, an ethanol-responsive hepatoma cell line. In fact, MnSOD upregulation by exposure to ethanol in vitro was much more pronounced in p66KO versus wild-type isolated liver cells, and blunted in HepG2 cells overexpressing p66shc. p66 overexpression also prevented the activation of a luciferase reporter gene controlled by the SOD2 promoter, indicating that p66 repression of MnSOD operates at a transcriptional level. Finally, p66 generated ROS in HepG2 cells and potentiated oxidative stress and mitochondrial depolarization by ethanol. Taken together, the above observations clearly indicate a role for p66 in alcohol-induced cell damage, likely via a cell-autonomous mechanism involving reduced expression of antioxidant defenses and mitochondrial dysfunction.

Regression of morphological alterations and oxidative stress-related parameters after acute lindane-induced hepatotoxicity in rats

Changes in rat liver oxidative stress-related parameters, morphological alterations, as well as circulating and tissue levels of lindane were studied 1-7 days after the administration of a single dose of 60 mg of lindane/kg. One day after lindane treatment, a significant enhancement in the oxidative stress status of the liver was observed, characterized by an increase in thiobarbituric acid reactants production and in the microsomal generation of superoxide radical (O.-2) coupled to cytochrome P450 induction, and a decrement in the activity of superoxide dismutase (SOD) and catalase. Consequently, the O.-2 production/SOD activity ratio was enhanced two-fold. In this condition, light microscopy studies revealed the incidence of liver lesions in periportal areas, together with significant changes at the mitochondrial level observed by electron microscopy, which coincide with the maximal levels of lindane in the liver, adipose tissue, plasma and whole blood. Changes in oxidative stress-related parameters observed after 1 day of lindane treatment regressed to normal from the third day and thereafter, together with the decrement in circulating and tissue levels of the insecticide. It is concluded that morphological and oxidative stress-related changes induced in the liver by acute lindane intoxication are readily reversible, depend on the hepatic content of the insecticide, and seem to be conditioned by the changes in O.-2 generation.

Alcohol-induced oxidative stress in rat liver

1. Livers from rats treated acutely with ethanol showed increased chemiluminescence, malondialdehyde production, and diene formation. Previous administration of (+)-cyanidanol-3 completely abolished acute ethanol-induced chemiluminescence. 2. Rats fed alcohol liquid diets for 3 weeks showed significant increases in microsomal and mitochondrial malondialdehyde formation, and in microsomal H2O2 and O2-. generation. 3. Rats fed a solid basal diet plus ethanol solution for 12 weeks also showed increased microsomal production of O2-. and increased content of microsomal cytochrome P-450. Hydroperoxide-induced chemiluminescence was higher in homogenates, mitochondria and microsomes from ethanol-treated rats than from controls. Vitamins E and A were more effective inhibitors of hydroperoxide-stimulated chemiluminescence in liver homogenates from ethanol-treated rats than from control animals. 4. Results are consistent with peroxidative stress leading to increased lipid peroxidation in liver of rats fed ethanol both acutely and after long-term dosing.

Biochemical lesions of liver mitochondria from rats after chronic alcohol consumption

Mitochondria obtained from nonfatty livers of male rats fed alcohol for 4 months showed reduced contents of cytochromes a-a3 and b and decreased activity of cytochrome oxidase and mitochondrial H2O2 production. Neither succinate dehydrogenase and NADH dehydrogenase activities, nor the cytochromes c and c1 and ubiquinone content were affected. Alcohol ingestion also impaired the in vitro incorporation of [14C]leucine into the protein of the hepatic mitochondrial membranes. The data suggested that chronic interference of ethanol with the synthesis of protein may be expected to result in lowered values of components of the electron transport chain and thus in interference with mitochondrial properties.

Functional alterations of liver mitochondria in chronic experimental alcoholism

Abstract Mitochondria obtained from nonfatty livers of male rats fed an alcoholic “super diet” for 4 months displayed enlargement and bizarre configurations. In vitro , the mitochondria from alcohol-treated rats showed reduced oxidation of succinate and of malate-glutamate, but the energy coupling remained apparently unchanged when compared with that of three different controls. With β-hydroxybutyrate as substrate, the maximal respiratory rate was affected in relation to those of control rats in whose regimens alcohol was isocalorically substituted by sucrose or fat, but not when the whole basal diet replaced alcohol. According to these results, it seems clear that the respiration of hepatic mitochondria is significantly altered when ethanol is supplied to rats at high levels over long periods and when a nutritional basal diet which does not induce fatty liver is used.

Effect of phenobarbital and 3-methylcholanthrene on the early oxidative stress component induced by lindane in rat liver

1. Lindane administered to untreated rats or rats pretreated with phenobarbital (PB) or 3-methylcholanthrene (MC) increased liver lipid peroxidation, of the same magnitude in all groups. 2. PB pretreatment produced a 50% increase in lipid peroxidation (TBAR) by liver homogenates and microsomes, an effect accompanied by increases in cytochrome P-450, NADPH-cytochrome P-450 reductase, NADPH oxidase and microsomal superoxide anion production, MC pretreatment resulted in increases in liver cytochrome P-450 and NADPH oxidase only. 3. Pretreatment of rats with PB, but not MC or lindane, gave increases in glutathione peroxidase and reductase. 4. Pretreatment with PB, but not MC, increased liver GSH. Lindane decreased liver GSH to the same extent as PB plus lindane. 5. Biliary GSH, GSSG and bile flow were decreased by lindane to similar extents in all groups. 6. Lindane induced periportal necrosis with haemorrhagic foci in all groups. 7. Data presented indicate that the early lipid peroxidative response of liver to lindane was unchanged by PB- or MC-stimulated hepatic microsomal enzyme induction.