Protective effect of colchiceine against acute liver damage

Pretreatment of rats with colchiceine (10 micrograms/day/rat) for seven days protected against CCl4-induced liver damage. CCl4 intoxication was demonstrated histologically and by increased serum activities of alanine amino transferase (ALT), alkaline phosphatase (Alk. Phosph.) gamma glutamyl transpeptidase (GGTP), bilirubins and decreased activity of glucose-6-phosphatase (G-6Pase). Furthermore, an increase in liver lipid peroxidation and a decrease in plasma membrane GGTP and Alk. Phosph. activities were found. Colchiceine increased 1.5-fold the LD50 of CCl4 and prevented the release of intracellular enzymes as well as the decrease in GGTP and Alk. Phosph. activities in plasma membranes. It also completely prevented the lipid peroxidation induced by CCl4 and limited the extent of the histological changes.     

Administration of the tris salt of alpha-tocopheryl hemisuccinate inactivates CYP2E1, enhances microsomal alpha-tocopherol levels and protects against carbon tetrachloride-induced hepatotoxicity

A series of tocopherol compounds were examined for their capacity to protect against carbon tetrachloride (CCl4)-induced hepatotoxicity in rats. Of the tocopherol compounds tested in our study, only the tris salt of d-alpha-tocopheryl hemisuccinate (TS-tris) protected against CCl4-induced hepatotoxicity. The administration of d-alpha-tocopherol (alpha-T) and the nonhydrolyzable tocopherol ether, d-alpha-tocopheryloxybutyrate tris salt (TSE-tris), failed to protect against CCl4-induced hepatotoxicity. TS-tris was the only tocopherol which significantly decreased CYP2E1 activity after 18 h. This decrease in CYP2E1 activity is likely to limit the activation of CCl4 and protect against CCl4-induced hepatotoxicity. Our results also suggest that TS-tris protection against CCl4-induced hepatotoxicity correlates with the enhanced capacity of TS-tris to deliver alpha-T and increase the antioxidant status of hepatocytes. TSE-tris did not increase cellular alpha-T levels, while administration of TS-tris produced large increases in alpha-T levels in liver homogenates as well as in liver nuclei, microsomes, mitochondria and plasma membranes. This enhanced ability to deliver tocopherol equivalents to parenchymal liver cells may be related in part to the ability of TS-tris to form liposomes in aqueous solutions. TS-tris administration protected against CCl4-induced microsomal lipid peroxide formation and inactivation of the microsomal enzyme glucose-6-phosphatase (G6Pase). Supplementation of animals with alpha-T protected against microsomal lipid peroxide formation but not against the inactivation of G6Pase. Based on our findings, we propose that high cellular levels of alpha-T protect against CCl4-induced hepatotoxicity by scavenging CCl4 radicals as well as protecting against lipid peroxidation. Our results do not support the importance of microsomal lipid peroxidation as an early event in acute CCl4-induced hepatic necrosis.     

Protective effects of N-acetyl-L-cysteine against acute carbon tetrachloride hepatotoxicity in rats

In recent years, N-acetyl-L-cysteine (NAC) has been widely investigated as a potentially useful protective and antioxidative agent to be applied in many pathological states. The aim of the present work was further evaluation of the mechanisms of the NAC protective effect under carbon tetrachloride-induced acute liver injuries in rats. The rat treatment with CCl4 (4 g/kg, intragastrically) caused pronounced hepatolysis observed as an increase in blood plasma bilirubin levels and hepatic enzyme activities, which agreed with numerous previous observations. The rat intoxication was accompanied by an enhancement of membrane lipid peroxidation (1.4-fold) and protein oxidative damage (protein carbonyl group and mixed protein-glutathione disulphide formations) in the rat liver. The levels of nitric oxide in blood plasma and liver tissue significantly increased (5.3- and 1.5-fold, respectively) as blood plasma triacylglycerols decreased (1.6-fold). The NAC administration to control and intoxicated animals (three times at doses of 150 mg/kg) elevated low-molecular-weight thiols in the liver. The NAC administration under CCl4-induced intoxication prevented oxidative damage of liver cells, decreased membrane lipid peroxidation, protein carbonyls and mixed protein-glutathione disulphides formation, and partially normalized plasma triacylglycerols. At the same time the NAC treatment of intoxicated animals did not produce a marked decrease of the elevated levels of blood plasma ALT and AST activities and bilirubin. The in vitro exposure of human red blood cells to NAC increased the cellular low-molecular-weight thiol levels and retarded tert-butylhydroperoxide-induced cellular thiol depletion and membrane lipid peroxidation as well as effectively inhibited hypochlorous acid-induced erythrocyte lysis. Thus, NAC can replenish non-protein cellular thiols and protect membrane lipids and proteins due to its direct radical-scavenging properties, but it did not attenuate hepatotoxicity in the acute rat CCl4-intoxication model.     

Promethazine inhibits the formation of aldehydic products of lipid peroxidation but not covalent binding resulting from the exposure of rat liver fractions to CCl4.

Promethazine is known to have protective activity in relation to CCl4-induced liver necrosis. This hepatoprotective property has been investigated with regard to the free radical scavenging and antioxidant properties of promethazine using isolated hepatocytes and microsomal suspensions. CCl4 is activated in both systems to free radical metabolites that bind covalently to lipid and protein, and initiate lipid peroxidation. A large number of carbonyl products is produced during CCl4-induced lipid peroxidation; promethazine strongly inhibits the production of all classes of carbonyl compounds in both microsomal suspensions and isolated hepatocytes. In contrast, promethazine is a very weak inhibitor of the covalent binding of metabolites of CCl4. We conclude that promethazine acts by scavenging the trichloromethylperoxyl radical and lipid peroxyl radicals, and is a weak scavenger of the trichloromethyl radical. These data, when considered together with the hepatoprotective effects of promethazine, suggest that lipid peroxidation is of relatively more importance than covalent binding in the pathogenesis of CCl4-induced liver necrosis.     

Lipid peroxidation and covalent binding in the early functional impairment of liver Golgi apparatus by carbon tetrachloride

The onset of the lipoprotein secretory block provoked by CCl4 in the whole animal was monitored after purification of liver Golgi membranes. Both lipid transit through the apparatus and hexosylation of the lipoprotein are markedly inhibited 5-15 min after poisoning. Pre-treating the animal with alpha-tocopherol, shown to prevent lipid peroxidation without modifying the covalent binding due to CCl4 metabolites, affords little protection against lipid accumulation in the Golgi, but total preservation of galactosyl transferase activity. While haloalkylation therefore appears to be the major mechanism of damage in the early phases of CCl4-induced derangement of lipid secretion, lipid peroxidation is probably more involved later; this is indicated by the marked, though never complete, protection against fatty liver afforded at 24 h after CCl4 poisoning by supplementation of the membrane with alpha-tocopherol.     

Antioxidative effect of o-benzoquinone derivatives during CCl4-induced lipid peroxidation in the rat liver

It was found that o-benzoquinones (oBQ) inhibit the CCl4-dependent lipid peroxidation (LPO) in rat liver microsomes in vitro. The experimental data suggest that the antioxidant effect of oBQ is not due to the ability of these substances to shunt the NADPH-dependent electron transport pathways. More likely, oBQ inhibit LPO due to the ability of their reduced forms to scavenge the free radicals which induce LPO. Based on the experimental data, it was concluded that the increasing absorption of liver lipids at 230-236 nm after administration of CCl4 is due to the accumulation of reduced hydroperoxides. This process was shown to be inhibited by oBQ.     

The critical steady-state hypoxic conditions in carbon tetrachloride-induced lipid peroxidation in rat liver microsomes

Defined steady-state oxygen partial pressures (PO2) were maintained constant with an oxystat system to study carbon tetrachloride (CCl4)-induced lipid peroxidation and oxygen uptake in rat liver microsomes. The initial rates of oxygen uptake and malondialdehyde formation indicated drastically increasing lipid peroxidation by decreasing PO2, attaining a maximum between 1-10 mmHg (0.1-1.3 kPa). Under these conditions, at the hypoxic end of the physiological PO2 in liver, CCl4 caused a 5-fold increase in the oxygen uptake rate and a 20-fold increase in the malondialdehyde formation rate while, at 80 mmHg (10.7 kPa) the haloalkane caused only an increase of 2- and 4-fold, respectively; in comparison, there was only a slight increase in NADPH-induced lipid peroxidation with increasing PO2. These data clearly demonstrate the critical role of low steady-state PO2 in CCl4-induced lipid peroxidation and support lipid peroxidation as a key factor in CCl4 hepatotoxicity.     

Sensitivity of ATPase-ADPase activities from synaptic plasma membranes of rat forebrain to lipid peroxidation in vitro and the protective effect of vitamin E

The in vitro effects of membrane lipid peroxidation on ATPase-ADPase activities in synaptic plasma membranes from rat forebrain were investigated. Treatment of synaptic plasma membranes with an oxidant generating system (H₂O₂/Fe²⁺/ascorbate) resulted in lipid peroxidation and inhibition of the enzyme activity. Besides, trolox as a water soluble vitamin E analogue totally prevented lipid peroxidation and the inhibition of enzyme activity. These results demonstrate the susceptibility of ATPase-ADPase activities of synaptic plasma membranes to free radicals and suggest that the protective effect against lipid peroxidation by trolox prevents the inhibition of enzyme activity. Thus, inhibition of ATPase-ADPase activities of synaptic plasma membranes in cerebral oxidative stress probably is related to lipid peroxidation in the brain.     

The role of lipid peroxidation in CCl4-induced damage to liver microsomal enzymes: comparative studies in vitro using microsomes and isolated liver cells

The question as to whether CCl4 decreases the activities of glucose-6-phosphatase and cytochrome P-450 in liver endoplasmic reticulum mainly through its action in stimulating lipid peroxidation has been investigated using Promethazine to block lipid peroxidation. The investigation, moreover, has compared the effects of CCl4, with and without Promethazine, on isolated rat hepatocytes with corresponding effects on rat liver microsomal suspensions. Our data give no support for the view that products of lipid peroxidation are the main cause of the decrease in cytochrome P-450 observed in CCl4-intoxication. However, our present results are consistent with lipid peroxidation being a major contributory factor to the decrease in glucose-6-phosphatase activity observed in CCl4-induced liver injury.     

Oxygen- and carbon-centered free radical formation during carbon tetrachloride metabolism. Observation of lipid radicals in vivo and in vitro

Free radical reactions involved in the metabolism of carbon tetrachloride by rat liver have been considered to be a cause of at least part of the injury resulting from exposure to this halocarbon. In an earlier study employing electron spin resonance and spin-trapping techniques, we demonstrated that trichloromethyl (13.CCl3) radicals are readily observed in rat liver microsomes metabolizing 13CCl4, and that the same radical could be shown to form in vivo in the liver of intact rats given a single dose of 13CCl4. This report describes the production of lipid dienyl (L.) and oxygen-centered lipid radicals (LO. or LOO., or both) in in vitro systems metabolizing 13CCl4, and also the formation of lipid dienyl radicals (L.) in liver of intact animals exposed to CCl4. The radicals appear to be produced in a sequence of reactions governed among other things by the oxygen tension in the system. The lipid radicals (L.) which form in intact liver of CCl4-treated rats are apparently the result of an attack on lipids of the endoplasmic reticulum by 13.CCl3 radicals formed by reductive cleavage to CCl4 and are the initial intermediates in the process of lipid peroxidation. These investigations demonstrate that while the events occurring in liver microsomes in vitro appear to parallel those which take place in intact liver in vivo, the conditions in vivo make the spin-trapping studies of radicals in intact animals much more selective than it is in vitro for a given spin trap, and requires the use of more than one type of spin-trapping agent to detect different radical species in vivo.     

Free radical lipid oxidation and physical properties of lipid layer of biological membranes

The results obtained mainly by the author and coworkers are summarized. One efficient method to detect free radicals in biological samples is chemiluminescence (CL). In the absence of activators CL of membraneous systems is due to lipid peroxide free radicals, whereas in the presence of luminol it is initiated by oxygen radicals. Low levels of free radicals in the cells and blood plasma are maintained by antioxidants, enzymes included. Ferrous ions increase free radical concentrations in the cells and tissues. Deleterious action of hydroxyl radicals is the result of the breakage of DNA strains and of lipid peroxidation (LPO). The latter reaction brings about the damage of the membrane barriers due to a decrease of the electrical stability of the membrane lipid bilayer and "self-breakdown" of the membranes by potential differences produced in the living cells.     

Aggravation by halomethanes of damages in isolated erythrocyte membranes photosensitized by porphyrins

It was found that halogen methanes (CCl4, CHBr3) enhance the destruction of protein tryptophanyls and lipid peroxidation photosensitized by Zn-tetraphenylporphin and Zn-tetramethylpyridylporphyrin in isolated erythrocyte membranes. It was shown that this effect is due to photoinduced electron transport from Zn-porphyrins to halogen methanes with the formation of highly reactive halogenmethyl radicals. The hydrophilic Zn-tetramethylpyridylporphyrin is more active at the photosensition of damage to membrane proteins, whereas the hydrophobic Zn-tetraphenylporphin is more effective in lipid peroxidation.     

Kupffer cells inhibition prevents hepatic lipid peroxidation and damage induced by carbon tetrachloride

The aim of this work was to determine if the action mechanism of gadolinium on CCl(4)-induced liver damage is by preventing lipid peroxidation (that may be induced by Kupffer cells) and its effects on liver carbohydrate metabolism. Four groups of rats were treated with CCl(4), CCl(4)+GdCl(3), GdCl(3), and vehicles. CCl(4) was given orally (0.4 g 100 g(-1) body wt.) and GdCl(3) (0.20 g 100 g(-1) body wt.) was administered i.p. All the animals were killed 24 h after treatment with CCl(4) or vehicle. Glycogen and lipid peroxidation were measured in liver. Alkaline phosphatase, gamma-glutamyl transpeptidase, alanine amino transferase activities and bilirubins were measured in rat serum. A liver histological analysis was performed. CCl(4) induced significant elevations on enzyme activities and bilirubins; GdCl(3) completely prevented this effect. Liver lipid peroxidation increased 2.5-fold by CCl(4) treatment; this effect was also prevented by GdCl(3). Glycogen stores were depleted by acute intoxication with CCl(4). However, GdCl(3) did not prevent this effect. The present study shows that Kupffer cells may be responsible for liver damage induced by carbon tetrachloride and that lipid peroxidation is produced or stimulated by Kupffer cells, since their inhibition with GdCl(3) prevented both lipid peroxidation and CCl(4)-induced liver injury.     

A note on the stability of conjugated diene absorption of rat liver microsomal lipids after carbon tetrachloride poisoning

Liver microsomal lipid peroxidation has been observed in fatal human CCl(4) poisoning, in rats with fatty livers induced by CCl(4) or by yellow phosphorus, and in mice poisoned with 1,1,2,2-tetrachloroethane. These observations suggest the possibility that other instances of toxic liver injury may involve lipid peroxidation. Cases of acute, fatal, toxic liver injury (e.g., from halothane anesthesia) are not likely to occur at or near laboratories equipped to determine whether any lipid peroxidation might have taken place. The data presented indicate that rat livers may be stored frozen for at least 7 days with no demonstrable diminution in CCl(4)-induced conjugated diene absorption of liver microsomal lipids.     

Carbon tetrachloride-induced liver cell injury in the Mongolian gerbil (Meriones unguiculatus)

1. Male Mongolian gerbils (Meriones unguiculatus) liver activates CCl4 to free radicals that bind covalently to cellular components (CB) and stimulate a lipid peroxidation (LP) process to a larger extent than the rat liver. 2. CCl4 administration results in a less intense necrogenic effect in gerbils than in rats and does not cause fatty liver. 3. CCl4 causes less intense effects on liver ultrastructure or calcium metabolism but more marked depression of glucose 6 phosphatase activity (G6P-ase) in gerbils than in rats. 4. Results suggest that a better ability of gerbil liver to keep calcium homeostasis than rat liver might be the cause of their relative resistance to necrosis. Higher intensity of CB and LP in gerbils than in rats might explain more intense effects on G6P-ase.     

Protective effects of melatonin against carbon tetrachloride hepatotoxicity in rats

Melatonin is an indolamine, mainly secreted by the pineal gland into the blood of mammalian species. The potential for protective effects of melatonin on carbon tetrachloride (CCl(4))-induced acute liver injury in rats was investigated in this work. CCl(4) exerts its toxic effects by generation of free radicals; it was intragastrically administered to male Wistar rats (4 g kg(-1) body weight) at 20 h before the animals were decapitated. Melatonin (15 mg kg(-1) body weight) was administered intraperitoneally three times: 30 min before and at 2 and 4 h after CCl(4) injection. Rats injected with CCl(4) alone showed significant lipid and hydropic dystrophy of the liver, massive necrosis of hepatocytes, marked increases in free and conjugated bilirubin levels, elevation of hepatic enzymes (alanine aminotransferase and aspartate aminotransferase) in plasma, as well as NO accumulation in liver and in blood. Melatonin administered at a pharmacological dose diminished the toxic effects of CCl(4). Thus it decreased both the structural and functional injury of hepatocytes and clearly exerted hepatoprotective effects. Melatonin administration also reduced CCl(4)-induced NO generation. These findings suggest that the effect of melatonin on CCl(4)-induced acute liver injury depends on the antioxidant action of melatonin.     

Correlations between common tests for assessment of liver damage: indices of the hepatoprotective activity of promethazine in carbon tetrachloride hepatotoxicity

The effects of promethazine (PM) on different aspects of the hepatotoxic action of CCl4 in the rat were investigated with the objective of finding rapid and reliable indicators of hepatoprotective effects. The study was based on definitive histological assessment of liver damage caused by CCl4 in the presence and absence of PM: PM (78 mumol kg-1, i.p.) protected against CCl4-induced hepatic necrosis 24 h after a low dose of CCl4 (1.3 mmol kg-1) but not against a higher dose (13.0 mmol kg-1). The large increases in plasma activities of GOT, GPT and LDH produced by dosing with CCl4 were partially inhibited by the administration of PM. PM and CCl4 caused a synergistic and long-lasting decrease in body temperature (2-3 degrees C for 8-10 h). Modifying the toxicity with PM, together with a low dose of CCl4, helped to minimize secondary effects of CCl4, to clarify the sequence of toxic events, and to assess the sensitivity of some standard tests of hepatotoxicity. Simultaneous measurement of over 20 commonly used biochemical screening tests in individual animals 3 or 6 h after treatment permitted direct correlation of a wide variety of concentrations, activities and effects. For example, liver CHCl3 concentrations (as a measure of CCl4 metabolism) correlate strongly with increases in diene conjugation of microsomal lipids (as a measure of CCl4-induced lipid peroxidation); malonaldehyde production appears to be less sensitive as a measure of lipid peroxidation in vivo than diene conjugation. The changes induced in each parameter and the correlations between them are discussed with reference to the overall nature of the hepatotoxic reaction and its modification by PM.     

The antioxidative activity of drugs in the liver microsomal system of rats]

The antioxidative properties of drugs--diethylcarbamazine citrate--DECC, dipyridamole-DP, levamisole and labinzarit--have been investigated in various microsomal lipid peroxidation (LPO) models: NADPH-, ascorbate- and CCl4-dependent. The most strong antioxidant of direct action turned out to be DP, DECC exhibited the antioxidative properties as a result of metabolic activity in monooxygenases system of rat liver microsomes. Levamisole and labinzarit turned out to be weak antioxidants. The control of microsomal membrane stability against Fe(2+)-ADP, NADPH-induced LPO, after being isolated from rat liver after the action of CCl4 without and with DECC, showed that DECC protected microsomal membranes from CCl4 in vivo and they remained stable against LPO in vitro.     

Isoflavone genistein-8-c-glycoside prevents the oxidative damages in structure and function of rat liver microsomal membranes

Bioflavonoids (polyhydroxyphenols) are ubiquitous components of plants, fruits and vegetables; these compounds are efficient scavengers of free oxygen radicals and peroxides. The aim of this study was to investigate the antioxidant and radioprotective effects of genistein-8-C-glicoside (G8CG), an isoflavone, isolated from the flowers of Lipinus luteusl L. G8CG prevents dose-dependently the destruction of the cytochrome P-450 and its conversion to an inactive form cytochrome P-420, inhibits membrane lipid peroxidation and membrane SH-group oxidation in isolated rat liver microsomal membranes under tert-butylhydroperoxide-induced oxidative stress. Single whole-body gamma-irradiation (1 Gy) of rats results in blood plasma and liver microsomal membrane lipid peroxidation, impairments of microsomal membrane structure and function. Rat treatment with G8CG (75 mg/kg) developed the clear protective effect, stabilized membrane structure and improved the parameters of the monooxygenase function. We can conclude that G8CG can be used as antioxidant and radioprotective agent.     

Protective effect of Aquilegia vulgaris (L.) on carbon tetrachloride-induced oxidative stress in rats

The ethyl ether extract of A. vulgaris inhibited in vitro microsomal lipid peroxidation (IC50 58.8 microg/ml) and showed moderate ability to scavenge superoxide radicals and to chelate iron ions. The extract (100 mg/kg body weight, po) decreased uninduced and enzymatic microsomal lipid peroxidation in the liver of male rats pretreated with CCl4 (1 ml/kg body weight) by 27 and 40%, respectively. Activity of antioxidant and related enzymes (catalase and glucose-6-phosphate dehydrogenase) inhibited by CCl4 was significantly restored after administration of the extract. The extract itself significantly enhanced superoxide dismutase activity. There was no effect of the extract on hepatic glutathione level and cytochrome P450 content, both were decreased by CCl4. Neither CCl4 nor the tested extract affected activities of NADPH-cytochrome P450 reductase and two monooxygenases, aniline hydroxylase and aminopyrine n-demethylase. It can be concluded that the protective effect of the A. vulgaris extract in CCl4-induced liver injury is mediated by inhibition of microsomal lipid peroxidation and restoring activity of some antioxidant and related enzymes.