Suppressive effect of tritoqualine on enzyme leakage induced by D-galactosamine in rat primary-cultured hepatocytes

Tritoqualine (TRQ) was previously reported to suppress enzyme leakage and lipid peroxidation induced by carbon tetrachloride in isolated hepatocytes. In the present study, we investigated the effect of TRQ on enzyme leakage from rat primary-cultured hepatocytes using D-galactosamine (GalN) which causes hepatic injury without lipid peroxidation. Leakage of GPT and GPT was significantly increased at 18 hr after GalN addition, being saturated at 42-50 hr. This enzyme leakage was suppressed dose-dependently by TRQ at 42 hr, but not by vitamin E. These results suggest that TRQ shows a suppressive effect on enzyme leakage from hepatocytes independently of its inhibitory action on lipid peroxidation.     

Lipid peroxidation and irreversible cell damage: synergism between carbon tetrachloride and 1,2-dibromoethane in isolated rat hepatocytes

The combination of 1,2-dibromoethane (DBE) with carbon tetrachloride (CCl4) in the isolated rat hepatocyte model produces a significant potentiation of both lipid peroxidation and plasma membrane damage induced by the latter compound. The increase in malondialdehyde production precedes the hepatocyte damage, evaluated in terms both of lactate dehydrogenase leakage and trypan blue exclusion. When hepatocytes are isolated from vitamin E pretreated rats, both the prooxidant and the cytotoxic effects of CCl4 are prevented. Also the synergism between CCl4 and DBE on lipid peroxidation disappears completely while that on cell damage is strongly reduced. The increased lipid peroxidation appears to be one of the mechanisms of the observed synergism between CCl4 and DBE on hepatocyte damage. Regarding the antioxidant status of the hepatocyte challenged with CCl4 and DBE, an early and significant consumption of vitamin E is observed only in the presence of the mixture of these xenobiotics. Total nonprotein thiol content is not significantly modified by CCl4 poisoning while DBE, alone and in association with CCl4, markedly decreases it. Vitamin E supplementation does not prevent but moderately delays total nonprotein thiol depletion due to DBE or to the mixture. Finally, glutathione transferase activity is significantly reduced by CCl4 treatment and not by DBE, and vitamin E supplementation totally prevents such inhibition. The increased prooxidant effect of CCl4 plus DBE compared to CCl4 alone seems related to the shift in DBE metabolism consequent to the CCl4-dependent inactivation of glutathione transferase.     

Prophylactic effect of tritoqualine (TRQ) on the CCl4-induced chronic liver injury model in rats

Tritoqualine (TRQ) administered at doses of 100 or 200 mg/kg, perorally, had a preventive effect on the liver injury in rats induced by the treatment with CCl4 for 12 weeks consecutively. Rats subjected to this chronic treatment with CCl4 showed a decrease in body weight gain and changes in several serum parameters that are indicators of hepatic function were observed: the increase of transaminases, as a parameter of hepatocyte breakdown; the increase of alkaline phosphatase, as a parameter of biliary system abnormalities, the reduction of prothrombin time, as a marker of protein biosynthesis in the liver; and the change of lipids concentrations, reflecting liver injury. After the administration of TRQ perorally, there was a notable suppression of the increment in leaked enzymes in the serum and a marked improvement of the parameters concerning protein biosynthesis and lipid metabolism in comparison with CCl4 control rats. Marked fibrosis in the liver was observed after CCl4 treatment for 12 weeks, and the collagen content in the liver was 5 times higher than that of control rats. TRQ suppressed the increment in collagen formation and also showed improvement of the decrease of the liver function with regards to protein biosynthesis in CCl4-treated rats. Judging from these results, it was concluded that TRQ had a remarkable protecting action on the liver injury chronically induced by CCl4 treatment and was a effective compound for restoring liver function.     

In vivo production of ethylene from 2-keto-4-methylthiobutyrate in mice

The use of 2-keto-4-methylthiobutyric acid (KMB), the alpha-keto analog of methionine, was studied as a potential means of detecting free radical generation in vivo. KMB-dependent ethylene production (presumably from free radical interception), and ethane production from in vivo lipid peroxidation, were monitored simultaneously by measuring the rate of exhalation of these hydrocarbons by mice. Injection of KMB (1 g/kg) into mice resulted in an 8-fold increase in ethylene production above endogenous levels seen in saline-injected controls (1.47 +/- 0.35 vs 0.17 +/- 0.02 nmoles/100 g/hr respectively). Administration of CCl4 (3.0 g/kg) to initiate hepatic lipid peroxidation, 20 min prior to KMB injection, augmented the production of ethylene (2.37 +/- 0.10 nmoles/100 g/hr). Lipid peroxidation following injection of CCl4 was monitored via the increased exhalation of ethane. Pretreating the mice with vitamin E (100 mg/kg daily for 3 days), an inhibitor of lipid peroxidation, did not result in a significant change in ethylene production from KMB by itself or after prior injection of CCl4. However, vitamin E did suppress ethane production initiated by CCl4. Similar results were obtained with mouse liver slices studied in vitro. Metyrapone (150 mg/kg), an inhibitor of hepatic mixed function oxidase activity, also suppressed significantly the CCl4-stimulated production of ethane, but not the CCl4-stimulated production of ethylene from KMB. It appears that ethylene production from KMB does not derive from free radicals generated during in vivo lipid peroxidation since suppression of lipid peroxidation by vitamin E or metyrapone did not suppress ethylene production.     

Effects of novel antioxidants on carbon tetrachloride-induced lipid peroxidation and toxicity in precision-cut rat liver slices

Previous studies in rat liver microsomes have demonstrated the effectiveness of the 21-aminosteroid, U-74,006F, the troloxamine, U-78,517G, and N,N'-diphenyl-p-phenylenediamine (DPPD) in preventing carbon tetrachloride (CCl4)-induced lipid peroxidation. Studies reported here utilized liver slices to assess whether these antioxidants could prevent lipid peroxidation and ensuing toxicity in a more complete/complex system. Liver slices prepared from Aroclor 1254-induced SD rats were incubated in Dulbecco's modified eagle media, 37 degrees C, for up to 9 hr. Slices were preincubated with test compounds for 30 min prior to addition of CCl4. Lipid peroxidation, as measured by the formation of thiobarbituric acid-reactive substances and ethane evolution, was decreased by U-74,006F (100 microM), U-78,517G (100 microM), and DPPD (1 microM). CCl4 (2.5 microliters) decreased intracellular K+ content, intracellular lactate dehydrogenase (LDH), and intracellular isocitrate dehydrogenase (ICD) activities over a 9-hr incubation period. Despite the marked effects on lipid peroxidation, U-74,006F showed no protection against K+ or LDH loss and only moderate protection against ICD loss. U-78,517G showed no protection against K+ loss but substantial protection against enzyme loss. DPPD demonstrated slight protection against K+ and marked protection against enzyme loss. All three compounds inhibited CCl4-induced lipid peroxidation; U-78,517G being most effective, followed by DPPD and U-74,006F. Inhibition of lipid peroxidation provided protection to the membrane structure as indicated by inhibition of LDH and ICD loss. The antioxidants failed to protect against CCl4-induced toxicity (K+ loss). These results suggest that CCl4-induced lipid peroxidation and toxicity may be dissociable.     

Vitamin E improves membrane lipid alterations induced by CCl4 intoxication

The effect of pretreatment with vitamin E on membrane lipid alterations produced by the acute intoxication with CCl4 was studied. Rats were treated with an oral dose of CCl4 (0.4 g per 100 g body weight) and 24 h later the animals were sacrificed and liver plasma membranes isolated. After extraction, the membrane lipids were analysed by thin-layer chromatography and quantitated by densitometry. The phospholipid: protein ratio determined in plasma membranes of CCl4-treated rats was almost three-fold higher than that found in control animals. Sphingomyelin (Sph) and phospharidyl choline (PC) increased, while phosphatidyl ethanolamine (PE) decreased in the plasma membranes isolated from the CCl4-treated group. Animals pretreated for 7 days with a daily dose of vitamin E (200 IU per kg body weight) showed a lower increase in the phospholipid: protein ratio (two-fold) and the changes in Sph, PC and PE were lower. When the rats were pretreated with a higher dose of vitamin E (400 IU per kg body weight) for the same period, the lipid composition of plasma membrane was normal. These results indicate that vitamin E can protect against the alterations induced by CCl4 on the liver membranes. The protective action of vitamin E against CCl4 membrane damage is probably associated with its antioxidant properties.     

Increasing lipid peroxidation by vitamin E deficiency does not augment adriamycin-induced inhibition of hepatic drug metabolism

Adriamycin treatment in vivo or addition to incubation mixtures in vitro inhibits hepatic drug metabolism. It has been suggested that adriamycin-induced membrane lipid peroxidation may be a mechanism responsible for this activity in vitro. To determine if similar mechanisms operate in vivo, adriamycin inhibition of drug metabolism was compared in rats whose tissue lipid peroxidizability was altered by manipulating dietary levels of vitamin E. Weanling rats maintained on vitamin E deficient (0 ppm) or supplemented (10 or 100 ppm) diets for 12 weeks were given either adriamycin, 5 mg/kg/week, or equal volumes of the saline vehicle for 3 weeks intraperitoneally. Vitamin E deficiency alone (0 ppm, saline pretreatment) produced a 37% increase in hepatic lipid peroxidation without any appreciable alteration in hepatic aniline hydroxylase, ethylmorphine N-demethylase or aryl hydrocarbon hydroxylase activities. Adriamycin pretreatment altered hepatic lipid peroxidizability over corresponding saline pretreated controls dependent on dietary vitamin E. No increase was seen in the 100 ppm group, while 44% and 500% increases occurred at 10 and 0 ppm vitamin E, respectively. Adriamycin pretreatment decreased drug-metabolizing enzyme activity by an average of 32% for aniline hydroxylase, 26% for ethylmorphine N-demethylase and 63% for aryl hydrocarbon hydroxylase. Statistically, decreases in drug metabolism were independent of dietary vitamin E and did not correlate with lipid peroxidizability. These data would suggest that in vivo adriamycin-induced depression of hepatic drug-metabolizing enzymes is not mediated by elevated lipid peroxidation.     

Efficient amelioration of carbon tetrachloride induced toxicity in isolated rat hepatocytes by Syzygium cumini Skeels extract.

Syzygiumcumini, Indian black plum or Java plum, is a rich source for anthocyanins (230mg/100g DW) showing high antioxidant activity in vitro. In the following study it is further demonstrated that S. cumini peel extract rich in anthocyanins (SCA) offers considerable protection against carbon tetrachloride (CCl(4))-induced damage in rat hepatocytes. SCA itself being non-toxic to primary rat hepatocytes at concentrations ranging from 50 to 500ppm, was found to suppress CCl(4)-induced LDH leakage by 54% at 50ppm, thereby improving the cell viability by 39%. The SCA significantly reversed the CCl(4) induced changes in cellular glutathione (GSH) level, lipid peroxidation and activity of the antioxidant enzyme glutathione peroxidase. Exposure of hepatocytes to SCA after CCl(4) treatment was found to elevate GSH and GPx activities by 2-folds, whereas the activities of catalase and superoxide dismutase were not significantly affected. The fruit pulp extract (SPE) was less effective in offering protection to rat hepatocytes, particularly in terms of total GSH content and a consequent increase in lipid peroxidation although the higher GPx activity suggests the probable involvement of GSH as a substrate for GPx. These observations suggest that the fruit peel extract of S. cumini, is largely responsible for the reversal of CCl(4)-induced oxidative damage in rat hepatocytes. Both peel and pulp extract appear to offer protection to rat hepatocytes through GPx along with other biological pathways independent of catalase and superoxide dismutase.     

The effects of glutathione and vitamin E on iron toxicity in isolated rat hepatocytes

This study examined the acute toxicity of ferrous sulfate on rat hepatocyte suspensions, the correlation between lipid peroxidation and cell death, and the roles of glutathione and vitamin E in protecting against iron toxicity. Incubation with ferrous sulfate for 2 h produced lipid peroxidation, but did not decrease cell viability in the hepatocytes. When diethyl maleate (DEM) was added to deplete cellular glutathione concentrations, ferrous sulfate treatment (2.0-5.0 mM) did cause cell death and lipid peroxidation developed more extensively, suggesting that iron-mediated hepatotoxicity is influenced by glutathione content. Reduced glutathione (GSH), N-acetylcysteine (NAC) and alpha-tocopherol (vitamin E), alone and in combination, were added to hepatocyte suspensions in an attempt to protect cells against iron-induced damage. In iron-DEM-treated cells, GSH and NAC treatment increased viability by 43 and 36%, respectively, but only the combination of the two agents reduced lipid peroxidation (53% decrease). Vitamin E treatment reduced lipid peroxidation by 39% and also increased cell viability by 12%. The greatest protection against iron-induced lipid peroxidation occurred with the combination of GSH, NAC and vitamin E, which reduced lipid peroxidation by 94% in iron-treated cells, and by 98% in iron-DEM-treated cells. However, this combination did not prevent iron-induced cell death, although it did increase viability by 18%. These results suggest that iron-induced cell death may not be dependent upon lipid peroxidation, at least in short-term exposures. The results also suggest an interaction between GSH and vitamin E in protecting against lipid peroxidation.     

Vitamin E and glutathione are required for preservation of microsomal glutathione S-transferase from oxidative stress in microsomes

Glutathione (GSH) inhibited lipid peroxidation induced by NADPH-BrCCl3 in vitamin E sufficient microsomes, but did not in phenobarbital (PB)-treated microsomes (containing about 60% of normal vitamin E) or in vitamin E-deficient microsomes (containing about 30% of normal vitamin E). There was a good correlation between the increased formation of CHCl3 from BrCCl3 in the presence of GSH under anaerobic conditions and the vitamin E level in the microsomes. A normal level of vitamin E in microsomes was thus very important for GSH-dependent inhibition of lipid peroxidation and for the efficient formation of CHCl3 from BrCCl3. Bromosulfophthalein (BSP) eliminated the effects of GSH on lipid peroxidation and CHCl3 formation. The apparent Km and Vmax of substrates for GSH S-transferase were changed by in vivo depletion of vitamin E in microsomes, and the Vmax/Km values were significantly reduced. The enzyme activity in microsomes was inactivated following the loss of vitamin E during in vitro lipid peroxidation, and GSH prevented the loss of vitamin E and protected the enzyme from attack by free radicals. GSH inhibited lipid peroxidation induced by NADPH-Fe2+ and the loss of GSH S-transferase activity during the peroxidation in PB-treated microsomes, but did not in the case of induction by NADPH-BrCCl3. A possible relation between the microsomal GSH S-transferase activity and defense by GSH against lipid peroxidation in microsomes is discussed.     

Effect of phorone-induced glutathione depletion on the metabolism and hepatotoxicity of carbon tetrachloride and vinylidene chloride in rats

Although the depletion of hepatic glutathione in male rats following treatment with phorone (diisopropylidene acetone) did not affect the xenobiotic-metabolizing microsomal enzyme system, the metabolic elimination of vinylidene chloride (VDC) from the atmosphere of a closed exposure system was inhibited. However, the hepatotoxicity of VDC was enhanced after GSH-depletion, although no enhancement of VDC-induced in vivo lipid peroxidation was observed. In contrast, GSH depletion had no influence on the metabolic elimination of carbon tetrachloride, but augmented both the hepatotoxic response to and the in vivo lipid peroxidation induced by CCl4. In the case of VDC GSH-depletion hepatoxicity was increased because of a change in the metabolic pathway, resulting in production of intermediates of greater toxicity: lack of GSH in CCl4 treated rats renders membrane phospholipids more susceptible to peroxidative damage.     

In vitro and in vivo studies of the effect of vitamin E on microsomal cytochrome P450 in rat liver

Administration of a diet supplemented with 0.06% vitamin E acetate to male rats over a 6-week period doubled hepatic microsomal stores of alpha-tocopherol over those in control (vitamin E adequate) rat liver. Total cytochrome P450 content and NADPH-cytochrome P450 reductase activity were significantly elevated in hepatic microsomes from vitamin E-supplemented rats to 111% and 123% of respective control values. Androstenedione 16 alpha-hydroxylase activity was increased in these fractions (2.57 +/- 0.31 nmol product/min/mg protein vs 1.81 +/- 0.38 in controls) whereas activities of the 6 beta-, 7 alpha- and 16 beta-hydroxylase pathways were unchanged. Immunoquantitation of the microsomal 16 alpha-hydroxylase, P450 IIC11, indicated a corresponding increase in the hepatic content of the enzyme. In view of the established antioxidant role of tocopherols, the effects of dietary vitamin E manipulation on the concentration of protein sulphydryl groups and the susceptibility of microsomes to ferric sulphate-ADP-NADPH-mediated lipid peroxidation were also assessed. Dietary supplementation did not influence microsomal protein sulphydryl content (68 +/- 10 nmol glutathione equivalents/mg protein) but decreased the extent of lipid peroxidation produced by the ferric sulphate-ADP-NADPH system in vitro. Further in vitro experiments demonstrated that vitamin E acetate (2 microM) protected protein sulphydryl groups and lipids against peroxidation in control microsomes and partially reduced the associated losses of P450-mediated steroid hydroxylase activities. Western immunoquantitation of P450 IIC11 revealed that exogenous vitamin E acetate protected completely against peroxidation-induced apoprotein loss. These studies establish that the in vitro protective effects of vitamin E acetate against sulphydryl and lipid peroxidation extend to protection of the P450 apoprotein but that enzyme activity is only partially protected. This finding suggests that peroxidation-dependent loss of P450 in vitro is mediated by haem degradation from the P450 holoenzyme and is not directly related to lipid/sulphydryl oxidation. In contrast, the in vivo effects of dietary vitamin E on drug metabolizing enzymes are regulatory in nature and are unrelated to effects on lipid peroxidation.     

Therapeutic effect of TRQ on chronic liver injury model in rats induced by CCl4

Rats were treated with CCl4 for 12 weeks to induce chronic liver injury. An administration of tritoqualine (TRQ) to rats was begun 3 weeks after the first CCl4 treatment, and the therapeutic effect of TRQ on this model was investigated. On the 12th week after CCl4 treatment, a marked increase in content of hydroxyproline and histamine in the liver was found. In addition, increased fibrosis around Glisson's sheath was observed under microscopic observation. The increase in these biochemical parameters was suppressed significantly in the rats administered TRQ at doses of 25-100 mg/kg. The histopathological observation demonstrated the suppression of the formation of pseudolobules with fibrinogenesis in the liver of TRQ administered rats. In addition, there was a noticeable improvement in the activity of the liver protein synthesis in the TRQ administered rats when the parameters that represented the hepatic functions were measured. Glutamic oxaloacetic transaminase in the serum of TRQ-administered rats also decreased significantly, compared with the CCl4 treated control rats. From these results, TRQ was shown to exhibit a marked therapeutic effect on liver damage accompanied by chronically accelerated fibrosis in rats which have been treated with CCl4 for 12 weeks.     

Antioxidant and hepatoprotective actions of the medicinal herb Artemisia campestris from the Okinawa Islands

The antioxidant action of Artemisia campestris was examined in vitro and in vivo. A water extract of A. campestris showed a strong scavenging action of 1,1-diphenyl-2-picrylhydrazyl (DPPH), hydroxyl and superoxide anion radicals. When the extract was given intraperitoneally to mice prior to carbon tetrachloride (CCl4) treatment, CCl4-induced liver toxicity, as seen by an elevation of serum aspartate aminotransferase and alanine aminotransferase activities, was significantly reduced. Depression of the elevation of serum enzyme levels after CCl4-treatment was also observed by oral administration of the extract. In that case, CCl4-derived lipid peroxidation in the liver was decreased by the extract treatment. These results suggest that the extract of A. campestris scavenges radicals formed by CCl4 treatment resulting in protection against CCl4-induced liver toxicity.     

Lipid peroxidation and protein thiol depletion are not involved in the cytotoxicity of N-hydroxy-2-acetylaminofluorene in isolated rat hepatocytes

Freshly isolated rat hepatocytes were used to study the mechanism of cell death induced by N-hydroxy-2-acetylaminofluorene (N-OH-AAF). Exposure to 1.0 mM N-OH-AAF resulted in more than 90% cell death (as measured by LDH leakage) of hepatocytes isolated from male rats within 6 hr. Only 36% of the hepatocytes isolated from female rats died within this period. When inorganic sulfate was omitted from the incubation medium, a 6 hr exposure to 1.0 mM N-OH-AAF resulted in only 40% cell death of male hepatocytes. These findings are in accordance with the sex difference and sulfation dependence of N-OH-AAF hepatotoxicity observed in the rat in vivo. N-OH-AAF decreased glutathione (GSH) in male hepatocytes in a concentration-dependent manner. This GSH consumption was only partly dependent on the presence of inorganic sulfate. No lipid peroxidation was observed during N-OH-AAF exposure; N-OH-AAF even prevented endogenous and diethyl maleate (DEM)-induced lipid peroxidation. No reduction of free protein thiol groups was found after exposure to N-OH-AAF, even after 75% cell death had occurred. A reduction of protein thiols after N-OH-AAF exposure was observed in GSH depleted hepatocytes (obtained by DEM plus vitamin E pretreatment). Under these conditions N-OH-AAF-induced cell death occurred earlier. Therefore, GSH protects against protein thiol depletion by N-OH-AAF in control cells. N-OH-AAF-induced cell death was preceded by a loss of intracellular ATP. It is concluded, therefore, that neither lipid peroxidation nor depletion of protein thiols, but possibly loss of intracellular ATP, is involved in the sulfation-dependent cytotoxic mechanism of N-OH-AAF in isolated rat hepatocytes.     

Further examination of the selective toxicity of CCl4 in rat liver slices.

Lipid peroxidation and loss of enzymes located predominantly in either periportal or centrilobular hepatocytes were investigated in precision-cut liver slices from male Sprague-Dawley rats. Pretreatment of animals with 80 mg/kg phenobarbital for the site-specific enzyme studies enhanced and accelerated CCl4 toxicity in slices resulting from increased radical formation. Liver slices were exposed to 0.57 mM CCl4 by vaporization using a roller incubation system at 37 degrees C for a total of 9 hr. Conjugated diene formation, an index of lipid peroxidation, was detected 15 min following CCl4 administration and increased over time. Loss of cytochrome P450 occurred in a time-dependent manner relative to controls where levels in treated slices were 42% of controls at 9 hr. A 48-hr fast prior to termination increased intracellular K+ leakage relative to that present in slices from fed animals. Significant leakage of glucose-6-phosphate dehydrogenase and beta-glucuronidase from centrilobular hepatocytes occurred 9 hr following CCl4 administration. The content of the periportal enzymes (lactate dehydrogenase and sorbitol dehydrogenase) was unchanged in the same slices over the duration of the experiment. Reduction of 3-(4,5-dimethylthiazol-2-yl)-2,5- diphenyltetrazolium bromide, a mitochondrial selective dye and indicator of viability, was significantly lower in treated slices from phenobarbital-treated animals at 9 hr relative to controls. These studies demonstrate that precision-cut slices are an ideal in vitro system for mechanistic studies and the investigation of site-specific toxicants since the integral architecture of the liver and cellular identity are maintained.     

Effect of estrogen on liver plasma membrane in rats.

The effect of estrogen on plasma membrane was investigated using the primary cultured rat hepatocytes treated with carbon tetrachloride (CCl4) and the isolated plasma membrane of rat liver. 17 beta-Estradiol (E2), at concentrations of 10(-10) M to 10(-4) M, 10(-8) M to 10(-6) M and 10(-12) M to 10(-4) M, had an inhibitory effect on the CCl4-induced leakage of glutamic oxaloacetic transaminase, glutamic pyruvic transaminase and lactate dehydrogenase, respectively from primary cultured rat hepatocytes. Diethylstilbestrol, which caused inhibition at a dose of 10(-4) M, did not inhibit any enzyme leakage at any further concentrations of 10(-12) M to 10(-6) M. In the isolated plasma membrane of rat liver, Mg(2+)- and Na+,K(+)-adenosine triphosphatase activity was increased by E2 treatment at concentrations of 10(-6) M and 10(-4) M.     

Effect of iron overload on spontaneous and xenobiotic-induced lipid peroxidation in vivo

To study the effect of iron-overload on hepatic lipid peroxidation, two rat models of haemochromatosis were employed: in the first model resembling secondary haemochromatosis, repeated i.p. injections with Fe-dextran led to an accumulation of Fe in Kupffer cells, while in the second model resembling hereditary haemochromatosis, iron was located mainly in periportal hepatocytes after feeding on a diet containing 3.5% Fe-fumarate for 3 weeks. In both models, total hepatic iron content was elevated four- to fivefold over controls. In vivo lipid peroxidation (ethane exhalation) was enhanced only in the second model, indicating that the hepatocytes are the main targets of Fe-induced lipid peroxidation. Low hepatotoxicity was observed in the second model. Additional treatment of the rats with hepatotoxic agents led to different results: with ethanol and bromobenzene, lipid peroxidation was only evident in both models of iron-overload, while paracetamol-induced lipid peroxidation was seen only in Fe-fumarate-fed rats. CCl4-induced lipid peroxidation was strongly enhanced in both models of haemochromatosis. Hepatotoxicity was enhanced by iron overload only in the case of CCl4-treated, Fe-fumarate-fed rats. The activities of phase I and phase II enzymes of xenobiotic metabolism were not markedly altered in livers of iron-overloaded rats. This implies that neither the bioactivation nor the detoxification of the agents studied were affected in experimental haemochromatosis.     

Protective effect of deferoxamine on chromium(VI)-induced DNA single-strand breaks, cytotoxicity, and lipid peroxidation in primary cultures of rat hepatocytes

Incubation of primary cultures of rat hepatocytes with K₂Cr₂O₇ and deferoxamine (DFO), an iron chelator, resulted in a marked decrease in cellular levels of DNA single-strand breaks caused by K₂Cr₂O₇. Cellular treatment with DFO also suppressed both dichromate-induced cytotoxicity – evaluated by the leakage of lactate dehydrogenase, and lipid peroxidation – as monitored by malondialdehyde formation. In addition, treatment with DFO attenuated the suppression of the levels of vitamin E and C as well as the inhibition of alkaline phosphatase and glutathione peroxidase activity attributed to K₂Cr₂O₇. However, DFO had no influence on the cellular level of glutathione or the activity of glutathione reductase and superoxide dismutase suppressed by dichromate. Under the same experimental conditions, cellular uptake and distribution of chromium were not affected by DFO. These results indicate that DFO protects cells from chromium(VI)-induced DNA strand breaks, cytotoxicity, lipid peroxidation, vitamin E and C depression, and glutathione peroxidase inhibition. The role of antioxidants in chromium(VI)-induced cytotoxicity, DNA breaks, and lipid peroxidation is discussed. Received: 17 September 1996 / Accepted: 25 November 1996