The mechanism of acute cytotoxicity of triethylphosphine gold(I) complexes : II. Triethylphosphine gold chloride-induced alterations in mitochondrial function

Triethylphosphine gold complexes have therapeutic activity in the treatment of rheumatoid arthritis. Many of these compounds are also highly cytotoxic in vitro to a variety of tumor and non-tumor cell lines. Triethylphosphine gold chloride (TEPAu) is highly cytotoxic to isolated rat hepatocytes at concentrations greater than 25 microM. The earliest changes that could be detected in hepatocytes included bleb formation in the plasma membrane, alterations in the morphology of mitochondria, and rapid decreases in cellular ATP and oxygen consumption. The degradation of ATP could be followed sequentially through ADP and AMP and was ultimately accounted for entirely as xanthine. The sum of adenine and xanthine-derived nucleotides remained constant throughout the experiments. TEPAu (50 microM) caused a significant decrease in the hepatocyte ATP/ADP ratio and energy charge within 5 min. The antioxidant, N,N'-diphenyl-p-phenylenediamine (DPPD), which blocked TEPAu-induced malondialdehyde formation but not cell death, also had no effect on the decreases in oxygen consumption, ATP, ATP/ADP ratio, or energy charge. In isolated rat liver mitochondria, TEPAu (1 microM) caused significant reductions in carbonyl cyanide-4-trifluoromethoxyphenylhydrazone (FCCP) (uncoupled)-stimulated respiration. TEPAu (5 microM) inhibited state 3 respiration and the respiratory control ratio without affecting state 4 respiration and caused a rapid dissipation of the mitochondrial-membrane hydrogen-ion gradient (membrane potential). Concentrations greater than 5 microM also inhibited state 4 respiration. TEPAu caused a concentration-dependent inhibition of FCCP-stimulated respiration with pyruvate/malate and succinate as substrates but had not effect on ascorbate/tetramethyl-p-phenylenediamine-supported respiration. The inhibition of state 4 respiration and FCCP-stimulated respiration by TEPAu (10 microM) could be reversed by the addition of 2 mM dithiothreitol. Dithiothreitol also partially protected cells from TEPAu-induced injury and reversed the TEPAu-induced depletion in cellular ATP. These data indicate that TEPAu may be acting functionally as a respiratory site II inhibitor, similar to antimycin. The reversal of TEPAu-induced inhibition of mitochondrial respiration and cell lethality by dithiothreitol suggests that mitochondrial thiols may be involved.     

The mechanism of acute cytotoxicity of triethylphosphine gold(I) complexes. III. Chlorotriethylphosphine gold(I)-induced alterations in isolated rat liver mitochondrial function

Chlorotriethylphosphine gold(I) (TEPAu) is an organo-gold compound that has therapeutic activity in animal models of rheumatoid arthritis. Initial studies have suggested that TEPAu is a potent cytotoxic compound in vitro against a variety of cultured cell types and isolated hepatocytes. Mitochondrial dysfunction induced by this compound has been suggested as a primary biochemical alteration which may result in lethal cell injury in isolated hepatocytes. The purpose of this study was, therefore, to determine the mechanism of TEPAu-induced dysfunction of isolated rat liver mitochondria. TEPAu induced a rapid, concentration-related collapse of the mitochondrial inner membrane potential (EC50 = 24.7 +/- 2.5 microM) which was potentiated in Ca2+ loaded mitochondria (EC50 = 11.3 +/- 3.8 microM). TEPAu-induced collapse of the membrane potential was partially inhibited in the presence of ruthenium red or EGTA. TEPAu caused the rapid release of mitochondrially sequestered Ca2+ which was not inhibited by ruthenium red and, thus, was not via a reversal of the Ca2+ uniporter. TEPAu caused mitochondrial swelling, increased permeability of the inner membrane, and the oxidation/hydrolysis of endogenous mitochondrial pyridine nucleotides. Addition of exogenous ATP slightly reversed the effects of TEPAu on pyridine nucleotides. TEPAu-induced mitochondrial alterations were reversed or inhibited by exposure to the sulfhydryl reducing agent, dithiothreitol. Also, the TEPAu-induced collapse of the mitochondrial membrane potential was partially inhibited by dibucaine, a non-specific inhibitor of phospholipases. These data suggest that TEPAu-induced mitochondrial dysfunction is sulfhydryl dependent. TEPAu-induced mitochondrial dysfunction results in dissipation of the potential difference across the inner mitochondrial membrane which inhibits mitochondrial oxidative phosphorylation. The mechanism by which TEPAu induces the collapse of the membrane potential may be mediated by a sulfhydryl-dependent increase in permeability of the inner membrane to protons.     

Organic hydroperoxide-induced lipid peroxidation and cell death in isolated hepatocytes

Organic hydroperoxides such as tert-butyl hydroperoxide (TBHP) are cytotoxic to suspensions of isolated hepatocytes. The exact mechanism of toxicity is unknown but may involve peroxidation of cellular lipids, alkylation of cellular macromolecules, or alterations in cellular calcium homeostasis. These studies were designed to examine lipid peroxidation as a mechanism of organic hydroperoxide-induced cell death. Hepatocytes isolated from mice were more susceptible to the cytotoxic effects of TBHP than were rat hepatocytes. TBHP-induced cell death was preceded by malondialdehyde formation which was also greater in mouse than rat hepatocytes. Species differences in lipid peroxidation were due to intrinsic properties of hepatocyte membranes as lipids isolated from mouse liver and peroxidized with iron/ascorbate formed approximately eightfold more malondialdehyde than lipids isolated from rat liver. Initiation of lipid peroxidation in mouse and rat hepatocytes with iron/ascorbate caused the formation of malondialdehyde equal to that seen with TBHP and a slight depletion of cellular GSH. As with TBHP, malondialdehyde formation induced by iron/ascorbate was greater in mouse than in rat hepatocytes. However, iron/ascorbate had no effect on hepatocyte viability or morphology from either species. Furthermore, TBHP-induced malondialdehyde and ethane formation in isolated rat hepatocytes were completely blocked by promethazine whereas cell toxicity was altered only slightly. Therefore, these data do not support a role for lipid peroxidation in the acute cytotoxicity of TBHP to suspensions of isolated rat hepatocytes.     

Inhibition of human phospholipase C by aurothiomalate and (triethylphosphine) gold complexes.

The effect of several gold complexes on the activity of phospholipase C from human blood platelets was studied in vitro. Aurothiomalate and auranofin--2 agents used for the chrysotherapy of rheumatoid arthritis--, gold chloride, (triethylphosphine)gold chloride, and 5 newly synthesized (triethylphosphine)gold complexes dose-dependently inhibited the enzyme with IC50 values between 0.8 mumol/l ((triethylphosphine)gold chloride) and over 100 mumol/l (auranofin). None of the compounds affected phospholipase A2 from human polymorphonuclear leukocytes at concentrations up to 100 mumol/l. Inhibition of phospholipase C by (triethylphosphine)gold chloride, aurothiomalate, and compound 3 was not significantly different at substrate concentrations of 20 and 100 mumol/l phosphatidylinositol, suggesting that these gold complexes do not inhibit phospholipase C by competing with the substrate. After confirming the Ca2+ dependence of the human platelet phospholipase C by demonstrating inhibition by the Ca2+ chelators EDTA and EGTA--but no inhibition by the Zn2+ chelator 1,10-phenanthroline--the inhibition of the enzyme by (triethylphosphine)gold chloride, aurothiomalate, and compound 3 was studied at 3 different concentrations of Ca2+ in the range of 0.2 to 2 mmol/l. Inhibition by (triethylphosphine)gold chloride was not affected by changes of Ca2+, whereas inhibition by aurothiomalate and compound 3 was markedly suppressed by increasing the Ca2+ concentration.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mitochondrial thioredoxin reductase inhibition by gold(I) compounds and concurrent stimulation of permeability transition and release of cytochrome c

The effects of auranofin, chloro(triethylphosphine)gold(I) (TEPAu), and aurothiomalate on mitochondrial respiration, pyridine nucleotide redox state, membrane permeability properties, and redox enzymes activities were compared. The three gold(I) derivatives, in the submicromolar range, were extremely potent inhibitors of thioredoxin reductase and stimulators of the mitochondrial membrane permeability transition (MPT). Auranofin appeared as the most effective one. In the micromolar range, it inhibited respiratory chain and glutathione peroxidase activity only slightly if not at all. TEPAu and aurothiomalate exhibited effects similar to auranofin, although TEPAu showed a moderate inhibition on respiration. Aurothiomalate inhibited glutathione peroxidase at concentrations where auranofin and TEPAu were without effect. Under nonswelling conditions, the presence of auranofin and aurothiomalate did not alter the redox properties of the mitochondrial pyridine nucleotides indicating that membrane permeability transition occurred independently of the preliminary oxidation of pyridine nucleotides. Under the same experimental conditions, TEPAu showed a moderate stimulation of pyridine nucleotides oxidation. Mitochondrial total thiol groups, in the presence of the gold(I) derivatives, slightly decreased, indicating the occurrence of an oxidative trend. Concomitantly with MPT, gold(I) compounds determined the release of cytochrome c that, however, occurred also in the presence of cyclosporin A and, partially, of EGTA, indicating its independence of MPT. It is concluded that the specific inhibition of thioredoxin reductase by gold(I) compounds may be the determinant of MPT and the release of cytochrome c.     

Dihydroisotanshinone I protects against menadione-induced toxicity in a primary culture of rat hepatocytes

Dihydroisotanshinone I is a phenanthrenequinone derivative isolated from the roots of Salvia trijuga Diels. The present study demonstrated the hepatoprotective effect of dihydroisotanshinone I against menadione-induced cytotoxicity in a primary culture of rat hepatocytes. Pretreating the cells with dihydroisotanshinone I at concentrations ranging from 2.5 microM to 20 microM for 24 hours caused dose-dependent protection against hepatotoxicity induced by menadione. Intracellular glutathione level and activity of DT-diaphorase have been suggested to play important roles in menadione-induced cytotoxicity. However, treating the hepatocytes with 20 microM dihydroisotanshinone I for 24 hours did not cause a significant change in glutathione level and DT-diaphorase activity. On the contrary, adding dihydroisotanshinone I to freshly isolated hepatocytes at concentrations between 50 nM to 200 nM inhibited NADH-induced superoxide production dose-dependently as indicated by the decrease of lucigenin-amplified chemiluminescence. In addition, dihydroisotanshinone I at concentrations ranging from 5 microM to 20 microM inhibited tert-butyl hydroperoxide-induced lipid peroxidation dose-dependently in isolated hepatocytes as indicated by the level of malondialdehyde. These results suggest that the protective action of dihydroisotanshinone I against menadione-induced hepatotoxicity is attributed to its antioxidant properties including the free radical scavenging activity and inhibition of lipid peroxidation. Abbreviations. DTD:DT-diaphorase GSH:glutathione LDH:lactate dehydrogenase MDA:malondialdehyde MTT:3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide TBHP: tert-butyl hydroperoxide     

N-Nitrosofenfluramine induces cytotoxicity via mitochondrial dysfunction and oxidative stress in isolated rat hepatocytes

The cytotoxic effects of fenfluramine, an appetite suppressant, and its N-nitroso derivative, N-nitrosofenfluramine, have been studied in freshly isolated rat hepatocytes and isolated hepatic mitochondria. Exposure of hepatocytes to N-nitrosofenfluramine caused not only concentration (0.25–1.0 mmol L^–1) and time (0–3 h)-dependent cell death accompanied by the loss of cellular ATP, adenine nucleotide pools, reduced glutathione (GSH), and protein thiols, but also the accumulation of oxidized glutathione and malondialdehyde (MDA), indicating lipid peroxidation. There was a time lag for the onset of the accumulation of MDA after the rapid depletion of ATP. Supplementation of the hepatocyte suspensions with N-acetylcysteine (4 mmol L^–1), a precursor of intracellular GSH, partially inhibited N-nitrosofenfluramine (1 mmol L^–1)-induced cytotoxicity. In comparative effects based on cell viability and rhodamine 123 retention, an index of mitochondrial membrane potential, fenfluramine was less toxic than N-nitrosofenfluramine. In mitochondria isolated from rat liver, N-nitrosofenfluramine caused an increase in the rate of state-4 oxygen consumption, indicating an uncoupling effect, and a decrease in the rate of state-3 oxygen consumption in a concentration-dependent manner. These results indicate that (a) mitochondria are target organelles for N-nitrosofenfluramine, which elicits cytotoxicity through mitochondrial dysfunction related to membrane potential and/or oxidative phosphorylation at an early stage and subsequently lipid peroxidation at a later stage; and (b) the toxicity of N-nitrosofenfluramine is greater than that of fenfluramine, suggesting participation of the nitroso group in the toxicity.     

Cytotoxicity of ortho-phenylphenol in isolated rat hepatocytes.

The effects of ortho-phenylphenol (OPP) and its metabolites, phenyl-hydroquinol (PHQ) and phenyl-benzoquinone (PBQ), on isolated rat hepatocytes were investigated. Addition of OPP (0.5-1.0 mM) to cells caused a dose-dependent cell death accompanied by the depletion of intracellular levels of ATP, glutathione (GSH) and protein thiols. GSH loss correlated with the formation of oxidized GSH. In addition, PHQ and especially PBQ (both at 0.5 mM) resulted in acute cell death with rapid depletion of ATP, GSH and protein thiols, and further low doses of PBQ (10-50 microM) elicited serious impairment of mitochondrial functions related to oxidative phosphorylation and Ca fluxes in isolated liver mitochondria. These results indicate that mitochondria are a target for these compounds and that OPP is itself toxic to hepatocytes even when metabolism is inhibited. The loss of cellular GSH and protein thiols accompanied by the impairment of mitochondrial function may be the main mechanisms of cytotoxicity induced by OPP and its metabolites.     

Role of glutathione depletion in the cytotoxicity of acetaminophen in a primary culture system of rat hepatocytes

A primary culture system of postnatal rat hepatocytes was utilized to study the cytotoxicity of acetaminophen and the toxicological significance of glutathione (GSH) depletion. The relative time of onset and magnitude of GSH depletion, lipid peroxidation and cytotoxicity were contrasted in order to gain insight into their interrelationships. Exposure of the hepatocytes to acetaminophen resulted in time- and dose-dependent depletion of cellular GSH. The acetaminophen-induced GSH depletion and ensuing lactate dehydrogenase (LDH) leakage were quite modest and delayed in onset, in contrast to that caused by iodoacetamide (IAA) and by diethylmaleate (DEM), 2 well-known depletors of GSH. There was comparable LDH leakage, irrespective of drug treatment, when GSH levels decreased to about 20% of normal. Reduction of GSH levels below the 20% threshold by IAA treatment resulted in marked LDH leakage and loss of viability. Maximal LDH leakage in response to IAA and acetaminophen preceded maximal malondialdehyde (MDA) formation, suggesting that lipid peroxidation may be a consequence of cell damage as well as GSH depletion. IAA and DEM produced a comparable, modest accumulation of MDA, yet IAA was much more cytotoxic. These findings indicate that lipid peroxidation does not play a central role in hepatocellular injury by compounds which deplete GSH, although it may contribute to degeneration of the cell. As events in the cultured postnatal hepatocytes paralleled those reported in vivo, the system can be a useful and valid model with which to study mechanisms of chemical toxicity.     

A new approach on methamphetamine-induced hepatotoxicity: involvement of mitochondrial dysfunction

Abstract

1.?Methamphetamine (METH) is a highly addictive stimulant that is among the most widely abused illicit drugs. Clinical evidence has shown that the liver is a target of METH toxicity. The exact cellular and molecular mechanisms involved in METH-induced hepatotoxicity have not yet been completely understood.

2.?In this study, the cellular pathways involved in METH liver toxicity were investigated in freshly isolated rat hepatocytes. METH cytotoxicity was associated with reactive oxygen species (ROS) formation, lipid peroxidation and rapid glutathione (GSH) depletion which is a third marker of cellular oxidative stress. Our results showed that the hepatocyte mitochondrial membrane potential (ΔΨm) was rapidly decreased by METH, which was prevented by antioxidants and ROS scavenger, suggesting that mitochondrial membrane damage was a consequence of ROS formation. Incubation of hepatocytes with METH also caused release of cytochrome c from mitochondria into the cytosol before cell lysis ensued.

3.?Our findings showed that cytotoxic action of METH is mediated by oxidative stress and subsequent changes in mitochondrial membrane conformation and cytochrome c release into the cytosol which causes mitochondrial collapse of ΔΨm.     

Methotrexate induced mitochondrial injury and cytochrome c release in rat liver hepatocytes

Methotrexate (MTX) is a folic acid antagonist that is widely used to treat a variety of diseases. One of the most serious side effects of MTX therapy is hepatotoxicity. The potential molecular cytotoxic mechanisms of MTX toward isolated rat hepatocytes were investigated using Accelerated Cytotoxicity Mechanism Screening (ACMS) techniques. A concentration and time dependent increase in cytotoxicity and reactive oxygen species (ROS) formation and a decrease in mitochondrial membrane potential (MMP) were observed with MTX. Furthermore, a significant increase in MTX (300?μM)-induced cytotoxicity and ROS formation were observed when glutathione (GSH)-depleted hepatocytes were used whereas addition of N-acetylcysteine (a GSH precursor) decreased cytotoxicity. Catalase inactivation also increased MTX-induced cytotoxicity, while the direct addition of catalase to the hepatocytes decreased cytotoxicity. MTX treatment in isolated rat mitochondria caused swelling and significantly decreased adenosine triphosphate (ATP) and GSH content, and cytochrome c release. Potent antioxidants such as mesna, resveratrol and Trolox decreased MTX-induced cytotoxicity and ROS formation and increased MMP. This study suggests that MTX-induced cytotoxicity caused by ROS formation and GSH oxidation leads to oxidative stress and mitochondrial injury in rat hepatocytes.     

Effects of N-acetyl-l-cysteine on target sites of hydroxylated fullerene-induced cytotoxicity in isolated rat hepatocytes

The effects of N-acetyl-l-cysteine (NAC) on cytotoxicity caused by a hydroxylated fullerene [C₆₀(OH)₂₄], which is known a nanomaterial and/or a water-soluble fullerene derivative, were studied in freshly isolated rat hepatocytes. The exposure of hepatocytes to C₆₀(OH)₂₄ at a concentration of 0.1 mM caused time (0–3 h)-dependent cell death accompanied by the formation of cell blebs, loss of cellular ATP, and reduced glutathione (GSH) and protein thiol levels, as well as the accumulation of glutathione disulfide and malondialdehyde (MDA), indicating lipid peroxidation. Despite this, C₆₀(OH)₂₄-induced cytotoxicity was effectively prevented by NAC pretreatment ranging in concentrations from 1 to 5 mM. Further, the loss of mitochondrial membrane potential (MMP) and generation of oxygen radical species in hepatocytes incubated with C₆₀(OH)₂₄ were inhibited by pretreatment with NAC, which caused increases in cellular and/or mitochondrial levels of GSH, accompanied by increased levels of cysteine via enzymatic deacetylation of NAC. On the other hand, severe depletion of cellular GSH levels caused by diethyl maleate at a concentration of 1.25 mM led to the enhancement of C₆₀(OH)₂₄-induced cell death accompanied by a rapid loss of ATP. Taken collectively, these results indicate that pretreatment with NAC ameliorates (a) mitochondrial dysfunction linked to the depletion of ATP, MMP, and mitochondrial GSH level and (b) induction of oxidative stress assessed by reactive oxygen species generation, losses of intracellular GSH and protein thiol levels, and MDA formation caused by C₆₀(OH)₂₄, suggesting that the onset of toxic effects is at least partially attributable to a thiol redox-state imbalance as well as mitochondrial dysfunction related to oxidative phosphorylation.     

Modulation of N-Hydroxyparacetamol Cytotoxicity in Suspensions of Isolated Rat Hepatocytes

Abstract: The effect of inhibitors of toxicity of N-hydroxyparacetamol(N-OH-pHAA), a postulated proximate metabolite of paracetamol, was studied in isolated rat hepatocytes. Additions of ascorbate, menadione, thiol-containing amino acids and glutathione (GSH) led to an increased stability of N-OH-pHAA, reduced the covalent binding of N-OH-pHAA to cellular protein and decreased GSH depletion caused by N-OH-pHAA. Two to three hours elapsed after a 30 min. exposure of the cells to N-OH-pHAA before the cells responded with increased cell permeability. Ascorbate, acetylcysteine, GSH and promethazine were capable of inhibiting this second phase of N-OH-pHAA cytotoxicity in addition to their effects during the initial exposure phase. In contrast, the anti-oxidant tocopherole and phenacetin were only effective during the second phase. Increasing the incubation medium pH during the second phase of N-OH-pHAA mediated cellular damage resulted in decreases in cytotoxicity. Lipid peroxidation, as measured by accumulation of thiobarbituric acid reactive metabolites, did not seem to be directly correlated with cytotoxicity, since cysteamine or higher concentrations of N-OH-pHAA inhibited lipid peroxidation without decreasing cellular damage.     

A comparison of tissue gold levels in guinea-pigs after treatment with myocrisin injected intramuscularly and triethylphosphine gold chloride and myocrisin administered orally.

A comparative study of tissue gold levels produced in guinea-pigs after the oral administration of either triethylphosphine gold chloride or Myocrisin (sodium aurothiomalate) or after the injection of Myocrisin intramuscularly is reported. Gold concentrations were determined 5, 24 and 168 hours after administration in stomach, small intestine, large intestine, kidney, liver and spleen and 5 and 24 hours after administration in skin, adrenals, heart, lung and brain. In gastrointestinal tissues, tissue gold concentrations were highest with triethylphosphine gold chloride. The stomach gold level 5 hours after oral administration of triethylphosphine gold chloride is particularly high and, taken in conjunction with the other gastrointestinal gold levels measured, suggests that a stomach rather than an intestinal absorption mechanism may predominate. A more extensive time-course study on kidney and liver is reported and the possible relationship between tissue concentration and toxicity is discussed.     

S-nitrosyl glutathione-mediated hepatocyte cytotoxicity

1. The addition of n-butyl nitrite (BN) to isolated rat hepatocytes caused rapid S-nitrosyl glutathione (GSNO) formation, then a concomitant decrease in protein thiols, followed by a marked ATP depletion. Cytotoxic concentrations of BN also caused lipid peroxidation after a long lag period but before cytotoxicity ensued.

2. Prior glutathione (GSH) depletion protected hepatocytes against the BN-induced decrease in protein thiols, ATP depletion, lipid peroxidation and cytotoxicity. Thus cytotoxic effects were thought to be mediated via GSNO formed by reaction of BN with GSH, a reaction catalysed by the cytosolic fraction.

3. Cytotoxicity and lipid peroxidation, but not depletion of GSH, protein thiols or ATP, could be averted by the subsequent addition of antioxidants or the iron chelator, desferoxamine.

4. Addition of the thiol reductant, dithiothreitol to BN-treated hepatocytes restored GSH and protein thiols and also prevented cytotoxicity.     

Antioxidative activity of natural isorhapontigenin.

Isorhapontigenin (ISOR), isolated from Belamcanda chinensis, is a derivative of stilbene. Its chemical structure is very similar to that of resveratrol, with a potent antioxidative effect. In the present study, we investigated the antioxidative activity of ISOR in vitro. Oxidative damage of rat liver microsomes, brain mitochondria and synaptosomes was induced by Fe2+-Cys, VitC-ADP-Fe2+ and H2O2, respectively. The formation of malondialdehyde (MDA), decrease of reduced glutathione (GSH) and increase of ultra-weak chemiluminescence during the lipid peroxidation process were determined. In addition, the characteristic ultra-weak chemiluminescence of oxidative DNA damage induced by CuSO4-Phen-VitC-H2O2 system was studied. The results showed that ISOR significantly inhibited MDA formation in liver microsomes, brain mitochondria and synaptosomes induced by Fe2+-Cys. Also, ISOR markedly prevented the decrease of GSH in mitochondria and synaptosomes induced by H2O2 and the increase of ultra-weak chemiluminescence during lipid peroxidation induced by VitC-ADP-Fe2+ as well as oxidative DNA damage induced by CuSO4-Phen-VitC-H2O2. The effects of ISOR at 10(-5) and 10(-6) mol/L on the MDA formation and decrease of GSH were similar to that of the classical antioxidant vitamin E (10(-4) mol/L). It may be concluded that ISOR possessed potent antioxidative activity and was much more potent than vitamin E.     

Hepatocyte toxicity of mechlorethamine and other alkylating anticancer drugs. Role of lipid peroxidation.

The alkylating anticancer drugs, mechlorethamine (HN2), chlorambucil, cyclophosphamide, carmustine and lomustine readily induced cytotoxicity in isolated rat hepatocytes. Hepatocyte glutathione (GSH) was depleted rapidly following addition of the drugs. Lipid peroxidation ensued following GSH depletion and before cytotoxicity occurred. Furthermore, cytotoxicity was delayed by the antioxidants butylated hydroxyanisole (BHA) and alpha-tocopherol, the ferric iron chelator desferoxamine or the radical trap 4-hydroxy-2,2,6,6-tetramethylpiperidine-N-oxyl (TEMPO) even when added 10 min later. HN2 was much less toxic to hepatocytes under nitrogen and caused much less lipid peroxidation than under aerobic conditions. Cytotoxicity induced by HN2 was also prevented by choline, suggesting that a choline carrier is responsible for HN2 uptake in the hepatocytes. Various sulfur compounds acted as antidotes for HN2 cytotoxicity. Thiosulfate was still effective when added 30 min after HN2. Depletion of GSH in the hepatocytes markedly increased their susceptibility to HN2. However, BHA, desferoxamine or TEMPO protected these hepatocytes from HN2. This suggests that antioxidants could prove useful in preventing the increased risk of hepatotoxicity if GSH-depleting agents are used to overcome tumor resistance to nitrogen mustards.     

Ameliorative Effects of Taurine Against Methimazole-Induced Cytotoxicity in Isolated Rat Hepatocytes

Methimazole is used as an antithyroid drug to control the symptoms of hyperthyroidism and maintain patients in a euthyroid state. Administration of this drug is associated with agranulocytosis and hepatotoxicity, which are the two most significant adverse effects. The present investigation was conducted to study the protective role of taurine against cytotoxicity induced by methimazole and its proposed reactive intermediary metabolite, N-methylthiourea, in an in vitro model of isolated rat hepatocytes.At different points in time, markers such as cell viability, reactive oxygen species (ROS) formation, lipid peroxidation, mitochondrial membrane potential, and hepatocyte glutathione content were evaluated.Treating hepatocytes with methimazole resulted in cytotoxicity characterized by the reduction in cell viability, an increase in ROS formation and lipid peroxidation, mitochondrial membrane potential collapse, and a reduction in cellular glutathione content. Furthermore, a significant amount of oxidized glutathione (GSSG) was formed when rat hepatocytes were treated with methimazole. N-methylthiourea toxicity was accompanied by a reduction in cellular GSH content, but no significant changes in lipid peroxidation, ROS formation, GSSG production, or changes in mitochondrial membrane potential were detected. Administration of taurine (200 μM) effectively reduced the toxic effects of methimazole or its metabolite in isolated rat hepatocytes.     

Hepatoprotective dibenzylbutyrolactone lignans of Torreya nucifera against CCl4-induced toxicity in primary cultured rat hepatocytes

Three dibenzylbutyrolactone lignans, (-)-arctigenin, (-)-traxillagenin, and (-)-4'-demethyltraxillagenin, isolated from the bark of Torreya nucifera SIEB. et ZUCC. (Taxaceae) showed significant hepatoprotective activity in primary cultures of rat hepatocytes injured by carbon tetrachloride (CCl(4)). These lignans reduced the release of glutamic pyruvic transaminase into the culture medium from the CCl(4)-injured primary cultures of rat hepatocytes. Further investigation revealed that the three lignans significantly preserved the level of glutathione (GSH) and activities of superoxide dismutase, catalase, glutathione peroxidase, and glutathione reductase in the CCl(4)-injured rat hepatocytes. The lignans also ameliorated lipid peroxidation as demonstrated by a reduction in malondialdehyde-related products. Moreover, these lignans significantly attenuated the GSH reduction caused by diethylmaleate which depletes GSH through the formation of stable conjugates. However, these lignans showed no effect on the GSH synthesis inhibited by buthionine sulfoximine. From these results, it can be concluded that arctigenin, traxillagenin, and 4'-demethyltraxillagenin may protect hepatocytes from CCl(4) injury by maintaining the GSH level.     

Involvement of glutathione in 1-naphthylisothiocyanate (ANIT) metabolism and toxicity to isolated hepatocytes

1-Naphthylisothiocyanate (ANIT) is a model compound which causes cholestasis in laboratory animals. Various biochemical and morphological changes including biliary epithelial and parenchymal cell necrosis occur in the liver of animals treated with ANIT. Although the mechanism(s) for these effects is not understood, a role for glutathione (GSH) in toxicity has been implicated. The possible role of GSH in hepatocellular toxicity caused by ANIT was investigated in this study. Treatment of freshly isolated rat hepatocytes with ANIT caused a concentration- and time-dependent depletion of cellular GSH that preceded lactate dehydrogenase (LDH) leakage. Analysis of the incubation medium indicated that the majority of the cellular GSH which was lost was present extracellularly as GSH or as a GSH-releasing compound. Mixing ANIT with GSH at pH 7.5 yielded a compound that was characterized by HPLC and fast atom bombardment-mass spectrometry (FAB-MS) S-(N-naphthyl-thiocarbamoyl)-L-glutathione (GS-ANIT). When dissolved in aqueous solutions at neutral pH, 95% of GS-ANIT dissociated to yield free ANIT and GSH. Under conditions designed to maximize formation and stability of GS-ANIT, GS-ANIT was found in the extracellular medium of hepatocytes treated with ANIT. Treatment of hepatocytes with the GS-ANIT caused GSH depletion and LDH leakage similar to that observed with equimolar amounts of ANIT. These data suggest that ANIT depletes hepatocytes of GSH through a reversible conjugation process. Such a process may play a role in the toxicity of ANIT.