tert–butylhydroperoxide—Induced toxicity in isolated hepatocytes: Contribution of thiol oxidation and lipid peroxidation

Incubation of isolated rat hepatocytes with tert-butylhydroperoxide resulted in marked cytotoxicity preceded by intracellular glutathione depletion and extensive lipid peroxidation. Addition of antioxidants delayed, but did not prevent, this toxicity. A significant decrease in protein-free sulfhydryl groups also, occurred in the presence of tert-butylhydroperoxide; direct oxidation of protein thiols and mixed disulfide formation with glutathione were responsible for this decrease. The involvement of protein thiol depletion in tert-butylhydroperoxide–induced cytotoxicity is suggested by our observation that administration of dithiothreitol, which caused re-reduction of the oxidized sulfhydryl groups and mixed disulfides, efficiently protected the cells from toxicity. Moreover, depletion of intracellular glutathione by pretreatment of the hepatocytes with diethyl maleate accelerated and enhanced the depletion of protein thiols induced by tert-butylhydroperoxide and potentiated cell toxicity even in the absence of lipid peroxidation.     

Cocaine-induced biochemical changes and cytotoxicity in hepatocytes isolated from both mice and rats

The mechanism of cocaine-induced cytotoxicity was investigated in hepatocytes isolated from both male C3H mice and male Sprague-Dawley rats. Cocaine was more cytotoxic to mouse hepatocytes than rat and induced reduced glutathione (GSH) depletion prior to marked increases in cytotoxicity in both systems. In both mouse and rat cells, GSH depletion was accompanied by GSSG production, but in rat cells, quantitative measures suggested that other mechanisms contributed to GSH depletion. No cocaine-induced depletion of protein-thiol groups or generation of protein-glutathione mixed disulfides could be detected in rat cells. Cocaine induced lipid peroxidation, using malondialdehyde (MDA) production as an index of the peroxidation process, in both mouse and rat hepatocytes. Inhibition of MDA production to below control levels using the antioxidant N,N'-diphenyl-phenylene diamine (DPPD) however, had no inhibitory effect on cocaine-induced cytotoxicity in either mouse or rat cells. These data suggest that neither generalized protein thiol depletion nor lipid peroxidation are critical determinants of cocaine-induced cytotoxicity in cellular systems.     

Alterations in intracellular thiol homeostasis during the metabolism of menadione by isolated rat hepatocytes

The effects of menadione (2-methyl-1,4-naphthoquinone) metabolism on intracellular soluble and protein-bound thiols were investigated in freshly isolated rat hepatocytes. Menadione was found to cause a dose-dependent decrease in intracellular glutathione (GSH) level by three different mechanisms: (a) Oxidation of GSH to glutathione disulfide (GSSG) accounted for 75% of the total GSH loss; (b) About 15% of the cellular GSH reacted directly with menadione to produce a GSH-menadione conjugate which, once formed, was excreted by the cells into the medium; (c) A small amount of GSH (approximately 10%) was recovered by reductive treatment of cell protein with NaBH4, indicating that GSH-protein mixed disulfides were also formed as a result of menadione metabolism. Incubation of hepatocytes with high concentrations of menadione (greater than 200 microM) also induced a marked decrease in protein sulfhydryl groups; this was due to arylation as well as oxidation. Binding of menadione represented, however, a relatively small fraction of the total loss of cellular sulfhydryl groups, since it was possible to recover about 80% of the protein thiols by reductive treatments which did not affect protein binding. This suggests that the loss of protein sulfhydryl groups, like that of GSH, was mainly a result of oxidative processes occurring within the cell during the metabolism of menadione.     

Menadione-induced cytotoxicity is associated with protein thiol oxidation and alteration in intracellular Ca2+ homeostasis

The toxicological implications of alterations in intracellular thiol homeostasis during menadione metabolism have been investigated using freshly isolated rat hepatocytes. A strict correlation between depletion of protein sulfhydryl groups and loss of cell viability was observed. Loss of protein thiols preceded cell death, and occurred more rapidly in cells with decreased levels of reduced glutathione. Depletion of protein thiols was also associated with inhibition of Ca²⁺ efflux from the cells and perturbation of intracellular Ca²⁺ homeostasis. It is proposed that the oxidative stress induced by menadione metabolism in isolated hepatocytes results in the depletion of both soluble and protein thiols, and that the latter effect is critically associated with a perturbation of Ca²⁺ homeostasis and loss of cell viability.     

Role of cellular calcium homeostasis in toxic liver injury induced by the pyrrolizidine alkaloid senecionine and the alkenal trans-4-OH-2-hexenal

The pyrrolizidine alkaloid senecionine has been shown to be hepatotoxic, genotoxic, and cytotoxic. However, the biochemical mechanism by which senecionine produces hepatocellular toxicity remains to be elucidated. The role of calcium homeostasis in toxic liver injury was examined in isolated rat hepatocytes treated with senecionine and trans-4-OH-2-hexenal (t-4HH), a microsomal metabolite of senecionine, and appropriate cofactors. Hepatocytes treated with senecionine and t-4HH demonstrated greater cytotoxicity (leakage of lactate dehydrogenase) when incubated in the absence of extracellular Ca²⁺ than in its presence. Both compounds elicited an increase in cytosolic Ca²⁺ levels of isolated hepatocytes in the presence of extracellular Ca²⁺ In the following study, senecionine and t-4HH depleted intracellular glutathione levels and induced lipid peroxidation and cytotoxicity in isolated hepatocytes. Pretreatment with the thiolgroup reducing agent dithiothreitol prevented depletion of intracellular glutathione and protected hepatocytes against senecionine and t-4HH-induced lipid peroxidation and cytotoxicity. Both compounds also depleted intracellular ATP and NADPH levels. These results suggest that hepatotoxocity induced by senecionine and t-4HH is not dependent on the influx of extracellular Ca²⁺; however, alterations in intracellular Ca²⁺, possibly associated with depletion of intracellular glutathione, NADPH, and ATP, may play a critical role.     

Mechanisms of Trazodone‐Induced Cytotoxicity and the Protective Effects of Melatonin and/or Taurine toward Freshly Isolated Rat Hepatocytes

It has been reported that the bioactive intermediate metabolites of trazodone might cause hepatotoxicity. This study was designed to investigate the exact mechanism of hepatocellular injury induced by trazodone as well as the protective effects of taurine and/or melatonin against this toxicity. Freshly isolated rat hepatocytes were used. Trazodone was cytotoxic and caused cell death with LC₅₀ of 300 µm within 2 h. Trazodone caused an increase in reactive oxygen species (ROS) formation, malondialdehyde accumulation, depletion of intracellular reduced glutathione (GSH), rise of oxidized glutathione disulfide (GSSG), and a decrease in mitochondrial membrane potential, which confirms the role of oxidative stress in trazodone‐induced cytotoxicity. Preincubation of hepatocytes with taurine prevented ROS formation, lipid peroxidation, depletion of intracellular reduced GSH, and increase of oxidized GSSG. Taurine could also protect mitochondria against trazodone‐induced toxicity. Administration of melatonin reduced the toxic effects of trazodone in isolated rat hepatocytes. © 2013 Wiley Periodicals, Inc. J BiochemMol Toxicol 27:457‐462, 2013; View this article online at wileyonlinelibrary.com . DOI 10.1002/jbt.21509     

Glutathione depleting agents and lipid peroxidation

The mechanisms by which glutathione (GSH) depleting agents produce cellular injury, particularly liver cell injury have been reviewed. Among the model molecules most thoroughly investigated are bromobenzene and acetaminophen. The metabolism of these compounds leads to the formation of electrophilic reactants that easily conjugate with GSH. After substantial depletion of GSH, covalent binding of reactive metabolites to cellular macromolecules occurs. When the hepatic GSH depletion reaches a threshold level, lipid peroxidation develops and severe cellular damage is produced. According to experimental evidence, the cell death seems to be more strictly related to lipid peroxidation rather than to covalent binding. Loss of protein sulfhydryl groups may be an important factor in the disturbance of calcium homeostasis which, according to several authors, leads to irreversible cell injury. In the bromobenzene-induced liver injury loss of protein thiols as well as impairment of mitochondrial and microsomal Ca2+ sequestration activities are related to lipid peroxidation. However, some redox active compounds such as menadione and t-butylhydroperoxide produce direct oxidation of protein thiols.     

Lipid peroxidation-dependent and -independent protein thiol modifications in isolated rat hepatocytes: differential effects of vitamin E and disulfiram

Exposure of isolated rat hepatocytes to allyl alcohol (AA), diethyl maleate (DEM) and bromoisovalerylurea (BIU) induced lipid peroxidation, depletion of free protein thiols to about 50% of the control value and cell death. Vitamin E completely prevented lipid peroxidation, protein thiol depletion and cell death. A low concentration (0.1 mM) of the lipophylic disulfide, disulfiram (DSF), also prevented the induction of lipid peroxidation by the hepatotoxins; however, in the presence of DSF, protein thiol depletion and cell death occurred more rapidly. Incubation of cells with a high concentration (10 mM) of DSF alone led to 100% depletion of protein thiols and cell death, which could not be prevented by vitamin E. The level of free protein thiols in cells, decreased to 50% by exposure to AA, DEM and BIU, could be reversed to 75% of the initial level by dithiothreitol (DTT) treatment, indicating that the protein thiols were partially modified into disulfides and partially into other, stable thiol adducts. The 100% depletion of protein thiols by DSF was completely reversed by DTT treatment. The involvement of lipid peroxidation in protein thiol depletion was studied by measuring the effect of a lipid peroxidation product, 4-hydroxynonenal (4-HNE), on protein thiols in a cell free liver fraction. 4-HNE did not induce lipid peroxidation in this system, but protein thiols were depleted to 30% of the initial value, irrespective of the presence of vitamin E. DTT treatment could reverse this for only 25%. Similar, DSF-induced protein thiol depletion could be reversed completely by DTT. We conclude that (at least) two types of protein thiol modifications can occur after exposure of hepatocytes to toxic compounds: one due to interaction of endogeneously generated lipid peroxidation products with protein thiols, which is not reversible by the action of DTT, and one due to a disulfide interchange between disulfides like DSF and protein thiols, which can be reversed by the action of DTT.     

Inhibition of iodoacetamide and t-butylhydroperoxide toxicity in LLC-PK1 cells by antioxidants: a role for lipid peroxidation in alkylation induced cytotoxicity

Previously we reported that thiol depletion and lipid peroxidation were associated with the cytotoxicity of nephrotoxic cysteine S-conjugates, a group of toxins which kill LLC-PK1 cells after metabolic activation and covalent binding. To determine if this is a general mechanism of cytotoxicity in these cells, we compared the effect of antioxidants, an iron chelator, and a thiol reducing agent on the toxicity of an alkylating agent, iodoacetamide (IDAM), and an organic peroxidant, t-butylhydroperoxide (TBHP). IDAM or TBHP toxicity was concentration (0.01 to 1.0 mM) and time (1 to 6 h) dependent. Both toxins caused lipid peroxidation which occurred prior to cell death as determined by leakage of lactate dehydrogenase (LDH). The alkylating agent IDAM bound to cellular macromolecules and depleted cellular non-protein thiols almost completely by 1 h, while LDH release occurred first at 2 to 3 h. The toxicity of IDAM and TBHP was inhibited by the antioxidants DPPD, BHA, BHQ, PGA, and BHT and the iron chelator deferoxamine. However, DPPD blocked TBHP- and IDAM-induced lipid peroxidation and toxicity without affecting binding and depletion of cellular nonprotein thiols. Furthermore, the thiol reducing agent dithiothreitol was able to block lipid peroxidation and toxicity. Therefore it is possible that with an alkylating agent, depletion of cellular nonprotein thiols cooperates with covalent binding and contributes to lipid peroxidation and cell death. There appear to be common elements in the toxicity of alkylating agents and organic peroxidants in LLC-PK1 cells.     

Effects of Oxidative Stress Caused by Hyperoxia and Diquat. A Study in Isolated Hepatocytes

The effects of oxidative stress caused by hyperoxia or administration of the redox active compound diquat were studied in isolated hepatocytes, and the relative contribution of lipid peroxidation, glutathione (GSH) depletion, and NADPH oxidation to the cytotoxicity of active oxygen species was investigated.

The redox cycling of diquat occurred primarily in the microsomal fraction since diquat was found not ' to penetrate into the mitochondria. Depletion of intracellular GSH by pretreatment of the animals with diethyl maleate promoted lipid peroxidation and sensitized the cells to oxidative stress. Diquat toxicity was also greatly enhanced when glutathione reductase was inhibited by pretreatment of the cells with 1,3-bis(2-chloroethyI)-1-nitrosourea. Despite extensive lipid peroxidation, loss of cell viability was not observed, with either hyperoxia or diquat, until the GSH level had fallen below ≈ 6 nmol/10⁶ cells.

The iron chelator desferrioxamine provided complete protection against both diquat-induced lipid peroxidation and loss of cell viability. In contrast, the antioxidant a-tocopherol inhibited lipid peroxidation but provided only partial protection from toxicity. The hydroxy! radical scavenger α-keto-γ-methiol butyric acid, finally, also provided partial protection against diquat toxicity but had no effect on lipid peroxidation.

The results indicate that there is a critical GSH level above which cell death due to oxidative stress is not observed. As long as the glutathione peroxidase – glutathione reductase system is unaffected, even relatively low amounts of GSH can protect the cells by supporting glutathione peroxidase-mediated metabolism of H₂O₂ and lipid hydroperoxides.     

Piperine mediated alterations in lipid peroxidation and cellular thiol status of rat intestinal mucosa and epithelial cells.

Piperine (1-Piperoyl piperidine) is the major alkaloid of black and long peppers used widely in various systems of traditional medicine. The present study investigates the toxicity of piperine via free-radical generation by determining the degree of lipid peroxidation and cellular thiol status in the rat intestine. Lipid peroxidation content, measured as thiobarbituric reactive substances (TBARS), was increased with piperine treatment although conjugate diene levels were not altered. A significant increase in glutathione levels was observed, whereas protein thiols and glutathione reductase activity were not altered. The study suggests that increased TBARS levels may not be a relevant index of cytotoxicity, since thiol redox was not altered, but increased synthesis transport of intracellular GSH pool may play an important role in cell hemostasis and requires further study.     

Three models of free radical-induced cell injury

Three models of free radical-induced cell injury are presented in this review. Each model is described by the mechanism of action of few prototype toxic molecules. Carbon tetrachloride and monobromotrichloromethane were selected as model molecules for alkylating agents that do not induce GSH depletion. Bromobenzene and allyl alcohol were selected as prototypes of GSH depleting agents. Paraquat and menadione were presented as prototypes of redox cycling compounds. All these groups of toxins are converted, during their intracellular metabolism, to active species which can be radical species or electrophilic intermediates. In most cases the activation is catalyzed by the microsomal mixed function oxidase system, while in other cases (e.g. allyl alcohol) cytosolic enzymes are responsible for the activation. Radical species can bind covalently to cellular macromolecules and can promote lipid peroxidation in cellular membranes. Of course both phenomena produce cell damage as in the case of CCl4 or BrCCl3 intoxication. However, the covalent binding is likely to produce damage at the molecular site where it occurs; lipid peroxidation, on the other hand, besides causing loss of membrane structure, also gives rise to toxic products such as 4-hydroxyalkenals and other aldehydes which in principle can move from the site of origin and produce effects at distant sites. Electrophilic intermediates readily reacts with cellular nucleophiles, primarily with GSH. The result is a severe GSH depletion as in the case of bromobenzene or allyl alcohol intoxication. When the depletion reaches some threshold values lipid peroxidation develops abruptly and in an extensive way. This event is accompanied by cellular death. The reason for which lipid peroxidation develops in a cell severely depleted of GSH remains to be clarified. Probably the loss of the defense systems against a constitutive oxidative stress is not compatible with cellular life. Some free radicals generated by one-electron reduction can react with oxygen to give superoxide anions which can be converted to other more dangerous reactive oxygen species. This is the case of paraquat and menadione. Damage to cellular macromolecules is due to the direct action of these oxygen radicals and, at least in the menadione-induced cytotoxicity, lipid peroxidation is not involved. All these initial events affect the protein sulfhydryl groups in the membranes. Since some protein thiols are essential components of the molecular arrangement responsible for the Ca2+ transport across cellular membranes, loss of such thiols can affect the calcium sequestration activity of subcellular compartments, that is the capacity of mitochondria and microsomes to regulate the cytosolic calcium level.(ABSTRACT TRUNCATED AT 400 WORDS)     

Studies on the mechanism of 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine cytotoxicity in isolated hepatocytes

Oxidative stress and covalent binding have been proposed as possible mechanisms involved in the cytotoxic effects of the parkinsonism-causing compound 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP). However, the toxicity induced by MPTP in isolated rat hepatocytes seems to be relatively independent of oxygen radical-induced oxidative stress. Here we demonstrate that MPTP cytotoxicity is not potentiated by pretreatment with 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU), an inhibitor of glutathione reductase, nor prevented by the antioxidant N,N'-diphenyl-p-phenylenediamine (DPPD) or the iron-chelating agent desferrioxamine. Moreover, preincubation of hepatocytes with diethylmaleate to lower the level of intracellular reduced glutathione (to 20% of the initial value) did not affect either the rate or extent of MPTP cytotoxicity. Thus, nucleophilic soluble thiols do not seem to play a protective role against MPTP-induced cell damage, in contrast to what one would have expected if covalent protein binding and oxidative stress were involved as toxic mechanisms. On the other hand, MPTP cytotoxicity was potentiated by pretreatment of hepatocytes with cytochrome P-450 inhibitors (e.g., SKF 525A and metyrapone) and a more rapid depletion of ATP was observed in these experimental conditions. We conclude that mitochondrial damage and subsequent ATP depletion are likely to play a critical role in the toxicity of MPTP to isolated hepatocytes and that the metabolism of MPTP via the cytochrome P-450 monooxygenase system can be considered to be a detoxifying pathway.     

Dexamethasone protects cultured rat hepatocytes against cadmium toxicity: involvement of cellular thiols

In the present study, the effects of dexamethasone on cadmium-induced toxicity were evaluated in isolated rat hepatocytes. Hepatocytes were cultured for 24 h in William’s E medium containing fetal calf serum (10%), insulin (0.1 IU/ml), and glucagon (0.01 μM) in the absence or presence of 0.1 μM dexamethasone. Cadmium chloride, 5 or 10 μM, was added to the medium and the toxicity was evaluated for up to 48 h after treatment. Lactate dehydrogenase (LDH) release, the reduced and oxidized glutathione ratio (GSH/GSSG), protein-SH groups, and lipid peroxidation levels were evaluated. Cadmium induced a dose- and time-dependent LDH release in control hepatocytes at 24 h (Cd 10 μM 42%) while hepatocytes pretreated with dexamethasone showed lower necrosis (Cd 10 μM 12% at 24 h). GSH/GSSH ratio and protein-SH groups were higher while lipid peroxidation was lower in dexamethasone-treated hepatocytes as compared with untreated cells. In conclusion, cadmium toxicity was associated with an increase in intracellular oxidative stress responsible for accelerated cell death. The use of dexamethasone prevented cadmium damage, suggesting that the cytoprotective action of this hormone is related to its effect in preventing changes in thiols such as glutathione and protein-SH groups.     

Oxidative stress studied in intact mammalian cells

Exposure of isolated rat hepatocytes to toxic doses of menadione (2-methyl-1,4-naphthoquinone) results in enhanced formation of active oxygen species, depletion of cellular glutathione and protein thiols, and perturbation of intracellular calcium ion homeostasis. An increase in cytosolic Ca2+ concentration, resulting from inhibition of the plasma membrane Ca2+ translocase by menadione metabolism, appears to be critically involved in the development of cytotoxicity.     

Biotransformation and cytotoxic effects of hydroxychavicol, an intermediate of safrole metabolism, in isolated rat hepatocytes

The biotransformation and cytotoxic effects of hydroxychavicol (HC; 1-allyl-3,4-dihydroxybenzene), which is a catecholic component in piper betel leaf and a major intermediary metabolite of safrole in rats and humans, was studied in freshly isolated rat hepatocytes. The exposure of hepatocytes to HC caused not only concentration (0.25-1.0 mM)- and time (0-3 h)-dependent cell death accompanied by the loss of cellular ATP, adenine nucleotide pools, reduced glutathione, and protein thiols, but also the accumulation of glutathione disulfide and malondialdehyde, indicating lipid peroxidation. At a concentration of 1 mM, the cytotoxic effects of safrole were less than those of HC. The loss of mitochondrial membrane potential and generation of oxygen radical species assayed using 2′,7′-dichlorodihydrofluoresein diacetate (DCFH-DA) in hepatocytes treated with HC were greater than those with safrole. HC at a weakly toxic level (0.25 and/or 0.50 mM) was metabolized to monoglucuronide, monosulfate, and monoglutathione conjugates, which were identified by mass spectra and/or ¹H nuclear magnetic resonance spectra. The amounts of sulfate rather than glucuronide or glutathione conjugate predominantly increased, accompanied by a loss of the parent compound, with time. In hepatocytes pretreated with either diethyl maleate or salicylamide, HC-induced cytotoxicity was enhanced, accompanied by a decrease in the formation of these conjugates and by the inhibition of HC loss. Taken collectively, our results indicate that (a) mitochondria are target organelles for HC, which elicits cytotoxicity through mitochondrial failure related to mitochondrial membrane potential at an early stage and subsequently lipid peroxidation through oxidative stress at a later stage; (b) the onset of cytotoxicity depends on the initial and residual concentrations of HC rather than those of its metabolites; (c) the toxicity of HC is greater than that of safrole, suggesting the participation of a catecholic intermediate in safrole cytotoxicity in rat hepatocytes.     

Cell calcium, vitamin E, and the thiol redox system in cytotoxicity

The controversial role of extracellular Ca2+ in toxicity to in vitro hepatocyte systems is reviewed. Recent reports demonstrate that extracellular Ca2+-related cytotoxicity is dependent on Ca2+-influenced vitamin E (alpha-tocopherol) content of isolated hepatocytes. Based on a Ca2+-omission model of in vitro oxidative stress, the role of vitamin E in cytotoxicity is further explored. This model demonstrates the interdependence of the GSH redox system and vitamin E as protective agents during oxidative stress. Following chemical oxidant-induced depletion of intracellular GSH, cell morphology and viability are maintained by the continuous presence of cellular alpha-tocopherol above a threshold level of 0.6-1.0 nmol/10(6) cells. alpha-Tocopherol threshold-dependent cell viability is directly correlated with the prevention of the loss of cellular protein thiols in the absence of intracellular GSH. Potential mechanisms for this phenomenon are explored and include a direct reductive action of alpha-tocopherol on protein thiyl radicals, and the prevention of oxidation of protein thiols by scavenging of lipid peroxyl radicals by alpha-tocopherol. It is suggested that in light of the threshold phenomenon of vitamin E prevention of potentially severe oxidative stress-induced cytotoxicity, its use as a protective agent against an oxidative challenge in vivo should be reassessed.     

Comparative studies on the mechanisms of paraquat and 1-methyl-4-phenylpyridine (MPP+) cytotoxicity

1-methyl-4-phenylpyridine (MPP+) is the putative toxic metabolite of 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) and is structurally similar to the herbicide paraquat (PQ++). We have therefore compared the effects of MPP+ and PQ++ on a well characterized experimental model, namely isolated rat hepatocytes. PQ++ generates reactive oxygen species within cells by redox cycling and its toxicity to hepatocytes was potentiated by pretreatment with 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU), an inhibitor of glutathione reductase. In BCNU-treated cells, PQ++ caused GSH depletion, lipid peroxidation and cell death. These cytotoxic effects were prevented by the antioxidant N,N'-diphenyl-p-phenylenediamine (DPPD) and the iron-chelating agent desferrioxamine. MPP+ also caused GSH depletion in BCNU-treated hepatocytes but its cytotoxicity was not markedly affected by BCNU, nor was it accompanied by significant lipid peroxidation. DPPD and desferrioxamine also failed to prevent MPP+-induced cell death. We conclude that the production of active oxygen species is likely to play a major role in PQ++ cytotoxicity, while MPP+-induced cell damage may involve additional, more important toxic mechanisms.     

Mechanism of sulfite cytotoxicity in isolated rat hepatocytes

Sulfite (SO(3)(2-)) has been widely used as preservative and antimicrobial in preventing browning of foods and beverages. SO(2), a common air pollutant, also is capable of producing sulfite and bisulfite depending on the pH of solutions. A molybdenum-dependent mitochondrial enzyme, sulfite oxidase, oxidizes sulfite to inorganic sulfate and prevents its toxic effects. In the present study, sulfite toxicity towards isolated rat hepatocytes was markedly increased by partial inhibition of cytochrome a/a(3) by cyanide or by putting rats on a high-tungsten/low-molybdenum diet, which result in inactivation of sulfite oxidase. Sulfite cytotoxicity was accompanied by a rapid disappearance of GSSG followed by a slow depletion of reduced glutathione (GSH). Depleting hepatocyte GSH beforehand increased cytotoxicity of sulfite. On the other hand, dithiothreitol (DTT), a thiol reductant, added even 1h after the addition of sulfite to hepatocytes, prevented cell death and restored hepatocyte GSH levels. Sulfite cytotoxicity was also accompanied by an increase of oxygen uptake, reactive oxygen species (ROS) formation and lipid peroxidation. Cytochrome P450 inhibitors, metyrapone and piperonyl butoxide also prevented sulfite-induced cytotoxicity and lipid peroxidation. Desferroxamine and antioxidants also protected the cells against sulfite toxicity. These findings suggest that cytotoxicity of sulfite is mediated by free radicals as ROS formation increases by sulfite and antioxidants prevent its toxicity. Reaction of sulfite or its free radical metabolite with disulfide bonds of GSSG and GSH results in the compromise of GSH/GSSG antioxidant system leaving the cell susceptible to oxidative stress. Restoring GSH content of the cell or protein-SH groups by DTT can prevent sulfite cytotoxicity.     

Lipid peroxidation-mediated cytotoxicity and DNA damage in U937 cells

Membrane lipid peroxidation processes yield products that may react with DNA and proteins to cause oxidative modifications. In the present study, we evaluated lipid peroxidation-mediated cytotoxicity and oxidative DNA damage in U937 cells. Upon exposure of U937 cells to tert-butylhydroperoxide (t-BOOH) and 2,2'-azobis (2-amidinopropane) hydrochloride (AAPH), which induce lipid peroxidation in membranes, the cells exhibited a reduction in viability and an increase in the endogenous production of reactive oxygen species (ROS), as measured by the oxidation of 2',7'-dichlorodihydrofluorescein. In addition, a significant decrease in the intracellular GSH level and the activities of major antioxidant enzymes were observed. We also observed lipid peroxidation-mediated oxidative DNA damage, reflected by an increase in 8-OH-dG level and loss of the ability of DNA to renature. When the cells were pretreated with the antioxidant N-acetylcysteine (NAC) or the spin trap alpha-phenyl-N-t-butylnitrone (PBN), lipid peroxidation-mediated cytotoxicity in U937 cells was protected. This effect seems to be due to the ability of NAC and PBN to reduce ROS generation induced by lipid peroxidation. These results suggest that lipid peroxidation resulted in a pro-oxidant condition of U937 cells by the depletion of GSH and inactivation of antioxidant enzymes, which consequently leads to a decrease in survival and oxidative damage to DNA. The results indicate that the peroxidation of lipid is probably one of the important intermediary events in oxidative stress-induced cellular damage.