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.     

Relationship between metabolism and cytotoxicity of ortho-phenylphenol in isolated rat hepatocytes.

The relationship between the metabolism and the cytotoxicity of ortho-phenylphenol (OPP) was investigated using isolated rat hepatocytes. Addition of OPP (0.5-1.0 mM) to the hepatocytes caused a dose-dependent toxicity; 1.0 mM OPP caused acute cell death. Pretreatment of hepatocytes with SKF-525A (50 microM, a non-toxic level) enhanced the cytotoxicity of OPP (0.5-1.0 mM). This was accompanied by inhibition of OPP metabolism. Conversely, OPP at low concentrations (0.5 or 0.75 mM) was converted sequentially to phenyl-hydroquinol (PHQ) and then to glutathione (GSH) conjugate in the cells. The concentrations of both metabolites, especially PHQ-GSH conjugate, were very low in hepatocytes exposed to 1.0 mM OPP alone as well as with SKF-525A. The cytotoxicity induced by 0.5 mM OPP was enhanced by the addition of diethylmaleate (1.25 mM) which continuously depletes cellular GSH. In contrast, additions to hepatocytes of 5 mM of dithiothreitol, cysteine, N-acetyl-L-cysteine or ascorbic acid significantly inhibited the cytotoxicity induced by 0.5 mM PHQ; GSH, protein thiols and ATP losses were also prevented. Further, these compounds depressed the rate of PHQ loss in hepatocyte suspensions. These results indicate that the acute cytotoxicity caused by the high dose (1.0 mM) of OPP is associated with direct action by the parent compound; at low doses (0.5-0.75 mM) of OPP, the prolonged depletion of GSH in hepatocytes enhances the cytotoxicity induced by PHQ.     

Effects of dicoumarol on cytotoxicity caused by tert-butylhydroquinone in isolated rat hepatocytes

The effects of dicoumarol, an inhibitor of DT-diaphorase, on the cytotoxicity of tert-butylhydroquinone (tBHQ) were studied in freshly isolated rat hepatocytes. Addition of tBHQ (0.5 mM) to hepatocytes resulted in a time-dependent cell death accompanied by depletion of intracellular ATP, glutathione (GSH), and protein thiols. Pretreatment of hepatocytes with dicoumarol (30 μM) did not affect cell viability or cellular levels of ATP, GSH, or protein thiols during the incubation period; however, dicoumarol did promote the appearance of cell blebs and the depletion of ATP and protein thiols induced by tBHQ and ultimately enhanced the cytotoxicity of tBHQ.     

Sulfhydryl binding and topoisomerase inhibition by PCB metabolites

Polychlorinated biphenyls (PCBs) are highly persistent contaminants in our environment. Their persistence is due to a general resistance to metabolic attack. Lower halogenated PCBs, however, are metabolized to mono- and dihydroxy compounds, and the latter may be further oxidized to quinones with the formation of reactive oxygen species (ROS). We have shown that PCB metabolism generates ROS in vitro and in cells in culture and this leads to oxidative DNA damage, like DNA strand breaks and 8-oxo-dG formation. In the present study, we have evaluated the reactivity of PCB metabolites with other nucleophiles, like glutathione (GSH), by assessing (1) quantitative GSH binding in vitro, (2) GSH and thiol (sulfhydryl) depletion in HL-60 cells, (3) the associated cytotoxicity, and (4) the inhibition of topoisomerase II activity in vitro. PCB quinones were found to bind GSH in vitro at a ratio of 1:1.5 and to deplete GSH in HL-60 cells as measured by both spectrophotometric and spectrofluorometric methods. By flow cytometry analysis, we confirmed that there was intracellular GSH depletion in HL-60 cells by PCB quinones and this is associated with cytotoxicity. On the other hand, the PCB hydroquinone metabolites did not bind GSH or other thiols within 1 h of exposure. However, by spectral analyses we found that the PCB hydroquinones could be oxidized enzymatically to the quinones, which could then bind GSH. The resulting hydroquinone-glutathione addition product(s) could undergo a second and third cycle of oxidation and GSH addition with the formation of di- and tri-GSH-PCB adducts. The effect of the PCB metabolites was also tested on a sulfhydryl-containing enzyme, topoisomerase II. PCB quinones inhibited topoisomerase II activity while the PCB hydroquinone metabolites did not. Hence, the oxidation of PCB hydroquinone metabolites to quinones in cells followed by the binding of quinones to GSH and to protein sulfhydryl groups and the resulting oxidative stress may be important aspects of the toxicity of these compounds.     

Cytotoxicity of propyl gallate and related compounds in rat hepatocytes

 The cytotoxic effects of propyl gallate (PG), its related gallates and gallic acid have been studied in freshly isolated rat hepatocytes. Addition of PG (0.5–2.0 mM) to hepatocyte suspension elicited concentration-dependent cell death accompanied by losses of intracellular ATP, adenine nucleotide pools, glutathione (GSH) and protein thiols. The rapid loss of intracellular ATP preceded the onset of cell death caused by PG. In the comparative toxic effects of PG and related gallates at concentration of 1 mM, octyl gallate (OG), dodecyl gallate (DG) and butyl gallate (BG) elicited an abrupt depletion of ATP, followed by an acute cell death. These gallates were more toxic than PG; the toxic effects of PG were similar to those of methyl gallate (MG) and ethyl gallate (EG). In mitochondria isolated from rat liver, PG caused a concentration-dependent increase in the rate of state 4 oxygen consumption, indicating an uncoupling effect. The rate of state 3 oxygen consumption was inhibited by OG and DG. According to the respiratory control index, the order of impairment potency to mitochondria was OG>BG, DG>PG>EG, MG>gallic acid. These results indicate that PG and related gallates are toxic to hepatocytes and that the acute cytotoxicity may be due to mitochondrial dysfunction. Received: 16 May 1994 / Accepted: 15 August 1994     

Effect of buthionine sulfoximine on orthophenylphenol-induced hepato- and nephrotoxic potential in male rats

A single oral administration of orthophenylphenol (OPP, 1400 mg/kg; about half the LD₅₀) to male Fischer 344 rats produced an elevation of serum transaminase activity 24 h later. Pretreatment with l-buthionine-S,R-sulfoximine (BSO, 900 mg/kg) in the OPP-treated rats potentiated the hepatic and renal damage which was accompanied by necrosis. Six hours after the administration of OPP (700 or 1400 mg/kg), hepatic and renal glutathione (GSH) levels decreased with increasing dosage. Hepatic GSH depletion with OPP was enhanced with BSO pretreatment and the recovery of GSH in both organs was slow in the high-dose OPP group. These results suggest that hepatic and renal damage is associated with a serious and prolonged GSH depletion. When either phenyl-p-benzoquinone (PBQ) or phenylhydroquinone (PHQ), which are intermediates of OPP, was administered orally to rats at 700 or 1400 mg/kg, the mortality with the high dose of PBQ was 75% at 24 h. The serum transaminase activity and UN level increased with the low dose of PBQ, accompanied by necrotic hepatocytes. The toxic effects of PHQ on kidney or liver were less than those on PBQ. These observations suggest that the liver and kidney may be target organs for toxic actions of a large dose of OPP and its intermediate, PBQ.Part of this work was presented at IInd International ISSX Meeting Xenobiotic Metabolism and Disposition, May 16–20, 1988, Kobe, Japan     

Effects of phospholipase A2 inhibitors on diethyl maleate-induced lipid peroxidation and cellular injury in isolated rat hepatocytes

Isolated hepatocytes provide a suitable system for investigation of various aspects of the mechanism of a toxic response. The mechanism by which most chemicals induce hepatotoxicity is still not known. Evidence that phospholipases may play a role in cellular injury has been reported. In the present study the effects of reported inhibitors of phospholipase A2 (quinacrine, chlorpromazine, dexamethasone, and dibutyryl cyclic AMP) on diethyl maleate (DEM)-induced lipid peroxidation, reduced glutathione (GSH) depletion, and cellular injury were examined in isolated hepatocyte suspensions. Hepatocytes were incubated for 7 h under control conditions or with (1) DEM (4 mM), (2) one of the inhibitors (quinacrine, 10, 50, or 150 microM; chlorpromazine, 50 microM; dexamethasone, 0.1, 0.5, 1, or 2.5 mM; dibutyryl cyclic AMP, 0.1, 0.5, 1, or 2.5 mM) or aspirin (500 microM), or (3) a combination of DEM and one of the inhibitors or aspirin to determine their effect on DEM toxicity. Samples were withdrawn at hourly intervals for estimation of cellular injury (loss of intracellular K+ and lactate dehydrogenase and trypan blue exclusion index), lipid peroxidation (thiobarbituric acid reactants assay), and GSH concentration. Quinacrine and chlorpromazine inhibited DEM-induced lipid peroxidation but not cellular injury or GSH loss. This suggests that phospholipase A2 may be involved in DEM-induced lipid peroxidation but not cell damage. However, dexamethasone and dibutyryl cyclic AMP enhanced both lipid peroxidation and loss of cell viability due to DEM, suggesting novel aspects of the biochemical mechanisms of chemically induced cytotoxicity.     

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.     

Metabolites of the biocide o-phenylphenol generate oxidative DNA lesions in V 79 cells

Incubation of the o-phenylphenol (OPP) metabolites, o-phenylhydroquinone (PHQ) and o-phenylbenzoquinone (PBQ) with V 79 Chinese hamster cells led to a significant enhancement of the amount of 8-hydroxy-2'-deoxyguanosine (8-OH-dG) in nuclear DNA. With OPP no distinct induction of this lesion could be observed. In addition, PHQ and PBQ were able to generate DNA single-strand breaks (DNA SSB), while OPP failed to induce this lesion. All incubations were performed for 1 h without exogenous metabolic activations and the lowest effective concentration tested was 20 microM. It is concluded that these metabolites may contribute to the carcinogenicity of OPP and sodium o-phenylphenolate (SOPP) observed in rats, by generating reactive oxygen species (ROS) through their redox cycling properties.     

Biotransformation and cytotoxicity of a brominated flame retardant, tetrabromobisphenol A, and its analogues in rat hepatocytes

The metabolism and cytotoxic effects of tetrabromobisphenol A (TBBPA), a phenolic flame retardant, and its analogues were studied in freshly isolated rat hepatocytes and isolated hepatic mitochondria, respectively. The exposure of hepatocytes to TBBPA 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 oxidized glutathione and malondialdehyde, indicating lipid peroxidation. TBBPA at a weakly toxic level (0.25 mM) was metabolized to monoglucuronide and monosulfate conjugates: the amounts of glucuronide rather than sulfate conjugate predominantly increased, accompanied by a loss of the parent compound, with time. In comparative effects based on cell viability, mitochondrial membrane potential and some toxic parameters, bisphenol A (BPA) was less toxic than TBBPA and tetrachlorobisphenol A (TCBPA), which are not significant differences in these parameters. In mitochondria isolated from rat liver, TBBPA and TCBPA caused an increase in the rate of State 4 oxygen consumption in the presence of succinate, indicating an uncoupling effect and a decrease in the rate of State 3 oxygen consumption in a concentration-dependent manner (5-25 microM). Taken collectively, our results indicate that (i) mitochondria are target organelles for TBBPA, which elicits cytotoxicity through mitochondrial dysfunction related to oxidative phosphorylation at an early stage and subsequently lipid peroxidation at a later stage; and (ii) the toxicity of TBBPA and TCBPA is greater than that of BPA, suggesting the participation of halogen atoms such as bromine and chlorine in the toxicity.     

Cytotoxic effects of 2,6-di-tert-butyl-4-methylphenyl N-methylcarbamate (terbutol) herbicide on hepatocytes and mitochondria isolated from male rats

The cytotoxic effects of 2,6-di-tert-butyl-4-methylphenyl N-methylcarbamate (terbutol) and its major metabolites were investigated in freshly isolated rat hepatocytes. Terbutol and its metabolite, especially 2,6-di-tert-butyl-4-methylphenyl carbamate (N-demethylterbutol), at a concentration of 1.0 mM resulted in a time dependent cell killing accompanied by losses of intracellular ATP, protein thiols, and glutathione (GSH) and the accumulation of oxidized GSH. Supplementation of the hepatocyte suspension with 5 mM N-acetylcysteine, a precursor of intracellular GSH, inhibited the cytotoxicity of N-demethylterbutol. In mitochondria isolated from rat liver, terbutol and its metabolites impaired respiration related to oxidative phosphorylation and the potency of their toxicity is associated with impairment of mitochondrial respiration. These results indicate that N-demethylterbutol is the most cytotoxic followed by terbutol and other metabolites, and that both the mitochondrial respiratory system and protein thiols are important targets for these compounds.     

The toxicity of disulphides to isolated hepatocytes and mitochondria

The disulfide metabolites of thiono-sulfur drugs were found to be about 50 to 100 times more toxic to isolated rat hepatocytes than the corresponding parent drugs. The order of decreasing cytotoxicity for the disulfide metabolites was disulfiram greater than propylthiouracil disulfide greater than formamidine disulfide greater than phenylthiourea disulfide greater than thiobenzamide disulfide greater than cystamine. Depletion of intracellular GSH levels preceded cytotoxicity. GSH could be restored and cytotoxicity averted by adding the thiol reducing dithiothreitol. Depletion of GSH with diethylmaleate potentiated the toxicity of disulfides 3 to 4-fold confirming the protective role of GSH in disulfide toxicity. The toxicity of disulfiram was increased 4-fold in cells pretreated with ATP (0.8 mM) to effect a transient increase in cytosolic Ca2+ suggesting an impairment of Ca2+ homeostasis by the toxicant. Disulfiram (200 microM) rapidly depleted hepatocyte ATP levels within 15 minutes which suggests that ATP production is inhibited. The disulfide effectiveness at causing mitochondrial Ca2+ release was similar to their effectiveness at inducing hepatocyte cytotoxicity. These results suggest that hepatocyte toxicity is the result of oxidative inactivation of membrane protein thiols that regulate intracellular Ca2+ homeostasis.     

Comparative cytotoxic effects of N-acetyl-p-benzoquinone imine and two dimethylated analogues

N-acetyl-p-benzoquinone imine (NAPQI), a reactive metabolite of acetaminophen, has previously been shown to be toxic to hepatocytes freshly isolated from rat liver [Mol. Pharmacol. 28:306-311 (1985)] NAPQI arylates and oxidizes cellular thiols, and either one or both reactions may be important in the pathogenesis of cytotoxicity. Two dimethylated analogues of NAPQI, N-acetyl-3,5-dimethyl-p-benzoquinone imine (3,5-diMeNAPQI) and N-acetyl-2,6-dimethyl-p-benzoquinone imine (2,6-diMeNAPQI), were prepared to determine whether one reaction might be more damaging to cells than the other. Of the three quinone imines, the least potent cytotoxin to rat hepatocytes was 3,5-diMeNAPQI. However, the cytotoxicity of 3,5-diMeNAPQI was markedly enhanced by pretreatment of cells with 1,3-bis-(2-chloroethyl)-N-nitrosourea, which inhibits glutathione reductase. Reactions of 3,5-diMeNAPQI with GSH, both chemically and in hepatocytes, indicated that this quinone imine primarily oxidized thiols. These findings were corroborated by results of covalent binding experiments, which showed that radiolabeled 3,5-diMeNAPQI bound only to a small extent to hepatocyte proteins. On the other hand, 2,6-diMeNAPQI, the most potent cytotoxin of the three quinone imines that was investigated bound extensively to hepatocyte proteins. In addition, 2,6-diMeNAPQI reacted with GSH, both chemically and in hepatocytes, to form significant amounts of GSSG. Reduction products of NAPQI and its dimethylated analogues were not important contributors to cytotoxicity or GSSG formation based on the following results: 1) the quinone imines did not increase oxygen consumption by hepatocytes nor did they lead to oxygen uptake in solution; 2) dicoumarol, an inhibitor of the reductase, DT-diaphorase, had no effect on cytotoxicity caused by the quinone imines. Evidence for the involvement of ipso-adducts of the quinone imines in their reactions with cellular thiols is provided by results of investigations on the effects of DTT on the metabolism, covalent protein binding, and cytotoxic effects of the quinone imines.     

Depletion of cellular protein thiols as an indicator of arylation in isolated trout hepatocytes exposed to 1,4-benzoquinone.

A method to measure protein thiols (PrSH), reduced and oxidized, was adapted to determine PrSH depletion in isolated rainbow trout hepatocytes exposed to arylating agent 1,4-benzoquinone (BQ). Toxicant analysis revealed rapid conversion of BQ to 1, 4-hydroquinone (HQ) upon addition to hepatocytes. Hepatocytes exposed to 200 microM BQ+HQ showed 80% decline in glutathione (GSH) (1 h), 30% loss of PrSH (6 h), and no loss of viability (24 h). Recoverable oxidized PrSH was detected only after 24 h (200 microM BQ+HQ). Exposure to 600 microM BQ+HQ caused rapid (10 min) loss of > 90% GSH and > 60% PrSH, with eventual cell death. Half of the PrSH depletion at 6 h observed in hepatocytes exposed to 600 microM BQ+HQ was recoverable by reduction with dithiothreitol. Following the loss of GSH in hepatocytes exposed to 600 microM BQ+HQ, cellular PrSH were susceptible to direct arylation and oxidation. Rainbow trout hepatocytes, which contained 10-fold less GSH than rat cells, had a GSH:PrSH ratio of 1:82 compared with rat ratios of 1:2 to 1:6. The methods reported are useful for further study and discrimination of reactive modes of action needed for prediction of aquatic organism susceptibility to these types of toxicants.     

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.     

Molecular mechanisms of hydrogen sulfide toxicity

RATIONALE: The toxicity of H2S has been attributed to its ability to inhibit cytochrome c oxidase in a similar manner to HCN. However, the successful use of methemoglobin for the treatment of HCN poisoning was not successful for H2S poisonings even though the ferric heme group of methemoglobin scavenges H2S. Thus, we speculated that other mechanisms contribute to H2S induced cytotoxicity. Experimental procedure. Hepatocyte isolation and viability and enzyme activities were measured as described by Moldeus et al. (1978), and Steen et al. (2001). RESULTS: Incubation of isolated hepatocytes with NaHS solutions (a H2S source) resulted in glutathione (GSH) depletion. Moreover, GSH depletion was also observed in TRIS-HCl buffer (pH 6.0) treated with NaHS. Several ferric chelators (desferoxamime and DETAPAC) and antioxidant enzymes (superoxide dismutase [SOD] and catalase) prevented cell-free and hepatocyte GSH depletion. GSH-depleted hepatocytes were very susceptible to NaHS cytotoxicity, indicating that GSH detoxified NaHS or H2S in cells. Cytotoxicity was also partly prevented by desferoxamine and DETAPC, but it was increased by ferric EDTA or EDTA. Cell-free oxygen consumption experiments in TRIS-HCl buffer showed that NaHS autoxidation formed hydrogen peroxide and was prevented by DETAPC but increased by EDTA. We hypothesize that H2S can reduce intracellular bound ferric iron to form unbound ferrous iron, which activates iron. Additionally, H2S can increase the hepatocyte formation of reactive oxygen species (ROS) (known to occur with electron transport chain). H2S cytotoxicity therefore also involves a reactive sulfur species, which depletes GSH and activates oxygen to form ROS.     

Mechanisms of N-acetyl-p-benzoquinone imine cytotoxicity

N-Acetyl-p-benzoquinone imine (NAPQI), a reactive metabolite of acetaminophen, rapidly reacts at physiological pH with glutathione (GSH) forming an acetaminophen-glutathione conjugate and stoichiometric amounts of acetaminophen and glutathione disulfide (GSSG). The same reaction products are formed in isolated hepatocytes incubated with NAPQI. In hepatocytes which have been treated with 1,3-bis-(2-chloroethyl)-1-nitrosourea (BCNU) in order to inhibit glutathione reductase, the initial rise in GSSG concentration in the presence of NAPQI is maintained, whereas GSSG is rapidly reduced back to GSH in untreated hepatocytes. Oxidation by NAPQI of GSH to GSSG and the reduction of GSSG back to GSH by the NADPH-dependent glutathione reductase appear to be responsible for the rapid oxidation of NADPH that occurs in hepatocytes incubated with NAPQI in that the effect is blocked by pretreatment of cells with BCNU. When added to hepatocytes, NAPQI not only reacts with GSH but also causes a loss in protein thiol groups. The loss in protein thiols occurs more rapidly in cells pretreated with BCNU or diethylmaleate. Whereas both of these treatments enhance cytotoxicity caused by NAPQI, BCNU pretreatment has no effect on the covalent binding of [14C-ring]NAPQI to cellular proteins. Furthermore, dithiothreitol added to isolated hepatocytes after maximal covalent binding of [14C-ring]NAPQI but preceding cell death protects cells from cytotoxicity and regenerates protein thiols. Thus, the toxicity of NAPQI to isolated hepatocytes may result primarily from its oxidative effects on cellular proteins.     

Glyoxal markedly compromises hepatocyte resistance to hydrogen peroxide

Glyoxal is an interesting endogenous alpha-oxoaldehyde as it originates from pathways that have been linked to various pathologies, including lipid peroxidation, DNA oxidation and glucose autoxidation. In our previous study we showed that the LD(50) of glyoxal towards isolated rat hepatocytes was 5mM. However, 10microM glyoxal was sufficient to overcome hepatocyte resistance to H(2)O(2)-mediated cytotoxicity. Hepatocyte GSH oxidation, NADPH oxidation, reactive oxygen species formation, DNA oxidation, protein carbonylation and loss of mitochondrial potential were also markedly increased before cytotoxicity ensued. Cytotoxicity was prevented by glyoxal traps, the ferric chelator, desferoxamine, and antioxidants such as quercetin and propyl gallate. These results suggest there is a powerful relationship between H(2)O(2)-induced oxidative stress and glyoxal which involves an inhibition of the NADPH supply by glyoxal resulting in cytotoxicity caused by H(2)O(2)-induced mitochondrial oxidative stress.     

N-acetylcysteine and glutathione-dependent protective effect of PZ51 (Ebselen) against diquat-induced cytotoxicity in isolated hepatocytes

The glutathione peroxidase (GSH-Px)-like reduction of H2O2 by the selenoorganic compound 2-phenyl-1,2-benzoisoselenazol-3(H)-one (PZ51: Ebselen) was studied using glutathione (GSH) and the therapeutic agent N-acetylcysteine (NAC) to provide reducing equivalents. In a purely chemical system containing H2O2 and in an enzymatic system of glucose/glucose oxidase-generated H2O2 Ebselen alone did not reduce H2O2. Ebselen in combination with either GSH (1 mM) or NAC (1 mM) was capable of reducing H2O2 in both systems. In these non-cellular systems GSH was a more effective source of reducing equivalents than NAC. The GSH-Px-like activity of Ebselen was further investigated in a cellular system. The redox-cycling bipyridylium compound diquat generates active oxygen species, depletes intracellular glutathione, and is cytotoxic in isolated hepatocytes pretreated with the glutathione reductase inhibitor 1,3-bis(Z-chloro-ethyl)-1-nitrosourea (BCNU). Ebselen alone did not ameliorate diquat cytotoxicity, but in combination with either GSH (1 mM) or NAC (1 mM) it produced a significant delay in diquat-induced cytotoxicity. Further additions of either GSH (0.5 mM) or NAC (0.5 mM) at 30 min intervals provided significantly more protection against diquat-induced cytotoxicity and intracellular GSH depletion than the single 1 mM addition. Thus, the combination of Ebselen and NAC may provide an effective antidote in cases of overexposure to bipyridylium herbicides, such as diquat and paraquat.     

Molecular Mechanisms of Hydrogen Sulfide Toxicity

Rationale. The toxicity of H2S has been attributed to its ability to inhibit cytochrome c oxidase in a similar manner to HCN. However, the successful use of methemoglobin for the treatment of HCN poisoning was not successful for H2S poisonings even though the ferric heme group of methemoglobin scavenges H2S. Thus, we speculated that other mechanisms contribute to H2S induced cytotoxicity. Experimental procedure. Hepatocyte isolation and viability and enzyme activities were measured as described by , and . Results. Incubation of isolated hepatocytes with NaHS solutions (a H₂S source) resulted in glutathione (GSH) depletion. Moreover, GSH depletion was also observed in TRIS-HCl buffer (pH 6.0) treated with NaHS. Several ferric chelators (desferoxamime and DETAPAC) and antioxidant enzymes (superoxide dismutase [SOD] and catalase) prevented cell-free and hepatocyte GSH depletion. GSH-depleted hepatocytes were very susceptible to NaHS cytotoxicity, indicating that GSH detoxified NaHS or H₂S in cells. Cytotoxicity was also partly prevented by desferoxamine and DETAPC, but it was increased by ferric EDTA or EDTA. Cell-free oxygen consumption experiments in TRIS-HCl buffer showed that NaHS autoxidation formed hydrogen peroxide and was prevented by DETAPC but increased by EDTA. We hypothesize that H₂S can reduce intracellular bound ferric iron to form unbound ferrous iron, which activates iron. Additionally, H₂S can increase the hepatocyte formation of reactive oxygen species (ROS) (known to occur with electron transport chain). H₂S cytotoxicity therefore also involves a reactive sulfur species, which depletes GSH and activates oxygen to form ROS.