Lipoic acid increases glutathione production and enhances the effect of mercury in human cell lines

Thiols are known to influence the metabolism of glutathione. In a previous study (Toxicology 156 (2001) 93) dithiothreitol (DTT) did not show any effect on intra- or extracellular glutathione concentrations in HeLa cell cultures but increased the effects of mercury ions on glutathione concentrations, whereas monothiols such as N-acetylcysteine (NAC) or glutathione did not. In the present study, we have investigated the effects of thiols as well as the interaction between thiols and mercury ions in cultures of both HeLa and hepatoma cells. Furthermore, we have added alpha-lipoic acid (LA) to the previously used test panel of thiols, since it is metabolised intracellularly to a dithiol (dihydrolipoate). The present study shows that LA increased intra- and extracellular concentrations of glutathione in both HeLa and hepatoma cell cultures. In contrast to results for HeLa cells, the presence of DTT increased the intracellular glutathione concentration in hepatoma cells. No increase of glutathione concentrations was observed in hepatoma cell cultures in the presence of the monothiols (NAC, homocysteine or glutathione) tested, in agreement with previous findings in HeLa cell cultures. The presence of dithiols, either DTT or dihydrolipoate (the metabolite of LA), increased the effects of mercury ions on glutathione concentrations in hepatoma cells, whereas monothiols such as NAC or glutathione did not, in agreement with previous findings in HeLa cells. Thus, metabolic effects of mercury ions were observed in hepatoma cells as well as in HeLa cells at a lower concentration than the supposed toxicity threshold for mercury in blood.     

Reversibility of copper-thiol binding in Nitzschia closterium and Chlorella pyrenoidosa

The effect of ionic copper and copper complexes on intracellular thiols in the marine diatom Nitzschia closterium (Ehrenberg) W. Smith, and the green alga Chlorella pyrenoidosa Chick was studied using the lipid-soluble thiol reagent, dithiodipyridine. Treatment of cells with copper ions significantly reduced the concentration of intracellular thiol groups, whereas copper complexes and H₂O₂ had no effect.To test the reversibility of intracellular copper-thiol binding in N. closterium and C. pyrenoidosa, cells exposed to copper (60–200 μg Cu·1⁻¹) were treated with various sulfhydryl compounds and chelating agents, with and without removal of copper from solution. Cysteine, glutathione (GSH), EDTA and bathocuproine disulfonate were most effective in reversing copper toxicity, whereas oxidized glutathione, cystine and glycine had no effect. It is proposed that copper (II) adsorbed to the algae is reduced to copper (I) by -SH groups, and bound as a Cu(I)-S-complex. Sulfhydryl compounds can reverse toxicity through thiol-disulfide interchange reactions, allowing algal growth to recommence, and powerful copper-chelating agents produce the same effect by withdrawing copper from the cell.     

Vanadium and copper in clinical solutions of albumin and their potential to damage protein structure.

Solutions of albumin, for injectable use in humans, are shown to contain the transition metals vanadium, copper, and iron. Variation in the concentration of these metal ions among products from six different manufacturers suggests that problems of metal contamination arise through manufacturing processes. Vanadium concentrations correlated with the loss of tryptophan residues in albumin, whereas copper concentrations correlated with loss of thiol groups and tryptophan residues. Incubation of vanadate and cupric salts with the thiol group-containing molecules cysteine and glutathione resulted in reduction of the metal ions to lower oxidation states. Reduced forms of vanadium and copper were able to transfer electrons to molecular oxygen and produce highly reactive and damaging intermediates of oxygen, such as the hydroxyl radical.     

Relationship of non-protein thiol pools and accumulated Cd or Hg in the marine macrophyte Posidonia oceanica (L.) Delile

The accumulation of cadmium or mercury and the effect of these elements on the levels of non-protein thiols in the blades of the marine macrophyte Posidonia oceanica were investigated. A significant accumulation of cadmium or mercury, dependent on metal concentration supplied, was observed in metal-treated blades. In the blades treated either with cadmium or mercury, a significant increase in the levels of non-protein thiols (other than glutathione) and a marked depletion of the reduced glutathione content as a function of the metal, exposure time and metal concentration supplied were found. This investigation provides first experimental report on the relationship between non-protein thiol pools and accumulated cadmium or mercury in P. oceanica.     

Oxidation of proximal protein sulfhydryls by phenanthraquinone, a component of diesel exhaust particles

Diesel exhaust particles (DEP) contain quinones that are capable of catalyzing the generation of reactive oxygen species in biological systems, resulting in induction of oxidative stress. In the present study, we explored sulfhydryl oxidation by phenanthraquinone, a component of DEP, using thiol compounds and protein preparations. Phenanthraquinone reacted readily with dithiol compounds such as dithiothreitol (DTT), 2,3-dimercapto-1-propanol (BAL), and 2,3-dimercapto-1-propanesulfonic acid (DMPS), resulting in modification of the thiol groups, whereas minimal reactivities of this quinone with monothiol compounds such as GSH, 2-mercaptoethanol, and N-acetyl-L-cysteine were seen. The modification of DTT dithiol caused by phenanthraquinone proceeded under anaerobic conditions but was accelerated by molecular oxygen. Phenanthraquinone was also capable of modifying thiol groups in pulmonary microsomes from rats and total membrane preparation isolated from bovine aortic endothelial cells (BAEC), but not bovine serum albumin (BSA), which has a Cys34 as a reactive monothiol group. A comparison of the thiol alkylating agent N-ethylmaleimide (NEM) with that of phenanthraquinone indicates that the two mechanisms of thiol modification are distinct. Studies revealed that thiyl radical intermediates and reactive oxygen species were generated during interaction of phenanthraquinone with DTT. From these findings, it is suggested that phenanthraquinone-mediated destruction of protein sulfhydryls appears to involve the oxidation of presumably proximal thiols and the reduction of molecular oxygen.     

Enzyme activity and sulfhydryl status in rat renal cortex following mercuric chloride and dithiothreitol administration

Previous experiments indicated that the partial reversal of mercuric chloride-induced renal dysfunction in rats by subsequent dithiothreitol (DTT) administration was not related to increased mercury excretion, decreased renal mercury concentration, a change in renal cortical subcellular mercury distribution, or the formation of a Hg-DTT complex. The present studies investigated whether DTT, a sulfhydryl reducing agent, protected renal cortical sulfhydryl status in general, or the activity of various renal enzymes (Mg- and Na,K-ATPases, alkaline phosphatase, and glutathione peroxidase) in particular. Additionally, the occurrence of conjugated dienes was used to assess the degree of lipid peroxidation. HgCl2 produced significant decreases in renal cortical protein-bound sulfhydryl concentration, alkaline phosphatase activity, and ATPase activity within 2.5 h of administration, with no effect observed on glutathione peroxidase activity or the levels of conjugated dienes in rat renal cortex. Administration of DTT 60 min after mercury neither provided protection from inhibition nor promoted restoration of the affected enzymes or sulfhydryl status. It is concluded that the partial protection of renal function offered by DTT in the early stages of mercury toxicity does not result from maintaining the integrity of renal cortical sulfhydryl status or the activity of the enzymes investigated. Furthermore, the early stages of mercury toxicity did not appear to be related to lipid peroxidation.     

Molecular interactions with mercury in the kidney

Mercury is unique among the heavy metals in that it can exist in several physical and chemical forms, including elemental mercury, which is a liquid at room temperature. All forms of mercury have toxic effects in a number of organs, especially in the kidneys. Within the kidney, the pars recta of the proximal tubule is the most vulnerable segment of the nephron to the toxic effects of mercury. The biological and toxicological activity of mercurous and mercuric ions in the kidney can be defined largely by the molecular interactions that occur at critical nucleophilic sites in and around target cells. Because of the high bonding affinity between mercury and sulfur, there is particular interest in the interactions that occur between mercuric ions and the thiol group(s) of proteins, peptides and amino acids. Molecular interactions with sulfhydryl groups in molecules of albumin, metallothionein, glutathione, and cysteine have been implicated in mechanisms involved in the proximal tubular uptake, accumulation, transport, and toxicity of mercuric ions. In addition, the susceptibility of target cells in the kidneys to the injurious effects of mercury is modified by a number of intracellular and extracellular factors relating to several thiol-containing molecules. These very factors are the theoretical basis for most of the currently employed therapeutic strategies. This review provides an update on the current body of knowledge regarding the molecular interactions that occur between mercury and various thiol-containing molecules with respect to the mechanisms involved in the renal cellular uptake, accumulation, elimination, and toxicity of mercury.     

Selenium in water enhances antioxidant defenses and protects against copper-induced DNA damage in the blue mussel Mytilus edulis

Selenium and copper are naturally occurring elements in the environment that have important roles in cellular function. Selenium is known for its role in antioxidant defense, whereas copper is a redox-active metal capable of acting as a pro-oxidant. We investigated the effects of short term selenium (Na₂SeO₃) supplementation (4 μg/L for 3 days) on antioxidant parameters of the blue mussel, Mytilus edulis, and its possible protective effects against a subsequent copper (CuSO₄) exposure (56 μg/L for 3 days). Selenium supplementation caused a 4-fold increase in glutathione levels in gills. The activity of selenium-dependent glutathione peroxidase was modulated by selenium in gills (2-fold increase) and also in cell-free haemolymph (40% increase). Copper exposure produced decreases in protein thiol levels (35%) and in thioredoxin reductase activity (60%) in gills and induced an increase in DNA damage in haemocytes (70% increase in % tail DNA observed using the comet assay). The decrease in thioredoxin reductase activity may constitute a mechanism of copper toxicity in bivalves, warranting further investigation. Pre-treatment with selenium largely prevented these deleterious effects of copper on protein thiols, thioredoxin reductase activity and DNA damage. The results suggest that induction of key antioxidant defenses such as glutathione and selenium-dependent glutathione peroxidase, as a result of selenium supplementation, may play an important role in protection of aquatic organisms against oxidative stress.     

Mercaptodextran, a metal-chelating and disulphide-reducing polythiol of high molecular weight

A high molecular weight polythiol, mercaptodextran has been synthesized by thiolating various dextrans with N-acetyl homocysteine thiolactone. The thiol groups are unusually stable towards autoxidation. They are highly reactive and readily reduce disulphide bonds. Because of these properties mercaptodextran may be used to keep autoxidizable thiols in the reduced form. Mercaptodextran has no radioprotective effect, since it does not penetrate the cellular membrane. Mercaptodextran has a very high affinity for heavy metal ions. Competitive binding experiments show that mercapto-dextran has much higher affinity for silver, mercuric, cupric and auric ions than most other thiols (glutathione, penicillamine, N-acetyl-DL-penicillamine, cysteamine, mercapto-propionyl glycine, cysteine and diethyl dithiocarbamate) and other chelating agents (EDTA). Only 2,3-dimercaptopropanol (BAL) shows comparable binding properties. The stability constants for the Hg-BAL and Hg-mercaptodextran complexes are both about 10²⁰, and about 100-times higher than for the Hg-penicillamine complex. The high metal-binding ability combined with a low toxicity suggest a possible use of mercaptodextran in acute metal-intoxications.     

TOXICITY OF TRACE ELEMENTS IN TOBACCO SMOKE

The potential to cause cellular damage by metal ions in conjunction with other constituents of tobacco smoke is enormous. Various studies have demonstrated the role of reactive oxygen species in the toxicity of transition metals, and the presence of many highly reactive metal ions in high concentrations in tobacco smoke indicates a role for metal ions in the subsequent toxicity and carcinogenicity of tobacco smoke. This review summarizes current information pertaining to the role of metal ions in the toxicity and carcinogenicity of tobacco smoke, and describes the mechanisms that may be involved. Evidence indicates that multiple mechanisms may be involved in the production of reactive oxygen species involving metal ions in tobacco smoke. Similar mechanisms involving redox cycling with the production of superoxide anion, hydrogen peroxide, and hydroxyl radical appear to be involved for iron, copper, and chromium. However, some metal ions, such as nickel, lead, cadmium, mercury, arsenic, and antimony, deplete glutathione and protein-bound sulfhydryls, thus contributing to an oxidative stress in this manner. Reactions involved in the production of reactive oxygen species may be commonly associated withmost membranous fractions of the lungs as mitochondria, microsomes, and peroxisomes. Furthermore, phagocytic cells accumulate in the lungs of smokers, and are another important source of reactive oxygen species. These phagocytic cells accumulate metal ions as iron, which catalyzes the formation of reactive oxygen species. Thus, a single metal ion may initiate formation of reactive oxygen species by more than a single mechanism, and involve more than one organelle or cell type. Metal ions can also act as catalysts for the formation of reactive oxygen species and various free radicals by numerous organic, redox cycling constituents such as hydroquinone and catechol, which are present in tobacco smoke, thus greatly enhancing the potential for tissue damaging effects in lungs. Finally, radioactive elements such as polonium-210 in tobacco smoke are additional contributing factors to the production of tissue damage. The cumulative and summative effects of metal ions are believed to play a significant role in the toxicity and carcinogenicity of tobacco smoke.     

Critical role of sulfenic acid formation of thiols in the inactivation of glyceraldehyde-3-phosphate dehydrogenase by nitric oxide.

The relationship between possible modifications of the thiol groups of glyceraldehyde-3-phosphate dehydrogenase (GAPDH) by nitric oxide (NO) and modified enzyme activity was examined. There are 16 free thiols, including 4 active site thiols, in a tetramer of GAPDH molecule. NO donors, sodium nitroprusside (SNP), and S-nitroso-N-acetyl-DL-penicillamine (SNAP) decreased the number of free thiols with a concomitant inhibition of GAPDH activity in a concentration- and time-dependent manner. After treatment for 30 min, free thiols were maximally decreased to 8-10 per GAPDH tetramer and enzyme activity was also inhibited to 5-10% of control activity. In the presence of 30 mM dithiothreitol (DTT), these effects were completely blocked. Since similar results were obtained in the case of hydrogen peroxide (H2O2) treatment, which is known to oxidize the thiols, these effects of nitric oxide donors were probably due to modification of thiol groups present in a GAPDH molecule. On the other hand, DTT posttreatment after the treatment of GAPDH with SNP, SNAP, or H2O2 did not completely restore the modified thiols and the inhibited enzyme activity. DTT posttreatment after the 30-min-treatment with these agents restored free thiols to 14 in all treatments. In the case of SNAP treatment, all 4 active sites were restored and enzyme activity reached more than 80% of the control activity, but in two other cases one active site remained modified and enzyme activity was restored to about only 20%. Therefore, all 4 free thiols in the active site seem to be very important for full enzyme activity. DTT posttreatment in the presence of sodium arsenite, which is known to reduce sulfenic acid to thiol, almost completely restored both thiol groups and enzyme activity. These findings suggest that nitric oxide inhibits GAPDH activity by modifications of the thiols which are essential for this activity, and that the modification includes formation of sulfenic acid, which is not restored by DTT. S-nitrosylation, which is one type of thiol modification by NO, occurred when GAPDH was treated with SNAP but not SNP. Analysis of thiol modification showed that SNAP preferentially nitrosylated the active site thiols, the nitrosylation of which fully disappeared by DTT posttreatment. It seems that SNAP nitrosylates the active site thiols of GAPDH to prevent these thiols from oxidizing to sulfenic acid.     

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.     

Mercury impairment of mouse thymocyte survival in vitro: involvement of cellular thiols

Heavy metals are well known to be able to induce immunotoxicity, but comparative metal studies related to apoptosis have not been conducted. In the present study, the effects of arsenic, cadmium, gold, lead, manganese, and mercury on thymocytes from BALB/c mice were analyzed. Thymic cells were cultured for 3-24 h in vitro in the absence or presence of metal, and markers of apoptosis or cell death, including annexin V binding, DNA loss/oligonucleosomal fragmentation, 7-amino-actinomycin D uptake (loss of impermeance), changes of the mitochondrial membrane potential (JC-1 fluorescence), and Western analysis of cellular thiols, were assayed. Mercury (Hg) was the only metal shown to be consistently toxic with the dose and times utilized. Cadmium (Cd) was the only other metal tested that also produced some significant level of DNA loss; however, the induction of apoptosis by Cd was not as consistent as that observed with Hg. When Hg was added with 2-mercaptoethanol (2-ME), Hg produced greater toxicity. Endogenous DNA synthesis by thymocytes was immediately inhibited by Hg and Hg + 2-ME. The Hg + 2-ME-induced apoptosis appeared to be associated with altered levels of cellular thiols, in that glutathione (GSH) depletion was significant in comparison to the non-metal control and Hg alone. The increased Hg-induced toxicity in the presence of 2-ME likely was due to the ability of 2-ME to enhance (10- to 20-fold) the cellular uptake of Hg. Western analysis with biotin maleimide demonstrated that Hg + 2-ME and to a lesser extent the positive control dexamethasone eliminated many reactive thiols; the major thiol-reactive protein still reactive with the maleimide probe had an approximate Molecular Mass of 45 kD. Surprisingly, Hg alone enhanced the expression of this thiol-expressing protein, which by Mass Spectrometry (MS)/MS analysis was shown to be beta-actin. Hg also produced the appearance of yet to be identified new proteins. Based on the results with Hg + 2-ME, it is suggested that numerous protein thiols participate in maintenance of cell survival and their loss is associated with apoptosis. The increased expression of new thiol-reactive proteins or thiol-reactive proteins with altered electrophoretic profiles needs to be further investigated. However, the enhanced toxicity attributed to Hg + 2-ME suggests that increased intracellular oxidative stress, observed as increased depletion of GSH, is responsible for the accelerated cell death.     

The anti-inflammatory activity of Ebselen but not thiols in experimental alveolitis and bronchiolitis

This paper describes the effects of the thiol compounds glutathione and N-acetylcysteine and the seleno-organic agent Ebselen on the development of Sephadex-induced lung edema and cell infiltration in the rat. Neither thiol had any effect upon the development of the edema when administered in large, repeated doses. In contrast, when Ebselen was co-administered with the thiols, there was a dose-dependent inhibition of the development of the edema, but lung weights could not be returned to normal values. However, when the thiols were omitted and Ebselen was administered alone, the development of the edema was totally blocked. In addition, in Ebselen-only treated animals there was a selective inhibition of the infiltration of lymphocytes, basophils and eosinophils into the lung lumen without affecting the populations of macrophages and neutrophils. Again, the Ebselen-induced effect was reduced by coadministration of either thiol. These findings are discussed in terms of the potential mechanism of action of Ebselen in vivo and of the possibility of Ebselen being of therapeutic potential in cases of diffuse pulmonary inflammation in humans.     

Structure-activity relationships for hepatocyte toxicity and electrophilic reactivity of alpha,beta-unsaturated esters, acrylates and methacrylates

Covalent binding of reactive electrophiles to cellular targets is a molecular interaction that has the potential to initiate severe adverse biological effects. Therefore, electrophile reactivity towards biological nucleophiles could serve as an important correlate for toxic effects such as hepatocyte death. To determine if reactivity correlates with rat hepatotoxicity, alpha,beta-unsaturated esters, consisting of acrylates and methacrylates, that are inherently electrophilic and exhibit widely varying degrees of reactivity were investigated. Reactivity was measured using simple assays with glutathione and butylamine as surrogates for soft thiol and hard amino biological nucleophile targets. A linear relationship was observed between hepatotoxicity and thiol reactivity only, while no amine reactivity was observed. Structure-activity relationships were also investigated, with results showing toxicity was well modeled by electronic parameters E(LUMO) and partial charge of the carbon atoms in the reactive center. No relationship was observed between toxicity and logP. These results suggest that differences in hepatocyte toxicity of acrylates and methacrylates can be related to their electrophilic reactivity which corresponds to their ability to deplete GSH and protein thiols.     

Thiolic antioxidants protect from nitric oxide-induced toxicity in fetal midbrain cultures

Nitric oxide (NO) may act as a neuroprotector or neurotoxic agent in dopamine neurons, depending on cell redox status. We have investigated the effect of several thiolic antioxidants, glutathione (GSH), its cell permeable analog GSH ethyl ester (GSHEE), and the GSH synthesis precursor L-N-acetyl cysteine (L-NAC), as well as non-thiolic antioxidants like ascorbic acid (AA) and uric acid, on NO-induced toxicity in fetal midbrain cultures. The cultures were treated for 8-24 h with neurotoxic doses of the NO donor diethylamine/nitric oxide complex sodium DEA/NO (200-400 micro M) and/or antioxidants. Thiolic antioxidants, at equimolar concentrations, added at the same time or previous to DEA/NO, protected from cell death, from tyrosine hydroxylase (TH) positive cell number decrease and from intracellular GSH depletion, induced by DEA/NO, without increasing intracellular GSH content. In these conditions, S-nitrosothiol compound formation was detected in the culture media. Protection disappeared when antioxidants were supplied 30 min after NO treatment. Nevertheless, non-thiolic antioxidants, AA and uric acid, with similar peroxynitrite scavenging activity to thiolic antioxidants, and free radical-scavenging enzymes as catalase and Cu/Zn-superoxide dismutase, which prevent extracellular peroxynitrite ion formation, and 4,5-dihydroxy-1,3-benzene-disulfonic acid (Tiron), which prevents intracellular peroxynitrite ion formation, did not rescue cell cultures from neurotoxicity induced by NO. In addition, AA exacerbated DEA/NO-induced toxicity in a dose-dependent manner from 200 micro M AA. The present results suggest that only antioxidants with thiol group exert neuroprotection from NO-induced toxicity in fetal midbrain cultures, probably by direct interaction of NO and thiol groups, resulting in NO blocking. On the other hand, some classical antioxidants, like AA, exacerbate neurotoxicity due to NO.     

Effects of 2,3-dimercapto-1-propanesulfonic acid (DMPS) on methylmercury-induced locomotor deficits and cerebellar toxicity in mice

Chelating therapy has been reported as a useful approach for counteracting mercurial toxicity. Moreover, 2,3-dimercapto-1-propanesulfonic acid (DMPS), a tissue-permeable metal chelator, was found to increase urinary mercury excretion and decrease mercury content in rat brain after methylmercury (MeHg) exposure. We evaluated the capability of DMPS to reduce MeHg-induced motor impairment and cerebellar toxicity in adult mice. Animals were exposed to MeHg (40 mg/L in drinking water, ad libitum) during 17 days. In the last 3 days of exposure (days 15-17), animals received DMPS injections (150 mg/kg, i.p.; once a day) in order to reverse MeHg-induced neurotoxicity. Twenty-four hours after the last injection (day 18), behavioral tests related to the motor function (open field and rotarod tasks) and biochemical analyses on oxidative stress-related parameters (cerebellar glutathione, protein thiol and malondyaldehyde levels, glutathione peroxidase and glutathione reductase activities) were carried out. Histological analyses for quantifying cellular damage and mercury deposition in the cerebellum were also performed. MeHg exposure induced a significant motor deficit, observed as decreased locomotor activity in the open field and decreased falling latency in the rotarod apparatus. DMPS treatment displayed an ameliorative effect toward such behavioral parameters. Cerebellar glutathione and protein thiol levels were not changed by MeHg or DMPS treatment. Conversely, the levels of cerebellar thiobarbituric acid reactive substances (TBARS), a marker for lipid peroxidation, were increased in MeHg-exposed mice and DMPS administration minimized such phenomenon. Cerebellar glutathione peroxidase activity was decreased in the MeHg-exposed animals, but DMPS treatment did not prevent such event. Histological analyses showed a reduced number of cerebellar Purkinje cells in MeHg-treated mice and this phenomenon was completely reversed by DMPS treatment. A marked mercury deposition in the cerebellar cortex was observed in MeHg-exposed animals (granular layer>Purkinje cells>molecular layer) and DMPS treatment displayed a significant ameliorative effect toward these phenomena. These findings indicate that DMPS displays beneficial effects on reversing MeHg-induced motor deficits and cerebellar damage in mice. Histological analyses indicate that these phenomena are related to its capability of removing mercury from cerebellar cortex.     

The nature of halogen substitution determines the mode of cytotoxicity of halopropanols

The cytochrome P450-dependent generation of reactive metabolites from 1,3-dichloropropanol and 1,3-dibromopropanol was assessed in a microsomal thiol depletion assay, while the toxicity of these compounds was assessed in rat hepatocyte cultures and in the 3T3 cell line. Thiol-depleting metabolites of both compounds were generated in the microsomal assay; however, only dibromopropanol extensively depleted glutathione when glutathione S-transferase was used as the enzyme source. The cytotoxicity of dichloropropanol was both cytochrome P450- and glutathione-dependent, whereas that of dibromopropanol was glutathione-dependent but largely independent of cytochrome P450. These results indicate that the mechanisms underlying the cytotoxicity of halopropanols are dependent on the nature of the halogen substitution and that microsomal and cellular assays for reactive metabolite generation may yield conflicting results.     

The role of thiol-reducing agents on modulation of glutamate binding induced by heavy metals in platelets.

In the present study, we investigated if thiol-reducing agents are capable of altering mercury (Hg2+), lead (Pb2+) and cadmium (Cd2+) effects on platelet glutamatergic system. Dimercaprol (BAL), a dithiol chelating agent therapeutically used for the treatment of heavy metals poisoning, was capable of protecting the [3H]-glutamate binding against the effects caused by Pb2+ and Hg2+. 2,3-Dimercaptopropane-1-sulfonic acid (DMPS), another dithiol-reducing chelating agent, was capable of protecting the effect caused by Cd2+, Pb2+ and Hg2+. The similar effect was observed with addition of dithiothreitol (DTT) on [3H]-glutamate binding in human platelets. Dithiol-reducing agents (BAL, DMPS and DTT) alone did not alter [3H]-glutamate binding. In contrast, reduced glutathione (GSH), a monothiol-reducing agent, caused a significant inhibition on [3H]-glutamate binding at all concentrations tested. GSH did not modify heavy metal effects on [3H]-glutamate binding in platelets. The findings of the present investigation indicate that dithiol-reducing agents are capable of altering Hg2+, Pb2+ and Cd2+ effects on platelet glutamatergic system. In vitro data on chelating-metal interactions provide only an estimated guide to the treatment of heavy metal poisoning. Consequently, more studies in intoxicated patients are necessary to determine the precise use of the peripheral models and chelating agents.     

Changes in the redox state of neuroblastoma cells after manganese exposure

The toxicological effects of manganese chloride on the redox state of thiols and on the lipid peroxidation in cultures of the neuroblastoma clone N1E 115 were studied. The cell cultures were exposed, after a stationary growth phase was attained, to manganese chloride (25–100 μM) for up to 9 days. The non-protein thiols decreased at the most 27% as compared to the controls. Significant effects were obtained at all manganese concentrations tested. The total thiol content was maximally reduced by 40%. This reduced thiol content was also reflected in a lowered activity of the thiolenzyme, glyceraldehyde-3-phosphate dehydrogenase in manganese exposed cells. In addition the lipid peroxide level in the cells was decreased during the manganese treatment.