Alterations of cholesterol synthesis precursors (7-dehydrocholesterol, 7-dehydrodesmosterol, desmosterol) in dysmyelinating neurological mutant mouse (quaking, shiverer and trembler) in the PNS and the CNS.

In brain, levels of cholesterol, desmosterol and 7-dehydrodesmosterol are reduced in shiverer and quaking, but not in trembler 60-day-old dysmyelinating mutant mice. Very interestingly, 7-dehydrocholesterol is not altered in any mutant. The amount of cholesterol is similar in the different normal control mouse strains and in rat. In contrast, levels of precursors are not the same. In sciatic nerve, cholesterol is slightly reduced in shiverer, reduced 2-fold in quaking, and dramatically reduced in trembler (10-fold). 7-Dehydrocholesterol is affected in all mutants.

Glutathione peroxidase mimics prevent TNFalpha- and neutrophil-induced endothelial alterations.

Based on the assumption that glutathione peroxidase (GPx) activity might be limiting in preventing peroxide-induced impairment of endothelial regulatory functions, we studied the effect of a series of new selenium-containing GPx mimics on endothelial cells exposed to an inflammatory stress. The two compounds that have the highest GPx activity, BXT-51072 and BXT-51077, were shown to be the most efficient inhibitors of leukocyte recruitment by human umbilical vein endothelial cells (HUVEC), upon incubation with neutrophils (10-fold excess over HUVEC) and with 1 ng/ml TNF-alpha for 1 or 3.5 h. When HUVEC were pre- and cotreated with 10 microM of either compound, neutrophil adhesion and endothelial alteration were markedly inhibited, as assessed by immunoassays of myeloperoxidase and von Willebrand factor, respectively. These two GPx mimics were also found to be the most efficient inhibitors of the TNFalpha-induced endothelial expression of P- and E-selectin and of the TNFalpha- or interleukin1-induced endothelial release of interleukin-8. Our results demonstrate that GPx mimics such as BXT-51072 behave as potent antagonists of TNF-alpha and interleukin-1 through the downregulation of endothelial proinflammatory responses.

ICAM-1 and VCAM-1 expression induced by TNF-alpha are inhibited by a glutathione peroxidase mimic.

Intercellular adhesion molecule-1 (ICAM-1) and vascular cell adhesion molecule-1 (VCAM-1) are respectively involved in the endothelial recruitment of neutrophils, and in that of lymphocytes or tumor cells, in response to specific signals. We have used the glutathione peroxidase (GPx) mimic BXT-51072 to assess the possibility that endogenous hydroperoxides play a role in the tumor necrosis factor-alpha (TNFalpha)-induced expression of ICAM-1 and VCAM-1 by monolayers of human endothelial cells. The GPx mimic BXT-51072 strongly inhibits the TNFalpha-induced and cycloheximide-sensitive expression of ICAM-1 and VCAM-1. It also inhibits the TNFalpha-induced reorganization of the actin network and the associated formation of stress fibers. Actin reorganization induced by cytochalasin D treatment did not inhibit ICAM-1 expression. Our results are compatible with specific and synergistic effects of endogenous hydroperoxides on the biosynthesis and processing of cell adhesion molecules and cytoskeleton components.

Glutathione and cysteine depletion in rats and mice following acute intoxication with diethylmaleate.

We examined the dose-dependent glutathione (GSH) depletion in liver, kidney, heart and brain of rats and mice, and cysteine depletion in rat kidney, following i.p. administration of diethylmaleate (DEM). In either rodent, the fall in total GSH concentration in liver and heart reached an upper value of 90 and 80% with 3 and 4 mmol DEM/kg respectively, which did not increase with higher doses. This study suggests that the residual level of GSH corresponds to the mitochondrial pool, in which case DEM might serve as a tool for the measurement of mitochondrial GSH ex vivo. In further experiments, we studied the time course of GSH and cysteine after administration of 3 mmol DEM/kg in rat tissues. Maximal depletion was reached approximately 1 hr after the i.p. injection. Subsequent GSH repletion was fast in liver and kidney, whereas it was slow in heart and brain, with a return to control values by 8-12 and by 48 hr after intoxication, respectively. This study provides new data for cardiac GSH and renal cysteine decrease after intoxication with DEM and should help to optimize GSH depletion models for further pharmacological investigations, especially when the use of inhibitors of glutathione metabolic turnover is undesirable and when side-effects other than GSH depletion must be avoided.

Unaltered brain membranes after prolonged intake of highly oxidizable long-chain fatty acids of the (n-3) series.

Feeding rats a diet enriched in n-3 polyunsaturated fatty acids (Menhaden oil) increased the content in eicosapentaenoic acid 20:5 n-3 of brain phospholipids. Conversely 22:4 n-6 was reduced. These changes were not associated with alterations in either vitamin E concentration or glutathione peroxidase and catalase activities in cerebrum and cerebellum. No increase in peroxidative damage was found. Interestingly the major very-long-chain fatty acids (22:6 n-3 and 22:5 n-3) were not affected.

Brain alterations induced by vitamin E deficiency and intoxication with methyl ethyl ketone peroxide.

Rats fed a vitamin E-deficient diet from age 3-10 weeks were either maintained on a vitamin E-deficient diet or fed a vitamin E-enriched diet for 8 subsequent weeks. The content of vitamin E, endoperoxide-derived malonaldehyde, lipofluorescent material and polyunsaturated fatty acids, and the activities of catalase, glutathione reductase, and glutathione peroxidase were then measured in cerebral tissues, with or without intoxication with methyl ethyl ketone peroxide (MEKP). For this purpose, one half of the animals in each vitamin E group received an ip injection of 5 mg MEKP per kg of body weight, which was followed 44 hours later, i.e., 4 hours before sample collection, by a second ip injection of 15 mg MEKP per kg of body weight. Despite the fact that the vitamin E concentration was 12-times lower in the brain of vitamin E-deficient rats, no significant change in other cerebral parameters was found between the two groups of animals. In contrast, the activity of selenium-glutathione peroxidase was markedly decreased in the liver of 10-week old vitamin E-deficient rats. Unexpectedly, acute systemic intoxication with MEKP caused only a small, albeit significant, decrease in glutathione reductase activity in the brain of vitamin E-sufficient rats, while no significant change in other cerebral parameters was observed in either group of animals. These results suggest that the central nervous system (CNS) is still substantially protected when its vitamin E content has been decreased to 3 micrograms/g fresh weight, and that systemic intoxication with MEKP may not cause lipid peroxidation in the CNS.

Effects of lead acetate on cerebral glutathione peroxidase and catalase in the suckling rat.

Exposure of immature rats to lead acetate results in hemorrhagic encephalopathy of variable evolution. As the maintenance of adequate protection against peroxides may be critical in this condition, the activities of selenium-glutathione peroxidase and catalase in cerebrum and cerebellum of suckling rats poisoned with lead acetate were studied from day six to day sixteen post-exposure. Age-related decreases of glutathione peroxidase and catalase activities in both controls and lead poisoned animals were observed. An increase in catalase activity was observed in cerebrum and cerebellum of lead-treated rats compared to controls. Glutathione peroxidase activity did not change significantly in cerebrum over the period studied. By contrast, glutathione peroxidase activity in cerebellum of lead-treated rats remained at about twice the control level over most of the study period. This apparent increase in glutathione peroxidase activity may be due either to a slower ontogenic decrease of its specific activity or to enzyme induction in response to oxidant stress in cerebellum.

Interaction of gold(I) with the active site of selenium-glutathione peroxidase.

Gold(I) thioglucose in the presence of excess glutathione (GSH) leads to strong and reversible inhibition of selenium-glutathione peroxidase (EC 1.11.1.9) around neutral pH. Binding at equilibrium and competition studies demonstrated that the most reduced form of the active site selenocysteine is the only binding site for gold(I). Steady-state kinetics that gold(I) forms a dead-end complex with glutathione peroxidase in competition with the reduction of hydroperoxide. The apparent Ki is 2.3 microM at pH 7.6, 37 degrees C and 1 mM GSH. Theoretical models of inhibition were assessed by the use of linear least-squares fitting to a generalized integrated rate equation. The results are consistent with trapping of gold(I) at the active site in the form of a mixed bidentate selenolato -thiolate complex involving GSH and the active site selenocysteine. The kinetics of inhibition imply that the resting form of glutathione peroxidase in the presence of excess GSH is also within the enzyme cycle. This rules out the existence of selenium(+IV) species in the redox cycle of the active site when t- butylhydroperoxide is used as a substrate. Electronic properties of selenium and gold as well as a large relief of inhibition by selenocysteine suggest that a very stable interaction should be obtained between Se(-II) and gold(I) through covalent bonding. These results suggest that glutathione peroxidase could be a target of gold drugs used in the treatment of rheumatoid arthritis.

Intracellular antioxidants: from chemical to biochemical mechanisms.

Intracellular antioxidants include low molecular weight scavengers of oxidizing species, and enzymes which degrade superoxide and hydroperoxides. Such antioxidants systems prevent the uncontrolled formation of free radicals and activated oxygen species, or inhibit their reactions with biological structures. Hydrophilic scavengers are found in cytosolic, mitochondrial and nuclear compartments. Ascorbate and glutathione scavenge oxidizing free radicals in water by means of one-electron or hydrogen atom transfer. Similarly, ergothioneine scavenges hydroxyl radicals at very high rates, but it acts more specifically as a chemical scavenger of hypervalent ferryl complexes, halogenated oxidants and peroxynitrite-derived nitrating species, and as a physical quencher of singlet oxygen. Hydrophobic scavengers are found in cell membranes where they inhibit or interrupt chain reactions of lipid peroxidation. In animal cells, they include alpha-tocopherol (vitamin E) which is a primary scavenger of lipid peroxyl radicals, and carotenoids which are secondary scavengers of free radicals as well as physical quenchers of singlet oxygen. The main antioxidant enzymes include dismutases such as superoxide dismutases (SOD) and catalases, which do not consume cofactors, and peroxidases such as selenium-dependent glutathione peroxidases (GPx) in animals or ascorbate peroxidases (APx) in plants. The reducing coenzymes of peroxidases, and as a rule all reducing components of the antioxidant network, are regenerated at the expense of NAD(P)H produced in specific metabolic pathways. Synergistic and co-operative interactions of antioxidants rely on the sequential degradation of peroxides and free radicals as well as on mutual protections of enzymes. This antioxidant network can induce metabolic deviations and plays an important role in the regulation of protein expression and/or activity at the transcriptional or post-translational levels. Its biological significance is discussed in terms of environmental adaptations and functional regulations of aerobic cells.

Structural and functional importance of dietary polyunsaturated fatty acids in the nervous system.

The nervous system is the organ with the second greatest concentration of lipids. These lipids participate directly in membrane functioning. Brain development is genetically programmed. It is therefore necessary to ensure that nerve cells receive an adequate supply of nutrients, especially of lipids, during their differentiation and multiplication, and throughout their lives. The effects of polyunsaturated fatty acid deficiency have been extensively studied; prolonged deficiency leads to death in animals. Linoleic acid is now universally recognized to be an essential nutrient. Until recently, however, alpha-linolenic acid was considered non-essential. Feeding animals with oils that have a low alpha-linolenic content results in all brain cells and organelles and various organs having reduced amounts of 22:6n-3, which is compensated for by an increase in 22:5n-6. The speed of recuperation from these anomalies is extremely slow for brain cells, organelles, and microvessels, in contrast to other organs. A decrease in alpha-linolenic series acids in the membranes results in a 40% reduction in the Na(+)-K(+)-ATPase of nerve terminals and a 20% reduction in 5'-nucleotidase. Some other enzymatic activities are not affected, although membrane fluidity is altered. A diet low in alpha-linolenic acid induces alterations in the electroretinogram which disappear with age; motor function and activity are little affected, but learning behavior is markedly altered. The presence of alpha-linolenic acid in the diet confers a greater resistance to certain neurotoxic agents (triethyl-lead). During the period of cerebral development, there is a linear relationship between brain content of n-3 acids and the n-3 content of the diet up to the point where alpha-linolenic levels reach 200 mg for 100 g of food intake. Beyond that level there is a plateau. For other organs, such as the liver, the relationship is also linear up to 200 mg/100 g, but then there is merely an abrupt change in slope and not a plateau. When dietary 18:2n-6 content was varied, it was noted that 20:4n-6 optimum values were obtained at 150 mg/100 g for all nerve structures, 300 mg for testicle and muscle, 800 mg for kidney, and 1200 mg for liver, lung and heart. A deficiency in alpha-linolenic acid and an excess of linoleic acid have the same main effect: an increase in 22:5n-6 levels.(ABSTRACT TRUNCATED AT 400 WORDS)

[Possible role of glutathione peroxidase in the regulation of collagenase activity]. / Rôle possible de la glutathion peroxydase dans la régulation de l'activité collagénase.

Glutathione peroxidase (Se-GPx) is a selenoenzyme which catalyzes the reduction of hydroperoxides by glutathione (GSH), in most mammalian cells. Several Slow-acting drugs that are used in the treatment of rheumatoid arthritis, including D-Penicillamine, alpha-mercaptopropionylglycine and gold salts, are specific inhibitors of Se-GPx. In situation of oxidant stress, Se-GPx activity is a major source of glutathione disulfide (GSSG), an essential activator of leucocyte collagenase. Hence the possibility that the enzymatic reduction of hydroperoxides produced during chronic inflammation would play an important role in the destruction of joint tissue of arthritic patients. Inhibition of a protective system such as Se-GPx may therefore be involved in the mechanism of action of D-Penicillamine and gold salts, but it could also explain some of their undesirable or toxic effects. Confirmation of this hypothesis would open the way to new pharmacological strategies.

[Glutathione peroxidases: value of their determination in clinical biology]. / Les glutathion peroxydases: intérêt de leur dosage en biologie clinique.

The role of glutathione peroxidase in the oxidative metabolism and recent advances in the demonstration of the consequences of the desequilibrium in the proxidant/antioxidant balance on biological molecules oxidation, intracellular signals transduction, apoptosis and necrosis, have led to new approach in the knowledge of many pathological processes. Methods for determining antioxidant capacity have been developed. The measurement of glutathione peroxidase activity is a key step in the study of oxidative stress. Its determination in clinical biology needs optimal conditions for standardised assays which will be used for epidemiological studies aimed to evaluate the role of nutritional factors involved in the pathogeny of diseases caused or accompanied by oxidative stress.

Glutathione oxidase activity of selenocystamine: a mechanistic study.

Selenocystamine (RSe-SeR) was shown to catalyze the oxygen-mediated oxidation of excess GSH to glutathione disulfide, at neutral pH and ambient PO2. This glutathione oxidase activity required the heterolytic reduction of the diselenide bond, which produced two equivalents of the selenolate derivative selenocysteamine (RSe-), via the transient formation of a selenenylsulfide intermediate (RSe-SG). Formation of RSe- was the only reaction observed in anaerobic conditions. At ambient PO2, the kinetics and stoichiometry of GSSG production as well as that of GSH and oxygen consumptions demonstrated that RSe- performed a three-step reduction of oxygen to water. The first step was a one-electron transfer from RSe- to dioxygen, yielding superoxide and a putative selenyl radical RSe., which decayed very rapidly to RSe-SeR. In the second step, RSe- reduced superoxide to hydrogen peroxide through a much faster one-electron transfer, also associated with the decay of RSe. to RSe-SeR. The third step was a two-electron transfer from RSe- to hydrogen peroxide, again much faster than oxygen reduction, which resulted in the production of RSe-SG, presumably via a selenenic acid intermediate (RSeOH) which was trapped by excess GSH. This third step was studied on exogenous hydroperoxide in anaerobic conditions, and it could be eliminated from the glutathione oxidase cycle in the presence of excess catalase. The role of RSe- as a one- and two-electron reductant was confirmed by competitive carboxymethylation with iodoacetate. RSe- was able to rapidly reduce ferric cytochrome c to its ferrous derivative. The overall rate of catalytic glutathione oxidation was GSH concentration dependent and oxygen concentration independent. Excess glutathione reductase and NADPH increased the catalytic oxidation of GSH, probably by switching the rate-limiting step from selenylsulfide to diselenide cleavage. When GSH was substituted for dithiothreitol, it was shown to reduce RSe-SeR to RSe- in a fast and quantitative reaction, and selenocystamine behaved as a dithiothreitol oxidase, whose catalytic cycle was dependent on oxygen concentration. The oxidase cycle of glutathione was inhibited by mercaptosuccinate, while that of dithiothreitol was not affected. When mercaptosuccinate was substituted for GSH, a stable selenenylsulfide was formed. These observations suggest that electrostatic interactions affect the reductive cleavage of diselenide and selenenylsulfide linkages. This study illustrates the ease of one-electron transfers from RSe- to a variety of reducible substrates. Such free radical mechanisms may explain much of the cytotoxicity of alkylselenols, and they demonstrate that selenocystamine is a poor catalytic model of the enzyme glutathione peroxidase.

[Metabolism and antioxidant function of glutathione]. / Métabolisme et fonction antioxydante du glutathion.

Glutathione (gamma-glutamyl-cysteinyl-glycine or GSH) is a cysteine-containing tripeptide with reducing and nucleophilic properties which play an important role in cellular protection from oxidative damage of lipids, proteins and nucleic acids. GSH regulates the metabolism of proteins and their activities by means of thiol-disulfide exchange. During oxidative stress, GSH plays a key role of protection and detoxification as a cofactor of glutathione peroxidases and glutathione-S-transferases. There are synergistic interactions between GSH and other components of the antioxidant defense system such as vitamin C, vitamin E and superoxide dismutases.

Purification and characterization of selenium-glutathione peroxidase from hamster liver.

Hamster liver glutathione peroxidase was purified to homogeneity in three chromatographic steps and with 30% yield. The purified enzyme had a specific activity of approximately 500 mumol cumene hydroperoxide reduced/min/mg of protein at 37 degrees C, pH 7.6, and 0.25 mM GSH. The enzyme was shown to be a tetramer of indistinguishable subunits, the molecular weight of which was approximately 23,000 as estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A single isoelectric point of 5.0 was attributed to the active enzyme. Amino acid analysis determined that selenocysteine, identified as its carboxymethyl derivative, was the only form of selenium. One residue of cysteine was found to be present in each glutathione peroxidase subunit. The presence of tryptophan was colorimetrically determined. Pseudo-first-order kinetics of inactivation of the enzyme by iodoacetate was observed at neutral pH with GSH as the only reducing agent. An optimal pH of 8.0 at 37 degrees C and an activation energy of 3 kcal/mol at pH 7.6 were found. A ter-uni-ping-pong mechanism was shown by the use of an integrated-rate equation. At pH 7.6, the apparent second-order rate constants for reaction of glutathione peroxidase with hydroperoxides were as follows: k1 (t-butyl hydroperoxide), 7.06 X 10(5) mM-1 min-1; k1 (cumene hydroperoxide), 1.04 X 10(6) mM-1 min-1; k1 (p-menthane hydroperoxide), 1.2 X 10(6) mM-1 min-1; k1 (diisopropylbenzene hydroperoxide), 1.7 X 10(6) mM-1 min-1; k1 (linoleic acid hydroperoxide), 2.36 X 10(6) mM-1 min-1; k1 (ethyl hydroperoxide), 2.5 X 10(6) mM-1 min-1; and k1 (hydrogen peroxide), 2.98 X 10(6) mM-1 min-1. It is concluded that for bulky hydroperoxides, the more hydrophobic the substrate, the faster its reduction by glutathione peroxidase.

Alteration of the alpha-tocopherol content in the brain and peripheral nervous tissue of dysmyelinating mutants.

In the brain of quaking and shiverer mutants, vitamin E content was normal when related to both wet weight and dry weight. When related to lipid extract, phosphorus, and polyunsaturated fatty acids, vitamin E was slightly increased only in the quaking mutant. In the sciatic nerve from trembler mutants, vitamin E was 134% of control values in the dry material, but normal in relation to wet weight. It was 260% in the lipid extract and 716% based on phosphorus. In relation to total fatty acids, there was a threefold increase in trembler mutants. Interestingly, it was increased approximately three times when related to 18:2 n-6, 20:4 n-6, and 20:5 n-3, and seven times when related to 22:6 n-3. The fact that the amount of vitamin E in fresh weight was normal, suggests that vitamin E plays a role in some nonmembrane material, such as the extracellular matrix or the basal lamina.

Purification and properties of a recombinant sulfur analog of murine selenium-glutathione peroxidase.

We previously constructed plasmids for synthesis of glutathione-peroxidase (GPx) mutants in an Escherichia coli expression system. In these recombinant proteins either cysteine ([Cys]GPx mutant) or serine ([Ser]GPx mutant) were present in place of the active-site selenocysteine (SeCys) of the natural enzyme. We have now investigated GPx activity of [Cys]GPx and [Ser]GPx mutants. Enzyme assays performed on preparations of these partially purified proteins demonstrated that the [Cys]GPx mutant exhibited a significant GPx activity, unlike the [Ser]GPx mutant. Purification of [Cys]GPx was performed in two steps of ion-exchange chromatography giving a 98% homogenous protein in 50% yield. The purified [Cys]GPx protein was shown to be a symmetrical tetramer by the means of gel-filtration HPLC and SDS/PAGE. Two isoelectric points were found (6.8 and 7.2) which may reflect two different oxidation states of the mutant protein. The GPx activity of the [Cys]GPx mutant was optimal at pH 8.5. The [Cys]GPx mutant had a specific activity approximately 1000-fold smaller than that of the natural enzyme, and was very easily inactivated by hydroperoxides. Inhibition of the activity with iodoacetate determined a pKa of 8.3, presumably that of the active-site cysteine. Unlike that of SeGPx, the GPx activity of [Cys]GPx was only slightly inhibited by mercaptosuccinate. We discuss hypothetical mechanistic constraints of either catalytic cycle, which may explain such results.