Increased superoxide radicals generation from alveolar macrophages in immature guinea-pigs

To study the effect of maturation on abilities of superoxide radicals (O-2) generation in the airways, we compared stimuli-induced O-2 generation by alveolar macrophages in immature (aged 10+/-2 days) and adult (aged 90+/-2 days) guinea-pigs. The production of O-2 was assayed by chemiluminescence method, using a Cypridina luciferin analog as a highly sensitive and specific probe for O-2. Whereas no significant difference in cell components of bronchoalveolar lavage fluid was observed between immature and adult animals, O-2 generation induced by stimulation of alveolar macrophages was greater in immature than in adult animals, with significant differences observed after platelet-activating factor (100 nM) or phorbol myristate acetate (0.5 micro g/ml). The results suggest that alveolar macrophages from immature animals are far more potent O-2 generators than the same cells of adult animals.     

Lipid peroxidation and the generation of free radicals, superoxide anion, and hydrogen peroxide in beta-lapachone-treated Trypanosoma cruzi epimastigotes.

β-Lapachone, an antimicrobial agent, was reduced by Trypanosoma cruzi epimastigotes to a semiquinone radical. It markedly increased the generation of superoxide anion and hydrogen peroxide in intact cells. Using NADH as electron donor, β-lapachone also increased significantly the rate of H₂O₂ generation in epimastigote homogenates. Incubation of epimastigotes with β-lapachone stimulated lipid peroxidation.     

Asbestos catalyzes hydroxyl and superoxide radical generation from hydrogen peroxide

To understand chemical characteristics of the asbestos minerals which might contribute to tissue damage, the catalytic properties of three different varieties were studied. Using spin trapping techniques it was determined that crocidolite, chrysotile, and amosite asbestos were all able to catalyze the generation of toxic hydroxyl radicals from a normal byproduct of tissue metabolism, hydrogen peroxide. The iron chelator desferroxamine inhibits this reaction, indicating a major role for iron in the catalytic process, and suggesting a possible mechanism by which asbestos toxicity might be reduced.     

Mechanism of superoxide and hydrogen peroxide generation by human electron-transfer flavoprotein and pathological variants

Reactive oxygen species production by mitochondrial enzymes plays a fundamental role both in cellular signaling and in the progression of dysfunctional states. However, sources of reactive oxygen species and the mechanisms by which enzymes produce these reactive species still remain elusive. We characterized the generation of reactive oxygen species by purified human electron-transfer flavoprotein (ETF), a mitochondrial enzyme that has a central role in the metabolism of lipids, amino acids, and choline. The results showed that ETF produces significant amounts of both superoxide and hydrogen peroxide in the presence of its partner enzyme medium-chain acyl-CoA dehydrogenase (MCAD). ETF-mediated production of reactive oxygen species is partially inhibited at high MCAD/ETF ratios, whereas it is enhanced at high ionic strength. Determination of the reduction potentials of ETF showed that thermodynamic properties of the FAD cofactor are changed upon formation of a complex between ETF and MCAD, supporting the notion that protein:protein interactions modulate the reactivity of the protein with dioxygen. Two pathogenic ETF variants were also studied to determine which factors modulate the reactivity toward molecular oxygen and promote reactive oxygen species production. The results obtained show that destabilized conformations and defective protein:protein interactions increase the ability of ETF to generate reactive oxygen species. A possible role for these processes in mitochondrial dysfunction in metabolic disorders of fatty acid β-oxidation is discussed.     

Generation of hydrogen peroxide, superoxide and hydroxyl radicals during the oxidation of dihydroxyfumaric acid by peroxidase.

1. Dihydroxyfumarate slowly autoxidizes at pH6. This reaction is inhibited by superoxide dismutase but not by EDTA. Mn2+ catalyses dihydroxyfumarate oxidation by reacting with O2 leads to to form Mn3+, which seems to oxidize dihydrofumarate rapidly. Cu2+ also catalyses dihydroxyfumarate oxidation, but by a mechanism that does not involve O2 leads to. 2. Peroxidase catalyses oxidation of dihydroxyfumarate at pH6; addition of H2O2 does not increase the rate. Experiments with superoxide dismutase and catalase suggest that there are two types of oxidation taking place: an enzymic, H2O2-dependent oxidation of dihydroxyfumarate by peroxidase, and a non-enzymic reaction involving oxidation of dihydroxyfumarate by O2 leads to. The latter accounts for most of the observed oxidation of dihydroxyfumarate. 3. During dihydroxyfumarate oxidation, most peroxidase is present as compound III, and the enzymic oxidation may be limited by the low rate of breakdown of this compound. 4. Addition of p-coumaric acid to the peroxidase/dihydroxyfumarate system increases the rate of dihydroxyfumarate oxidation, which is now stimulated by addition of H2O2, and is more sensitive to inhibition by catalase but less sensitive to superoxide dismutase. Compound III is decomposed in the presence of p-coumaric acid. p-Hydroxybenzoate has similar, but much smaller, effects on dihydroxyfumarate oxidation. However, salicylate affects neither the rate nor the mechanism of dihydroxyfumarate oxidation. 5. p-Hydroxybenzoate, salicylate and p-coumarate are hydroxylated by the peroxidase/dihydroxyfumarate system. Experiments using scavengers of hydroxyl radicals shown that OH is required. Ability to increase dihydroxyfumarate oxidation is not necessary for hydroxylation to occur.     

Generation of superoxide radicals in alkaline solutions of hydrogen peroxide and the effect of superoxide dismutase on this system

Superoxide radicals in high concentrations were generated from alkaline H₂O₂ without using catalysts or irradiation. The dependence of the intensity and parameters of the superoxide radical EPR spectrum on pH, temperature, viscosity and H₂O₂ concentration were studied. The observed changes are explained on the base of matrix effects. The addition of superoxide dismutase to alkaline H₂O₂ led initially to a drop in the EPR spectrum intensity, followed by an increase in the concentration of superoxide radicals.     

Generation of superoxide anion radicals and hydrogen peroxide in the auto-oxidation of caffeic acid

Caffeic acid (5-200 mkM) reduces cytochrome c during autoxidation in potassium phosphate buffer, pH 7-8. The reduction is inhibited by superoxide dismutase, which suggests generation of superoxide anion radicals. The generation rate is 0.028-0.115 mkmoles O2- per min. Superoxide appears to be a side product of the reaction, since the autoxidation of caffeic acid itself (followed by A420) is not inhibited by superoxide dismutase. The autoxidation is accompanied by oxygen of consumption. An addition of catalase results in liberation of some part of consumed oxygen, this being indicative of accumulation of hydrogen peroxide. Caffeic acid is known to be responsible for the resistance of plants to parasites because of its toxicity. This function presumably depends on superoxide or other reactive oxygen species.     

Generation of superoxide radicals in alkaline solutions of hydrogen peroxide and the effect of superoxide dismutase on this system.

Superoxide radicals in high concentrations were generated from alkaline H2O2 without using catalysts or irradiation. The dependence of the intensity and parameters of the superoxide radical EPR spectrum on pH, temperature, viscosity and H2O2 concentration were studied. The observed changes are explained on the base of matrix effects. The addition of superoxide dismutase to alkaline H2O2 led initially to a drop in the EPR spectrum intensity, followed by an increase in the concentration of superoxide radicals.     

A dual role for calcium in regulation of superoxide generation by stimulated rat alveolar macrophages

Superoxide production in alveolar macrophages is stimulated by agonists which act through Ca2+-mediated (concanavalin A) and/or protein kinase C (phorbol ester or diacylglycerol analogues) -mediated events. Simultaneous addition of saturating concentrations of concanavalin A and a protein kinase C activator (either phorbol 12-myristate-13-acetate or 1-oleoyl-2-acetyl-sn-glycerol) caused a supra-additive enhancement of the initial rate of O2-. production. This synergism closely correlated with the known time-course of Ca2+ mobilization induced by concanavalin A; however, it occurred under conditions in which protein kinase C activation is reportedly not Ca2+ dependent. Phorbol ester-induced O2-. production was partially inhibited by the Ca2+ ionophore, A23187. Although phorbol ester-stimulated O2-. production initially was enhanced by concanavalin A, the duration of this O2-. production was reduced in comparison to that induced by phorbol ester alone. These results suggest a dual role for intracellular Ca2+ in both stimulatory and inhibitory regulation of O2-. production.     

Activation of redox-systems of monocytes by hydrogen peroxide

In this work the influence of H2O2 on the ability of human blood monocytes to generate ROS upon stimulation of cells by adhesion to glass surface and fMLP was studied using the luminol-dependent chemiluminescence (LDCL) method. Pretreatment of cells with H2O2 increased the adhesiveness of monocytes and ROS generation. Superoxide generation by cells in response to fMLP depended on the duration of pretreatment and the concentration of H2O2. The stimulatory effect on fMLP-induced LDCL of cells further depended on the Ca2+ concentration in the medium and on the activities of phospholipase A2, cyclooxygenases, and Mek1/2.     

Effects of rifampicin and doxycycline on the production of hydrogen peroxide by macrophages]

The influence of rifampicin and doxycycline on oxidative metabolism of macrophages was estimated in vitro by production of hydrogen peroxide. It was shown that low concentrations of rifampicin and doxycycline stimulated production of hydrogen peroxide by macrophages of guinea pigs. In concentrations of 1 to 10 micrograms/ml corresponding to the mean therapeutic ones doxycycline increased both the spontaneous and zymosan-induced production of hydrogen peroxide by the macrophages. The potentiating activity of doxycycline on the cells activated by opsonized zymosan was higher. The maximum increase in the induced production of hydrogen peroxide (by 40 per cent) was observed when the antibiotic concentration was 1 microgram/ml. Rifampicin in concentrations of 0.1 to 1 microgram/ml corresponding to the mean therapeutic ones stimulated the zymosan-induced production of hydrogen peroxide by the macrophages. The maximum increase in the production of hydrogen peroxide (by 22 per cent) was noted at the rifampicin concentration of 1 microgram/ml.     

Activation of murine macrophages by hydrogen peroxide

Hydrogen peroxide at concentrations from 0.1 to 20 μM enhances phagocytosis and oxidative burst of murine peritoneal macrophages. The activation of these macrophage functions is paralled by prolonged hyperpolarization and a transient increase in cytoplasmic free calcium concentration. All the effects are dose- and time-dependent. The results obtained for H₂O₂ are compared with those for a natural activator, peptide N-formyl-methionyl-leucly-phenylalanine. The data demonstrate the ability of small doses of hydrogen peroxide to stimulate macrophages through the intracellular mechanisms of ion transduction.     

Production of superoxide radicals and hydrogen peroxide by NADH-ubiquinone reductase and ubiquinol-cytochrome c reductase from beef-heart mitochondria.

Complex I (NADH-ubiquinone reductase) and Complex III (ubiquinol-cytochrome c reductase) supplemented with NADH generated O₂^? at maximum rates of 9.8 and 6.5 nmol/min/mg of protein, respectively, while, in the presence of superoxide dismutase, the same systems generated H₂O₂ at maximum rates of 5.1 and 4.2 nmol/min/mg of protein, respectively. H₂O₂ was essentially produced by disproportionation of O₂^?, which constitutes the precursor of H₂O₂. The effectiveness of the generation of oxygen intermediates by Complex I in the absence of other specific electron acceptors was 0.95 mol of O₂^? and 0.63 mol of H₂O₂/mol of NADH. A reduced form of ubiquinone appeared to be responsible for the reduction of O₂ to O₂^?, since (a) ubiquinone constituted the sole common major component of Complexes I and III, (b) H₂O₂ generation by Complex I was inhibited by rotenone, and (c) supplementation of Complex I with exogenous ubiquinones increased the rate of H₂O₂ generation. The efficiency of added quinones as peroxide generators decreased in the order Q₁ > Q₀ > Q₂ > Q₆ = Q₁₀, in agreement with the quinone capacity of acting as electron acceptor for Complex I. In the supplemented systems, the exogenous quinone was reduced by Complex I and oxidized nonenzymatically by molecular oxygen. Additional evidence for the role of ubiquinone as peroxide generator is provided by the generation of O₂^? and H₂O₂ during autoxidation of quinols. In oxygenated buffers, ubiquinol (Q₀H₂), benzoquinol, duroquinol and menadiol generated O₂^? with k₃ values of 0.1 to 1.4 m^? · s^?1 and H₂O₂ with k₄ values of 0.009 to 4.3 m^?1 · s^?1.     

Participation of superoxide,hydrogen peroxide and hydroxyl radicals in NADPH-cytochrome P-450 reductase-catalyzed peroxidation of methyl linolenate

• 1.1. NADPH-cytochrome P-450 reductase-catalyzed peroxidation of methyl linolenate is inhibited by superoxide dismutase, catalase, ethanol and mannitol and is potentiated by H₂O₂.
• 2.2. H₂O₂ is shown to be generated in the incubation mixture in the presence of NADPH and NADPH-cytochrome P-450 reductase. If the system contains Fe-EDTA complex, H₂O₂ is not formed. In the presence of the enzyme and Fe-EDTA complex, added H₂O₂ is consumed.
• 3.3. In the presence of Fe-EDTA complex, NADPH-cytochrome P-450 reductase is shown to generate O_2⁻ at a slow rate.These results suggest that H₂O₂ produced from O_2⁻ is decomposed to form OH· by the action of Fe-EDTA complex in the lipid peroxidation system and that OH· is a trigger of lipid peroxidation.

     

A comparative study of superoxide dismutase activity in polymorphonuclear leukocytes, monocytes, and alveolar macrophages of the guinea pig.

Superoxide dismutase, an enzyme which catalyzes the dismutation of superoxide radical formed during the univalent reduction of oxygen, was quantitated by observing the inhibition of cytochrome C reduction in three cell fractions in guinea pig peritoneal PMNs and monocytes and compared to alveolar macrophages. No differences were found in the 16,000 × g pellets containing mitochondria, membranes, and granules and representing 96% of total SOD activity in PMNs and monocytes but only 48% total SOD activity in alveolar macrophages. The 100,000 × g microsomal pellet of alveolar macrophages contained 8% of total SOD activity and two-five times more activity than the respective fractions from monocytes and PMNs. However, there was 70 times more SOD in the 100,000 × g supernatant from alveolar macrophages containing 44% of total enzyme activity than in the same fraction of PMNs and monocytes containing less than 2% total SOD activity. SOD activity is mainly located in the 16,000 × g particulate fraction of PMN and monocytes but more equally distributed between the particulate fractions and cytosol of alveolar macrophages.     

Hydroxylation of aromatic compounds by reduced nicotinamide-adenine dinucleotide and phenazine methosulphate requires hydrogen peroxide and hydroxyl radicals, but not superoxide.

1. A mixture of NADH and phenazine methosulphate hydroxylates aromatic compounds at acidic pH values. 2. Hydroxylation is inhibited by catalase and by scavengers of the hydroxyl radical (-OH) but not by superoxide dismutase. 3. It is concluded that neither O2 leads to nor HO2- is sufficiently reactive to hydroxylate aromatic rings.