Production of superoxide anions and hydrogen peroxide in Ehrlich ascites tumour cell nuclei.

Nuclei isolated from Ehrlich-Lettré ascites tumour cells catalyze the co-oxidation of epinephrine to adrenochrome in the presence of NADPH. Adrenochrome formation is sensitive to superoxide dismutase but not to scavengers of hydroxyl radicals or singlet oxygen. Addition of NADPH also initiates the production of hydrogen peroxide. Moreover measurements of superoxide dismutase activity indicate the presence of this enzyme in the ascites cell nuclei, although the sensitivity of adrenochrome formation to externally added superoxide dismutase indicates that the endogenous enzyme is not sufficient for a complete protection from superoxide radicals.     

Involvement of superoxide radicals on adrenochrome formation stimulated by arachidonic acid in bovine heart sarcolemmal vesicles

Highly purified sarcolemmal membranes prepared from bovine heart muscle produced superoxide radicals, especially when incubated with NADPH or NADH, as revealed by the oxidation of adrenaline to adrenochrome. The reaction was inhibited by superoxide dismutase or by heat denaturation of the sarcolemmal vesicles. Less evident was the inhibitory effect shown by catalase, while mannitol, deferoxamine or dicumarol were uneffective. The formation of adrenochrome was an oxygen-dependent reaction with a Km for adrenaline of 8-10 microM. Moreover, the reaction was inhibited by preincubating the sarcolemmal membranes with propranolol, while the alpha-antagonist phentolamine was without effect. Adrenaline oxidation was unaffected by the presence of exogenous linolenic acid or methylarachidonic acid, while arachidonic acid, with a Km for this reaction of 175 microM, showed a marked stimulatory effect. This activation was suppressed by superoxide dismutase, catalase and NaCN, while mannitol was without effect. Moreover, the reaction was blocked by the cyclooxygenase inhibitor indomethacin, differently from the lipooxygenase inhibitor nordihydroguaiaretic acid. Also, the incubation of the sarcolemmal vesicles with phospholipase A2 and calcium produced a stimulation of adrenochrome formation which was partially suppressed by albumin. In the experiments using arachidonic acid or phospholipase A2, the addition of indomethacin blocked the adrenaline oxidation. These results indicate that arachidonic acid accentuated the heart sarcolemmal adrenochrome formation presumably by participating in the cyclooxygenase reaction.     

Superoxide and hydrogen peroxide production and NADPH oxidation stimulated by nitrofurantoin in lung microsomes: possible implications for toxicity.

The addition of nitrofurantoin to aerobic incubation mixtures containing rat lung microsomes strongly enhanced the generation of adrenochrome from epinephrine. Adrenochrome formation in this system was blocked by superoxide dismutase, but not by catalase. Hydrogen peroxide production was also strongly enhanced by nitrofurantoin in these preparations; superoxide dismutase did not significantly alter the amount of H₂O₂ measured, but no H₂O₂ was detected in incubation mixtures in the presence of catalase. Nitrofurantoin enhanced the oxidation of NADPH in lung microsomal suspensions under aerobic conditions; the enhancement was unaffected by catalase but was partially prevented by superoxide dismutase. Neither adrenochrome formation nor H₂O₂ production were enhanced by nitrofurantoin under anaerobic (N₂) conditions, but NADPH oxidation in the presence of nitrofurantoin was greater under anaerobic conditions than under aerobic conditions. These results are consistent with the view that the redox cycling of nitrofurantoin in lung microsomes in the presence of oxygen results in the consumption of NADPH and the production of activated oxygen species, emphasizing some $\text{in vitro}$ metabolic similarities with the lung-toxic herbicide, paraquat.     

The involvement of oxygen radicals during the autoxidation of adrenalin.

1. In unbuffered alkaline solutions, autoxidizing adrenalin generates superoxide anions: both the scavenging by adrenalin itself, leading to adrenochrome, and the formation of nitrite from hydroxylamine are inhibited by superoxide dismutase. No hydroxyl radical could be detected. 2. The yield of hydrogen peroxide increases with pH in a way similar to that of adrenochrome and nitrite. The dissociated form of adrenalin (pK = 8.5) is proposed as the source of superoxide anions. 3. Superoxide dismutase delays rather than inhibits the reaction. In addition to the diminished formation of adrenochrome due to the scavenging of superoxide anions and re-reduction of the semiquinone by hydrogen peroxide, respectively, adrenochrome is further removed by hydrogen peroxide, with final products absorbing at 310 nm. 4. The diminished inhibitory effect of superoxide dismutase above pH 10 is due to superoxide-independent reactions. This effect is masked by the alkaline conversion of adrenochrome to indole compounds. 5. It is concluded that monitoring the absorption of adrenochrome in alkaline solutions does not produce reliable evidence for superoxide anions.     

Generation of the superoxide radical during autoxidation of oxymyoglobin.

Autoxidation of bovine oxymyoglobin to metmyoglobin induces co-oxidation of epinephrine to adrenochrome. This co-oxidation is markedly inhibited by superoxide dismutase [EC 1.15.1.1]. Electron transfer from oxymyoglobin to ferricytochrome c is partially inhibited by superoxide dismutase. These results indicate that autoxidation of oxymyoglobin results in generation of superoxide radicals. Autoxidation of oxymyoglobin is accelerated by superoxide dismutase and partially inhibited by catalase [EC 1.11.1.6].     

On the mechanism of production of superoxide radical by reaction mixtures containing NADH, phenazine methosulfate, and nitroblue tetrazolium

In aerobic reaction mixtures containing NADH, phenazine methosulfate, and nitroblue tetrazolium, O2- production is mediated by the tetrazolium, not the phenazine. Thus, superoxide dismutase inhibited reduction of the tetrazolium, but when ferricytochrome c was substituted for the tetrazolium its reduction was not affected by this enzyme. Furthermore, NADH plus the phenazine did not accelerate the oxidation of epinephrine to adrenochrome unless the tetrazolium was present, and under those circumstances superoxide dismutase did inhibit adrenochrome formation. When the tetrazolium and ferricytochrome c were present simultaneously, addition of superoxide dismutase was seen to accelerate the reduction of the cytochrome. This is explainable by the reduction of O2- by the reduced phenazine, which thus competes with cytochrome c for the available O2-. When the O2- was eliminated by superoxide dismutase, more of the reduced phenazine was available for the direct reduction of cytochrome c.     

Purification and immunochemical studies of pyruvate dehydrogenase complex from rat heart, and cell-free synthesis of lipoamide dehydrogenase, a component of the complex

A mixture of NADPH and ferredoxin reductase is a convenient way of reducing adriamycin in vitro. Under aerobic conditions the adriamycin semiquinone reacts rapidly with O2 and superoxide radical is produced. Superoxide generated either by adriamycin:ferredoxin reductase or by hypoxanthine:xanthine oxidase can promote the formation of hydroxyl radicals in the presence of soluble iron chelates. Hydroxyl radicals produced by a hypoxanthine:xanthine oxidase system in the presence of an iron chelate cause extensive fragmentation in double-stranded DNA. Protection is offered by catalase, superoxide dismutase or desferrioxamine. Addition of double-stranded DNA to a mixture of adriamycin, ferredoxin reductase, NADPH and iron chelate inhibits formation of both superoxide and hydroxyl radicals. This is not due to direct inhibition of ferredoxin reductase and single-stranded DNA has a much weaker inhibitory effect. It is concluded that adriamycin intercalated into DNA cannot be reduced.     

Some features of nucleo-cytoplasmic RNA transport from isolated nuclei

Messenger RNA is released preferentially from isolated rat liver nuclei in the presence of the ATP-generating system and cytosol. The release is suppressed by spermidine, while cytoplasmic RNase inhibitor was ineffective and PCMB like some other thiol-blocking agents inhibitory. Cytoplasmic SOD added to the system strongly suppressed RNA release. A similar effect could be obtained by anaerobiosis due to addition of SMP. In both cases the inhibition is reversed by cyanide.In contrast to normal liver where the generation of superoxide radicals takes place almost exclusively in microsomes and is coupled with the oxidation of NADPH, in mouse ascites hepatoma 22a the generation of superoxide radicals occurs mainly in the nuclear envelope and is coupled with the oxidation of both NADPH and NADH and inhibited by cyanide.Abbreviations PCMB p-Chloromercuri benzoate - SMP Submitochondrial particles - SOD Superoxide dismutase     

DNA damage by superoxide-generating systems in relation to the mechanism of action of the anti-tumour antibiotic adriamycin

1. A mixture of NADPH and ferrodoxin reductase is a convenient way of reducing adriamycin in vitro. Under aerobic conditions the adriamycin semiquinone reacts rapidly with O₂ and superoxide radical is produced. 2. Superoxide generated either by adriamycin:ferredoxin reductase or by hypoxanthine: xanthine oxidase can promote the formation of hydroxyl radicals in the presence of soluble iron chelates. 3. Hydroxyl radicals produced by a hypoxanthine:xanthine oxidase system in the presence of an iron chelate cause extensive fragmentation in double-stranded DNA. Protection is offered by catalase, superoxide dismutase or desferrioxamine. 4. Addition of double-stranded DNA to a mixture of adriamycin, ferredoxin reductase, NADPH and iron chelate inhibits formation of both superoxide and hydroxyl radicals. This is not due to direct inhibition of ferredoxin reductase and single-stranded DNA has a much weaker inhibitory effect. It is concluded that adriamycin intercalated into DNA cannot be reduced.     

NADH- and NADPH-dependent formation of superoxide anions by bovine heart submitochondrial particles and NADH–ubiquinone reductase preparation

1. Both NADH and NADPH supported the oxidation of adrenaline to adrenochrome in bovine heart submitochondrial particles. The reaction was completely inhibited in the presence of superoxide dismutase, suggesting that superoxide anions (O(2) (-)) are responsible for the oxidation. The optimal pH of the reaction with NADPH was at pH7.5, whereas that with NADH was at pH9.0. The reaction was inhibited by treatment of the preparation with p-hydroxymercuribenzoate and stimulated by treatment with rotenone. Antimycin A and cyanide stimulated the reaction to the same extent as rotenone. The NADPH-dependent reaction was inhibited by inorganic salts at high concentrations, whereas the NADH-dependent reaction was stimulated. 2. Production of O(2) (-) by NADH-ubiquinone reductase preparation (Complex I) with NADH or NADPH as an electron donor was assayed by measuring the formation of adrenochrome or the reduction of acetylated cytochrome c which does not react with the respiratory-chain components. p-Hydroxymercuribenzoate inhibited the reaction and rotenone stimulated the reaction. The effects of pH and inorganic salts at high concentrations on the NADH- and NADPH-dependent reactions of Complex I were essentially similar to those on the reactions of submitochondrial particles. 3. These findings suggest that a region between a mercurialsensitive site and the rotenone-sensitive site of the respiratory-chain NADH dehydrogenase is largely responsible for the NADH- and NADPH-dependent O(2) (-) production by the mitochondrial inner membranes.     

Reaction of superoxide anions with melanins: electron spin resonance and spin trapping studies

Scavenging of superoxide radicals by melanin is a possible factor in the photoprotection afforded by melanin pigments. The reaction between superoxide anions and melanins has been studied by electron spin resonance and spin trapping methods. It was found that superoxide anions react to produce melanin free radicals in a reaction inhibited by superoxide dismutase but not by catalase. The rate of radical formation depends on the concentration of melanin and superoxide, the pH of the medium and the presence of diamagnetic metal ions. The melanin pigment competes with the enzyme superoxide dismutase for removal of superoxide radicals. It was found that the xanthine-xanthine oxidase system is not suitable for studying the reaction of superoxide with melanin, as the enzymatic activity of xanthine oxidase is considerably inhibited by melanin.     

A novel approach to study the reaction of adrenaline autooxidation: A possibility for polarographic determination of superoxide dismutase activity and antioxidant properties of various preparations

The reaction of adrenaline autooxidation in an alkaline carbonate buffer followed by formation of superoxide radicals and the product of its oxidation, adrenochrome, which models the quinone pathway of adrenaline metabolism in the body, is accompanied by oxygen consumption. A study of this process by the polarographic method enabled one to apply this reaction to determine the activity of superoxide dismutase and antioxidant properties of biological and chemical compounds; it is based on evaluation of a latent period and the rate of oxygen consumption, which are measured in the presence of examined compounds. It was suggested that known neuroand cardiotoxicity of the quinone products of adrenaline oxidation may be associated not only to their intrinsic properties and reactive oxygen species formed but also local hypoxia of those regions of the cell and tissue where the quinone oxidation of adrenaline occurs.     

Acute lindane intoxication: A study on lindane tissue concentration and oxidative stress-related parameters in liver and erythrocytes

Treatment of rats with daily dosis of 20 mg of lindane/kg for 3 consecutive days led to the accumulation of the insecticide in several tissues, including erythrocytes and liver. Lindane did not alter the hematocrit and hemoglobin concentration but reduced methemogiobin levels by 17%. Red blood cells from controls and lindane-treated rats, exposed to t-butyl hydroperoxide, exhibited comparable rates of oxygen uptake and visible chemiluminescence, whereas the induction period that precedes oxygen uptake was significantly enhanced in the latter group. Lindane treatment did not modify the activity of erythrocyte glutathione peroxidase, glucose-6-phosphate dehydrogenase, catalase, and methemoglobin reductase, being the total content of glutathione and superoxide dismutase activity significantly increased. The liver from lindane-treated rats showed an enhanced microsomal pro-oxidant activity, evidenced by higher cytochrome P450 content and NADPH-cytochrome c reductase and NADPH oxidase activities. The higher enzyme activities led to an increased superoxide anion generation (adrenochrome formation) and lipid peroxidation (measured either by the production of thiobarbituric acid reactants and spontaneous visible chemiluminescence). Concomitantly, liver glutathione content and the activity of glutathione peroxidase-glutathione reductase couple were augmented by lindane treatment, without any change in superoxide dismutase activity, together with a reduction in that of catalase. Results suggest that lindane does not alter the prooxidant/antioxidant status of the erythrocyte in conditions of a significant cellular accumulation of the insecticide, which might exert direct action on enzymatic systems leading to enhanced superoxide dismutase activity and glutathione content. In the liver, lindane-induced pro-oxidant condition was not accompanied by cell injury, probably due to the adaptative increase in some antioxidant mechanisms of the hepatocyte.     

Characteristics of Eliciting Effects of Furostanol Glycosides on Cultured Yam Cells

To unravel mechanisms of elicitor action of furostanol glycosides (FGs), the formation of superoxide anion after the addition of FGs to a suspension culture of yam (Dioscorea deltoidea Wall. ex Griseb) cells was studied. The substantial increase in superoxide level, evaluated by nitroblue tetrazolium (NBT) reduction to formazan, was found at the exponential phase of cell growth. The involvement of NADPH oxidase in the superoxide generation was revealed by means of inhibitory analysis. Diphenyliodonium chloride (DPI), the inhibitor of NADPH oxidase, compromised the action of FGs. Meanwhile, the elimination of apoplastic peroxidase did not affect the accumulation of formazan, which suggests the involvement of NADPH oxidase but not peroxidase in the superoxide generation. In addition to NBT-test, the superoxide formation was judged by changes in activity of superoxide dismutase (SOD). Exogenous FGs activated the enzyme due to the increased production of superoxide anion. In this case, DPI decreased SOD activity that conforms to the NADPH oxidase involvement in the superoxide generation. The analysis of antioxidant activity of FGs by inhibition of radicals of 2,2-diphenyl-1-picrylhydrazyl showed that FGs are weak reductants in comparison with ascorbic acid. The results of the work allow for the suggestion that, supposing a weak reducing capacity of FGs, the special feature of their exogenous action on cultured yam cells is the increase in the level of superoxide anion radical mainly produced by NADPH oxidase.     

Formation of superoxide and hydroxyl radicals from 1-methyl-4-phenylpyridinium ion (MPP+): reductive activation by NADPH cytochrome P-450 reductase

Formation of free radical intermediates from 1--methyl-4-phenylpyridinium ion(MPP+) has been studied using spin-trapping techniques. Incubation of MPP+ with purified NADPH cytochrome P-450 reductase and NADPH under anaerobic conditions failed to produce any detectable radical intermediates. However, in the presence of air and a spin-trap, a significant stimulation of superoxide and hydroxyl radicals was detected. Formation of these toxic radicals from MPP+ was inhibited by superoxide dismutase, catalase, and ethanol. Under identical conditions, however, considerably less of these radicals were formed with MPP+ in comparison to paraquat, a lung toxin containing two pyridinium moieties.     

The formation of active oxygen species following activation of 1-naphthol, 1,2- and 1,4-naphthoquinone by rat liver microsomes

The hepatic microsomal metabolism of 1-naphthol, 1,2- and 1,4-naphthoquinone has been shown to generate active oxygen species by using electron spin resonance spin-trapping techniques. 1-Naphthol, in the presence of NADPH, and 1,2- and 1,4-naphthoquinone, with either NADH or NADPH, caused a stimulation in both the rate of microsomal oxygen consumption and the formation of superoxide spin adduct, 5,5-dimethyl-2-hydroxyperoxypyrrolidino-1-oxyl (DMPO-OOH). Superoxide dismutase, but not catalase, prevented the formation of this spin adduct, further supporting the suggestion that the superoxide free radical was the major oxy-radical formed during the microsomal metabolism of 1-naphthol and the naphthoquinones. These results are compatible with the suggestion that 1-naphthol may exert its toxicity to isolated hepatocytes and other cellular systems by metabolism to naphthoquinones followed by their redox cycling with concomittant generation of active oxygen species in particular superoxide free radicals.     

Effect of drugs on oxidation and precipitation of the isolated chains of human hemoglobin

Summary The paper deals with the action of: primaquine, epinephrine, adrenochrome, acetylphenylhydrazine and sulphanilamide on the autoxidation of the isolated chains from human hemoglobin and on the precipitation which follows. The effect of superoxide dismutase and catalase on the drug induced autoxidation allows the assessment of the possible role of 0₂ derivatives (notably superoxide or peroxide) in the overall reaction mechanism. It is also shown that primaquine and acetylphenylhydrazine enhance precipitation of the isolated oxidized chains, while epinephrine and adrenochrome display a small inhibitory effect on precipitation. These effects do not involve O₂ radicals, but have presumably to be related to a destabilizing (or stabilizing) action of the drugs on the structure of the protein.     

Inhibition Of Thioredoxin Reductase (E.C. 1.6.4.5.) By Antitumor Quinones

Thioredoxin reductase (TR) is a widely distributed flavoenzyme that provides reduced thioredoxin, a dithiol hydrogen donor for protein disulfide reduction and for the reduction of ribonucleotides to deoxy-ribonucleotides, the first unique step of DNA synthesis. Antitumor quinones were found to exhibit time-and concentration-dependent inhibition of purified rdt liver TR that requires the presence of NADPH. Diaziquone initially shows competitive inhibition of the enzyme with 5,5′-dithiobis 2-nitrobenzoic acid as substrate with a K, of 7.5 SμM. which becomes non-competitive after I hour incubation with NADPH with a K, of 0.5 μM. Doxoruhicin shows non-competitive inhibition both initially and after 1 hr incubation with NADPH, with K_i values of 10μM and 0.5μM. respectively. Electron spin resonance spectroscopy showed the formation of semiquinone free radicals by TR incubated under anaerobic conditions with doxorubicin or diaziquone and NADPH. Redox cycling and formation of oxygen radicals does not play a major role in the inhibition of TR by antitumor quinones as shown by the minor effect on inhibition of removing O₂, and the lack of effect of superoxide dismutase and catalase. Diaziquone causes time- and concentration-dependent inhibition of TR activity in intact A204 human rhabdomyosarcoma cells that is associated with growth inhibition. The results suggest that inhihition of TR by antitumor quinones could contribute to their growth inhibitory properties     

Involvement of carbonyl reductase in superoxide formation through redox cycling of adrenochrome and 9,10-phenanthrenequinone in pig heart

The effects of adrenochrome, a metabolite of epinephrine (adrenaline), and 9,10-phenanthrenequinone (PQ), a component of diesel exhaust particles, on the stereoselective reduction of 4-benzoylpyridine (4-BP) were examined in pig heart cytosol. PQ was a potent inhibitor for the 4-BP reduction, while adrenochrome was a poor inhibitor. A similar result was observed in the effects of adrenochrome and PQ on the reduction of all-trans retinal. Furthermore, although PQ mediated efficiently the formation of superoxide anion radical through its redox cycling in pig heart cytosol, adrenochrome had no ability to mediate the superoxide formation. These may be because the reactivity for adrenochrome, catalyzed by pig heart carbonyl reductase (PHCR), is much lower than that for PQ. The optimal pH for the reduction of PQ in pig heart cytosol was around 5.5. Dicumarol, a potent inhibitor of DT-diaphorase, had little effect on the time course of NADPH oxidation during the reduction of PQ. Therefore, it is concluded that PHCR plays a critical role in superoxide formation through redox cycling of PQ.