Effect of superoxide dismutase on the autoxidation of various hydroquinones--a possible role of superoxide dismutase as a superoxide:semiquinone oxidoreductase

The autoxidation of DT-diaphorase-reduced 1,4-naphthoquinone, 2-OH-1,4-naphthoquinone, and 2-OH-p-benzoquinone is efficiently prevented by superoxide dismutase. This effect was assessed in terms of an inhibition of NADPH oxidation (over the amount required to reduce the available quinone), O2 consumption, and H2O2 formation. Superoxide dismutase also affects the distribution of molecular products -hydroquinone/quinone-involved in autoxidation, by favoring the accumulation of the reduced form of the above quinones. In contrast, the rate of autoxidation of DT-diaphorase-reduced 1,2-naphthoquinone is enhanced by superoxide dismutase, as shown by increased rates of NADPH oxidation, O2 consumption, and H2O2 formation and by an enhanced accumulation of the oxidized product, 1,2-naphthoquinone. These findings suggest that superoxide dismutase can either prevent or enhance hydroquinone autoxidation. The former process would imply a possible new activity displayed by superoxide dismutase involving the reduction of a semiquinone by O2-.. This activity is probably restricted to the redox properties of the semiquinones under study, as indicated by the failure of superoxide dismutase to prevent autoxidation of 1,2-naphthohydroquinone.     

Generation of superoxide radical during autoxidation of hydroxylamine and an assay for superoxide dismutase.

Accompanying the autoxidation of hydroxylamine at pH 10.2, nitroblue tetrazolium was reduced and nitrite was produced in the presence of EDTA. The rate of autoxidation was negligible below pH 8.0, but sharply increased with increasing pH. The reduction of nitroblue tetrazolium was inhibited by superoxide dismutase, indicating the participation of superoxide anion radical in the autoxidation. Hydrogen peroxide stimulated the autoxidation and superoxide dismutase inhibited the hydrogen peroxide-induced oxidation, results which suggest the participation of hydrogen peroxide in autoxidation and in the generation of superoxide radical. An assay for superoxide dismutase using autoxidation of hydroxylamine is described.     

Effect of superoxide dismutase on the autoxidation of substituted hydro- and semi-naphthoquinones

The effect of superoxide dismutase on the autoxidation of hydro- and semi-1,4-naphthoquinones with different substitution pattern and covering a one-electron reduction potential range from -95 to -415 mV was examined. The naphthoquinone derivatives were reduced via one or two electrons by purified NADPH-cytochrome P-450 reductase or DT-diaphorase, respectively. Superoxide dismutase did not alter or slightly enhance the initial rates of enzymic reduction, whereas it affected in a different manner the following autoxidation of the semi- and hydroquinones formed. Autoxidation was assessed as NADPH oxidation in excess to the amounts required to reduce the quinone present, H2O2 formation, and the redox state of the quinones. Superoxide dismutase enhanced 2--8-fold the autoxidation of 1,4-naphthosemiquinones, following the reduction of the oxidized counterpart by NADPH-cytochrome P-450 reductase, except for the glutathionyl-substituted naphthosemiquinones, whose autoxidation was not affected by superoxide dismutase. Superoxide dismutase exerted two distinct effects on the autoxidation of naphthohydroquinones formed during DT-diaphorase catalysis: on the one hand, it enhanced slightly the autoxidation of 1,4-naphthohydroquinones with a hydroxyl substituent in the benzene ring: 5-hydroxy-1,4-naphthoquinone and the corresponding derivatives with methyl- and/or glutathionyl substituents at C2 and C3, respectively. On the other hand, superoxide dismutase inhibited the autoxidation of naphthohydroquinones that were either unsubstituted or with glutathionyl-, methyl-, methoxyl-, hydroxyl substituents (the latter in the quinoid ring). The inhibition of hydroquinone autoxidation was reflected as a decrease of NADPH oxidation, suppression of H2O2 production, and accumulation of the reduced form of the quinone. The enhancement of autoxidation of 1,4-naphthosemiquinones by superoxide dismutase has been previously rationalized in terms of the rapid removal of O2-. by the enzyme from the equilibrium of the autoxidation reaction (Q2-. + O2----Q + O2-.), thus displacing it towards the right. The superoxide dismutase-dependent inhibition of H2O2 formation as well as NADPH oxidation during the autoxidation of naphthohydroquinones--except those with a hydroxyl substituent in the benzene ring--seems to apply to those organic substrates which can break down with simultaneous formation of a semiquinone and O2-.. Inhibition of hydroquinone autoxidation by superoxide dismutase can be interpreted in terms of suppression by the enzyme of O2-.- dependent chain reactions or a direct catalytic interaction with the enzyme that might involve reduction of the semiquinone at expense of O2(-.).(ABSTRACT TRUNCATED AT 400 WORDS)     

Interactions between metals, ligands, and oxygen in the autoxidation of 6-hydroxydopamine: mechanisms by which metal chelation enhances inhibition by superoxide dismutase

Transition metal ions and superoxide participate in different autoxidations to a variable extent. In the reaction of 6-hydroxydopamine (6-OHDA) with oxygen at pH 7.0 or 8.0, addition of 5 to 300 U/ml superoxide dismutase inhibited autoxidation by up to 96% at the highest concentrations. Superoxide dismutase at concentrations of 5-20 U/ml inhibited by less than 40% when present alone, but inhibited by over 99% in the presence of desferrioxamine or histidine. EDTA also enhanced the inhibition by 20 U/ml superoxide dismutase to 86%, even though EDTA accelerated the autoxidation of 6-OHDA when present alone or with desferrioxamine. In contrast, other ligands, such as ADP or phytic acid, had little or no effect on inhibition by superoxide dismutase. Proteins such as albumin, cytochrome oxidase, or denatured superoxide dismutase also enhanced inhibition by active superoxide dismutase from less than 40% to over 90%. Evidently, in the presence of redox active metals, autoxidation occurs by inner sphere electron transfer, presumably within a ternary 6-OHDA.metal.oxygen complex. This mechanism does not involve free O2-. and is not inhibited by superoxide dismutase. On the other hand, the presence of certain ligands (including proteins) diminishes the ability of trace metals to exchange electrons with 6-OHDA or oxygen by an inner sphere mechanism. These ligands render autoxidation dependent on propagation by O2-. and therefore inhibitable by superoxide dismutase. Previously conflicting reports that superoxide dismutase alone inhibits 6-OHDA autoxidation are thus explicable on the basis that at sufficient concentration the apoprotein coordinates trace metals in such a way to preclude inner sphere metal catalysis.     

Multiple actions of superoxide dismutase: why can it both inhibit and stimulate reduction of oxygen by hydroquinones?

Superoxide dismutase can either inhibit or stimulate autoxidation of different hydroquinones, suggesting multiple roles for O2.-. Inhibitory actions of superoxide dismutase include termination of O2.(-)-propagated reaction chains and metal chelation by the apoprotein. Together, chelation of metals and termination of O2.(-)-propagated chains can effectively prevent reduction of oxygen. Chain termination by superoxide dismutase can thus account for negligible accumulation of H2O2 without invoking a superoxide:semiquinone oxidoreductase activity for this enzyme. One stimulatory action of superoxide dismutase is to decrease thermodynamic limitations to reduction of oxygen. Whether superoxide dismutase inhibits or accelerates an autoxidation depends on the reduction potentials of the quinone and the availability of metal coordination for inner sphere electron transfers.     

Superoxide dismutases enhance the rate of autoxidation of 3-hydroxyanthranilic acid

The autoxidation of 3-hydroxyanthranilate to cinnabarinate at 37 degrees C and at pH 7.4 is hastened by superoxide dismutase (SOD). The Cu,Zn-containing enzyme from bovine erythrocytes and the Mn-containing enzyme from Escherichia coli were equally effective in this regard; whereas the H2O2-inactivated Cu,Zn enzyme was ineffective. Catalase appears to augment the effect of superoxide dismutase, because it prevents the bleaching of cinnabarinate by H2O2. It follows that O2-, which is a product of the autoxidation, slows the net autoxidation by engaging in back reactions and that SOD increases the rate of autoxidation by removal of O2- and thus by prevention of these back reactions.     

Mechanism of dismutation of superoxide produced during autoxidation of melanin pigments

The hydrogen peroxide produced during the autoxidation of melanin pigments has been measured using an oxidase electrode. The autoxidation has been shown to occur via the superoxide intermediate. The melanin pigment competes with superoxide dismutase for the scavenging of superoxide radicals. However, superoxide dismutase at high concentrations caused a substantial increase in the production of hydrogen peroxide, formed during melanin autoxidation. The implications of this finding are discussed in light of melanin's ability to function as a pseudo-dismutase.     

Dual effects of superoxide dismutase on the autoxidation of 1,4-naphthohydroquinone

The autoxidation of 1,4-naphthohydroquinone, in a phosphate, EDTA buffer at pH 7.4, exhibits an autocatalysis whose lag phase becomes more pronounced in the presence of either the Cu,Zn- or the Mn-containing superoxide dismutases. In contrast, the autoxidation of a second aliquot of the hydroquinone, added after complete oxidation of the first, is linear and is accelerated by superoxide dismutase. Catalase or inactive superoxide dismutase were without effect in either situation. These results are explicable in terms of a free radical chain reaction which is initially propagated by O2- and then, as the quinone accumulates, by univalent reduction of the quinone by the hydroquinone. Reduction of the quinone by O2- diminishes the overall rate of oxidation. It is not necessary to postulate catalysis by superoxide dismutase of the reduction of the semiquinone by O2-.     

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.     

Negative and positive assays of superoxide dismutase based on hematoxylin autoxidation

Hematoxylin, a natural dye commonly used as a histological stain, generates superoxide upon oxidation to its quinonoid product, hematein. The parameters affecting this reaction were assessed in developing a new and versatile assay for superoxide dismutase. The autoxidation of hematoxylin to hematein was accompanied by an increase in absorbance between 400 and 670 nm. The autoxidation rate was proportional to hematoxylin concentration and increased with pH above 6.55. Trace metals accelerated the autoxidation and this effect was eliminated by EDTA. Superoxide dismutase inhibited the autoxidation 90-95% below pH 7.8, but above pH 8.1 the rate was augmented by superoxide dismutase. The rate inhibition at low pH was proportional to the superoxide dismutase concentration up to 70% inhibition. The rate acceleration at high pH was proportional to superoxide dismutase concentration up to approximately 200% acceleration. The autoxidation rate was not significantly affected by ethanol, cyanide, azide, hydrogen peroxide, or catalase. However, the reaction was inhibited by the reducing agents NADH, reduced glutathione, ascorbate, and dithiothreitol, and by undialyzed extracts of Escherichia coli B. When cell extracts were dialyzed prior to assay, the degree of inhibition observed was proportional to the concentration of superoxide dismutase in the extract. These observations form the basis for negative and positive assays of superoxide dismutase which are inexpensive and simple to perform. The negative assay has the added advantage of being applicable at physiological pH.     

Reactions involving superoxide and normal and unstable haemoglobins.

Superoxide ions (O2-) oxidized oxyhaemoglobin to methaemoglobin and reduced methaemoglobin to oxyhaemoglobin. The reactions of superoxide and H2O2 with oxyhaemoglobin or methaemoglobin and their inhibition by superoxide dismutase or catalase were used to detect the formation of superoxide or H2O2 on autoxidation of oxyhaemoglobin. The rate of autoxidation was decreased at about 35% in the presence of both enzymes. The copper-catalysed autoxidation of Hb (haemoglobin) was also shown to involve superoxide production. Superoxide was released on autoxidation of three unstable haemoglobins and isolated alpha and beta chains, at rates faster than with Hb A. Reactions of superoxide with Hb Christchurch and Hb Belfast were identical with those with Hb A, and occurred at the same rate. Hb Koln contrasted with the other haemoglobins in that the thiol groups of residue beta-93 as well as the haem groups reacted with superoxide. Haemichrome formation from methaemoglobin occurred very rapidly with Hb Christchurch and Hb Belfast, as well as the isolated chains, compared with Hb A. The process did not involve superoxide production or utilization. The relative importance of autoxidation and superoxide production compared with haemichrome formation in the haemolytic process associated with these abnormal haemoglobins and thalassaemia is considered.     

Assay of superoxide dismutase activity in animal tissues

Convenient assays for superoxide dismutase have necessarily been of the indirect type. It was observed that among the different methods used for the assay of superoxide dismutase in rat liver homogenate, namely the xanthine-xanthine oxidase ferricytochromec, xanthine-xanthine oxidase nitroblue tetrazolium, and pyrogallol autoxidation methods, a modified pyrogallol autoxidation method appeared to be simple, rapid and reproducible. The xanthine-xanthine oxidase ferricytochromec method was applicable only to dialysed crude tissue homogenates. The xanthine-xanthine oxidase nitroblue tetrazolium method, either with sodium carbonate solution, pH 10.2, or potassium phosphate buffer, pH 7·8, was not applicable to rat liver homogenate even after extensive dialysis. Using the modified pyrogallol autoxidation method, data have been obtained for superoxide dismutase activity in different tissues of rat. The effect of age, including neonatal and postnatal development on the activity, as well as activity in normal and cancerous human tissues were also studied. The pyrogallol method has also been used for the assay of iron-containing superoxide dismutase inEscherichia coli and for the identification of superoxide dismutase on polyacrylamide gels after electrophoresis.     

Autoxidation of soluble trypsin-cleaved microsomal ferrocytochrome b5 and formation of superoxide radicals.

The rate and mechanism of autoxidation of soluble ferrocytochrome b5, prepared from liver microsomal suspensions, appear to reflect an intrinsic property of membrane-bound cytochrome b5. The first-order rate constant for autoxidation of trypsin-cleaved ferrocytochrome b5, prepared by reduction with dithionite, was 2.00 X 10(-3) +/- 0.19 X 10(-3) S-1 (mean +/- S.E.M., n =8) when measured at 30 degrees C in 10 mM-phosphate buffer, pH 7.4. At 37 degrees C in aerated 10 mM-phosphate buffer (pH 7.4)/0.15 M-KCl, the rate constant was 5.6 X 10(-3) S-1. The autoxidation reaction was faster at lower pH values and at high ionic strengths. Unlike ferromyoglobin, the autoxidation reaction of which is maximal at low O2 concentrations, autoxidation of ferrocytochrome b5 showed a simple O2-dependence with an apparent Km for O2 of 2.28 X 10(-4) M (approx. 20kPa or 150mmHg)9 During autoxidation, 0.25 mol of O2 was consumed per mol of cytochrome oxidized. Cyanide, nucleophilic anions, EDTA and catalase each had little or no effect on autoxidation rates. Adrenaline significantly enhanced autoxidation rates, causing a tenfold increase at 0.6 mM. Ferrocytochrome b5 reduced an excess of cytochrome c in a biphasic manner. An initial rapid phase, independent of O2 concentration, was unaffected by superoxide dismutase. A subsequent slower phase, which continued for up to 60 min, was retarded at low O2 concentrations and inhibited by 65% by superoxide dismutase at a concentration of 3 mug/ml. It is concluded that autoxidation is responsible for a significant proportion of electron flow between cytochrome b5 and O2 in liver endoplasmic membranes, this reaction being capable of generating superoxide anions. A biological role for the reaction is discussed.     

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].     

The role of superoxide radical in the autoxidation of cytochrome c.

The net rate of autoxidation of ferrocytochrome c was decreased by ferricytochrome c. Superoxide dismutase accelerated this autoxidation to a limit and overcame the inhibitory effect of ferricytochrome c. This was the case whether the autoxidationwas observed in the presence or in the absence of denaturants, such as alcohols orurea, and whether the superoxide dismutase used was the Cu-2+-Zn-2+ enzyme from bovine erythrocytes or the Mn-3+-enzyme from Escherichia coli. It can be deduced that the autoxidation of ferrocytochrome c, under a variety of conditions, geenerates O2 minus which can then dismute to H202 + O2 or can reduce ferricytochrome c back to ferrocytochrome c. Superoxide dismutase, by accelerating the dismutation of O2 minus, prevents the back reaction and thus exposes the true rate of reaction of ferrocytochrome c with molecular oxygen.     

Thiol-dependent lipid peroxidation

Initiation of lipid peroxidation in liposomes by cysteine, glutathione, or dithiothreitol required iron, and was not inhibited by superoxide dismutase. The absence of superoxide involvement in thiol autoxidation was confirmed by the inability of superoxide dismutase to inhibit thiol reduction of cytochrome c. Furthermore, the rate of cytochrome c reduction by thiols was not decreased under anaerobic conditions. We suggest that lipid peroxidation initiated by thiols and iron occurs via direct reduction of iron. Control of cellular thiol autoxidation, and reactions occurring as a consequence, such as lipid peroxidation, must therefore involve chelation of transition metals to control their redox reactions.     

Superoxide radical production during the autoxidation of 1-methyl-4-phenyl-2,3-dihydropyridinium perchlorate.

1-Methyl-4-phenyl-2,3-dihydropyridinium perchlorate (MPDP+), an intermediate in the metabolism of the neurotoxin 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine, was found to generate superoxide radicals during its autoxidation process. The generation of superoxide radicals was detected by their ability to reduce ferricytochrome c. Superoxide dismutase inhibited this reduction in a dose-dependent manner. The rate of reduction of ferricytochrome c was dependent not only on the concentration of MPDP+ but also on the pH of the system. Thus, the rate of autoxidation of MPDP+ and the sensitivity of this autoxidation to superoxide dismutase-inhibitable ferricytochrome c reduction were both augmented, as the pH was raised from 7.0 to 10.5. The rate constant (Kc) for the reaction of superoxide radical with ferricytochrome c to form ferricytochrome c was found to be 3.48 x 10(5) M-1 s-1. The rate constant (KMPDP+) for the reaction of MPDP+ with ferricytochrome3+ c was found to be only 4.86 M-1 s-1. These results, in conjunction with complexities in the kinetics, lead to the proposal that autoxidation of MPDP+ proceeds by at least two distinct pathways, one of which involves the production of superoxide radicals and hence is inhibitable by superoxide dismutase. It is possible that the free radicals so generated could induce oxidative injury which may be central to the MPTP/MPDP(+)-induced neuropathy.     

Superoxide-dependence of the short chain sugars-induced mutagenesis

Short chain sugars such as glycolaldehyde are produced at the initial stages of nonenzymatic glycosylation. Because their carbonyl groups cannot be blocked by cyclization, such compounds tautomerize to enediols, which are prone to autoxidation. Superoxide radical serves as an initiator and a propagator of this autoxidation. The biological importance of the involvement of superoxide in sugar autoxidation in vivo was examined using superoxide dismutase (SOD)-deficient and SOD-replete strains of Escherichia coli. Glycolaldehyde, glyceraldehyde, and dihydroxyacetone greatly enhanced the mutation rates in SOD-deficient E. coli. The effect was oxygen-dependent and was suppressed by SOD or by a SOD mimetic. The mutagenic effect of glycolaldehyde coincided with intracellular accumulation of glyoxal, a product of glycolaldehyde autoxidation.     

Effects of superoxide dismutase on the autoxidation of 1,4-hydroquinone

During autoxidation of 1,4-hydroquinone (H2Q, less than 1 mM) at pH 7.4 and 37 degrees C, stoichiometric amounts of 1,4-benzoquinone (Q) and hydrogen peroxide were formed during the initial reaction. The reaction kinetics showed a significant induction period which was abolished by minute amounts of Q. Hydrogen peroxide and catalase were without effect on the autoxidation process. Transition metals apparently were not involved, since chelators like EDTA, DETAPAC, and desferrioxamine or FeSO4 had no influence on the autoxidation kinetics. Superoxide dismutase (SOD) did not abolish the induction period but dramatically enhanced the autoxidation rate by more than two orders of magnitude. The stimulatory effect was first-order in SOD concentration but showed saturation kinetics. The dependence of Q and hydrogen peroxide formation rates on H2Q concentration shows a biphasic behaviour: dependence on the square at low H2Q, but on the square root at high H2Q concentration. As revealed by calculatory simulations the results can be adequately described by the known reaction rate constants. The reaction starts with the comproportionation of H2Q and Q to yield two semiquinone molecules which autoxidize to give two superoxide radicals and two molecules of Q which enter into a new cycle of comproportionation. Because of unfavourable equilibria the autocatalytic reaction soon comes to steady state, and the further reaction is governed by the rate of superoxide removal. At excess SOD, the comproportionation reaction is rate-limiting, thus explaining the saturation effects of SOD. The experiments do not allow a decision between the two functions of SOD; the conventional action as a superoxide:superoxide oxidoreductase or as a semiquinone:superoxide oxidoreductase. In the latter reaction SOD is thought to be reduced by semiquinone with Q formation. In the second step the reduced enzyme would be re-oxidized by a superoxide radical which is formed during autoxidation of the second semiquinone molecule generated in the comproportionation reaction. From thermodynamic considerations, the latter function of SOD appears to be plausible.     

Kinetic analysis and mechanistic aspects of autoxidation of catechins

A peroxidase-based bioelectrochemical sensor of hydrogen peroxide (H(2)O(2)) and a Clark-type oxygen electrode were applied to continuous monitoring and kinetic analysis of the autoxidation of catechins. Four major catechins in green tea, (-)-epicatechin, (-)-epicatechin gallate, (-)-epigallocatechin, and (-)-epigallocatechin gallate, were used as model compounds. It was found that dioxygen (O(2)) is quantitatively reduced to H(2)O(2). The initial rate of autoxidation is suppressed by superoxide dismutase and H(+), but is independent of buffer capacity. Based on these results, a mechanism of autoxidation is proposed; the initial step is the one-electron oxidation of the B ring of catechins by O(2) to generate a superoxide anion (O(2)(*-)) and a semiquinone radical, as supported in part by electron spin resonance measurements. O(2)(*-) works as a stronger one-electron oxidant than O(2) against catechins and is reduced to H(2)O(2). The semiquinone radical is more susceptible to oxidation with O(2) than fully reduced catechins. The autoxidation rate increases with pH. This behavior can be interpreted in terms of the increase in the stability of O(2)(*-) and the semiquinone radical with increasing pH, rather than the acid dissociation of phenolic groups. Cupric ion enhances autoxidation; most probably it functions as a catalyst of the initial oxidation step of catechins. The product cuprous ion can trigger a Fenton reaction to generate hydroxyl radical. On the other hand, borate ion suppresses autoxidation drastically, due to the strong complex formation with catechins. The biological significance of autoxidation and its effectors are also discussed.