Reprint of: Biological Effects of the Superoxide Radical.

Can the superoxide radical exert deleterious effects independent of participating with H2O2 in the production of the hydroxyl radical? Examination of the superoxide-related literature reveals data suggesting an affirmative answer to this question. © 1986 Academic Press, Inc.

Reprint of: Intracellular Production of Superoxide Radical and of Hydrogen Peroxide by Redox Active Compounds.

Several compounds have been found capable of diverting the electron flow in Escherichia coli and thus causing increased intracellular production of O2- and H2O2. One indication of this electron-shunting action was increased cyanide-resistant respiration and one cellular response was increased biosynthesis of the manganese-containing superoxide dismutase and of catalase. Blocking cytochrome oxidase with cyanide or azide increased the electron flow available for reduction of paraquat and presumably of the other exogenous compounds tested and thus increased their biological effects. Paraquat, pyocyanine, phenazine methosulfate, streptonigrin, juglone, menadione, plumbagin, methylene blue, and azure C were all effective in elevating intracellular production of O2- and H2O2. The effect of alloxan appeared paradoxical in that it increased cyanide-resistant respiration without significantly increasing the cell content of the manganese-superoxide dismutase and with only a small effect on the level of catalase. The alloxan effect on cyanide-resistant respiration was artifactual and was due to an oxygen-consuming reaction between alloxan and cyanide, rather than to a diversion of the intracellular electron flow. With paraquat as a representative electron-shunting compound, the increase in biosynthesis of the manganese-superoxide dismutase was prevented by inhibitors of transcription or of translation, but not by an inhibitor of replication. The increase in this enzyme activity, caused by paraquat and presumably by the other compounds, was thus due to de novo enzyme synthesis activated or derepressed at the level of transcription.

Oxygen: how do we stand it?.

The electronic structure of ground state oxygen, which is essential for the life of all aerobic organisms, makes it potentially dangerous for those organisms. Atmospheric oxygen contains two unpaired electrons with parallel spin states, which predisposes it to reduction by a univalent pathway. As a consequence, normal aerobic metabolism generates dangerous reactive intermediates of the reduction of O2. These include superoxide radical (O2*-), hydrogen peroxide (H2O2), and hydroxyl radical (HO*). These reactive oxygen species and others that they can engender can damage all cellular macromolecules and unless opposed by cellular defenses, would make aerobic life impossible. Such defenses include superoxide dismutases, catalases, and peroxidases, enzymes that decrease the concentration of the reactive oxygen species that are their substrates, and others that repair or recycle oxidatively damaged macromolecules. Any factor that stimulates reactive oxygen species production or suppresses the antioxidant systems would inevitably cause cell damage. The role of such oxidative damage in various diseases is well documented. In vivo detection of O2- and other reactive oxygen species is however hampered by the lack of easy, specific, and sensitive analytical methods. Potential artifacts and limitations of the most common detection methods currently in use are briefly discussed.

Superoxide dismutases: anti- versus pro- oxidants?

The family of superoxide dismutases (SODs) are well known for their antioxidant actions exerted by catalyzing the conversion of O(2)(·-) into H(2)O(2) plus oxygen. The importance of this action is revealed by the multiple phenotypic deficits exhibited by a variety of organisms that have been made to lack one or more of the SODs. Never the less there have been reports of deleterious consequences caused by overproduction of SOD. Several explanations have been proposed for these counter intuitive effects; one of which is that elevated SOD causes increased formation of H(2)O(2). The reasons for dismissing this explanation are explored.

Mechanism of the peroxidase activity of Cu, Zn superoxide dismutase.

In addition to its very efficient catalysis of the dismutation of superoxide ( O(2)(-) ) into O(2) plus H(2)O(2), Cu, Zn SOD acts less efficiently as a non-specific peroxidase. This peroxidase activity is CO(2) dependent although very slow peroxidation of some substrates occurs in the absence of CO2. The mechanism of that CO(2) dependence is explained by the generation of a strong oxidant at the copper site by two sequential reactions with H(2)O(2), followed by the oxidation of CO(2) to the carbonate radical that then diffuses into the bulk solution. This diffusible carbonate radical is then responsible for the diverse oxidations that have been reported. A different mechanism that involves the reduction of peroxymonocarbonate by the reduced superoxide dismutase to yield carbonate radical has been proposed. We will demonstrate that this mechanism is not supported by the available data. It seems likely that generation of the carbonate radical has relevance to the oxidative stress faced by aerobic organisms.

Putative denitrosylase activity of Cu,Zn-superoxide dismutase.

The Cu,Zn-superoxide dismutase (SOD1) has been reported to exert an S-nitrosylated glutathione (GSNO) denitrosylase activity that was augmented by a familial amyotrophic lateral sclerosis (FALS)-associated mutation in this enzyme. This putative enzymatic activity as well as the spontaneous decomposition of GSNO has been reexamined. The spontaneous decomposition of GSNO exhibited several peculiarities, such as a lag phase followed by an accelerating rate plus a marked dependence on GSNO concentration, suggestive of autocatalysis, and a greater rate in polypropylene than in glass vessels. Dimedone caused a rapid increase in absorbance likely due to reaction with GSNO, followed by a slower increase possibly due to reaction with an intermediate such as glutathione sulfenic acid. SOD1 weakly increased the rate of decomposition of GSNO, but did so only when GSH was present; and FALS-associated mutant forms of SOD1 were not more active in this regard than was the wild type. Decomposed GSNO, when added to fresh GSNO, hastened its decomposition, in accord with autocatalysis, and when added to GSH, generated GSNO in accord with the presence of nitrite. A mechanism is proposed that is in accord with these observations.

The effects of superoxide dismutase on H2O2 formation.

Numerous reports of the effects of overproduction of SODs have been explained on the basis of increased H2O2 production by the catalyzed dismutation of O2-. In this review we consider the effects of increasing [SOD] on H2O2 formation and question this explanation.

Modification of cysteine 111 in human Cu,Zn-superoxide dismutase.

Human Cu,Zn-superoxide dismutase (hSOD1) has 4 cysteines per subunit. Cys57 and Cys148 are involved in an intrasubunit disulfide bond, while Cys6 and Cys111 are free. Cys6 is buried within the protein while Cys111 is on the surface, near the dimer interface. We examined by liquid chromatography-mass spectrometry the commercially purchased hSOD1 isolated from erythrocytes as well as hSOD1s isolated from human erythrocytes, brain, and hSOD1 expressed in Sf9, yeast, and E. coli. Our goal was to ascertain whether the Cys111 modification occurred naturally in vivo. Only the Sigma erythrocyte hSOD1 appeared to contain a trisulfide crosslink between the Cys111 residues. Thus it failed to react with N-ethylmaleimide, showed absorbtion at 325 nm that was eliminated by 2-mercaptoethanol, and had a mass 30 units more than expected for the native dimer. We examined the possibility that different purification methods might cause this modification in erythrocyte hSOD1. None of the procedures examined for hSOD1 purification produced such a trisulfide. In disagreement with Liu et al. [Biochemistry, 2000, 39, 8125-8132], complete derivitization of both Cys111s of hSOD1 from Sf9 cells with N-ethylmaleimide, 4-vinylpyridine, and by 5,5'-dithiobis(2-nitrobenzoic acid) were readily achieved; indicating that steric hindrance was not a problem.

Inactivation of copper, zinc superoxide dismutase by H2O2 : mechanism of protection.

Cu,Zn SOD is known to be inactivated by HO(2)(-) and to be protected against that inactivation by a number of small molecules including formate, imidazole, and urate. This inactivation has been shown to be due to oxidation of a ligand field histidine residue by a bound oxidant formed by reaction of the active site Cu(II) with HO(2)(-). We now report that protective actions of both formate and NADH increase as the pH was raised in the range 8.0-9.5. This is taken to indicate increased accessibility of the Cu site with rising pH and/or increased reactivity of the bound oxidant toward exogeneous substrates at high pH. Formate appears to act as a sacrificial substrate that protects by competing with the endogenous histidine residue for reaction with the bound oxidant, or that repairs the damage by reducing the histidyl radical intermediate. The same is likely also true of NADH.

Kinetic properties of Cu,Zn-superoxide dismutase as a function of metal content--order restored.

In a recent publication (Michel et al. Arch. Biochem. Biophys. 439:234-240; 2005) the authors argued that the catalytic rate constant, k(cat), for wild-type Cu,Zn-superoxide dismutase (Cu,Zn-SOD), determined previously by pulse radiolysis, was overestimated due to contamination with excess copper. They reported that addition of 0.1 mM EDTA to a sample that already contained excess copper did not remove spurious activity, which is incompatible with well-known stability constants of copper complexes and contradicts previous observations. In the present study we verified that the addition of EDTA eliminates completely the effect of excess copper on the decomposition rate of O2*- in the presence of Cu,Zn-SOD. We determined that k(cat) = (2.82 +/- 0.02) x 10(9) M(-1) s(-1) at low ionic strength (2 < I < 15 mM) and (1.30 +/- 0.02) x 10(9) M(-1) s(-1) in the presence of 50 mM phosphate at pH 7.8 (I = approximately 150 mM), which are about twice higher than those reported by Michel et al. We also determined k(cat) by the cytochrome c assay and demonstrated the correlation between these direct and indirect assays. The phenotypic deficits imposed by deletion of SODs, and the oxygen dependence of these deficits, have repeatedly demonstrated that the several SODs do in fact, as well as is theory, provide an important protection against that facet of oxidative stress imposed by O2*-.

The role of CO2 in metal-catalyzed peroxidations.

Transition metals, such as Cu(+2), Mn(+2), and Co(+2), have been seen to catalyze the bicarbonate enhanced oxidation of a variety of substrates by H(2)O(2). In several of these cases it has been demonstrated that CO(2), rather than bicarbonate, is the enhancing species. Mechanisms that are in accord with the data involve a hypervalent state that may be written (MO)(+n), or (MOH)(+n+1), or (M)(+n+2). This metal centered oxidant then oxidizes CO(2) to the carbonate radical; that is then the proximal oxidant of the various substrates. Whether a similar process has in vivo reality remains to be demonstrated.

New PEG-ylated Mn(III) porphyrins approaching catalytic activity of SOD enzyme.

Two new tri(ethyleneglycol)-derivatized Mn(III) porphyrins were synthesized with the aim of increasing their bioavailability, and blood-circulating half-life. These are Mn(III) tetrakis(N-(1-(2-(2-(2-methoxyethoxy)ethoxy)ethyl)pyridinium-2-yl)porphyrin, MnTTEG-2-PyP5+ and Mn(III) tetrakis(N,N'-di(1-(2-(2-(2-methoxyethoxy)ethoxy)ethyl)imidazolium-2-yl)porphyrin, MnTDTEG-2-ImP5+. Both porphyrins have ortho pyridyl or di-ortho imidazolyl electron-withdrawing substituents at meso positions of the porphyrin ring that assure highly positive metal centered redox potentials, E1/2 = +250 mV vs. NHE for MnTTEG-2-PyP5+ and E1/2 = + 412 mV vs. NHE for MnTDTEG-2-ImP5+. As expected, from established E1/2 vs. log kcat(O2 *-) structure-activity relationships for metalloporphyrins (Batinic-Haberle et al., Inorg. Chem., 1999, 38, 4011), both compounds exhibit higher SOD-like activity than any meso-substituted Mn(III) porphyrins-based SOD mimic thus far, log kcat = 8.11 (MnTTEG-2-PyP5+) and log kcat = 8.55 (MnTDTEG-2-ImP5+), the former being only a few-fold less potent in disproportionating O2*- than the SOD enzyme itself. The new porphyrins are stable to both acid and EDTA, and non toxic to E. coli. Despite elongated substituents, which could potentially lower their ability to cross the cell wall, MnTTEG-2-PyP5+ and MnTDTEG-2-ImP5+ exhibit similar protection of SOD-deficient E. coli as their much smaller ethyl analogues MnTE-2-PyP5+ and MnTDE-2-ImP5+, respectively. Consequently, with anticipated increased blood-circulating half-life, these new Mn(III) porphyrins may be more effective in ameliorating oxidative stress injuries than ethyl analogues that have been already successfully explored in vivo.

The role of CO2 in cobalt-catalyzed peroxidations.

Augmentation, by CO(2)/HCO(3)(-), of Co(II)-catalyzed peroxidations was explored to clarify whether the rate enhancement was due to CO(2) or to HCO(3)(-). The rate of oxidation of NADH by Co(II) plus H(2)O(2), in Tris or phosphate, was markedly enhanced by CO(2)/HCO(3)(-). Phosphate was seen to inhibit the Co(II)-catalyzed peroxidation, probably due to its sequestration of the Co(II). When CO(2) was used, there was an initial burst of NADH oxidation followed by a slower linear rate. The presence of carbonic anhydrase eliminated this initial burst; establishing that CO(2) rather than HCO(3)(-) was the species responsible for the observed rate enhancements. Both kinetic and spectral data indicated that Co(II) was converted by H(2)O(2) into a less active form from which Co(II) could be regenerated. This less active form absorbed in both the UV and visible regions, and is assumed to be a peroxy bridged binuclear complex. The rate of formation of this absorbing form was increased by HCO(3)(-)/CO(2). A minimal mechanism consistent with these observations is proposed.