Direct generation of superoxide anions by flash photolysis of human oxyhemoglobin.

The results presented in this report suggest that human oxyhemoglobin can directly form methemoglobin and superoxide anion when flashed with low intensity (38 joules) white light. The effect only occurred in quartz but not glass (cut off lambda approximately equal to 300 nm) cuvettes. The formation of O2 was established by observing the reduction of oxidized cytochrome c concomitant with MetHb formation at pH 9, and by showing that superoxide dismultase and catalse inhibit cytochrome c reduction at that pH. The inhibition of cytochrome c reduction by catalase led us to explore the possibility that H2O2 might reduce oxidized cytochrome c at pH 9. We show that H2O2 does reduce oxidized cytochrome c at that pH but not at pH 7. Furthermore, catalase but not superoxide dismutase, almost completely inhibited this reduction process. These experiments serve to confirm our interpretation of the effect of catalase on the reduction of oxidized cytochrome c in the photolytic experiments, thus establishing that H2O2 was also formed. In addition, we were able to identify the production of O2 and H2O2 due to the photolysis of water in agreement with the results of McCord and Fridovich ((1973) Photochem. Photobiol. 17, 115-121). Production of O2 from this source was considerably less than that observed when HbO2 was present. Addition of MetHb to aerated solutions of oxidized cytochrome c did not cause additional reduction, unlike addition of HbO2. The production of MetHb was found to have at least two components. One component was the primary photolytic process, and the second was a strongly pH-dependent reattack of HbO2 by O2. Addition of superoxide dismutase inhibited this second component, but did not significantly effect the primary photolytic process.     

The role of superoxide in the destruction of erythrocyte targets by human neutrophils

Human neutrophils exposed to the soluble stimulus, phorbol myristate acetate, generate a flux of O2.- which can destroy human erythrocyte targets. Under optimal conditions, each neutrophil was capable of lysing almost 10 erythrocyte targets. Hemolysis was inhibited by exogenous copper-zinc or iron superoxide dismutase while neither heat-denatured enzyme nor albumin inhibited cytotoxicity. Although neutrophils can also generate H2O2, neither catalase nor a glutathione-glutathione peroxidase system inhibited hemolysis. Hemolysis was prevented by conversion of the hemoglobin to carbon monoxyhemoglobin, suggesting an intracellular mechanism of cytotoxicity. Conversion of hemoglobin to methemoglobin by nitrite treatment did not impair neutrophil-mediated hemolysis. However, nitrite-treated targets were not protected by superoxide dismutase, while exogenous catalase inhibited cytotoxicity, suggesting a potential role for H2O2 and methemoglobin. H2O2 and methemoglobin are known to interact to form an oxidant complex whose cytotoxic potential was underlined by the marked sensitivity of nitrite-treated cells to commercial H2O2. It is proposed that neutrophil-derived O2.- oxidizes oxyhemoglobin to generate methemoglobin and H2O2 which interact to form a cytotoxic complex capable of hemolyzing the erythrocyte target.     

Degradation of uric acid during autocatalytic oxidation of oxyhemoglobin induced by sodium nitrite.

The oxidation of oxyhemoglobin produced by sodium nitrite occurs in two stages: 1) an initial slow phase followed by 2) a rapid autocatalytic phase that carries the reaction to completion. The length of the slow phase is extended when uric acid is added to the reaction mixture. As the concentration of uric acid increases, the length of the slow phase increases until a concentration is reached at which the rate of methemoglobin formation is nearly linear until the reaction is complete. Further increases in the concentration of uric acid do not affect the rate of the reaction in the slow phase. At low concentrations of uric acid, where an autocatalytic phase is reached, uric acid is degraded during the reaction. At concentrations of uric acid that keep the reaction in the linear phase, the uric acid is not degraded. It is concluded that uric acid may protect oxyhemoglobin by reacting with HbO2H to yield [HbOH]+ and the urate radical. The urate radical may react with a second molecule of HbO2H and become oxidized. At higher concentrations, the radical may undergo electron transfer with oxyhemoglobin to regenerate the uric acid and form methemoglobin.     

Inhibition by superoxide dismutase of methemoglobin formation from oxyhemoglobin.

The formation of methemoglobin from oxyhemoglobin in a solution containing photoreduced riboflavin and oxygen was inhibited by superoxide dismutase. The rate of the reaction was pH-dependent in the range of 6.8 to 7.8, increasing as the pH was reduced. Inhibition by superoxide dismutase was enhanced as the EDTA concentration increased and was dependent on enzymatic activity. Under conditions in which superoxide dismutase inhibition was incomplete, catalase inhibited the reaction but mannitol had no effect. The data support the mediation of methemoglobin formation by superoxide. The hypothesis is offered that superoxide anion reduced the heme-bound oxygen in oxygemoglobin by one electron, permitting the subsequent dissociation of ferrihemoglobin and peroxide. The ability of superoxide dismutase to inhibit the formation of methemoglobin may represent one of its functions in the mature erythrocyte.     

Stoichiometry of the reaction of oxyhemoglobin with nitrite.

During the reaction of oxyhemoglobin (HbO2) with nitrite, the concentration of residual nitrite, nitrate, oxygen, and methemoglobin (Hb+) was determined successively. The results obtained at various pH values indicate the following stoichiometry for the overall reaction: 4HbO2 + 4NO2- 4H+ leads to 4Hb+ + 4NO3- + O2 + 2H2 O (Hb denotes hemoglobin monomer). NO2- binds with methemoglobin noncooperatively with a binding constant of 340 M-1 at pH 7.4 and 25 degrees C. Thus, the major part of Hb+ produced is aquomethemoglobin, not methemoglobin nitrite, when less than 2 equivalents of nitrite is used for the oxidation.     

Retinoic acid 5,6-epoxidation by hemoproteins

Retinoic acid 5,6-epoxidase activity was found in several hemoproteins such as human oxy- and methemoglobin (HbO2 and MetHb), equine skeletal muscle oxy- and metmyoglobin (MbO2 and MetMb), bovine liver catalase, and horseradish peroxidase. Hematin also catalyzed retinoic acid 5,6-epoxidation. The results suggest that the heme moiety participates in the epoxidation. However, neither horse heart cytochrome c, nor free ferrous ion nor free ferric ion exhibited the epoxidase activity. Some hemoproteins (HbO2, MetHb, MbO2, MetMb, catalase, peroxidase, and hematin) exhibited characteristic individual pH dependences of the activity, suggesting that the epoxidase activities of the hemoproteins are influenced by the apoenzymes to some degree. This view is also supported by the finding that preincubation of an HbO2 preparation at various temperatures (37-70 degrees C) reduced its epoxidase activity with increasing temperature, whereas the activity of hematin was unaffected. Active oxygen scavengers such as mannitol, catalase, and superoxide dismutase exhibited no effect on the epoxidase activities of HbO2, MetHb, MbO2, and MetMb. A ligand of heme, CN- (100 mM), inhibited the epoxidase activities but N3- (100 mM) did not. The epoxidase activities were completely inhibited by NADPH, NADH, and/or 2-mercaptoethanol but not by NADP+ and/or NAD+. An intermediate in the epoxidation may be reduced by NADPH, NADH and/or 2-mercaptoethanol. Radical species can be considered as plausible candidates for the intermediate.     

Mechanism of electron transfer to coordinated dioxygen of oxyhemoglobins to yield peroxide and methemoglobin. Protein control of electron donation by aquopentacyanoferrate(II)

Reactions of human oxyhemoglobin A with iron(II) compounds have been investigated. Human oxyhemoglobin (HbO2) reacts with aquopentacyanoferrate(II), Fe(II)(CN)5H2O3-, to yield hydrogen peroxide, aquomethemoglobin and Fe(III)(CN)5H2O2-. The reaction follows a second order rate law, first order in the pentacyanide and in HbO2. Since reaction rates are lower in the presence of catalase, the H2O2 produced must promote metHb formation in reactions independent of pentacyanide. Changes in concentrations of effectors (e.g. H+, inositol hexaphosphate, Cl-, and Zn2+), alkylation of beta-93 cysteine with N-ethylmaleimide, and substitution at distal histidine (as in Hb Zurich with beta-63 His----Arg) in each case can markedly affect pentacyanide reaction rates demonstrating a fine control of rates by protein structure. Hexacyanoferrate(II) (ferrocyanide) reacts with HbO2 to produce cyano-metHb as well as aquo-metHb but the reaction with the hexacyanide is much slower than with the aquopentacyanide. Iron(II) EDTA converts HbO2 to deoxy-Hb with no evidence for formation of metHb as an intermediate. These findings support a mechanism in which the pentacyanide anion reacts directly with coordinated dioxygen. One-electron transfers to O2 from both pentacyanide iron(II) and heme iron(II) result in the formation of a mu-peroxo intermediate, HbFe(III)-O-O-Fe(III) (CN)5(3-). Hydrolysis of this intermediate yields metHb . H2O, H2O2, and FeIII(CN)5H2O2-. The reaction of HbO2 with Fe(CN)6(4-) must follow an outer sphere electron transfer mechanism. However, the very slow rate that is seen with Fe(CN)6(4-) could arise entirely from the pentacyanide produced from loss of one cyanide ligand from the hexacyanide. Fe(II)EDTA reacts rapidly with free O2 in solution but can not interact directly with the heme-bound O2 of HbAO2. The dynamic character of the O2 binding sites apparently permits access of the Fe2+ of the pentacyanide to coordinated dioxygen but the protein structure is not sufficiently flexible to allow the larger Fe2+EDTA molecule to react with bound O2. It is necessary for maintenance of the oxygen transport function of the red cell for reductants such as the methemoglobin reductase system, glutathione, and ascorbate to be able to reduce metHb to deoxy-Hb. It is also important for these reductants to be unable to donate an electron to HbO2 to yield H2O2 and metHb. Thus, a mechanistic requirement for the delivery of one-electron directly to the dioxygen ligand, if peroxide is to be produced, enables the protein to protect the oxygenated species from those electron donors normally present in the cell by denying these reductants steric access to coordinated O2.(ABSTRACT TRUNCATED AT 400 WORDS)     

The mechanism of superoxide anion generation by the interaction of phenylhydrazine with hemoglobin.

The mechanism by which superoxide anion is generated by the interaction of phenylhydrazine with either oxy- or methemoglobin was investigated. Rather than superoxide anion generation resulting from an accelerated autooxidation of oxyhemoglobin, it was found that both oxy- and methemoglobin function as peroxidases toward phenylhydrazine with the resultant oxidation of this compound to phenyldiazine. Generation of phenyldiazine from the oxidation of phenylhydrazine by hemoglobin or by the hydrolysis and subsequent decarboxylation of methyl phenylazoformate (C6H5N=NCOOCH3) resulted in the production of superoxide anion. It is suggested that under certain conditions hemoglobin may function as a drug-metabolizing peroxidase.     

Possible contribution of oxyhemoglobin to the iron-induced hemolysis simultaneous effect of iron and hemoglobin on lipid peroxidation

The mechanism of iron toxicity in iron overloaded patients is not well established. A hypothesis was put forward that free radical processes are involved. Our earlier study indicates that iron-induced hemolysis is preceded by peroxidation of the membrane lipids. In the present work the simultaneous effect of iron and hemoglobin on lipid peroxidation was studied. It was found that in hemoglobin-containing liposome suspensions Fe2+ in concentrations above 10(-5) M inhibits the peroxidation, while Fe3+ drastically potentiates it, with concomitant transformation of oxyhemoglobin to methemoglobin. The experiments with scavengers of activated oxygen indicate superoxide anion radical (O-.2), hydroxyl radical (OH.) and singlet oxygen (1O2) participation. The possible mechanism of the phenomenon is discussed. A conclusion is drawn that the toxic effect of Fe3+ may be associated not only with iron--membrane interaction, but also with increased methemoglobin formation and O-.2 release.     

Neutrophil-mediated methemoglobin formation in the erythrocyte. The role of superoxide and hydrogen peroxide

Human neutrophils incubated with phorbol myristate acetate oxidized hemoglobin within the intact erythrocyte by a mechanism dependent on cell-cell contact but independent of phagocytosis. Spectrophotometric examination of the erythrocyte lysates revealed that the major component formed was methemoglobin along with small amounts of a species with spectral characteristics similar to choleglobin. Methemoglobin formation was directly related to the neutrophil concentration and the time of incubation. The addition of superoxide dismutase or catalase modestly inhibited the formation of methemoglobin, while a combination of the enzymes provided the most dramatic protection. Methemoglobin of hydroxyl radical or hypochlorous acid scavengers. Apparently, either O2.- or H2O2 alone was capable of mediating methemoglobin formation in the intact erythrocyte. Maintenance of the intraerythrocytic hemoglobin in its oxygenated state or its derivatization to carbon monoxyhemoglobin markedly inhibited methemoglobin formation. Blockade of the anion channels in the intact erythrocyte with sulfonated stilbenes inhibited O2.- but not H2O2 from oxidizing intracellular hemoglobin. It appears that neutrophil-derived O2.- and H2O2 can cross the erythrocyte membrane through the anion channel or diffuse directly into the intracellular space and react with oxyhemoglobin or deoxyhemoglobin to form a mixture of hemoglobin oxidation products within the intact cell.     

Reactions of triethylphosphine gold(I) complexes with heme proteins: novel spin-state changes in cytochrome b562, myoglobin, and hemoglobin

Reactions of bacterial Fe(III) cyt b562, HbO2, met Hb and met Mb with Et3PAuCl and Et3PAuNO3 (and some related complexes) have been investigated by electronic absorption and EPR and NMR spectroscopy. Except for met Hb, which denatured, the products were novel high-spin Fe(III) heme proteins. The reactions of cyt b562 and Mb were reversible. Two distinct kinetic steps were observed in the autoxidation of HbO2 and MbO2. These may involve the liberation of superoxide. Autoxidation of HbO2 occurred more rapidly than that of MbO2. The kinetics of the spin-state change of cyt b562 were too fast to measure by conventional (spectrophotometric) methods. The reaction of Et3PAuCl with HbO2 was not blocked by N-ethylmaleimide. The reactions are discussed in terms of attack by Et3PAu+ on histidine residues in the hydrophobic haem pockets of the proteins.     

Fatty-acid initiated auto-oxidation of hemoglobin

The interaction of fatty acids (FA) with oxyhemoglobin (HbO2) was investigated. It was found that under effect of FA HbO2 is converted into the oxidized low-spin form, i. e., hemichrome. An increase in the level of reactive oxygen species was registered by the ESP method, using the spin traps, 1.2-dioxybenzo-3.5-disulphonate (tiron) and 5.5-dimethylpyrroline-1-oxide (DMPO). To investigate the nature of radical particles, the OH radical traps. thiourea and D-mannitol, as well as superoxide dismutase (SOD) and catalase were employed. The mechanism of interaction of HbO2 and FA is discussed; its feasible physiological role in the functioning of erythrocytes is postulated.     

Membrane effects of nitrite-induced oxidation of human red blood cells.

The aim of our investigation was to study the red blood cell (RBC) membrane effects of NaNO(2)-induced oxidative stress. Hyperpolarization of erythrocyte membranes and an increase in membrane rigidity have been shown as a result of RBC oxidation by sodium nitrite. These membrane changes preceded reduced glutathione depletion and were observed simultaneously with methemoglobin (metHb) formation. Changes of the glutathione pool (total and reduced glutathione, and mixed protein-glutathione disulfides) during nitrite-induced erythrocyte oxidation have been demonstrated. The rates of intracellular oxyhemoglobin and GSH oxidation highly increased as pH decreased in the range of 7.5-6.5. The activation energy of intracellular metHb formation obtained from the temperature dependence of the rate of HbO(2) oxidation in RBC was equal to 16.7+/-1.6 kJ/mol in comparison with 12.8+/-1.5 kJ/mol calculated for metHb formation in hemolysates. It was found that anion exchange protein (band 3 protein) of the erythrocyte membrane does not participate significantly in the transport of nitrite ions into the erythrocytes as band 3 inhibitors (DIDS, SITS) did not decrease the intracellular HbO(2) oxidation by extracellular nitrite.     

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.     

Production of superoxide anion during the oxidation of hemoglobin by menadione.

Menadione in the presence of oxyhemoglobin will accelerate the formation of methemoglobin and result in the generation of superoxide anion. Menadione appears to oxidize slowly ferrohemoglobin to ferrihemoglobin, while forming menadione semiquinone in the process. Menadione semiquinone is known to react with molecular oxygen to yield superoxide anion. The superoxide anion appears to be the source of hydrogen peroxide which accounts for most of the observed methemoglobin formation when hemoglobin is reacted with menadione.     

Mechanism of autocatalytic oxidation of oxyhemoglobin by nitrite. An intermediate detected by electron spin resonance

Oxidation of oxyhemoglobin by nitrite is characterized by the presence of a lag phase followed by the autocatalysis. Just before the autocatalysis begins, an asymmetric ESR signal is detected which is similar to that of the methemoglobin radical generated from methemoglobin and H2O2 in shape, g value (2.005), peak-to-peak width (18 G) and other properties, except the difference in the dependence on temperature. Generation of H2O2 is indicated by the prolongation of the lag phase by the addition of catalase. On the other hand, the oxidation is modified by neither superoxide dismutase nor Nitroblue tetrazolium. The oxidation is prolonged in the presence of KCN. The present results indicate a free-radical mechanism for the oxidation in which the asymmetric radical catalyzes the formation of NO2 from NO2- by a peroxidase action and NO2 oxidizes oxyhemoglobin in the autocatalytic phase.     

Generation of nitro radical anions of some 5-nitrofurans, 2- and 5-nitroimidazoles by norepinephrine, dopamine, and serotonin. A possible mechanism for neurotoxicity caused by nitroheterocyclic drugs

Catecholamine neurotransmitters such as norepinephrine, dopamine, and related catecholamine derivatives reduce nitroheterocyclic drugs such as nitrofurantoin, nifurtimox, nifuroxime, nitrofurazone, misonidazole, and metronidazole in slightly alkaline solutions. Drugs which contain 5-nitrofurans are reduced at lower pH than drugs which contain 2- and 5-nitroimidazoles. 5-Nitroimidazole derivatives such as metronidazole and ronidazole are known to be more difficult to reduce than 2-nitroimidazole derivatives, due to their lower redox potential. Catecholamines, when reducing nitro drugs, undergo concomitant oxidation to form semiquinone radicals. Both semiquinone radicals and nitro anion radicals formed in a reaction of nitro drug and catecholamine derivative were detected by electron spin resonance spectroscopy. Oxygen consumption studies in solutions containing nitro drug and catecholamine derivative showed that nitro anion radicals formed under aerobic conditions reduce oxygen to form the superoxide radical and hydrogen peroxide. Quinones formed in the reaction of catecholamine and nitro drug were detected by optical spectroscopy. Biosynthetic precursors and some metabolic products of catecholamines were also used in these studies, and they all exhibited reactions similar to catecholamines. Bovine chromaffin granules which synthesize and store catecholamines produced the nitrofurantoin anion radical when intact granules were treated with nitrofurantoin. These radicals formed inside the granules were observed by ESR spectroscopy. The formation of nitrofurantoin radical, semiquinone radicals of catecholamines, and oxygen-derived radicals by chromaffin granules is proposed to cause damage to adrenal medulla, and this process may lead to neurotoxicity.     

Reaction of human hemoglobin with peroxynitrite. Isomerization to nitrate and secondary formation of protein radicals

Peroxynitrite, a strong oxidant formed intravascularly in vivo, can diffuse onto erythrocytes and be largely consumed via a fast reaction (2 x 10(4) m(-1) s(-1)) with oxyhemoglobin. The reaction mechanism of peroxynitrite with oxyhemoglobin that results in the formation of methemoglobin remains to be elucidated. In this work, we studied the reaction under biologically relevant conditions using millimolar oxyhemoglobin concentrations and a stoichiometric excess of oxyhemoglobin over peroxynitrite. The results support a reaction mechanism that involves the net one-electron oxidation of the ferrous heme, isomerization of peroxynitrite to nitrate, and production of superoxide radical and hydrogen peroxide. Homolytic cleavage of peroxynitrite within the heme iron allows the formation of ferrylhemoglobin in approximately 10% yields, which can decay to methemoglobin at the expense of reducing equivalents of the globin moiety. Indeed, spin-trapping studies using 2-methyl-2-nitroso propane and 5,5 dimethyl-1-pyrroline-N-oxide (DMPO) demonstrated the formation of tyrosyl- and cysteinyl-derived radicals. DMPO also inhibited covalently linked dimerization products and led to the formation of DMPO-hemoglobin adducts. Hemoglobin nitration was not observed unless an excess of peroxynitrite over oxyhemoglobin was used, in agreement with a marginal formation of nitrogen dioxide. The results obtained support a role of oxyhemoglobin as a relevant intravascular sink of peroxynitrite.     

Red cell lysis induced by microorganisms as a case of superoxide- and hydrogen peroxide-dependent hemolysis mediated by oxyhemoglobin

Some bacteria, isolated from the blood of hospitalized patients, have been shown to hemolyze red blood cells through a mechanism which was dependent on the oxygenated state of intracellular hemoglobin, since transformation of hemoglobin into the CO-derivative inhibited the lysis. Hemolysis was also inhibited by superoxide dismutase and catalase, while only catalase prevented the formation of methemoglobin in experiments where isolated oxyhemoglobin was exposed to metabolizing bacteria. Production by bacteria of extracellular superoxide was demonstrated. It is suggested that hemolysis is due to interaction of O₂⁻ and/or H₂O₂ with intracellular hemoglobin and that some product of such interaction is the lytic agent.     

In Vitro Protective Effect and Antioxidant Mechanism of Resveratrol Induced by Dapsone Hydroxylamine in Human Cells

Dapsone (DDS) hydroxylamine metabolites cause oxidative stress- linked adverse effects in patients, such as methemoglobin formation and DNA damage. This study evaluated the ameliorating effect of the antioxidant resveratrol (RSV) on DDS hydroxylamine (DDS-NHOH) mediated toxicity in vitro using human erythrocytes and lymphocytes. The antioxidant mechanism was also studied using in-silico methods. In addition, RSV provided intracellular protection by inhibiting DNA damage in human lymphocytes induced by DDS-NHOH. However, whilst pretreatment with RSV (10–1000 μM significantly attenuated DDS-NHOH-induced methemoglobinemia, but it was not only significantly less effective than methylene blue (MET), but also post-treatment with RSV did not reverse methemoglobin formation, contrarily to that observed with MET. DDS-NHOH inhibited catalase (CAT) activity and reactive oxygen species (ROS) generation, but did not alter superoxide dismutase (SOD) activity in erythrocytes. Pretreatment with RSV did not alter these antioxidant enzymes activities in erythrocytes treated with DDS-NHOH. Theoretical calculations using density functional theory methods showed that DDS-NHOH has a pro-oxidant effect, whereas RSV and MET have antioxidant effect on ROS. The effect on methemoglobinemia reversion for MET was significantly higher than that of RSV. These data suggest that the pretreatment with resveratrol may decrease heme-iron oxidation and DNA damage through reduction of ROS generated in cells during DDS therapy.