The autoxidation of glyceraldehyde and other simple monosaccharides under physiological conditions catalysed by buffer ions

Glyceraldehyde and other simple monosaccharides autoxidise under physiological conditions generating 1-hydroxyalkyl (carbon-centred) free radicals and intermediates of dioxygen reduction: superoxide, hydrogen peroxide and hydroxyl radicals. The major glyceraldehyde-derived product is the alpha-ketoaldehyde, hydroxypyruvaldehyde. Close similarities between the temperature dependence of the kinetics of glyceraldehyde autoxidation and glyceraldehyde enolisation to an ene-diol indicates that enolisation is the rate-determining step in the autoxidative process. Inspection of a wide range of carbonyl compounds showed that the monosaccharide moiety -CH(OH)-C- is conserved in carbonyl compounds reactive towards autoxidation, indicating that the ability to form an ene-diol is a prerequisite to monosaccharide autoxidation. The ene-diol intermediate autoxidises rapidly to the products: hydrogen peroxide, water and alpha-ketoaldehydes: beta-hydroxypyruvaldehyde is produced from glyceraldehyde and dihydroxyacetone, glyoxal from glycolaldehyde autoxidation. Ene-diol autoxidation is catalysed by hydrogen peroxide and trace metal ion contaminants; removal of either of these factors sufficiently retards ene-diol autoxidation such that ene-diol autoxidation rather than enolisation becomes the rate determining step in the overall autoxidative process. Under enolisation control, the rate of monosaccharide autoxidation is influenced by pH and the buffer system used for pH control.     

The oxidation of oxyhaemoglobin by glyceraldehyde and other simple monosaccharides.

Glyceraldehyde and other simple monosaccharides oxidize oxyhaemoglobin to methaemoglobin in phosphate buffer at pH 7.4 and 37 degrees C, with the concomitant production of H2O2 and an alpha-oxo aldehyde derivative of the monosaccharide. Simple monosaccharides also reduce methaemoglobin to ferrohaemichromes (non-intact haemoglobin) at pH 7.4 and 37 degrees C. Carbonmonoxyhaemoglobin is unreactive towards oxidation by autoxidizing glyceraldehyde. Free-radical production from autoxidizing monosaccharides with haemoglobins was observed by the e.s.r. technique of spin trapping with the spin trap 5,5-dimethyl-l-pyrroline N-oxide. Hydroxyl and l-hydroxyalkyl radical production observed from monosaccharide autoxidation was quenched in the presence of oxyhaemoglobin and methaemoglobin. The haemoglobins appear to quench the free radicals by reaction with the free radicals and/or the ene-diol precursor of the free radical.     

Glutathionyl- and hydroxyl radical formation coupled to the redox transitions of 1,4-naphthoquinone bioreductive alkylating agents during glutathione two-electron reductive addition.

The kinetic parameters of the redox transitions subsequent to the two-electron transfer implied in the glutathione (GSH) reductive addition to 2- and 6-hydroxymethyl-1,4-naphthoquinone bioalkylating agents were examined in terms of autoxidation, GSH consumption in the arylation reaction, oxidation of the thiol to glutathione disulfide (GSSG), and free radical formation detected by the spin-trapping electron spin resonance method. The position of the hydroxymethyl substituent in either the benzenoid or the quinonoid ring differentially influenced the initial rates of hydroquinone autoxidation as well as thiol oxidation. Thus, GSSG- and hydrogen peroxide formation during the GSH reductive addition to 6-hydroxymethyl-1,4-naphthoquinone proceeded at rates substantially higher than those observed with the 2-hydroxymethyl derivative. The distribution and concentration of molecular end products, however, was the same for both quinones, regardless of the position of the hydroxymethyl substituent. The [O2]consumed/[GSSG]formed ratio was above unity in both cases, thus indicating the occurrence of autoxidation reactions other than those involved during GSSG formation. EPR studies using the spin probe 5,5'-dimethyl-1-pyrroline-N-oxide (DMPO) suggested that the oxidation of GSH coupled to the above redox transitions involved the formation of radicals of differing structure, such as hydroxyl and thiyl radicals. These were identified as the corresponding DMPO adducts. The detection of either DMPO adduct depended on the concentration of GSH in the reaction mixture: the hydroxyl radical adduct of DMPO prevailed at low GSH concentrations, whereas the thiyl radical adduct of DMPO prevailed at high GSH concentrations. The production of the former adduct was sensitive to catalase, whereas that of the latter was sensitive to superoxide dismutase as well as to catalase. The relevance of free radical formation coupled to thiol oxidation is discussed in terms of the thermodynamic and kinetic properties of the reactions involved as well as in terms of potential implications in quinone cytotoxicity.     

DMPO-Alkyl radical spin trapping: an in situ radiolysis steady-state ESR study

Short-lived free radicals formed in the reaction of 11 substrates and radiolytically produced hydroxyl radicals were trapped successfully with 5, 5-dimethyl-1-pyrroline-N-oxide (DMPO) in dilute aqueous solution. The in situ radiolysis steady-state ESR spectra of the spin adducts were analyzed to determine accurate ESR parameters for these spin adducts in a uniform environment. Parent alkyl radicals include methyl, ethyl, 1-propyl and 2-propyl (1-methylethyl). Hydroxyalkyl parent radicals were hydroxymethyl, hydroxyethyl, 2-hydroxy-2-propyl (1-methyl-1-hydroxyethyl), 1-hydroxypropyl and 2-hydroxy-2-methylpropyl. Carboxyl radical (carbon dioxide anion, formate radical) and sulfite anion radical were the sigma radicals studied. The DMPO spin adduct of 1-propyl was identified for the first time. For most spin adducts, g factors were also determined for the first time. In DMPO spin adducts of hydroxyalkyl radicals, nitrogen and C(2)-proton hyperfine coupling constants are smaller than those of alkyl radical adducts; the hydroxyalkyl spin adducts possess larger g values than their unsubstituted counterparts. These changes are ascribed to the spread of pi conjugation to include the hydroxyl group. Strong evidence of spin addend-aminoxyl group interaction can be seen in the asymmetrical line shapes in the hydroxyethyl and the hydroxypropyl spin adducts.     

The production of oxygen-centered radicals by Bacillus-Calmette-Guerin-activated macrophages: An electron paramagnetic resonance study of the response to phorbol myristate acetate

The spin trapping with 5,5-dimethyl-1-pyrroline-N-oxide of free radicals formed from Bacillus-Calmette-Guerin elicited peritoneal macrophages stimulated with phorbol myristate acetate resulted in the formation of a superoxide and hydroxyl spin adducts. The formation of both spin adducts was inhibited by copper/zinc superoxide dismutase. Only 70% of the hydroxyl spin adduct could be inhibited by catalase or the scavenger dimethyl sulfoxide. This suggests that the production of hydroxyl radicals involves prior formation of both superoxide radicals and hydrogen peroxide, implicating a Fenton catalysed Haber-Weiss reaction. The metal scavenger desferrioxamine also reduced the hydroxyl radical signal by 70%. The unaccounted 30% hydroxyl radical-like signals are probably due to carbon-centered free radicals formed by the lipoxygenase reaction. Spin trapping in the presence of the lipid-soluble spin trap, 5-octadecyl-5,3,3-trimethyl-1-pyrroline-N-oxide, resulted in a spectrum consistent with the presence of an oxaziridine nitroxide. This results from the free radical-induced cyclisation of a nitrone with an unsaturated fatty acid.     

Metal ion-induced activation of molecular oxygen in pigmented polymers

Diamagnetic and paramagnetic metal ions enhanced the rate of production of hydrogen peroxide during autoxidation of melanin pigments, as measured using an oxidase electrode. However, redox-active metal ions, such as Fe3+ and Cu2+, caused a marked decrease in H2O2 production. Evidence for redox-active metal ion-dependent formation of hydroxyl radicals during autoxidation of melanin pigments has been obtained using the electron spin resonance-spin trapping method. Evidence for direct reduction of Fe3+ by melanin polymers also has been obtained using optical spectroscopy. Mechanisms of molecular activation of oxygen induced by metal ions on melanin polymers are discussed.     

Effects of Oxygen Radical Scavengers on the Inactivation of SS ΦX174 DNA by the Semi-Quinone Free Radical of the Antitumor Agent Etoposide

We have studied the effects of oxygen radical scavengers on the inactivation of ss ΦX174 DNA by the semi-quinone free radical of the antitumor agent etoposide (VP 16-213), which was generated from the ortho-quinone of etoposide at pH ≥ 7.4. A semi-quinone free radical of etoposide is thought to play a role in the inactivation of ss ΦDX174 DNA by its precursors 3',4'-ortho-quinone and 3',4'-ortho-dihydroxy-derivative. The possible role of oxygen radicals formed secondary to semi-quinone formation in the inactivation of DNA by the semi-quinone free radical was investigated using the hydroxyl radical scavengers t-butanol and DMSO. the spin trap DMPO, the enzymes catalase and superoxide dismutase, the iron chelator EDTA and potassium superoxide. Hydroxyl radicals seem not important in the process of inactivation of DNA by the semi-quinone free radical, since t-butanol, DMSO, catalase and EDTA had no inhibitory effect on DNA inactivation. The spin trapping agent DMPO strongly inhibited DNA inactivation and semi-quinone formation from the ortho-quinone of etoposide at pH ≥ 7.4 with the concomitant formation of a DMPO-OH adduct. This adduct probably did not arise from OH· trapping but from trapping of O₂^-. DMSO increased both the semi-quinone formation from and the DNA inactivation by the ortho-quinone of etoposide at pH ≥ 7.4. Potassium superoxide also stimulated ΦDX174 DNA inactivation by the ortho-quinone at pH ≤ 7. From the present study, it is also concluded that superoxide anion radicals probably play an important role in the formation of the semi-quinone free radical from the orthoquinone of etoposide, thus indirectly influencing DNA inactivation.     

Diaziquone as a potential agent for photoirradiation therapy: formation of the semiquinone and hydroxyl radicals by visible light

When diaziquone was irradiated with 500 nm visible light, hydroxyl free radicals as well as the diaziquone semiquinone were produced. The diaziquone semiquinone is a stable free radical that exhibits a characteristic 5-line electron spin resonance (ESR) spectrum. Since hydroxyl free radicals are short lived, and not observable by conventional ESR, the nitrone spin trap 5,5-dimethyl-1-pyrroline-1-oxide (DMPO) was used to convert hydroxyl radicals into longer lived ESR detectable spin adducts. The formation of hydroxyl radicals was further confirmed by investigating reactions in which hydroxyl radical scavangers, sodium formate and dimethylsulfoxide, compete with the spin traps DMPO or POBN (alpha-(4-Pyridyl-1-oxide)-N- tert-butylnitrone) for hydroxyl free radicals. The products of these scavenging reactions were also trapped with DMPO or POBN. If drug free radicals and hydroxyl free radicals are important in the activity of quinone-containing antitumor agents, AZQ may have a potential in photoirradiation therapy or photodynamic therapy.     

Free Radical Metabolism of Alcohols by Rat Liver Microsomes

By using e.s.r. spectroscopy coupled with the spin trapping technique we have detected the formation of free radical intermediates by rat liver microsomes incubated with either ethanol, 2-propanol or 2-butanol in the presence of a NADPH regenerating system and 4-pyridyl-l-oxide-t-butyl nitrone (4-POBN) as spin trap. The e.s.r. spectra have been identified as due to the hydroxyalkyl free radical adducts of 4-POBN.

The free radical formation depends upon the activity of the microsomal monoxygenase system and is blocked by omitting NADP⁺ from the incubation mixture, by anaerobic incubation or by enzyme denaturation. The involvement of hydroxyl radicals (OH) produced through a Fenton-type reaction from endogenously formed hydrogen peroxide is suggested by the opposite effects exerted on the e.s.r. signal intensity by azide and catalase. Consistently, iron chelation by desferrioxamine inhibits the free radical formation, while the supplementation of EDTA-iron increases it by several fold. Inhibitors of cytochrome P₄₅₀-dependent monoxygenase system reduce to various extents the production of free radical intermediates suggesting that reactive oxygen species might be formed at the active site of cytochrome P₄₅₀ where they react with alkyl alcohol molecules.

The data presented support the hypothesis that free radical species are generated during the microsomal metabolism of alcohols and suggest the possibility that ethanol-derived radicals might play a role in the pathogenesis of the liver lesions consequent upon alcoholic abuse.     

EPR kinetic studies of superoxide radicals generated during the autoxidation of 1-methyl-4-phenyl-2,3-dihydropyridinium, a bioactivated intermediate of parkinsonian-inducing neurotoxin 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine.

1-Methyl-4-phenyl-2,3-dihydropyridinium (MPDP+), a metabolic product of the nigrostriatal toxin 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP), has been shown to generate superoxide radicals during its autoxidation process. The generation of superoxide radicals was detected as a 5,5-dimethyl-1-pyrroline-N-oxide (DMPO).O2- spin adduct by spin trapping in combination with EPR techniques. The rate of formation of spin adduct was dependent not only on the concentrations of MPDP+ and oxygen but also on the pH of the system. Superoxide dismutase inhibited the spin adduct formation in a dose-dependent manner. The ability of DMPO to trap superoxide radicals, generated during the autoxidation of MPDP+, and of superoxide dismutase to effectively compete with this reaction for the available O2-, has been used as a convenient competition reaction to quantitatively determine various kinetic parameters. Thus, using this technique the rate constant for scavenging of superoxide radical by superoxide dismutase was found to be 7.56 x 10(9) M-1 s-1. The maximum rate of superoxide generation at a fixed spin trap concentration using different amounts of MPDP+ was found to be 4.48 x 10(-10) M s-1. The rate constant (K1) for MPDP+ making superoxide radical was found to be 3.97 x 10(-6) s-1. The secondary order rate constant (KDMPO) for DMPO-trapping superoxide radicals was found to be 10.2 M-1 s-1. The lifetime of superoxide radical at pH 10.0 was calculated to be 1.25 s. These values are in close agreement to the published values obtained using different experimental techniques. These results indicate that superoxide radicals are produced during spontaneous oxidation of MPDP+ and that EPR spin trapping can be used to determine the rate constants and lifetime of free radicals generated in aqueous solutions. It appears likely that the nigrostriatal toxicity of MPTP/MPDP+ leading to Parkinson's disease may largely be due to the reactivity of these radicals.     

OH radical formation by photolysis of aqueous porphyrin solutions. A spin trapping and e.s.r. study

Radical production during the photolysis of deaerated aqueous alkaline solutions (pH 11) of some water-soluble porphyrins was investigated. Metal-free and metallo complexes of tetrakis (4-N-methylpyridyl)porphyrin (TMPyP) and tetra (4-sulphonatophenyl)porphyrin (TPPS4) were studied. Evidence for the formation of OH radicals during photolysis at 615, 545, 435, 408 and 335 nm of Fe(III) TPPS4 is presented. Fe(III) TMPyP, Mn(III) TPPS4 and Mn(III) TMPyP also gave OH radicals but only during photolysis at 335 nm. The method of spin trapping with 5,5-dimethyl-1-pyrroline-1-oxide (DMPO) and 4-pyridyl-1-oxide-N-tert-butylnitrone (POBN) combined with e.s.r. was used for the detection of OH, H and hydrated electrons. With the spin trap DMPO, photolysis generated DMPO-OH adducts under certain conditions but no DMPO-H adducts could be observed. With POBN, no POBN-H adducts were found. The formation of OH was confirmed by studying competition reactions for OH between the spin traps and OH scavengers (formate, isopropanol) and the concomitant formation of the CO-2 adduct and the (CH3)2COH adduct with both DMPO and POBN. The photochemical generation of OH radicals was pH dependent; at pH 7.5 no OH radicals could be detected. Photolysis (615-335 nm) of dicyanocomplexes of the Fe(III) porphyrins did not produce OH radicals. When corresponding Cu(II), Ni(II), Zn(II) and metal-free porphyrins were photolysed at 615 and 335 nm, no OH radicals could be spin trapped. These results tend to associate the well-known phenomenon of photoreduction of Fe(III) and Mn(III) porphyrins with the formation of OH radicals. This process is described mainly as the photoreduction of the metal ion by the ligand-bound hydroxyl ion via an intramolecular process.     

Homogentisic acid autoxidation and oxygen radical generation: implications for the etiology of alkaptonuric arthritis

The metabolic disorder, alkaptonuria, is distinguished by elevated serum levels of 2,5-dihydroxyphenylacetic acid (homogentisic acid), pigmentation of cartilage and connective tissue and, ultimately, the development of inflammatory arthritis. Oxygen radical generation during homogentisic acid autoxidation was characterized in vitro to assess the likelihood that oxygen radicals act as molecular agents of alkaptonuric arthritis in vivo. For homogentisic acid autoxidized at physiological pH and above, yielding superoxide (O2-)2 and hydrogen peroxide (H2O2), the homogentisic acid autoxidation rate was oxygen dependent, proportional to homogentisic acid concentration, temperature dependent and pH dependent. Formation of the oxidized product, benzoquinoneacetic acid was inhibited by the reducing agents, NADH, reduced glutathione, and ascorbic acid and accelerated by SOD and manganese-pyrophosphate. Manganese stimulated autoxidation was suppressed by diethylenetriaminepentaacetic acid (DTPA). Homogentisic acid autoxidation stimulated a rapid cooxidation of ascorbic acid at pH 7.45. Hydrogen peroxide was among the products of cooxidation. The combination of homogentisic acid and Fe3+-EDTA stimulated hydroxyl radical (OH.) formation estimated by salicylate hydroxylation. Ferric iron was required for the reaction and Fe3+-EDTA was a better catalyst than either free Fe3+ or Fe3+-DTPA. SOD accelerated OH. production by homogentisic acid as did H2O2, and catalase reversed much of the stimulation by SOD. Catalase alone, and the hydroxyl radical scavengers, thiourea and sodium formate, suppressed salicylate hydroxylation. Homogentisic acid and Fe3+-EDTA also stimulated the degradation of hyaluronic acid, the chief viscous element of synovial fluid. Hyaluronic acid depolymerization was time dependent and proportional to the homogentisic acid concentration up to 100 microM. The level of degradation observed was comparable to that obtained with ascorbic acid at equivalent concentrations. The hydroxyl radical was an active intermediate in depolymerization. Thus, catalase and the hydroxyl radical scavengers, thiourea and dimethyl sulfoxide, almost completely suppressed the depolymerization reaction. The ability of homogentisic acid to generate O2-, H2O2 and OH. through autoxidation and the degradation of hyaluronic acid by homogentisic acid-mediated by OH. production suggests that oxygen radicals play a significant role in the etiology of alkaptonuric arthritis.     

The production of hydroxyl radicals by adriamycin in red blood cells

Spin trapping of the free radicals formed from the interaction between adriamycin and red blood cells resulted in the formation of a hydroxyl spin adduct. The formation of hydroxyl radicals was found to be inhibited by mannitol. Hemoglobin was found not to be obligatory for the formation of hydroxyl radicals which probably result from the reduction of hydrogen peroxide by adriamycin semiquinone.     

Mechanism of copper-catalyzed autoxidation of cysteine

The kinetics of copper-catalyzed autoxidation of cysteine and its derivatives were investigated using oxygen consumption, spectroscopy and hydroxyl radical detection by fluorescence of a coumarin probe. The process has complex two-phase kinetics. During the first phase a stoichiometric amount of oxygen (0.25 moles per mole of thiol) is consumed without production of hydroxyl radicals. In the second reaction phase excess oxygen is consumed in a hydrogen peroxide-mediated process with significant ^·OH production. The reaction rate in the second phase is decreased for cysteine derivatives with a free aminogroup and increased for compounds with a modified aminogroup. The kinetic data suggest the catalytic action of copper in the form of a cysteine complex. The reaction mechanism consists of two simultaneous reactions (superoxide-dependent and peroxide-dependent) in the first phase, and peroxide-dependent in the second phase. The second reaction phase begins after oxidation of free thiol. This consists of a Fenton-type reaction between cuprous-cysteinyl complex and following oxidation of cysteinyl radical to sulfonate with the consumption of excessive oxygen and significant production of hydroxyl radicals.     

Characterization of free radicals produced during oxidation of etoposide (VP-16) and its catechol and quinone derivatives. An ESR Study

Spectroscopic evidence for the radical-mediated metabolism of VP-16, VP-16 catechol, and VP-16 quinone during enzymatic oxidation and autoxidation has been obtained. Autoxidation of the catechol yields the primary semiquinone together with the primary molecular product VP-16 quinone, which subsequently undergoes hydrolytic oxidation to form secondary quinones and semiquinones. Both primary and secondary phenoxyl radicals were detected during peroxidatic oxidation of VP-16. Neither the primary nor the secondary radicals react with DNA at a detectable rate. Evidence for the production of hydroxyl radical during iron-catalyzed oxidation of VP-16 catechol was obtained. These free radical reactions may have implications for the mechanism of antitumor action of VP-16.     

Hydralazine stimulates production of oxygen free radicals in Eagle's medium and cultured fibroblasts.

The effect of hydralazine on the oxygen free radical production was studied in whole cultured murine liver fibroblasts and mitochondrial and microsomal fractions of the cells by ESR spin trapping with DMPO and measurement of Tiron semiquinone formation. Hydralazine itself was found to generate free radicals in phosphate buffer and especially in Eagle's Minimal Essential Medium. Most of the adduct of the spin trap DMPO was due to its reaction with hydralazine-induced hydroxyl radical. Moreover, this compound stimulated free radical formation in fibroblasts. These data suggest that hydralazine alters the cellular free radical metabolism which may have implications for the biological activity of this drug.     

An electron spin resonance study of o-semiquinones formed during the enzymatic and autoxidation of catechol estrogens

Electron spin resonance spectroscopy has been used to demonstrate production of semiquinone-free radicals from the oxidation of the catechol estrogens 2- and 4-hydroxyestradiol and 2,6- and 4,6-dihydroxyestradiol. Radicals were generated either enzymatically (using horseradish peroxidase-H2O2 or tyrosinase-O2) or by autoxidation, and were detected as their complexes with spin-stabilizing metal ions (Zn2+ and/or Mg2+). In the peroxidase system, radicals are produced by one-electron oxidation of the catechol estrogen and their decay is by a second-order pathway, consistent with their disproportionation to quinone and catechol products. With tyrosinase-O2, radical generation occurs indirectly. Initial hydroxylation of phenolic estrogen (at either the 2- or 4-position) gives a catechol estrogen in situ; subsequent two-electron oxidation of the catechol to the quinone, followed by reverse disproportionation, leads to the formation of radicals. A competing mechanism for radical production involves autoxidation of the catechol. Results obtained from the estrogen systems have been compared with those from the model compound 5,6,7,8-tetrahydro-2-naphthol.     

In vivo evidence of free radical generation in the mouse lung after exposure to Pseudomonas aeruginosa bacterium: an ESR spin-trapping investigation

In the Pseudomonas aeruginosa-induced rodent pneumonia model, it is thought that free radicals are significantly associated with the disease pathogenesis. However, until now there has been no direct evidence of free radical generation in vivo. Here we used electron spin resonance (ESR) and in vivo spin trapping with α-(4-pyridyl-1-oxide)-N-tert-butylnitrone to investigate free radical production in a murine model. We detected and identified generation of lipid-derived free radicals in vivo (a(N) =14.86 ± 0.03 G and a(H)(β) =2.48 ± 0.09 G). To further investigate the mechanism of lipid radical production, we used modulating agents and knockout mice. We found that with GdCl(3) (phagocytic toxicant), NADPH-oxidase knockout mice (Nox2(-)/(-)), allopurinol (xanthine-oxidase inhibitor) and Desferal (metal chelator), generation of lipid radicals was decreased; histopathological and biological markers of acute lung injury were noticeably improved. Our study demonstrates that lipid-derived free radical formation is mediated by NADPH-oxidase and xanthine-oxidase activation and that metal-catalysed hydroxyl radical-like species play important roles in lung injury caused by Pseudomonas aeruginosa.     

Peroxyl, alkoxyl, and carbon-centered radical formation from organic hydroperoxides by chloroperoxidase

The decomposition of organic hydroperoxides as catalyzed by chloroperoxidase was investigated with electron spin resonance (ESR) spectroscopy. Tertiary peroxyl radicals were directly detected by ESR from incubations of tert-butyl hydroperoxide or cumene hydroperoxide with chloroperoxidase at pH 6.4. Peroxyl, alkoxyl, and carbon-centered free radicals from tertiary hydroperoxide/chloroperoxidase systems were successfully trapped by the spin trap 5,5-dimethyl-1-pyrroline N-oxide, whereas alkoxyl radicals were not detected in the ethyl hydroperoxide/chloroperoxidase system. The carbon-centered free radicals were further characterized by spin-trapping studies with tert-nitrosobutane. Oxygen evolution measured by a Clark oxygen electrode was detected for all the hydroperoxide/chloroperoxidase systems. The classical peroxidase mechanism is proposed to describe the formation of peroxyl radicals. In the case of tertiary peroxyl radicals, their subsequent self-reactions result in the formation of alkoxyl free radicals and molecular oxygen. beta-Scission and internal hydrogen atom transfer reactions of the alkoxyl free radicals lead to the formation of various carbon-centered free radicals. In the case of the primary ethyl peroxyl radicals, decay through the Russell pathway forms molecular oxygen.     

The transition metal-mediated formation of the hydroxyl free radical during the reduction of molecular oxygen by ferredoxin-ferredoxin:NADP+ oxidoreductase

The NADPH-supported enzymatic reduction of molecular oxygen by ferredoxin-ferredoxin:NADP+ oxidoreductase was investigated. The ESR spin trapping technique was employed to identify the free radical metabolites of oxygen. The spin trap 5,5-dimethyl-1-pyrroline N-oxide (DMPO) was used to trap and identify the oxygen-derived free radicals. [17O]Oxygen was employed to demonstrate that the oxygen-centered radicals arose from molecular oxygen. From the data, the following scheme is proposed: (Formula:see text). The formation of the free hydroxyl radical during the reduction of oxygen was demonstrated with quantitative competition experiments. The hydroxyl radical abstracted hydrogen from ethanol or formate, and the resulting scavenger-derived free radical was trapped with known rate constants. If H2O2 was added to the enzymatic reaction, a stimulation of the production of the hydroxyl radical was obtained. This stimulation was manifested in both the concentration and the rate of formation of the DMPO/hydroxyl radical adduct. Catalase was shown to inhibit formation of the hydroxyl radical adduct, further supporting the formation of hydrogen peroxide as an intermediate during the reduction of oxygen. All three components, ferredoxin, ferredoxin:NADP+ oxidoreductase, and NADPH, were required for reduction. Ferredoxin:NADP+ oxidoreductase reduces ferredoxin, which in turn is responsible for the reduction of oxygen to hydrogen peroxide and ultimately the hydroxyl radical. The effect of transition metal chelators on the DMPO/hydroxyl radical adduct concentration suggests that the reduction of chelated iron by ferredoxin is responsible for the reduction of hydrogen peroxide to the hydroxyl radical via Fenton-type chemistry.