Neutrophil superoxide production measurement by means of stable nitroxide radical accumulation detected by ESR

A new assay for superoxide radicals is based on the interaction of hydroxylamine (1-oxy-2,2,6,6-tetramethyl-4-oxopiperidine) with superoxide, giving rise to a stable nitroxide radical. Working concentration ranges of hydroxylamine and cells are determined. It was shown that the amount of superoxide generated was proportional to the concentration of nitroxide radicals. The sensitivity and specificity of the proposed assay were compared to chemiluminescence and cytochrome-c reduction.     

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.     

Reactions of superoxide with the myoglobin tyrosyl radical

The contribution of superoxide-mediated injury to oxidative stress is not fully understood. A potential mechanism is the reaction of superoxide with tyrosyl radicals, which either results in repair of the tyrosine or formation of tyrosine hydroperoxide by addition. Whether these reactions occur with protein tyrosyl radicals is of interest because they could alter protein structure or modulate enzyme activity. Here, we have used a xanthine oxidase/acetaldehyde system to generate tyrosyl radicals on sperm whale myoglobin in the presence of superoxide. Using mass spectrometry we found that superoxide prevented myoglobin dimer formation by repairing the protein tyrosyl radical. An addition product of superoxide at Tyr151 was also identified, and exogenous lysine promoted the formation of this product. In our system, reaction of tyrosyl radicals with superoxide was favored over dimer formation with the ratio of repair to addition being approximately 10:1. Our results demonstrate that reaction of superoxide with protein tyrosyl radicals occurs and may play a role in free radical-mediated protein injury.     

Mechanism of oxidation of N-hydroxyphentermine by superoxide

Cytochrome P-450 oxidizes N-hydroxyphentermine (MPPNHOH) by an indirect pathway involving superoxide. The chemical details of this oxidation, in which N-hydroxyphentermine is converted to 2-methyl-2-nitro-1-phenylpropane (MPPNO2), have been elucidated by examining the interaction of MPPNHOH with superoxide in aqueous and organic solvents. The role of peroxide, hydroperoxy radicals, and oxygen in the reaction was also examined. The results indicate that superoxide itself is oxidizing MPPNHOH to a nitroxide that disproportionates to MPPNHOH and 2-methyl-2-nitroso-1-phenylpropane (MPPNO). MPPNO is then oxidized to MPPNO2 by O2 or hydroperoxide. Two possible mechanisms for the superoxide oxidation were considered, a proton abstraction and a hydrogen atom abstraction. Stoichiometric and oxygen evolution studies favor the hydrogen abstraction pathway.     

Singlet Oxygen-Trapping Reaction as a Method of 1O2 Detection: Role of Some Reducing Agents

The production of singlet oxygen by H₂O₂ disproportionation and via the oxidation of H₂O₂ by NaOCl in a neutral medium was monitored by spin trapping with 2,2,6,6 tetramethyl-4-piperidone (TMPone). The singlet oxygen formed in both reactions oxidized 2,2,6,6 tetramethyl-4-piperidone to give nitroxide radicals. However the production of nitroxide radicals was relatively small considering the concentrations of H₂O₂ and NaOCl used in the reaction systems. Addition of electron donating agents: ascorbate, Fe²⁺ and desferrioxamine leads to an increase in the production of nitroxide radicals. We assumed that a very slow step of the reaction sequence, the homolytic breaking of the O-O bond of N-hydroperoxide (formed as an intermediate product during the reaction of ¹O₂ with TMPone) could be responsible for the relatively small production of nitroxide radicals. Electron donating agents added to the reaction system probably raise the rate of the hydroperoxide decomposition by allowing a more rapid heterolytic cleavage of the O-O bond leading to a greater production of nitroxide radicals. The largest effect was observed in the presence of desferrioxamine. Its participation in this process is proved by the concomitant appearance of desferrioxamine nitroxide radicals. The results obtained demonstrate that the method proposed by several authors and tested in this study to detect singlet oxygen is not convenient for precise quantitative studies. The reactivity of TMPone towards O₂^-7HO₂' and 'OH has been also investigated. It has been found that both O₂^-7HO₂' and 'OH radicals formed in a phosphate buffer solution (pH 7.4, 37°C), respectively by a xanthine-oxidase/hypoxanthine system and via H₂O₂ UV irradiation, do not oxidize 2,2,6,6 tetramethyl-4-piperidone to nitroxide radicals.     

Inhibition of protein hydroperoxide formation by protein thiols

Studies on plasma and cells exposed to hydroxyl and peroxyl radicals have indicated that there are few inhibitors of protein hydroperoxide formation. We have, however, observed a small variable lag period during bovine serum albumin (BSA) oxidation by 2-2' azo-bis-(2-methyl-propionamidine) HCl (AAPH) generated peroxyl radicals, where no protein hydroperoxide was formed. The addition of free cysteine to BSA during AAPH oxidation also produced a lag phase suggesting protein thiols could inhibit protein hydroperoxide formation. The selective reduction of thiols on BSA by beta-mercaptoethanol treatment caused the appearance of a lag period where no protein hydroperoxide was formed during the AAPH mediated oxidation. Increasing free thiol concentration on the BSA increased the lag period. Protein hydroperoxide formation began when the protein thiol concentration dropped below one thiol per BSA molecule. It is unlikely that the lag period is due to gross structural alteration of the reduced protein since blocking the free thiols with N-ethyl maleimide eliminated the lag in protein hydroperoxide formation. Protein thiols were found to be ineffective in inhibiting hydroxyl radical-mediated protein hydroperoxide formation during X-ray radiolysis. Evidence is given for protein thiol oxidation occurring via a free radical mediated chain reaction with both free cysteine and protein bound thiol. The data suggest that reduced protein thiol groups can inhibit protein hydroperoxide formation by scavenging peroxyl radicals.     

Kinetics of superoxide-induced exchange among nitroxide antioxidants and their oxidized and reduced forms.

Nitroxide stable radicals generally serve for probing molecular motion in membranes and whole cells, transmembrane potential, intracellular oxygen and pH, and are tested as contrast agents for magnetic resonance imaging. Recently nitroxides were found to protect against oxidative stress. Unlike most low molecular weight antioxidants (LMWA) which are depleted while attenuating oxidative damage, nitroxides can be recycled. In many cases the antioxidative activity of nitroxides is associated with switching between their oxidized and reduced forms. In the present work, superoxide radicals were generated either radiolytically or enzymatically using hypoxanthine/xanthine oxidase. Electron paramagnetic resonance (EPR) spectrometry was used to follow the exchange between the nitroxide radical and its reduced form; whereas, pulse radiolysis was employed to study the kinetics of hydroxylamine oxidation. The results indicate that: a) The rate constant of superoxide reaction with cyclic hydroxylamines is pH-independent and is lower by several orders of magnitude than the rate constant of superoxide reaction with nitroxides; b) The oxidation of hydroxylamine by superoxide is primarily responsible for the non-enzymatic recycling of nitroxides; c) The rate of nitroxides restoration decreases as the pH decreases because nitroxides remove superoxide more efficiently than is hydroxylamine oxidation; d) The hydroxylamine reaction with oxidized nitroxide (comproportionation) might participate in the exchange among the three oxidation states of nitroxide. However, simulation of the time-dependence and pH-dependence of the exchange suggests that such a comproportionation is too slow to affect the rate of non-enzymatic nitroxide restoration. We conclude that the protective activity of nitroxides in vitro can be distinguished from that of common LMWA due to hydroxylamine oxidation by superoxide, which allows nitroxide recycling and enables its catalytic activity.     

Electron paramagnetic resonance probes of the radical decomposition of cumene hydroperoxide initiated by metmyoglobin

Electron paramagnetic resonance studies have provided evidence for metmyoglobin initiation of the radical decomposition of cumene hydroperoxide, carried out in buffered aqueous solutions at ambient temperatures. The radicals formed oxidize aminopyrine to a free radical, readily detected at acidic pH, or react with the spin trap nitrosobenzene. The only species so trapped was the cumyl radical (optimal pH, 9.0), previously observed in a similar spin-trapping study of the chemical decomposition of cumene hydroperoxide in organic solvents. The earlier proposal that the cumyl radical arises from breakdown of an initially formed, unstable phenylcumyloxy nitroxide is consistent with the experimental findings of this study. Moreover, it was shown that the decomposition of cumene hydroperoxide initiated by ferrous ion or by other heme compounds occurs by the same mechanism. Thus, the very low peroxidatic activities of several hemeproteins with cumene hydroperoxide involve oxidizing free radicals, unlike H₂O₂-dependent oxidations catalyzed by true hemeprotein peroxidases, in which enzyme species are the functional oxidants.     

Evaluation of a new copper(II)-curcumin complex as superoxide dismutase mimic and its free radical reactions

A mononuclear (1:1) copper complex of curcumin, a phytochemical from turmeric, was synthesized and examined for its superoxide dismutase (SOD) activity. The complex was characterized by elemental analysis, IR, NMR, UV-VIS, EPR, mass spectroscopic methods and TG-DTA, from which it was found that a copper atom is coordinated through the keto-enol group of curcumin along with one acetate group and one water molecule. Cyclic voltammetric studies of the complex showed a reversible Cu(2+)/Cu(+) couple with a potential of 0.402 V vs NHE. The Cu(II)-curcumin complex is soluble in lipids and DMSO, and insoluble in water. It scavenges superoxide radicals with a rate constant of 1.97 x 10(5) M(-1) s(-1) in DMSO determined by stopped-flow spectrometer. Subsequent to the reaction with superoxide radicals, the complex was found to be regenerated completely, indicating catalytic activity in neutralizing superoxide radicals. Complete regeneration of the complex was observed, even when the stoichiometry of superoxide radicals was 10 times more than that of the complex. This was further confirmed by EPR monitoring of superoxide radicals. The SOD mimicking activity of the complex was determined by xanthine/xanthine oxidase assay, from which it has been found that 5 microg of the complex is equivalent to 1 unit of SOD. The complex inhibits radiation-induced lipid peroxidation and shows radical-scavenging ability. It reacts with DPPH radicals with rate constant 10 times less than that of curcumin. Pulse radiolysis-induced one-electron oxidation of the complex by azide radicals in TX-100 micellar solutions produced strongly absorbing ( approximately 500 nm) phenoxyl radicals, indicating that the phenolic moiety of curcumin remained intact on complexation with copper. The results confirm that the new Cu(II)-curcumin complex possesses SOD activity, free radical neutralizing ability, and antioxidant potential. Quantum chemical calculations with density functional theory have been performed to support the experimental observations.     

Inhibition of protein hydroperoxide formation by protein thiols

Abstract

Studies on plasma and cells exposed to hydroxyl and peroxyl radicals have indicated that there are few inhibitors of protein hydroperoxide formation. We have, however, observed a small variable lag period during bovine serum albumin (BSA) oxidation by 2-2′ azo-bis-(2-methyl-propionamidine) HCl (AAPH) generated peroxyl radicals, where no protein hydroperoxide was formed. The addition of free cysteine to BSA during AAPH oxidation also produced a lag phase suggesting protein thiols could inhibit protein hydroperoxide formation. The selective reduction of thiols on BSA by β-mercaptoethanol treatment caused the appearance of a lag period where no protein hydroperoxide was formed during the AAPH mediated oxidation. Increasing free thiol concentration on the BSA increased the lag period. Protein hydroperoxide formation began when the protein thiol concentration dropped below one thiol per BSA molecule. It is unlikely that the lag period is due to gross structural alteration of the reduced protein since blocking the free thiols with N-ethyl maleimide eliminated the lag in protein hydroperoxide formation. Protein thiols were found to be ineffective in inhibiting hydroxyl radical-mediated protein hydroperoxide formation during X-ray radiolysis. Evidence is given for protein thiol oxidation occurring via a free radical mediated chain reaction with both free cysteine and protein bound thiol. The data suggest that reduced protein thiol groups can inhibit protein hydroperoxide formation by scavenging peroxyl radicals.     

Application of Spin Traps to Biological Systems

Since 1971. when nitroxides were first reported to be bioreduced, several cellular enzymes, in addition to ascorbic acid. have been found to catalyze the reduction of nitroxides to their corresponding hydroxylami-nes. Numerous studies have demonstrated that cellular bioreduction of nitroxides are both dependent upon the structure of the nitroxide and cell type. For example, pyrrolidinyloxyls are considerably more resistant to bioreduction than their corresponding piperidinyloxyls. In addition, cellular levels of reductases present in freshly isolated rat hepatocytes are considerably greater than concentrations found in freshly isolated rat enterocytes. Thus, through the proper selection of a cell type and an appropriate nitroxide. one can study cellular-mediated free radical processes.

With the discovery that α-hydrogen-containing nitroxides, including 2, Z-dimethyl-S-hydroxy-l-pyrrolidinyloxyl (DMPO-OH) decompose rapidly in the presence of superoxide and thiols, the ability to determine if hydroxyl radical is generated during stimulation of human neutrophils, is in doubt. To explore the limits of spin trapping in this context. we have studied the effect of varying the rates of superoxide production. in the presence and absence of thiols, on the decomposition of DMPO-OH. In parallel studies, we have found that t-butyl α-methyl-4-pyridinyl-N-oxide nitroxide (4-POBN-CH₃) will not degrade in the presence of superoxide and a thiol. From these studies. we have determined that if hydroxyl radicals were generated as an isolated event in the presence of a continual flow of superoxide. spin trapping might not be able to detect its formation. Otherwise. spin trapping should be able to measure hydroxyl radicals. if continually generated, during activation of human neutrophils.     

Radical-radical reactions of superoxide: a potential route to toxicity

Superoxide reacts with many radicals, such as phenoxyl radicals, at near diffusion-controlled rates. These reactions are usually considered to be repair processes and have received little biological attention. However, addition of superoxide to give hydroperoxides and secondary oxidation products can also occur. The relative contributions of addition and repair vary depending on the properties of the phenol. With tyrosine, addition to give tyrosine hydroperoxide predominates, but in peptides the efficiency of hydroperoxide formation depends on the proximity of free amine groups. Radicals from other phenolic compounds, such as alpha-tocopherol and serotonin, also undergo addition reactions with superoxide. Physiologically, these reactions are likely to be more significant than dimerization when both radicals are generated together. They warrant attention as potential contributors to superoxide toxicity.     

Superoxide Reaction with Nitroxides

Stable, free radical nitroxides are commonly used ESR spectroscopy tools. However, it has recently been found that ESR observable signal from 5-membered ring spin-adducts or stable label nitroxides is lost or diminished by reaction with superoxide. A similar radical-radical annihilation was not found for six membered ring nitroxide radicals. To discern why six-membered ring nitroxides are not reduced under superoxide flux generated by hypoxanthine/xanthine oxidase, spectrophoprmetric (Cyt C) and chemilu-minescence (lucigenin) and ESR assays were used to follow the reactions. Spectrophotometry and chemi-luminescence clearly demonstrated that the six-membered piperidine-I-oxyl compounds (TEMPO, TEMPOL, and TEMPAMIN) rapidly react with superoxide: rate constants at pH 7.8 ranging from 7 × 10⁴ to 1.2 × 10^-5M^-1s^-l. The absence of detectable ESR signal loss results from facile re-oxidation of the corresponding hydroxylamine by superoxide. To fully corroborate the efficiency of the 6-membered nitroxide superoxide dismutase activity, they were shown to protect fully mammalian cells from oxidative damage resulting from exposure to the superoxide and hydrogen peroxide generating system hypoxanthine/ xanthine oxidase. Since six-membered cyclic nitroxides react with superoxide about 2 orders of magnitude faster than the corresponding 5-membered ring nitroxides. they may ultimately be more useful as superoxide oxide dismutase mimetic agents.     

Using Nitroxide Decay to Study the Photooxidation Kinetics of Automotive Topcoat Enamels

Free radical scavenging by nitroxide dopant is used to quantify the photoinitiation rate of free radicals in acrylic/melamine and polyesterlurethane coatings during photolysis under “near ambient” exposure conditions. Photoinitiation rate measurements on weathered coatings reveal that acrylic/melamine coatings photooxidize non-autocatalytically, while polyester/urethane coatings photooxidize autocatalytically. The decomposition of hydroperoxide photolysis products by melamine crosslinker is claimed to account for this difference in photooxidation kinetics.     

Using Nitroxide Decay to Study the Photooxidation Kinetics of Automotive Topcoat Enamels

Free radical scavenging by nitroxide dopant is used to quantify the photoinitiation rate of free radicals in acrylic/melamine and polyesterlurethane coatings during photolysis under “near ambient” exposure conditions. Photoinitiation rate measurements on weathered coatings reveal that acrylic/melamine coatings photooxidize non-autocatalytically, while polyester/urethane coatings photooxidize autocatalytically. The decomposition of hydroperoxide photolysis products by melamine crosslinker is claimed to account for this difference in photooxidation kinetics.     

Endocytosis-independent uptake of liposome-encapsulated superoxide dismutase prevents the killing of cultured hepatocytes by tert-butyl hydroperoxide

Liposome-encapsulated (LSOD) or free (FSOD), human recombinant Cu-Zn superoxide dismutase prevented the killing of cultured rat hepatocytes by tert-butyl hydroperoxide (TBHP). A dose of 32 U/ml of LSOD reduced the cell killing by 50%. By contrast, it required 288 U/ml of FSOD to similarly reduce the toxicity of TBHP by 50%. Both LSOD and FSOD increased the cell-associated superoxide dismutase activity of the cultured hepatocytes. Whereas 64 U/ml of LSOD increased cell-associated superoxide dismutase activity fourfold, it required 500 U/ml of FSOD to achieve a similar increase. Furthermore, methylamine, benzyl alcohol, cytochalasin B, oligomycin, and monensin, all inhibitors of endocytosis, prevented the increase in cell-associated superoxide dismutase produced by 500 U/ml of FSOD. These same inhibitors had no effect on the increase in cell-associated superoxide dismutase activity produced by a much lower concentration of LSOD. Thus, liposome-encapsulated superoxide dismutase prevented the cell killing by TBHP more efficiently than free superoxide dismutase because it more efficiently entered the hepatocytes by a mechanism that was independent of the endocytosis responsible for the uptake of FSOD. These data further define the conditions of the toxicity of TBHP. The target hepatocyte must contribute superoxide anions, in addition to the previously shown ferric iron. It is hypothesized that superoxide anions reduce ferric to ferrous iron; the latter then reacts with the hydroperoxide to form tert-butyl alkoxyl radicals. Such radicals are potent oxidizing agents that can initiate the peroxidation of cellular lipids previously shown to lethally injure the hepatocytes.     

Nitroxide-Stimulated H2O2 Decomposition by Peroxidases and Pseudoperoxidases

Nitroxide free radicals interact with Hb/metHb, Mb/metMb and with peroxidases/phenols to induce a catalase-like conversion of H₂O₂ to O₂ (catalatic activity), without being substantially consumed in the process. The mechanism of this reaction is postulated to involve a one-electron oxidation of the nitroxide to the immonium oxene, which then reacts further to release oxygen and the nitroxide. An involvement of the immonium oxene in the reaction mechanism is consistent with ferryl heme reduction by nitroxides and a detection of the reduced nitroxide when the reaction mixture is supplemented with the two-electron reductant sodium borohydride. The nitroxide-induced catalatic activity is completely inhibited when the reaction mixture is supplemented with glutathione. Nitroxides suppress free radical formation by hydroperoxide-activated heme proteins, as inferred from their inhibition of the spin-trapping of glutathionyl radicals. H₂O₂ decomposition and a suppression of reactive free radical formation by heme proteins appears to be an antioxidant activity of nitroxides, which is distinct from their previously reported superoxide dismutating activity and which may be a factor in their protective action in models of cardiac reperfusion injury.     

Free radical scavenging actions of metallothionein isoforms I and II

By employing electron spin resonance spectroscopy, we examined the free radicals scavenging effects of hepatic metallothionein (MT) isoforms I and II (MTs-I and II) on four types of free radicals. Solutions of 0.15mM of MT-I and 0.3mM of MT-II were found to scavenge the 1,1-diphenyl-2-picrylhydrazyl radicals (1.30 × 10¹⁵ spins/ml) completely. In addition, both isoforms exhibited total scavenging action against the hydroxyl radicals (1.75 × 10¹⁵ spins/ml) generated in a Fenton reaction. Similarly, 0.3mM of MT-I scavenged almost 90% of the superoxide (2.22 × 10¹⁵ spins/ml) generated by the hypoxanthine and xanthine oxidase system, while a 0.3mM MT-II solution could only scavenge 40% of it. By using 2,2,6,6-tetramethyl-4-piperidone as a “spin-trap” for the reactive oxygen species (containing singlet oxygen, superoxide and hydroxyl radicals) generated by photosensitized oxidation of riboflavin and measuring the relative signal intensities of the resulting stable nitroxide adduct, 2,2,6,6-tetramethyl-4-piperidine-1-oxyl, we observed that MT-II (0.3 mM) could scavenge 92%, while MT-I at 0.15 mM μl/ml concentrations could completely scavenge all the reactive species (2.15 × 10¹⁵ spins/ml) generated.

The results of these studies suggest that although both isoforms of MT are able to scavenge free radicals, the MT-I appears to be a superior scavenger of superoxide and 1,1 diphenyl-2-picrylhydrazyl radicals.     

A new approach for extracellular spin trapping of nitroglycerin-induced superoxide radicals both in vitro and in vivo

Anti-ischemic therapy with nitrates is complicated by the induction of tolerance that potentially results from an unwanted coproduction of superoxide radicals. Therefore, we analyzed the localization of in vitro and in vivo, glyceryl trinitrate (GTN)-induced formation of superoxide radicals and the effect of the antioxidant vitamin C and of superoxide dismutase (SOD). Sterically hindered hydroxylamines 1-hydroxy-3-carboxy-2,2,5,5-tetramethylpyrrolidine (CP-H) and 1-hydroxy-4-phosphonooxy-2,2,6,6-tetramethylpiperidin (PP-H) can be used for in vitro and in vivo quantification of superoxide radical formation. The penetration/incorporation of CP-H or PP-H and of their corresponding nitroxyl radicals was examined by fractionation of the blood and blood cells during a 1-h incubation. For monitoring in vivo, GTN-induced (130 microg/kg) O2*- formation CP-H or PP-H were continuously infused (actual concentration, 800 microM) for 90 to 120 min into rabbits. Formation of superoxide was determined by SOD- or vitamin C-inhibited contents of nitroxide radicals in the blood from A. carotis. The incubation of whole blood with CP-H, PP-H, or corresponding nitroxyl radicals clearly shows that during a 1-h incubation, as much as 8.3% of CP-H but only 0.9% of PP-H is incorporated in cytoplasm. Acute GTN treatment of whole blood and in vivo bolus infusion significantly increased superoxide radical formation as much as 4-fold. Pretreatment with 20 mg/kg vitamin C or 15,000 U/kg superoxide dismutase prevented GTN-induced nitroxide formation. The decrease of trapped radicals after treatment with extracellularly added superoxide dismutase or vitamin C leads to the conclusion that GTN increases the amount of extracellular superoxide radicals both in vitro and in vivo.     

Susceptibility of glutathione peroxidase to proteolysis after oxidative alteration by peroxides and hydroxyl radicals.

Glutathione peroxidase is a key enzyme in the antioxidant system of the cells. This enzyme has been shown to be irreversibly inactivated by H2O2, tert-butyl hydroperoxide (tert-BHP) and hydroxyl radicals when incubated without GSH. We observed that in our experimental conditions glutathione peroxidase was not degraded by trypsin or chymotrypsin while degraded by pronase, papa?n, pepsin, and lysosomal proteases. Hydroxyl radicals and superoxide anions but not H2O2 or tert-BHP could also fragment the enzyme on their own. A former incubation with H2O2, tert-BHP, or hydroxyl radicals also increased the proteolytic susceptibility of glutathione peroxidase. Like superoxide dismutase (SOD) and other oxidatively denatured proteins, glutathione peroxidase inactivated by peroxides or free radicals seems to be degraded preferentially by proteases. As hydroxyl radicals can fragment the enzyme by themselves, the increased proteolytic susceptibility afterwards is easily understood while the increased susceptibility induced by H2O2 and tert-BHP seems to be more specific.