Quantitative 31P NMR detection of oxygen-centered and carbon-centered radical species

Quantitative 31P NMR spin trapping techniques can be used as effective tools for the detection and quantification of many free radical species. Free radicals react with a nitroxide phosphorus compound, 5-diisopropoxy-phosphoryl-5-methyl-1-pyrroline-N-oxide (DIPPMPO), to form stable radical adducts, which are suitably detected and accurately quantified using (31)P NMR in the presence of phosphorus containing internal standards. Initially, the 31P NMR signals for the radical adducts of oxygen-centered (*OH, O2*-) and carbon-centered (*CH3, *CH2OH, CH2*CH2OH) radicals were assigned. Subsequently, the quantitative reliability of the developed technique was demonstrated under a variety of experimental conditions. The 31P NMR chemical shifts for the hydroxyl and superoxide reaction adducts with DIPPMPO were found to be 25.3, 16.9, and 17.1 ppm (in phosphate buffer), respectively. The 31P NMR chemical shifts for *CH3, *CH2OH, *CH(OH)CH3, and *C(O)CH3 spin adducts were 23.1, 22.6, 27.3, and 30.2 ppm, respectively. Overall, this effort forms the foundations for a targeted understanding of the nature, identity, and mechanisms of radical activity in a variety of biomolecular processes.     

The inhibition of bovine heart hexokinase by 2-deoxy-D-glucose-6-phosphate: characterization by 31P NMR and metabolic implications.

The glucose analog, 2-deoxy-D-glucose (2DG), has been used widely for studying the initial steps in the metabolism of glucose by radio-isotope tracer methods and by 31P NMR. In the rat heart perfused with acetate/2DG (both 5 mM) plus insulin, trapping of phosphorus by 2-deoxy-D-glucose-6-phosphate (2DG6P) results in a steady state exhibiting high 2DG6P (55 mM) and low ATP concentrations but near-normal function, as observed in an earlier 31P NMR study. In order to understand how the 2DG6P concentration is stabilized, we studied the inhibition of a mammalian hexokinase by 2DG6P in vitro by a 31P NMR technique. Inhibition, previously unobserved, was found. It is similar to inhibition by G6P in that it is competitive with ATP and not competitive with 2DG, but the inhibition constant (1.4 mM) is much larger. The experimental protocol includes provisions for enzymatic destruction of stray inhibitors such as G6P. The results show that the high 2DG6P and low ATP concentrations found in the steady state of the perfused heart should strongly reduce the rate of phosphorylation of sugars by hexokinase.     

The metal-mediated formation of hydroxyl radical by aqueous extracts of cigarette tar

Aqueous extracts of cigarette tar produce hydroxyl radicals that are spin trapped by 5,5-dimethyl-1-pyrroline-N-oxide. The addition of catalase almost completely inhibits and superoxide dismutase partially inhibits spin adduct formation. The addition of ethylenediamine tetraacetic acid greatly increases the amount of hydroxyl radical adduct observed; in contrast, diethylenetriamine pentaacetic acid causes complete inhibition of spin adduct formation. We suggest that the hydroxyl radical arises from the metal-mediated decomposition of hydrogen peroxide, and that hydrogen peroxide is formed from the reduction of dioxygen by the semiquinones present in the cigarette tar.     

Radicalization of lignocellulosic fibers, related structural and morphological changes

The radicalization of unbleached lignocellulosic fibers obtained from thermomechanical (TMP) and chemothermomechanical (CTMP) pulps was performed in heterogeneous phase by reaction with dioxygen in the presence of N,N'-ethylenebis(salicylideneiminato)cobalt(II), [Co(salen)], as catalyst. Phenoxy cobalt radicals immobilized in fibers were observed by electron paramagnetic resonance (EPR) spectroscopy; their amount depends on the fiber swelling induced by reaction medium. The absolute concentration of such radicals in fibers, about 10(16) spin/g, reaches values 10 times higher than that of phenoxy radicals formed in similar oxidative reactions catalyzed by laccase. The generation of phenoxy cobalt radicals in fibers was related to structural changes of lignin units, detected by mono- and bidimensional nuclear magnetic resonance ((13)C NMR and 2D-HSQC) investigations, and to morphological modifications in fibers observed by scanning electron microscopy (SEM).     

Metabolic activation of sulfur mustard leads to oxygen free radical formation

We recently published electron paramagnetic resonance (EPR) spin trapping results that demonstrated the enzymatic reduction of sulfur mustard sulfonium ions to carbon-based free radicals using an in vitro system containing sulfur mustard, cytochrome P450 reductase, NADPH, and the spin trap α-(4-pyridyl-1-oxide)-N-tert-butylnitrone (4-POBN) in buffer (A.A. Brimfield et al., 2009, Toxicol. Appl. Pharmacol. 234:128-134). Carbon-based radicals have been shown to reduce molecular oxygen to form superoxide and, subsequently, peroxyl and hydroxyl radicals. In some cases, such as with the herbicide paraquat, a cyclic redox system results, leading to magnified oxygen free radical concentration and sustained tissue damage. Low mustard carbon radical concentrations recorded by EPR in our in vitro system, despite a robust (4.0mM) sulfur mustard starting concentration, led us to believe a similar oxygen reduction and redox cycling process might be involved with sulfur mustard. A comparison of the rate of mustard radical-POBN adduct formation in our in vitro system by EPR at atmospheric and reduced oxygen levels indicated a sixfold increase in 4-POBN adduct formation (0.5 to 3.0 μM) at the reduced oxygen concentration. That result suggested competition between oxygen and POBN for the available carbon-based mustard radicals. In parallel experiments we found that the oxygen radical-specific spin trap 5-tert-butoxycarbonyl-5-methylpyrroline-N-oxide (BMPO) detected peroxyl and hydroxyl radicals directly when it was used in place of POBN in the in vitro system. Presumably these radicals originated from O(2) reduced by carbon-based mustard radicals. We also showed that reactive oxygen species (ROS)-BMPO EPR signals were reduced or eliminated when mustard carbon radical production was impeded by systematically removing system components, indicating that carbon radicals were a necessary precursor to ROS production. ROS EPR signals were completely eliminated when superoxide dismutase and catalase were included in the complete in vitro enzymatic system, providing additional proof of oxygen radical participation. The redox cycling hypothesis was supported by density functional theory calculations and frontier molecular orbital analysis.     

EPR spin trapping detection of carbon-centered carotenoid and beta-ionone radicals

Free radical intermediates were detected by the electron paramagnetic resonance spin trapping technique upon protonation/deprotonation reactions of carotenoid and beta-ionone radical ions. The hyperfine coupling constants of their spin adducts obtained by spectral simulation indicate that carbon-centered radicals were trapped. The formation of these species was shown to be a result of chemical oxidation of neutral compounds by Fe(3+) or I(2) followed by deprotonation of the corresponding radical cations or addition of nucleophilic agents to them. Bulk electrolysis reduction of beta-ionone and carotenoids also leads to the formation of free radicals via protonation of the radical anions. Two different spin adducts were detected in the reaction of carotenoid polyenes with piperidine in the presence of 2-methyl-2-nitroso-propane (MNP). One is attributable to piperidine radicals (C(5)H(10)N*) trapped by MNP and the other was identified as trapped neutral carotenoid (beta-ionone) radical produced via protonation of the radical anion. Formation of these radical anions was confirmed by ultraviolet-visible spectroscopy. It was found that the ability of carotenoid radical anions/cations to produce neutral radicals via protonation/deprotonation is more pronounced for unsymmetrical carotenoids with terminal electron-withdrawing groups. This effect was confirmed by the radical cation deprotonation energy (H(D)) estimated by semiempirical calculations. The results indicate that the ability of carotenoid radical cations to deprotonate decreases in the sequence: beta-ionone > unsymmetrical carotenoids > symmetrical carotenoids. The minimum H(D) values were obtained for proton abstraction from the C(4) atom and the C(5)-methyl group of the cyclohexene ring. It was assumed that deprotonation reaction occurs preferentially at these positions.     

Spin-trapping studies of the oxidation-reduction reactions of iron bleomycin in the presence of thiols and buffer.

The reaction of ferrous bleomycin with dioxygen is reexamined to clarify whether radical species derived from molecular oxygen are generated. Detection of low levels of spin-trapped oxyradicals confirm the production of OH during this reaction when bleomycin is present in excess, but not when iron and drug concentrations are equal. In phosphate buffer, hydroxyl radicals continue to be spin trapped for at least 15 min after Fe(II)bleomycin has been oxidized to Fe(III)bleomycin. In HEPES buffer, detection of a HEPES radical in the absence of spin trap over the same period independently supports the conclusion that reactive radicals are present after the initial oxidation of Fe(II)bleomycin is complete. When glutathione is included in the aerobic reaction mixture, thiyl radical species are spin trapped. The reaction of Fe(III)bleomycin with cysteine produces thiyl radical without spin-trapped hydroxyl radical.     

31P nuclear magnetic resonance evidence for polyphosphoinositide associated with the hydrophobic segment of glycophorin A.

Glycophorin A, the major human erythrocyte sialoglycoprotein, contains a significant amount of phosphorus when isolated by the lithium diiodosalicylate-phenol procedure. Only a small percentage (approximately 1%) of this phosphorus is phosphoprotein. 31P nuclear magnetic resonance (NMR) analysis of glycophorin A has identified the remaining phosphorus content as phospholipid in origin. From the 31P chemical shifts, the phospholipid has been identified as diphosphoinositide. 31P NMR spectra of the peptides produced by trypsin hydrolysis of glycophorin A reveal that all the diphosphoinositide is closely associated with the hydrophobic region of the protein, suggesting that there is a specific affinity between this phospholipid and the intramembranous portion of glycophorin A.     

The 31P NMR visibility of ATP in perfused rat liver remains about 90%, unaffected by changes of metabolic state.

The 31P NMR visibility of ATP of the perfused rat liver was tested over a wide range of metabolic conditions, including normoxic and hypoxic perfusions, fructose loads, and various intervals of normothermic ischemia, for both ad libitum fed and 24-h fasted rats. The 31P NMR signal of ATP was compared to the concentration of ATP determined by enzymatic assays on liver biopsies performed at the end of NMR acquisition. In a first series of experiments, the NMR resonance of intracellular ATP was quantitated in absolute terms by applying the 1H NMR water signal as internal reference: during normoxic and hypoxic perfusions, a constant amount of ATP (0.43 +/- 0.19 mM, mean +/- SD), approximately 12% of the cellular ATP, is not detected by NMR. Nevertheless, there is a high correlation (slope = 0.96 +/- 0.09; r2 = 0.93) between the measurements of ATP by 31P NMR spectroscopy and by biochemical analysis. In a second series of experiments, there was a highly significant correlation between the NMR and analytical biochemical measurements of ATP for whole range of metabolic states, i.e., fructose loads (1.0-10 mM) and various intervals of normothermic ischemia (ranging from 2 to 12 min), indicating unchanged ATP visibility. Thus, as opposed to the studies of Murphy et al. [Murphy, E., et al. (1988) Biochemistry 27, 526-528], it is concluded that ATP at 37 degrees C remains almost entirely visible in the perfused rat liver, also during ischemia.     

The line asymmetry of electron spin resonance spectra as a tool to determine the cis:trans ratio for spin-trapping adducts of chiral pyrrolines N-oxides: the mechanism of formation of hydroxyl radical adducts of EMPO, DEPMPO, and DIPPMPO in the ischemic-reperfused rat liver

Nonstereospecific addition of free radicals to chiral nitrones yields cis/trans diastereoisomeric nitroxides often displaying different electron spin resonance (ESR) characteristics. Glutathione peroxidase-glutathione (GPx-GSH) reaction was applied to reduce the superoxide adducts (nitrone/*OOH) to the corresponding hydroxyl radical (HO*) adducts (nitrone/*OH) of two nitrones increasingly used in biological spin trapping, namely 5-diethoxyphosphoryl-5-methyl-1-pyrroline N-oxide (DEPMPO) and 5-ethoxycarbonyl-5-methyl-1-pyrroline N-oxide, and of 5-diisopropoxyphosphoryl-5-methyl-1-pyrroline N-oxide (DIPPMPO), a sterically hindered DEPMPO analogue. The method offered improved conditions to record highly resolved ESR spectra and by accurate simulation of line asymmetry we obtained clear evidence for the existence of previously unrecognized isomer pairs of cis- and trans-[DEPMPO/*OH] and [DIPPMPO/*OH]. Additional nitrone/*OH generation methods were used, i.e. photolysis of hydrogen peroxide and the Fenton reaction. We developed a kinetic model involving first- and second-order decay and a secondary conversion of trans to cis isomer to fully account for the strongly configuration-dependent behavior of nitrone/*OH. In the reductive system and, to a lower extent, in the Fenton or photolytic systems cis-nitrone/*OH was the more stable diastereoisomer. In various biologically relevant milieu, we found that the cis:trans-nitrone/*OH ratio determined right after the spin adduct formation significantly differed upon the GPx-GSH vs (Fenton or photolytic) systems of formation. This new mechanistic ESR index consistently showed for all nitrones that nitrone/*OH signals detected in the postischemic effluents of ischemic isolated rat livers are the reduction products of primary nitrone/*OOH. Thus, ESR deconvolution of cis/trans diastereoisomers is of great interest in the study of HO* formation in biological systems.     

Radical scavenger can scavenge lipid allyl radicals complexed with lipoxygenase at lower oxygen content

Lipoxygenases have been proposed to be a possible factor that is responsible for the pathology of certain diseases, including ischaemic injury. In the peroxidation process of linoleic acid by lipoxygenase, the E,Z-linoleate allyl radical-lipoxygenase complex seems to be generated as an intermediate. In the present study, we evaluated whether E,Z-linoleate allyl radicals on the enzyme are scavenged by radical scavengers. Linoleic acid, the content of which was greater than the dissolved oxygen content, was treated with soya bean lipoxygenase-1 (ferric form) in the presence of radical scavenger, CmP (3-carbamoyl-2,2,5,5-tetramethylpyrrolidine-N-oxyl). The reaction rate between oxygen and lipid allyl radical is comparatively faster than that between CmP and lipid allyl radical. Therefore a reaction between linoleate allyl radical and CmP was not observed while the dioxygenation of linoleic acid was ongoing. After the dissolved oxygen was depleted, CmP stoichiometrically trapped linoleate-allyl radicals. Accompanied by this one-electron redox reaction, the resulting ferrous lipoxygenase was re-oxidized to the ferric form by hydroperoxylinoleate. Through the adduct assay via LC (liquid chromatography)-MS/MS (tandem MS), four E,Z-linoleate allyl radical-CmP adducts corresponding to regio- and diastereo-isomers were detected in the linoleate/lipoxygenase system, whereas E,E-linoleate allyl radical-CmP adducts were not detected at all. If E,Z-linoleate allyl radical is liberated from the enzyme, the E/Z-isomer has to reach equilibrium with the thermodynamically favoured E/E-isomer. These data suggested that the E,Z-linoleate allyl radicals were not liberated from the active site of lipoxygenase before being trapped by CmP. Consequently, we concluded that the lipid allyl radicals complexed with lipoxygenase could be scavenged by radical scavengers at lower oxygen content.     

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.     

Free radical formation from organic hydroperoxides in isolated human polymorphonuclear neutrophils.

We have demonstrated with electron paramagnetic resonance (EPR) that organic hydroperoxides are decomposed to free radicals by both human polymorphonuclear leukocytes (PMNs) and purified myeloperoxidase. When tert-butyl hydroperoxide was incubated with either PMNs or purified myeloperoxidase, peroxyl, alkoxyl, and alkyl radicals were trapped by the spin trap 5,5-dimethyl-1-pyrroline N-oxide (DMPO). In the case of ethyl hydroperoxide, DMPO radical adducts of peroxyl and alkyl (identified as alpha-hydroxyethyl when trapped by tert-nitrosobutane) radicals were detected. Radical adduct formation was inhibited when azide was added to the incubation mixture. Myeloperoxidase-deficient PMNs produced DMPO radical adduct intensities at only about 20-30% of that of normal PMNs. Our studies suggest that myeloperoxidase in PMNs is primarily responsible for the decomposition of organic hydroperoxides to free radicals. The finding of the free radical formation derived from organic hydroperoxides by PMNs may be related to the cytotoxicity of this class of compounds.     

Effect of cadmium ions on dioxygen affinity and polyphosphate activity of human red blood cells

The effect of cadmium ions on the dioxygen affinity, the time-dependent depletion of intracellular polyphosphates, and the elongation of human red blood cells (RBC's) was examined. The incubation of RBC's in the presence of 1 mM Cd2+ at 37 degrees C for more than one hour results in a decrease of the p50 value by 2.5-3.0 mmHg in comparison to controls. The p50 of stripped (phosphate-free) hemoglobin is not affected by the presence of 1 mM Cd2+ (p50 = 4.8 mmHg at pH 7.2 and 37 degrees C). Experiments with RBC cryolysates demonstrate an apparently competitive effect of 2.3-bisphosphoglycerate (DPG) with cadmium ions on the dioxygen affinity. From 31P NMR spectra, 31P T1 relaxation, and 31P T2 relaxation behavior a more direct evidence for DPG-Cd2+ complexation is obtained. 31P NMR spectra of RBC cryolysates also indicate DPG-Cd2+ complexation. The hydrolysis of free polyphosphates in RBC's incubated at 37 degrees C as monitored by 31P NMR spectra can be noticed after a three-hour lag phase (constant polyphosphate level). This lag phase is lengthened from three hours to four hours in the presence of Cd2+ ions. RBC elongation, as a measure of deformability, decreases slightly upon incubation with 1 mM Cd2+.     

A novel protocol to identify and quantify all spin trapped free radicals from in vitro/in vivo interaction of HO(.-) and DMSO: LC/ESR, LC/MS, and dual spin trapping combinations

When dimethyl sulfoxide (DMSO) is oxidized via hydroxyl radical (HO(.-)), it forms methyl radicals ((.-)CH(3)) that can be spin trapped and detected by electron spin resonance (ESR). This ESR spin trapping technique has been widely used in many biological systems to indicate in vivo HO(.-) formation. However, we recently reported that (.-)CH(3) might not be the only carbon-centered radical that was trapped and detected by ESR from in vivo DMSO oxidation. In the present study, newly developed combination techniques consisting of dual spin trapping (free radicals trapped by both regular and deuterated alpha-[4-pyridyl 1]-N-tert-butyl nitrone, d(0)/d(9)-POBN) followed by LC/ESR and LC/MS were used to characterize and quantify all POBN-trapped free radicals from the interaction of HO(.-) and DMSO. In addition to identifying the two well-known free radicals, (.-)CH(3) and (.-)OCH(3), from this interaction, we also characterized two additional free radicals, (.-)CH(2)OH and (.-)CH(2)S(O)CH(3). Unlike ESR, which can measure POBN adducts only in their radical forms, LC/MS identified and quantified all three redox forms, including the ESR-active radical adduct and two ESR-silent forms, the nitrone adduct (oxidized adduct) and the hydroxylamine (reduced adduct). In the bile of rats treated with DMSO and POBN, the ESR-active form of POBN/(.-)CH(3) was not detected. However, with the addition of the LC/MS technique, we found approximately 0.75 microM POBN/(.-)CH(3) hydroxylamine, which represents a great improvement in radical detection sensitivity and reliability. This novel protocol provides a comprehensive way to characterize and quantify in vitro and in vivo free radical formation and will have many applications in biological research.     

Iron and free radical oxidations in cell membranes.

Brain tissue being rich in polyunsaturated fatty acids, is very susceptible to lipid peroxidation. Iron is well known to be an important initiator of free radical oxidations. We propose that the principal route to iron-mediated lipid peroxidations is via iron-oxygen complexes rather than the reaction of iron with hydrogen peroxide, the Fenton reaction. To test this hypothesis, we enriched leukemia cells (K-562 and L1210 cells) with docosahexaenoic acid (DHA) as a model for brain tissue, increasing the amount of DHA from approximately 3 mole % to 32 mole %. These cells were then subjected to ferrous iron and dioxygen to initiate lipid peroxidation in the presence or absence of hydrogen peroxide. Lipid-derived radicals were detected using EPR spin trapping with alpha-(4-pyridyl-1-oxide)-N-t-butylnitrone (POBN). As expected, lipid-derived radical formation increases with increasing cellular lipid unsaturation. Experiments with desferal demonstrate that iron is required for the formation of lipid radicals from these cells. Addition of iron to DHA-enriched L1210 cells resulted in significant amounts of radical formation; radical formation increased with increasing amount of iron. However, the exposure of cells to hydrogen peroxide before the addition of ferrous iron did not increase cellular radical formation, but actually decreased spin adduct formation. These data suggest that iron-oxygen complexes are the primary route to the initiation of biological free radical oxidations. This model proposes a mechanism to explain how catalytic iron in brain tissue can be so destructive.     

Nonradical mechanism of (bi)sulfite reaction with DEPMPO: cautionary note for SO3*- radical spin trapping

Knowledge of the formation of radicals from sulfites, in vivo, is of interest in understanding the allergic and inflammatory responses to environmental sulfur dioxide exposure. Sulfite anion trioxide (SO(3)(-*)) radical formation was measured in mice, preloaded with the spin trap, 5-(diethoxy-phosphoryl)-5-methyl-pyrrolidine-N-oxide, (DEPMPO). Based on spin trapping NMR, a surprising quantity of reduced SO(3)(-*)-adduct was observed that did not depend on co-administration of oxidizing agents, suggesting a possible nonradical reaction between (bi)sulfite and DEPMPO. The products of the reversible nucleophylic addition of (bi)sulfite to the nitrone functional group were identified using (31)P-NMR, (1)H-NMR, and (13)C-NMR spectroscopy as cis- and trans- stereoisomers of hydroxylamine and confirmed by quantum chemical calculations. Oxidation of the hydroxylamines results in the formation of two corresponding cis- and trans-isomeric nitroxides, only one of which has been earlier described as the paramagnetic adduct of genuinely trapped SO(3)(-*) radical. The results demonstrate that SO(3)(-*) detection using nitrone spin traps such as DEPMPO and DMPO may involve nonradical addition reactions except in cases when the required controls unambiguously prove a radical mechanism.     

Electron trapping and reactions in rhamnose by ESR and ENDOR.

The main objective for a reinvestigation of rhamnose was to devise a mechanistic link between the trapped electron detected previously and the secondary radicals observed at 77 K and at room temperature. Single crystals of rhamnose were X-irradiated at temperatures between 15 and 300 K and examined using ESR, ENDOR, and field-swept ENDOR techniques. After low-temperature irradiation a C3 H-abstraction radical is formed following the visible light-induced decay of the trapped electron. This species was previously assigned erroneously to a C2 H-abstraction species. At temperatures above 120 K, this radical deprotonates at the C3 hydroxy group. Furthermore, a C2 H-abstraction radical is formed following the thermally induced decay of the trapped electron. The C2 and C3 H-abstraction radicals did not convert into each other. A third radical species formed at low temperatures is a C5 H-abstraction radical. It is unstable above 250 K and decays without any apparent successor. The C2 and C3 H-abstraction radicals are formed thermally and photochemically from the parent trapped electron. The conversions are mediated by hydrogen atoms formed intermediately or by elimination of hydride ions. The thermal decomposition pathway requires further studies, in particular with respect to the possible role of water. Recently, Box et al. analyzed the site of the trapped electron in rhamnose crystals. The present results support the results obtained by these authors (Radiat. Res. 121, 262 (1990)). In particular, trapped electron vs proton distances closely match the conversion mechanisms suggested.     

Dioxygen reactivity and heme redox potential of truncated human cystathionine beta-synthase

Cystathionine beta-synthase (CBS) catalyzes the condensation of serine and homocysteine to cystathionine, which represents the committing step in the transsulfuration pathway. CBS is unique in being a pyridoxal phosphate-dependent enzyme that has a heme cofactor. The activity of CBS under in vitro conditions is responsive to the redox state of the heme, which is distant from the active site and has been postulated to play a regulatory role. The heme in CBS is unusual; it is six-coordinate, low spin, and contains cysteine and histidine as axial ligands. In this study, we have assessed the redox behavior of a human CBS dimeric variant lacking the C-terminal regulatory domain. Potentiometric redox titrations showed a reversible response with a reduction potential of -291 +/- 5 mV versus the normal hydrogen electrode, at pH 7.2. Stopped-flow kinetic determinations demonstrated that Fe(II)CBS reacted with dioxygen yielding Fe(III)CBS without detectable formation of an intermediate species. A linear dependence of the apparent rate constant of Fe(II)CBS decay on dioxygen concentration was observed and yielded a second-order rate constant of (1.11 +/- 0.07) x 10 (5) M (-1) s (-1) at pH 7.4 and 25 degrees C for the direct reaction of Fe(II)CBS with dioxygen. A similar reactivity was observed for full-length CBS. Heme oxidation led to superoxide radical generation, which was detected by the superoxide dismutase (SOD)-inhibitable oxidation of epinephrine. Our results show that CBS may represent a previously unrecognized source of cytosolic superoxide radical.     

ESR spin-trapping studies on the reaction of Fe2+ ions with H2O2-reactive species in oxygen toxicity in biology

Using ESR spin-trapping techniques with 5,5-dimethyl-1-pyrroline-N-oxide (DMPO), we confirmed the 1:1 stoichiometry for the formation of hydroxyl radicals with Fe2+ in the Fenton reaction under experimental conditions wherein [H2O2] is 90 microM and [Fe2+] is very low, 1 microM or less. The stoichiometry decreased markedly as the Fe2+ concentration was increased. The efficiency of hydroxyl radical generation varied with the nature of the iron chelators used and increased in the order of phosphate alone approximately ADP less than EDTA less than diethylenetriaminepentaacetic acid (DETAPAC). The second order rate constant for the Fenton reaction was measured to be 2.0 x 10(4) M-1 s-1 for phosphate alone, 8.2 x 10(3) M-1 s-1 for ADP, 1.4 x 10(4) M-1 s-1 for EDTA, and 4.1 x 10(2) M-1 s-1 for DETAPAC. Measuring the radicals formed as spins trapped in the presence of ethanol, we estimated the amount of total oxidizing intermediates formed in the Fenton reaction, which we concluded consists of hydroxyl radicals and an iron species. The oxidizing species of iron which might be assigned as ferryl, FeO2+, or Fe(IV) = O was generated effectively in the presence of ADP even at low Fe2+ concentrations. In general, as the Fe2+ concentration was increased, the ferryl species predominated over the hydroxyl radical except for the case of Fe(II)-DETAPAC, which generated only hydroxyl radicals as the oxidizing species. Three possible pathways are proposed for the Fenton reaction, the dominant ones depending very much on the nature of the iron chelator being used.