Spin trapping of lipid radicals with DEPMPO-derived spin traps: detection of superoxide, alkyl and alkoxyl radicals in aqueous and lipid phase

The spin trap 5-(diethoxyphosphoryl)-5-methyl-1-pyrroline N-oxide (DEPMPO) forms a superoxide adduct with a half-life of almost 15 min. DEPMPO is very hydrophilic and its use for the detection of radicals in the lipid phase (lipid-derived radicals and superoxide generated in the lipid phase) is therefore limited due to its very low concentration in the lipid phase. For the detection of lipid-derived radicals, three derivatives of DEPMPO with increasing degree of lipid solubility have been investigated: 5-(di-n-propoxyphosphoryl)-5-methyl-1-pyrroline N-oxide (DPPMPO), 5-(di-n-butoxyphosphoryl)-5-methyl-1-pyrroline N-oxide (DBPMPO), and 5-(bis-(2-ethylhexyloxy)phosphoryl)-5-methyl-1-pyrroline N-oxide (DEHPMPO). As compared with the spin trap DMPO, the half-lives of the respective superoxide adducts were clearly higher in aqueous solutions of the spin traps, which facilitates qualitative ESR measurements. The stability of the superoxide spin adducts formed with the various lipophilic spin traps in aqueous buffer were similar to those observed with DEPMPO (half-life: 7-11 min.). In model experiments using Fe(3+)-catalyzed nucleophilic addition of methanol or tert-butanol to the respective spin trap the respective alkoxyl radical adducts were formed in aqueous solution as transient species in the presence of high concentrations of the alcohol. Upon dilution with water the alkoxyl group was substituted by water, giving the respective hydroxyl adduct of the spin trap. Care must therefore be taken when Fenton-type reactions are used for the generation of radicals such as the use of Fe(2+) complexes with phosphate or DTPA or inactivation of iron by addition of "Desferal" (Novarti's Pharma GmbH, Vienna, Austria) after a short incubation time. Addition of Fe(2+) under anaerobic conditions to an aqueous suspension of linoleic acid hydroperoxide and the spin trap resulted in the detection of three different species: a carbon-centered radical adduct, an acyl radical adduct, and the hydroxyl adduct. In the presence of oxygen a different species was observed with DEPMPO, DPPMPO, and DBPMPO, which was only slightly suppressed upon the addition of SOD, possibly the respective spin adduct of either the alkylperoxyl radical or, in analogy to DMPO, a secondary alkoxyl radical.     

Detection of radicals produced by reaction of hydroperoxides with rat liver microsomal fractions.

EPR spin trapping using the spin traps 5,5-dimethyl-1-pyrroline N-oxide (DMPO) and 3,5-dibromo-4-nitrosobenzene sulphonic acid (DBNBS) has been employed to examine the generation of radicals produced on reaction of a number of primary, secondary and lipid hydroperoxides with rat liver microsomal fractions in both the presence and absence of reducing equivalents. Two major mechanisms of radical generation have been elucidated. In the absence of NADPH or NADH, oxidative degradation of the hydroperoxide occurs to give initially a peroxyl radical which in the majority of cases can be detected as a spin adduct to DMPO; these radicals can undergo further reactions which result in the generation of alkoxyl and carbon-centered radicals. In the presence of NADPH (and to a lesser extent NADH) alkoxyl radicals are generated directly via reductive cleavage of the hydroperoxide. These alkoxyl radicals undergo further fragmentation and rearrangement reactions to give carbon-centered species which can be identified by trapping with DBNBS. The type of transformation that occurs is highly dependent on the structure of the alkoxyl radical with species arising from beta-scission, 1,2-hydrogen shifts and ring closure reactions being identified; these processes are in accord with previous chemical studies and are characteristic of alkoxyl radicals present in free solution. Studies using specific enzyme inhibitors and metal-ion chelators suggest that most of the radical generation occurs via a catalytic process involving haem proteins and in particular cytochrome P-450. An unusual species (an acyl radical) is observed with lipid hydroperoxides; this is believed to arise via a cage reaction after beta-scission of an initial alkoxyl radical.     

Spin trapping of polyunsaturated fatty acid-derived peroxyl radicals: reassignment to alkoxyl radical adducts

Polyunsaturated fatty acid (PUFA) peroxyl radicals play a crucial role in lipid oxidation. ESR spectroscopy with the spin-trapping technique is one of the most direct methods for radical detection. There are many reports of the detection of PUFA peroxyl radical adducts; however, it has recently been reported that attempted spin trapping of organic peroxyl radicals at room temperature formed only alkoxyl radical adducts in detectable amounts. Therefore, we have reinvestigated spin trapping of the linoleic, arachidonic, and linolenic acid-derived PUFA peroxyl radicals. The slow-flow technique allowed us to obtain well-resolved ESR spectra of PUFA-derived radical adducts in a mixture of soybean lipoxygenase, PUFA, and the spin trap 5,5-dimethyl-1-pyrroline N-oxide (DMPO). However, interpretation of the ESR spectra was complicated by the overlapping of the PUFA-derived alkoxyl radical adduct spectra. In order to understand these spectra, PUFA-derived alkoxyl radical adducts were modeled by various alkoxyl radical adducts. For the first time, we synthesized a wide range of DMPO adducts with primary and secondary alkoxyl radicals. It was found that many ESR spectra previously assigned as DMPO/peroxyl radical adducts based on their close similarity to the ESR spectrum of the DMPO/superoxide radical adduct, in conjunction with their insensitivity to superoxide dismutase, are indeed alkoxyl radical adducts. We have reassigned the PUFA alkylperoxyl radical adducts to their corresponding alkoxyl radical adducts. Using hyperfine coupling constants of model DMPO/alkoxyl radical adducts, the computer simulation of DMPO/PUFA alkoxyl radical adducts was performed. It was found that the trapped, oxygen-centered PUFA-derived radical is a secondary, chiral alkoxyl radical. The presence of a chiral carbon atom leads to the formation of two diastereomers of the DMPO/PUFA alkoxyl radical adduct. Therefore, attempted spin trapping of the PUFA peroxyl radical by DMPO at room temperature leads to the formation of the PUFA alkoxyl radical adduct.     

Spin Trapping Using 2,2-Dimethyl-2H-Imidazole-1-Oxides

The ability of novel cyclic nitrones, 4-substituted 2,2-dimethyl-2H-imidazole-1-oxides (IMO's) to trap a variety of short-lived free radicals has been investigated using ESR spectroscopy. IMO's scavenge oxygen-, carbon- and sulfur-derived free radicals to give persistent nitroxides. Compared to the spin trap 5,5-dimethyl-pyrroline-1-oxide, a higher lifetime of hydroxyl radical adducts and a higher selectivity related to the trapping of carbon-centered radicals was found. A reaction between IMO's and superoxide was not observed. ESR parameters of 4-carboxyl-2,2-dimethyl-2H-imidazole-1-oxide (CIMO) spin adducts are highly sensitive to the structure of the trapped radical, e.g., different spectra were detected with radicals derived from Na₂SO₃ and NaHSO₃. From the data obtained, a successful application of these new spin traps in biological systems can be expected.     

Studies on the photolytic breakdown of hydroperoxides and peroxidized fatty acids by using electron spin resonance spectroscopy. Spin trapping of alkoxyl and peroxyl radicals in organic solvents.

Spin trapping using 5,5-dimethyl-1-pyrroline N-oxide (DMPO) has been used to detect and distinguish between the carbon-centred, alkoxyl, and peroxyl radicals produced during the photolytic decomposition of hydroperoxides. Photolysis of tert-butyl and cumene hydroperoxides, and peroxidized fatty acids, in toluene, with low levels of u.v. light, is shown to lead to the initial production of alkoxyl radicals by homolysis of the oxygen-oxygen bond. Subsequent reaction of these radicals with excess hydroperoxide leads, by hydrogen abstraction, to the production of peroxyl radicals that can be detected as their corresponding adducts with the spin trap. Subsequent breakdown of these adducts produces alkoxyl radicals and a further species that is believed to be the oxidized spin-trap radical 5,5-dimethyl-1-pyrrolidone-2-oxyl. No evidence was obtained at low hydroperoxide concentrations, with either the cumene or lipid alkoxyl radicals, for the occurrence of beta-scission reactions; the production of low levels of carbon-centred radicals is believed to be due to the alternative reactions of hydrogen abstraction, ring closure, and/or 1,2 hydrogen shifts. Analogous experiments with 3,3,5,5-tetramethyl-1-pyrroline N-oxide (TMPO) led only to the trapping of alkoxyl radicals with no evidence for peroxyl radical adducts, this is presumably due to a decreased rate of radical addition because of increased steric hindrance.     

Trapping of free radicals with direct in vivo EPR detection: a comparison of 5,5-dimethyl-1-pyrroline-N-oxide and 5-diethoxyphosphoryl-5-methyl-1-pyrroline-N-oxide as spin traps for HO* and SO4*-.

To spin trap hydroxyl radical (HO*) with in vivo detection of the resultant radical adducts, the use of two spin traps, 5,5-dimethyl-1-pyrroline-N-oxide (DMPO) and 5-diethoxyphosphoryl-5-methyl-1-pyrroline-N-oxide (DEPMPO) (10 mmol/kg) has been compared. In mice treatment with 5-aminolevulinic acid and Fe3+ resulted in detection of adducts of hydroxyl radicals (HO*), but only with use of DEPMPO. Similarly, 'HO* adducts' generated via nucleophilic substitution of SO4*- adducts formed in vivo could be observed only when using DEPMPO as the spin trap. The reasons for the differences observed between DEPMPO and DMPO are likely due to different in vivo lifetimes of their hydroxyl radical adducts. These results seem to be the first direct in vivo EPR detection of hydroxyl radical adducts.     

Spin adducts of superoxide,alkoxyl, and lipid-derived radicals with EMPO and its derivatives

The compound 5-(ethoxycarbonyl)-5-methyl-1-pyrroline N-oxide (EMPO) is a hydrophilic cyclic nitrone spin trap, which, in contrast to DMPO, forms a relatively stable superoxide adduct (t(1/2)=8.6 min) with an EPR spectrum similar to the respective DMPO adduct. In order to find the optimal degree of lipophilicity of this novel type of spin trap with respect to the detection of radicals formed during lipid peroxidation, the ethoxy group of EMPO was replaced by alkoxy substituents of increasing chain length, leading to the methoxy- (MeMPO), 1-propoxy- (PrMPO), 1-butoxy- (BuMPO), and 1-octyloxy- (OcMPO) derivatives of EMPO. The stability of their superoxide adducts was found to be strongly dependent on the size of the alkoxycarbonyl group. Increasing chain length of the alkoxyl substituent decreased the stability of alkoxyl radical adducts of MeMPO, EMPO, and PrMPO, but increased the stability of OcMPO adducts. The stability of alkoxyl radical adducts of BuMPO, on the other hand, were practically independent of the size of the alkoxyl group. Detection of lipid alkoxyl radicals formed by peroxidizing linoleic acid in a stationary system was therefore only possible with the most lipophilic spin trap, OcMPO. However, with the more hydrophilic spin traps MeMPO, EMPO, PrMPO, and BuMPO optimal EPR signal intensity could be obtained when a slow-flow system was used. Thus, within this series EMPO is the best spin trap for the detection of superoxide; OcMPO, on the other hand, is most suitable for the detection of lipid alkoxyl radicals.     

ESR measurement of rapid penetration of DMPO and DEPMPO spin traps through lipid bilayer membranes

The passive permeation rates of DMPO and DEPMPO spin traps and their hydroxyl radical adducts through liposomal membranes were measured using ESR spectroscopy. For the spin traps, we measured the time-dependent change in the signal intensity of the OH-adduct, which is formed by a reaction between the penetrated spin trap and hydroxyl radicals produced by the UV-radiolysis of H(2)O(2) inside the liposomes. The hydroxyl radicals produced outside the liposomes were quenched with polyethylene glycol. For the OH-adduct, pre-formed adduct was mixed with liposomes and the time-dependent change of the ESR signal was measured in the presence of a line-broadening reagent outside the liposomes to make the signal outside the liposomes invisible. Both the spin traps and their OH-adducts diffused across the lipid membranes rapidly and reached equilibrium within tens of seconds. These findings suggest that if used for the detection of free radicals inside cells, these spin traps should be well distributed in cells and even in organelles.     

Studies on the metal-ion and lipoxygenase-catalysed breakdown of hydroperoxides using electron-spin-resonance spectroscopy.

The breakdown of cumene hydroperoxide and peroxidized fatty acids by iron is shown, by use of the spin trap 5,5-dimethyl-l-pyrroline-N-oxide, to be sensitive to (a) the oxidation state of the metal and (b) the nature of the chelating ligands. The initial step in the Fe2+-catalysed breakdown is the production of an alkoxyl radical by one-electron reduction, and this type of radical has been successfully trapped from each substrate. Subsequent reactions of this alkoxyl species produce both carbon-centred and peroxyl radicals, depending on the concentrations of the reagents present. The use of the same spin trap in microsomal systems undergoing either NADPH-supported or Fe2+-induced peroxidation led to the detection of low concentrations of radical adducts, among which are signals that are believed to be due to lipid alkoxyl radicals. Reaction of polyunsaturated fatty acid hydroperoxides with both Fe2+ and lipoxygenase under anaerobic conditions gives rise to signals not only from the alkoxy-radical adduct, but also from a further species which is tentatively identified as being due to an acyl [RC(O).]-radical adduct; chemical studies lend support to this assignment.     

Detection of peroxyl and alkoxyl radicals produced by reaction of hydroperoxides with heme-proteins by electron spin resonance spectroscopy

ESR spin trapping using the spin trap 5,5-dimethyl-1-pyrroline N-oxide (DMPO) has been used to directly detect alkoxyl radicals (with hyperfine coupling constants aN 1.488, aH 1.600 mT and aN 1.488, aH 1.504 mT for the tBuO. and PhC(CH3)2O. adducts, respectively) and peroxyl radicals (aN 1.448, aH 1.088, aH 0.130 mT and aN 1.456, aH 1.064, aH 0.128 mT for the tBuOO. and PhC(CH3)2OO. adducts, respectively) produced from t-butyl or cumene hydroperoxides by a variety of heme-containing substances (purified cytochrome P-450, metmyoglobin, oxyhemoglobin, methemoglobin, cytochrome c, catalase, horseradish peroxidase) and the model compound hematin. The observed species exhibit a complicated dependence on reagent concentrations and time, with maximum concentrations of the peroxyl radical adducts being observed immediately after mixing of the hydroperoxide with low concentrations of the heme-compound. Experiments with inhibitors (CN-, N3-, CO, metyrapone and imidazole) suggest that the major mechanism of peroxyl radical production involves high-valence-state iron complexes in a reaction analogous to the classical peroxidase pathway. The production of alkoxyl radicals is shown to arise mainly from the breakdown of peroxyl radical spin adducts, with direct production from the hydroperoxide being a relatively minor process.     

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.     

Characterization of the high resolution ESR spectra of the methoxyl radical adducts of 5-(diethoxyphosphoryl)-5-methyl-1-pyrroline N-oxide (DEPMPO)

Spin-trapping investigators are largely limited by the instability of the radical adducts. Spin trap 5-(diethoxyphosphoryl)-5-methyl-1-pyrroline N-oxide (DEPMPO) forms very stable alkoxyl radical adducts. However, the presence of two chiral centers in the DEPMPO alkoxyl radical adduct results in two diastereomers with distinctive ESR spectra, which complicates the interpretation of the ESR spectra. We have analyzed the high resolution ESR spectra of the DEPMPO/_•OCH₃ radical adduct. DEPMPO/_•OCH₃ has been synthesized by the nucleophilic addition of alcohols to DEPMPO. The electron spin resonance (ESR) spectrum of DEPMPO/_•OCH₃ in oxygen-free methanol solution reveals superhyperfine structure with hyperfine coupling constants as small as 0.3 G. In order to simplify the analysis of the electron spin resonance (ESR) spectrum, we synthesized the DEPMPO/_•OCD₃ radical adduct. Computer simulation of the DEPMPO/_•OCD₃ ESR spectrum revealed two diastereomers. Hyperfine coupling constants of γ-protons and ₁₇O from the -OCH₃ group were also determined. ESR spectra of DEPMPO/_•OCH₃ in phosphate buffer have also been characterized. The presence of specific hyperfine couplings from the -OCH₃ group can be used for the unambiguous identification of the DEPMPO/_•OCH₃ radical adducts. We suggest that the analysis of high resolution ESR spectra can be used for the unambiguous characterization of DEPMPO radical adducts.     

NMR spin trapping: detection of free radical reactions with a new fluorinated DMPO analog

Electron spin resonance (ESR) and nuclear magnetic resonance (NMR) spin trapping were used for detection of free radical reactions utilizing a new fluorinated analog of DMPO, 4-hydroxy-5,5-dimethyl-2-trifluoromethylpyrroline-1-oxide (FDMPO). The parent FDMPO spin trap exhibits a single 19F-NMR resonance at -66.0 ppm. The signal to noise ratio improved 10.4-fold compared to 31P-NMR sensitivity of the phosphorus-containing spin trap, DEPMPO. The spin adducts of FDMPO with .OH, .CH3, and .CH2OH were characterized. Competitive spin trapping of FDMPO with DMPO showed that both have similar rates of addition of .OH and C-centered radicals. The corresponding paramagnetic spin adducts of FDMPO were extremely stable to degradation. In the presence of ascorbate, reaction products from C-centered radicals resulted in the appearance of two additional 19F-NMR signals at -78.6 and -80 ppm for FDMPO/ .CH(3) and at -74.6 and -76.75 ppm for FDMPO/ .CH(2)OH. In each case, these peaks were assigned to the two stereoisomers of their respective, reduced hydroxylamines. The identification of the hydroxylamines for FDMPO/ .CH3 was confirmed by EPR and 19F-NMR spectra of independently synthesized samples. In summary, spin adducts of FDMPO were highly stable for ESR. For NMR spin trapping, FDMPO showed improved signal to noise and similar spin trapping efficiency compared to DEPMPO.     

Superoxide and peroxyl radical generation from the reduction of polyunsaturated fatty acid hydroperoxides by soybean lipoxygenase.

Soybean lipoxygenase is shown to catalyze the breakdown of polyunsaturated fatty acid hydroperoxides to produce superoxide radical anion as detected by spin trapping with 5,5-dimethyl-1-pyrroline-N-oxide (DMPO). In addition to the DMPO/superoxide radical adduct, the adducts of peroxyl, acyl, carbon-centered, and hydroxyl radicals were identified in incubations containing linoleic acid and lipoxygenase. These DMPO radical adducts were observed just prior to the system becoming anaerobic. Only a carbon-centered radical adduct was observed under anaerobic conditions. The superoxide radical production required the presence of fatty acid substrates, fatty acid hydroperoxides, active lipoxygenase, and molecular oxygen. Superoxide radical production was inhibited when nordihydroguaiaretic acid, butylated hydroxytoluene, or butylated hydroxyanisole was added to the incubation mixtures. We propose that polyunsaturated fatty acid hydroperoxides are reduced to form alkoxyl radicals and that after an intramolecular rearrangement, the resulting hydroxyalkyl radical reacts with oxygen, forming a peroxyl radical which subsequently eliminates superoxide radical anion.     

Spin trapping of C- and O-centered radicals with methyl-, ethyl-, pentyl-, and phenyl-substituted EMPO derivatives

In order to develop spin traps with an optimal ratio between hydrophilic and lipophilic properties, low toxicity, and high stability of spin adducts (especially with superoxide radicals), several EMPO-derived spin traps have recently been synthesized forming more stable superoxide adducts (t(1/2) > 20 min) than DMPO or DEPMPO. In this study, ESR-, 1H-, and 13C-NMR data of several phenyl- or n-pentyl-substituted EMPO derivatives are presented with full signal assignment. Methyl groups at position 3 or 4 stabilized the superoxide adducts considerably. Spin adducts from other oxygen- and carbon-centered radicals (e.g., derived from methanol or linoleic acid hydroperoxide) are also described.     

Generation of free radicals from organic hydroperoxide tumor promoters in isolated mouse keratinocytes. Formation of alkyl and alkoxyl radicals from tert-butyl hydroperoxide and cumene hydroperoxide

The organic hydroperoxides tert-butyl hydroperoxide and cumene hydroperoxide are tumor promoters in the skin of SENCAR mice, and this activity is presumed to be mediated through the activation of the hydroperoxides to free radical species. In this study we have assessed the generation of free radicals from organic hydroperoxides in the target cell (the murine basal keratinocyte) using electron spin resonance. Incubation of primary isolates of keratinocytes from SENCAR mice in the presence of spin traps (5,5-dimethyl-1-pyrroline N-oxide or 2-methyl-2-nitrosopropane) and either tert-butyl hydroperoxide or cumene hydroperoxide resulted in the generation and detection of radical adducts of these spin traps. tert-Butyl alkoxyl and alkyl radical adducts of 5,5-dimethyl-1-pyrroline N-oxide were detected shortly after addition of tert-butyl hydroperoxide, whereas only alkyl radical adducts were observed with cumene hydroperoxide. Spin trapping of the alkyl radicals with 2-methyl-2-nitrosopropane led to the identification of methyl and ethyl radical adducts following both tert-butyl hydroperoxide and cumene hydroperoxide exposures. Prior heating of the cells to 100 degrees C for 30 min prevented radical formation. The radical generating capacity of subcellular fractions of these epidermal cells was examined using 5,5-dimethyl-1-pyrroline N-oxide and cumene hydroperoxide, and this activity was confined to the 105,000 X g supernatant fraction.     

Using anti-5,5-dimethyl-1-pyrroline N-oxide (anti-DMPO) to detect protein radicals in time and space with immuno-spin trapping

The detection of protein free radicals using the specific free radical reactivity of nitrone spin traps in conjunction with nitrone-antibody sensitivity and specificity greatly expands the utility of the spin trapping technique, which is no longer dependent on the quantum mechanical electron spin resonance (ESR). The specificity of the reactions of nitrone spin traps with free radicals has already made spin trapping with ESR detection the most universal, specific tool for the detection of free radicals in biological systems. Now the development of an immunoassay for the nitrone adducts of protein radicals brings the power of immunological techniques to bear on free radical biology. Polyclonal antibodies have now been developed that bind to protein adducts of the nitrone spin trap 5,5-dimethyl-1-pyrroline N-oxide (DMPO). In initial studies, anti-DMPO was used to detect DMPO protein adducts produced on myoglobin and hemoglobin resulting from self-peroxidation by H2O2. These investigations demonstrated that myoglobin forms the predominant detectable protein radical in rat heart supernatant, and hemoglobin radicals form inside red blood cells. In time, all of the immunological techniques based on antibody-nitrone binding should become available for free radical detection in a wide variety of biological systems.     

Characterization of the High Resolution ESR Spectra of the Methoxyl Radical Adducts of 5-(diethoxyphosphoryl)-5-methyl-1-pyrroline N-oxide (DEPMPO)

Spin-trapping investigators are largely limited by the instability of the radical adducts. Spin trap 5-(diethoxyphosphoryl)-5-methyl-1-pyrroline N-oxide (DEPMPO) forms very stable alkoxyl radical adducts. However, the presence of two chiral centers in the DEPMPO alkoxyl radical adduct results in two diastereomers with distinctive ESR spectra, which complicates the interpretation of the ESR spectra. We have analyzed the high resolution ESR spectra of the DEPMPO/^?OCH³ radical adduct. DEPMPO/^?OCH³ has been synthesized by the nucleophilic addition of alcohols to DEPMPO. The electron spin resonance (ESR) spectrum of DEPMPO/^?OCH³ in oxygen-free methanol solution reveals superhyperfine structure with hyperfine coupling constants as small as 0.3?G. In order to simplify the analysis of the electron spin resonance (ESR) spectrum, we synthesized the DEPMPO/^?OCD³ radical adduct. Computer simulation of the DEPMPO/^?OCD³ ESR spectrum revealed two diastereomers. Hyperfine coupling constants of γ-protons and ¹⁷O from the –OCH³ group were also determined. ESR spectra of DEPMPO/^?OCH³ in phosphate buffer have also been characterized. The presence of specific hyperfine couplings from the –OCH³ group can be used for the unambiguous identification of the DEPMPO/^?OCH³ radical adducts. We suggest that the analysis of high resolution ESR spectra can be used for the unambiguous characterization of DEPMPO radical adducts.     

Reassignment of organic peroxyl radical adducts.

The study of the important role of peroxyl radicals in biological systems is limited by their difficult detection with direct electron spin resonance (ESR). Many ESR spectra were assigned to 5,5-dimethyl-1-pyrroline N-oxide (DMPO)/peroxyl radical adducts based only on the close similarity of their ESR spectra to that of DMPO/superoxide radical adduct in conjunction with their insensitivity to superoxide dismutase, which distinguishes the radical adduct from DMPO/superoxide radical adduct. Later, the spin-trapping literature reported that DMPO/peroxyl radical adducts have virtually the same hyperfine coupling constants as synthesized alkoxyl radical adducts, raising the issue of the correct assignment of peroxyl radical adducts. However, using 17O-isotope labelling, the methylperoxyl and methoxyl radical adducts should be distinguishable. We have reinvestigated the spin trapping of the methylperoxyl radical. The methylperoxyl radical was generated in aerobic solution with 17O-molecular oxygen either in a Fenton system with dimethylsulfoxide or in a chloroperoxidase system with tert-butyl hydroperoxide. Two different spin traps, DMPO and 2,2,4-trimethyl-2H-imidazole-1-oxide (TMIO), were used to trap methylperoxyl radical. 17O-labelled methanol was used to synthesize methoxyl radical adducts by nucleophylic addition. It was shown that the 17O hyperfine coupling constants of radical adducts formed in methylperoxyl radical-generating systems are identical to that of the methoxyl radical adduct. Therefore, methylperoxyl radical-producing systems form detectable methoxyl radical adduct, but not detectable methylperoxyl radical adducts at room temperature. One of the possible mechanisms is the decomposition of peroxyl radical adduct with the formation of secondary alkoxyl radical adduct. These results allow us to reinterpret previously published data reporting detection of peroxyl radical adducts. We suggest that detection of 17O-alkoxyl radical adduct from 17O-labelled molecular oxygen can be used as indirect evidence for peroxyl radical generation.     

Detection of lipid radicals by electron paramagnetic resonance spin trapping using intact cells enriched with polyunsaturated fatty acid.

Electron paramagnetic resonance (EPR) spin trapping was used to detect lipid-derived free radicals generated by iron-induced oxidative stress in intact cells. Using the spin trap alpha-(4-pyridyl 1-oxide)-N-tert-butylnitrone (POBN), carbon-centered radical adducts were detected. These lipid-derived free radicals were formed during incubation of ferrous iron with U937 cells that were enriched with docosahexaenoic acid (22:6n-3). The EPR spectra exhibited apparent hyperfine splittings characteristic of a POBN/alkyl radical, aN = 15.63 +/- 0.06 G and aH = 2.66 +/- 0.03 G, generated as a result of beta-scission of alkoxyl radicals. Spin adduct formation depended on the FeSO4 content of the incubation medium and the number of 22:6-enriched cells present; when the cells were enriched with oleic acid (18:1n-9), spin adducts were not detected. This is the first direct demonstration, using EPR, of a lipid-derived radical formed in intact cells in response to oxidant stress.