The cellular-induced decay of DMPO spin adducts of .OH and .O2

In a recent report, it was concluded that DMPO, often considered the spin trap of choice for detection of superoxide and hydroxyl radical adducts in biological systems, may be unsuitable for many biological uses because of its instability in cellular systems. It was demonstrated in red blood cells and in hamster V79 cells that the DMPO spin adducts of .O2- and .OH are metabolized very rapidly so that even if formed, they may not be detected in many experiments with cells. Because of the potential importance of these findings to experiments already reported on the occurrence of oxygen radicals in cellular systems, and the implications of these findings for future experiments, we have extended the studies on DMPO to other cellular, systems. We have also investigated the role of oxygen in this system because it has been shown recently that very hypoxic cells reduce some nitroxides much more rapidly than oxic cells and therefore it seemed possible that the rapid loss of radical adducts of DMPO was due to the hypoxic conditions under which the previous experiments were carried out. The results of the present experiments indicate that the loss of the DMPO spin adducts occurs in other cell systems as well, that the decomposition rate is independent of the concentration of oxygen, and that the final products of cellular metabolism of DMPO adducts are different from those of most nitroxides. There is no evidence that intracellular DMPO-spin adducts of oxygen radicals can be observed under conditions similar to those used in this study. We conclude that DMPO is not likely to be a suitable agent for studying intracellular oxygen radicals.     

The Effect of Oxygen at Physiological Levels on the Detection of free Radical Intermediates by Electron Paramagnetic Resonance

It is well known that oxygen enhances Che relaxation of free radical EPR probes through spin lattice and Heisenberg spin-spin interactions with consequent effect on the line height and width. The two relaxation processes have opposing effects on the signal heights and depend on the concentration of oxygen, the incident microwave power, and the presence of other paramagnetic species. During EPR studies of chemical, biochemical, and cellular processes involving free radicals, molecular oxygen has significant magnetic influence on the EPR signal intensity of the free radical species under investigation in addition to affecting the rates of production of the primary species and the stability of the spin adduct nitroxides. These effects are often overlooked and can cause artifacts and lead to erroneous interpretation. In the present study, the effects of oxygen and ferricyanide on the EPR signal height of stable and persistent spin adduct nitroxides at commonly employed microwave powers were examined. The results show that under commonly adopted EPR spectrometer instrumental conditions, artifactual changes in the EPR signal of spin adducts occur and the best way to avoid them is by keeping the oxygen level constant using a gas-permeable cell.     

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.     

Inhibition of radical adduct reduction and reoxidation of the corresponding hydroxylamines in in vivo spin trapping of carbon tetrachloride-derived radicals.

In vivo spin trapping of radical metabolites has become a promising tool in understanding and predicting toxicities caused by different xenobiotics. However, in biological systems radical adducts can be reduced to electron paramagnetic resonance (EPR)-silent hydroxylamines. To overcome this difficulty, different procedures for reoxidation of the reduced radical adducts were systematically investigated and some metabolic inhibitors of nitroxide reduction were tested. As a test system, carbon tetrachloride (CCl4), a known hepatotoxic substance, was used. CCl4 is metabolized by liver to .CCl3 and, in the presence of the spin trap phenyl N-t-butylnitrone (PBN), forms the PBN/.CCl3 and PBN/.CO2- radical adducts. These radical adducts were measured in the bile using electron paramagnetic resonance after administration of CCl4 and PBN to the rat. We have shown that these radical adducts were reduced to the corresponding hydroxylamines in vivo, since immediately after the collection of bile only traces of the radical adducts could be detected, but after oxidation by different procedures such as bubbling with oxygen, addition of mild oxidant potassium ferricyanide or autoxidation the EPR spectra intensity increases, indicating that the hydroxylamines had been re-oxidized back to nitroxides. The collection of bile into plastic Eppendorf tubes containing the sulfhydryl reagent N-ethylmaleimide (NEM) or the enzyme ascorbate oxidase did not increase the intensity of the spectra significantly, demonstrating that neither reduction by reduced glutathione (GSH) nor ascorbic acid occurred ex vivo. However in the presence of NEM faster re-oxidation was observed. A new radical adduct that was not observed previously in any in vivo experiment and which exhibited 13C hyperfine coupling was detected when the rats were injected with 13CCl4. We have proven that this is the same adduct detected previously in vitro in microsomal incubations of CCl4, PBN, GSH, and reduced nicotinamide adenine dinucleotide phosphate (NADPH). As a general rule, we have shown that a variety of oxidation procedures should be tried to detect the different radical adducts which are otherwise not observable due to the in vivo reduction of radical adducts.     

Optimal EPR detection of weak nitroxide spin adduct and ascorbyl free radical signals.

We have investigated the optimal nominal power settings for the electron paramagnetic resonance detection of typical nitroxides, nitroxide spin adducts, and the ascorbyl free radical. In room temperature aqueous solution, we find that, for all the nitroxides examined, saturation effects begin at approx. 25 mW nominal power with maximum signal intensity achieved at approx. 100 mW power when using a TM110 cavity. For the ascorbyl free radical, we find that saturation effects begin at approx. 16 mW nominal power and that maximum peak-to-peak signal amplitude is obtained at approx. 40 mW microwave power. For the ascorbyl free radical, we find that a modulation amplitude of approx. 0.65 G yields the maximum signal height for the doublet signal. This information will help researchers maximize the EPR signal height of minimally detectable free radicals such as encountered in biological systems.     

Spin trapping of nitrogen dioxide and of radicals generated from nitrous acid

Spin trapping of nitrogen dioxide radical by several nitrones has been studied. The reaction results in the formation of persistent acyl nitroxides, after the oxidation of the intermediate spin adducts having an -ONO group on C-2 atom. The intermediate is effectively detected when DEPMPO is used as the spin trap. The reaction between PBN or 5,7-di-tert-butyl-3,3-dimethyl indoline N-oxide with nitrous acid gives the corresponding acyl nitroxide only when oxygen is present in the reaction milieu.

On the other hand, nitroso spin traps do not trap ^⋅NO₂ confirming that the unpaired electron of nitrogen dioxide is localized on the oxygen atom.     

Evidence for the formation of strand-break precursors in hydroxy-attacked thymidine 5'-monophosphate by the spin trapping method

A method combining spin trapping, ESR, and HPLC was employed to obtain evidence for the formation of sugar radicals in OH-attacked TMP with special emphasis on the detection of strand-break precursors of DNA. OH radicals were produced by irradiating an N2O-saturated aqueous solution with X-rays. When an N2O-saturated aqueous solution containing TMP and a spin trapping reagent, MNP, was irradiated with X-rays, it was estimated on the basis of theoretical calculations using rate constants that 94% of the TMP radicals were induced by OH radicals. Since several spin adducts between TMP radicals and MNP, as well as the byproducts of the spin trapping reagent itself, were produced, reverse-phase HPLC was used to separate them. The presence of six spin adducts was confirmed by ESR examination. Further examination of these spin adducts by UV absorbance spectrophotometry showed the presence of a chromophore at 260 nm in three adducts. Since a gradual increase in the release of unaltered base from these adducts was observed when they were allowed to stand for 0-22 h at room temperature, they could be regarded as the spin adducts of sugar radicals and MNP. ESR spectra from the spin adducts were consistent with hydrogen abstraction radicals at the C1', C4', and C5' positions of the sugar moiety. These radicals appeared to be precursors of AP sites and strand breaks. In addition to these spin adducts, ESR spectra that were consistent with the spin adducts of base radicals (the C5 and C6 radicals) and MNP were observed.     

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.     

Analysis of the reduction of nitroxides by flavin mononucleotide

This article describes a simle method to prepare hydroxylamines from nitroxides by photo-activated flavin mononucleotide. The half-time of reduction varied from 2 to 38.4 s for a series of nitroxides. For most nitroxides short exposures to light (min) were sufficient to produce significant amounts of hydroxylamine; longer periods of exposure increased the yields of other products. Proxyl (2,2,5-trimethyl-5-alkylpyrrolidine-N-oxy) nitroxides were unsually reactive with a much higher yield of products which could not be reoxidized by ferricyanide to the nitroxides. Optimum conditions for reversible reduction depend on the nitroxide and the amounts of other reducible substances such as oxygen and ferricyanide that may be present.     

Reduction and destruction rates of nitroxide spin probes

A series of nitroxides was tested for rates of one-electron reduction in a chemical, a photochemical, and two biological systems by ESR assays. In all cases, piperidine and hydropyridine nitroxides were reduced consistently more rapidly than pyrroline and pyrrolidine nitroxides. Substituents on the nitroxides also affected reduction rates, although not as greatly as ring structure. One of the reduction systems, consisting of the photosensitizer FMN and the photoreductant EDTA, was used to study both anaerobic reduction and O2-dependent reoxidation of some of the nitroxides. Reduced piperidine and hydropyridine nitroxides were also oxidized more rapidly than the reduced pyrroline and pyrrolidine nitroxides. Reoxidation subsequent to reduction was partially inhibited by superoxide dismutase, indicating that superoxide radicals are involved in the process. Even after prolonged reoxidation, not all of the probe molecules were returned to their oxidized form, implying an irreversible "destruction" of the spin probe concomitant with its chemical reduction. Probe destruction was studied more specifically with a photochemical system for generating methyl radicals, which showed that these carbon-centered radicals destroyed different nitroxides at rates which were much less influenced by the nitroxide structures than one-electron reduction was.     

Structural dependence of nitroxide spin labels and nitroxide spin adducts on their reducibility by ascorbate ion

Summary

The reducibility of a series of nitroxides (aminoxyls) by ascorbate was tested by measuring the nitroxide decay rates with a stopped-flow electron paramagnetic resonance technique in aqueous phosphate buffer solution. The dependence of reactivity on the structures and pH of the medium was found for both cyclic nitroxides and nitroxide adducts of phenyl N-tert butyl nitrone (PBN). In cyclic nitroxides, the ring size is a dominant factor in determining reaction rates but substituents have additional effects on the rate depending on their electronegativity. For alkyl and hydroxyalkyl adducts of PBN, at fixed ascorbate concentration, half-lives increase with lengthening of the substituent, suggesting that a long chain in the substituent sterically protects the nitroxide group and thus prevents its reduction by ascorbate.     

Measurements in vivo of parameters pertinent to ROS/RNS using EPR spectroscopy

The technique of in vivo EPR spectroscopy can provide useful and even unique information pertinent to the study of oxygen/ nitrogen radicals and related processes. The parameters that can be measured include: (a) Oxygen centered radicals (by spin trapping); (b) carbon centered radicals (by spin trapping and sometimes by direct observation); (c) sulfur centered radicals (by spin trapping and sometimes by direct observation); (d) nitric oxide (by spin trapping); (e) oxygen (using oxygen sensitive paramagnetic materials); (f) redox state (using metabolism of nitroxides); (g) thiol groups (using special nitroxides); (h) pH (using special nitroxides); (h) perfusion (using washout of paramagnetic tracers); (i) some redox active metal ions (chromium, manganese). The current state of the art for these and other measurements is discussed, especially in relationship to experiments that are likely to be useful for studies of reactive oxygen species (ROS) and/or reactive nitrogen species (RNS).     

Effects of oxygen on the metabolism of nitroxide spin labels in cells

The products of the reduction of nitroxides in cells are the corresponding hydroxylamines, which cells can oxidize back to the nitroxides in the presence of oxygen. Both the reduction of nitroxides and the oxidation of hydroxylamines are enzyme-mediated processes. For lipid-soluble nitroxides, the rates of reduction are strongly dependent on the intracellular concentration of oxygen; severely hypoxic cells reduce nitroxides more rapidly than cells supplied with oxygen. In contrast, the rates of oxidation of hydroxylamines increase smoothly with increasing intracellular oxygen concentration up to 150 microM. In order to separate the effects on the rates of metabolism of nitroxides due directly to oxygen from effects due to the redox state of enzymes, we studied the cells under conditions in which each of these variables could be changed independently. Oxygen affects the metabolism of these nitroxides primarily by interacting with cytochrome c oxidase to change the redox state of the enzymes in the respiratory chain. Our results are consistent with the conclusions that in these cells reduction of lipophilic nitroxides occurs at the level of ubiquinone in the respiratory chain in mitochondria, and oxidation of the corresponding hydroxylamines occurs at the level of cytochrome c oxidase.     

Cellular uptake of electron paramagnetic resonance imaging probes through endocytosis of liposomes

Electron paramagnetic resonance imaging (EPRI) allows detection and localization of paramagnetic spin probes in vivo and in real time. We have shown that nitroxide spin probes entrapped in the intracellular milieu can be imaged by EPRI. Therefore, with the development of a tumor-targetable vehicle that can efficiently deliver nitroxides into cells, it should be possible to use nitroxide spin probes to label and image cells in a tumor. In this study, we assess the potential of liposomes as a delivery vehicle for imaging probes. We demonstrate that liposomes can stably encapsulate nitroxides at very high concentrations (> 100 mM), at which nitroxides exhibit concentration-dependent quenching of their EPR signal—a process analogous to the quenching of fluorescent molecules. The encapsulating liposomes thus appear spectroscopically “dark”. When the liposomes are endocytosed and degraded by cells, the encapsulated nitroxides are liberated and diluted into the much larger intracellular volume. The consequent relief of quenching generates a robust intracellular nitroxide signal that can be imaged. We show that through endocytosis of nitroxide-loaded liposomes, CV1 cells can achieve intracellular nitroxide concentrations of ∼ 1 mM. By using tissue phantom models, we verify that this concentration is more than sufficient for in vivo EPR imaging.     

Measurements in vivo of parameters pertinent to ROS/RNS using EPR spectroscopy

The technique of in vivo EPR spectroscopy can provide useful and even unique information pertinent to the study of oxygen/nitrogen radicals and related processes. The parameters that can be measured include: (a) Oxygen centered radicals (by spin trapping); (b) carbon centered radicals (by spin trapping and sometimes by direct observation); (c) sulfur centered radicals (by spin trapping and sometimes by direct observation); (d) nitric oxide (by spin trapping); (e) oxygen (using oxygen sensitive paramagnetic materials); (f) redox state (using metabolism of nitroxides); (g) thiol groups (using special nitroxides); (h) pH (using special nitroxides); (h) perfusion (using washout of paramagnetic tracers); (i) some redox active metal ions (chromium, manganese). The current state of the art for these and other measurements is discussed, especially in relationship to experiments that are likely to be useful for studies of reactive oxygen species (ROS) and/or reactive nitrogen species (RNS).     

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.     

Exchange and shuttling of electrons by nitroxide spin labels

The ability of nitroxide spin labels to act as oxidizers of reduced nitroxides (hydroxylamines) in biological and model systems was demonstrated. All of the nitroxides tested were able to act as oxidizing agents with respect to hydroxylamine derivatives of nitroxides. The rates of these reactions were first order with respect to nitroxide concentration and with respect to hydroxylamine concentration, making the reaction second order overall. The second-order rate constants are reported for a number of these reactions. These reactions proceeded to an equilibrium state and the equilibrium constants for several combinations of reactants are presented. Both the rate constants and the equilibrium constants were found to be dependent on the ring structure of the nitroxide and hydroxylamine, with piperidines being reduced more easily and pyrrolidines and oxazolidines being oxidized more easily. All of the hydroxylamine derivatives were oxidized by air to their respective nitroxides, with the rate of this oxidation greater for pyrrolidines than for piperidines. Furthermore, hydroxylamines that are permeable to lipid bilayers were able to act as shuttles of reducing equivalents to liposome-encapsulated nitroxides that were otherwise inaccessible to reducing agents. This mechanism of shuttling of electrons was able to explain the relatively rapid reduction by cells of a nonpermeable nitroxide in the presence of a permeable nitroxide.     

Superoxide Scavenging Activity of Spin-Labeled Nitrosourea and Triazene Derivatives

Superoxide scavenging activities (SSA) of newly synthesized spin-labeled nitrosourea and triazene derivatives, and their precursor nitroxides were investigated by the ESR/spin-trapping method using the spin trap 5,5-dimethyl-1-pyrroline-N-oxide (DMPO) and hypoxanthine/xanthine oxidase as the superoxide-generating system. The spin-labeled nitrosoureas, triazenes and their precursor nitroxides exhibited excellent SSA, whereas clinically used nitrosourea and triazene, which do not contain the nitroxide moiety, did not show any SSA. Furthermore, it was deduced that these nitroxides scavenge superoxide by redox cycling between nitroxide and corresponding hydroxylamine.     

EPR detection of lipid-derived free radicals from PUFA, LDL, and cell oxidations

We have used the spin trap 5,5-dimethyl-pyrroline-1-oxide (DMPO) and EPR to detect lipid-derived radicals (Ld*) during peroxidation of polyunsaturated fatty acids (PUFA), low-density lipoprotein (LDL), and cells (K-562 and MCF-7). All oxygen-centered radical adducts of DMPO from our oxidizable targets have short lifetimes (<20 min). We hypothesized that the short lifetimes of these spin adducts are due in part to their reaction with radicals formed during lipid peroxidation. We proposed that stopping the lipid peroxidation processes by separating oxidation-mediator from oxidation-substrate with an appropriate extraction would stabilize the spin adducts. To test this hypothesis we used ethyl acetate to extract the lipid-derived radical adducts of DMPO (DMPO/Ld*) from an oxidizing docosahexaenioc acid (DHA) solution; Folch extraction was used for LDL and cell experiments. The lifetimes of DMPO spin adducts post-extraction are much longer (>10 h) than the spin adducts detected without extraction. In iron-mediated DHA oxidation we observed three DMPO adducts in the aqueous phase and two in the organic phase. The aqueous phase contains DMPO/HO* aN approximately aH approximately 14.8 G) and two carbon-centered radical adducts (aN1 approximately 15.8 G, aH1 approximately 22.6 G; aN2 approximately 15.2 G, aH2 approximately 18.9 G). The organic phase contains two long-chain lipid radical adducts (aN approximately 13.5 G, aH approximately 10.2 G; and aN approximately 12.8 G; aH approximately 6.85 G, 1.9 G). We conclude that extraction significantly increases the lifetimes of the spin adducts, allowing detection of a variety of lipid-derived radicals by EPR.     

Radical-Induced Damage to Proteins: E.S.R. Spin-Trapping Studies

The reactions of hydroxyl radicals generated from Fe¹¹/H₂O₂ and Cu¹¹/H₂O₂ redox couples with a variety of proteins (BSA, histones, cytochrome c, lysozyme and protamine) have been investigated by e.s.r. spin trapping. The signals obtained, which are generally anisotropic in nature, characterize the formation of partially-immobilized spin-adducts resulting from attack of the HO- radicals on the protein and subsequent reaction of the protein-derived radicals with the spin trap. Similar spin adducts are observed on incubation of two haem-proteins (haemoglobin and myoglobin) with H₂O₂ in the absence of added metal ions implying a reaction at the haem centre followed by internal electron transfer reactions.

Two strategies have been employed to obtain information about the site(s) of radical damage in these proteins. The first involves the use of a variety of spin traps and in particular DMPO: with this particular trap the broad spectra from largely immobilized radicals show characteristic a(β-H) values which enable carbon-, oxygen- and sulphur-centred radicals to be distinguished. The second involves the use of enzymatic cleavage of first-formed adducts to release smaller nitroxides, with isotropic spectra, which allow the recognition of β-proton splittings and hence information about the sites of radical damage to be obtained. These results, which allows backbone and side-chain attack to be distinguished, are in agreement with random attack of the HO^. radical on the protein and are in accord with studies carried out on model peptides. In contrast the use of less reactive attacking radicals [N₃·, ·CH(CH₃)OH] and oxidising agents (Ce⁴⁺) provides evidence for selective attack on these proteins at particular residues.