Carotenoids as cellular antioxidants.

Consumption of carotenoids is associated with an enhanced immune response and protection against neoplasia and atherosclerosis. Because these effects have been achieved using carotenoids with no pro-vitamin A activity, they are assumed to be due to the antioxidant properties of carotenoids. Carotenoids protect against photosensitized oxidation by quenching singlet oxygen. In addition, beta-carotene reacts chemically with peroxyl radicals to produce epoxide and apocarotenal products. To investigate the potential significance of these reactions to biological systems, we have used soybean lipoxygenase to generate peroxyl radical enzymatically. beta-Carotene inhibits the oxidation of linoleic acid by soybean lipoxygenase as well as the formation of the hydroperoxide product. In addition, the absorption of beta-carotene is diminished (bleached) by soybean lipoxygenase. The potential significance of these antioxidant reactions of carotenoids to biological function is discussed.     

EPR spin trapping of protein radicals

Electron paramagnetic resonance (EPR) spin trapping was originally developed to aid the detection of low-molecular-mass radicals formed in chemical systems. It has subsequently found widespread use in biology and medicine for the direct detection of radical species formed during oxidative stress and via enzymatic reactions. Over the last 15 years this technique has also found increasing use in detecting and identifying radicals formed on biological macromolecules as a result of either radical reactions or enzymatic processes. Though the EPR signals that result from the trapping of large, slowly tumbling radicals are often broad and relatively poor in distinctive features, a number of techniques have been developed that allow a wealth of information to be obtained about the nature, site, and reactions of such radicals. This article summarizes recent developments in this area and reviews selected examples of radical formation on proteins.     

Oxidation of biological electron donors and antioxidants by a reactive lactoperoxidase metabolite from nitrite (NO2-): an EPR and spin trapping study

We report that a lactoperoxidase (LPO) metabolite derived from nitrite (NO2-) catalyses one-electron oxidation of biological electron donors and antioxidants such as NADH, NADPH, cysteine, glutathione, ascorbate, and Trolox C. The radical products of the reaction have been detected and identified using either direct EPR or EPR combined with spin trapping. While LPO/H2O2 alone generated only minute amounts of radicals from these compounds, the yield of radicals increased sharply when nitrite was also present. In aerated buffer (pH 7) the nitrite-dependent oxidation of NAD(P)H by LPO/H2O2 produced superoxide radical, O2*-, which was detected as a DMPO/*O2H adduct. We propose that in the LPO/H2O2/NO2-/biological electron donor systems the nitrite functions as a catalyst because of its preferential oxidation by LPO to a strongly oxidizing metabolite, most likely a nitrogen dioxide radical *NO2, which then reacts with the biological substrates more efficiently than does LPO/H2O2 alone. Because both nitrite and peroxidase enzymes are ubiquitous our observations point at a possible mechanism through which nitrite might exert its biological and cytotoxic action in vivo, and identify some of the physiological targets which might be affected by the peroxidase/H2O2/nitrite systems.     

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.     

Kinetic analysis-based quantitation of free radical generation in EPR spin trapping

Because short-lived reactive oxygen radicals such as superoxide have been implicated in a variety of disease processes, methods to measure their production quantitatively in biological systems are critical for understanding disease pathophysiology. Electron paramagnetic resonance (EPR) spin trapping is a direct and sensitive technique that has been used to study radical formation in biological systems. Short-lived oxygen free radicals react with the spin trap and produce paramagnetic adducts with much higher stability than that of the free radicals. In many cases, the quantity of the measured adduct is considered to be an adequate measure of the amount of the free radical generated. Although the intensity of the EPR signal reflects the magnitude of free radical generation, the actual quantity of radicals produced may be different due to modulation of the spin adduct kinetics caused by a variety of factors. Because the kinetics of spin trapping in biochemical and cellular systems is a complex process that is altered by the biochemical and cellular environment, it is not always possible to define all of the reactions that occur and the related kinetic parameters of the spin-trapping process. We present a method based on a combination of measured kinetic data for the formation and decay of the spin adduct alone with the parameters that control the kinetics of spin trapping and radical generation. The method is applied to quantitate superoxide trapping with 5-diethoxyphosphoryl-5-methyl-1-pyrroline N-oxide (DEPMPO). In principle, this method is broadly applicable to enable spin trapping-based quantitative determination of free radical generation in complex biological systems.     

Electron paramagnetic resonance (EPR) spin trapping of biological nitric oxide

Nitric oxide (NO) is a free radical species with multiple physiological functions. Because of low concentrations and short half-life of NO, its direct measurement in living tissues remains a difficult task. Electron paramagnetic resonance (EPR) spin trapping is probably one of the best suitable platforms for development of new methods for quantification of biological NO. The most reliable EPR-based approaches developed so far are based on the reaction of NO with various iron complexes, both intrinsic and exogenously applied. This review is focused on the current state and perspectives of EPR spin trapping for experimental and clinical NO biology.     

EPR spin trapping of a radical intermediate in the urate oxidase reaction

Urate oxidase, or uricase (EC 1.7.3.3), is a peroxisomal enzyme that catalyses the oxidation of uric acid to allantoin. The chemical mechanism of the urate oxidase reaction has not been clearly established, but the involvement of radical intermediates was hypothesised. In this study EPR spectroscopy by spin trapping of radical intermediates has been used in order to demonstrate the eventual presence of radical transient urate species. The oxidation reaction of uric acid by several uricases (Porcine Liver, Bacillus Fastidiosus, Candida Utilitis) was performed in the presence of 5-diethoxyphosphoryl-5-methyl-pyrroline-N-oxide (DEPMPO) as spin trap. DEPMPO was added to reaction mixture and a radical adduct was observed in all cases. Therefore, for the first time, the presence of a radical intermediate in the uricase reaction was experimentally proved.     

The NoH value in EPR spin trapping: a new parameter for the identification of 5,5-dimethyl-1-pyrroline-N-oxide spin adducts.

The ratio of the nitrogen to hydrogen hyperfine splittings (aN/aH) of spin adducts derived from the spin trap 5,5-dimethyl-1-pyrroline-N-oxide (DMPO) has been found to be a useful parameter for adduct identification. For example, this parameter makes it possible to distinguish between the superoxide (aN/aH = 1.22-1.26) and peroxyl (aN/aH = 1.33-1.40) radical adducts of DMPO in aqueous solution. Since the aN to aH ratio corrects for minor differences in EPR spectrometer calibration, it is a more reproducible parameter than the aN and aH values themselves.     

Photodynamic action of C-phycocyanins obtained from marine and fresh water cyanobacterial cultures: a comparative study using EPR spin trapping technique

C-phycocyanins, major biliproteins of blue green algae (cyanobacteria), widely used as colourants in food and cosmetics are known for their antioxidant as well as therapeutic potential. Recent claims indicating phycobiliproteins exert stronger photodynamic action on tumor cells than clinically approved hematoporphyrin derivatives motivate us to investigate the photodynamic action of two newly isolated C-phycocyanins from Phormidium [PHR] and Lyngbya [LY] spp, respectively in comparison with known C-phycocyanin from Spirulina sp. [SPI]. Photolysis of air saturated solutions of PHR, LY and SPI in the presence of 2,2,6,6-Tetramethyl piperidinol (TEMPL) generated three line EPR spectrum characteristic of 4-hydroxy-2,2,6,6-tetramethylpiperidinyloxyl (TEMPOL). The increase in intensity of the EPR spectrum with time of irradiation and decrease in intensity, in the presence of 1O2 quencher DABCO confirm the formation of 1O2. Photoirradiation in the presence of spin trap 5,5-dimethyl-1-pyrroline-N-oxide (DMPO) generated EPR signal characteristic of O2(-) adduct. Efficiency of 1O2 generation is of the order LY > PHR> SPI. The yield of reactive oxygen species (ROS) generation is found to be 1O2>O2(-) indicating type II mechanism to be the prominent pathway for photosensitation by phycocyanins.     

Detection of nitric oxide in tissue by spin trapping EPR spectroscopy and triacetylglycerol extraction

A modified method based on EPR spin trapping and triacetylglycerol extraction was used for tissue nitric oxide (NO) detection at room temperature. NO signal intensity was stable for about 1.5 h and the detection limit of this method was less than 200 pmol g^–1 tissue. Using this method, we report evidence that NO production in vivo can be inhibited by adriamycin in mice livers.     

Photogeneration of superoxide by adriamycin and daunomycin. An electron spin resonance and spin trapping study

The hydroxyl and superoxide anion spin adducts of DMPO and 4-MePyBN, respectively, were obtained during photoirradiation of adriamycin and daunomycin solutions with visible light. Ethanol and dimethyl sulfoxide did not scavenge hydroxyl radicals in the photoirradiated drug solutions. Furthermore, the hydroxyl-DMPO spin adduct is not formed in the photolysis of air-free drug solutions, indicating that hydroxyl radicals are not directly produced in the photochemical reactions. Instead, the observed hydroxyl-DMPO is formed from the decay of the superoxide anion-DMPO spin adduct. The mechanism for generating the superoxide anion radical appears to be a direct electron transfer from the photoexcited adriamycin and daunomycin to dissolved oxygen.     

EPR spin trapping of an oxalate-derived free radical in the oxalate decarboxylase reaction

EPR spin trapping experiments on bacterial oxalate decarboxylase from Bacillus subtilis under turn-over conditions are described. The use of doubly (13)C-labeled oxalate leads to a characteristic splitting of the observed radical adducts using the spin trap N-tert-butyl-α-phenylnitrone linking them directly to the substrate. The radical was identified as the carbon dioxide radical anion which is a key intermediate in the hypothetical reaction mechanism of both decarboxylase and oxidase activities. X-ray crystallography had identified a flexible loop, SENS161-4, which acts as a lid to the putative active site. Site directed mutagenesis of the hinge amino acids, S161 and T165 was explored and showed increased radical trapping yields compared to the wild type. In particular, T165V shows approximately ten times higher radical yields while at the same time its decarboxylase activity was reduced by about a factor of ten. This mutant lacks a critical H-bond between T165 and R92 resulting in compromised control over its radical chemistry allowing the radical intermediate to leak into the surrounding solution.     

Vanadyl-induced Fenton-like reaction in RNA. An ESR and spin trapping study.

Vanadyl (VO2+) complexed to RNA reacts with hydrogen peroxide in a Fenton-like manner producing hydroxyl radicals (.OH). The hydroxyl radicals can be spin trapped with 5,5-dimethyl-1-pyrroline-1-oxide (DMPO) forming the DMPO-OH spin adduct. In addition, in the presence of ethanol the formation of the hydroxyethyl radical adduct of DMPO (DMPO-ETOH) confirms the production of hydroxyl radicals by the RNA/VO2+ complex. When the reaction between the RNA/VO2+ complex and H2O2 is carried out in the presence of the spin trap 2-methyl-2-nitrosopropane (MNP), radicals produced in the reaction of .OH with RNA are trapped. Base hydrolysis of the MNP-RNA adducts (pH 12) followed by a reduction in the pH to pH 7 after hydrolysis is complete, yields an MNP adduct with a well-resolved ESR spectrum identical to the ESR spectrum obtained from analogous experiments with poly U. The ESR spectrum consists of a triplet of sextets (aN = 1.48 mT, a beta N = 0.25 mT and a beta H = 0.14 mT), indicating that the unpaired nitroxide electron interacts with the nuclei of a beta-nitrogen and beta-hydrogen. The results suggest that the .OH generated in the RNA/VO2+ reaction with H2O2 add to the C(5) carbon of uracil forming a C(6) carbon centered radical. This radical is subsequently spin trapped by MNP.     

A comparative study of EPR spin trapping and cytochrome c reduction techniques for the measurement of superoxide anions

Superoxide anions (O₂^.−) generated by the reaction of xanthine with xanthine oxidase were measured by the reduction of cytochrome c and by electron paramagnetic resonance (EPR) spectroscopy using the spin trap 5,5-dimethyl-1-pyrroline-N-oxide (DMPO). Studies were performed to determine the relative sensitivities of these two techniques for the measurement of O₂^.−. Mixtures of xanthine, xanthine oxidase, DMPO generated two adducts, a transient DMPO-OOH and a smaller but longer-lived DMPO-OH. Both adducts were inhibited by superoxide dismutase (SOD), demonstrating they originated from O₂^.−, and were also significantly decreased when the experiments were performed using unchelated buffers, suggesting that metal ion impurities in unchelated buffers alter the formation or degradation of DMPO-adducts. O₂^.−, generated by concentrations of xanthine as low as 0.05 μM, were detectable using EPR spin trapping. In contrast, mixtures of xanthine, xanthine oxidase, and cytochrome c measured spectrophotometrically at 550 nm demonstrated that concentrations of xanthine above 1 μM were required to produce measurable levels of reduced cytochrome c. These studies demonstrate that spin trapping using DMPO was at least 20-fold more sensitive than the reduction of cytochrome c for the measurement of superoxide anions. However, at levels of superoxide generation where cytochrome c provides a linear measurement of production, EPR spin trapping may underestimate radical production, probably due to degradation of DMPO radical adducts.     

Improvement of the sensitivity of EPR spin trapping in biological systems by cyclodextrins: A model study with thylakoids and photosystem II particles

Electron paramagnetic resonance (EPR) spin trapping spectroscopy is an important method used in free radical research; however, its application in biological systems is hindered by EPR silencing of spin adducts. Previous studies in superoxide-generating chemical systems have shown that spin adducts can be partially stabilized by cyclodextrins. In this work, for the first time, this proposed protective effect of cyclodextrins is investigated in a real biological sample—in isolated thylakoid membranes and photosystem II (PSII) particles with EMPO as a spin trap. It is shown that (i) randomly methylated β-cyclodextrin and 2-hydroxypropyl-β-cyclodextrin form inclusion complexes with EMPO–superoxide adducts (EMPO-OOH), (ii) both cyclodextrins increase the intensity of the EMPO-OOH EPR signal in PSII particles up to five times, (iii) higher EMPO-OOH EPR signal intensity is a result of increased stability of EMPO-OOH, and (iv) the extent of the protection of EMPO-OOH adduct provided by cyclodextrins is different in thylakoids and PSII particles. Along with the spin trapping data, the toxicity of cyclodextrins is also discussed with particular focus on photosynthetic preparations. The presented data show that both tested cyclodextrins can be used as valuable tools to improve the sensitivity of spin trapping in biological samples.     

Visible-light-induced OH radicals in DNA-proflavine complexes: an e.p.r. and spin trapping study

Using the spin-trapping technique, irradiation with visible light of complexes between DNA and proflavine was shown to generate OH radicals. The characteristic spectra were not obtained when proflavine or DNA were irradiated alone, nor when oxygen was absent. Using DMPO as a spin trap we found that the intensity of the DMPO-OH e.p.r. signal was enhanced when the molar ratio between bound proflavine and the DNA phosphorus increased up to a value of 0.15 demonstrating the efficiency of the intercalated dye molecules. A strong decrease of the e.p.r. signal was observed in the presence of various OH. scavengers like t-butanol, isopropanol or sodium benzoate. The OH. production was also decreased when the irradiation was made in the presence of SOD, ceruloplasmin or catalase and after addition of Chelex 100 resin.     

Persistent free radicals in woodsmoke: an ESR spin trapping study

Free radicals are detected in the gas-phase smoke resulting from the combustion of wood using the electron spin resonance (ESR) spin trapping method. The materials were pyrolyzed by rapid heating in a quartz tube in a flowing air stream. The filtered smoke was bubbled into a dodecane solution of alpha-phenyl-N-tert-butyl nitrone, and the resulting nitroxide radicals were detected by ESR. The radicals spin trapped from woodsmoke are compared to those we have spin trapped from tobacco smoke; the smoke from both yellow pine and oak produce more intense ESR spectra than does tobacco smoke per unit mass burned under the conditions of these experiments. When woodsmoke is bubbled through pure dodecane and the resulting woodsmoke/dodecane solution is held for a delay time before the PBN is added, radicals are detected even after the woodsmoke/dodecane solution is aged for more than 20 min. Similar experiments with tobacco smoke show that radicals no longer are trapped even after much shorter delay times from tobacco smoke/dodecane solutions.