Time window of nitroxide effect on myocardial ischemic-reperfusion injury potentiated by iron

Transition metals such as iron and copper potentiate the postischemic reperfusion (I/R) injury induced by oxygen-derived radical and nonradical toxic species (ROS). Various natural and synthetic antioxidants have been previously tested to ameliorate such injury, yet the limitations of the common antioxidants are well known. An alternative strategy for combating oxidative damage is presented wherein cell-permeable, nitroxide stable radicals, which act as SOD-mimics and oxidize reduced metals thus prompting the Fenton-like chemistry, are investigated for utility in ameliorating I/R injury. Our study concentrates on the early effect of nitroxide on the myocardial I/R injury. Isolated rat hearts in the Langendorff configuration were equilibrated with Krebs-Henseleit buffer and then subjected to 18 min of normothermic global ischemia followed by 20 min reperfusion. Iron administered as Fe(III)-citrate (10 microM) did not affect the cardiac function under normoxia but did potentiate I/R injury and decreased the recovery during reperfusion. The iron-induced damage was manifested by further deterioration of the cardiac hemodynamic function and the energy status as reflected by decreased tissue level of phosphorylated nucleotides. Nitroxide at 200 microM protected against the iron-potentiated I/R injury by improving the recovery of the hemodynamic function and the cardiac energy status. Exogenously added iron requires bioreduction to form deleterious Fe(II) bound to critical cellular sites. The nitroxide, which enters the cell and oxidizes the reduced metal instantaneously, provided protection even when administered 2 or 3.5, but not 5 min, after the onset of reperfusion. Thus, its narrow therapeutic time window provides insight into the schedule of the I/R injurious process.     

Stable Nitroxide Radicals Protect Lipid Acyl Chains From Radiation Damage

The present study focused on protective activity of two six-membered-ring nitroxide radicals, 2,2,6,6-tetramethylpiperidine-1-oxyl (Tempo) and 4-hydroxy-Tempo (Tempol), against radiation damage to acyl chain residues of egg phosphatidylcholine (EPC) of small unilamellar vesicles (SUV). SUV were -irradiated (10–12 kGy) under air at ambient temperature in the absence and presence of nitroxides. Acyl chain composition of the phospholipids before and after irradiation was determined by gas chromatography. Both Tempo and Tempol effectively and similarly protected the acyl chains of EPC SUV, including the highly sensitive polyunsaturated acyl chains, C20:4, C22:5, and C22:6. The conclusions of the study are: (a) The higher the degree of unsaturation in the acyl chain, the greater is the degradation caused by irradiation. (b) The fully saturated fatty acids palmitic acid (C16) and stearic acid (C18) showed no significant change in their levels. (c) Both Tempo and Tempol provided similar protection to acyl chain residues. (d) Nitroxides' lipid-bilayer/aqueous distribution is not validly represented by their n-octanol/saline partition coefficient. (e) The lipid-bilayer/aqueous partition coefficient of Tempo and Tempol cannot be correlated with their protective effect. (f) The nitroxides appear to protect via a catalytic mode. Unlike common antioxidants, such as -tocopherol, which are consumed under irradiation and are, therefore, less effective against high radiation dose, nitroxide radicals are restored and terminate radical chain reactions in a catalytic manner. Furthermore, nitroxides neither yield secondary radicals upon their reaction with radicals nor act as prooxidants. Not only are nitroxides self-replenished, but also their reduction products are effective antioxidants. Therefore, the use of nitroxides offers a powerful strategy to protect liposomes, membranes, and other lipid-based assemblies from radiation damage. © 1997 Elsevier Science Inc.     

Mechanisms underlying gastric antiulcerative activity of nitroxides in rats

Reactive oxygen-derived species and redox-active metals are implicated in mediation of the pathogenesis of gastric mucosal damage and ulceration. Therefore, common strategies of intervention employ metal chelators, antioxidative enzymes, and low-molecular-weight antioxidants (LMWA). The aim of the present study was to elaborate the mechanism(s) responsible for the protection provided by nitroxide radicals in the experimental model of gastric ulceration. Fasted male rats were treated ig with 1 ml 96% ethanol, with or without ig pretreatment with nitroxide or hydroxylamine. In several experiments, rats were injected ip or iv with iron(III) or iron(II) prior to ethanol administration. Rats were sacrificed 10 min after ethanol administration, the stomach was removed, washed and lesion area measured. Pretreatment with iron(III) complexed to nitrilotriacetate or citrate, aggravated the extent of the gastric injury. Conversely, iron(II) inhibited the formation of lesions. The nitroxides were rapidly reduced to their respective hydroxylamines and demonstrated antiulcerative activity for rats treated with iron. However, injecting the hydroxylamine resulted in a similar tissue distribution of nitroxide/hydroxylamnine but did not provide protection. The results show that: (a) the nitroxide radicals, rather than their respective non-radical reduced form, are the active species responsible for protection; (b) nitroxides protect by dismutating O2*- and possibly indirectly increasing the NO level; (c) unlike classical LMWA which are reducing agents, nitroxides inhibit gastric damage by acting as mild oxidants, oxidizing reduced metals and pre-empting the Fenton reaction; and (d) the nitroxides act catalytically as recycling antioxidants.     

Up-regulation of A1M/α1-microglobulin in skin by heme and reactive oxygen species gives protection from oxidative damage

During bleeding the skin is subjected to oxidative insults from free heme and radicals, generated from extracellular hemoglobin. The lipocalin α₁-microglobulin (A1M) was recently shown to have reductase properties, reducing heme-proteins and other substrates, and to scavenge heme and radicals. We investigated the expression and localization of A1M in skin and the possible role of A1M in the protection of skin tissue from damage induced by heme and reactive oxygen species. Skin explants, keratinocyte cultures and purified collagen I were exposed to heme, reactive oxygen species, and/or A1M and investigated by biochemical methods and electron microscopy. The results demonstrate that A1M is localized ubiquitously in the dermal and epidermal layers, and that the A1M-gene is expressed in keratinocytes and up-regulated after exposure to heme and reactive oxygen species. A1M inhibited the heme- and reactive oxygen species-induced ultrastructural damage, up-regulation of antioxidation and cell cycle regulatory genes, and protein carbonyl formation in skin and keratinocytes. Finally, A1M bound to purified collagen I (K_d = 0.96×10⁻⁶ M) and could inhibit and repair the destruction of collagen fibrils by heme and reactive oxygen species. The results suggest that A1M may have a physiological role in protection of skin cells and matrix against oxidative damage following bleeding.     

Mechanisms underlying gastric antiulcerative activity of nitroxides in rats

Reactive oxygen-derived species and redox-active metals are implicated in mediation of the pathogenesis of gastric mucosal damage and ulceration. Therefore, common strategies of intervention employ metal chelators, antioxidative enzymes, and low-molecular-weight antioxidants (LMWA). The aim of the present study was to elaborate the mechanism(s) responsible for the protection provided by nitroxide radicals in the experimental model of gastric ulceration.

Fasted male rats were treated ig with 1 ml 96% ethanol, with or without ig pretreatment with nitroxide or hydroxylamine. In several experiments, rats were injected ip or iv with iron(III) or iron(II) prior to ethanol administration. Rats were sacrificed 10 min after ethanol administration, the stomach was removed, washed and lesion area measured. Pretreatment with iron(III) complexed to nitrilotriacetate or citrate, aggravated the extent of the gastric injury. Conversely, iron(III) inhibited the formation of lesions. The nitroxides were rapidly reduced to their respective hydroxylamines and demonstrated antiulcerative activity for rats treated with iron. However, injecting the hydroxylamine resulted in a similar tissue distribution of nitroxide/hydroxylamine but did not provide protection.

The results show that: (a) the nitroxide radicals, rather than their respective non-radical reduced form, are the active species responsible for protection; (b) nitroxides protect by dismutating O^·-₂ and possibly indirectly increasing the NO level; (c) unlike classical LMWA which are reducing agents, nitroxides inhibit gastric damage by acting as mild oxidants, oxidizing reduced metals and pre-empting the Fenton reaction; and (d) the nitroxides act catalytically as recycling antioxidants.     

Dual activity of nitroxides as pro- and antioxidants: catalysis of copper-mediated DNA breakage and H2O2 dismutation

Nitroxide antioxidants can be reduced to hydroxylamines or oxidized to oxoammonium cations. Consequently, nitroxides can modify oxidative damage acting as reducing and/or as oxidizing agents, and in many cases the nitroxides are continuously recycled. They provide protection against oxidative stress via various mechanisms including SOD-mimic activity and detoxification of carbon-, oxygen-, and nitrogen-centered radicals, as well as oxidation of reduced transition metals. In contrast to the common concept, according to which the nitroxides' protective effect takes place via inhibition of the Fenton reaction, there are observations suggesting the opposite. In the present investigation, DNA breakage catalyzed by copper served as an experimental model for studying the anti- and pro-oxidative activity of nitroxides. Nitroxides provided protection in the presence of GSH, which is known to facilitate metal-catalyzed DNA damage. In the absence of a reductant, nitroxides enhanced DNA breakage under aerobic conditions with or without added H(2)O(2) and facilitated H(2)O(2) depletion. The rates of nitroxide-catalyzed DNA breakage and H(2)O(2) depletion increased as the concentrations of copper, H(2)O(2), and nitroxide increased. Although the catalytic activity of nitroxides is low, it is sufficient to induce DNA breakage. The efficacy of DNA breakage by the tested piperidine nitroxides correlated with the nitroxide-induced depletion of H(2)O(2) with the exception of the pyrrolidine nitroxide 3-carbamoylproxyl. The results suggest that the nitroxide and the copper are continuously recycled while catalyzing DNA breakage and depletion of H(2)O(2), which serves both as a source of reducing equivalents and as the electron sink.     

Oxygen radicals stimulate intracellular proteolysis and lipid peroxidation by independent mechanisms in erythrocytes

Exposure of red blood cells to oxygen radicals can induce hemoglobin damage and stimulate protein degradation, lipid peroxidation, and hemolysis. To determine if these events are linked, rabbit erythrocytes were incubated at 37 degrees C with various oxygen radical-generating systems and antioxidants. Protein degradation, measured by the production of free alanine, increased more than 11-fold in response to xanthine (X) + xanthine oxidase (XO). A similar increase in proteolysis occurred when the cells were incubated with acetaldehyde plus XO, with ascorbic acid plus iron (Asc + Fe), or with hydrogen peroxide (H2O2) alone. Upon addition of XO, increased proteolysis was evident within 5 min and was linear for up to 5 h. In contrast, lipid peroxidation, as shown by the production of malonyldialdehyde, conjugated dienes, or lipid hydroperoxides was observed only after 2 h of incubation with X + XO, acetaldehyde + XO, or H2O2. Ascorbate plus Fe2+ induced both protein degradation and lipid peroxidation; however, the addition of various antioxidants (urate, xanthine, glucose, or butylated hydroxytoluene) decreased lipid peroxidation without affecting proteolysis. Thus, these processes seem to occur by distinct mechanisms. Furthermore, at low concentrations of XO, protein degradation was clearly increased in the absence of detectable lipid peroxidation products. Hemolysis occurred only in a small number of cells (9%) and followed the appearance of lipid peroxidation products. Thus, an important response of red cells to oxygen radicals is rapid degradation of damaged cell proteins. Increased proteolysis seems to occur independently of membrane damage and to be a more sensitive indicator of cell exposure to oxygen radicals than is lipid peroxidation.     

Nitroxides inhibit peroxyl radical-mediated DNA scission and enzyme inactivation

Nitroxides are cell-permeable stable radicals that protect biomolecules from oxidative damage in several ways. The mechanisms of protection studied to date include removal of superoxide radicals as SOD-mimics, oxidation of transition metal ions to preempt the Fenton reaction, and scavenging carbon-centered radicals. However, there is no agreement regarding the reaction of piperidine nitroxides with peroxyl radicals. The question of whether they can protect by scavenging peroxyl radicals is important because these radicals are formed in the presence of oxygen abundant in biological tissues. To further our understanding of the antioxidative behavior of piperidine nitroxides, we studied their effect on biochemical systems exposed to the water soluble radical initiator 2,2'-azobis (2-amidinopropane) hydrochloride (AAPH). AAPH thermally decomposes to yield tert-amidinopropane radicals (t-AP(*)) that readily react with oxygen to form peroxyl radicals (t-APOO(*)). It has recently been reported that piperidine nitroxides protect plasmid DNA from t-AP(*) though not from t-APOO(*). The present study was directed at the question of whether these nitroxides can protect biological systems from damage inflicted by peroxyl radicals. The reaction of nitroxides with AAPH-derived radicals was followed by cyclic voltammetry and electron paramagnetic resonance spectroscopy, whereas the accumulation of peroxide was iodometrically assayed. Assaying DNA damage in vitro, we demonstrate that piperidine nitroxides protect from both t-AP(*) and t-APOO(*). Similarly, nitroxides inhibit AAPH-induced enzyme inactivation. The results indicate that piperidine nitroxides protect the target molecule by reacting with and detoxifying peroxyl radicals.     

γ-Irradiation Damage to Liposomes Differing in Composition and Their Protection by Nitroxides

The present study aims to determine the effect of bilayer composition on oxidative damage and the protection against it in lipid multicomponent membranes. Irradiation damage in 200-nm liposomes and the protection provided by the nitroxide radicals, 2,2,6,6-tetramethylpiperidine-1-oxyl (Tempo) and 4-hydroxy-2,2,6,6-tetramethylpiperidine-1-oxyl (Tempol) were assessed by monitoring several chemical and physical parameters. Liposomes were prepared in four different lipid compositions (mole ratios), DPPC:DPPG 10:1; DPPC:DPPG:cholesterol 10:1:4; EPC:EPG 10:1; and EPC:EPG:cholesterol 10:1:4, and γ-irradiated with a dose of 32 kGy. Lipid degradation was determined by HPLC and GC analyses, whereas size and differential scanning calorimetry measurements were used to monitor physical changes in the liposomal dispersions. The results indicate that: (1) addition of 5 mM Tempo or Tempol, or freezing of the sample inhibited radiation-induced lipid degradation; (2) Tempo and Tempol caused neither physical nor chemical changes in the liposomal dispersions; and (3) both nitroxides prevented or reduced some of the radiation-induced changes in thermotropic characteristics of the liposomes, preventing a shift in the temperature of the maximum of the main phase transition (T_m).     

Ex vivo Assessment of Lymphocyte Antioxidant Status Using the Comet Assay

Lymphocytes were isolated from volunteers before and after receiving a single supplement of vitamin C, vitamin E or β-carotene. The lymphocytes were treated with H₂O₂, and DNA strand breaks were measured by single cell gel electrophoresis (the comet assay). Significant protection against oxidative DNA damage was evident 2-4 h after vitamin C intake, and 18-24 h after consumption of the other antioxidants. Lymphocytes from smokers were more sensitive to DNA damage than those from non-smokers, and they showed at least as great a protective effect with antioxidants.     

Ex vivo Assessment of Lymphocyte Antioxidant Status Using the Comet Assay

Lymphocytes were isolated from volunteers before and after receiving a single supplement of vitamin C, vitamin E or β-carotene. The lymphocytes were treated with H₂O₂, and DNA strand breaks were measured by single cell gel electrophoresis (the comet assay). Significant protection against oxidative DNA damage was evident 2–4 h after vitamin C intake, and 18–24 h after consumption of the other antioxidants. Lymphocytes from smokers were more sensitive to DNA damage than those from non-smokers, and they showed at least as great a protective effect with antioxidants.     

Do stable nitroxide radicals catalyze or inhibit the degradation of hyaluronic acid?

Reactive oxygen-derived species and particularly OH radicals can degrade hyaluronic acid (HA), resulting in a loss of viscosity and a subsequent decrease in its effectiveness as a joint-lubricating agent. The production of OH in the vicinity of HA can be catalyzed by bound redox-active metals, which participate in the Haber-Weiss reaction. Damage to HA can also occur as a result of hypochlorite formed by myeloperoxidase (MPO). The protective reagents commonly used to inhibit oxidative stress-induced degradation of HA include antioxidative enzymes, such as SOD and catalase, chelators that coordinate metal ions rendering them redox-inactive, and scavengers of radicals, such as OH, as well as nonradical reactive species. In recent years, stable cyclic nitroxides have also been widely used as effective antioxidants. In many cases, nitroxide antioxidants operate catalytically and mediate their protective effect through an exchange between their oxidized and reduced forms. It was anticipated, therefore, that nitroxides would protect HA from oxidative degradation as well. On the other hand, nitroxides serve as catalysts in many oxidation reactions of alcohols, sugars and polysaccharides, including hyalouronan. Such opposite effects of nitroxides on oxidative degradation are particularly intriguing and the aim of the present study was to examine their effect on HA when subjected to diverse forms of oxidative stress. The results indicate that nitroxides protect HA from OH radicals generated enzymatically or radiolytically. The protective effect is attributable neither to the scavenging of OH nor to the oxidation of reduced metal, but to the reaction of nitroxides with secondary carbohydrate radicals-most likely peroxyl radicals.     

Reduction of ultraviolet light-induced oxidative stress by amino acid-based iron chelators

The generation of free radicals by ultraviolet (UV) light accelerates skin aging, which is known as photoaging. Cutaneous iron catalyzes the generation of free radicals. We designed novel antioxidants that suppressed the iron-catalyzed free radical generation and the ensuing UV-induced damage by mimicking the binding site of iron sequestering proteins. These antioxidants, N-(2-hydroxybenzyl)amino acids, were prepared by condensation of amino acids such as glycine and L-serine with salicylaldehyde and followed by catalytic reduction. The compounds formed a 2:1 complex to iron ion. These amino acid derivatives inhibited the iron-induced hydroxyl radical generation (the Fenton reaction). The compounds also suppressed UV-induced lipid peroxidation in murine dermal fibroblast homogenates. In addition, N-(2-hydroxybenzyl)-L-serine showed protective activity against UV-induced cytotoxicity in murine dermal fibroblasts. Desferrioxamine, a strong iron sequestering compound, was effective in inhibiting the Fenton reaction and the lipid peroxidation, but it was ineffective in protecting against UV-induced cytotoxicity. The results suggest that UV-induced oxidative stress can be reduced by these amino acid derivatives.     

Olive phenols efficiently inhibit the oxidation of serum albumin-bound linoleic acid and butyrylcholine esterase

Background

Olive phenols are widely consumed in the Mediterranean diet and can be detected in human plasma. Here, the capacity of olive phenols and plasma metabolites to inhibit lipid and protein oxidations is investigated in two plasma models.

Methods

The accumulation of lipid oxidation products issued from the oxidation of linoleic acid bound to human serum albumin (HSA) by AAPH-derived peroxyl radicals is evaluated in the presence and absence of phenolic antioxidants. Phenol binding to HSA is addressed by quenching of the Trp214 fluorescence and displacement of probes (quercetin, dansylsarcosine and dansylamide). Next, the esterase activity of HSA-bound butyrylcholine esterase (BChE) is used as a marker of protein oxidative degradation.

Results

Hydroxytyrosol, oleuropein, caffeic and chlorogenic acids inhibit lipid peroxidation as well as HSA-bound BChE as efficiently as the potent flavonol quercetin. Hydroxycinnamic derivatives bind noncompetitively HSA subdomain IIA whereas no clear site could be identified for hydroxytyrosol derivatives.

General significance

In both models, olive phenols and their metabolites are much more efficient inhibitors of lipid and protein oxidations compared to vitamins C and E. Low postprandial concentrations of olive phenols may help to preserve the integrity of functional proteins and delay the appearance of toxic lipid oxidation products.     

Hyperbaric oxygen preconditioning protects skin from UV-A damage

Hyperbaric oxygen therapy (HBOT) is used for a number of applications, including the treatment of diabetic foot ulcers and CO poisoning. However, we and others have shown that HBOT can mobilize cellular antioxidant defenses, suggesting that it may also be useful under circumstances in which tissue protection from oxidative damage is desired. To test the protective properties of hyperbaric oxygen (HBO) on a tissue level, we evaluated the ability of a preconditioning treatment regimen to protect cutaneous tissue from UV-A-induced oxidative damage. Three groups of hairless SKH1-E mice were exposed to UV-A 3 days per week for 22 weeks, with two of these groups receiving an HBO pretreatment either two or four times per week. UV-A exposure increased apoptosis and proliferation of the skin tissue, indicating elevated levels of epithelial damage and repair. Pretreatment with HBO significantly reduced UV-A-induced apoptosis and proliferation. A morphometric analysis of microscopic tissue folds also showed a significant increase in skin creasing following UV-A exposure, which was prevented by HBO pretreatment. Likewise, skin elasticity was found to be greatest in the group treated with HBO four times per week. The effects of HBO were also apparent systemically as reductions in caspase-3 activity and expression were observed in the liver. Our findings support a protective function of HBO pretreatment from a direct oxidative challenge of UV-A to skin tissue. Similar protection of other tissues may likewise be achievable.     

Zeaxanthin in combination with ascorbic acid or alpha-tocopherol protects ARPE-19 cells against photosensitized peroxidation of lipids

The antioxidant action of carotenoids is believed to involve quenching of singlet oxygen and scavenging of reactive oxygen radicals. However, the exact mechanism by which carotenoids protect cells against oxidative damage, particularly in the presence of other antioxidants, remains to be elucidated. This study was carried out to examine the ability of exogenous zeaxanthin alone and in combination with vitamin E or C, to protect cultured human retinal pigment epithelium cells against oxidative stress. The survival of ARPE-19 cells, subjected to merocyanine 540-mediated photodynamic action, was determined by the MTT test and the content of lipid hydroperoxides in photosensitized cells was analyzed by HPLC with electrochemical detection. We found that zeaxanthin-supplemented cells, in the presence of either alpha-tocopherol or ascorbic acid, were significantly more resistant to photoinduced oxidative stress. Cells with added antioxidants exhibited increased viability and accumulated less lipid hydroperoxides than cells without the antioxidant supplementation. Such a synergistic action of zeaxanthin and vitamin E or C indicates the importance of the antioxidant interaction in efficient protection of cell membranes against oxidative damage induced by photosensitized reactions.     

Protective Effect of Cannabidiol on Hydrogen Peroxide-Induced Oxidative Damage in Human Umbilical Vein Endothelial Cells (HUVECs)

Natural antioxidants play an important role in promoting good health because of their prevention for oxidative damage. The work aimed to explore the antioxidant mechanism and activity of cannabidiol (CBD) at the cellular level. The human umbilical vein endothelial cell (HUVEC) with oxidative damage was employed as the model to study the protective capability of CBD. The results showed that CBD pre-treatment before the cells were exposed to hydrogen peroxide (H₂O₂) resulted in an obvious increase of cell viability (about 100 %) and antioxidant related enzymes activity, and a decline of malondialdehyde (MDA) level. Besides, CBD could alleviate the increase of intracellular reactive oxygen species (ROS) content, the contraction of nucleus, and condensation of chromatin. The changes showed a dose-dependent effect. Additionally, the free radicals scavenging capacity of CBD was comparable to that of typical natural antioxidant, anthocyanidins. In summary, CBD could be employed as a potent antioxidant source for avoiding the oxidative damage. These results could provide the foundation for the development of CBD antioxidant products.     

Effect of natural exogenous antioxidants on aging and on neurodegenerative diseases

Abstract

Aging and neurodegenerative diseases share oxidative stress cell damage and depletion of endogenous antioxidants as mechanisms of injury, phenomena that are occurring at different rates in each process. Nevertheless, as the central nervous system (CNS) consists largely of lipids and has a poor catalase activity, a low amount of superoxide dismutase and is rich in iron, its cellular components are damaged easily by overproduction of free radicals in any of these physiological or pathological conditions. Thus, antioxidants are needed to prevent the formation and to oppose the free radicals damage to DNA, lipids, proteins, and other biomolecules. Due to endogenous antioxidant defenses are inadequate to prevent damage completely, different efforts have been undertaken in order to increase the use of natural antioxidants and to develop antioxidants that might ameliorate neural injury by oxidative stress. In this context, natural antioxidants like flavonoids (quercetin, curcumin, luteolin and catechins), magnolol and honokiol are showing to be the efficient inhibitors of the oxidative process and seem to be a better therapeutic option than the traditional ones (vitamins C and E, and β-carotene) in various models of aging and injury in vitro and in vivo conditions. Thus, the goal of the present review is to discuss the molecular basis, mechanisms of action, functions, and targets of flavonoids, magnolol, honokiol and traditional antioxidants with the aim of obtaining better results when they are prescribed on aging and neurodegenerative diseases.     

Oxidant-induced haemoprotein degradation in rat tissue slices: effect of bromotrichloromethane, antioxidants and chelators

Haemoprotein degradation and lipid peroxidation were evaluated in rat liver, kidney and heart slices incubated for 2 h in the presence and absence of bromotrichloromethane, antioxidants and chelators to obtain information about the relationship between oxidants and damage to haemoproteins. Haemoproteins were modified by bromotrichloromethane, and this modification, measured as loss of ferrohaemoproteins, generally was concurrent with lipid peroxidation measured as thiobarbituric acid-reactive substances. These two processes occurred simultaneously as a function of incubation time and oxidant concentration. Inhibition of the two processes by nordihydroguaiaretic acid, butylated hydroxyanisole and Trolox C, and lack of inhibition by mannitol, catalase and superoxide dismutase also were coincident. However, Methylene blue, EDTA, sodium fluoride, 2,4-dinitrophenol, N-ethylmaleimide and o-phenanthroline affected the two processes differently. The results suggested that haemoproteins may compete with other molecules for oxidant radicals, thus serving as protectors of cells against oxidant radicals. Products of haemoprotein degradation such as protein polymers, free amino acids and bilirubin may be indicators of in vivo oxidative stress.     

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

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