Inhibition of the metmyoglobin-induced peroxidation of linoleic acid by dietary antioxidants: Action in the aqueous vs. lipid phase

The gastric digestion of food containing oxidizable lipids and iron catalysts for peroxide decomposition such as (met)myoglobin from muscle meat can be accompanied by an extensive formation of potentially toxic lipid hydroperoxides. An early protective action by dietary antioxidants in the gastro-intestinal tract is plausible, especially for poorly bioavailable antioxidants such as polyphenols. Hence, the ability of antioxidants to inhibit lipid peroxidation initiated by dietary iron in mildly acidic emulsions is a valuable and general model. In this work, the ability of some ubiquitous dietary antioxidants representative of the main antioxidant classes (alpha-tocopherol, the flavonol quercetin, beta-carotene) to inhibit the metmyoglobin-induced peroxidation of linoleic acid is investigated by UV-visible spectroscopy and HPLC in mildly acidic emulsions. The phenolic antioxidants quercetin and alpha-tocopherol come up as the most efficient peroxidation inhibitors. Inhibition by quercetin essentially proceeds in the aqueous phase via a fast reduction of an unidentified activated iron species (with a partially degraded heme) produced by reaction of metmyoglobin with the lipid hydroperoxides. This reaction is faster by, at least, a factor 40 than the reduction of ferrylmyoglobin (independently prepared by reacting metmyoglobin with hydrogen peroxide) by quercetin. By contrast, alpha-tocopherol mainly acts in the lipid phase by reducing the propagating lipid peroxyl radicals. The poorer inhibition afforded by beta-carotene may be related to both its slower reaction with the lipid peroxyl radicals and its competitive degradation by autoxidation and/or photo-oxidation.     

Redox cycling of myoglobin and ascorbate: a potential protective mechanism against oxidative reperfusion injury in muscle

Metmyoglobin catalyzes the decomposition of H2O2 as well as other hydroperoxides by using ascorbic acid as a substrate. The ratio of H2O2 reduced to ascorbate oxidized is close to one, whereas the rate of oxidation is directly proportional to both H2O2 and metmyoglobin concentrations. Ascorbate also prevents the protein modifications and the O2 evolution that accompany the reaction of metmyoglobin with hydroperoxides. In the absence of ascorbate, myoglobin and H2O2 promote the peroxidation of unsaturated fatty acids and, thus, may cause damage to cellular constituents. However, lipid peroxidation is inhibited in the presence of ascorbate and, for this reason, it is suggested that this heme protein functions in the opposite manner. The redox cycling of myoglobin by ascorbate may act as an important electron "sink" and defense mechanism against peroxides during oxidative challenge to muscle.     

Metmyoglobin promotes arachidonic acid peroxidation at acid pH

The ability of metmyoglobin and other heme proteins to promote peroxidation of arachidonic acid under acidic conditions was investigated. Incubation of metmyoglobin with arachidonic acid resulted in a pH-dependent increase in lipid peroxidation as measured by the formation of thiobarbituric acid reactive products and oxygen consumption. Increased peroxidation was observed at pH levels below 6.0, reaching a plateau between pH 5.5 and 5.0. At comparable heme concentrations, metmyoglobin was more efficient than oxymyoglobin, methemoglobin, or ferricytochrome c in promoting arachidonic acid peroxidation. Metmyoglobin also promoted peroxidation of 1-palmityl-2-arachidonyl phosphatidylcholine and methylarachidonate but at significantly lower rates than arachidonic acid. Addition of fatty acid-free albumin inhibited arachidonic acid peroxidation in a molar ratio of 6 to 1 (arachidonic acid:albumin). Both ionic and non-ionic detergents inhibited metmyoglobin-dependent arachidonic acid peroxidation under acidic conditions. The anti-oxidants butylated hydroxytoluene and nordihydroguaiaretic acid and low molecular weight compounds with reduced sulfhydryl groups inhibited the reaction. However, mannitol, benzoic acid, and deferoxamine were without significant effect. Visible absorption spectra of metmyoglobin following reaction with arachidonic acid showed minimal changes consistent with a low level of degradation of the heme protein during the reaction. These observations support the hypothesis that metmyoglobin and other heme proteins can promote significant peroxidation of unsaturated fatty acids under conditions of mildly acidic pH such as may occur at sites of inflammation and during myocardial ischemia and reperfusion. This may be the result of enhanced aggregation of the fatty acid and/or interaction of the fatty acid with heme under acidic conditions.     

Saliva plays a dual role in oxidation process in stomach medium

The aim of this study was to evaluate the role of saliva in the oxidation process under the acidic condition of the stomach. Saliva specimens played varied roles in the lipid peroxidation process of heated muscle tissue in simulated gastric fluid: pro-oxidant effects, no effects, and antioxidant effects. To elucidate these differences, selected saliva components were examined. The pseudoperoxidase activity of lactoperoxidase increased lipid peroxidation, while thiocyanate and nitrite-reduced lipid peroxidation. The effect of a saliva specimen on lipid peroxidation was correlated with the concentration of nitrite in the specimen, but not with that of other saliva components. The inhibitory effect of nitrite may be due to its conversion to NO. Elucidation of the antioxidant effect of saliva on co-oxidation of d-alpha-tocopherol in gastric fluid, demonstrated that saliva alone cannot protect d-alpha-tocopherol from co-oxidation, although it partially protected against lipid peroxidation. The presence of red wine polyphenols in stomach medium totally inhibits food lipid peroxidation and d-alpha-tocopherol co-oxidation.     

Acidic pH amplifies iron-mediated lipid peroxidation in cells

The goal of our study was to investigate the mechanism by which changes in extracellular pH influence lipid peroxidation processes. Ferrous iron can react with hydroperoxides, via a Fenton-type reaction, to initiate free radical chain processes. Iron is more soluble at lower pH values, therefore we hypothesized that decreasing the environmental pH would lead to increased iron-mediated lipid peroxidation. We used Photofrin, a photosensitizer that produces singlet oxygen, to introduce lipid hydroperoxides into leukemia cells (HL-60, K-562, and L1210). Singlet oxygen reacts with the PUFA of cells producing lipid hydroperoxides. Using EPR spin trapping with POBN, free radical formation from HL-60 cells was only detected when Photofrin, light, and ferrous iron were present. Free radical formation increased with increasing iron concentration; in the absence of extracellular iron, radical formation was below the limit of detection and lipid hydroperoxides accumulated in the membrane. In the presence of iron, lipid-derived radical formation in cells is pH dependent; the lower the extracellular pH (7.5-5.5), the higher the free radical flux; the lower the pH, the greater the membrane permeability induced in K-562 cells, as determined by trypan blue dye exclusion. These data demonstrate that lipid peroxidation processes, mediated by iron, are enhanced with decreasing extracellular pH. Thus, acidic pH not only releases iron from "safe" sites, but this iron will also be more damaging.     

Cobaltous ion inhibition of lipid peroxidation in biological membranes.

The effect of cobalt on lipid peroxidation in biological membranes, phospholipid liposomes and fatty acid micelles was investigated. Cobaltous ion, at micromolar concentrations, inhibited iron-ascorbate induced lipid peroxidation in erythrocyte ghosts, microsomes and phosphatidylserine liposomes at pH 7.4. The pH seemed to be important for the anti-peroxidative effect of cobalt, because under slightly acidic conditions cobalt did not inhibit peroxidation. Cobalt was less effective in inhibiting peroxidation stimulated by organic hydroperoxides. Iron-ascorbate induced lipid peroxidation was also inhibited by EDTA. However, certain ratios of EDTA: cobalt in the reaction mixture stimulated peroxidation. Cobalt did not inhibit lipid peroxidation in linoleic acid micelles and phosphatidylethanolamine liposomes. The presence of phosphatidylserine, however, rendered these micelles and liposomes to cobalt inhibition. We conclude that the cobaltous ion is a potent inhibitor of lipid peroxidation in biological membranes and that the binding of cobalt to phosphatidylserine is necessary for the inhibitory effect of this metal ion.     

Oxidation of low density lipoprotein and plasma by 15-lipoxygenase and free radicals

It is generally accepted that the oxidation of pentadiene structures of polyunsaturated lipids by lipoxygenase (LOX) is regio- and enantio-specific, while the free radical-mediated lipid peroxidation gives stereo-random racemic products. It was confirmed that the oxidation of human low density lipoprotein (LDL) by 15-LOX from rabbit reticulocytes gave phosphatidylcholine (PC) and cholesteryl ester (CE) hydroperoxides regio-, stereo- and enantio-specifically. 15-LOX also oxidized human plasma to give specific PC and CE hydroperoxides in spite of the presence of high concentrations of antioxidants. More CE hydroperoxides were formed than PC hydroperoxides from LDL, but the reverse order was observed for plasma oxidation. The S/R ratio of the hydroperoxides decreased during long time incubation but remained significantly larger than one, while free radical-mediated oxidation of LDL and plasma gave racemic products.     

Photocarcinogenesis and diet

Nearly 50 years ago the first reports appeared that cast suspicion on lipids, or peroxidative products thereof, as being involved in the expression of actinically induced cancer. Whereas numerous studies have implicated lipids as potentiators of specific chemical-induced carcinogenesis, only recently has the involvement of these dietary constituents in photocarcinogenesis been substantiated. It has now been demonstrated that both level of dietary lipid intake and degree of lipid saturation have pronounced effects on photoinduced skin cancer, with increasing levels of unsaturated fat intake enhancing cancer expression. The level of intake of these lipids is also manifested in the level of epidermal lipid peroxidation. Conversely, dietary antioxidants inhibit both lipid peroxidation and photocarcinogenesis, the degree of inhibition of the latter being roughly equivalent to the degree of cancer enhancement evoked by the respective level of dietary lipid. The apparent similarities of lipid effects on both chemical and photoinduced carcinogenesis suggest a common underlying role for these dietary constituents in the carcinogenic process. This role may involve free radical-mediated lipid peroxidative reactions. Regardless of the mechanism, it is obvious that both dietary lipid and antioxidants can modify the photocarcinogenic response of skin.     

Susceptibility of plasma lipids to peroxidation

Lipid peroxidation is an old and yet novel subject. It induces membrane disturbance and damage and its products are known to induce the generation of various cytokines and cell signaling. In the present work, the susceptibility and specificity of human plasma lipids to oxidation were studied, aiming specifically at elucidating the effects of oxidation milieu and oxidants. Cholesteryl esters (CEs) and phosphatidylcholines (PCs) were more readily oxidized in plasma than in organic solution under similar conditions. The susceptibilities of PC and free cholesterol (FC) relative to CE to free radical-mediated lipid peroxidation induced by peroxyl radicals and peroxynitrite were smaller in plasma than in organic solution. The higher rate of CE oxidation by free radicals than PC may be accounted for by the physical effects as well as higher content of polyunsaturated lipids in CE than PC. On the contrary, PC was more readily oxidized than CE by lipoxygenases. The lipid hydroperoxides were stable in organic solution but reduced to the corresponding hydroxides in plasma, the rate being much faster for PC hydroperoxides than for CE and FC hydroperoxides. It was confirmed that free radical-mediated oxidation gave both cis,trans and trans,trans, racemic, random hydroperoxides, while that by lipoxygenase gave only regio- and stereo-specific cis,trans-hydroperoxide.     

The influence of phospholipid polar head on the lipid hydroperoxide dependent initiation of lipid peroxidation.

In a buffer (Mes) and at a pH (6.5) where Fe2+ is very stable, we have studied the peroxidation of liposomes catalyzed by FeCl2. The liposomes studied, prepared by sonolysis, contained either phosphatidylcholine or 1:1 molar ratio of phosphatidylcholine and phosphatidic acid. The presence of the negatively charged phospholipid causes: 1) rapid Fe2+ oxidation and oxygen consumption; 2) increased generation of lipid hydroperoxides; 3) decreased generation of thiobarbituric acid-reactive materials; 4) very low inhibition of Fe2+ oxidation and lipid hydroperoxide generation by BHT; 5) inhibition of the termination phase of lipid peroxidation at high FeCl2 concentrations. A hypothesis is proposed to explain the results obtained.     

Leukocytes utilize myeloperoxidase-generated nitrating intermediates as physiological catalysts for the generation of biologically active oxidized lipids and sterols in serum

The initiation of lipid peroxidation and the concomitant formation of biologically active oxidized lipids and sterols is believed to play a central role in the pathogenesis of inflammatory and vascular disorders. Here we explore the role of neutrophil- and myeloperoxidase (MPO)-generated nitrating intermediates as a physiological catalyst for the initiation of lipid peroxidation and the formation of biologically active oxidized lipids and sterols. Activation of human neutrophils in media containing physiologically relevant levels of nitrite (NO(2)(-)), a major end product of nitric oxide (nitrogen monoxide, NO) metabolism, generated an oxidant capable of initiating peroxidation of lipids. Formation of hydroxy- and hydroperoxyoctadecadienoic acids [H(P)ODEs], hydroxy- and hydroperoxyeicosatetraenoic acids [H(P)ETEs], F(2)-isoprostanes, and a variety of oxysterols was confirmed using on-line reverse phase HPLC tandem mass spectrometry (LC/MS/MS). Lipid oxidation by neutrophils required cell activation and NO(2)(-), occurred in the presence of metal chelators and superoxide dismutase, and was inhibited by catalase, heme poisons, and free radical scavengers. LC/MS/MS studies demonstrated formation of additional biologically active lipid and sterol oxidation products known to be enriched in vascular lesions, such as 1-hexadecanoyl-2-oxovalaryl-sn-glycero-3-phosphocholine, which induces upregulation of endothelial cell adhesion and chemoattractant proteins, and 5-cholesten-3beta-ol 7beta-hydroperoxide, a potent cytotoxic oxysterol. In contrast to the oxidant formed during free metal ion-catalyzed reactions, the oxidant formed during MPO-catalyzed oxidation of NO(2)(-) readily promoted lipid peroxidation in the presence of serum constituents. Collectively, these results suggest that phagocytes may employ MPO-generated reactive nitrogen intermediates as a physiological pathway for initiating lipid peroxidation and forming biologically active lipid and sterol oxidation products in vivo.     

Oxidative modification of human low-density lipoprotein by horseradish peroxidase in the absence of hydrogen peroxide

Heme-peroxidases, such as horseradish peroxidase (HRP), are among the most popular catalysts of low density lipoprotein (LDL) peroxidation. In this model system, a suitable oxidant such as H₂O₂ is required to generate the hypervalent iron species able to initiate the peroxidative chain. However, we observed that traces of hydroperoxides present in a fresh solution of linoleic acid can promote lipid peroxidation and apo B oxidation, substituting H₂O₂.

Spectral analysis of HRP showed that an hypervalent iron is generated in the presence of H₂O₂ and peroxidizing linoleic acid. Accordingly, careful reduction of the traces of linoleic acid lipid hydroperoxide prevented formation of the ferryl species in HRP and lipid peroxidation. However, when LDL was oxidized in the presence of HRP, the ferryl form of HRP was not detectable, suggesting a Fenton-like reaction as an alternative mechanism. This was supported by the observation that carbon monoxide, a ligand for the ferrous HRP, completely inhibited peroxidation of LDL.

These results are in agreement with previous studies showing that myoglobin ferryl species is not produced in the presence of phospholipid hydroperoxides, and emphasize the relevance of a Fenton-like chemistry in peroxidation of LDL and indirectly, the role of pre-existing lipid hydroperoxides.     

Lipid peroxidation: mechanisms, inhibition, and biological effects

In the last 50 years, lipid peroxidation has been the subject of extensive studies from the viewpoints of mechanisms, dynamics, product analysis, involvement in diseases, inhibition, and biological signaling. Lipids are oxidized by three distinct mechanisms; enzymatic oxidation, non-enzymatic, free radical-mediated oxidation, and non-enzymatic, non-radical oxidation. Each oxidation mechanism yields specific products. The oxidation of linoleates and cholesterol is discussed in some detail. The relative susceptibilities of lipids to oxidation depend on the reaction milieu as well as their inherent structure. Lipid hydroperoxides are formed as the major primary products, however they are substrates for various enzymes and they also undergo various secondary reactions. Phospholipid hydroperoxides, for example, are reduced to the corresponding hydroxides by selenoproteins in vivo. Various kinds of antioxidants with different functions inhibit lipid peroxidation and the deleterious effects caused by the lipid peroxidation products. Furthermore, the biological role of lipid peroxidation products has recently received a great deal of attention, but its physiological significance must be demonstrated in future studies.     

Antioxidant defenses in rat intestine and mesenteric lymph

Abstract

Dietary oxysterols can reach the circulation and this may contribute to atherosclerosis, where lipid oxidation is thought to be important. There is also evidence that, in rats,peroxidized lipids are absorbed and transported into lymph [Aw TY, Williams MW, Gray L. Absorption and lymphatic transport of peroxidized lipids by rat small intestine in vivo: role of mucosal GSH. Am J Physiol 1992; 262: G99–G106], although the method used to detect lipid peroxides lacked specificity. We tested whether intragastric administration of vegetable oils containing triglyceride hydroperoxides (TG-OOH) to rats resulted in detectable lipid hydroperoxides in mesenteric lymph. Using sensitive HPLC with postcolumn chemiluminescence detection, we were unable to detect hydroperoxides of triglycerides, cholesterylesters or phospholipids during the course of lipid absorption, and lymph levels of ascorbate, urate, α-tocopherol and ubiquinol-9 did not change significantly. By contrast, we observed a striking reducing activity judged by the efficient reduction of administered ubiquinones-9 and -10 to the corresponding ubiquinols. Exposure of rat lymph and isolated chylomicrons to aqueous peroxyl radicals revealed patterns of antioxidant consumption and lipid hydroperoxide formation similar to those described previously for human extravascular fluids and isolated lipoproteins, respectively. In particular, rates of TG-OOH formation in lymph and chylomicrons were very low to undetectable as long as ascorbate and/or ubiquinols were present, but subsequently proceeded in a chain reaction despite the presence of α-tocopherol. These studies demonstrate that rat intestine and mesenteric lymph possess efficient antioxidant defenses against preformed lipid hydroperoxides and (peroxyl) radical mediated lipid oxidation. We conclude that dietary lipid hydroperoxides or postprandial oxidation of lipids are not likely to contribute to these particular forms of oxidized lipids in circulation and aortic tissue.     

The mechanism of NADPH-dependent lipid peroxidation. The propagation of lipid peroxidation.

NADPH-dependent lipid peroxidation occurs in two distinct sequential radical steps. The first step, initiation, is the ADP-perferryl ion-catalyzed formation of low levels of lipid hydroperoxides. The second step, propagation, is the iron-catalyzed breakdown of lipid hydroperoxides formed during initiation generating reactive intermediates and products characteristic of lipid peroxidation. Propagation results in the rapid formation of thiobarbituric acid-reactive material and lipid hydroperoxides. Propagation can be catalyzed by ethylenediamine tetraacetate-chelated ferrous ion, diethylenetriamine pentaacetic acid-chelated ferrous ion, or by ferric cytochrome P-450. However, cytochrome P-450 is destroyed during propagation.     

Oxidative modification of human low-density lipoprotein by horseradish peroxidase in the absence of hydrogen peroxide

Heme-peroxidases, such as horseradish peroxidase (HRP), are among the most popular catalysts of low density lipoprotein (LDL) peroxidation. In this model system, a suitable oxidant such as H₂O₂ is required to generate the hypervalent iron species able to initiate the peroxidative chain. However, we observed that traces of hydroperoxides present in a fresh solution of linoleic acid can promote lipid peroxidation and apo B oxidation, substituting H₂O₂.

Spectral analysis of HRP showed that an hypervalent iron is generated in the presence of H₂O₂ and peroxidizing linoleic acid. Accordingly, careful reduction of the traces of linoleic acid lipid hydroperoxide prevented formation of the ferryl species in HRP and lipid peroxidation. However, when LDL was oxidized in the presence of HRP, the ferryl form of HRP was not detectable, suggesting a Fenton-like reaction as an alternative mechanism. This was supported by the observation that carbon monoxide, a ligand for the ferrous HRP, completely inhibited peroxidation of LDL.

These results are in agreement with previous studies showing that myoglobin ferryl species is not produced in the presence of phospholipid hydroperoxides, and emphasize the relevance of a Fenton-like chemistry in peroxidation of LDL and indirectly, the role of pre-existing lipid hydroperoxides.     

Oxidative degradation of model lipids representative for main paper pulp lipophilic extractives by the laccase–mediator system

Different model lipids-alkanes, fatty alcohols, fatty acids, resin acids, free sterols, sterol esters, and triglycerides-were treated with Pycnoporus cinnabarinus laccase in the presence of 1-hydroxybenzotriazole as mediator, and the products were analyzed by gas chromatography. The laccase alone decreased the concentration of some unsaturated lipids. However, the most extensive lipid modification was obtained with the laccase-mediator system. Unsaturated lipids were largely oxidized and the dominant products detected were epoxy and hydroxy fatty acids from fatty acids and free and esterified 7-ketosterols and steroid ketones from sterols and sterol esters. The former compounds suggested unsaturated lipid attack via the corresponding hydroperoxides. The enzymatic reaction on sterol esters largely depended on the nature of the fatty acyl moiety, i.e., oxidation of saturated fatty acid esters started at the sterol moiety, whereas the initial attack of unsaturated fatty acid esters was produced on the fatty acid double bonds. In contrast, saturated lipids were not modified, although some of them decreased when the laccase-mediator reactions were carried out in the presence of unsaturated lipids suggesting participation of lipid peroxidation radicals. These results are discussed in the context of enzymatic control of pitch to explain the removal of lipid mixtures during laccase-mediator treatment of different pulp types.     

Lipid peroxidation and haemoglobin degradation in red blood cells exposed to t-butyl hydroperoxide. The relative roles of haem- and glutathione-dependent decomposition of t-butyl hydroperoxide and membrane lipid hydroperoxides in lipid peroxidation and haemolysis

Red cells exposed to t-butyl hydroperoxide undergo lipid peroxidation, haemoglobin degradation and hexose monophosphate-shunt stimulation. By using the lipid-soluble antioxidant 2,6-di-t-butyl-p-cresol, the relative contributions of t-butyl hydroperoxide and membrane lipid hydroperoxides to oxidative haemoglobin changes and hexose monophosphate-shunt stimulation were determined. About 90% of the haemoglobin changes and all of the hexose monophosphate-shunt stimulation were caused by t-butyl hydroperoxide. The remainder of the haemoglobin changes appeared to be due to reactions between haemoglobin and lipid hydroperoxides generated during membrane peroxidation. After exposure of red cells to t-butyl hydroperoxide, no lipid hydroperoxides were detected iodimetrically, whether or not glucose was present in the incubation. Concentrations of 2,6-di-t-butyl-p-cresol, which almost totally suppressed lipid peroxidation, significantly inhibited haemoglobin binding to the membrane but had no significant effect on hexose monophosphate shunt stimulation, suggesting that lipid hydroperoxides had been decomposed by a reaction with haem or haem-protein and not enzymically via glutathione peroxidase. The mechanisms of lipid peroxidation and haemoglobin oxidation and the protective role of glucose were also investigated. In time-course studies of red cells containing oxyhaemoglobin, methaemoglobin or carbonmono-oxyhaemoglobin incubated without glucose and exposed to t-butyl hydroperoxide, haemoglobin oxidation paralleled both lipid peroxidation and t-butyl hydroperoxide consumption. Lipid peroxidation ceased when all t-butyl hydroperoxide was consumed, indicating that it was not autocatalytic and was driven by initiation events followed by rapid propagation and termination of chain reactions and rapid non-enzymic decomposition of lipid hydroperoxides. Carbonmono-oxyhaemoglobin and oxyhaemoglobin were good promoters of peroxidation, whereas methaemoglobin relatively spared the membrane from peroxidation. The protective influence of glucose metabolism on the time course of t-butyl hydroperoxide-induced changes was greatest in carbonmono-oxyhaemoglobin-containing red cells followed in order by oxyhaemoglobin- and methaemoglobin-containing red cells. This is the reverse order of the reactivity of the hydroperoxide with haemoglobin, which is greatest with methaemoglobin. In studies exposing red cells to a wide range of t-butyl hydroperoxide concentrations, haemoglobin oxidation and lipid peroxidation did not occur until the cellular glutathione had been oxidized. The amount of lipid peroxidation per increment in added t-butyl hydroperoxide was greatest in red cells containing carbonmono-oxyhaemoglobin, followed in order by oxyhaemoglobin and methaemoglobin. Red cells containing oxyhaemoglobin and carbonmono-oxyhaemoglobin and exposed to increasing concentrations of t-butyl hydroperoxide became increasingly resistant to lipid peroxidation as methaemoglobin accumulated, supporting a relatively protective role for methaemoglobin. In the presence of glucose, higher levels of t-butyl hydroperoxide were required to induce lipid peroxidation and haemoglobin oxidation compared with incubations without glucose. Carbonmono-oxyhaemoglobin-containing red cells exposed to the highest levels of t-butyl hydroperoxide underwent haemolysis after a critical level of lipid peroxidation was reached. Inhibition of lipid peroxidation by 2,6-di-t-butyl-p-cresol below this critical level prevented haemolysis. Oxidative membrane damage appeared to be a more important determinant of haemolysis in vitro than haemoglobin degradation. The effects of various antioxidants and free-radical scavengers on lipid peroxidation in red cells or in ghosts plus methaemoglobin exposed to t-butyl hydroperoxide suggested that red-cell haemoglobin decomposed the hydroperoxide by a homolytic scission mechanism to t-butoxyl radicals.     

Concentrations of iron correlate with the extent of protein, but not lipid, oxidation in advanced human atherosclerotic lesions

Previous studies have provided compelling evidence for the presence of oxidized proteins and lipids in advanced human atherosclerotic lesions. The catalyst responsible for such oxidation is unknown and controversial. We have previously provided evidence for elevated levels of iron in lesions. In this study we hypothesized that if iron ions catalyzed protein and lipid oxidation in the artery wall, then there should be a positive correlation between these parameters. Iron concentrations in ex vivo healthy human arteries and advanced carotid lesions were quantified by electron paramagnetic resonance spectroscopy. Four specific side-chain oxidation products of proteins, and the lipid oxidation products 7-ketocholesterol and cholesterol ester alcohols and hydroperoxides, were quantified by HPLC in the same samples used for the iron measurements. Parent amino acids, cholesterol, and cholesterol esters were also quantified. Statistically elevated levels of iron, cholesterol, cholesterol esters, 7-ketocholesterol, and cholesterol ester alcohols and hydroperoxides were detected in advanced lesions compared with healthy control tissue. Iron levels correlated positively and strongly with all four markers of protein oxidation, but not with either marker of lipid oxidation. These data support the hypothesis that elevated levels of iron contribute to the extent of protein, but not lipid, oxidation in advanced human lesions.