Spin-trapping studies of hydroxyl radical production involved in lipid peroxidation.

Evidence presented in this report suggests that the hydroxyl radical (OH.), which is generated from liver microsomes is an initiator of NADPH-dependent lipid peroxidation. The conclusions are based on the following observations: 1) hydroxyl radical production in liver microsomes as measured by esr spin-trapping correlates with the extent of NADPH induced microsomal lipid peroxidation as measured by malondialdehyde formation; 2) peroxidative degradation of arachidonic acid in a model OH · generating system, namely, the Fenton reaction takes place readily and is inhibited by thiourea, a potent OH · scavenger, indicating that the hydroxyl radical is capable of initiating lipid peroxidation; 3) trapping of the hydroxyl radical by the spin trap, 5,5-dimethyl-1-pyrroline-1-oxide prevents lipid peroxidation in liver microsomes during NADPH oxidation, and in the model system in the presence of linolenic acid. The possibility that cytochrome P-450 reductase is involved in NADPH-dependent lipid peroxidation is discussed. The optimal pH for the production of the hydroxyl radical in liver microsomes is 7.2. The generation of the hydroxyl radical is correlated with the amount of microsomal protein, possibly NADPH cytochrome P-450 reductase. A critical concentration of EDTA (5 × 10^?5m) is required for maximal production of the hydroxyl radical in microsomal lipid peroxidation during NADPH oxidation. High concentrations of Fe²⁺-EDTA complex equimolar in iron and chelator do not inhibit the production of the hydroxyl radical. The production of the hydroxyl radical in liver microsomes is also promoted by high salt concentrations. Evidence is also presented that OH radical production in microsomes during induced lipid peroxidation occurs primarily via the classic Fenton reaction.     

Effect of exposure of various oxidants on rat liver and intestinal microsomes--a comparative study.

Rat liver and intestinal microsomes were exposed to various free radical generating systems and their effect were assessed by studying different parameters such as formation of malonaldehyde (MDA) and conjugated diene, arachidonic acid depletion and alteration in protein thiol groups and tocopherol levels. These studies revealed that liver being highly vulnerable tissue showed all the effects of free radical attack whereas intestinal microsomes were resistant to most oxidants except iron independent generation of free radicals using 2-2'-azobis (2-amidinopropane) dihydrochloride (ABAP). Intestinal microsomes were found to contain considerable amount of non-esterified fatty acids in total lipid fraction as compared to liver microsomes and iron-fatty acid complex may be incapable of participating in peroxidation. In vitro measurement of hydroxyl radical generation showed that intestinal microsomes were incapable of generating these active species. These results suggest that iron dependent free radical mediated lipid peroxidation might not occur in intestinal epithelial cells.     

The effect of chronic alcohol feeding on lipid peroxidation in microsomes: lack of relationship to hydroxyl radical generation

Chronic alcohol feeding causes microsomal induction including increased generation of hydroxyl radicals. Ethanol induced liver injury may be mediated by lipid peroxidation for which hydroxyl radicals have been proposed as major mediators. Ethanol promotes lipid peroxidation when given acutely but also may serve as a hydroxyl radical scavenger. Therefore, we studied the acute and chronic effects of alcohol on microsomal lipid peroxidation and hydroxyl radical generation. Chronic alcohol feeding in rats increased microsomal generation of hydroxyl radicals but lipid peroxidation of endogenous lipid was inversely related to hydroxyl radical generation. Ethanol (50mM) had a slight inhibitory effect on hydroxyl radical production in peroxidizing microsomes, no effect on endogenous lipid peroxidation and enhanced the lysis of RBCs added as targets of peroxidation. Enhanced microsomal generation of hydroxyl radicals following chronic alcohol feeding is not an important mediator of lipid peroxidation.     

Role of hydroxyl radical in superoxide induced microsomal lipid peroxidation: Protective effect of anion channel blocker

Treatment of bovine pulmonary artery smooth muscle microsomes with the superoxide radical generating system hypoxanthine plus xanthine oxidase stimulated iron release, hydroxyl radical production and lipid peroxidation. Pretreatment of the microsomes with deferoxamine or dime thy lthiourea markedly inhibited lipid peroxidation, and prevented hydroxyl radical production without appreciably altering iron release. The superoxide radical generating system did not alter the ambient superoxide dismutase activity. However,addition of exogenous superoxide dismutase prevented superoxide radical induced iron release,hydroxyl radical production and lipid peroxidation. Simultaneous treatment of the microsomes with deferoxamine, dimethylthiourea or superoxide dismutase prevented hydroxyl radical production and liqid peroxidation. While deferoxamine or dimethylthiourea did not appreciably alter iron release, superoxide dismutase prevented iron release. However, addition of deferoxamine, dimethylthiourea or superoxide dismutase even 2 min after treatment did not significantly inhibit lipid peroxidation, hydroxyl radical production and iron release. Pretreatment of microsomes with the anion channel blocker 4,4’- dithiocyano 2,′- disulphonic acid stilbine did not cause any discernible change in chemiluminiscence induced by the superoxide radical generating system but markedly inhibited lipid peroxidation without appreciably altering iron release and hydroxial radical production.     

Spin trapping evidence for alcohol-associated oxidative stress

The spin trapping method combined with EPR spectroscopy has been employed by a number of laboratories to study alcohol-induced oxidative stress. Ethanol is converted to a free radical metabolite, the 1-hydroxyethyl radical in chemical reactions that generate hydroxyl radicals, in incubations of rat liver microsomes and in vivo. Furthermore, both acute and chronic ethanol administration leads to formation of radicals in the liver that are presumed to be products of lipid peroxidation. In general, overall radical production is enhanced by treatments known to be involved in alcoholic liver injury, such as chronic alcohol administration along with high levels of dietary fat.     

Comparison of the ability of ferric complexes to catalyze microsomal chemiluminescence, lipid peroxidation, and hydroxyl radical generation

The interaction of microsomes with iron and NADPH to generate active oxygen radicals was determined by assaying for low level chemiluminescence. The ability of several ferric complexes to catalyze light emission was compared to their effect on microsomal lipid peroxidation or hydroxyl radical generation. In the absence of added iron, microsomal light emission was very low; chemiluminescence could be enhanced by several cycles of freeze-thawing of the microsomes. The addition of ferric ammonium sulfate, ferric-citrate, or ferric-ADP produced an increase in chemiluminescence, whereas ferric-EDTA or -diethylenetriaminepentaacetic acid (detapac) were inhibitory. The same response to these ferric complexes was found when assaying for malondialdehyde as an index of microsomal lipid peroxidation. In contrast, hydroxyl radical generation, assessed as oxidation of chemical scavengers, was significantly enhanced in the presence of ferric-EDTA and -detapac and only weakly elevated by the other ferric complexes. Ferric-desferrioxamine was essentially inert in catalyzing any of these reactions. Chemiluminescence and lipid peroxidation were not affected by superoxide dismutase, catalase, or competitive hydroxyl radical scavengers whereas hydroxyl radical production was decreased by the latter two but not by superoxide dismutase. Chemiluminescence was decreased by the antioxidants propylgallate or glutathione and by inhibiting NADPH-cytochrome P-450 reductase with copper, but was not inhibited by metyrapone or carbon monoxide. The similar pattern exhibited by ferric complexes on microsomal light emission and lipid peroxidation, and the same response of both processes to radical scavenging agents, suggests a close association between chemiluminescence and lipid peroxidation, whereas both processes can be readily dissociated from free hydroxyl radical generation by microsomes.     

Nickel-mediated inhibition in the glutathione-dependent protection against lipid peroxidation

Glutathione protects liver microsomes against the rapid onset of lipid peroxidation via a sulfhydryl dependent heat labile factor known as free radical reductase. The administration of nickel to mice resulted in an inhibition in the activity of free radical reductase, and enhanced lipid peroxidation and the activity of glutathione S-transferase in a dose dependent manner. The pretreatment of cyclam, a known specific chelator of nickel restored free radical reductase and glutathione S-transferase activities and alleviated nickel mediated enhancement of lipid peroxidation. Our results indicate that nickel-mediated inhibition in free radical reductase activity and activation of glutathione S-transferase may be due to the interaction of nickel with sensitive-SH groups located on these proteins.     

Antioxidant effects of an aqueous extract of Ilex paraguariensis

In this work we investigate the antioxidant properties of an aqueous extract prepared from an infusion of Ilex paraguariensis (Aquifoliaceae) using free radical-generating systems. The extract inhibited the enzymatic and nonenzymatic lipid peroxidation in rat liver microsomes in a concentration-dependent fashion, with IC(50) values of 18 microg/ml and 28 microg/ml, respectively. The extract also inhibited the H(2)O(2)-induced peroxidation of red blood cell membranes with an IC(50) of 100 microg/ml and exhibited radical scavenging properties toward superoxide anion (IC(50) = 15 microg/ml) and 2,2-diphenyl-1-picrylhydrazyl radical. In the range of concentrations used, the extract was not a scavenger of the hydroxyl radical. Our results suggest that ingestion of extracts of Ilex paraguariensis could contribute to increase the antioxidant defense of an organism against free radicals attack.     

The mechanism of liver microsomal lipid peroxidation.

In the presence of Fe-3+ and complexing anions, the peroxidation of unsaturated liver microsomal lipid in both intact microsomes and in a model system containing extracted microsomal lipid can be promoted by either NADPH and NADPH : cytochrome c reductase or by xanthine and xanthine oxidase. Erythrocuprein effectively inhibits the activity promoted by xanthine and xanthine oxidase but produces much less inhibition of NADPH-dependent peroxidation. The singlet-oxygen trapping agent, 1, 3-diphenylisobenzofuran, had no effect on NADPH-dependent peroxidation but strongly inhibited the peroxidation promoted by xanthine and xanthine oxidase. NADPH-dependent lipid peroxidation was also shown to be unaffected by hydroxyl radical scavengers.. The addition of catalase had no effect on NADPH-dependent lipid peroxidation, but it significantly increased the rate of malondialdehyde formation in the reaction promoted by xanthine and xanthine oxidase. The results demonstrate that NADPH-dependent lipid peroxidation is promoted by a reaction mechanism which does not involve either superoxide, singlet oxygen, HOOH, or the hydroxyl radical. It is concluded that NADPH-dependent lipid peroxidation is initiated by the reduction of Fe-3+ followed by the decomposition of hydroperoxides to generate alkoxyl radicals. The initiation reaction may involve some form of the perferryl ion or other metal ion species generated during oxidation of Fe-2+ by oxygen.     

Participation of oxygen activated species in enzymatic lipid peroxidation in biomembranes]

The participation of oxygen activated species in the induction of lipid peroxidation (LPO) in the membrane systems containing cytochrome P-450 (liver microsomes) and in the membrane fragments devoid of this hemoprotein (brain and skeletal muscle microsomes) was studied. It was shown that the rate of NADH-dependent LPO does not depend on the presence of hemoproteins and the activity of NADH-specific flavoprotein in the membranes. On the other hand, the microsomal membranes of the liver with high specific contents of b5 and P-450 cytochromes and NADPH-specific flavoprotein, had the highest rates of NADPH-dependent LPO. It was found that the most effective inhibitors of free oxygen activated species in the case of NADPH- and NADH-dependent LPO in the microsomal fractions of liver, brain and skeletal muscles are the superoxide (O ./2) anion radical inhibitors. The singlet oxygen (1O2) quenchers inhibit only NADPH-dependent LPO in the liver, however, in a far lesser degree. The hydroxyl radical (OH) scavengers had no effect on enzymatic LPO in all systems studied.     

羟基自由基对兔脑微粒体膜脂及膜蛋白的损伤

本文研究了过氧化氢与亚铁离子体系产生的羟基自由基对兔脑微粒体脂质过氧化作用及对膜上(Na~++K~+)-ATP酶活性的影响.结果表明,羟基自由基导致兔脑微粒体脂质过氧化,增加丙二醛的含量.羟基自由基还使微粒体膜巯基数下降,(Na~++K~+)-ATP酶活力受到抑制.阿魏酸钠对抑制微粒体脂质过氧化及对膜巯基和(Na~++K~+)-ATP酶均有保护作用.自旋捕集实验结果进一步证明药物对羟基自由基的猝灭作用.     

Oxidative damage shifts from lipid peroxidation to thiol arylation by catechol-containing antioxidants

Catechol-containing antioxidants are able to protect against lipid peroxidation by nonenzymatic scavenging of free radicals with their catechol moiety. During their antioxidant activity, catechol oxidation products such as semiquinone radicals and quinones are formed. These oxidation products of 4-methylcatechol inactivate the GSH-dependent protection against lipid peroxidation and the calcium sequestration in liver microsomes. This effect is probably due to arylation by oxidation products of 4-methylcatechol of free thiol groups of the enzymes responsible for the GSH-dependent protection and calcium sequestration, i.e. the free radical reductase and calcium ATPase. It is concluded that a catechol-containing antioxidant might shift radical damage from lipid peroxidation to sulfhydryl arylation.     

Free radical scavenging action of the medicinal herb Limonium wrightii from the Okinawa islands

Free radical scavenging action of Limonium wrightii O. kunthe was examined in vitro and in vivo by using electron spin resonance spectrometer and chemiluminescence analyzer. A water extract of L. wrightii showed a strong scavenging action for the 1,1-diphenyl-2-picrylhydrazyl, or superoxide anion and moderate for hydroxyl radical. The extract also depressed production of reactive oxygen species from polymorphonuclear leukocytes stimulated by phorbor-12-mysistate acetate and inhibited lipid peroxidation in rat liver microsomes. When the extract was given intraperitoneally to mice prior to carbon tetrachloride (CCl4) treatment, CCl4-induced liver toxicity, as seen by an elevation of serum aspartate aminotransferase and alanine aminotransferase activities, was significantly reduced. Gallic acid was identified as the active component of L. wrightii with a strong free radical scavenging action. Our results demonstrate the free radical scavenging action of L. wrightii and that gallic acid contributes to these actions.     

C-phycocyanin: a potent peroxyl radical scavenger in vivo and in vitro

C-Phycocyanin (from Spirulina platensis) effectively inhibited CCl(4)-induced lipid peroxidation in rat liver in vivo. Both native and reduced phycocyanin significantly inhibited peroxyl radical-induced lipid peroxidation in rat liver microsomes and the inhibition was concentration dependent with an IC(50) of 11.35 and 12.7 microM, respectively. The radical scavenging property of phycocyanin was established by studying its reactivity with peroxyl and hydroxyl radicals and also by competition kinetics of crocin bleaching. These studies have demonstrated that phycocyanin is a potent peroxyl radical scavenger with an IC(50) of 5.0 microM and the rate constant ratios obtained for phycocyanin and uric acid (a known peroxyl radical scavenger) were 1.54 and 3.5, respectively. These studies clearly suggest that the covalently linked chromophore, phycocyanobilin, is involved in the antioxidant and radical scavenging activity of phycocyanin.     

Ferritin, Lipid Peroxidation and Redox-Cycling Xenobiotics

A number of xenobiotics are toxic because they rcdox cycle and generate free radicals. Interaction with iron, either to produce reactive species such as the hydroxyl radical, or to promote lipid peroxidation, is an important factor in this toxicity. A potential biological source of iron is ferritin. The cytotoxic pyrimidines, dialuric acid, divicine and isouramil, readily release iron from ferritin and promote ferritin-dependent lipid peroxidation. Superoxide dismutase and GSH, which maintain the pyrimidines in their reduced form, enhance both iron release and lipid peroxidation. Microsomes plus NADPH can reduce a number of iron complexes, although not ferritin. Reduction of Adriamycin. paraquat or various quinones to their radicals by the microsomes enhances reduction of the iron complexes, and in some cases, enables iron release from ferritin. Adriamycin stimulates iron-dependent lipid peroxidation of the microsomes. Ferritin can provide the iron, and peroxidation is most pronounced at low PO₂. Compiexing agents that supress intraccllular iron reduction and lipid peroxidation may protect against the toxicity of Adriamycin.     

Cephaloridine-induced lipid peroxidation initiated by reactive oxygen species as a possible mechanism of cephaloridine nephrotoxicity

Rat kidney microsomes reduced cephaloridine when incubated anaerobically with NADPH. Superoxide anion was generated in a concentration- and time-dependent manner when cephaloridine was incubated with rat kidney microsomes. Cephaloridine increased the in vitro peroxidation of rat kidney microsomal lipids in a concentration- and time-dependent manner. Cephaloridine-induced lipid peroxidation was inhibited by a combination of superoxide dismutase and catalase, by the hydroxyl radical scavengers, mannitol, (+)-cyanidanol-3 and by the singlet oxygen scavenger histidine in a concentration-dependent manner. It is proposed that cephaloridine nephrotoxicity may occur through the transfer of an electron from reduced cephaloridine to oxygen and subsequent formation of the superoxide anion, hydrogen peroxide, the hydroxyl radical and singlet oxygen. These activated oxygen species then are very likely to react with membrane lipids to induce lipid peroxidation and nephrotoxicity.     

Cytochrome P-450 deficiency and resistance to t-butyl hydroperoxide of hepatoma microsomal lipid peroxidation

Lipid peroxidation of microsomes from rat liver and Morris hepatoma 9618A was induced by means of tert-butyl hydroperoxide (t-BuOOH). In rat liver microsomes t-BuOOH stimulated an early formation of lipid hydroperoxides (LOOH) and an increasing accumulation of malondialdehyde; t-BuOOH was completely consumed and cytochrome P-450 was rapidly destroyed. In hepatoma microsomes (60% deficiency of cytochrome P-450) a remarkable inhibition of both malondialdehyde and LOOH was observed; t-BuOOH was consumed only partially and cytochrome P-450 was destroyed slowly. In the presence of aminopyrine, malondialdehyde production was inhibited to the same extent (about 70%) in normal and tumour microsomes. The concentration of t-BuOOH required to achieve half-maximal velocity of malondialdehyde accumulation was comparable in the two microsome types. It is proposed that the deficiency of cytochrome P-450 limits the activation of t-BuOOH to the free radical species which initiate lipid peroxidation. Low cytochrome P-450 content would also affect the LOOH-dependent propagation of lipid peroxidation.     

Lipid peroxidation induced by cercosporin as a possible determinant of its toxicity

The photodynamic action of cercosporin was assayed in various kinds of natural and artificial membranes. Cerosporin induces lipoperoxidation of liposomes, rat liver and pea internode mitochondria and microsomes, estimated both as malondialdehyde (MDA) formation and O2 consumption. Cercosporin-induced lipoperoxidation is inhibited by either singlet oxygen quenchers, free radical trapping agents or EDTA. Superoxide anion (O2-), hydrogen peroxide and hydroxyl radicals (.OH) are not involved in the activity of cercosporin. In addition cercosporin, by chelating iron, lowers the lipoperoxidation induced by such a metal. Therefore cercosporin stimulates, through singlet oxygen production, the hydroperoxide formation but, at the same time, it inhibits the continuation of the iron-mediated free radical chain. The present results suggest that cellular lipid peroxidation has a certain relevance to toxic activity of cercosporin.     

Inhibition of rat liver microsomal lipid peroxidation by N-acyldehydroalanines: an in vitro comparative study

Captodative substituted olefins are radical scavengers which react with free radicals to form stabilized radical adducts. One of those compounds, N-(paramethoxyphenylacetyl)dehydroalanine (AD-5), may react and scavenge both superoxide anion (O-2) and alk-oxyl radicals (RO.), and in this way prevent the appearance of their mediated biological effects. Nitrofurantoin and tert-butyl hydroperoxide were used as model compounds to stimulate free radical production and their mediated lipid peroxidation in rat liver microsomes. In addition, lipid peroxidation was also initiated by exposure of rat liver microsomal suspensions to ionizing radiation (gamma rays). The microsomal lipid peroxidation induced by these chemicals and physical agents was inhibited by the addition of AD-5. These effects were dose-dependent in a millimolar range of concentration. In addition, AD-5 has no effect on microsomal electron transport, showing that NADPH-cytochrome P450 reductase activity was not modified. These data, together with the comparisons of the effects of AD-5 and some antioxidant molecules such as superoxide dismutase, uric acid, and mannitol, support the conclusion that inhibition of lipid peroxidation by AD-5 is the result of its free radical scavenger activity. In addition, the inhibitory effect of AD-5 on microsomal lipid peroxidation was dependent of the nature of the free radical species involved in the initiation of the process, suggesting that O-2 is scavenged more efficiently than RO.