6-Hydroxymelatonin converts Fe (III) to Fe (II) and reduces iron-induced lipid peroxidation

Disorders of iron accumulation are known to produce hepatotoxicity. Agents, which can reduce Fe(3+) to a more usable form Fe(2+) could potentially limit such damage. Since it has been previously demonstrated that the pineal secretory product, melatonin, is able to bind iron, we decided to investigate the potential protective properties of the principal melatonin metabolite and degradant, 6-hydroxymelatonin (6-OHM). Using adsorptive cathode stripping voltammetry (AdCSV) we showed that Fe(3+) in the presence of 6-OHM is converted to Fe(2+). We further demonstrated that 6-OHM reduces the Fe(2+)-induced rise in lipid peroxidation in rat liver homogenates. The results imply that 6-OHM facilitates the conversion of Fe(3+) to Fe(2+) which is a more biologically usable form of iron. While such a conversion could also potentially make more Fe(2+) available for driving the Fenton reaction and the consequent generation of the dangerous hydroxyl radical, 6-OHM is able to quench these radicals, thereby providing tissue protection.     

The role of iron in oxygen radical mediated lipid peroxidation

The role of iron in the peroxidation of polyunsaturated fatty acids is reviewed, especially with respect to the involvement of oxygen radicals. The hydroxyl radical can be generated by a superoxide-driven Haber-Weiss reaction or by Fenton's reaction; and the hydroxyl radical can initiate lipid peroxidation. However, lipid peroxidation is frequently insensitive to hydroxyl radical scavengers or superoxide dismutase. We propose that the hydroxyl radical may not be involved in the peroxidation of membrane lipids, but instead lipid peroxidation requires both Fe2+ and Fe3+. The inability of superoxide dismutase to affect lipid peroxidation can be explained by the fact that the direct reduction of iron can occur, exemplified by rat liver microsomal NADPH-dependent lipid peroxidation. Catalase can be stimulatory, inhibitory or without affect because H2O2 may oxidize some Fe2+ to form the required Fe3+, or, alternatively, excess H2O2 may inhibit by excessive oxidation of the Fe2+. In an analogous manner reductants can form the initiating complex by reduction of Fe3+, but complete reduction would inhibit lipid peroxidation. All of these redox reactions would be influenced by iron chelation.     

Oxygen radical-mediated lipid peroxidation and inhibition of Ca2+-ATPase activity of cardiac sarcoplasmic reticulum

Oxygen radicals have been implicated as important mediators of myocardial ischemic and reperfusion injury. A major product of oxygen radical formation is the highly reactive hydroxyl radical via a biological Fenton reaction. The sarcoplasmic reticulum is one of the major target organelles injured by this process. Using a oxygen radical generating system consisting of dihydroxyfumarate and Fe3+-ADP, we studied lipid peroxidation and Ca2+-ATPase of cardiac sarcoplasmic reticulum. Incubation of sarcoplasmic reticulum with dihydroxyfumarate plus Fe3+-ADP significantly inhibited enzyme activity. Addition of superoxide dismutase, superoxide dismutase plus catalase (15 micrograms/ml) or iron chelator, deferoxamine (1.25-1000 microM) protected Ca2+-ATPase activity. Time course studies showed that this system inhibited enzyme activity in 7.5 to 10 min. Similar exposure of sarcoplasmic reticulum to dihydroxyfumarate plus Fe3+-ADP stimulated malondialdehyde formation. This effect was inhibited by superoxide dismutase, catalase, singlet oxygen, and hydroxyl radical scavengers. EPR spin-trapping with 5,5-dimethyl-1-pyrroline-N-oxide verified production of the hydroxyl radical. The combination of dihydroxyfumarate and Fe3+-ADP resulted in a spectrum of hydroxyl radical spin trap adduct, which was abolished by ethanol, catalase, mannitol, and superoxide dismutase. The results demonstrate the role of oxygen radicals in causing inactivation of Ca2+-ATPase and inhibition of lipid peroxidation of the sarcoplasmic reticulum which could possibly be one of the important mechanisms of oxygen radical-mediated myocardial injury.     

Mechanism of cobalt (II) ion inhibition of iron-supported phospholipid peroxidation

Co2+ inhibited nonenzymatic iron chelate-dependent lipid peroxidation in dispersed lipids, such as ascorbate-supported lipid peroxidation, but not iron-independent lipid peroxidation. Histidine partially abolished the Co2+ inhibition of the iron-dependent lipid peroxidation. The affinity of iron for phosphatidylcholine liposomes in Fe(2+)-PPi-supported systems was enhanced by the addition of an anionic lipid, phosphatidylserine, and Co2+ competitively inhibited the peroxidation, while the inhibiting ability of Co2+ as well as the peroxidizing ability of Fe(2+)-PPi on liposomes to which other phospholipids, phosphatidylethanolamine, or phosphatidylinositol had been added was reduced. Co2+ inhibited microsomal NADPH-supported lipid peroxidation monitored in terms of malondialdehyde production and the peroxidation monitored in terms of oxygen consumption. The inhibitory action of Co2+ was not associated with iron reduction or NADPH oxidation in microsomes, suggesting that Co2+ does not affect the microsomal electron transport system responsible for lipid peroxidation. Fe(2+)-PPi-supported peroxidation of microsomal lipid liposomes was markedly inhibited by Co2+.     

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.     

A new and suitable reconstructed system for NADPH-dependent microsomal lipid peroxidation

In order to evaluate the O-2 participation in NADPH-dependent microsomal lipid peroxidation, we used reconstructed system which contained detergent-solubilized NADPH-dependent cytochrome P-450 reductase, cytochrome P-450, phospholipid liposomes, NADPH and Fe3+-ADP. Lipid peroxidation, monitored by the formation of thiobarbituric acid-reactive substance, was increased with increasing concentration of detergent-solubilized NADPH cytochrome P-450 reductase, cytochrome P-450 or Fe3+-ADP. Cytochrome P-450-dependent lipid peroxidation was parallel to O-2 generation monitored by chemiluminescence probe with 2-methyl-6-(p-methoxyphenol)-3,7-dihydroimidazo[1,2-a]pyrazin++ +-3-one. Lipid peroxidation was significantly inhibited by superoxide dismutase, but not by catalase or sodium benzoate. The reconstructed system herein described is considered to be very close to NADPH-dependent microsomal lipid peroxidation system.     

Recycling and antioxidant activity of tocopherol homologs of differing hydrocarbon chain lengths in liver microsomes

Tocopherols (vitamin E) function as inhibitors of lipid peroxidation in biomembranes by donating a hydrogen atom to the chain propagating lipid radicals, thus giving rise to chromanoxyl radicals of the antioxidant. We have shown that alpha-tocopherol homologs differing in the lengths of their hydrocarbon side chains (alpha-Cn) manifest strikingly different antioxidant potencies in membranes. The antioxidant activity of tocopherol homologs during (Fe2+ + ascorbate)- or (Fe2+ + NADPH)-induced lipid peroxidation in rat liver microsomes increased in the order alpha-tocopherol (alpha-C16) less than alpha-C11 less than alpha-C6 less than alpha-C1. Chromanoxyl radicals generated from alpha-tocopherol and its more polar homologs by an enzymatic oxidation system (lipoxygenase + linolenic acid) can be recycled in rat liver microsomes by NAD-PH-dependent electron transport or by ascorbate. The efficiency of recycling increased in the same order: alpha-tocopherol (alpha-C16) less than alpha-C11 less than alpha-C6 less than alpha-C1. Thus the high efficiency of regeneration of short-chain homologs of vitamin E may account for their high antioxidant potency.     

Mechanisms of the effects of Ca2+ ions on lipid peroxidation

Mechanisms underlying Ca2+ effects on lipid peroxidation (LPO) induced in liposomes (from egg yolk lecithin) and UFsomes (from linolenic acid, methyl linolenate) with the aid of O2- -system (Fe2+ + ascorbate) were studied. It was shown that stimulation of lipid peroxidation by low Ca2+ concentrations (10(-6)-10(-5) M) was due to its ability to release Fe2+-ions bound to negatively charged (phosphate, carboxylic) lipid groups (of licethin, linolenic acid), thus increasing the concentration of catalytically active Fe2+. The inhibitory effect of high Ca2+ concentrations was caused by its interaction with superoxide anion-radicals and was not observed in LPO-systems, independent of O2- generation (e. g. Fe2+ + cumol hydroperoxide).     

Microsomal reduction of low-molecular-weight Fe3+ chelates and ferritin: enhancement by adriamycin, paraquat, menadione, and anthraquinone 2-sulfonate and inhibition by oxygen

Reduction of iron is important in promoting xenobiotic-enhanced, microsomal lipid peroxidation, yet there is little evidence that Fe3+ chelates that promote lipid peroxidation can be reduced by the microsomal system. We have shown that rat liver microsomes catalyse NADPH-dependent reduction of Fe3+ without chelator, as well as Fe3+(ADP), Fe3+(ATP), Fe3+(citrate), Fe3+(EDTA), and ferrioxamine in N2. The NADPH oxidation that accompanied Fe3+ reduction was inhibited by CO for all chelates, except Fe3+ (EDTA). This implies that, except for Fe3+ (EDTA), cytochrome P450 was involved in reduction of the complexes. Adriamycin, paraquat, and anthraquinone 2-sulfonate (AQS) enhanced reduction of all the Fe3+ chelates, whereas menadione enhanced reduction only of Fe3+(ADP) and Fe3+(citrate). All the compounds enhanced oxidation of NADPH in the presence or absence of iron. This was not inhibited by CO, and the results are compatible with Fe3+ reduction occurring via the xenobiotic radicals produced by cytochrome P450 reductase. Microsomal reduction of the xenobiotics, except menadione, enabled the reduction and release of iron from ferritin. Fe3+ chelate reduction, both with and without xenobiotic, was inhibited by O2, although it still proceeded in air at 10-20% of the rate in N2. Iron-dependent lipid peroxidation was promoted by ADP and ATP, inhibited 50% by citrate, and completely inhibited by EDTA and desferrioxamine. Of the xenobiotics, only Adriamycin enhanced microsomal lipid peroxidation. These results indicate that the effects of chelators and xenobiotics on Fe3+ reduction do not correlate with lipid peroxidation and, although reduction is necessary, there must be other factors involved.     

Mechanism of reaction of a suggested superoxide-dismutase mimic, Fe(II)-N,N,N',N'-tetrakis(2-pyridylmethyl)ethylenediamine.

The interaction of a recently developed intracellular superoxide dismutase analogue, Fe(II)-N,N,N',N'-tetrakis(2- pyridylmethyl)ethylenediamine (Fe(II)-TPEN), with reactive oxygen species was investigated under in vitro conditions. The complex catalyzed the dismutation of enzyme- or radiolysis-generated superoxide with the production of H2O2; under steady-state conditions the equilibrium was strongly shifted toward Fe(III)-TPEN. Fe(II)-TPEN reacted with H2O2 to generate hydroxyl radicals in a Fenton reaction. The oxidized Fe(III)-TPEN was readily reduced by ascorbate or glutathione. Given the capacity to produce hydroxyl radicals and the reaction with cellular reductants it seems unlikely that Fe-TPEN may find widespread use as an intracellular superoxide dismutase substitute.     

Antioxidant mechanism of Mn(II) in phospholipid peroxidation.

Antioxidant action of Mn2+ on radical-mediated lipid peroxidation without added iron in microsomal lipid liposomes and on iron-supported lipid peroxidation in phospholipid liposomes or in microsomes was investigated. High concentrations of Mn2+ above 50 microM inhibited 2,2'-azobis (2-amidinopropane) (ABAP)-supported lipid peroxidation without added iron at the early stage, while upon prolonged incubation, malondialdehyde production was rather enhanced as compared with the control in the absence of Mn2+. However, in a lipid-soluble radical initiator, 2,2'-azobis (2,4-dimethyl-valeronitrile) (AMVN)-supported lipid peroxidation of methyl linoleate in methanol Mn2+ apparently did not scavenge lipid radicals and lipid peroxyl radicals, contrary to a previous report. At concentrations lower than 5 microM, Mn2+ competitively inhibited Fe(2+)-pyrophosphate-supported lipid peroxidation in liposomes consisting of phosphatidylcholine with arachidonic acid at the beta-position and phosphatidylserine dipalmitoyl, and reduced nicotinamide adenine dinucleotide phosphate (NADPH)-supported lipid peroxidation in the presence of iron complex in microsomes. Iron reduction responsible for lipid peroxidation in microsomes was not influenced by Mn2+.     

Antioxidant action of ubiquinol homologues with different isoprenoid chain length in biomembranes

Ubiquinones (CoQn) are intrinsic lipid components of many membranes. Besides their role in electron-transfer reactions they may act as free radical scavengers, yet their antioxidant function has received relatively little study. The efficiency of ubiquinols of varying isoprenoid chain length (from Q0 to Q10) in preventing (Fe2+ + ascorbate)-dependent or (Fe2+ + NADPH)-dependent lipid peroxidation was investigated in rat liver microsomes and brain synaptosomes and mitochondria. Ubiquinols, the reduced forms of CoQn, possess much greater antioxidant activity than the oxidized ubiquinone forms. In homogenous solution the radical scavenging activity of ubiquinol homologues does not depend on the length of their isoprenoid chain. However in membranes ubiquinols with short isoprenoid chains (Q1-Q4) are much more potent inhibitors of lipid peroxidation than the longer chain homologues (Q5-Q10). It is found that: i) the inhibitory action, that is, antioxidant efficiency of short-chain ubiquinols decreases in order Q1 greater than Q2 greater than Q3 greater than Q4; ii) the antioxidant efficiency of long-chain ubiquinols is only slightly dependent on their concentrations in the order Q5 greater than Q6 greater than Q7 greater than Q8 greater than Q9 greater than Q10 and iii) the antioxidant efficiency of Q0 is markedly less than that of other homologues. Interaction of ubiquinols with oxygen radicals was followed by their effects on luminol-activated chemiluminescence. Ubiquinols Q1-Q4 at 0.1 mM completely inhibit the luminol-activated NADPH-dependent chemiluminescent response of microsomes, while homologues Q6-Q10 exert no effect. In contrast to ubiquinol Q10 (ubiquinone Q10) ubiquinone Q1 synergistically enhances NADPH-dependent regeneration of endogenous vitamin E in microsomes thus providing for higher antioxidant protection against lipid peroxidation. The differences in the antioxidant potency of ubiquinols in membranes are suggested to result from differences in partitioning into membranes, intramembrane mobility and non-uniform distribution of ubiquinols resulting in differing efficiency of interaction with oxygen and lipid radicals as well as different efficiency of ubiquinols in regeneration of endogenous vitamin E.     

Complement-component-C3-opsonized immunoglobulin G anti-DNA antibodies do not bind effectively to red blood cells unless aggregated on a high-Mr DNA matrix.

The significance of microsomal vitamin E in protecting against the free-radical process of lipid peroxidation was evaluated with the low-level-chemiluminescence technique in microsomal fractions from vitamin E-deficient and control rats. The induction period that normally precedes the ascorbate/ADP/Fe3+-induced lipid peroxidation was taken as reflecting the microsomal vitamin E content and was found to be 5-6-fold decreased in microsomal fractions from vitamin E-deficient rats. Supplementation of microsomal fractions from vitamin E-deficient rats with exogenous vitamin E partially restores the induction period observed in that from control rats. The decrease in chemiluminescence intensity and the increase in the induction period both correlate linearly with the amount of vitamin E added. However, the efficiency of exogenous vitamin E is about 50-fold lower than that exerted by the naturally occurring vitamin E in microsomal membranes. These observations are discussed in terms of the process of re-incorporation of vitamin E into membranes, the experimental model for lipid peroxidation selected, and the method to evaluate lipid peroxidation, namely low-level chemiluminescence.     

Interplay between lipoic acid and glutathione in the protection against microsomal lipid peroxidation

Reduced glutathione (GSH) delays microsomal lipid peroxidation via the reduction of vitamin E radicals, which is catalyzed by a free radical reductase (Haenen, G.R.M.M. et al. (1987) Arch. Biochem. Biophys. 259, 449-456). Lipoic acid exerts its therapeutic effect in pathologies in which free radicals are involved. We investigated the interplay between lipoic acid and glutathione in microsomal Fe2+ (10 microM)/ascorbate (0.2 mM)-induced lipid peroxidation. Neither reduced nor oxidized lipoic acid (0.5 mM) displayed protection against microsomal lipid peroxidation, measured as thiobarbituric acid-reactive material. Reduced lipoic acid even had a pro-oxidant activity, which is probably due to reduction of Fe3+. Notably, protection against lipid peroxidation was afforded by the combination of oxidized glutathione (GSSG) and reduced lipoic acid. It is shown that this effect can be ascribed completely to reduction of GSSG to GSH by reduced lipoic acid. This may provide a rationale for the therapeutic effectiveness of lipoic acid.     

Inhibition of microsomal lipid peroxidation by cytosolic protein in presence of ADP and high concentration of Fe2+

Microsomal lipid peroxidation induced by NADPH, but not by ascorbate, was found to be inhibited by liver cytosol. This inhibition was not dependent on glutathione and was enhanced by ADP in presence of Fe2+ at a concentration of 50 microM or higher. ATP was also effective, but not AMP or cyclic AMP. The cytosolic factor appeared to be a protein as it was heat-labile (greater than 70 degrees C), was non-dialyzable and was precipitated by ammonium sulfate and acetone. It was stable for several months in frozen state and also when heated at 50 degrees C for 10 min. The inhibition by the cytosolic protein was obtained by producing a lag in the activity of lipid peroxidation and was reversed by ceruloplasmin but not by catalase, cytochrome c, hemoglobin or superoxide dismutase. This inhibitory effect by cytosol was limited to formation of lipid peroxides whereas oxygen uptake and NADPH oxidation remained unaffected. Regulation of lipid peroxidation by nucleotide-Fe complexes and cytosolic proteins is indicated by these studies.     

Effect of lecithin on liver microsomal lipid peroxidation]

The effect of exogeneous (egg) lecithin on peroxidation of microsomal lipids was studied with the view of elucidating the role of various components of lipid substrate in the overall oxidation rate of the lipids. The following processes were studied a) NADPH-dependent microsomal lipid peroxidation in the presence of lecithin; b) ascorbate-dependent microsomal lipid peroxidation in the presence of lecithin; c) oxidation of lipid mixture, isolated from the microsomes, and that of lecithin in the presence of the Fe2+ + ascorbate system; 4) oxidation of lecithin induced by the Fe2+ + ascorbate system. It was found that in the presence of exogeneous lecithin the oxidation of microsomal lipids in inhibited, which is probably due to the peculiarities of lecithin oxidation. It was shown that the specific rate of lecithin oxidation is decreased with an increase in lecithin concentration. Possible mechanisms of lecithin effect on microsomal lipid peroxidation are discussed.     

A marked stimulation of Fe(3+)-dependent lipid peroxidation in phospholipid liposomes under acidic conditions

Lipid peroxidation in phosphatidylcholine liposomes induced by Fe(3+) alone, assessed by thiobarbituric acid-reactive substances (TBARS) production, was markedly enhanced as the solution pH was lowered from 7.4 to 5.5. On the other hand, at physiological pH, TBARS production by Fe(3+) was almost negligible. Results of the radical scavenger experiments with superoxide dismutase, catalase and hydroxyl radical ((&z.rad;)OH) scavengers (sodium benzoate, mannitol and dimethylthiourea), deoxyribose degradation and ESR spectrometry suggest that the stimulation of Fe(3+)-dependent lipid peroxidation under acidic conditions is involved in generation of superoxide anion (O(2)(&z.rad;-)), hydrogen peroxide (H(2)O(2)) and (&z.rad;)OH during the reaction. The stimulation of Fe(3+)-dependent TBARS production by increasing the [H(+)] completely disappeared by triphenylphosphine (TPP) treatment of the liposomes, but the reaction was reversible with either incorporation of cumen hydroperoxide (CumOOH) into the TPP-treated liposomes or the addition of CumOOH to the treated liposomes. Incubation of the CumOOH-incorporated TPP-treated liposomes with Fe(3+) at pH 5.5 also resulted in (&z.rad;)OH generation. Based on these results, a possible mechanism of stimulatory effect of Fe(3+) on lipid peroxidation under acidic conditions is discussed.     

Selective sensitization of chemiluminescence resulted from lipid and oxygen radical reactions

Eu3+-tetracycline complex (EuT) increased the chemiluminescence (CL) intensity of linolenic acid micells (UFA-somes) oxidized with lipoxygenase and CL of the lecithin liposomes peroxidized with Fe2+ ions by 3 orders of magnitude. In the systems producing oxygen radicals (xanthine + xanthine oxidase and Fenton's reagent) EuT was ineffective. Luminol increased CL intensity up to 4 orders of magnitude in Fenton's reagent and by 2 orders of magnitude in xanthine oxidase reaction. The sensitization of CL in Fe2+-induced lipid peroxidation (LPO) of liposomes was by a factor 40, while in lipoxygenase reaction very low sensitization was observed. By means of cut-off light filter OS-12 (Soviet) having short wave-length transmittance limit at 560 nm it was possible to measure separately in the same sample the luminol-sensitized CL (maximal emission near 480 nm) and EuT-sensitized CL (maximum at 620 nm); these two CL components reflect, correspondingly, the production rate of oxygen- and lipid-free radicals. Mannitol, the OH radical scavenger, inhibited luminol-dependent component of CL in peroxidized liposomes and did not inhibited EuT sensitized CL in the same system. Apparently, hydroxyl radicals are produced in LPO reactions and responsible for the effect of CL sensitization by luminol, but are not involved in the chain LPO process.     

Increased lipid peroxidation in kidney of vitamin B-6 deficient rats

Lipid peroxidation in kidney of rats fed with vitamin B-6 deficient diet for a period of 12 weeks was studied with pair-fed controls. The basal lipid peroxide level as well as the degree of susceptibility to lipid peroxidation in presence of promotors such as NADPH, ascorbate, t-butyl hydroperoxide, Fe2+, Cu2+ and oxalate, were increased in vitamin B-6 deficient kidney. The observed increased lipid peroxidation in vitamin B-6 deficient kidney was correlated with high levels of lipids, copper, iron, calcium and oxalate, low levels of antioxidants and antioxidant enzymes and increased levels of hydroperoxides and hydroxyl radicals.     

Ferrous ion-mediated cytochrome P-450 degradation and lipid peroxidation in adrenal cortex mitochondria.

The relationship between the degradation reaction of cytochrome P-450 and lipid peroxidation was studied utilizing bovine adrenal cortex mitochondria. The two reactions were found to be closely correlated in terms of their response to storage of the mitochondrial preparation, stimulation by Fe2+, inhibition by EDTA and their initiation by cumene hydroperoxide. Both reactions were also found not to be inhibited by catalase, superoxide dismutase, 1,4-diazabicyclo-(2,2,2)-octane and alcohols, indicating that H2O2, superoxide, singlet oxygen and hydroxyl radicals do not participate in these reactions. Yet, diphenylamine proved to be a powerful inhibitor for both reactions, suggesting the involvement of a radical species. Cumene hydroperoxide could induce these two reactions at below 0.1 mM concentrations in the presence of molecular oxygen. The chemiluminescence observed during the Fe2+-mediated lipid peroxidation reaction which was not inhibited by either superoxide dismutase or 1,4-diazabicyclo-(2,2,2)-octane, was biphasic: one was a rapid burst; and the other was a slowly increasing emission. The latter portion of the emission of light coincided with the formation of malondialdehyde. These results indicate that in adrenal cortex mitochondria the degradation of cytochrome P-450 is closely related to lipid peroxidation.