Formation,isolation and structure determination of methyl linolenate diperoxides

Autoxidation of methyl linolenate gives rise to isomeric mono-hydroperoxides by reaction with one mole of oxygen but further reaction with a second mole of oxygen readily occurs to produce an isomeric mixture of diperoxides. Autoxidation of individual pure methyl hydroperoxylinolenate isomers has been used as a method of obtaining less complex diperoxide mixtures which can be separated into their pure components by preparative high-pressure liquid chromatography (HPLC). The major diperoxide isomers arising from the autoxidation of pure 9R- and 13S- hydroperoxides of methyl linolenate have been isolated and characterised as isomeric epidioxyhydroperoxides of methyl linolenate. These same compounds have been identified as components of the more complex mixture of diperoxides produced during methyl linolenate autoxidation. The structures of the isolated diperoxides have been determined by physico-chemical methods and a mechanism for their formation is proposed.     

The Effect of Lipid Peroxide on the Lipid and Carbohydrate Metabolism in Rat Liver

Feeding tests were carried out on rats to clarify the mechanisms of fatty liver formation induced by autoxidized methyl linoleate. Lipid peroxides prepared by autoxidation of highly purified methyl linoleate were given orally to rats. Triglyceride and glycogen contents in liver were determined and enzyme activities including triglyceride synthetase and α-glycerophosphate dehydrogenase were also examined. The following results were obtained. 1. Triglyceride accumulation in rat liver fed autoxidized methyl linoleate was observed. 2. Increase in triglyceride content in rat liver was soon followed by the decrease of hepatic glycogen. 3. When rats were starved prior to introduction of autoxidized methyl linoleate, hepatic triglyceride accumulation did not occur. 4. The activities of α-glycerophosphate dehydrogenase and triglyceride synthetase in liver, and those of glutamic oxalacetic transaminase and leucine aminopeptidase in plasma were practically similar among the rats of test groups fed fresh or autoxidized methyl linoleate and the control fed diet without methyl linoleate. 5. The addition of l-carnitine which is a stimulator of fatty acid oxidation retarded the accumulation of the hepatic triglyceride mentioned above.     

Mechanism of site-specific DNA damage induced by methylhydrazines in the presence of copper(II) or manganese(III).

DNA damage induced by methylhydrazines (monomethylhydrazine, 1,1-dimethylhydrazine, and 1,2-dimethylhydrazine) in the presence of metal ions was investigated by a DNA sequencing technique. 1,2-Dimethylhydrazine plus Mn(III) caused DNA cleavage at every nucleotide without marked site specificity. ESR-spin-trapping experiments showed that the hydroxyl free radical (.OH) is generated during the Mn(III)-catalyzed autoxidation of 1,2-dimethylhydrazine. DNA damage and .OH generation were inhibited by .OH scavengers and superoxide dismutase, but not by catalase. The results suggest that 1,2-dimethylhydrazine plus Mn(III) generates .OH, not via H2O2, and that .OH causes DNA damage. In the presence of Cu(II), DNA cleavage was caused by the three methylhydrazines frequently at thymine residues, especially of the GTC sequence. The order of Cu(II)-mediated DNA damage (1,2-dimethylhydrazine greater than monomethylhydrazine approximately 1,1-dimethylhydrazine) was not correlated with the order of methyl free radical (.CH3) generation during Cu(II)-catalyzed autoxidation (monomethylhydrazine greater than 1,1-dimethylhydrazine much greater than 1,2-dimethylhydrazine). Catalase and bathocuproine, a Cu(I)-specific chelating agent, inhibited DNA damage while catalase did not inhibit the .CH3 generation. The order of DNA damage was correlated with the order of ratio of H2O2 production to O2 consumption observed during Cu(II)-catalyzed autoxidation of methylhydrazines. These results suggest that the Cu(I)-peroxide complex rather than the .CH3 plays a more important role in methylhydrazine plus Cu(II)-induced DNA damage.     

The reaction of DNA with lipid oxidation products, metals and reducing agents

The interaction of lipid hydroperoxides and secondary oxidation products with DNA was investigated by evaluating the fluorescence formed in the presence of metals and reducing agents. We also investigated the effect of malonaldehyde, because it has been generally considered responsible for the formation of fluorescence with DNA. However, malonaldehyde usually has been estimated by the notoriously unspecific thiobarbituric acid test. At low concentration of oxidation products (1 mM), fluorescence formation required the presence of metals and ascorbic acid. In contrast, a positive thiobarbituric acid reaction was obtained with many lipid oxidation products without metals or ascorbic acid. Monohydroperoxides from autoxidized methyl linoleate and linolenate produced the highest level of fluorescence. Hydroperoxy epidioxides of linolenate and dihydroperoxides of linoleate and linolenate were among the most active secondary products in forming fluorescence with DNA. In contrast, malonaldehyde produced very little fluorescence under our conditions. The thiobarbituric acid values did not correlate with fluorescence formation. This study showed that, in our model reaction system, DNA forms fluorescent products by the breakdown of lipid oxidation products in the presence of metals and ascorbic acid into reactive materials other than malonaldehyde. Therefore, the importance of malonaldehyde in its crosslinking properties with DNA may have been exaggerated in the literature.     

Structures of Dimers Produced from Methyl Linoleate during Initial Stage of Autoxidation

A structural investigation on the main fraction of dimers formed during the induction period of autoxidation in methyl linoleate (ML) was carried out. The dimeric fraction (A₂), which was isolated from the autoxidized ML (POV= 18) by various Chromatographic techniques and gave a single spot on TLC, was further separated into four major components (components 1–4) by high performance liquid chromatography (HPLC). The mean molecular weights of these components were found to be 643–655 and component 4 gave the parent peak 652 on an FD-mass spectrum which corresponded to 2 × ML + 4O. The reduced products of each component with stannous chloride were identified in common as methyl 9- or 13-hydroxy octadecadienoate and methyl 9,13-dihydroxy octadecenoate by GC-MS. These results show that all of these dimers contained a peroxide bridge linking between a pair of MLs across C-9 or C-13 on one of the MLs and C-9 or C-13 on the other, with a hydroperoxy group.     

Fluorescence formation from the interaction of DNA with lipid oxidation degradation products

To clarify the mechanism of fluorescence formation between DNA and lipid degradation products in the presence of ferric chloride and ascorbic acid, a number of carbonyl compounds and decomposition products of pure methyl linolenate hydroperoxides were examined. Keto derivatives of methyl ricinoleate, linoleate, and oleate, alkanals and 2-alkenals produced little or no fluorescence with DNA in the presence of ferric chloride-ascorbic acid. 2,4-Alkadienals were more active and 2,4,7-decatrienal was the most active. Mixtures of volatile aldehydes prepared from linolenate hydroperoxide decomposed either thermally or with iron and ascorbate had the same activity as 2,4,7-decatrienal. Higher molecular-weight products from the decomposition of methyl linolenate hydroperoxides showed relatively low activity. beta-Carotene, alpha-tocopherol and other antioxidants effectively reduced the amount of fluorescence formed by linolenate hydroperoxides. The results suggest that, in addition to hydroperoxide decomposition products, singlet oxygen and/or free radical species contribute significantly to the fluorescence formed from the interaction of methyl linolenate hydroperoxides with DNA in the presence of ferric chloride and ascorbic acid.     

Free radical scavenging and cytotoxic properties in the ellipticine series

In the series of cytotoxic intercalating compounds derived from ellipticine, we tried to correlate free radical scavenging properties with cytotoxic activities. Scavenging properties were determined in vitro on two experimental models: a) antioxidant activity of the drugs during the autoxidation of methyl linolenate induced by azo-bis-isobutyronitrile; this activity was measured either by the initial rate ratios in the presence and in the absence of the drug or by the length of the inhibition period of the reaction in the presence of the drug and b) ability to reduce DPPH free radicals. Cytotoxic properties were expressed by ID50 the dose which reduces by 50% the L 1210 cell growth rate as compared to controls after 48 h. It appears that antioxidant activity and reduction of DPPH both require the presence of a free OH group on the ellipticine ring. A good correlation is observed between cytotoxicity and antioxidant activity of the hydroxylated derivatives; minor structural modifications which result in a loss of cytotoxic activity also result in a loss of antioxidant properties. No such correlation is observed with DPPH reducing properties of ellipticine derivatives.     

Site-specific DNA damage induced by hydrazine in the presence of manganese and copper ions. The role of hydroxyl radical and hydrogen atom.

The mechanism of DNA damage by hydrazine in the presence of metal ions was investigated by DNA sequencing technique and ESR-spin trapping method. Hydrazine caused DNA damage in the presence of Mn(III), Mn(II), Cu(II), Co(II), and Fe(III). The order of inducing effect on hydrazine-dependent DNA damage (Mn(III) greater than Mn(II) approximately Cu(II) much greater than Co(II) approximately Fe(III)) was related to that of the accelerating effect on the O2 consumption rate of hydrazine autoxidation. DNA damage by hydrazine plus Mn(II) or Mn(III) was inhibited by hydroxyl radical scavengers and superoxide dismutase, but not by catalase. On the other hand, bathocuproine and catalase completely inhibited DNA damage by hydrazine plus Cu(II), whereas hydroxyl radical scavengers and superoxide dismutase did not. Hydrazine plus Mn(II) or Mn(III) caused cleavage at every nucleotide with a little weaker cleavage at adenine residues, whereas hydrazine plus Cu(II) induced piperidine-labile sites frequently at thymine residues, especially of the GTC sequence. ESR-spin trapping experiments showed that hydroxyl radical is generated during the Mn(III)-catalyzed autoxidation of hydrazine, whereas hydrogen atom adducts of spin trapping reagents are generated during Cu(II)-catalyzed autoxidation. The results suggest that hydrazine plus Mn(II) or Mn(III) generate hydroxyl free radical not via H2O2 and that this hydroxyl free radical causes DNA damage. A possibility that the hydrogen atom releasing compound participates in hydrazine plus Cu(II)-induced DNA damage is discussed.     

Continuous anaerobic treatment of autoxidized bark extracts in laboratory-scale columns

Debarking wastewaters of the forest industry contain high concentrations of tannins that are inhibitory to methane bacteria. The tannins can be polymerized to nontoxic colored compounds by the applications of an autoxidation pretreatment, enabling the anaerobic treatment of easily biodegradable components in the wastewater. The continuous anaerobic treatment of untreated and autoxidized pine bark extract was studied in laboratory-scale columns packed with a granular sludge bed. The autoxidation doubled the conversion efficiency of bark extract COD to methane (from 19 to 40%). After 5 months of operation, anaerobic treatment of the autoxidized extracts was feasible at high influent concentrations (14 g COD/L) and loading rates (26 g biodegradable COD/L . d) with 98% elimination of the biodegradable fraction. The detoxification pretreatment polymerized the toxic tannins to poorly biodegradable high molecular weight tannins and humic compounds which were not eliminated during anaerobic treatment. Although the original tannins of the untreated extract were eliminated by 60%, they were not biodegraded to volatile fatty acids and methane but instead were transformed to phenolic degradation intermediates (phenol, p-cresol, 3-phenyl-propionate, and carboxycyclohexane). Therefore, the autoxidation pretreatment did not decrease the content of readily biodegradable substrates which accounted for 53% of the extract COD. The recalcitrant COD expected in the effluents of reactors treating autoxidized debarking waste-water can be effectively separated by calcium precipitation prior to anaerobic treatment.     

The effect of dietary autoxidized oils on immunocompetent cells in mice

Effects of dietary autoxidized oil on immunocompetent cells, such as splenocytes and thymocytes, were studied in mice. When the autoxidized methyl linoleate was administered orally to male C57BL/6 mice in a single dose, the DNA synthesis of thymocytes was remarkably depressed 1 day after the treatment, and then the mitogenic response to concanavalin A of splenocytes was increased 3 days after the dose. With long-term (90 days) feeding of slightly autoxidized soybean oil (with a peroxide value of 150 mequiv/kg) in mice, the DNA synthesis of thymocytes was depressed and the mitogenic response to concanavalin A of splenocytes was increased. No effect was observed on plasma glutamic acid-oxaloacetic acid transaminase and glutamic acid-pyruvic acid transaminase levels, nor on liver thiobarbituric acid reactants due to the dose of autoxidized soybean oil. These findings indicate that oral intake of autoxidized oil affects immunocompetent cells and causes depression of the DNA synthesis of thymocytes in mice.     

Reaction products of [60]fullerene during the autoxidation of methyl linoleate in bulk phase

The antioxidative action of fullerenes has received much attention, but their reaction mechanism toward lipid-derived peroxyl radicals has not been well elucidated. In this study, the reaction products of [60]fullerene (C(60)) during the autoxidation of methyl linoleate (MeL) were isolated and their structures were characterized. MeL containing 0.1mol% C(60) was autoxidized at 60°C in bulk phase and two reaction products of C(60), 1 and 2, were obtained. The structure of 1 was the addition products of C(60) with 9-peroxyl-10-alkyl radicals of methyl (11E)-13-hydroperoxy-11-octadecaenoate (1a and 1b) and with 12-alkyl-13-peroxyl radicals of methyl (10E)-9-hydroperoxy-10-octadecaenoate (1c and 1d). 2 was a mixture of the addition products of C(60) with 9,11-dialkyl radicals of methyl 9,12-octadecadienoate (2a) and with 11,13-dialkyl radicals of methyl 9,12-octadecadienoate (2b). When MeL containing 0.1mol% C(60) was autoxidized at 60°C under air-sufficient and air-insufficient conditions, C(60) could suppress the formation of MeL hydroperoxides in both conditions. The reaction product of C(60) first formed was 2 even under air-sufficient conditions, and then 1 was accumulated. The results indicate that the primary antioxidative action of C(60) would be trapping of chain-initiating carbon-centered radicals of unsaturated lipid to form 2.     

Inhibition of glutathione reductase by isoproterenol oxidation products

Oxidative stress induced by catecholamines is a well recognized toxic event. This effect has been extensively observed in the heart, where high levels of catecholamines cause enzyme inhibition, lipid peroxidation, energy depletion and myocardial necrosis. Catecholamines can be converted into o-quinones and undergo cyclization into aminochromes. This process can occur enzymatically or through autoxidation and involves the formation of free radicals. Aminochromes are highly reactive molecules that can cause oxidation of protein sulfhydryl groups and deamination catalysis, among other deleterious effects; in addition, inhibition of some enzymes has been also reported. We have studied the effects of isoproterenol oxidation products (IOP) on glutathione reductase (GR) activity in vitro. Isoproterenol (ISO) autoxidation was conducted at 37 degrees C in the dark, for 4 h at pH 7.0 and this process was monitored by UV spectrophotometry at both 340 and 490nm. Addition of the autoxidized solution to GR in the presence of oxidized glutathione (GSSG) and NADPH showed that IOP inhibits GR in a competitive mode and that this effect increases during the 4 h incubation period. This inhibitory effect of IOP was partially prevented by the addition of reduced glutathione (GSH), L-cysteine and ascorbic acid to the reaction mixtures.     

Inhibition of Glutathione Reductase by Isoproterenol Oxidation Products

Oxidative stress induced by catecholamines is a well recognized toxic event. This effect has been extensively observed in the heart, where high levels of catecholamines cause enzyme inhibition, lipid peroxidation, energy depletion and myocardial necrosis. Catecholamines can be converted into o-quinones and undergo cyclization into aminochromes. This process can occur enzymatically or through autoxidation and involves the formation of free radicals. Aminochromes are highly reactive molecules that can cause oxidation of protein sulfhydryl groups and deamination catalysis, among other deleterious effects; in addition, inhibition of some enzymes has been also reported. We have studied the effects of isoproterenol oxidation products (IOP) on glutathione reductase (GR) activity in vitro. Isoproterenol (ISO) autoxidation was conducted at 37 degrees C in the dark, for 4 h at pH 7.0 and this process was monitored by UV spectrophotometry at both 340 and 490 nm. Addition of the autoxidized solution to GR in the presence of oxidized glutathione (GSSG) and NADPH showed that IOP inhibits GR in a competitive mode and that this effect increases during the 4 h incubation period. This inhibitory effect of IOP was partially prevented by the addition of reduced glutathione (GSH), L-cysteine and ascorbic acid to the reaction mixtures.     

Secondary products of lipid oxidation

In the last decade, a multitude of secondary products have been identified from the radical and photosensitized oxidations of polyunsaturated lipids. These secondary products consist of oxygenated monomeric materials including epoxy-hydroperoxides, oxo-hydroperoxides, hydroperoxy epidioxides, dihydroperoxides, hydroperoxy bis-epidioxides, and hydroperoxy bicycloendoperoxides. More recently, higher molecular weight dimeric compounds have been identified from autoxidized methyl linoleate and linolenate. Decomposition of these oxidation products form a wide range of carbonyl compounds, hydrocarbons, furans, and other materials that contribute to the flavor deterioration of foods and that are implicated in biological oxidation. The interaction of some of these degradation products with DNA may be involved in cell-damaging reactions.     

A novel cleavage product formed by autoxidation of lycopene induces apoptosis in HL-60 cells

Dietary carotenoids have been thought to have beneficial effects on human health through their antioxidant activity, provitamin A activity, and effects on cancer cell propagation. Recent studies suggest that oxidation products or metabolites are involved in biological activities of carotenoids. We previously reported that an autoxidation mixture of lycopene induced apoptosis in HL-60 human promyelocytic leukemia cells, but lycopene alone did not. In the present study, bioassay-directed fractionations of autoxidized lycopene led to isolation of a novel cleavage product of lycopene. Spectral analyses elucidated its structure as (E,E,E)-4-methyl-8-oxo-2,4,6-nonatrienal (MON), suggesting the formation through the oxidative cleavages at the 5, 6- and 13, 14-double bonds of lycopene. MON was proved to cause a dose-dependent reduction of viability in HL-60 cells with morphological changes such as chromatin condensation and nuclear fragmentation. Treatment of HL-60 cells with MON could induce DNA fragmentation and increase apoptotic cells in a time- and dose-dependent manner. The MON treatment could enhance both caspase 8 and caspase 9 activities. Moreover, it reduced the expression of Bcl-2 and Bcl-X_L proteins, whereas it had no effect on the level of Bax protein. These results clearly indicated that MON induced apoptosis in HL-60 cells, associated with the down regulation of Bcl-2 and Bcl-X_L and the activation of caspase cascades. The concentration of MON attained by treatment of the autoxidized lycopene preparation was far less than the IC₅₀ (10 μM) value of MON alone in reducing the viability of HL-60 cells. The fractionation of the oxidized lycopene indicated the presence of other active oxidation products. Thus, unidentified products as well as MON would be responsible for the apoptosis-inducing activity of the autoxidized lycopene.     

Manganese-mediated oxidative damage of cellular and isolated DNA by isoniazid and related hydrazines: non-Fenton-type hydroxyl radical formation.

The mechanism by which hydrazines induce damage to cellular and isolated DNA in the presence of metal ions has been investigated by pulsed-field gel electrophoresis (PFGE), DNA sequencing methods, and the ESR spin-trapping technique. For the detection of single-strand breaks by PFGE, an experimental procedure with alkali treatment has been designed. Isoniazid, hydrazine, and phenylhydrazine induced DNA single- and double-strand breaks in cells pretreated with Mn(II), whereas iproniazid did not. With isolated 32P-DNA, isoniazid produced DNA damage in the presence of Cu(II), Mn(II), or Mn(III). Iproniazid damage isolated DNA only in the presence of Cu(II). The Cu(II)-mediated DNA damage by isoniazid or iproniazid is due to active oxygen species other than hydroxyl free radical (.OH), presumably the Cu(I)-peroxide complex. Cleavage of isolated DNA by isoniazid plus Mn(II) occurred without marked site specificity. The DNA damage was inhibited by .OH scavengers and superoxide dismutase (SOD) but not by catalase, suggesting the involvement of .OH formed via O2- but not via H2O2. Consistently, in ESR experiments .OH formation was observed during Mn(II)-catalyzed autoxidation of isoniazid, and the .OH formation was inhibited by SOD, but not by catalase. Iproniazid plus Mn(II) produced no or little .OH. We propose a reaction mechanism for the .OH formation without a H2O2 intermediate during manganese-catalyzed autoxidation of hydrazine. The present and previous data raise the possibility that hydrazines plus Mn(II)-induced cellular DNA damage may occur, at least in part, through the non-Fenton-type reaction.     

Copper-dependent DNA damage induced by hydrazobenzene, an azobenzene metabolite

Hydrazobenzene is carcinogenic to rats and mice and azobenzene is carcinogenic to rats. Hydrazobenzene is a metabolic intermediate of azobenzene. To clarify the mechanism of carcinogenesis by azobenzene and hydrazobenzene, we investigated DNA damage induced by hydrazobenzene, using ³²P-5'-end-labeled DNA fragments obtained from the c-Ha-ras-1 proto-oncogene and the p53 tumor suppressor gene. Hydrazobenzene caused DNA damage in the presence of Cu(II). Piperidine treatment enhanced the DNA damage greatly, suggesting that hydrazobenzene caused base modification and liberation. However, azobenzene did not cause DNA damage even in the presence of Cu(II). Hydrazobenzene plus Cu(II) caused DNA damage frequently at thymine residues. Catalase and a Cu(I)-specific chelator inhibited Cu(II)-mediated DNA damage by hydrazobenzene. Typical ^·OH scavengers did not inhibit the DNA damage. The main active species is probably a metal oxygen complex, such as Cu(I)-OOH. Formation of 8-oxo-7, 8-dihydro-2'-deoxyguanosine was increased by hydrazobenzene in the presence of Cu(II). Oxygen consumption and UV-Visible spectroscopic measurements have shown that hydrazobenzene is autoxidized to azobenzene with H₂O₂ formation. It is considered that the metal-mediated DNA damage by hydrazobenzene through H₂O₂ generation may be relevant for the expression of carcinogenicity of azobenzene and hydrazobenzene.     

Molecular mechanisms of DNA damage induced by procarbazine in the presence of Cu(II)

Procarbazine [N-isopropyl-alpha-(2-methylhydrazino)-p-toluamide], a hydrazine derivative, which has been shown to have effective antineoplastic activity, induces cancer in some experimental animals and humans. To clarify a new mechanism for its carcinogenic effect, we examined DNA damage induced by procarbazine in the presence of metal ion, using 32P-5'-end-labeled DNA fragments obtained from the human p53 tumor suppressor gene and the c-Ha-ras-1 protooncogene. Procarbazine plus Cu(II) induced piperidine-labile and formamidopyrimidine-DNA glycosylase-sensitive lesions at the 5'-ACG-3' sequence, complementary to a hotspot of the p53 gene, and the 5'-TG-3' sequence. Catalase partially inhibited DNA damage, suggesting that not only H(2)O(2) but also other reactive species are involved. Procarbazine plus Cu(II) significantly increased the formation of 8-oxo-7,8-dihydro-2'-deoxyguanosine, which was completely inhibited by calatase. Electron spin resonance spin-trapping experiments revealed that methyl radicals were generated from procarbazine and Cu(II). On the basis of these findings, it is considered that procarbazine causes DNA damage through non-enzymatic formation of the Cu(I)-hydroperoxo complex and methyl radicals. In conclusion, in addition to alkylation, oxidative DNA damage may play important roles in not only antitumor effects but also mutagenesis and carcinogenesis induced by procarbazine.     

The Isomeric Composition of Hydroperoxides Formed by Autoxidation of Unsaturated Triglycerides and Vegetable Oils

Trioleoylglycerol (TO), trilinoleoylglycerol (TL), and trilinolenoylglycerol (TLN)were autoxi-dized in the dark at 37°C. Monohydroperoxides (MHP), the primary products, were isolated by preparative thin-layer chromatography (TLC). The isomeric compositions of their hydroperoxy fatty acid components were determined by gas chromatography-mass spectrometry (GC-MS) as follows—TO: the 8-, 9-, 10-, and 11-isomers; TL: the 9-, and 13-isomers; and TLN: the 9-, 12-, 13-, and 16-isomers. The proportions of isomers in each MHP did not vary with the oxidation time. The isomeric compositions of hydroperoxy fatty acid components obtained from autoxidized soybean and olive oils indicated that each unsaturated fatty acyl group of triacylglycerol (TG) in vegetable oils produced isomeric hydroperoxides during autoxidation in a way similar to the corresponding fatty acid methyl esters. The proportions of the isomers obtained from autoxidized oils changed with the level of oxidation. Isomers coming from linolenic acid in soybean oil and those from linoleic acid in olive oil decreased remarkably at a high level of oxidation.     

Mechanisms of DNA damage induced by morin,an inhibitor of amyloid β-peptide aggregation

Morin is a potential inhibitor of amyloid β-peptide aggregation. This aggregation is involved in the pathogenesis of Alzheimer’s disease. Meanwhile, morin has been found to be mutagenic and exhibits peroxidation of membrane lipids concurrent with DNA strand breaks in the presence of metal ions. To clarify a molecular mechanism of morin-induced DNA damage, we examined the DNA damage and its site specificity on ³²P-5′-end-labeled human DNA fragments treated with morin plus Cu(II). The formation of 8-oxo-7,8-dihydro-2′-deoxyguanosine (8-oxodG), an indicator of oxidative DNA damage, was also determined in calf thymus DNA treated with morin plus Cu(II). Morin-induced DNA strand breaks and base modification in the presence of Cu(II) were dose dependent. Morin plus Cu(II) caused piperidine-labile lesions preferentially at thymine and guanine residues. The DNA damage was inhibited by methional, catalase and Cu(I)-chelator bathocuproine. The typical ?OH scavengers ethanol, mannitol and sodium formate showed no inhibitory effect on DNA damage induced by morin plus Cu(II). When superoxide dismutase was added to the solution, DNA damage was not inhibited. In addition, morin plus Cu(II) increased 8-oxodG formation in calf thymus DNA fragments. We conclude that morin undergoes autoxidation in the presence of Cu(II) via a Cu(I)/Cu(II) redox cycle and H₂O₂ generation to produce Cu(I)-hydroperoxide, which causes oxidative DNA damage.