Antioxidant activity of flavonoids and reactivity with peroxy radical

The autoxidation of linoleic acid and methyl linolenate is inhibited by flavonoids. The antioxidant efficiency of these flavonoids increases with their concentration and in the order fustin < catechin < quercetin < rutin = luteolin < kaempferol < morin for linoleic acid and rutin < catechin < morin = kaempferol for methyl linolenate. Flavonoids are more effective on linoleic acid than on methyl linolenate. The antioxidant activity offlavonoids is related to an inhibition of the formation of trans,trans hydroperoxide isomers of linoleic acid. This inhibition exhibited the great H-atom donating ability of flavonoids to peroxy radical, thus terminating the chain radical reaction.     

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.     

Site-specific DNA damage caused by lipid peroxidation products

DNA damage induced by autoxidized lipids was investigated using covalently closed circular (supercoiled) DNA and DNA fragments of defined sequence. DNA-strand-breaking substances accumulated during autoxidation of methyl linolenate, and strand breakage was measured with samples taken at different times. The DNA-strand-breaking activity reached its maximum a little after the peak value of peroxide and decreased upon further autoxidation. The peak of the DNA-strand-breaking activity did not always coincide with the peak of thiobarbituric acid reactants or of conjugated diene, either. The DNA-strand-breaking reaction was dependent on metal ions and was inhibited by potassium iodide and tiron and partially by catalase, suggesting the involvement of radical species and/or oxygen radicals. No direct cleavage of singly end-labeled 100-200 basepair DNA fragments by autoxidized methyl linolenate and cupric ion was detected under the conditions used. Cleavage occurred during subsequent heating in piperidine after the reaction. The alkali-labile damage was preferentially induced at pyrimidine residues, especially in dinucleotide sequences of pyrimidine-guanine (5'----3'), which was determined by sequencing.     

On the autoxidation of bilirubin.

The instability of oxygenated aqueous solutions of bilirubin in the dark is due to several distinguishable processes: autoxidation, surface phenomena and precipitation-aggregation. Autoxidation occurs in aqueous solutions over a pH range 7.4–13.2 in the presence of even traces of oxygen. Several autoxidation products have been isolated and identified. At pH 7.4–8.8 bilirubin precipitates from 2.5 × 10^?5 M solutions and adsorbs to the walls of the glass container. In ammoniacal methanol, chloroform and dimethyl sulfoxide aggregation phenomena do not occur and autoxidation is very slow.     

Synthesis and properties of methyl 9,12,15-octadecatrienoate geometric isomers

The eight geometrically isomeric methyl 9,12,15-octadecatrienoates were prepared by using the Wittig reaction to couple cis- or trans-3-hexyenyltriphenylphosphonium bromide and methyl 12-oxo-cis- or trans-9-dodecenoate. Pairs of geometric triene isomers formed were separated by partial silver resin chromatography. Physical constants including melting points, percent trans by infrared, equivalent chain lengths (ECL), and ¹³C nuclear magnetic resonance (NMR) chemcial shifts are tabulated for the individual isomers.     

Mechanisms for the formation of isoprostane endoperoxides from arachidonic acid. "Dioxetane" intermediate versus beta-fragmentation of peroxyl radicals

The isoprostanes are a class of autoxidation products generated from arachidonic acid (or its esters) by a free radical initiated process. The potent biological activity of these compounds has been attracting intense research interest since they were detected in humans as well as animal models in the early 1990s. The measurement of these compounds has been regarded as one of the most useful non-invasive biomarkers for oxidative stress status. Two mechanisms for the formation of these compounds have been proposed. In the first mechanism, a peroxyl radical undergoes successive 5-exo cyclizations analogous to the enzymatic mechanism proposed for prostaglandin biosynthesis. The second mechanism starts with a 4-exo cyclization of a peroxyl radical leading to an intermediate dioxetane, a mechanism that has also been proposed for prostaglandin biosynthesis as well as for the formation of 4-hydroxy nonenal (HNE). Autoxidation of cholesteryl-15-HpETE under free radical conditions provides Type IV isoprostanes. The "dioxetane" mechanism for isoprostane generation from 15-HpETE requires that optically pure products are formed from an optically pure reactant, whereas an alternate mechanism for the process involving beta-fragmentation of the 15-peroxyl would give racemic isoprostane products. We have carried out a test of the mechanism based upon these stereochemical requirements. The results of analysis of the product mixture derived from autoxidation of optically pure Ch-15-HpETE by atmospheric pressure chemical ionization-mass spectrometry coupled with chiral high performance liquid chromatography indicate that the major isoprostane diastereomers are formed as a racemic mixture. These experimental results are consistent with a mechanism for isoprostane formation involving beta-fragmentation of the 15-peroxyl radical followed by re-addition of oxygen to form the 11-HPETE peroxyl, and they exclude a mechanism proceeding through the formation of a dioxetane intermediate.     

Esr Detection of Free Radical Intermediates During Autoxidation Of 5-Hydroxyprimaquine

Autoxidation of 5–hydroxyprimaquine, a putative metabolite of the antimalarial primaquine, was studied by oxygen consumption and ESR spectroscopy. 5–Hydroxyprirnaquine undenvent fast autoxidation under mild conditions (pH 7.4-8. 5, 25°C. and presence of I mM diethylenetriamine pentaacetic acid); each mol of the drug consumed 0.75 mol of oxygen and formed 0.5 mol of hydrogen peroxide. Direct-ESR experiments demonstrated that 5–hydroxyprimaquine autoxidation was accompanied by generation of a drug-derived free radical that is oxygen sensitive. Generation of hydroxyl radical was also established by spin-trapping experiments in the presence of 5,5–dimethyl-l-pyrroline N-oxide. The effect of antioxidant enzymes on hydroxyl radical adduct yield and analysis of autoxidation stoichiometry suggest that the main route for hydroxyl radical generation is the iron-catalyzed reaction between the drug-derived free radical and hydrogen peroxide.     

Transformation of Metalaxyl by the Fungus Syncephalastrum racemosum

The fungus Syncephalastrum racemosum (Cohn) Schroeter was found to transform the fungicide metalaxyl [N-(2,6-dimethylphenyl)-N-(methoxyacetyl)-alanine methyl ester] in pure culture. After 21 days of incubation in a basal medium amended with 5 μg of metalaxyl per ml, more than 80% of the compound was transformed by the fungus. The transformation rates decreased as the concentrations of metalaxyl increased from 5 to 100 μg/ml. No transformation was observed when the concentration of metalaxyl was higher than 200 μg/ml. Two isomeric metabolites and a mixture of two other isomeric metabolites were isolated from the organic extract of the growth medium and identified as N-(2-methyl-6-hydroxymethylphenyl)-N- and N-(2-hydroxymethyl-6-methylphenyl)-N-(methoxyacetyl)-alanine methyl ester and N-(3-hydroxy- and N-(5-hydroxy-2,6-dimethyl-phenyl)-N-(methoxyacetyl)-alanine methyl ester according to their mass-spectral and nuclear magnetic resonance-spectral characteristics. Benzylic hydroxylation of the methyl side chains and/or aromatic hydroxylation appeared to be the major reactions involved in the metabolism of metalaxyl.     

Monohydroperoxides Formed by Autoxidation and Photosensitized Oxidation of Methyl Eicosapentaenoate

Methyl eicosapentaenoate (methyl 5,8,11,14,17-eicosapentaenoate) was subjected to autoxidation and methylene blue sensitized photooxidation. Methyl eicosapentaenoate monohydroperoxides, the primary products of the autoxidation and photosensitized oxidation, were isolated by silica gel column chromatography, and characterized by ultraviolet, infrared and nuclear magnetic resonance spectra. The isomeric composition of the monohydroperoxides were determined by gas chromatography-mass spectrometry as follows: the 5-, 8-, 9-, 11-, 12-, 14-, 15- and 18-isomers (autoxidation), and the 5-, 6-, 8-, 9-, 11-, 12-, 14-, 15-, 17- and 18-isomers (photosensitized oxidation). Methyl eicosapentaenoate was readily oxidized both by autoxidation and by photosensitized oxidation.     

Geometrical Isomers of Monohydroperoxides Formed by Autoxidation of Methyl Linoleate

Isomeric monohydroperoxides produced from autoxidized methyl linoleate were separated into two geometrical isomers (cis-trans and trans-trans) by silver nitrate TLC. Purified monohydroperoxides were converted into hydroxy octadecadienoates. Trimethylsilyl (TMS) derivatives of these compounds (four components) were separated into three peaks in the gas chromatogram; the mixture of 9-hydroxy-cis,trans-isomer and 13-hydroxy-cis,trans-isomer, 9-hydroxy-trans,trans-isomer and 13-hydroxy-trans,trans-isomer. The trans-trans isomers became more dominant than the cis-trans isomers in the later stage of autoxidation and with the rise of temperature. At the degradation of monohydroperoxides, the decrease of trans- trans isomers was apparently slower than that of cis-trans isomers. It is proposed that cis,trans isomerization of monohydroperoxides takes place at the process of autoxidation of methyl linoleate.     

Prevention of sulfhydryl autoxidation by a polypeptide from red kidney beans, described to be a stimulator of RNA synthesis

The autoxidation of cysteine catalysed by ubiquitously occurring Cu²⁺ is prevented by reduced FV, a polypeptide isolated from red kidney beans and described earlier to be a stimulator of RNA synthesis. Without special precautions, amounts of copper sufficient to provoke a rapid autoxidation of cysteine are present in most biochemical and biological systems. Autoxidation of cysteine leads to the formation of H₂O₂, which suppresses the incorporation of labeled uridine into RNA, referred to as suppression of RNA synthesis, and, in addition, to a deficiency of cysteine in the medium. Reduced FV contains 19 mole per cent cysteine and is able to bind Cu²⁺ in a way that abolishes its catalytic activity. The stimulation of RNA synthesis exerted by reduced FV in bacteria and lymphocytes is explained by this inhibitory action on the autoxidation of cysteine, i.e. by the prevention of H₂O₂ formation and cysteine deficiency in the medium. It is suggested that sera and other blood components known to possess beneficial effects, or to be required, in cell culture in vitro, may act in a similar way.     

Effect of dietary conjugated linoleic acid isomers on water and glycerol permeability of kidney membranes

Conjugated linoleic acid (CLA) refers to a group of positional and geometrical isomers of linoleic acid in which the double bonds are conjugated. Dietary CLA has been associated with various health benefits although details of its molecular mode of action remain elusive. The effect of CLA supplemented to palm oil-based diets in Wistar rats, as a mixture of both or isolated c9,t11 and t10,c12 isomers, was examined on water and glycerol membrane permeability of kidney proximal tubule. Although water permeability was unaltered, an increase in glycerol permeability was obtained for the group supplemented with CLA mixture, even though the activation energy for glycerol permeation remained high. This effect was correlated with an increased CLA isomeric membrane incorporation for the same dietary group. These results suggest that diet supplementation with CLA mixture, in contrast to its individual isomers, may enhance membrane fluidity subsequently raising kidney glycerol reabsorption.     

Preparation of mitochondrial membrane proteins fromNeurospora crassa: prevention of lipid autoxidation damage by an antioxidant

Lipid autoxidation products, such as malonaldehyde, react with proteins, cross-linking them and decreasing their solubility. These reactions are of practical importance in experiments with membranes where lipids and proteins are closely associated.When no precautions against lipid autoxidation were taken, both aged and freshly prepared mitochondrial membrane proteins fromNeurospora crassa contained 1-amino-3-iminopropene groups formed by reaction of protein amino groups with malonaldehyde. This conclusion was derived by analysis of fluorescence emission, fluorescence polarization, the effect of porohydride reduction upon the fluorescence, and qualitative and quantitative determination of malonaldehyde with 4,4′-sulfonyldianiline after hydrolysis of the proteins.The efficiency of antioxidants in the prevention of lipid autoxidation and consequent modification of protein was tested in a model system consisting of an aerated, aqueous solution of albumin, and methyl linolenate. The antioxidant, 3,5-ditert-butyl-4-hydroxybenzylalcohol, a sterically hindered phenol, appeared to be highly efficient in either the model system or in the isolation of membrane proteins. Mitochondrial membrane proteins, prepared in parallel procedure in the presence and absence of this antioxidant, differed in malonaldehyde concentration, iminopropene fluorescence and electrophoretic mobility.Several unusual properties of aged membrane proteins, such as low solubility, resistance to trypsin hydrolysis, and changes in isoelectric points and electrophoretic mobilities can be explained as consequences of lipid autoxidation processes.We suggest that antioxidants, such as sterically hindered phenols, be employed in the preparation and storage of proteins from membranes or other systems containing large amounts of lipids or unsaturated fatty acids in order to prevent artifactual modification of the proteins by lipid autoxidation products.     

Implications of cholesterol autoxidation products in the pathogenesis of inflammatory diseases

There is rising interest in non-enzymatic cholesterol oxidation because the resulting oxysterols have biological activity and can be used as non-invasive markers of oxidative stress in vivo. The preferential site of oxidation of cholesterol by highly reactive species is at C₇ having a relatively weak carbon–hydrogen bond. Cholesterol autoxidation is known to proceed via two distinct pathways, a free radical pathway driven by a chain reaction mechanism (type I autoxidation) and a non-free radical pathway (type II autoxidation). Oxysterols arising from type II autoxidation of cholesterol have no enzymatic correlates, and singlet oxygen (¹ΔgO₂) and ozone (O₃) are the non-radical molecules involved in the mechanism. Four primary derivatives are possible in the reaction of cholesterol with singlet oxygen via ene addition and the formation of 5α-, 5β-, 6α- and 6β-hydroxycholesterol preceded by their respective hydroperoxyde intermediates. The reaction of ozone with cholesterol is very fast and gives rise to a complex array of oxysterols. The site of the initial ozone reaction is at the Δ_5,6 –double bond and yields 1,2,3-trioxolane, a compound that rapidly decomposes into a series of unstable intermediates and end products. The downstream product 3β-hydroxy-5-oxo-5,6-secocholestan-6-al (sec-A, also called 5,6-secosterol), resulting from cleavage of the B ring, and its aldolization product (sec-B) have been proposed as a specific marker of ozone-associated tissue damage and ozone production in vivo. The relevance of specific ozone-modified cholesterol products is, however, hampered by the fact sec-A and sec-B can also arise from singlet oxygen via Hock cleavage of 5α-hydroperoxycholesterol or via a dioxietane intermediate. Whatever the mechanism may be, sec-A and sec-B have no enzymatic route of production in vivo and are reportedly bioactive, rendering them attractive biomarkers to elucidate oxidative stress-associated pathophysiological pathways and to develop pharmacological agents.     

Lipid oxidation in biological membranes. Electron transfer proteins as initiators of lipid autoxidation.

Biological lipid autoxidation has been studied in a model system composed of sonicated phospholipids as substrate and electron transfer proteins found in membranes as possible catalysts. Heme compounds, flavoproteins, and iron-sulfur proteins were examined for their ability to initiate lipid autoxidation. Among many heme compounds tested, the most active were hematin ?microperoxidase ? methemoglobin > cytochrome c. With fresh preparations of phospholipids, reaction rates (nanomoles of oxygen/minute nanomoles of heme) ranged from 5 (cytochrome c) to 350 (hematin). Only the oxidized heme compounds were active as catalysts. Reduced heme compounds, flavoproteins and riboflavin were inactive. In the presence of heme compounds, aged preparations of sonicated phospholipids were much more rapidly oxidized than fresh preparations. They also had a higher content of fatty acid hydroperoxides as judged from their characteristic diene absorption peak at 234 nm. This observation agrees with the postulated mechanism of lipid autoxidation by heme compounds, namely, homolytic scission of preformed fatty acid hydroperoxides. Iron-sulfur proteins were also active as initiators of lipid autoxidation when destabilized in the presence of an appropriate iron chelator (o-phenanthroline or 2,2′-bipyridine) or a chaotropic ion. Oxygen uptake rates (nanomoles of oxygen/minute × milligrams of protein) varied from about 200 for an iron-sulfur protein isolated from complex I to about 5500 for Clostridium pasteurianum ferredoxin. However, per nanomole of labile sulfide, the rates for all active iron-sulfur proteins were 4–7 nmol of oxygen/min × nmol of labile sulfide.Superoxide-generating systems did not initiate lipid autoxidation, nor did erythrocuprein inhibit the autoxidations induced by heme compounds or ferredoxin. However, lipid oxidations induced by two other iron-sulfur proteins were partially inhibited by erythrocuprein. It is concluded that in the above system Superoxide anion is neither an initiator nor an obligatory intermediate of lipid autoxidation.     

Further Oxygenated Compounds Produced from Methyl Linoleate Monohydroperoxides at the Process of Autoxidation

The primary stable products, methyl linoleate monohydroperoxides (MLHPO), formed by the autoxidation of methyl linoleate were characterized by gas chromatography-mass spectrometry. MLHPO was converted into methyl hydroxy stearates which consisted of two isomers, methyl 9-hydroxy and methyl 13-hydroxy stearate. Trimethylsilyl ether derivatives of these hydroxy isomers were separated directly by gas chromatography and mass fragmentgraphy. MLHPO was degradated by incubating under aerobic condition at 37°C for a week, and the quantity of MLHPO was determined as hydroxy derivatives. Decrease of MLHPO was almost similar to that of conjugated diene structure, but the peroxide value was not appreciably decreased during the incubation. This fact based on the formation of further oxygenated compounds. After chemical reduction, these compounds were identified as methyl 9,13-hydroxy octadecenoate and methyl 9,12,13- or 9,10,13-trihydroxy octadecenoate, in which oxygen attached to the conjugated diene. The formation mechanisms of these oxygenated compounds are proposed.     

Reaction of ethyl 2-amino-4,6-O-benzylidene-2-deoxy-d-gluconate with acetylenic esters

Ethyl 2-amino-4,6-O-benzylidene-2-deoxy-d-gluconate adds to acetylenic esters to give sugar enaminones. The following acetylene derivatives have been employed: methyl propiolate, ethyl phenylpropiolate, and dimethyl acetylenedicarboxylate (6). With compound 6, the reaction leads to a mixture of the expected enaminone and the isomeric oxazolidine derivative. The structures and configurations of the new compounds were studied by spectroscopic and chemical methods.     

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.     

Some Analytical Observations of Autoxidation Products of Linoleic Acid and Their Thiobarbituric Acid Reactive Substances

Autoxidation products of linoleic acid (LA) were analyzed, when the weight became 1.14-fold under the autoxidation conditions of satisfactory atmospheric oxygen, at 37°C, in the dark, for 7 days. The LA absorbed 2.8 mol of oxygen to form secondary degradation products. This autoxidized LA consisted of 45% intact substance, 22% a mixture of polymers and endoperoxides, 18% LA hydroperoxides, 3% polar products, 1.7% azelaldehydeic acid, 1.3% hexahal, 0.9% azelaic acid, 0.6% octanoic acid, 0.3% suberaldehydeic acid, and so on. Thus, unstable 2,4-dienoic carbonyls were the main intermediate products of autoxidation of LA. Therefore, malonaldehyde was not a main product nor a major thiobarbituric acid reactive substance.     

Chiral metal complexes. Part 22. Stereoisomers of the dichloro [3,6-diaza-2S,7S-di(2-pyridyl)octane] - cobalt(III) ion and related species

The reaction of 3,6-diaza-2S,7S-di(2-pyridyl)- octane, S,S-peaen, with Co(II) and O₂ in aqueous solution yields a mixture, from which may be isolated three chelate diastereomers after the addition of HCl and HClO₄. These are δ-α-[Co(S,S-peaen)Cl₂]- ClO₄ and its Λ-α and Δ-β analogues. Previous workers had reported that a second β-diastereoisomer could be obtained but it has been shown that this is in fact an isomeric mixture of both Δ-α- and Λ-α- [Co(S,S-peaen)Cl₂]ClO₄. All three isomers react with oxalate anions to form an apparently unique product Λ-α-[Co(S,S-peaen)ox]⁺ in aqueous solution and which can be crystallized as its perchlorate salt. Two of the reactions reported represent unusual examples of octahedral inversions.