Myricitrin as a substrate and inhibitor of myeloperoxidase: implications for the pharmacological effects of flavonoids

Flavonoids are increasingly being ingested by the general population as chemotherapeutic and anti-inflammatory agents. They are potentially toxic because of their conversion to free radicals and reactive quinones by peroxidases. Little detailed information is available on how flavonoids interact with myeloperoxidase, which is the predominant peroxidase present at sites of inflammation. This enzyme uses hydrogen peroxide to oxidize chloride to hypochlorous acid, as well as to produce an array of reactive free radicals from organic substrates. We investigated how the flavonoid myricitrin is oxidized by myeloperoxidase and how it affects the activities of this enzyme. Myricitrin was readily oxidized by myeloperoxidase in the presence of hydrogen peroxide. Its main oxidation product was a dimer that underwent further oxidation. In the presence of glutathione, myricitrin was oxidized to a hydroquinone that was conjugated to glutathione. When myeloperoxidase oxidized myricitrin and related flavonoids it became irreversibly inactivated. The number of hydroxyl groups in the B ring of the flavonoids and the presence of a free hydroxyl m-phenol group in the A ring were important for the inhibitory effects. Less enzyme inactivation occurred in the presence of chloride. Neutrophils also oxidized myricitrin to dimers in a reaction that was partially dependent on myeloperoxidase. Myricitrin did not affect the production of hypochlorous acid by neutrophils. We conclude that myricitrin will be oxidized by neutrophils at sites of inflammation to produce reactive free radicals and quinones. It is unlikely to affect hypochlorous acid production by neutrophils.     

Cross linking of proteins in vitro by peroxidase

The enzyme peroxidase, a substrate (hydrogen donor), and hydrogen peroxide aggregated and polymerized soluble proteins included in the reaction mixture. Gel filtration and acrylamide disk gel electrophoresis revealed newly formed dimers, trimers, and higher protein polymers. Some of the protein polymers withstood the denaturing conditions of dodecyl sulfate disk gel electrophoresis; thus the formation of some covalent cross links was indicated. It is suggested that peroxidase catalyzes the oxidation of hydrogen donors to form free radicals or quinones, which subsequently interact with, cross link, and alter the soluble proteins.     

The involvement of biological quinones in the formation of hydroxyl radicals via the Haber-Weiss reaction

The present investigation was made to evaluate biologically relevant quinones as possible catalysts in the generation of hydroxyl radicals from hydrogen peroxide and superoxide radicals. ESR spectra demonstrated that menadione, plastoquinone, and ubiquinone derivatives could all be reduced to their semiquinone forms by electron transfer from superoxide radicals. Reductive homolytic cleavage of H₂O₂ was observed to be dependent upon the presence of semiquinones in the reaction medium. Our data strongly support the concept that quinones normally involved in physiological processes may also play a role as catalysts of the Haber-Weiss reaction in the biological generation of hydroxyl radicals.     

Lipid peroxidation initiated by superoxide-dependent hydroxyl radicals using complexed iron and hydrogen peroxide

Iron salts stimulate lipid peroxidation by decomposing lipid peroxides to produce alkoxyl and peroxyl radicals which initiate further oxidation. In aqueous solution ferrous salts produce OH. radicals, a reactive species able to abstract hydrogen atoms from unsaturated fatty acids, and so can initiate lipid peroxidation. When iron salts are added to lipids, containing variable amounts of lipid peroxide, the former reaction is favoured and OH. radicals contribute little to the observed rate of peroxidation. When iron is complexed with EDTA, however, lipid peroxide decomposition is prevented, but the complex reacts with hydrogen peroxide to form OH. radicals which are seen to initiate lipid peroxidation. Superoxide radicals appear to play an important part in reducing the iron complex.     

Inactivation of Ascorbate Peroxidase by Thiols Requires Hydrogen Peroxide

The hydrogen peroxide-dependent oxidation of ascorbate by ascorbateperoxidase from tea leaves was inhibited by thiols, such asdithiothreitol, glutathione, mercaptoethanol and cysteine. Thesethiols themselves did not inactivate the enzyme. However, theyinactivated the enzyme when hydrogen peroxide was produced bythe metal-catalyzed oxidation of thiols or when exogenous hydrogenperoxide was added. Thiols were oxidized by ascorbate peroxidaseand hydrogen peroxide to thiyl radicals, as detected by theESR spectra of the thiyl radical-5,5'-dimethyll- pyrroline-N-oxidieadducts. Inactivation of ascorbate peroxidase by thiols andhydrogen peroxide is caused by the interaction of the enzymewith the thiyl radicals produced at its reaction center. (Received September 10, 1991; Accepted December 9, 1991)     

Opposite effects of peroxidase in the initial stages of tyrosinase-catalysed melanin biosynthesis

The tyrosinase/oxygen enzymatic system catalyses the orthohydroxylation of L-tyrosine to L-dopa and the oxidation of this to dopaquinone, which evolves non-enzymatically towards to form melanins. The literature has demonstrated and revised the existence of peroxidase/hydrogen peroxide in the melanosomas of skin melanocytes, but points to controversy concerning the effects on melanogenesis. Some authors have recently proposed a new physiological function for tyrosinase, namely the direct scavenging of tyrosyl radicals, which are toxic oxidants of melanocytes. In this contribution, we describe and interpret four effects of peroxidase/hydrogen peroxide on melanogenesis. Two of these effects are its antagonism and synergy as regards the monophenolase and diphenolase activities, respectively, of tyrosinase/oxygen in the initial steps that trigger melanogenesis. Another effect concerns the increase in the oxidant character of the medium in the melanosome by increasing the synthesis of oxidising quinones (o-dopaquinone, p-topaquinone, dopachrome) and the consumption of antioxidant diphenols (L-dopa), which are intermediate biomolecules in melanogenesis. Lastly, we demonstrate that the tyrosyl radicals generated by light or by the peroxidase/hydrogen peroxide system are not directly trapped by the tyrosinase but by the antioxidant orthodiphenol, L-dopa, accumulated in the steady-state of melanogenesis. In conclusion, peroxidase/hydrogen peroxide may help regulate the development of melanogenesis and the oxidant environment within the melanosome. This enzyme deserves further study for its possible antitumoral and depigmentation capacities in skin cancer and hyperpigmentation.     

A Photochemical System for Generating Free Radicals: Superoxide, Phenoxyl, Ferryl and Methyl

The photosensitizer flavin mononucleotide (FMN), in conjunction with the reducing agents diethylenetria-minepentaacetic acid (DTPA), hydrazine and hydroxylamines derived from nitroxides, generates superoxide radicals in a strictly light-dependent reaction in aerobic solution. Addition of superoxide dismutase (SOD) converts this system to a hydrogen peroxide generator. In the presence of horseradish peroxidase the latter system becomes a phenoxyl radical generator with appropriate phenolic substrates. Under anaerobic conditions FMN, hydrogen peroxide and an iron chelate generate ferryl and when this system is combined with dimethylsulfoxide, methyl radicals are produced. All the radicals can be generated with little contamination from other radicals, in high yields and the reaction can be terminated immediately upon cessation of illumination. Useful applications of this photochemical system include ESR studies of transient free radical species.     

Oxidation of the substituted catechols dihydroxyphenylalanine methyl ester and trihydroxyphenylalanine by lactoperoxidase and its compounds

The reactions of native lactoperoxidase and its compound II with two substituted catechols have been investigated by ESR spin stabilization and spin trapping and by rapid scan and conventional spectrophotometric techniques. The catechols are Dopa methyl ester (dihydroxyphenylalanine methyl ester) and 6-hydroxy-Dopa (trihydroxyphenylalanine). o-Semiquinone radicals are formed in the anaerobic reaction of Dopa methyl ester with hydrogen peroxide catalyzed by native lactoperoxidase. The comparable anaerobic reaction of 6-hydroxy-Dopa appears to produce hydroxyl radicals in an unusual reaction. Compound II is reduced back to native lactoperoxidase by both catechols. The reaction between Dopa methyl ester and compound II undergoes an oscillation. The results on the overall lactoperoxidase cycle indicate two successive one-electron reductions of the peroxidase intermediates back to the native enzyme. The resulting free radical formation of o- and p-semiquinones and subsequent formation of stable quinones and Dopachromes is dependent upon the stereochemical arrangement of the catechol hydroxyl groups.     

Hydroxylated metabolites of the antimalarial drug primaquine. Oxidation and redox cycling.

Oxidation and redox cycling of the hydroxylated metabolites of the antimalarial drug primaquine (i.e. 5-hydroxyprimaquine, 5-hydroxydemethylprimaquine, and 5,6-dihydroxy-8-aminoquinoline) were studied. The three metabolites readily oxidized under physiological conditions, forming hydrogen peroxide and the corresponding quinone-imine derivatives as the main products. The latter compounds were characterized by visible, NMR, and infrared spectroscopy. Concomitant formation of drug-derived radicals and hydroxyl radicals was attested by direct and spin-trapping EPR experiments, respectively. The use of the spin stabilization method indicated that the radicals derived from 5-hydroxydemethylprimaquine and 5,6-dihydroxy-8-aminoquinoline are of the o-semiquinone type. Tentative structures are proposed for the radicals based on product identification and computer simulation of the experimental EPR spectra. The quinone-imines obtained from the reduced metabolites did not react at appreciable rates with NADPH but underwent redox cycling upon addition of ferredoxin:NADP+ oxidoreductase, forming hydrogen peroxide and hydroxyl radicals. The effect of antioxidant enzymes on hydroxyl radical yield obtained during oxidation and redox cycling indicates that the main route for hydroxyl radical formation is the metal ion-catalyzed reaction between the drug-derived radicals and hydrogen peroxide. Taken together, the results indicate that hydrogen peroxide is the potential toxic product formed from the primaquine metabolites.     

Quinone mediated ATP production in the filarial parasite Setaria digitata

The cattle filarial parasite Setaria digitata, a facultative anaerobe which is reported to be cyanide insensitive, lacks cytochromes and presents many unique characters. Experiments showed the occurrence of two lower quinones Q6 and Q8 and its rapid synthesis is revealed by a [14C] acetate incorporation study. A schematic quinone mediated hydrogen peroxide production with the generation of ATP through oxidation of substrates has been proposed. Search for specific blockers at the level of quinone might prove to be an effective measure for the control of filarial parasites and thereby filariasis.     

Reaction of hydrogen peroxide with ferrylhemoglobin: superoxide production and heme degradation

The reaction of Fe(II) hemoglobin (Hb) but not Fe(III) hemoglobin (metHb) with hydrogen peroxide results in degradation of the heme moiety. The observation that heme degradation was inhibited by compounds, which react with ferrylHb such as sodium sulfide, and peroxidase substrates (ABTS and o-dianisidine), demonstrates that ferrylHb formation is required for heme degradation. A reaction involving hydrogen peroxide and ferrylHb was demonstrated by the finding that heme degradation was inihibited by the addition of catalase which removed hydrogen peroxide even after the maximal level of ferrylHb was reached. The reaction of hydrogen peroxide with ferrylHb to produce heme degradation products was shown by electron paramagnetic resonance to involve the one-electron oxidation of hydrogen peroxide to the oxygen free radical, superoxide. The inhibition by sodium sulfide of both superoxide production and the formation of fluorescent heme degradation products links superoxide production with heme degradation. The inability to produce heme degradation products by the reaction of metHb with hydrogen peroxide was explained by the fact that hydrogen peroxide reacting with oxoferrylHb undergoes a two-electron oxidation, producing oxygen instead of superoxide. This reaction does not produce heme degradation, but is responsible for the catalytic removal of hydrogen peroxide. The rapid consumption of hydrogen peroxide as a result of the metHb formed as an intermediate during the reaction of reduced hemoglobin with hydrogen peroxide was shown to limit the extent of heme degradation.     

Intermediate Tyrosyl Radical and Amyloid Structure in Peroxide-Activated Cytoglobin

We characterized the peroxidase mechanism of recombinant rat brain cytoglobin (Cygb) challenged by hydrogen peroxide, tert-butylhydroperoxide and by cumene hydroperoxide. The peroxidase mechanism of Cygb is similar to that of myoglobin. Cygb challenged by hydrogen peroxide is converted to a Fe⁴⁺ oxoferryl π cation, which is converted to Fe⁴⁺ oxoferryl and tyrosyl radical detected by direct continuous wave-electron paramagnetic resonance and by 3,5-dibromo-4-nitrosobenzene sulfonate spin trapping. When organic peroxides are used as substrates at initial reaction times, and given an excess of peroxide present, the EPR signals of the corresponding peroxyl radicals precede those of the direct tyrosyl radical. This result is consistent with the use of peroxide as a reducing agent for the recycling of Cygb high-valence species. Furthermore, we found that the Cygb oxidation by peroxides leads to the formation of amyloid fibrils. This result suggests that Cygb possibly participates in the development of degenerative diseases; our findings also support the possible biological role of Cygb related to peroxidase activity.     

Enhancement of Lipid Peroxidation by Indole-3-Acetic Acid and Derivatives: Substituent Effects

The peroxidation of liposomes by a haem peroxidase and hydrogen peroxide in the presence of indole-3-acetic acid and derivatives was investigated. It was found that these compounds can accelerate the lipid peroxidation up to 65 fold and this is attributed to the formation of peroxyl radicals that may react with the lipids, possibly by hydrogen abstraction. The peroxyl radicals are formed by peroxidase-catalyzed oxidation of the enhancers to radical cations which undergo cleavage of the carbon-carbon bond on the side-chain to yield CO2 and carbon-centred radicals that rapidly add oxygen. In competition with decarboxylation, the radical cations deprotonate reversibly from the Nl position. Rates of decarboxylation,pK_a values and rate of reaction with the peroxidase compound I indicate consistent substituent effects which, however, can not be quantitatively related to the usual Hammett or Brown parameters. Assuming that the rate of decarboxylation of the radical cations taken is a measure of the electron density of the molecule (or radical), it is found that the efficiency of these compounds as enhancers of lipid peroxidation increases with increasing electron density, suggesting that, at least in the model system, the oxidation of the substrates is the limiting step in causing lipid peroxidation.     

Redox cycling of potential antitumor aziridinyl quinones

The formation of reactive oxygen intermediates (ROI) during redox cycling of newly synthesized potential antitumor 2,5-bis (1-aziridinyl)-1,4-benzoquinone (BABQ) derivatives has been studied by assaying the production of ROI (superoxide, hydroxyl radical, and hydrogen peroxide) by xanthine oxidase in the presence of BABQ derivatives. At low concentrations (< 10 microM) some BABQ derivatives turned out to inhibit the production of superoxide and hydroxyl radicals by xanthine oxidase, while the effect on the xanthine-oxidase-induced production of hydrogen peroxide was much less pronounced. Induction of DNA strand breaks by reactive oxygen species generated by xanthine oxidase was also inhibited by BABQ derivatives. The DNA damage was comparable to the amount of hydroxyl radicals produced. The inhibiting effect on hydroxyl radical production can be explained as a consequence of the lowered level of superoxide, which disrupts the Haber-Weiss reaction sequence. The inhibitory effect of BABQ derivatives on superoxide formation correlated with their one-electron reduction potentials: BABQ derivatives with a high reduction potential scavenge superoxide anion radicals produced by xanthine oxidase, leading to reduced BABQ species and production of hydrogen peroxide from reoxidation of reduced BABQ. This study, using a unique series of BABQ derivatives with an extended range of reduction potentials, demonstrates that the formation of superoxide and hydroxyl radicals by bioreductively activated antitumor quinones can in principle be uncoupled from alkylating activity.     

Inhibition of the Fenton reaction by the protein caeruloplasmin and other copper complexes. Assessment of ferroxidase and radical scavenging activities

The copper-containing protein caeruloplasmin is an important biological extracellular protein. By catalysing the oxidation of ferrous ions to the ferric state (ferroxidase activity) it can inhibit lipid peroxidation and the Fenton reaction. This activity is readily destroyed by heat-denaturation. When a ferric-EDTA complex is added to hydrogen peroxide, OH X radicals are formed in a reaction inhibitable by superoxide dismutase (SOD). This reaction is also inhibited by caeruloplasmin both before and after heat-denaturation, suggesting a non-catalytic scavenging role for the protein. A combination of ferroxidase and radical scavenging activities in fluids containing iron complexes and hydrogen peroxide, but no SOD or catalase, would make caeruloplasmin an important extracellular antioxidant.     

Manganese-lignin peroxidase hybrid from Bjerkandera adusta oxidizes polycyclic aromatic hydrocarbons more actively in the absence of manganese

We studied polycyclic aromatic hydrocarbon (PAH) oxidation using whole cells and purified manganese-lignin peroxidase (MnLiP) from Bjerkandera adusta UAMH 8258. Although the metabolism of PAHs by B. adusta has been previously demonstrated, less than 5% mineralization of 14C-labelled PAHs occurred in this study over a 40-day period. Oxidation of PAHs was examined by a purified MnLiP hybrid isoenzyme in the presence and absence of manganous ions. The rate of PAH oxidation was decreased by the presence of Mn. The substrates were anthracene and its methyl derivatives, pyrene and benzo[a]pyrene, PAHs with ionization potentials of 7.43 eV or lower. The PAH metabolites of the Mn-independent reaction were identified as the corresponding quinones. The pH optimum of the Mn-independent oxidation was generally about 4, while for the Mn-dependent reaction it was 3. The kinetic constants for the Mn-independent oxidation of 2-methylanthracene at pH 4 were determined, and the values we obtained were a kcat of 145/min, KM,app of 23.8 mmol/L for the aromatic substrate, and KM,app of 0.2 mmol/L for hydrogen peroxide. This is the first report of PAH oxidation by a MnLiP hybrid isoenzyme from white rot fungi.     

DNA cleavage by hydroxyl radicals generated in a vanadyl ion-hydrogen peroxide system.

Vanadyl ion (+4 oxidation state) has been shown to be an effective agent for chemoprotection of cancers in animals. For understanding the mechanism, distribution of vanadium was studied. More vanadium was found to accumulate in the nuclei of the liver of rats when it was given as vanadyl sulfate than when it was given as sodium vanadate (+5 oxidation state). The reactivity of vanadyl ion with DNA was investigated by the DNA cleavage technique and the reaction mechanism by ESR spectroscopy. Incubation of double-strand DNA with vanadyl ion and hydrogen peroxide resulted in marked concentration- and pH-dependent DNA cleavage. Studies by the ESR spin-trap method demonstrated that hydroxyl radicals are generated during the reactions of vanadyl ion with hydrogen peroxide. Thus the antineoplastic action of vanadyl ion is proposed to be due to DNA cleavage by hydroxyl radicals generated in the cells.     

The cellobiose-oxidizing enzymes CBQ and CbO as related to lignin and cellulose degradation — a review

Abstract: In this review properties of cellobiose:quinone oxidoreductase (CBQ) and cellobiose oxidase (CbO) are presented and their possible involvement in lignin and cellulose degradation is discussed. Although these enzymes are produced by many different fungi, their importance for wood-degrading fungi is the topic here. CBQ is a FAD enzyme, while CbO also contains a heine group of the cytochrome b type. Protease activity is reported to convert CbO to CBQ. During oxidation of cellobiose (emanating from cellulose) to cellobiono-l,5-lactone, both enzymes reduce quinones produced by laccase and peroxidase during lignin degradation to the corresponding phenols. Many phenoxy and cation radicals are also reduced. Quinone reduction is more rapid than oxygen reduction, although oxygen is slowly reduced to superoxide and/or hydrogen peroxide. Thus, a more appropriate name for CbO is cellobiose dehydrogenase. CbO also reduces Fe(III) and together with hydrogen peroxide produced by the enzyme Fenton's reagent may be formed, resulting in hydroxyl radical production. This radical can degrade both lignin and cellulose, possibly indicating that cellobiose oxidase has a central role in degradation of wood by wood-degrading fungi.     

Oxidation of Dimethylsulphoxide to Formaldehyde by Oxyhaemoglobin and Oxyleghaemoglobin in the Presence of Hydrogen Peroxide is Not Mediated by “Free” Hydroxyl Radicals

In the presence of excess hydrogen peroxide. human oxyhaemoglobin and oxyleghaemoglobin from soybean root nodules cause oxidation of dimethylsulphoxide to formaldehyde. This reaction is inhibited by thiourea but not by phenylalanine. HEPES. mannitol or arginine. It is concluded that dimethylsulphoxide oxidation is not mediated by “free” hydroxyl radicals. consistent with previous conclusions that intact haemoglobin, leghaemoglobin or myoglobin molecules do not react with H₂O₂ to form hydroxyl radicals detectable outside the protein.     

Albumin oxidation to diverse radicals by the peroxidase activity of Cu,Zn-superoxide dismutase in the presence of bicarbonate or nitrite: diffusible radicals produce cysteinyl and solvent-exposed and -unexposed tyrosyl radicals

The peroxidase activity of Cu,Zn-superoxide dismutase (Cu,Zn-SOD) has been extensively studied in recent years due to its potential relationship to familial amyotrophic lateral sclerosis. The mechanism by which Cu,Zn-SOD/hydrogen peroxide/bicarbonate is able to oxidize substrates has been proposed to be dependent on an oxidant whose nature, diffusible carbonate radical anion or enzyme-bound peroxycarbonate, remains debatable. One possibility to distinguish these species is to examine whether protein targets are oxidized to protein radicals. Here, we used EPR methodologies to study bovine serum albumin (BSA) oxidation by Cu,Zn-SOD/hydrogen peroxide in the absence and presence of bicarbonate or nitrite. The results showed that BSA oxidation in the presence of bicarbonate or nitrite at pH 7.4 produced mainly solvent-exposed and -unexposed BSA-tyrosyl radicals, respectively. Production of the latter was shown to be preceded by BSA-cysteinyl radical formation. The results also showed that hydrogen peroxide/bicarbonate extensively oxidized BSA-cysteine to the corresponding sulfenic acid even in the absence of Cu,Zn-SOD. Thus, our studies support the idea that peroxycarbonate acts as a two-electron oxidant and may be an important biological mediator. Overall, the results prove the diffusible and radical nature of the oxidants produced during the peroxidase activity of Cu,Zn-SOD in the presence of bicarbonate or nitrite.