Evidence for a free radical chain mechanism in the reaction between peroxidase and indole-3-acetic acid at neutral pH

The oxidation of indole-3-acetic acid (IAA) catalyzed by horseradish peroxidase (HRP) in the absence of added H2O2 was studied at pH 7.4 using spectral and kinetic approaches. Upon addition of a hundred-fold excess of IAA to HRP the native enzyme was rapidly transformed to compound II (HRP-II). HRP-II was the predominant catalytic enzyme species during the steady state. No compound III was observed. HRP-II was slowly transformed to the stable inactive verdohemo-protein, P-670. A precursor of P-670, so-called P-940 was not detected. After the cessation of IAA oxidation there was neither oxygen consumption nor P-670 formation; the remaining HRP-II was spontaneously reduced to native enzyme. Single exponential kinetics were observed in the steady state for IAA oxidation, oxygen consumption and P-670 formation yielding identical first order rate constants of about 6 . 10(4) s(-1). A comparison of the rate of IAA oxidation by HRP-II in the steady state and in the transient state indicated that more than 1 3 of the IAA was oxidized non-enzymatically during the steady state, confirming that a free radical chain reaction is involved in the peroxidase-catalyzed oxidation of IAA. IAA oxidation stopped before IAA was completely consumed, which cannot be ascribed to enzyme inactivation because 30-50% of the enzyme was still active after the end of the reaction. Instead, incomplete IAA oxidation is explained in terms of termination of the free radical chain reaction. Bimolecular rate constants of IAA oxidation by HRP-I and HRP-II determined under transient state conditions were (2.2 +/- 0.1) x 10(3) M(-1) s(-1) and (2.3 +/- 0.2) x 10(2) M(-1) s(-1).     

The mechanism of potentiation of horseradish peroxidase-catalysed oxidation of NADPH by porphyrins.

Several porphyrins, including HpD (haematoporphyrin derivative), potentiate the oxidation of NADPH by horseradish peroxidase/H2O2. To elucidate the mechanism of potentiation, the following observations are relevant. During peroxidase-catalysed NADPH oxidation, O2-.(superoxide radical) is generated, as judged from superoxide dismutase-inhibitable cytochrome c reduction. This generation of O2-. is suppressed by HpD. Peroxidase-catalysed NADPH oxidation is stimulated by superoxide dismutase and by anaerobic conditions. Under anaerobic conditions HpD has no influence on peroxide-catalysed NADPH oxidation. Previous studies have shown that horseradish peroxidase is inhibited by O2-.. Thus the experimental results indicate that the potentiating effect of HpD can be explained by its ability to inhibit O2-. generation in the horseradish peroxidase/H2O2/NADPH system.     

Oxidation of 4-tert-butylcatechol and dopamine by hydrogen peroxide catalysed by horseradish peroxidase.

The catalytic cycle of horseradish peroxidase (HRP; donor:hydrogen peroxide oxidoreductase; EC 1.11.1.7) is initiated by a rapid oxidation of it by hydrogen peroxide to give an enzyme intermediate, compound I, which reverts to the resting state via two successive single electron transfer reactions from reducing substrate molecules, the first yielding a second enzyme intermediate, compound II. To investigate the mechanism of action of horseradish peroxidase on catechol substrates we have studied the oxidation of both 4-tert-butylcatechol and dopamine catalysed by this enzyme. The different polarity of the side chains of both o-diphenol substrates could help in the understanding of the nature of the rate-limiting step in the oxidation of these substrates by the enzyme. The procedure used is based on the experimental data to the corresponding steady-state equations and permitted evaluation of the more significant individual rate constants involved in the corresponding reaction mechanism. The values obtained for the rate constants for each of the two substrates allow us to conclude that the reaction of horseradish peroxidase compound II with o-diphenols can be visualised as a two-step mechanism in which the first step corresponds to the formation of an enzyme-substrate complex, and the second to the electron transfer from the substrate to the iron atom. The size and hydrophobicity of the substrates control their access to the hydrophobic binding site of horseradish peroxidase, but electron density in the hydroxyl group of C-4 is the most important feature for the electron transfer step.     

Oxidase-peroxidase enzymes of Datura innoxia. Oxidation of formylphenylacetic acid ethyl ester.

An enzyme system from Datura innoxia roots oxidizing formylphenylacetic acid ethyl ester was purified 38-fold by conventional methods such as (NH4)2SO4 fractionation, negative adsorption on alumina Cy gel and chromatography on DEAE-cellulose. The purified enzyme was shown to catalyse the stoicheiometric oxidation of formylphenylacetic acid ethyl ester to benzoylformic acid ethyl ester and formic acid, utilizing molecular O2. Substrate analogues such as phenylacetaldehyde and phenylpyruvate were oxidized at a very low rate, and formylphenylacetonitrile was an inhilating agents, cyanide, thiol compounds and ascorbic acid. This enzyme was identical with an oxidase-peroxidase isoenzyme. Another oxidase-peroxidase isoenzyme which separated on DEAE-chromatography also showed formylphenylacetic acid ethyl ester oxidase activity, albeit to a lesser extent. The properties of the two isoenzymes of the oxidase were compared and shown to differ in their oxidation and peroxidation properties. The oxidation of formylphenylacetic acid ethyl ester was also catalysed by horseradish peroxidase. The Datura isoenzymes exhibited typical haemoprotein spectra. The oxidation of formylphenylacetic acid ethyl ester was different from other peroxidase-catalysed reactions in not being activated by either Mn2+ or monophenols. The oxidation was inhibited by several mono- and poly-phenols and by catalase. A reaction mechanism for the oxidation is proposed.     

A comparison of horseradish peroxidase and manganese ions as catalysts for the oxidation of dihydroxyfumaric acid

With horseradish peroxidase as catalyst the main product was dihydroxytartrate, but small amounts of glycolaldehyde, mesoxalic semialdehyde, mesoxalate and possibly glyoxal were also formed. Mn(2+) catalysis gave rise only to mesoxalate and oxalate. When oxygen uptake was followed by a manometric method the rate of the peroxidase-catalysed reaction was proportional to oxygen concentration and marked inhibition by cyanide was obtained only at low buffer concentration. The catalytic effects of peroxidase and Mn(2+) were almost always additive. Chelating agents inhibited the Mn(2+)-catalysed reaction, but had either no effect or a slight accelerating effect on the peroxidase-catalysed reaction. It is concluded that Mn(2+) does not function as cofactor in the peroxidase-catalysed oxidation.     

Anions activate the oxidation of indoleacetic Acid by peroxidases from tomato and other sources

Anionic peroxidase from tomato (Lycopersicon esculentum) fruit oxidized indoleacetic acid (IAA) slowly in the presence of Mn²⁺ and dichlorophenol in acetate buffers. The addition of certain anions to the reaction mixture increased the rate of oxidation. Phosphate was one of the effective anions and exerted maximal activation at 0.1 molar. The most effective activator of tomato peroxidase was nitrilotriacetate (NTA) at an optimum concentration of 60 micromolar. Only 0.17 nanomolar peroxidase was needed to oxidize 0.1 micromole IAA/5 minutes in the presence of NTA compared to 650 nanomolar peroxidase for the same rate in the absence of NTA. Other effective anions were oxalate, pyrophosphate, malate, and citrate. Each activator exhibited an optimum concentration and higher concentrations were inhibitory. Anionic peroxidase from horseradish was activated by the same anions. A cationic peroxidase from horseradish and lactoperoxidase oxidized IAA in acetate buffer although anions activated these enzymes severalfold. Microperoxidase and other hematoporphrins also catalyzed IAA oxidation in the presence of anions. It is proposed that IAA oxidation by peroxidase may be important when vacuolar contents mix with peroxidase as during plant injury.     

Indole-3-acetic Acid oxidation and crocin bleaching by horseradish peroxidase

During indoleacetic acid (IAA) oxidation by horseradish peroxidase the water soluble model polyene, crocin, is bleached. IAA-oxidation and crocin bleaching are stimulated at acidic pH as well as by the monophenol p-hydroxyacetophenone. IAA oxidation and crocin bleaching are neither influenced by catalase or superoxide dismutase nor by different OH-radical scavengers, whereas both ascorbate and propylgallate are inhibitory.     

The reaction between indole 3-acetic acid and horseradish peroxidase

Three distinct phases of the reaction between indole 3-acetic acid (IAA) and horse-radish peroxidase (isoenzymes B and C) were observed. When 100 μm IAA was added to an aerobic solution of the 7μm enzyme at pH 5.0 the oxidation of IAA occurred after a lag time of several seconds, during which the enzyme was partially converted into peroxide Compound II. At a time when the lag time was over the conversion of the enzyme into a green hemoprotein, called P-670 suddenly occurred at a considerable speed. The oxidation of IAA was almost over at the end of the second phase. The last phase was the restoration of the free enzyme from the remaining Compound II.Ascorbate and cytochrome c peroxidase elongated the lag phase of IAA oxidation. From these inhibition experiments it was suggested that a peroxide form of IAA would react with peroxidase to form its peroxide compounds as does hydrogen peroxide and cause the oxidation of IAA. A reaction path that the enzyme is directly reduced by IAA might be involved as an initiation step but appeared to play no essential role in the oxidation of IAA at steady state.Contrary to the cases with dihydroxyfumarate and NADH, Superoxide dismutase did not inhibit the aerobic oxidation of IAA by peroxidase. IAA peroxide radical instead of superoxide anion radical was suggested to be an intermediate in the oxidation of IAA.On the basis of stoichiometric relation of reactions between IAA and peroxidase peroxide compounds a tentative scheme of P-670 formation during the oxidation of IAA was presented.     

Partial purification and kinetics of indoleacetic Acid oxidase from tobacco roots

Extracts from roots of Nicotiana tabacum L var. Bottom Special contain oxidative enzymes capable of rapid degradation of indoleacetic acid (IAA) in the presence of Mn²⁺ and 2, 4-dichlorophenol. Purification of IAA oxidase was attempted by means of ammonium sulfate fractionation and elution through a column of SE-Sephadex. Two distinct fractions, both causing rapid oxidation of IAA in the absence of H₂O₂, were obtained. One fraction exhibited high peroxidase activity when guaiacol was used as the electron donor; the other did not oxidase guaiacol. Both enzyme fractions caused similar changes in the UV spectrum of IAA; absorption at 280 mμ was reduced, while major absorption peaks appeared at 254 and 247 mμ. The kinetics of IAA oxidation by both fractions were followed by measuring the increase in absorption at 247 mμ. The peroxidase-containing fraction showed no lag or a slight lag which could be eliminated by addition of H₂O₂ (3 μmoles/ml). The peroxidase-free fraction showed a longer lag, but addition of similar amounts of H₂O₂ inhibited the rate of IAA oxidation and did not remove the lag. With purified preparations, IAA oxidation was stimulated only at low concentrations of H₂O₂ (0.03 μmole/ml). A comparison of K_m values for IAA oxidation by the peroxidase-containing and peroxidase-free fractions suggests that tobacco roots contain an IAA oxidase which may have higher affinity for IAA and may be more specific than the general peroxidase system previously described from other plant sources. A similar oxidase is present in commercial preparations of horseradish peroxidase. It is suggested that oxidation of IAA by horseradish peroxidase may be due to a more specific component.     

Mechanism of peroxidase actions for salicylic acid-induced generation of active oxygen species and an increase in cytosolic calcium in tobacco cell suspension culture

Extracellularly secreted peroxidases in cell suspension culture of tobacco (Nicotiana tabacum L. cv. Bright Yellow-2, cell line BY-2) catalyse the salicylic acid (SA)-dependent formation of active oxygen species (AOS) which, in turn, triggers an increase in cytosolic Ca2+ concentration. Addition of horseradish peroxidase (HRP) to tobacco cell suspension culture enhanced the SA-induced increase in cytosolic Ca2+ concentration, suggesting that HRP enhanced the production of AOS. The mechanism of peroxidase-catalysed generation of AOS in SA signalling was investigated with chemiluminescence sensitive to AOS and electron spin resonance (ESR) spectroscopy, using the cell suspension culture of tobacco, and HRP as a model system of peroxidase reaction. The results showed that SA induced the peroxidase inhibitor-sensitive production of superoxide and H2O2 in tobacco suspension culture, but no production of hydroxy radicals was detected. Similar results were obtained using HRP. It was also observed that SA suppressed the H2O2-dependent formation of hydroxy radicals in vitro. The results suggest that SA protect the cells from highly reactive hydroxy radicals, while producing the less reactive superoxide and H2O2 through peroxidase-catalysed reaction, as the intermediate signals. The formation of superoxide was followed by that of H2O2, suggesting that superoxide was converted to H2O2. In addition, it was observed that superoxide dismutase-insensitive ESR signal of monodehydroascorbate radical was induced by SA both in the tobacco suspension culture and HRP reaction mixture, suggesting that SA free radicals, highly reactive against ascorbate, were formed by peroxidase-catalysed reactions. The formation of SA free radicals may lead to subsequent monovalent reduction of O2 to superoxide.     

Spin trapping of the azidyl radical in azide/catalase/H2O2 and various azide/peroxidase/H2O2 peroxidizing systems

The azidyl radical is formed during the oxidation of sodium azide by the catalase/hydrogen peroxide system, as detected by the ESR spin-trapping technique. The oxidation of azide by horseradish peroxidase, chloroperoxidase, lactoperoxidase, and myeloperoxidase also forms azidyl radical. It is suggested that the evolution of nitrogen gas and nitrogen oxides reported in the azide/catalase/hydrogen peroxide system results from reactions of the azidyl radical. The azide/horseradish peroxidase/hydrogen peroxide system consumes oxygen, and this oxygen uptake is inhibited by the spin trap 5,5-dimethyl-1-pyrroline-N-oxide, presumably due to the competition with oxygen for the azidyl radical. Although azide is used routinely as an inhibitor of myeloperoxidase and catalase, some consideration should be given to the biochemical consequences of the formation of the highly reactive azidyl radical by the peroxidase activity of these enzymes.     

Thiol and Mn(2+)-mediated oxidation of veratryl alcohol by horseradish peroxidase.

Horseradish peroxidase has been shown to catalyze the oxidation of veratryl alcohol (3,4-dimethoxybenzyl alcohol) and benzyl alcohol to the respective aldehydes in the presence of reduced glutathione, MnCl2, and an organic acid metal chelator such as lactate. The oxidation is most likely the result of hydrogen abstraction from the benzylic carbon of the substrate alcohol leading to eventual disproportionation to the aldehyde product. An aromatic cation radical intermediate, as would be formed during the oxidation of veratryl alcohol in the lignin peroxidase-H2O2 system, is not formed during the horseradish peroxidase-catalyzed reaction. In addition to glutathione, dithiothreitol, L-cysteine, and beta-mercaptoethanol are capable of promoting veratryl alcohol oxidation. Non-thiol reductants, such as ascorbate or dihydroxyfumarate (known substrates of horseradish peroxidase), do not support oxidation of veratryl alcohol. Spectral evidence indicates that horseradish peroxidase compound II is formed during the oxidation reaction. Furthermore, electron spin resonance studies indicate that glutathione is oxidized to the thiyl radical. However, in the absence of Mn2+, the thiyl radical is unable to promote the oxidation of veratryl alcohol. In addition, Mn3+ is unable to promote the oxidation of veratryl alcohol in the absence of glutathione. These results suggest that the ultimate oxidant of veratryl alcohol is a Mn(3+)-GSH or Mn(2+)-GS. complex (where GS. is the glutathiyl radical).     

Tropolone as a substrate for horseradish peroxidase

Tropolone (2,4,6-cycloheptatrien-1-one), in the presence of hydrogen peroxide but not in its absence, can serve as a donor for the horseradish peroxidase catalysed reaction. The product formed is yellow and is characterized by a new peak at 418 nm. The relationship between the rate of oxidation of tropolone (ΔA at 418 nm/min) and various concentrations of horseradish peroxidase, tropolone and hydrogen peroxide is described. The yellow product obtained by the oxidation of tropolone by horseradish peroxidase in the presence of hydrogen peroxide was purified by chromatography on Sephadex G-10 and its spectral properties at different pHs are presented. The M, of the yellow product was estimated to be ca 500, suggesting that tropolone, in the presence of horseradish peroxidase and hydrogen peroxide is converted to a tetratropolone.     

Activation of indole-3-acetic acid oxidase from horseradish and Prunus by phenols and H2O2

The enzyme-catalysed oxidation of indole-3-acetic acid (IAA) was sytematically investigated with respect to enzyme source and cofactor influence using differential spectrophotometry and oxygen uptake measurement. Commercially-available horseradish peroxidase (HRP) and a peroxidase preparation from Prunus phloem showed identical catalytic properties in degrading IAA. There was no lag phase of IAA oxidation with any of the reaction mixtures tested. Monophenols exhibited a much stronger stimulatory effect than inorganic cofactors, but during the incubation of IAA the phenols were also gradually oxidised. Hydrogen peroxide (H₂O₂) in combination with monophenols accelerated peroxidation of the monophenol and IAA oxidation simutaneously. Since photometric determination of IAA was affected by oxidation products of dichlorophenol or phenol contamination of the enzyme preparation used, the standard IAA absorption measurements appear to be susceptible to methodological errors. Under certain incubation conditions a catalase-like activity of HRP during the course of IAA oxidation was noted and substrate inhibition was observed above 1.5 × 10^\s-4 M IAA. Some concepts concerning the mode of activation of the enzyme-catalysed IAA oxidation are deduced from the experimental results.     

Hydrogen peroxide is a mediator of indole-3-acetic acid/horseradish peroxidase-induced apoptosis

Recently, we reported that a combination of indole-3-acetic acid (IAA) and horseradish peroxidase (HRP) induces apoptosis in G361 human melanoma cells. However, the apoptotic mechanism involved has been poorly studied. It is known that when IAA is oxidized by HRP, free radicals are produced, and since oxidative stress can induce apoptosis, we investigated whether reactive oxygen species (ROS) are involved in IAA/HRP-induced apoptosis. Our results show that IAA/HRP-induced free radical production is inhibited by catalase, but not by superoxide dismutase or sodium formate. Furthermore, catalase was found to prevent IAA/HRP-induced apoptotic cell death, indicating that IAA/HRP-produced hydrogen peroxide (H2O2) may be involved in the apoptotic process. Moreover, the antiapoptotic effect of catalase is potentiated by NADPH, which is known to protect catalase. On further investigating the IAA/HRP-mediated apoptotic pathway, we found that the IAA/HRP reaction leads to caspase-3 activation and poly(ADP-ribose) polymerase (PARP) cleavage, which was also blocked by catalase. Additionally, we found that IAA/HRP produces H2O2 and induces peroxiredoxin (Prx) sulfonylation. Consequently, our results suggest that H2O2 plays a major role in IAA/HRP-induced apoptosis.     

Peroxidase and Senescence

Kinetin and a, á-dipyridyl prevented the rapid decreaseof chlorophyll content in detached oat leaves senescing in thedark. In the light, detachment caused a 27–40% rise in peroxidaseactivity and kinetin enhanced the enzyme in the segments byabout 80%. Darkness prevented any detachment-induced rise ofthe activity and decreased the stimulating action of kinetinand mechanical injury. The effect of dipyridyl on peroxidaseactivity in the dark was similar to that of kinetin. Kinetin enhanced the same distinctive isoperoxidases under lightand dark conditions. Neither horseradish peroxidase nor that extracted from oat leavesshowed any ability to hydroxylate free proline in vitro. A systemwhich supposedly led to peroxidase-catalysed proline hydroxylationyielded small amounts of hydroxyproline in the absence of theenzyme. Staining with Fast Blue BB salt in the presence of IAA as asubstrate after electrophoresis indicated that all detectedoat isoperoxidases had an IAA oxidase activity visually parallelingtheir peroxidase activity. Crude extracts contained IAA oxidaseinhibitors that could be partially or fully removed by dialysis. The possible significance of the rise in peroxidase activityduring senescence is discussed.     

Inhibition and inactivation of horseradish peroxidase by thiourea

The kinetics of horseradish peroxidase (EC 1.11.1.7)-catalyzed oxidation of o-dianisidine by hydrogen peroxide in the presence of thiourea were studied. At the first, fast step of this process thiourea acts as a competitive reversible inhibitor with respect to o-dianisidine (Ki = 0.22 mM). The formation of a thiourea-peroxidase complex was determined by the increase in the absorbance at A495 and A638 of the enzyme. The dissociation constant for the peroxidase-thiourea complex is equal to 2.0-2.7 mM. Thiourea is not a specific substrate of peroxidase during the oxidation reaction by H2O2, but is an oxidase substrate (although not a very active one) of peroxidase. The irreversible inactivation of the enzyme during its incubation with thiourea was studied. The first-order inactivation rate constant (kin) was shown to increase with a fall in the enzyme concentration. The curve of the dependence of kin on the initial concentration of thiourea shows a maximum at 5-7 mM. The enzyme inactivation is due to its modification by intermediate free radical products of thiourea oxidation. The inhibitors of the free radical reactions (o-dianisidine) protect the enzyme against inactivation. The degree of inactivation depends on concentrations and ratio of thiourea and peroxidase. A possible mechanism of peroxidase interaction with thiourea is discussed.     

Enhancement of peroxidase-induced lipid peroxidation by indole-3-acetic acid: effect of antioxidants

Summary

Indole-3-acetic acid (IAA) enhanced the peroxidase-induced lipid peroxidation in phosphatidylcholine liposomes, as measured by loss of fluorescence of cis-parinaric acid. α-Tocopherol or β-carotene in the lipid phase or ascorbate or Trolox in the aqueous phase inhibited the loss of fluorescence induced by the peroxidase + IAA system, but glutathione had only a small inhibitory effect. The peroxyl radical formed by one-electron oxidation of IAA, followed by decarboxylation and reaction with oxygen, is suggested to act as the initiator of lipid peroxidation. The protection by ascorbate or Trolox is explained by the reactivity of these compounds with the IAA indolyl radical, as shown by pulse radiolysis experiments, whereas the weak effect of glutathione agrees with its low reactivity towards the IAA-derived peroxyl radical and its precursors.     

Peroxidase activity of catalase with respect to aromatic amines

The catalase dissociation into subunits has been studied at pH less than 3.5 and greater than 11.0. This process is characterized by pseudo-first order rate constants, depending on the initial concentrations of the enzyme and H+. At pH 2.85, the steady-state kinetics of five aromatic amines oxidation by catalase monomers has been studied for orthodianisidine (o-DA), 3,5,3',5'-tetramethylbenzidine (TMB), ortho- and para-phenylene diamine (p-PDA) and 5-aminosalycilic acid. The optimal substrates for catalase in acidic solutions are o-DA, TMB and p-PDA. A comparison has been carried out for the catalase peroxidative activity, and the catalytic characteristics of horseradish peroxidase in the oxidation of the same substrate. The mechanisms of peroxidatic amines oxidation by catalase and horseradish peroxidase are discussed.     

Mechanism of horseradish peroxidase-catalyzed oxidation of malonaldehyde

The mechanism of malonaldehyde oxidation by horseradish peroxidase in the presence of manganese(II) and acetate was investigated. Our results show that an apparent oxygenase behavior demonstrated by peroxidase in this system can be explained in terms of normal peroxidase activity. A free radical is generated from the reaction of malonaldehyde with compounds I and II of peroxidase; this radical is scavenged by dissolved molecular oxygen to give the appearance of peroxidase acting as an oxygenase. Oxygen consumption, absorbance spectra, and kinetic results show that the reaction is initiated by autoxidation of malonaldehyde to give a free radical. The radical reacts with oxygen and through the action of manganese(II), a peroxide is generated. This peroxide drives the peroxidase cycle to generate more free radicals which propagate the oxygen consumption reaction.