Purification and characterization of p-coumaroyl-D-glucose hydroxylase of sweet potato (Ipomoea batatas) roots

p-Coumaroyl-D-glucose hydroxylase in sweet potato (Ipomoea batatas Lam.) has been purified to apparent electrophoretic homogeneity using a combination of anion-and cation-exchange, hydrophobic and gel filtration chromatography. The purified enzyme was a monomer with a molecular weight of 33,000 and pI of 8.3. The purified enzyme showed not only hydroxylase activity but also polyphenol oxidase activity. L-Ascorbic acid was the best electron donor for the hydroxylation reaction, which had an optimum pH of 7.0. The enzyme hydroxylated p-coumaroyl-D-glucose, p-coumaric acid, and p-cresol but did not act on o-coumaric acid, m-coumaric acid, 4-hydroxy-3-methoxycinnamic acid, p-hydroxybenzoic acid or L-tyrosine. While the enzyme utilized p-coumaroyl-D-glucose and p-coumaric acid equally at pH 7.0, it hydroxylated only p-coumaroyl-D-glucose at pH 5.5. The enzyme oxidized diphenols such as D,L-(3,4-dihydroxyphenyl) alanine and caffeic acid, but exhibited no clear pH optimum in this reaction characteristic of polyphenol oxidase. Both the hydroxylase and the polyphenol oxidase activities were strongly inhibited by beta-mercaptoethanol, diethyldithiocarbamate, KCN, and p-coumaric acid (in concentrations higher than 5 mM). Ammonium sulfate and sodium chloride activated the hydroxylase activity but not the polyphenol oxidase activity of the enzyme. The enzyme activity and L-ascorbic acid contents changed in a manner suggesting their involvements in chlorogenic acid biosynthesis during incubation of sliced sweet potato root tissues.     

The expression of catechol oxidase activity during the hydroxylation of p-coumaric acid by spinach-beet phenolase

1. The conditions under which oxygen consumption in excess of that required for the hydroxylation of p-coumaric acid to caffeic acid, catalysed by spinach-beet phenolase, can be suppressed, have been examined. 2. With dimethyltetrahydropteridine as electron donor, oxygen uptake was exactly equivalent to the caffeic acid produced, provided that p-coumaric acid was in excess, but with excess of reductant, oxygen uptake caused by the further oxidation of caffeic acid was also observed. 3. With equal concentrations of ascorbate and p-coumaric acid, equivalent oxygen uptake and caffeic acid production was found only in the first stages of the reaction, whereas with NADH substituted for ascorbate, oxygen uptake was in excess throughout. 4. When ascorbate was used, the period of the reaction over which this equivalence was found was decreased at high reaction rates and not observed at all with aged enzyme preparations; equivalence was restored by adding bovine serum albumin to these aged preparations. 5. Equivalence between oxygen consumption and caffeic acid production was observed with NADH, if small quantities of dimethyltetrahydropteridine were also added. 6. It is concluded that hydroxylation proceeds without the concomitant production of caffeic acid only if the enzyme is stabilized for hydroxylation by p-coumaric acid and the reductant, and is protected from attack by o-quinones.     

Effect of sequestering and reducing agents on stabilization of plant dehydrogenase activity in crude extracts

Initial and long-term loss of dehydrogenase activity in crude extracts of herbaceous, and, especially, of woody tissue occur partially because of the inhibitory influence of phenolics. In addition, oxidation of phenols by phenolase results in subsequent enzyme oxidation. Preparation of crude extracts with insoluble PVP, in comparison with anion exchange resins or celluloses, best decreases phenolic concentrations and least decreases dehydrogenase activity in crude extracts. However, removal of phenolics during tissue homogenation does not maximize dehydrogenase activity. Therefore, other methods must be used to stabilize dehydrogenase activity. Sodium ethylenediaminetetracetic acid or sodium azide promoted activity of both purified mushroom and crude plant phenolases. Quinone reduction with diethyldithiocarbamate (DIECA) or mercaptoethanol eliminated apparent phenolase activity, but DIECA inhibited dehydrogenase activity. Elevated concentrations of EtSH diminished initial decay of dehydrogenase activity. Combined use of EtSH and insoluble PVP further stabilized 6-phosphogluconate, glucose 6-phosphate, and malate dehydrogenase, but not glyceraldehyde 3-phosphate dehydrogenase.     

Inhibitory effect of 4-cyanobenzaldehyde and 4-cyanobenzoic acid on mushroom (Agaricus bisporus) tyrosinase

Mushroom tyrosinase (EC 1.14.18.1), a copper containing oxidase, catalyzes both the hydroxylation of tyrosine into o-diphenols and the oxidation of o-diphenols into o-quinones. In the current study, the effects of 4-cyanobenzaldehyde and 4-cyanobenzoic acid on the monophenolase and diphenolase activities of mushroom tyrosinase have been studied. The results show that 4-cyanobenzaldehyde and 4-cyanobenzoic acid can inhibit both the monophenolase activity and the diphenolase activity of mushroom tyrosinase. The lag phase of tyrosine oxidation catalyzed by the enzyme was obviously lengthened, and the steady-state activity of the enzyme decreased sharply. 1.0 mM 4-cyanobenzaldehyde and 4-cyanobenzoic acid can lengthen the lag phase from 78 s to 134 and 115 s, respectively. Both 4-cyanobenzaldehyde and 4-cyanobenzoic acid can lead to reversible inhibition of the enzyme. The IC50 values of 4-cyanobenzaldehyde and 4-cyanobenzoic acid were estimated as 0.62 and 2.45 mM for monophenolase and as 0.72 and 1.40 mM for diphenolase, respectively. A kinetic analysis shows that 4-cyanobenzaldehyde and 4-cyanobenzoic acid are mixed-type inhibitors for the diphenolase. The apparent inhibition constants for 4-cyanobenzaldehyde and 4-cyanobenzoic acid binding with both the free enzyme and the enzyme-substrate complex have been determined and compared.     

Monophenolase activity of avocado polyphenol oxidase

Polyphenol oxidase of avocado mesocarp catalyses (a) the orthohydroxylation of monophenols like l-tyrosine, d-tyrosine, tyramine and p-cresol, and (b) the oxidation of the corresponding o-dihydroxyphenols to quinones. The rate of step b is much greater than that of step a. The hydroxylation of monophenols occurs after a lag period. DOPA or ascorbate effectively eliminate the lag but not dl-6-methyltetrahydropteridine or tetrahydrofolic acid. At 1.66 × 10^?4 M, α,α-dipyridyl has no effect, while diethyldithiocarbamate at this concentration inhibits the hydroxylation reaction by 90%. The tyrosinase activity of avocado polyphenol oxidase is inactivated in the course of the reaction; this inactivation occurs faster and is more pronounced in the presence of exogenously added DOPA. This inactivation is partially prevented by a large excess of ascorbate. The K_m values indicate that tyramine, dopamine, p-cresol and 4-methyl catechol are better substrates for avocado polyphenol oxidase than tyrosine or DOPA.     

The action of hydrogen peroxide on the hydroxylation of p-coumaric acid by spinach-beet phenolase.

Treatment of spinach-beet phenolase with H2O2 under aerobic conditions results in a stimulation of the p-coumaric acid hydroxylation it catalyses, but not the caffeic acid oxidation. Spectroscopic evidence suggests that an oxygenated enzyme species is formed under these conditions.     

Hydroxylation of p-Coumaric acid by illuminated chloroplasts. The role of superoxide.

1. Chloroplasts isolated from leaves of spinach-beet (Beta vulgaris L. ssp. vulgaris) do not catalyse the hydroxylation of p-coumaric acid in the dark unless a reductant (such as ascorbate, NADH or NADPH) is added. Superoxide dismutase has no effect on this reaction. 2. Illuminated chloroplasts catalyse the hydroxylation in the absence of added reductant. This reaction is completely inhibited by superoxide dismutase, but catalase has little effect. 3. Both hydroxylation in the light and hydroxylation in the dark in the presence of reductants are inhibited by diethyldithiocarbamate, EDTA, cyanide and 2-mercaptoethanol. 4. It is proposed that O-2- generated by illuminated chloroplasts is involved in the provision of a reductant to the enzyme phenolase.     

Evidence against superoxide involvement in tyrosine hydroxylation by mushroom tyrosinase

The possible involvement of superoxide anions in the hydroxylation of tyrosine by mushroom tyrosinase was studied. Superoxide dismutase and scavengers of superoxide ions of smaller MW than superoxide dismutase, such as nitroblue tetrazolium and copper salicylate, had no direct effect on the monohydroxyphenolase activity of mushroom tyrosinase. The kinetics of tyrosine hydroxylation, but not of DOPA oxidation, by mushroom tyrosinase was atrected by the addition of a xanthine-xanthine oxidase system. In the presence of the xanthine-xanthine oxidase system, the lag period of tyrosine hydroxylation was shortened compared to the lag period in the absence of the xanthine-xanthine oxidase system. The xanthine- xanthine oxidase system alone (without mushroom tyrosinase) had no effect on tyrosine conversion to dopachrome. Superoxide dismutase, catalase and hydroxyl radical scavengers counteracted to some extent the shortening of the lag period of tyrosine hydroxylation by mushroom tyrosinase caused by the xanthin e-xanthine oxidase system. It is suggested that the shortening of the lag period is due mainly to hydroxyl radicals generated by the xanthine-xanthine oxidase system via interaction of O₂^?. and hydrogen paroxide (a Haber-Weiss type reaction). The data do not support the direct participation of superoxide anions in tyrosine hydroxylation by mushroom tyrosinase.     

Callus Induction from Insect Galls by Dryocosmus kuriphilus on Chestnut Tree

Dehydrodicaffeic acid dilactone (DDACD) was found in a cultured mushroom by screening for catechol-O-methyltransferase inhibitors. The enzyme which converts two molecules of caffeic acid to DDCAD has been extracted from the mushroom and purified and the enzyme reaction has been studied. It was markedly inhibited by reducing agents, such as NADPH, NADH, glutathione and ascorbic acid but stimulated by Fe³⁺, Fe²⁺, Co²⁺, Ni²⁺, Cu²⁺, Cu⁺ and Zn²⁺ ions. Sodium diethyldithiocarbamate and sodium cyanide known to be copper chelating agents inactivated the enzyme, but activity was restored by addition of Cu²⁺ or Cu⁺. Although the enzymic reaction did not occur under anaerobic conditions, ¹⁸O-oxygen was not incorporated into DDCAD. o-Diphenol oxidase catalyzed DDCAD formation from caffeic acid and the DDCAD-forming enzyme catalyzed the formation of DOPAchrome from DOPA. Thus, the DDCAD-forming enzyme is a type of o-diphenol oxidase. Peroxidase and hydrogen peroxide produced DDCAD from caffeic acid.

On the other hand, DDCAD was non-enzymatically synthesized from caffeic acid in the presence of CuCl₂ in 64% yield. In both enzymic and non-enzymic syntheses, both (+)- DDCAD and (?)-DDCAD were produced.     

Kinetic studies on the hydroxylation of p-coumaric acid to caffeic acid by spinach-beet phenolase.

1. A spectrophotometric assay is described that enables the hydroxylation of p-coumaric acid to caffeic acid, catalysed by spinach-beet phenolase, to be followed continuously. 2. Initial-velocity and inhibitor studies indicate that the order of substrate addition is oxygen, p-coumaric acid and electron donor, with an irreversible step separating the binding of each substrate. 3. Caffeic acid is most likely to act as electron donor at the active site; other electron donors, such as ascorbic acid, NADH and dimethyltetrahydropteridine, function mainly to recycle cofactor amounts of caffeic acid. 4. A reaction scheme, consistent with these data, is proposed.     

A monophenol oxidase activity in extracts of sorghum

A p-hydroxycinnamic acid oxidase activity was present in enzyme preparations from first internodes of Sorghum vulgare variety Wheatland milo when incubated in phosphate buffer at pH 7.5. This preparation had no classical polyphenolase activity but had both peroxidase and catalase activities. Since horseradish preparations catalyzed the same reaction, the oxidation probably is another example of a peroxidase-oxidase reaction. A second substrate was p-hydroxyphenylpyruvic acid. Ferulic acid was slightly active at low concentrations and inhibitory at higher ones. Diphenols such as caffeic and chlorogenic acids were inactive and inhibitory to p-hydroxycinnamic acid oxidation. A variety of monophenols such as tyrosine and cinnamic acid were inactive. An active substrate must have a free monophenolic group and para to this a C₃ side chain with a double bond and probably a free terminal acid group. A sulfhydryl reducing agent at the 5 millimolar level such as mercaptoethanol, reduced glutathione, or dithiothreitol was obligatory. Products were varied and were found in both the ethyl acetate-soluble and insoluble fractions after acidification of the incubation mixtures. With internode extracts, about 1 micromole of O₂ was consumed per micromole of p-hydroxycinnamic acid that disappeared in the presence of mercaptoethanol. Tetrahydrafolic acid plus mercaptoethanol were required for a second step oxidation or a parallel reaction; about 2 micromoles of O₂ were consumed per micromole of p-hydroxycinnamic acid that disappeared. Potassium cyanide, diethyldithiocarbamate, ascorbic acid, and ethylenediaminetetraacetate were inhibitory. A similar mercaptoethanol-dependent monophenol oxidase was present in preparations from green shoots that also contained a classical polyphenolase activity. The activity was present in both soluble and particulate (500 to 100,000 gravity) fractions of internodes. Preliminary studies were made of enzyme complexes in the particulate fractions capable of converting phenylalanine and tyrosine to the level of ferulic acid when the above p-hydroxycinnamic acid oxidase was blocked with ascorbic acid. The ratelimiting step was the hydroxylation of p-hydroxycinnamic acid.     

The partial characterization of purified nitrite reductase and hydroxylamine oxidase from Nitrosomonas europaea

Nitrite reductase has been separated from cell-free extracts of Nitrosomonas and partially purified from hydroxylamine oxidase by polyacrylamide-gel electrophoresis. In its oxidized state the enzyme, which did not contain haem, had an extinction maximum at 590nm, which was abolished on reduction. Sodium diethyldithiocarbamate was a potent inhibitor of nitrite reductase. Enzyme activity was stimulated 2.5-fold when remixed with hydroxylamine oxidase, but was unaffected by mammalian cytochrome c. The enzyme also exhibited a low hydroxylamine-dependent nitrite reductase activity. The results suggest that this enzyme is similar to the copper-containing ;denitrifying enzyme' of Pseudomonas denitrificans. A dithionite-reduced, 465nm-absorbing haemoprotein was associated with homogeneous preparations of hydroxylamine oxidase. The band at 465nm maximum was not reduced during the oxidation of hydroxylamine although the extinction was abolished on addition of hydroxylamine, NO(2) (-) or CO. These last-named compounds when added to the oxidized enzyme precluded the appearance of the 465nm-absorption band on addition of dithionite. Several properties of 465nm-absorbing haemoprotein are described.     

Extracellular tyrosinase from the fungus Trichoderma reesei shows product inhibition and different inhibition mechanism from the intracellular tyrosinase from Agaricus bisporus

Tyrosinase (EC 1.14.18.1) is a widely distributed type 3 copper enzyme participating in essential biological functions. Tyrosinases are potential biotools as biosensors or protein crosslinkers. Understanding the reaction mechanism of tyrosinases is fundamental for developing tyrosinase-based applications. The reaction mechanisms of tyrosinases from Trichoderma reesei (TrT) and Agaricus bisporus (AbT) were analyzed using three diphenolic substrates: caffeic acid, L-DOPA (3,4-dihydroxy-l-phenylalanine), and catechol. With caffeic acid the oxidation rates of TrT and AbT were comparable; whereas with L-DOPA or catechol a fast decrease in the oxidation rates was observed in the TrT-catalyzed reactions only, suggesting end product inhibition of TrT. Dopachrome was the only reaction end product formed by TrT- or AbT-catalyzed oxidation of L-DOPA. We produced dopachrome by AbT-catalyzed oxidation of L-DOPA and analyzed the TrT end product (i.e. dopachrome) inhibition by oxygen consumption measurement. In the presence of 1.5mM dopachrome the oxygen consumption rate of TrT on 8mM L-DOPA was halved. The type of inhibition of potential inhibitors for TrT was studied using p-coumaric acid (monophenol) and caffeic acid (diphenol) as substrates. The strongest inhibitors were potassium cyanide for the TrT-monophenolase activity, and kojic acid for the TrT-diphenolase activity. The lag period related to the TrT-catalyzed oxidation of monophenol was prolonged by kojic acid, sodium azide and arbutin; contrary it was reduced by potassium cyanide. Furthermore, sodium azide slowed down the initial oxidation rate of TrT- and AbT-catalyzed oxidation of L-DOPA or catechol, but it also formed adducts with the reaction end products, i.e., dopachrome and o-benzoquinone.     

High polyphenol oxidase activity and low titratable acidity in browning bamboo tissue culture

Summary Tissue browning that frequently results in the early death of bamboo shoots in vitro correlated directly with polyphenol oxidase (PPO, EC 1.10.3.1) activity and inversely with titratable acidity. It was unrelated to the level of endogenous phenols. During the course of culture, timing of PPO activity paralleled that of explant browning. Browning was highest among shoots cultured in a medium of pH 8, which was consistent with the pH optinum of the bamboo enzyme. The pH optimum was first determined with the crude enzyme, then verified with two purified isozymes. Stability of the bamboo PPO was also highest at pH 10. PPO activities of the severely browning Dendrocalamus latiflorus, the moderately browning Phyllostachys nigra, and the relatively non-browning Bambusa oldhamii were inhibited strongly by ascorbic acid, cysteine, sodium diethyldithiocarbamate, and sodium sulfite. But characterization of bamboo PPO according to enzyme inhibitors was not possible because enzyme extracts of the three species gave varied responses to the traditional substances. Nutrient medium addenda of some PPO inhibitors, namely ascorbic acid, cysteine, kojic acid, and thiourea, mainly enhanced browning. However, ferulic acid at 3 mM and lower concentrations reduced the number of brown shoots per culture, although not the percentage of cultures that browned. Polyvinylpyrrolidone failed completely to suppress browning. The two purified isozymes showed different temperature optima for PPO activity: 60°C and 65°C. The purified isozymes displayed a substrate preference for dopamine, or a cathecol oxidase characteristics.     

Kinetic evaluation of catalase and peroxygenase activities of tyrosinase

Tyrosinase is a copper monooxygenase containing a coupled dinuclear copper active site (type-3 copper), which catalyzes oxygenation of phenols (phenolase activity) as well as dehydrogenation of catechols (catecholase activity) using O(2) as the oxidant. In this study, catalase activity (conversion of H(2)O(2) to (1/2)O(2) and H(2)O) and peroxygenase activity (H(2)O(2)-dependent oxygenation of substrates) of mushroom tyrosinase have been examined kinetically by using amperometric O(2) and H(2)O(2) sensors. The catalase activity has been examined by monitoring the initial rate of O(2) production from H(2)O(2) in the presence of a catalytic amount of tyrosinase in 0.1 M phosphate buffer (pH 7.0) at 25 degrees C under initially anaerobic conditions. It has been found that the catalase activity of mushroom tyrosinase is three-order of magnitude greater than that of mollusk hemocyanin. The higher catalase activity of tyrosinase could be attributed to easier accessibility of H(2)O(2) to the dinuclear copper site of tyrosinase. Mushroom tyrosinase has also been demonstrated for the first time to catalyze oxygenation reaction of phenols with H(2)O(2) (peroxygenase activity). The reaction has been investigated kinetically by monitoring the H(2)O(2) consumption rate in 0.5 M borate buffer (pH 7.0) under aerobic conditions. Similarity of the substituent effects of a series of p-substituted phenols in the peroxygenase reaction with H(2)O(2) to those in the phenolase reaction with O(2) as well as the absence of kinetic deuterium isotope effect with a perdeuterated substrate (p-Cl-C(6)D(4)OH vs p-Cl-C(6)H(4)OH) clearly demonstrated that the oxygenation mechanisms of phenols in both systems are the same, that is, the electrophilic aromatic substitution reaction by a (micro-eta(2):eta(2)-peroxo)dicopper(II) intermediate of oxy-tyrosinase.     

Extracellular tyrosinase from the fungus Trichoderma reesei shows product inhibition and different inhibition mechanism from the intracellular tyrosinase from Agaricus bisporus

Tyrosinase (EC 1.14.18.1) is a widely distributed type 3 copper enzyme participating in essential biological functions. Tyrosinases are potential biotools as biosensors or protein crosslinkers. Understanding the reaction mechanism of tyrosinases is fundamental for developing tyrosinase-based applications. The reaction mechanisms of tyrosinases from Trichoderma reesei (TrT) and Agaricus bisporus (AbT) were analyzed using three diphenolic substrates: caffeic acid, L-DOPA (3,4-dihydroxy-l-phenylalanine), and catechol. With caffeic acid the oxidation rates of TrT and AbT were comparable; whereas with L-DOPA or catechol a fast decrease in the oxidation rates was observed in the TrT-catalyzed reactions only, suggesting end product inhibition of TrT. Dopachrome was the only reaction end product formed by TrT- or AbT-catalyzed oxidation of L-DOPA. We produced dopachrome by AbT-catalyzed oxidation of L-DOPA and analyzed the TrT end product (i.e. dopachrome) inhibition by oxygen consumption measurement. In the presence of 1.5 mM dopachrome the oxygen consumption rate of TrT on 8 mM L-DOPA was halved. The type of inhibition of potential inhibitors for TrT was studied using p-coumaric acid (monophenol) and caffeic acid (diphenol) as substrates. The strongest inhibitors were potassium cyanide for the TrT-monophenolase activity, and kojic acid for the TrT-diphenolase activity. The lag period related to the TrT-catalyzed oxidation of monophenol was prolonged by kojic acid, sodium azide and arbutin; contrary it was reduced by potassium cyanide. Furthermore, sodium azide slowed down the initial oxidation rate of TrT- and AbT-catalyzed oxidation of L-DOPA or catechol, but it also formed adducts with the reaction end products, i.e., dopachrome and o-benzoquinone.     

Role of NADPH in the regulation of NADP-specific isocitrate dehydrogenase from pig heart.

The present results show that the NADP specific isocitrate dehydrogenase from pig heart exhibits a time lag before the reaction rate approaches a constant value at low metal ion concentrations. Addition of NADPH or EDTA to the assay mixture abolished the lag, and will under certain conditions activate the enzyme.The lag time increased with increasing concentrations of isocitrate and decreased with increasing enzyme concentration. The NADP and metal ion concentration affected the lag in a complex manner. At low NADP and isocitrate concentration, the lag was reduced 50% by an NADPH concentration of less than 2 μm. Stopped flow experiments showed that premixing of NADP or NADPH with the enzyme abolished the effect of NADPH on the lag time. NADPH activated the enzyme at high NADP concentrations. This activating effect could be accounted for by removal of substrate inhibition by NADP.Evidence was obtained to show that the effect of NADPH on the activity was caused by binding of the reduced coenzyme to a site separate from the normal coenzyme binding site. Binding of metal ions by the reduced coenzyme is probably of importance as EDTA affects the lag time and activity in a manner similar to NADPH. The NADPH effect seems to be a general property of NADP-linked isocitrate dehydrogenases.     

Effect of tiron on monohydroxy and o-dihydroxyphenolase activity of mushroom tyrosinase

Tiron has a multiple effect on mushroom tyrosinase. At relatively low concentrations (up to 3.3 mM), Tiron extended the lag period of tyrosine hydroxylation appreciably, while at concentrations between 3.3 and 8.3 mM the lag period was shortened and approached that of the control. At concentrations above 10 mM, Tiron shortened the lag period of tyrosine hydroxylation compared with that of the control.Tiron, at relatively high concentrations (above 266 mM), inhibited the initial rate of dl-DOPA oxidation by mushroom tyrosinase and lowered the final level of dopachrome formed. Preincubation of mushroom tyrosinase with Tiron resulted in the inactivation of the enzyme, with 50 % inactivation of 650 μg enzyme occurring in the presence of 400 mM Tiron.     

Effect of alterations in membrane lipid unsaturation on the properties of the insulin receptor of Ehrlich ascites cells

Rat heart ornithine decarboxylate activity from isoproterenol-treated rats was inactivated in vitro by reactive species of oxygen generated by the reaction xanthine/xanthine oxidase. Reduced glutathione, dithiothreitol and superoxide dismutase has a protective effect in homogenates and in partially purified ornithine decarboxylase exposed to the xanthine/xanthine oxidase reaction, while diethyldithiocarbamate, which is an inhibitor of superoxide dismutase, potentiated the damage induced by O2- on enzyme activity. Dithiothreitol at concentrations above 1.25 mM had an inhibitory effect upon supernatant ornithine decarboxylase activity, while at 2.5 mM it was most effective in the recovery of ornithine decarboxylase activity, after the purification of the enzyme by the ammonium sulphate precipitation procedure. The ornithine decarboxylase inactivated by the xanthine/xanthine oxidase reaction showed a higher value of Km and a reduction of Vmax with respect to control activity. The exposure of rats to 100% oxygen for 3 h reduced significantly the isoproterenol-induced heart ornithine decarboxylase activity. The injection with diethyldithiocarbamate 1 h before hyperoxic exposure further reduced heart ornithine decarboxylase activity.     

Effect of different phenols on the nadh-oxidation catalysed by a peroxidase from lupin

Cell wall-bound peroxidase (EC 1.11.1.7) from lupin (Lupinus albus) shows a transition from oxidase to peroxidase activity when it oxidizes NADH. The oxidase phase represents a lag period in the time course of the reaction. This phase is phenol-dependent and responsible for hydrogen peroxide formation. Guaiacol, an assay substrate, and p-coumaric, ferulic and sinapic acids, precursors of the cinnamyl alcohols used in the lignification process affect both the length of lag period and the rate of the peroxidase phase of NADH oxidation. The effect of different phenols on the time course of the reaction is related to the efficacy (V_max/K_m ratio) of the enzyme when it is acting on them as a peroxidese.