Studies on Auxin Protectors: XI. Inhibition of Peroxidase-Catalyzed Oxidation of Glutathione by Auxin Protectors and o-Dihydroxyphenols

Commercial horseradish peroxidase, when supplemented with dichlorophenol and either manganese or hydrogen peroxide, will rapidly oxidize glutathione. This peroxidase-catalyzed oxidation of glutathione is completely inhibited by the presence of auxin protectors. Three auxin protectors and three o-dihydroxyphenols were tested; all inhibited the oxidation. Glutathione oxidation by horseradish peroxidase in the presence of dichlorophenol and Mn is also completely inhibited by catalase, implying that the presence of Mn allows the horseradish peroxidase to reduce oxygen to H₂O₂, then to use the H₂O₂ as an electron acceptor in the oxidation of glutathione. Catalase, added 2 minutes after the glutathione oxidation had begun, completely inhibited further oxidation but did not restore any gluthathione oxidation intermediates. In contrast, the addition of auxin protectors, or o-dihydroxyphenols, not only inhibited further oxidation of gluthathione by horseradish peroxidase (+ dichlorophenol + Mn), but also caused a reappearance of glutathione as if these antioxidants reduced a glutathione oxidation intermediate. However, when gluthathione was oxidized by horseradish peroxidase in the presence of dichlorophenol and H₂O₂ (rather than Mn), then the inhibition of further oxidation by auxin protectors or o-dihydroxyphenols was preceded by a brief period of greatly accelerated oxidation. The data provide further evidence that auxin protectors are cellular redox regulators. It is proposed that the monophenol-diphenol-peroxidase system is intimately associated with the metabolic switches that determine whether a cell divides or differentiates.     

Tropolone—a compound that can aid in differentiating between tyrosinase and peroxidase

In studies dealing with melanogenesis in mammalian tissues, ultrastructural localization of enzymes, identification of subcellular organelles, differentiation and lignification in plant tissues, it is important to have means to differentiate between tyrosinase and peroxidase activities. For a variety of reasons, established criteria used for this purpose are not always reliable. We suggest that tropolone can aid in differentiating between tyrosinase and peroxidase activities since: (a) it is a very effective inhibitor of tyrosinase; (b) in the presence of hydrogen peroxide it can serve as a substrate for peroxidase; (c) at concentrations that inhibit tyrosinase, it does not inhibit peroxidase activity; and (d) it inhibits tyrosinase activity even in the presence of hydrogen peroxide and peroxidase. In a system containing a mixture of tyrosinase and peroxidase, tropolone can differentiate reliably between peroxidase and monohydroxyphenolase or o-dihydroxyphenolase activities of tyrosinase. Moreover, tropolone can differentiate reliably between peroxidase and tyrosinase activities using slices or crude dialysed extracts of various plant tissues.     

Dihydrotetramethylrosamine: a long wavelength, fluorogenic peroxidase substrate evaluated in vitro and in a model phagocyte

Dihydrotetramethylrosamine, a fluorogenic substrate for peroxidase, and its fluorescent oxidation product, tetramethylrosamine chloride, were evaluated. The substrate is colorless and nonfluorescent while the oxidized dye absorbs at 550 nm and emits at 574 nm in both methanol and water. In vitro assays demonstrated that the substrate was oxidized to the fluorophore by horseradish peroxidase in the presence of hydrogen peroxide. In vivo uptake and oxidation of the substrate by Amoeba proteus was characterized by the initial appearance of fluorescent phagocytic vacuoles with subsequent localization in vesicular organelles the size and shape of protozoan mitochondria. Similar staining patterns occurred in cells incubated with substrate, oxidized rosamine or rhodamine 123, a known mitochondrial stain.     

Enzymatic enhancement of the catalytic rate of sulfhydryl oxidase

The rate of oxidation of glutathione by solubilized sulfhydryl oxidase was significantly enhanced in the presence of horseradish peroxidase (donor:hydrogen-peroxide oxidoreductase, EC 1.11.1.7). This enhancement was proportional to the amount of active peroxidase in the assay, but could not be attributed solely to the oxidation of glutathione catalyzed by the peroxidase. A change in the Soret region of the horseradish peroxidase spectrum was observed when both glutathione and peroxidase were present. Moreover, addition of glutathione to a sulfhydryl oxidase/horseradish peroxidase mixture resulted in a rapid shift of the absorbance maximum from 403 nm to 417 nm. This shift indicates the oxidation of horseradish peroxidase. Spectra for three isozyme preparations of horseradish peroxidase, two acidic and one basic, all underwent this red-shift in the presence of sulfhydryl oxidase and glutathione. Cysteine and N-acetylcysteine could replace glutathione. Addition of catalase had no effect on the oxidation of peroxidase, indicating that the peroxide involved in the reaction was not derived from that released into the bulk solution by sulfhydryl oxidase-catalyzed thiol oxidation. Further evidence for a direct transfer of the hydrogen peroxide moiety was obtained by addition of glutaraldehyde to a sulfhydryl oxidase/horseradish peroxidase/N-acetylcysteine mixture. Size exclusion chromatography revealed the formation of a high-molecular-weight species with peroxidase activity, which was completely resolved from native horseradish peroxidase. Formation of this species was absolutely dependent on the presence of both the cysteine-containing substrate and sulfhydryl oxidase. The observed enhancement of sulfhydryl oxidase catalytic activity by the addition of horseradish peroxidase supports a bi uni ping-pong mechanism proposed previously for sulfhydryl oxidase.     

Luminol oxidation catalyzed by royal palm leaf peroxidase

We optimized the conditions for oxidation of luminol by hydrogen peroxide in the presence of peroxidase (EC 1.11.1.7) from royal palm leaves (Roystonea regia). The pH range (8.3–8.6) corresponding to maximum chemiluminescence was similar for palm tree peroxidase and horseradish peroxidase. Variations in the concentration of the Tris buffer were accompanied by changes in chemiluminescence. Note that maximum chemiluminescence was observed in the 30 mM Tris solution. The detection limit of the enzyme assay during luminol oxidation by hydrogen peroxide was 1 pM. The specific feature of palm tree peroxidase was the generation of a long-term chemiluminescent signal. In combination with the data on the high stability of palm tree peroxidase, our results indicate that this enzyme is promising for its use in analytical studies.     

Tomato peroxidase: purification, characterization, and catalytic properties

A major peroxidase has been found in the tomato pericarp (Lycopersicon esculentum var. Tropic) of the ripe and green fruit. A purification scheme yielding this enzyme approximately 85% pure has been developed. The tomato enzyme resembles horseradish peroxidase (HRP) in a standard peroxidase assay and in its ability to be reduced to ferroperoxidase, to be converted to oxyferroperoxidase (compound III), and to form peroxidase complexes with hydrogen peroxide (compounds I and II). In contrast to the HRP, the tomato peroxidase fails to catalyze the aerobic oxidation of indole-3-acetic acid in the presence of 2,4-dichlorophenol and manganese. The tomato peroxidase can be resolved into two nonidentical subunits in the presence of dithiothreitol while HRP remains as a single polypeptide chain after such treatment. Dithiothreitol is oxidized in the presence of tomato or horseradish peroxidase with the enzymes accumulating in their oxyferroperoxidase forms during the oxidation reaction. Whereas HRP returns to its free ferric form at the end of the reaction, the tomato enzyme is converted into a form that absorbs at 442 nanometers.     

Luminol oxidation by hydrogen peroxide with chemiluminescent signal formation catalyzed by peroxygenase from the fungus Agrocybe aegerita V.Brig.

Conditions of luminol oxidation by hydrogen peroxide in the presence of peroxygenase from the mushroom Agrocybe aegerita V.Brig. have been optimized. The pH value (8.8) at which fungal peroxygenase produces a maximum chemiluminescent signal has been shown to be similar to the pH optimum value of horseradish peroxidase. Luminescence intensity changed when the concentration of Tris-buffer was varied; maximum intensity of chemiluminescence was observed in 40 mM solution. It has been shown that enhancer (p-iodophenol) addition to the substrate mixture containing A. aegerita peroxygenase exerted almost no influence on the intensity of the chemiluminescent signal, similarly to soybean, palm, and sweet potato peroxidases. Detection limit of the enzyme in the reaction of luminol oxidation by hydrogen peroxide was 0.8 pM. High stability combined with high sensitivity make this enzyme a promising analytical reagent.     

Electronic factors and lipophilicity in the horseradish peroxidase-catalyzed oxidation of N,N-dialkylanilines with hydrogen peroxide and oxygen

Initial rates of N-dealkylation of 15 N, N-dialkylanilines with hydrogen peroxide and oxygen in the presence of the enzyme horseradish peroxidase are interpreted mainly in terms of electron availability on nitrogen. In these cases a mechanism similar to that postulated in the chemical oxidation of these substrates is suggested, and involves the formation of a cation radical. Lipophilicity acts as a limiting factor in the reaction, and highly hydrophilic and hydrophobic substrates deviate from the reactivity suggested by electronic factors toward higher and lower reactivity, respectively.     

The peroxidase-catalyzed oxidation of enkephalins.

In vitro experiments are reported showing that Leu-enkephalin and Metenkephalin, in the presence of hydrogen peroxide, can be oxidized by horseradish peroxidase. The products formed are strongly fluorescent and characterized by absorption peaks with maxima at 290 nm and 315 nm. The effects of substrate and enzyme concentrations on the oxidation rate of enkephalins are described. Amino acid analysis of the hydrolysates from peroxidase-treated enkephalins provides evidence for the presence of dityrosine. The data suggest that the oxidation leads to the production of enkephalin dimers with a linkage between the N-terminal tyrosine residues. Data are also obtained indicating that enkephalins function as hydrogen donors for mammalian peroxidases.     

The horseradish peroxidase-catalyzed oxidation of 3,5,3',5'-tetramethylbenzidine. Free radical and charge-transfer complex intermediates

Benzidine and related compounds are well known substrates for horseradish peroxidase/H2O2 oxidation. Typically, two different colored products are formed. In this paper, we study the oxidation of 3,5,3',5'-tetramethylbenzidine. The first colored product is a blue charge-transfer complex of the parent diamine and the diimine oxidation product. This species exists in rapid equilibrium with the radical cation. The radical was observed by ESR spectroscopy, and hyperfine splitting constants were determined. Addition of equimolar hydrogen peroxide yields the yellow diimine, which is stable at acid pH. At less than equimolar peroxide, all four species (diamine, radical cation, charge-transfer complex, and diimine) exist in equilibrium. A theoretical analysis of this redox system is presented, including a determination of the extinction coefficients and equilibrium constant for the nonradical species.     

Selective oxidations with molecular oxygen,catalyzed by chloroperoxidase in the presence of a reductant

Chloroperoxidase (CPO) catalyzes the oxidation of various substrates with molecular oxygen as the primary oxidant, in the presence of dihydroxyfumaric acid (DHF) as a sacrificial reductant. For example, indole is oxidized to 2-oxindole with up to 77% selectivity and thioanisole to the corresponding R-sulfoxide (e.e. >99%). To our knowledge, these are the first examples of (enantio)selective aerobic oxidations catalyzed by peroxidases. A mechanism is proposed which involves initial formation of hydrogen peroxide via autoxidation of DHF. CPO subsequently uses the hydrogen peroxide for the selective oxidation of the substrate, via an oxygen transfer mechanism. In contrast, horseradish proxidase (HRP) primarily catalyzes the oxidation of DHF via a classical peroxidase mechanism and oxidations of added substrates are aselective.     

Complexities in horseradish peroxidase-catalyzed oxidation of dihydroxyphenoxazine derivatives: appropriate ranges for pH values and hydrogen peroxide concentrations in quantitative analysis

The highly sensitive, convenient fluorescence assay, based on the oxidation of nonfluorescent 10-acetyl-3,7-dihydroxyphenoxazine (Amplex Red) to highly fluorescent resorufin, is becoming increasingly popular for hydrogen peroxide quantitation. Yet, the intricacies of the horseradish peroxidase-catalyzed oxidation of the reductant substrate Amplex Red by hydrogen peroxide and the resulting resorufin could complicate the assay design and data interpretation. In particular, substrate inhibition and enzyme inactivation at higher hydrogen peroxide concentrations were known to affect the enzyme kinetics and end-point fluorescence. In addition, here we report the spontaneous transformation of resorufin to less or nonfluorescent product(s) in the absence of hydrogen peroxide and horseradish peroxidase. This spontaneous decay of resorufin fluorescence is most prominent in the pH range 6.2-7.7, likely due to general base-catalyzed de-N-acetylation and polymerization of resorufin. From a practical point of view, precautions for properly designing assays for hydrogen peroxide or characterizing hydrogen peroxide-generating systems are discussed based on the spontaneous transformation of resorufin to less fluorescent compound(s), substrate inhibition and enzyme inactivation at higher (>100 microM) hydrogen peroxide concentrations, and enzymatic oxidation of resorufin to nonfluorescent resazurin.     

Free Radical Formation from the Antineoplastic Agent VP 16-213

Free radical formation from VP 16-213 was studied by ESR spectroscopy. Incubation of VP 16-213 with the one-electron oxidators persulphate-ferrous, myeloperoxidase (MPO)/hydrogen peroxide and horseradish peroxidase (HRP)/hydrogen peroxide readily led to the formation of a free radical. The ESR spectra obtained in the last two cases, were in perfect accord with that of a product obtained by electrochemical oxidation of VP 16-213 at +550 mV. The half-life of the free radical in 1 mM Tris (pH 7.4), 0.1 MNaClat 20°C, was 257 ± 4 s. The signal recorded on incubation with HRP/H₂O₂ or MPO/H₂O₂ did not disappear on addition of 0.3 - 1.2 mg/ml microsomal protein. From incubations with rat liver microsomes in the presence of NADPH, no ESR signals were obtained.     

New fluorogenic substrates for horseradish peroxidase: Rapid and sensitive assays for hydrogen peroxide and the peroxidase

p-Hydroxyphenyl compounds [3-(p-hydroxyphenyl)propionic acid, p-hydroxyphenethyl alcohol, hordenine, p-ethylphenol, 3-(p-hydroxyphenyl)-1-propanol, p-n-propylphenol, and p-hydroxyphenyllactic acid] were recently found to be excellent fluorogenic substrates for the horseradish peroxidase-mediated reaction with hydrogen peroxide. A very rapid and sensitive method for the fluorometric assays of hydrogen peroxide and the peroxidase was established by using 3-(p-hydroxyphenyl)propionic acid as the best of these substrates; hydrogen peroxide can be assayed precisely in amounts as small as 0.1 nmol, with peroxidase activity as low as 7.8 μU.     

Horseradish peroxidase compound I as a tool to investigate reactive protein-cysteine residues: from quantification to kinetics

Proteins containing reactive cysteine residues (protein-Cys) are receiving increased attention as mediators of hydrogen peroxide signaling. These proteins are mainly identified by mining the thiol proteomes of oxidized protein-Cys in cells and tissues. However, it is difficult to determine if oxidation occurs through a direct reaction with hydrogen peroxide or by thiol–disulfide exchange reactions. Kinetic studies with purified proteins provide invaluable information about the reactivity of protein-Cys residues with hydrogen peroxide. Previously, we showed that the characteristic UV–Vis spectrum of horseradish peroxidase compound I, produced from the oxidation of horseradish peroxidase by hydrogen peroxide, is a simple, reliable, and useful tool to determine the second-order rate constant of the reaction of reactive protein-Cys with hydrogen peroxide and peroxynitrite. Here, the method is fully described and extended to quantify reactive protein-Cys residues and micromolar concentrations of hydrogen peroxide. Members of the peroxiredoxin family were selected for the demonstration and validation of this methodology. In particular, we determined the pK_a of the peroxidatic thiol of rPrx6 (5.2) and the second-order rate constant of its reactions with hydrogen peroxide ((3.4 ± 0.2) × 10⁷ M^? 1 s^? 1) and peroxynitrite ((3.7 ± 0.4) × 10⁵ M^? 1 s^? 1) at pH 7.4 and 25 °C.     

4-phenylylboronic acid: A new type of enhancer for the horseradish peroxidase catalysed chemiluminescent oxidation of luminol

4-Phenylylboronic acid enhances the light emission from the horseradish peroxidase catalysed oxidation of luminol by hydrogen peroxide. Optimization studies showed that the greatest enhancement was obtained using micromolar concentrations of the new enhancer. The largest degree of enhancement was found with the basic isoenzyme of horseradish peroxidase (Type VIA), and lesser degrees of enhancement were obtained with Type VII and Type IX horseradish peroxidase. The enhancer was also effective in the peroxidase catalysed oxidation of isoluminol by peroxide.     

Dietary antioxidants interfere with Amplex Red-coupled-fluorescence assays

Oxidation of Amplex Red by hydrogen peroxide in the presence of horseradish peroxidase (HRP) gives rise to an intensely colour product, resorufin. This reaction has been frequently employed for measurements based on enzyme-coupled reactions that detect hydrogen peroxide as a final reaction product. In the current study, we show that the presence of dietary antioxidants at biological concentrations in the reaction medium produced interferences in the Amplex Red/HRP catalyzed reaction that result in an over quantification of the hydrogen peroxide produced. The interference observed showed a dose-dependent manner, and a possible mechanism of interaction of dietary antioxidants with HRP in the Amplex Red-coupled-fluorescent assay is proposed.     

Kinetic study of o-dianisidine oxidation by hydrogen peroxide in the presence of horseradish peroxidase]

A kinetic study of o-dianisidine oxidation by hydrogen peroxide in the presence of horseradish peroxidase within the pH range of 3.7-9.0 has been carried out. It was shown that the reaction of o-dianisidine peroxidase oxidation obeys the Michaelis--Menten kinetics; the kcat and Km values within the pH range used were determined. The optimum of peroxidase catalytic activity during o-dianisidine oxidation was observed at pH 5.0-6.0. The kinetic pattern of the reaction is discussed. It was demonstrated that deprotonation of the group at pK 6.5 decreases the kcat value 60 times. At pH greater than 8.0 an additional ionogenic group controls the enzyme activity.     

Galactose oxidase action on galactose containing glycolipids--a fluorescence method

Features that alter the glycolipid sugar headgroup accessibility at the membrane interface have been studied in bilayer lipid model vesicles using a fluorescence technique with the enzyme galactose oxidase. The effects on oxidation caused by variation in the hydrophobic moiety of galactosylceramide or the membrane environment for galactosylceramide, monogalactosyldiacylglycerol and digalactosyldiacylglycerol were studied. For this study we combined the galactose oxidase method for determining the oxidizability of galactose containing glycolipids, and the fluorescence method for determining enzymatic hydrogen peroxide production. Exposed galactose residues with a free hydroxymethyl group at position 6 in the headgroup of glycolipids were oxidized with galactose oxidase and subsequently the resultant hydrogen peroxide was determined by a combination of horseradish peroxidase and 10-acetyl-3,7-dihydroxyphenoxazine (Amplex Red). Amplex Red reacts with hydrogen peroxide in the presence of horseradish peroxidase with a 1:1 stoichiometry to form resorufin. With this coupled enzyme approach it is also possible to determine the galactolipid transbilayer membrane distribution (inside-outside) in bilayer vesicles.