Hydroxyl-radical production and ethanol oxidation by liver microsomes isolated from ethanol-treated rats.

In order to distinguish between the mechanism of microsomal ethanol oxidation and hydroxyl-radical formation, the rate of cytochrome P-450 (P-450)-dependent oxidation of dimethyl sulphoxide (Me2SO) was determined in the presence and in the absence of iron-chelating compounds, in liver microsomes from control, ethanol- and phenobarbital-treated rats. Ethanol treatment resulted in a specific increase (3-fold) of the microsomal ethanol oxidation and NADPH consumption per nmol of P-450. A form of P-450 was purified to apparent homogeneity from the ethanol-treated rats and characterized with respect of amino acid composition and N-terminal amino acid sequence. Specific ethanol induction of a cytochrome P-450 species having a catalytic-centre activity of 20/min for ethanol and consuming 30 nmol of NADPH/min could account for the results observed with microsomes. Phenobarbital treatment caused 50% decrease in the rate of ethanol oxidation and NADPH oxidation per nmol of P-450. The rate of oxidation of the hydroxyl-radical scavenger Me2SO was increased 3-fold by ethanol or phenobarbital treatment when expressed on a per-mg-of-microsomal-protein basis, but the rate of Me2SO oxidation expressed on a per-nmol-of-P-450 basis was unchanged. Addition of iron-chelating agents to the three different types of microsomal preparations caused an 'uncoupling' of the electron-transport chain accompanied by a 4-fold increase of the rate of Me2SO oxidation. It is concluded that ethanol treatment results in the induction of P-450 forms specifically effective in ethanol oxidation and NADPH oxidation, but not in hydroxyl-radical production, as detected by the oxidation of Me2SO.     

A novel tetrazolium method for peroxidase histochemistry and immunohistochemistry.

We developed a new method for the histochemical demonstration of peroxidase. This method, which has a novel reaction mechanism, is based on the oxidation of phenol by peroxidase and coupling of this reaction to the reduction of a tetrazolium salt, with the deposition of an insoluble formazan at sites of enzyme activity. This new method was compared with an established diaminobenzidine (DAB) technique for peroxidase histochemistry and immunohistochemistry. Although both methods identified peroxidase activity in myeloid cells of bone marrow biopsy specimens, there was no interference from red cell pseudoperoxidase activity with the phenol-tetrazolium method, in contrast to the diaminobenzidine method. The detection of cytokeratin using an indirect immunoperoxidase technique was compared with both methods for demonstrating peroxidase activity. The phenol-tetrazolium method gave results similar to that obtained with DAB and appeared to be at least as sensitive as DAB in detecting low amounts of antigen. In addition, the production of a formazan as the final reaction product means that the phenol-tetrazolium method is ideally suited for quantitative peroxidase histochemistry. Therefore, the phenol-tetrazolium method represents a useful alternative method to DAB and for certain applications offers significant advantages over DAB.     

Ascorbate peroxidase: A novel antioxidant enzyme in insects

Ascorbate peroxidase (APOX) activity, which catalyzes the oxidation of ascorbic acid with the concurrent reduction of hydrogen peroxide (H₂O₂), was found in larvae of Helicoverpa zea. Since insects apparently lack a Se-dependent glutathione peroxidase and since catalase has a low affinity for H₂O₂, this enzyme may be important in removing H₂O₂ in insects. We partially purified the APOX activity 58x from the whole body homogenates and investigated its activity with model lipid peroxides, electron donors, and known inhibitors of plant APOX. The H. zea APOX has activity with model lipid peroxides. This, along with the APOX activity found in fat body tissues, suggests that ascorbate peroxidase may be important in removing lipid peroxides in insects. The H. zea APOX has broader specificity for electron donors than the plant APOX with activity using cysteine, NADPH, glutathione, and cytochrome C as electron donors (22–93% of activity with ascorbate). The H. zea APOX is also resistant to many of the known inhibitors of plant APOX, suggesting that the enzyme has a different active site and may not be a heme-peroxidase. © 1997 Wiley-Liss, Inc.     

Pyruvate production in Candida glabrata: manipulation and optimization of physiological function

Candida glabrata, a multi-vitamin auxotrophic yeast, can accumulate a large amount of pyruvate extracellularly using glucose as the carbon source, a characteristic that has facilitated the cost-effective biotechnological production of pyruvate on an industrial scale. In this review, we describe the current advances in further improving the performance of C. glabrata for efficient pyruvate production, which includes: optimization of the vitamin and dissolved oxygen concentrations, regulation of intracellular cofactor levels and improvement of the environmental robustness of C. glabrata. We also discuss the current efforts using systems biology to understand the metabolism of C. glabrata. Finally, perspectives on engineering and exploiting C. glabrata as a cell factory for efficiently producing various chemicals and materials are discussed.     

Oxidase reactions of tomato anionic peroxidase

Tomato (Lycopersicon esculentum Mill) anionic peroxidase was found to catalyze oxidase reactions with NADH, glutathione, dithiothreitol, oxaloacetate, and hydroquinone as substrates with a mean activity 30% that of horseradish peroxidase; this is in contrast to the negligible activity of the tomato enzyme as compared to the horseradish enzyme in catalyzing an indoleacetic acid-oxidase reaction with only Mn²⁺ and a phenol as cofactors. Substitution of Ce³⁺ for Mn²⁺ produced an 18-fold larger response with the tomato enzyme than with the horseradish enzyme, suggesting a significant difference in the autocatalytic indoleacetic acid-oxidase reactions with these two enzymes. In attempting to compare enzyme activities with 2,4-dichlorophenol as a cofactor, it was found that reaction rates increased exponentially with both increasing cofactor concentration and increasing enzyme concentration. While the former response may be analogous to allosteric control of enzyme activity, the latter response is contrary to the principle that reaction rate is proportional to enzyme concentration, and additionally makes any comparison of enzyme activity difficult.     

Increasing manganese peroxidase production and biodecolorization of triphenylmethane dyes by novel fungal consortium

A fungal consortium-SR consisting of Trametes sp. SQ01 and Chaetomium sp. R01 was developed for decolorizing three kinds of triphenylmethane dyes, which were decolorized by individual fungi with low efficiencies. The fungal consortium-SR produced 1.3 U ml(-1) of manganese peroxidase, 5.5 times higher than that produced by the monoculture of Trametes sp. SQ01, and decolorized Crystal Violet, Coomassie Brilliant Blue G250 (CBB G250) and Cresol Red. The fungal consortium-SR had a decolorization rate of 63-96%, much higher than that of the monoculture of strain SQ01 (38-72%). In consortium-SR, the higher efficiencies of decolorization of Crystal Violet and CBB G250 were obtained when they added to the culture after 4d of mixed cultivation rather than at the beginning of cultivation. Cresol Red was the exception. It is suggested that the consortium-SR has great potential for decolorizing triphenylmethane dyes.     

Vectorial redox reactions of physiological quinones. II. A study of transient semiquinone formation

Transient absorption changes during reduction of quinone in liposomes by external dithionite, in the absence and presence of initially trapped ferricyanide, were matched with absorption spectra of semiquinone and quinone in the blue region. Plastoquinone, ubiquinone-9 and phylloquinone, each having an isoprenoid side chain were compared with trimethyl-p-benzoquinone, ubiquinone-9 and menadione, which lack a long side chain.Semiquinone transients could only be observed by our spectroscopic technique during reduction of quinones lacking the chain. If Triton X-100 was added to the liposomes preparation semiquinone transients were also observed with the isoprenoid quinones. This result is consistent with the view that isoprenoid quinones build domains in the membranes, in which the life time of the semiquinone might be decreased by fast disproportionation, and to which dithionite has limited access.     

Vectorial redox reactions of physiological quinones. II. A study of transient semiquinone formation.

Transient absorption changes during reduction of quinone in liposomes by external dithionite, in the absence and presence of initially trapped ferricyanide, were matched with absorption spectra of semiquinone and quinone in the blue region. Plastoquinone, ubiquinone-9 and phylloquinone, each having an isoprenoid side chain were compared with trimethyl-p-benzoquinone, ubiquinone-9 and menadione, which lack a long side chain. Semiquinone transients could only be observed by our spectroscopic technique during reduction of quinones lacking the chain. If Triton X-100 was added to the liposomes preparation semiquinone transients were also observed with the isoprenoid quinones. This result is consistent with the view that isoprenoid quinones build domains in the membranes, in which the life time of the semiquinone might be decreased by fast disproportionation, and to which dithionite has limited access.     

A novel glutathione peroxidase mimic with antioxidant activity

Many diseases are associated with the overproduction of hydroperoxides that inflict cell damage. A novel cyclodextrin derivative, 6A,6B-diseleninic acid-6A',6B'-selenium bridged beta-cyclodextrin (6-diSeCD), was synthesized to be a functional mimic of glutathione peroxidase (GPX) that normally removes these hydroperoxides. The mimic had high catalytic GPX activity of 13.5 U/micromol, which is 13.6-fold higher than ebselen (PZ51), and was chemically and biologically stable in vitro. Antioxidant activity was studied by ferrous sulfate/ascorbate-induced mitochondria damage model system. These data show that the mimic has great antioxidant activity. Such mimics may result in better clinical therapies for diseases mediated by hydroperoxides.     

Role of molecular oxygen in lignin peroxidase reactions

Homogeneous lignin peroxidase (diarylpropane oxygenase) oxidized veratryl alcohol to veratryl aldehyde under anaerobic conditions in the presence of either H2O2, m-chloroperoxybenzoic acid (mCPBA), or p-nitroperoxybenzoic acid (pNPBA). Lignin peroxidase also oxidized the 1-(3',4'-diethoxyphenyl)-1,2-dihydroxy-(4"-methoxyphenyl)-propane I under anaerobic conditions in the presence of mCPBA to yield 3,4-diethoxybenzaldehyde III and 1-(4'-methoxyphenyl)-1,2-dihydroxyethane IV. In contrast to what occurs under aerobic conditions, under anaerobic conditions no 2-hydroxy-1-(4'-methoxyphenyl)-1-oxoethane V was obtained. During the diarylpropane I cleavage under anaerobic conditions, 18O from H2(18)O was incorporated into the alpha-position of the phenylglycol IV. Lignin peroxidase also hydroxylated 1-(4'-ethoxy-3'-methoxyphenyl)propane II at the alpha-position to yield 1-(4'-ethoxy-3'-methoxyphenyl)-1-hydroxypropane VI under anaerobic conditions in the presence of mCPBA. During the phenylpropane II hydroxylation under anaerobic conditions, 18O from H2(18)O was incorporated into the alpha-position of VI. These results are rationalized according to a mechanism involving an initial one-electron oxidation of the diarylpropane I by the lignin peroxidase compound I to form a benzene pi cation radical which undergoes alpha, beta cleavage to produce a benzaldehyde and a C6C2 benzylic radical. The latter is then attacked by O2 to form a hydroperoxy radical which may decompose through a tetroxide to form the phenylglycol IV and phenylketol V. Under anaerobic conditions the C6C2 benzylic radical is probably oxidized to a carbonium ion which would be subsequently attacked by H2O to yield the phenylglycol V.     

A continuous spectrophotometric method for monitoring phospholipase D-catalyzed reactions of physiological substrates.

A continuous spectrophotometric method for monitoring phospholipase D-catalyzed hydrolysis of long acyl chain phosphatidylcholines has been formulated at pH 8.0 in a mixed detergent system using the coupling enzymes choline oxidase and peroxidase. Standard curves for phosphatidylcholine determination in both end-point and rate modes are presented and applied to the estimation of that phospholipid in a solubilized human erythrocyte membrane sample. In rate mode the method is suitable for kinetic study of phospholipase D with physiological substrates in micellar form.     

Promethazine oxidation by redox mediation in peroxidase reactions

The effect of promethazine on peroxidase-catalyzed oxidation of 3,3', 5,5'-tetramethylbenzidine was investigated at pH 5.4. Promethazine dose dependently introduced a lag in the appearance of tetramethylbenzidine charge-transfer complex monitored at 652 nm. Increasing concentrations of tetramethylbenzidine however decreased the lag period proportional to the tetramethylbenzidine concentration. Addition of promethazine to preformed charge transfer complex caused rapid bleaching of the blue-colored complex. Titration of promethazine with the yellow-colored diimine gave rise to the blue charge-transfer complex and the complete reduction of the species to the colorless parent amine compound. The available evidence suggests that promethazine is oxidized via redox mediation by tetramethylbenzidine peroxidase-oxidized products.     

Manganese peroxidase production by Bjerkandera sp. BOS55

The white-rot fungus Bjerkandera sp. BOS55 has been suggested as a good alternative for the production of ligninolytic enzymes, specially Manganese peroxidase (MnP), by its potential ability to degrade complex compounds. However, the application of this fungus requires the complete knowledge of the fermentation pattern in submerged cultures, conditions similar to those existing in industrial size reactors. For this purpose, the nutritional and environmental factors enabling high ligninolytic activity were studied. According to the results, under limitation and sufficiency of nitrogen, there is a threshold concentration for nitrogen from which MnP is produced. However, under nitrogen excess, the ligninolytic stage of the fungus was coincident with growth, with no apparent substrate limitation according to existing levels of carbon and nitrogen. Concerning carbon concentration, MnP synthesis took place independently of glucose concentration, this indicating that carbon limitation does not seem to be the triggering factor for MnP secretion. Other two environmental factors were studied: oxygenation and agitation, but no significant effect on MnP production was observed, a quite different aspect from the behaviour of other known fungi like Phanerochaete chrysosporium.     

A novel dicyclodextrinyl diselenide compound with glutathione peroxidase activity

A 6A,6A'-dicyclohexylamine-6B,6B'-diselenide-bis-beta-cyclodextrin (6-CySeCD) was designed and synthesized to imitate the antioxidant enzyme glutathione peroxidase (GPX). In this novel GPX model, beta-cyclodextrin provided a hydrophobic environment for substrate binding within its cavity, and a cyclohexylamine group was incorporated into cyclodextrin in proximity to the catalytic selenium in order to increase the stability of the nucleophilic intermediate selenolate. 6-CySeCD exhibits better GPX activity than 6,6'-diselenide-bis-cyclodextrin (6-SeCD) and 2-phenyl-1,2-benzoisoselenazol-3(2H)-one (Ebselen) in the reduction of H(2)O(2), tert-butyl hydroperoxide and cumenyl hydroperoxide by glutathione, respectively. A ping-pong mechanism was observed in steady-state kinetic studies on 6-CySeCD-catalyzed reactions. The enzymatic properties showed that there are two major factors for improving the catalytic efficiency of GPX mimics. First, the substrate-binding site should match the size and shape of the substrate and second, incorporation of an imido-group increases the stability of selenolate in the catalytic cycle. More efficient antioxidant ability compared with 6-SeCD and Ebselen was also seen in the ferrous sulfate/ascorbate-induced mitochondria damage system, and this implies its prospective therapeutic application.     

A sensitive and versatile chromogenic assay for peroxidase and peroxidase-coupled reactions

A sensitive and versatile chromogenic assay for peroxidase and peroxidase-coupled reactions is described. The assay is based on the oxidative coupling of 3-methyl-2-benzothiazolinone hydrazone (MBTH) and 3-(dimethylamino)benzoic acid (DMAB). In the presence of H₂O₂, MBTH and DMAB peroxidase catalyze the formation of a deep purple compound, most likely an indamine dye, which has a broad absorption band between 575 and 600 mm with a peak at 590 mm. Using this assay system, solutions of peroxidase can be determined in picomolar amounts by either a rate or fixed-time method. The assay was adapted for the measurement of free hydrogen peroxide at concentrations of 2–20 μm. By coupling the assay with glucose oxidase, it was possible to measure glucose at levels of 5–25 μm; from the data an operational molar extinction coefficient of 47,600 was calculated. Maltose could be assayed by the glucose oxidase modified system by first preincubating with α-glucosidase; a linear relationship between the absorbance and maltose concentrations in the range of 3 to 13 μm was obtained. Comparison of this assay to others shows it to have many more advantages; for example, in addition to its increased sensitivity and versatility, it employs compounds not shown to be carcinogenic and that are very soluble in water. This assay should offer broad applicability to assays based on peroxidase-coupled reactions such as for glucose determination and in enzyme immunoassays.     

A novel protease-docking function of integrin at invadopodia.

Invadopodia are membrane extensions of aggressive tumor cells that function in the activation of membrane-bound proteases occurring during tumor cell invasion. We explore a novel and provocative activity of integrins in docking proteases to sites of invasion, termed invadopodia. In the absence of collagen, alpha(3)beta(1) integrin and the gelatinolytic enzyme, seprase, exist as nonassociating membrane proteins. Type I collagen substratum induces the association of alpha(3)beta(1) integrin with seprase as a complex on invadopodia. The results show that alpha(3)beta(1) integrin is a docking protein for seprase to form functional invadopodia. In addition, alpha(5)beta(1) integrin may participate in the adhesion process necessary for invadopodial formation. Thus, alpha(3)beta(1) and alpha(5)beta(1) integrins play major organizational roles in the adhesion and formation of invadopodia, promoting invasive cell behavior.