DEVELOPMENT OF A NEW BIOSENSOR FOR DETERMINATION OF CATALASE ACTIVITY

Catalase is one of the major antioxidant enzymes that catalyzes the hydrolysis of H₂O₂. The aim of this study was to suggest a new method for the assay of catalase activity. For this purpose, an amperometric biosensor based on glucose oxidase for determination of catalase activity was developed. Immobilization of glucose oxidase was made by a cross-linking method with glutaraldehyde on a Clark-type electrode (dissolved oxygen probe). Optimization and characterization properties of the biosensor were studied and determination of catalase activity in defined conditions was investigated in artificial serum solution. The results were compared with a reference method.     

Extracellular Oxidases of the Lignin-Degrading Fungus <Emphasis Type="Italic">Panus tigrinus</Emphasis>

Two extracellular oxidases (laccases) were isolated from the extracellular fluid of the fungus Panus (Lentinus) tigrinus cultivated in low-nitrogen medium supplemented with birch sawdust. The enzymes were purified by successive chromatography on columns with TEAE-cellulose and DEAE-Toyopearl 650M. Both oxidases catalyze oxidation of pyrocatechol and ABTS. Moreover, oxidase 1 also catalyzes oxidation of guaiacol, o-phenylenediamine, and syringaldazine. The enzymes have identical pH (7.0) and temperature (60–65°C) optimums. Absorption spectra of the oxidases differ from the spectra of typical “blue” laccases and are similar to the spectrum of yellow oxidase.__________Translated from Biokhimiya, Vol. 70, No. 6, 2005, pp. 850–854.Original Russian Text Copyright © 2005 by Cadimaliev, Revin, Atykyan, Samuilov.     

The molybdoenzymes xanthine oxidase and aldehyde oxidase contain fast- and slow-DTNB reacting sulphydryl groups

The reactivities with an excess of 5-5-dithiobis (2-nitrobenzoic) acid (DTNB) of sulphydryl residues present in xanthine oxidase and aldehyde oxidase were studied and compared. The results show that two classes of sulphydryl groups with quite different reactivities exist in both enzymes either native or denatured. Some of the available sulphydryl residues thus react instantaneously with the DTNB, whereas the others react very slowly following pseudo-first-order kinetics. The number of sulphydryl residues of each class and the rate constant of slowly reacting groups are, respectively, 1.7 and 0.8 in native xanthine oxidase and 1.6 and 1.7 in native aldehyde oxidase. In denatured enzymes, the number of fast- and slow-reacting sulphydryl residues obtained are, respectively, 13.9 and 7.9 in xanthine oxidase and 5.7 and 5.4 in aldehyde oxidase. Analogously, the rate constant for the slowly reacting groups is similar for the two native enzymes, but in denatured aldehyde oxidase it is double that of denatured xanthine oxidase.     

Enzyme microgels in packed-bed bioreactors with downstream amperometric detection using microfabricated interdigitated microsensor electrode arrays.

In this article, we describe the use of pH- responsive hydrogels as matrices for the immobilization of two enzymes, glucose oxidase (GOx) and glutamate oxidase (GlutOx). Spherical hydrogel beads were prepared by inverse suspension polymerization and the enzymes were immobilized by either physical entrapment or covalent immobilization within or on the hydrogel surface. Packed-bed bioreactors were prepared containing the bioactive hydrogels and these incorporated into flow injection (FI) systems for the quantitation of glucose and monosodium glutamate (MSG) respectively. The FI amperometric detector comprised a microfabricated interdigitated array within a thin-layer flow cell. For the FI manifold incorporating immobilized GOx, glucose response curves were found to be linear over the concentration range 1.8-280 mg dL(-1) (0.1-15.5 mM) with a detection limit of 1.4 mg dL(-1) (0.08 mM). Up to 20 samples can be manually analyzed per hour, with the hydrogel-GOx bioreactor exhibiting good within-day (0.19%) precision. The optimized FI manifold for MSG quantitation yielded a linear response range of up to 135 mg dL(-1) (8 mM) with a detection limit of 3.38 mg dL(-1) (0.2 mM) and a throughput of 30 samples h(-1). Analysis of commercially produced soup samples gave a within-day precision of 3.6%. Bioreactors containing these two physically entrapped enzymes retained > 60% of their initial activities after a storage period of up to 1 year.     

Principles in the selection of inorganic elements by organisms — Application to molybdenum enzymes

Some basic principles were delineated with regard to the selection of inorganic elements by organisms; they are “basic fitness rule”, “abundance rule”, “efficiency rule” and “evolutionary pressure”. The basic fitness rule was then applied to the case of molybdenum, to show how inherently fit molybdenum is to the biological functions carried out by those enzymes dependent on it, including xanthine oxidase, sulfite oxidase, nitrate reductase and nitrogenase.     

Inhibition of acetylpolyamine and spermine oxidases by the polyamine analogue chlorhexidine

Acetylpolyamine and spermine oxidases are involved in the catabolism of polyamines. The discovery of selective inhibitors of these enzymes represents an important tool for the development of novel anti-neoplastic drugs. Here, a comparative study on acetylpolyamine and spermine oxidases inhibition by the polyamine analogue chlorhexidine is reported. Chlorhexidine is an antiseptic diamide, commonly used as a bactericidal and bacteriostatic agent. Docking simulations indicate that chlorhexidine binding to these enzymes is compatible with the stereochemical properties of both acetylpolyamine oxidase and spermine oxidase active sites. In fact, chlorhexidine is predicted to establish several polar and hydrophobic interactions with the active site residues of both enzymes, with binding energy values ranging from ?7.6 to ?10.6 kcal/mol. In agreement with this hypothesis, inhibition studies indicate that chlorhexidine behaves as a strong competitive inhibitor of both enzymes, values of K_i being 0.10 μM and 0.55 μM for acetylpolyamine oxidase and spermine oxidase, respectively.     

Molybdenum Cofactor-Containing Oxidoreductase Family in Plants

Recent investigations on plant molybdenum-containing enzymes that include xanthine dehydrogenase (EC 1.1.1.204) and xanthine oxidase (EC 1.1.3.22), nitrate reductase (EC 1.7.1.1-3), aldehyde oxidase (EC 1.2.3.1), and sulfite oxidase (EC 1.8.3.1) are reviewed. The enzymes belong to closely related protein family and share common structural features. Special attention is being paid to the recently solved crystal structures their implications for the substrate binding and catalytic mechanism. This revised version was published online in July 2006 with corrections to the Cover Date.     

Biochemical, electrophoretic and immunological characterization of peroxisomal enzymes in three soybean organs

Biochemical, electrophoretic and immunological studies were made among peroxisomal enzymes in three organs of soybean [Glycine max (L.) Merr. cv. Centennial] to compare the enzyme distribution and characteristics of specialized peroxisomes in one species. Leaves, nodules and etiolated cotyledons were compared with regard to several enzymes localized solely in their peroxisomes: catalase (EC 1.11.1.6), malate synthase (EC 4.1.3.2), glycolate oxidase (EC 1.1.3.1), and urate oxidase (EC 1.7.3.3). Catalase activity was found in all tissue extracts. Electrophoresis on native polyacrylamide gels indicated that leaf catalase migrated more anodally than nodule or cotyledon catalase as shown by both activity staining and Western blotting. Malate synthase activity and immunologically detectable protein were present only in the cotyledon extracts. Western blots of denaturing (lithium dodecyl sulfate) gels probed with anti-cotton malate synthase antiserum, reveal a single subunit of 63 kDa in both cotton and soybean cotyledons. Glycolic acid oxidase activity was present in all three organs, but ca 20-fold lower (per mg protein) in both nodule and cotyledon extracts compared to leaf extracts. Electrophoresis followed by activity staining on native gels indicated one enzyme form with the same mobility in nodule, cotyledon and leaf preparations. Urate oxidase activity was found in nodule extracts only. Native gel electrophoresis showed a single band of activity. Novel electrophoretic systems had to be developed to resolve the urate oxidase and glycolate oxidase activities; both of these enzymes moved cathodally in the gel system employed while most other proteins moved anodally. This multifaceted study of enzymes located within three specialized types of peroxisomes in a single species has not been undertaken previously, and the results indicate that previous comparisons between the enzyme content of specialized peroxisomes from different organisms are mostly consistent with that for a single species, soybean.     

生物胺降解酶研究进展及其应用

生物胺是存在于发酵食品和酒精饮料中的潜在胺类危害物。如果人体摄入过量的生物胺,则会引起呼吸困难、呕吐和发烧等过敏反应。生物胺降解酶是通过将生物胺氧化成醛类物质来实现降解生物胺的一类酶。目前发现的具有降解生物胺能力的酶主要包括胺氧化酶、胺脱氢酶和多铜氧化酶。本文详细阐述了这3类主要生物胺降解酶的催化机理、底物特异性、酶学性质、应用特性和它们对生物胺的降解效果,归纳和总结了生物胺降解酶的异源表达和分子改造的研究进展,并对生物胺降解酶在基因挖掘、分子改造和表达等方面的研究趋势进行了展望,以期为研究和开发食品中生物胺的酶法降解策略提供参考。     

Enhancement of Enzyme-Catalyzed Production of Reactive Oxygen Species by Suspensions of “Crocidolite” Asbestos Fibres

Ethylene release from methylthio-ketobutyric acid is an indicator for activated oxygen species of the OH '-radical type. Xanthine oxidase plus xanthine or diaphorase in the presence of NADH and j uglone produce OH'-type oxy-radicals. The production of reactive oxygen species in these enzymatic systems is enhanced by “crocidolite” asbestos fibres.     

Separate monophenolase and o-diphenolase enzymes in Triticum aestivum

Monophenolase and o-diphenolase activities of polyphenol oxidase are usually thought to be a part of the same enzyme complex. It has now been demonstrated that the two catalytic activities of the polyphenol oxidase of wheat grains are separable and reside in different enzymes. The electrophoretically separated monophenolase enzyme showed specificity only for monophenol (l-tyrosine) after its elution from acrylamide gels. Further, this enzyme is confined to the endosperm tissue and is undetectable in the embryonic region of the seedling.     

HISTOCHEMISTRY OF OXIDASES IN SEVERAL TISSUES OF BIVALVE MOLLUSCS

Various tissues of the marine bivalveMytilus galloprovincialiswere analysed histochemically for oxidases capable of generating reactive oxygen species (ROS) using the cerium-DAB technique. Incubations were performed on unfixed cryostat sections using polyvinyl alcohol and semipermeable membranes. High xanthine oxidoreductase andd -amino acid oxidase (DAOX) activities were observed in kidney epithelial cells of mussels. DAOX also presented a strong activity in all the digestive epithelia. No xanthine oxidase activity was observed in any of the mussel tissues tested suggesting the presence of an enzyme only showing dehydrogenase activity. Mannitol oxidase, associated with special organelles called ‘mannosomes’ of terrestrial gastropods, presented a weak activity in the stomach epithelium and a strong specific activity in the haemocytes. Only DAOX presented a discrete granular distribution compatible with a peroxisomal compartmentalization. No urate oxidase activity could be demonstrated in tissues of mussels. These observations suggest a role for peroxisomes in ROS generation and determine the tissues capable of producing oxygen radicals in the digestive gland. This study raises the question of the behaviour of these enzymes in conditions in which ROS-generating organic xenobiotics are accumulated in the digestive gland of molluscs.     

Molecular biology of plasma membrane redox enzymes: A survey of current knowledge

Summary Despite a large body of evidence for enzymatic activities and physiological functions of plasma membrane redox function, few of these enzymes have been characterized in terms of molecular biology. Examples for these with at least some molecular data up to complete sequences, membrane topology and binding sites for substrates and coenzymes or prosthetic groups are NADH-ferricyanide reductase of Ehrlich ascites membranes, NADH-coenzyme Q reductase of liver, NADH oxidase ectoenzyme of liver and HeLa (and possibly other) cells, protein disulfide isomerase which is widespread, and relatives thereof, as well as cytochromes P-450 andb ₅₅₈, NADPH oxidase of fat and thyroid cells and fat cell amine oxidase. Ferricyanide reductase and coenzyme O reductase may be identical, but NADH oxidase ectoenzyme is distinct and possibly functions also as a disulfide and a copper reductase. On the other hand, the plasma-membrane-located protein disulfide isomerase (PDI), despite its similar enzymatic activity, is completely different from the ectooxidase. The latter is shed from the membrane into the surrounding medium by proteolysis, whereas PDI is not an integral membrane protein and is secreted intact. Another disulfide reductase has been demonstrated in THP-1 cells, which again is totally different from the former two. It turns out that enzymatic activities are insufficient to describe redox enzymes. Special forms of cytochrome P-450 can be induced to expression at the cell membrane of liver, where they are transported by the cytoskeleton-associated secretory pathway. Why some isoforms are expressed at the surface and some are not is not yet clear. Cytochromeb ₅₅₈, the flavocytochrome of neutrophils, is described in other cells too, but there are different isoforms, which are genetically distinct. A relative has also been identified in duodenal cells, where it functions as a ferric reductase involved in iron absorption. NADPH oxidase of fat cells has very similar properties, but the identity is unproved, whereas thyroid oxidase is a non-heme protein which is calcium-sensitive and does not need assembly of subunits for activation. Finally, fat cell membranes also possess a quinone-containing amine-oxidase which may be involved in signaling of glucose-transport regulation, as it is also found in GLUT4-containing vesicles. However, the physiological connection has yet to be demonstrated.     

Cytokinins as Inhibitors of Plant Amine Oxidase

Abstract

The interaction of pea seedling amine oxidase with cytokinins was examined to probe a possible connection between cytokinin oxidase and amine oxidase by determining whether cytokinins are substrates or inhibitors of the latter. Kinetic measurements suggest that cytokinins are weak competitive inhibitors of amine oxidase while their behaviour as substrates was not observed. The absence of enzymatic activity with cytokinins as substrates denies the identity or even any similarity of these two enzymes which was previously considered [Hare, P.D. and van Staden, J. (1994) J. Physiol. Plant., 91, 128]. From the values of the inhibition constants obtained it seems unlikely that cytokinins take part in the regulation of amine oxidase activity in vivo. Their inhibitory effect on amine oxidase may be similar to that of some alkaloids studied earlier.     

Stable mediated amperometric biosensors using a graphite electrode embedded with tetrathiafulvalene in silicone oil

A new method has been developed to incorporate the mediator, tetrathiafulvalene (TTF), to the electrode/solution interface of an amperometric biosensor. TTF was dissolved in methylphenyl polysiloxane (silicone oil) and embedded in a graphite disc electrode. The mediator was able to diffuse to the electrode surface at an electrocatalytically significant speed. The storage of TTF in the inert polysiloxane provided a long-lasting and stable mediator supply.

TTF-silicone oil electrodes with immobilized glucose oxidase, xanthine oxidase, or amino acid oxidase exhibited sensitive, fast and reproducible responses. The glucose oxidase electrode was very stable for at least 2 months when stored at 4°C. Together with flow injection analysis (FIA), the enzyme electrodes were reused for at least 500 repeated analyses during a 25 h operation without losing their initial activity.     

Genetic variation of some aldehyde-oxidizing enzymes in the mouse

• 1 Twenty-six strains of mice were surveyed by starch gel electrophoresis for genetic variation of four liver enzymes; aldehyde dehydrogenase, aldehyde oxidase, xanthine oxidase and formaldehyde dehydrogenase.
• 2 A variant of aldehyde dehydrogenase was found in strains ICFW, IS/Cam, NZB, NZW, Simpson and Schneider. A variant of aldehyde oxidase was found in CE. A possible variant of xanthine oxidase was found in SF/Cam.
• 3 The gene determining the electrophoretic variant of aldehyde oxidase is either the same as, or very closely linked to, the Aox gene which determines aldehyde oxidase activity.

     

Xanthine oxidase and aldehyde oxidase: a simple procedure for the simultaneous purification from rat liver

Aldehyde oxidase (AO) and xanthine oxidase (XO) are cytosolic enzymes that have been involved in some pathological conditions and play an important role in the biotransformation of drugs and xenobiotics. The increasing interest in these enzymes demands for a simple and rapid procedure for their purification. This paper describes for the first time a method that allows simultaneous purification of both enzymes from the same batch of rat livers. It involves few steps, is reproducible and offers high enzyme yields with high specific activities. The rat liver homogenate was fractionated by heat denaturation and by ammonium sulphate precipitation to give a crude extract containing both enzymes. This extract was chromatographed on an Hydroxyapatite column that completely separated AO from XO. Further purification of XO by anion exchange chromatography on a Q-Sepharose Fast Flow column resulted in a highly purified (1200-fold) preparation, with a specific activity of 3.64 U/mg and with a 20% yield. AO was purified about 1000-fold at a yield of 15%, with a specific activity of 3.48 U/mg, by affinity chromatography on Benzamidine-Sepharose 6B. The purified enzymes gave single bands of approximately 300 kDa on a polyacrylamide gel gradient electrophoresis and displayed the characteristic absorption spectra of highly purified enzymes.     

Microbial oxidases of acidic -amino acids

Two microbial oxidases of acidic -amino acids have been purified to homogeneity. One is a -aspartate oxidase of the yeast Cryptococcus humicolus UJ1 that was induced markedly with -aspartate and is far more active toward -aspartate than -glutamate. The other is a -glutamate oxidase of Candida boidinii 2201 that preferred -glutamate to -aspartate as a substrate in terms of k_cat/K_m, but was not induced very effectively by -glutamate. The most potent competitive inhibitor of the C. humicolus -aspartate oxidase was malonate, and that of the C. boidinii -glutamate oxidase was -malate. The former enzyme was a homotetramer of 160 kDa consisting of subunits of 40 kDa, each of which contained 1 mol of FAD, while the latter was a monomer of 45 kDa. The N-terminal sequences of both enzymes were similar to those of other FAD enzymes and contained a consensus sequence common to most enzymes binding ADP-containing nucleotides. Peroxisomal localization of the C. humicolus -aspartate oxidase was shown by subcellular fractionation and morphological analysis via electron microscopy of C. humicolus cells, where induction of the enzyme was accompanied by induction of catalase and development of peroxisomes. The apo-form of C. humicolus -aspartate oxidase, prepared by removal of FAD was a monomeric protein of 40 kDa, and its binding with FAD proceeded in two stages. The K_d for the apoprotein-FAD complex was very low (8.2×10⁻¹² M) consistent with the observed tight binding. The C. humicolus -aspartate oxidase was essentially similar to other flavoprotein oxidases of acidic and neutral -amino acids with respect to its spectral properties and sensitivity to specific modifying reagents for arginyl and histidyl residues.     

Degradation of peroxisomal catalase and urate oxidase of rat liver

Urate oxidase and catalase were purified from rat liver peroxisomes, and respective antibodies were prepared from rabbits by the administration of these enzymes. Although urate oxidase generally precipitates in immunoprecipitation-possible pH ranges (pH 4.5–9.5), the enzyme remained soluble in 50 mM glycine buffer (pH 9.5) containing 50% glycerol up to concentration of 0.3 mg/ml. Anti-urate oxidase reacted with purified urate oxidase as well as with the crude preparation.After [³H]leucine was injected to rats, urate oxidase and catalase were purified from rat liver at certain intervals, and further precipitated by respective antibodies. The half-life of the catalase was 39 h and that of urate oxidase, 20 h. When the sonicated light mitochondrial fraction was incubated at 37°C and at pH 7.0 or 5.6, inactivation of catalase did not seem to differ between these pH values, and approximately 80% of the catalase activity remained even after 8 h. Urate oxidase was inactivated very rapidly at pH 5.6; only 30% of its activity survived incubation for 6 h. This inactivation was found to occur by some proteolytic process.From these findings, the turnover rate of urate oxidase was found to be different from that of catalase, and this distinction seemed to be due to different sensitivity to some degradative enzymes.     

Galactose oxidase and alcohol oxidase: Scope and limitations for the enzymatic synthesis of aldehydes

The utility of both galactose oxidase and alcohol oxidase for alcohol-to-aldehyde oxidation has been investigated, from a synthetic point of view. The speed of reaction and degree of conversion has been measured for 29 different primary alcohols. The two oxidative enzymes show complementary synthetic use, i.e. galactose oxidase for galactose-derived polyols and alcohol oxidase for aliphatic mono- and diols. Alcohol oxidase has been successfully used in combination with the aldolase DERA in a two-step, one-pot reaction cascade.