Cynomolgus monkey liver aldehyde oxidase: extremely high oxidase activity and an attempt at purification

Aldehyde oxidase (EC 1.2.3.1) in monkey (Macaca fascicularis) liver was characterized. Liver cytosol exhibited extremely high benzaldehyde and phthalazine oxidase activities based on aldehyde oxidase, compared with those of rabbits, rats, mice and guinea pigs. Monkey liver aldehyde oxidase showed broad substrate specificity distinct from that of the enzyme from other mammals. Purified aldehyde oxidase from monkey liver cytosol showed two major bands and two minor bands in sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). These bands were also observed in Western blotting analysis using anti-rat aldehyde oxidase. The molecular mass of the enzyme was estimated to be 130-151 kDa by SDS-PAGE, and to be about 285 kDa by HPLC gel filtration. The results suggest that isoforms of aldehyde oxidase exist in monkey livers.     

Kinetic analysis of reactive oxygen species generated by the in vitro reconstituted NADPH oxidase and xanthine oxidase systems

The nicotinamide adenine dinucleotide (NADH)/nicotinamide adenine dinucleotide phosphate (NADPH) oxidase and the xanthine oxidase (XOD) systems generate reactive oxygen species (ROS). In the present study, to characterize the difference between the two systems, the kinetics of ROS generated by both the NADH oxidase and XOD systems were analysed by an electron spin resonance (ESR) spin trapping method using 5,5-dimethyl-1-pyrroline-N-oxide (DMPO), 5-(diethoxyphosphoryl)-5-methyl-pyrroline N-oxide (DEPMPO) and 5-(2,2-dimethyl-1,3-propoxy cyclophosphoryl)-5-methyl-1-pyrroline N-oxide (CYPMPO). As a result, two major differences in ROS kinetics were found between the two systems: (i) the kinetics of (?)OH and (ii) the kinetics of hydrogen peroxide. In the NADH oxidase system, the interaction of hydrogen peroxide with each component of the enzyme system (NADPH, NADH oxidase and FAD) was found to generate (?)OH. In contrast, (?)OH generation was found to be independent of hydrogen peroxide in the XOD system. In addition, the hydrogen peroxide level in the NADPH-NADH oxidase system was much lower than measured in the XOD system. This lower level of free hydrogen peroxide is most likely due to the interaction between hydrogen peroxide and NADPH, because the hydrogen peroxide level was reduced by ~90% in the presence of NADPH.     

Milk xanthine oxidase type D (dehydrogenase) and type O (oxidase). Purification, interconversion and some properties

1. The xanthine oxidase of cow's milk, crude or purified, appears as an oxidase (type O), and can be converted almost completely into a NAD(+)-dependent dehydrogenase (type D) by treatment with dithioerythritol or dihydrolipoic acid, but only to a small extent by other thiols. 2. The D form of the enzyme is inhibited by NADH, which competes with NAD(+). 3. The kinetic constants of the two forms of the enzyme are similar to those of the corresponding forms of rat liver xanthine oxidase. 4. Milk xanthine oxidase is converted into an irreversible O form by pretreatment with chymotrypsin, papain or subtilisin, but only partially with trypsin. 5. The enzyme as purified shows a major faster band and a minor slower band on gel electrophoresis. The slower band is greatly reinforced after xanthine oxidase is converted into the irreversible O form by chymotrypsin.     

The regulation of rat liver xanthine oxidase. Involvement of thiol groups in the conversion of the enzyme activity from dehydrogenase (type D) into oxidase (type O) and purification of the enzyme

1. The ;xanthine oxidase' activity of rat liver supernatant, most of which behaves as an NAD(+)-dependent dehydrogenase (type D) can be rapidly converted into an oxidase (type O) by thiol reagents such as tetraethylthiuram disulphide, copper sulphate, 5,5'-dithiobis-(2-nitrobenzoic acid), N-ethylmaleimide and p-hydroxymercuribenzoate. Treatment with copper sulphate, if prolonged, leads to almost complete inactivation of the enzyme. The effect of these reagents is prevented by dithioerythritol, and in all cases but that of N-ethylmaleimide is reversed by the same thiol. 2. Dithioerythritol prevents and reverses the conversion of xanthine oxidase from type D into type O brought about by storage of rat liver supernatant at -20 degrees C, preincubation under anaerobic conditions, treatment with carbon or with diethyl ether, and reverses, but does not prevent, the conversion obtained by preincubation of the whole liver homogenate. 3. Conversion of the enzyme from type D into type O is effected by preincubation of rat liver supernatant with the sedimentable fraction from rat liver but not from chick or pigeon liver. The xanthine dehydrogenase activity of chick liver supernatant is not changed into an oxidase by preincubation with the sedimentable fraction from rat liver. 4. The enzyme activity of rat liver supernatant is converted from type D into type O during purification of the enzyme: the purified enzyme can be reconverted into type D by dithioerythritol. 5. The enzyme appears as an oxidase in the supernatant of rat heart, intestine, spleen, pancreas, lung and kidney. The enzyme of all organs but intestine can be converted into a dehydrogenase by dithioerythritol.     

Enhancement by streptozotocin of O2- radical generation by the xanthine oxidase system of pancreatic beta-cells

Spin-trapping techniques and electron spin resonance (ESR) spectroscopy were used to study the relationship between the effect of streptozotocin (STZ) on pancreatic beta-cells and free radical formation by these cells. Results showed that STZ enhanced generation of the DMPO-OH radical adduct, which is a degradation product of the superoxide anion (O2-) in the presence of cellular components, in a hypoxanthine-xanthine oxidase (XOD) system with a homogenate of beta-cells. This enhancing effect was also observed in a system without cellular components; STZ increased the signal height due to the O2- radical in a concentration-dependent manner and caused a maximum of 150% enhancement at a concentration of 1.5 mM. Thus, STZ seemed to enhance the generation of the O2- radical in the XOD system, probably by some mechanism of its interaction with XOD. Pancreatic beta-cells exhibited a high XOD activity and a very low superoxide dismutase activity. Therefore, the present result supports the possibility that the cytotoxic effect of STZ is closely related to free radical generation in pancreatic beta-cells.     

The respiratory burst oxidase of neutrophils. Separation of an FAD enzyme and its characterization

Pig blood neutrophils were briefly activated by various fatty acids and then fractionated into membrane vesicles with different NADPH oxidase activities. Treatment of these membranes with a detergent, octyl glucoside, resulted in a high yield of solubilized oxidase, which was subjected to isoelectric focusing on gels (pI 4.0-8.0). 1) A distinct band staining with NADPH-nitroblue tetrazolium focused at pI 5.0. The enzyme (pI 5.0) showed high specificity for NADPH and similar characteristics to the oxidase involved in the respiratory burst. 2) The enzyme was extracted from gel slices and analyzed. When measured promptly after its extraction, its NADPH oxidase activity was high, but there was apparent superoxide dismutase-insensitive cytochrome c reduction, probably due to direct electron transfer to the heme protein. However, it could produce superoxide anion (O2-) under some micelle conditions. 3) Therefore, the formation of the enzyme-substrate complex of yeast cytochrome c peroxidase was employed for the detection of H2O2. A fresh extract of stimulated cells catalyzed equimolar NADPH oxidation and H2O2 production of 306 and 300 nmol min-1 (mg protein)-1, respectively. The Km value of the enzyme for NADPH was 30 +/- 13 (S.D.) microM. The recovery of the extract (pI 5.0) was 19% of the total activity. 4) The enzyme extract contained 1.1-1.9 nmol of FAD/mg of protein, giving a turnover number of 300-600 min-1 in terms of O2- generation/FAD. No heme protein was found in the enzyme. The enzyme was mainly of 67-kDa molecular mass.     

Relevance of purine catabolism to hypoxia and recovery in euryoxic and stenoxic marine invertebrates,particularly bivalve molluscs

1. Activities of xanthine dehydrogenase (XDH) and xanthine oxidase (XOD) were measured in a variety of euryoxic and stenoxic marine molluscs.2. Euryoxic bivalves contain only XDH activity which, unlike the mammalian enzyme, is not converted to XOD during anoxic exposure.3. XOD activity was detected predominantly in stenoxic bivalves such as Pecten maximus, Placopeclen magellanicus, and in the cephalopod Loligo opalescens. Although extremely variable, XOD activity increased 4-fold in Cardium edule and 13-fold in Pecten maximus during anoxic exposures of 56 hr and 0.5 hr respectively.4. The data suggest that euryoxic species may tolerate anoxic-normoxic transitions in part by possessing a form of XDH that resists conversion to XOD (a source of Superoxide radicals responsible for ischemia-reperfusion tissue injury in mammals).5. XDH activities in Carcinus maenas digestive gland are sufficient to account fully for the urate reported to accumulate during hypoxia.     

Inactivation of glucose oxidase by diperoxovanadate-derived oxidants.

Inactivation of glucose oxidase occurred in the presence of bromide, vanadate, H(2)O(2), and phosphate (the bromide system), and this was prevented by NADH or phenol red, a bromine acceptor. Glucose oxidase present during the reaction between diperoxovanadate and a reduced form of vanadate, vanadyl (the vanadyl system), but not added after mixing the reactants, was inactivated, and this was accompanied by a loss of binding of the dye, Coomassie blue, to the protein. The transient intermediate of the type OVOOV(O(2)), known to form in these reactions and used in the oxidation of bromide ion and NADH, appears to be responsible for inactivating glucose oxidase. In both systems, the inactivation of the enzyme was prevented by histidine and DTT, known to quench singlet-oxygen. By direct measurement of 1270-nm emission of singlet-oxygen, its generation was demonstrated in the bromide system, and in the reaction of hypohalous acids with diperoxovanadate, but not in the vanadyl system. By themselves both hypohalous acids, HOCl and HOBr inactivated glucose oxidase, and their prior reaction with H(2)O(2) during which singlet-oxygen was released, protected the enzyme. The results provide support for possible oxidative inactivation of glucose oxidase by diperoxovanadate-derived oxidants.     

Actin-inhibition and folding of vertebrate deoxyribonuclease I are affected by mutations at residues 67 and 114

Amino acid (aa) residues (Val-67 and Ala-114) have been suggested as being mainly responsible for actin-binding in human and bovine deoxyribonucleases I (DNase I). This study presents evidence of these two aa mutational mechanisms, not only for actin-binding but also for folding of DNase I in mammals, reptiles and amphibians. Human and viper snake (Agkistrodon blomhoffii) enzymes are inhibited by actin, whereas porcine, rat snake (Elaphe quadrivirgata), and African clawed frog (Xenopus laevis) enzymes are not. To investigate the role of aa at 67, mutants of rat snake (Ile67Val) and viper snake (Val67Ile) enzymes were constructed. After substitution, the rat snake was inhibited by actin, while the viper snake was not. For the role of aa at 114, mutants of viper snake (Phe114Ala), rat snake (Phe114Ala), African clawed frog (Phe114Ala), and porcine (Ser114Ala/Ser114Phe) enzymes were constructed. Strikingly, the substitute mutants for viper snake, rat snake and African clawed frog expressed no protein. The porcine (Ser114Ala) enzyme was inhibited by actin, but not the porcine (Ser114Phe) enzyme. These results suggest that Val-67 may be essential for actin-binding, that Phe-114 may be related to the folding of DNase I in reptiles and amphibians, and that Ala-114 may be indispensable for actin-binding in mammals.     

Proceedings of the SMBE Tri-National Young Investigators' Workshop 2005. Lineage-specific expansions and contractions of the bitter taste receptor gene repertoire in vertebrates

The sense of bitter taste plays a critical role in how organisms avoid generally bitter toxic and harmful substances. Previous studies revealed that there were 25 intact bitter taste receptor (T2R) genes in humans and 34 in mice. However, because the recent chicken genome project reported only three T2R genes, it appears that extensive gene expansions occurred in the lineage leading to mammals or extensive gene contractions occurred in the lineage leading to birds. Here, I examined the T2R gene repertoire in placental mammals (dogs, Canis familiaris; and cows, Bos taurus), marsupials (opossums, Monodelphis domestica), amphibians (frogs, Xenopus tropicalis), and fishes (zebrafishes, Danio rerio; and pufferfishes, Takifugu rubripes) to investigate the birth-and-death process of T2R genes throughout vertebrate evolution. I show that (1) the first extensive gene expansions occurred before the divergence of mammals from reptiles/birds but after the divergence of amniotes (reptiles/birds/mammals) from amphibians, (2) subsequent gene expansions continuously took place in the ancestral mammalian lineage and the lineage leading to amphibians, as evidenced by the presence of 15, 18, 26, and 49 intact T2R genes in the dog, cow, opossum, and frog genome, respectively, and (3) contractions of the gene repertoire happened in the lineage leading to chickens. Thus, continuous gene expansions have shaped the T2R repertoire in mammals, but the contractions subsequent to the first round of expansions have made the chicken T2R repertoire narrow. These dramatic changes in the repertoire size might reflect the daily intake of foods from an external environment as a driving force of evolution.     

Immunological studies on the respiratory burst oxidase of pig blood neutrophils

Recently, a flavin enzyme (pI 5.0), that is probably responsible for superoxide (O2-)-generated oxidase activity, was separated by isoelectric focusing-polyacrylamide gel electrophoresis (IEF-PAGE) from neutrophil membranes in our laboratory [(1987) J. Biol. Chem. 262, 12316-12322]. In the present work, we performed immunological studies on this enzyme derived from pig blood neutrophils. The enzyme extract obtained on IEF-PAGE was injected into guinea pigs to raise antibodies. IgG antibody against the pI 5.0 protein inhibited maximally 54% of the O2- -generating activity of the membrane-solubilized oxidase, whereas the normal serum IgG was not inhibitory at all. Our results further confirmed that the enzyme (PI 5.0) is one of the component(s) of the O2- -generating system. The enzyme gave rise to a band corresponding to a major protein of 72 +/- 4 kDa on both non-denaturing and SDS-PAGE. Immunoblotting after SDS-PAGE demonstrated labelling of peptides of 70-72, 28-32 and 16-18 kDa.     

gp91phox-containing NAD(P)H oxidase mediates attenuation of nitric oxide-dependent control of myocardial oxygen consumption by ANG II

We have previously reported that ANG II stimulation increased superoxide anion (O2-) through the activation of NAD(P)H oxidase and inhibited nitric oxide (NO)-dependent control of myocardial oxygen consumption (MVo2) by scavenging NO. Our objective was to investigate the role of NAD(P)H oxidase, especially the gp91phox subunit, in the NO-dependent control of MVo2. MVo2 in mice with defects in the expression of gp91phox [gp91(phox)(-/-)] was measured with a Clark-type oxygen electrode. Baseline MVo2 was not significantly different between wild-type (WT) and gp91(phox)(-/-) mice. Stimulation of NO production by bradykinin (BK) induced significant decreases in MVo2 in WT mice. BK-induced reduction in MVo2 was enhanced in gp91(phox)(-/-) mice. BK-induced reduction in MVo2 in WT mice was attenuated by 10(-8) mol/l ANG II, which was restored by coincubation with Tiron or apocynin. In contrast to WT mice, BK-induced reduction in MVo2 in gp91(phox)(-/-) mice was not altered by ANG II. There was a decrease in lucigenin (5 x 10(-6) mol/l)-detectable O2- in gp91(phox)(-/-) mice compared with WT mice. ANG II resulted in significant increases in O2- production in WT mice, which was inhibited by coincubation with Tiron or apocynin. However, ANG II had no effect on O2- production in gp91(phox)(-/-) mice. Histological examination showed that the development of abscesses and/or the invasion of inflammatory cells occurred in lungs and livers but not in hearts and kidneys from gp91(phox)(-/-) mice. These results indicate that the gp91(phox) subunit of NAD(P)H oxidase mediates O2- production through the activation of NAD(P)H oxidase and attenuation of NO-dependent control of MVo2 by ANG II.     

Immunochemical properties of D-amino-acid oxidase

Antiserum against homogeneous hog kidney D-amino-acid oxidase (D-amino-acid: oxygen oxidoreductase (deaminating), EC 1.4.3.3) was elicited in rabbits, and monospecific antibodies were prepared by affinity chromatography. The antibodies inhibited up to 90% of hog D-amino-acid oxidase activity, and 100% of the enzyme could be immunoprecipitated. The antibodies inhibited both holoenzyme and reconstituted apoprotein to a similar degree, indicating that they did not interfere with the FAD-binding site of the protein. The antibodies inhibited D-amino-acid oxidase activity from other mammalian species to a similar degree, while the enzyme activities from birds, amphibians, fishes and yeast were inhibited and immunoprecipitated to lower extents. In immunoblotting experiments, after SDS-polyacrylamide gel electrophoresis, the antibodies recognized a single band of about 40 kDa in all the species analyzed, and the entity of the signal was inversely related to the phylogenetic distance from mammals. The antibodies did not inhibit D-alanine dehydrogenase activity from Escherichia coli, but gave positive bands in immunoblotting.     

A comparative study of the metabolic capacity of hearts from reptiles and mammals

The metabolic capacities of reptilian and mammalian hearts have been investigated using two methods: measurement of mitochondrial enzyme activity (cytochrome oxidase) and measurement of both mitochondrial volume density and membrane surface area. The heart tissues from the reptiles and mammals showed 2-fold "weight specific" and 3-fold total organ metabolic capacity differences. Heart mitochondria from reptiles and mammals showed 2-fold differences in the activity of their enzymes per mg of mitochondrial protein yet showed very similar mitochondrial surface areas per cm3 of mitochondria. Heart mitochondria differ from liver mitochondria which have the same enzyme activities per mg of protein and the same mitochondrial surface area per cm3 of mitochondria in both the reptiles and mammals. A wide variety of reptiles and mammals both showed relationships between total heart metabolic capacity and body weight. Mammals have larger hearts than similar sized reptiles and their hearts have a greater proportion of cellular volume occupied by mitochondria.     

Detection of peroxisomal fatty acyl-coenzyme A oxidase activity.

It has been postulated that the peroxisomal fatty acid-oxidizing system [Lazarow & de Duve (1976) Proc. Natl. Acad. Sci. U.S.A. 73, 2043--2046; Lazarow (1978) J. Biol. Chem. 253, 1522--1528] resembles that of mitochondria, except for the first oxidative reaction. In this step, O2 would be directly reduced to H2O2 by an oxidase. Two specific procedures developed to detect the activity of the characteristic enzyme fatty acyl-CoA oxidase are presented, namely polarographic detection of palmitoyl-CoA-dependent cyanide-insensitive O2 consumption and palmitoyl-CoA-dependent H2O2 generation coupled to the peroxidation of methanol in an antimycin A-insensitive reaction. Fatty acyl-CoA oxidase activity is stimulated by FAD, which supports the flavoprotein nature postulated for this enzyme. Its activity increases 7-fold per g wet wt. of liver in rats treated with nafenopin, a hypolipidaemic drug. Subcellular fractionation of livers from normal and nafenopin-treated animals provides evidence for its peroxisomal localization. The stoicheiometry for palmitoyl-CoA-dependent O2 consumption, H2O2 generation and NAD+ reduction is 1 : 1 : 1. This suggests that fatty acyl-CoA oxidase is the rate-limiting enzyme of the peroxisomal fatty acid-oxidizing system.     

两栖和爬行类生长及生长激素分泌活动的调节

根据生长内分泌学,综述了近年来两栖和爬行类生长激素（ＧＨ）分泌活动的调节及生长激素在两栖爬行类生长中作用这一研究领域所取得的主要成就和研究进展,研究结果表明：在脊椎动物的进化过程中,ＧＨ的化学结构和功能是相当保守的;ＧＨ对两栖爬行类的生长起促进作用;类胰岛素生长因子（ＩＧＦｓ）也能冰分传递ＧＨ促进两栖类的生长;在两栖爬行类,下丘脑对ＧＨ分泌的调控较哺乳类缺乏特异性,利用外源ＧＨ促进两栖爬行类的生长     

Interactions of the anesthetic nitrous oxide with bovine heart cytochrome c oxidase. Effects on protein structure, oxidase activity, and other properties

The interactions of nitrous oxide with cytochrome c oxidase isolated from bovine heart muscle have been investigated in search of an explanation for the inhibition of mitochondrial respiration by the inhalation anesthetic. Oxidase activity of the isolated enzyme is partially and reversibly reduced by nitrous oxide. N2O molecules are shown by infrared spectroscopy to occupy sites within the oxidase. Occupancy of sites within the protein by N2O has no observed effects on visible Soret spectra or on the O2 reaction site; no evidence is found for N2O serving as a ligand to a metal. The anesthetic does not substitute for O2 as an oxygen atom donor in either the cytochrome c oxidase or carbon monoxide dioxygenase reactions catalyzed by the enzyme. N2O appears to affect oxidase activity by reducing the rate of electron transfer from cytochrome c to the O2 reaction site rather than by interfering directly with the reduction of O2 to water. Cytochrome c oxidase represents a target site for nitrous oxide and possibly other anesthetics, and the inhibition of oxidase activity may contribute significantly to the anesthetic and/or toxic effects of these substances.     

Adenosine triphosphatase activity in the osmoregulatory organs of vertebrates

Studies have been made on the activity of cation- and anion-stimulated ATPases, as well as succinic dehydrogenase in homogenates and subcellular fractions from osmoregulatory organs of marine (elasmobranch and teleost) and freshwater (teleost) fishes, amphibians, reptiles, birds and mammals. The activity of Na+, K+-ATPase was found to be rather similar in almost all osmoregulatory organs of the species investigated. The highest level of Cl-stimulated ATPase was found in microsomal fraction of the kidneys from birds and mammals. Succinic dehydrogenase activity is significantly higher in the renal tissue of mammals, both in total homogenates and in mitochondrial fraction.     

Structural characteristics of genome organization in amphibians: Differential staining of chromosomes and DNA structure

Summary Differential staining patterns on amphibian chromosomes are in some respects distinct from those on mammalian chromosomes; C-bands are best obtained, whereas G- and Q-bands are either unobtainable (on anuran chromosomes) or coincide with C-bands (chromosomes of urodeles). In amphibians, rRNA genes are located at secondary constrictions, but in urodeles they are also found at other chromosome sites, the positions of these sites being strictly heritable. DNA content in amphibian cells is tens and hundreds times higher than in mammals. DNA contents in anurans and urodeles differ within certain limits: from 2 to 25 pg/N and from 30 to over 160 pg/N respectively. Species characterized by slow morphogenesis have larger genomes. Genome growth is normally due to an increase in the amount of repetitive DNA (mostly intermediate repetitive sequences), the amount of unique sequences being almost constant (11 pg/genome in urodeles, and 1.5 pg/genome in anurans). In anurans in general no satellite DNA was found, whereas such fractions were found in manyUrodela species. Nucleosome chromatin structure in amphibians is identical to that of other eukariotes. It is postulated that differences in chromosome banding between amphibians and mammals are due to differences in chromatin packing which in turn is related to the distinct organization of DNA repetitive sequences. It is likely that fish chromosomes have a similiar structure. A comparison of such properties as the chromosome banding patterns, variations in nuclear DNA content and some genome characteristics enable us to group fishes and amphibians together as regards chromosome structure, as distinct from amniotes - reptiles, birds and mammals. It is probable that in the ancient amphibians - ancestors of reptiles - chromatin packing underwent a radical transformation, following changes in the organization of DNA repetitive sequences.