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 degrees 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.     

Immunocytochemical localization of urate oxidase, fatty acyl-CoA oxidase, and catalase in bovine kidney peroxisomes

We investigated the localization of urate oxidase, peroxisomal fatty acyl-CoA oxidase, and catalase in bovine kidney by immunoblot analysis and protein A-gold immunocytochemistry, using the respective polyclonal monospecific antibodies raised against the enzymes purified from rat liver. By immunoblot analysis, these three proteins were detected in bovine kidney and bovine liver homogenates. Subcellular localization of these three enzymes in kidney was ascertained by protein A-gold immunocytochemical staining of Lowicryl K4M-embedded tissue. Peroxisomes in bovine kidney cortical epithelium possessed crystalloid cores or nucleoids, which were found to be the exclusive sites of urate oxidase localization. The limiting membrane, the marginal plate, and the matrix of renal peroxisomes were negative for urate oxidase staining. In contrast, catalase and fatty acyl-CoA oxidase were found in the peroxisome matrix. These results demonstrate that, unlike rat kidney peroxisomes which lack urate oxidase, peroxisomes of bovine kidney contain this enzyme as well as peroxisomal fatty acyl-CoA oxidase.     

Determination of the cross-points of rat liver peroxisomes, peroxisomal core and the core components by cross-partition.

The cross-points of rat liver peroxisomes, peroxisomal core and the core components were determined by means of cross-partition in two phase systems. The partitions were carried out in the systems containing 6% (w/w) Dextran T 500 and 6% (w/w) polyethyleneglycol 4000 in sodium salts. The same cross-point, pH 5.6, was obtained in peroxisomal marker enzymes in light mitochondrial fraction of liver homogenate, such as catalase, D-amino acid oxidase and urate oxidase. The cross-point as determined by cross-partition of purified peroxisomal core was 6.7. The cross-points of urate oxidase and framework protein fractions obtained by alkali treatment on the purified core were 7.8 and 4.2, respectively, and the ratio of the proteins of urate oxidase to framework protein was 2 : 1. The theoretical value of cross-point of the core calculated from from the relationship between the cross-point and protein ratio of each component of the core coincided with the experimental value obtained by this method.     

Determination of the cross-points of rat liver peroxisomes,peroxisomal core and the core components by cross-partition

The cross-points of rat liver peroxisomes, peroxisomal core and the core components were determined by means of cross-partition in two phase systems. The partitions were carried out in the systems containing 6% (w/w) Dextran T 500 and 6% (w/w) polyethyleneglycol 4000 in sodium salts. The same crosspoint, pH 5.6, was obtained in peroxisomal marker enzymes in light mitochondrial fraction of liver homogenate, such as catalase, d-amino acid oxidase and urate oxidase. The cross-point as determined by cross-partition of purified peroxisomal core was 6.7. The cross-points of urate oxidase and framework protein fractions obtained by alkali treatment on the purified core were 7.8 and 4.2, respectively, and the ratio of the proteins of urate oxidase to framework protein was 2:1. The theoretical value of cross-point of the core calculated from the relationship between the cross-point and protein ratio of each component of the core coincided with the experimental value obtained by this method.     

Effect of triton WR-1339 on peroxisomal enzymes of rat liver

The effect of Triton WR-1339 on peroxisomal enzymes of rat liver was studied. The dose vs. response relationships of peroxisomal enzyme activities to Triton WR-1339 were first examined 3.5 days after injection. Catalase activity was reduced to 50% of that of the control at a dose of 200 mg per 100 g body weight; it was found that the decrease depended on the dose of this compound. Urate oxidase activity was not significantly affected. D-Amino acid oxidase activity showed intermediate behavior. The activities of these enzymes were found to be reduced more markedly at 2 days than at 3.5 days after injection, and subsequently the levels of the activities recovered. At 2 days after injection of a dose of 200 mg per 100 g body weight, the activities of catalase, D-amino acid oxidase and urate oxidase had decreased to 40, 60 and 60%,respectively, of the control values.It was found that the decreases in the activities of these enzymes caused by Triton WR-1339 had occurred in the large granule fraction, but not in the cytoplasm.Measurement of the specific activity, Ouchterlony gel diffusion and quantitative immunoprecipitation suggested that there was a similarity between the Triton WR-1339-treated and untreated rats in the nature of purified catalases.These results suggest that Triton WR-1339 depresses the activities of liver peroxisomal enzymes, especially the catalase activity.     

Studies on peroxisomes. VI. Relationship between the peroxisomal core and urate oxidase.

The peroxisomal core from the liver of rats was purified 450-fold as a marker of urate oxidase [EC 1.7.3.3.] activity. This preparation has a high specific activity of urate oxidase but not of other peroxisomal enzymes: D-amino acid oxidase [EC 1.4.3.3.], L-alpha-hydroxy acid oxidase [EC 1.1.3.15], or catalase [EC 1.11.1.6]. No activity of marker enzymes for other subcellular particles; cytochrome c oxidase [EC1.9.3.1] (mitochondria), acid phosphatase [EC 3.1.3.2] (lysosomes), or glucose-6-phosphatase [EC 3.1.3.9] (microsomes), was detected in this preparation. The core obtained showed a single protein band in sodium dodecyl sulfate-polyacrylamide gel electrophoresis and the position of the band was found to correspond to a molecular weight 35,000. When the peroxisomal core was subjected to treatment at various pH's with 0.1 M carbonate buffer, urate oxidase was almost completely solubulized at pH 11.0, although approximately 35% of the core protein still remained in the pellet After solubilization of the core at pH 11.0, the specific activity of urate oxidase in the supernatant increased about 1.6 times; the density of the insoluble protein remaining in the pellet was identical with the that of the original core on sucrose density gradient centrifugation.     

Studies on peroxisomes III. Further studies on the intraparticulate localization of peroxisomal components in the liver of the rat

The peroxisome-rich fraction prepared from rat liver homogenate was treated by various procedures and the behavior of the peroxisomal core on sucrose density gradient centrifugation was investigated.Peroxisomes were destroyed by various treatments, such as pH 9.0, VirTis blender, sonication and deoxycholate, resulting in the solubilization of catalase from the particles. Urate oxidase was not solubilized at all such treatments. Although D-amino acid oxidase was solubilized by treatments with deoxycholate and VirTis blender, this enzyme was found to be resistant to solubilization by treatment with pH 9.0 or sonication, in contrast to catalase.When the peroxisomal core was investigated, using urate oxidase activity as a marker, its density proved to be changed when submitted to various treatments. These results indicated that the peroxisomes consist of four compartments: a catalase-containing compartment (matrix), a urate oxidase containing compartment (core), a D-amino acid oxidase containing compartment and a low density compartment which is proposed for the first time in the present paper. Furthermore, it was also found that the last two compartments seem to be bound to the core, though the binding might be weak.     

Glucocorticoid regulation of rat liver urate oxidase

Urate oxidase, an enzyme involved in purine catabolism, comprises the crystalline core of rat liver peroxisomes. An affinity-purified monospecific antibody was developed to study the expression of urate oxidase protein levels. Immunoreactive urate oxidase was not detectable in prenatal liver; however, it is present at low levels after birth until approximately day 15 (postnatal age); expression sharply increases just prior to day 20, after which the enzyme is maintained at adult levels. This pattern of expression was similar to that of another peroxisomal enzyme, catalase; these developmental increases reflect the increase in peroxisomal number. Administration of exogenous glucocorticoid hormone to 10-day-old rats resulted in a precocious rise (2.5-fold) in urate oxidase levels. Adrenalectomy at 10 days of age did not cause decreased levels in the fourth week of life. In adult animals, while exogenous glucocorticoid administration did not influence urate oxidase levels, adrenalectomy at 60 days of age decreased urate oxidase levels to 40 percent of control levels. Subsequent administration of exogenous glucocorticoid hormone restored urate oxidase to normal levels. Parallel studies of catalase levels indicate that this glucocorticoid-sensitive response is not generalized for all peroxisomal proteins. Our results suggest that peroxisomes proliferate during early postnatal development, but after this process is complete, the biogenesis of individual peroxisomal proteins may be independently regulated.     

Selective induction of peroxisomal enzymes by the hypolipidemic drug bezafibrate. Detection of modulations by automatic image analysis in conjunction with immunoelectron microscopy and immunoblotting

Quantitative immunoelectron microscopy in conjunction with quantitative analysis of immunoblots have been used to study the effects of bezafibrate (BF), a peroxisome-proliferating hypolipidemic drug, upon six different enzyme proteins in rat liver peroxisomes (Po). Antibodies against following peroxisomal enzymes: catalase, urate oxidase, alpha-hydroxy acid oxidase, acyl-CoA oxidase, bifunctional enzyme (hydratase-dehydrogenase) and thiolase, were raised in rabbits, and their monospecificities were confirmed by immunoblotting. Female Sprague-Dawley rats were treated for 7 days with 250 mg/kg/day bezafibrate and liver sections were incubated with the appropriate antibodies followed by the protein A-gold complex. The labeling density for each enzyme was estimated by automatic image analysis. In parallel experiments immunoblots prepared from highly purified peroxisome fractions of normal and BF-treated rats were incubated with the same antibodies. The antigens were visualized by an improved protein A-gold method including an anti-protein A step and silver amplification. The immunoblots were also quantitated by an image analyzer. The results revealed a selective induction of beta-oxidation enzymes by bezafibrate with thiolase showing the most increase followed by bifunctional protein and acyl-CoA oxidase. The labeling density for catalase and alpha-hydroxy acid oxidase was reduced, confirming fully the quantitative analysis of immunoblots which in addition revealed reduction of uricase. These observations demonstrate that hypolipidemic drugs induce selectively the beta-oxidation enzymes while other peroxisomal enzymes are reduced. The quantitative immunoelectron microscopy with automatic image analysis provides a versatile, highly sensitive and efficient method for rapid detection of modulations of individual proteins in peroxisomes.     

Cytochemical and immunocytochemical study on the peroxisomes of rat liver after administration of a hypolipidemic drug, MLM-160

After administration of a hypolipidemic drug, MLM-160, to male rats, liver peroxisomes were studied by biochemical, cytochemical, and immunocytochemical methods. The activities of D-amino acid oxidase, glycolate oxidase, and urate oxidase increased 2 to 3-fold by the treatment. The increase of the oxidases was confirmed by immunoblotting analysis. By light microscopy, immunoreaction for catalase was present in the cytoplasmic granules of hepatocytes. The stained granules formed some clusters and overlapped each other after MLM-160 treatment. However, immunostaining for D-amino acid oxidase and urate oxidase was present in discrete fine granules which did not overlap each other. By electron microscopy, many peroxisomes showed ring-like extensions and cavitation of the matrix, often giving the appearance of a peroxisome-within-a-peroxisome. In many cases, these unusual peroxisomes seemed to be interconnected with each other. Within the peroxisomes, the catalase was localized in the matrix. Urate oxidase was associated with the crystalloid cores. D-amino acid oxidase was localized focally in a small part of the matrix where the catalase was mostly negative. In conclusion, the administration of MLM-160 to male rats induces some peroxisomal oxidases, accompanying the appearance of unusual peroxisomes. The precise localization of peroxisomal enzymes suggested that there are subcompartments within the liver peroxisomes as shown in rat kidney peroxisomes.     

Subcellular Distribution of Enzymes in Ochromonas malhamensis*

SYNOPSIS. The activity and distribution of 7 enzymes in Ochromonas malhamensis were studied. Subcellular organelles were separated by centrifugation at 648,000 g min to precipitate the larger particles; the resulting supernatant was centrifuged at 5,560,000 g min to separate the microsomal fraction from the supernatant. Sixty-four percent of the cytochrome oxidase (1.9.3.1 ferrocytochrome c:oxygen oxidoreductase, 81% of the catalase (1.11.1.6 hydrogen-peroxide: hydrogen-peroxide oxidoreductase) and 70% of the urate oxidase (1.7.3.3 urate:oxygen oxidoreductase) activity was associated with the larger particles, altho only 20% of the total protein was found in this fraction. Three acid hydrolases, cathepsin (3.4.4.9 cathepsin C, acid phosphatase (3.1.3.2 orthophosphoric monoesterphosphohydrolase) and acid ribonuclease (2.7.7.17 ribonucleate nucleotido-2′-transferase) were found mostly in the supernate (50-60%, yet their latency and their similar subcellular distribution indicated the presence of lysosomes. After 2.5 hr centrifugation in a sucrose density gradient (ρ= 1.08–1.25, the acid hydrolases showed a broad distribution which differed greatly from cytochrome oxidase associated with mitochondria. Catalase, which could not be separated from cytochrome oxidase by centrifuging on this gradient, had a different distribution after centrifugation on a kinetic gradient. Urate oxidase had a similar distribution to catalase and both these enzymes were latent, indicating the presence of peroxisomes.     

On the loss of uricolytic activity during primate evolution--I. Silencing of urate oxidase in a hominoid ancestor

Urate oxidase activity is not detectable in liver homogenates from the gibbon, orangutan, chimpanzee, gorilla and human. Liver homogenates from five genera of Old World and two genera of New World monkeys have easily detectable levels of urate oxidase activity. There is no evidence for extant detectable intermediate steps in the loss of urate oxidase activity in the hominoids. Urate oxidase activity from Old World and New World monkeys is stable, a simple observation which debunks a long-standing myth. Urate oxidase activity was silenced in an ancestor to the five living genera of hominoids after divergence from the Old World monkeys.     

尿酸氧化酶在大肠杆菌中的表达、纯化及活性鉴定

尿酸氧化酶(urate oxidase,Uricase,EC.1.7.3.3)是一种能将尿酸氧化为尿囊素的蛋白酶。合成黄曲霉(Aspergillus flavus)尿酸氧化酶基因,构建表达载体pET43.1a/uox,重组质粒经双酶切鉴定和序列分析,证明插入序列正确,转化到大肠杆菌(Escherichia coli)JM109,菌株经诱导表达尿酸氧化酶蛋白,目的蛋白经过超声破碎,经检测以可溶性蛋白为主;菌体经超声破碎后,上清经过阴离子柱和阳离子柱两步纯化,得到尿酸氧化酶纯品,纯品以分光光度法进行体外酶活性测定。结果显示:尿酸氧化酶在大肠杆菌中获得高效表达,目的蛋白占菌体总蛋白的50%;表达产物经过两步层析柱纯化,获得电泳扫描纯度为95%的纯品;在体外活性测定中具有分解尿酸的能力,在临床检测和治疗中有重要意义。     

The different effects of the peroxisome proliferators clofibric acid and bis(2-ethylhexyl)phthalate on the activities of peroxisomal oxidases in rat liver

Treatment with peroxisome proliferators induces increased numbers and alterations in the shape of peroxisomes in liver. It ultimately leads to hepatocellular carcinomas induced by the persistent production of high amounts of H2O2 as a result of a dramatical increase in acyl-CoA oxidase activity. The effects of peroxisome proliferators on other peroxisomal oxidase activities are less well documented. In the present study, the distribution patterns of the activity of SdD-amino acid oxidase, SlD-alpha-hydroxy acid oxidase, polyamine oxidase, urate oxidase and catalase activities were investigated in unfixed cryostat sections of liver, kidney and duodenum of rats treated with either clofibrate or bis(2-ethylhexyl)phthalate. The activities of xanthine oxidoreductase, which produces urate, a potent anti-oxidant, and xanthine oxidase, which produces oxygen radicals, were studied as well. The liver was the only organ that was affected by treatment. The number of peroxisomes increased considerably. SdD-Amino acid oxidase and polyamine oxidase activities were completely abolished by the treatment, whereas SlD-alpha-hydroxy acid oxidase activity decreased and urate oxidase activity increased periportally and decreased pericentrally. Total catalase activity increased because of the larger numbers of peroxisomes, but it decreased per individual peroxisome. Xanthine oxidoreductase activity decreased, whereas the percentage of xanthine oxidase remained constant. We conclude that oxidases in rat liver are affected differentially, indicating that the expression of activity of each oxidase is regulated individually. © 1998 Chapman & Hall     

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.     

Cytochemical localization of catalase and several hydrogen peroxide-producing oxidases in the nucleoids and matrix of rat liver peroxisomes

Synopsis The distribution of catalase, amino acid oxidase, -hydroxy acid oxidase, urate oxidase and alcohol oxidase was studied cytochemically in rat hepatocytes. The presence of catalase was demonstrated with the conventional diaminobenzidine technique. Oxidase activities were visualized with methods based on the enzymatic or chemical trapping of the hydrogen peroxide produced by these enzymes during aerobic incubations.All enzymes investigated were found to be present in peroxisomes. Catalase activity was found in the peroxisomal matrix, but also associated with the nucleoid. After staining for oxidase activities the stain deposits occurred invariably in the peroxisomal matrix as well as in the nucleoids. In all experiments the activity of both catalase and the oxidases was confined to the peroxisomes. The presence of a hydrogen peroxide-producing alcohol oxidase was demonstrated for the first time in peroxisomes in liver cells.The results imply that the enzyme activity of the nucleoids of rat liver peroxisomes is not exclusively due to urate oxidase. The nucleoids obviously contain a variety of other enzymes that may be more or less loosely associated with the insoluble components of these structures.     

Isolation of several cDNAs encoding yeast peroxisomal enzymes

Several candidate clones carrying partial cDNAs for yeast peroxisomal enzymes, such as catalase, carnitine acetyltransferase, isocitrate lyase, malate synthase and acyl-CoA oxidase, were efficiently isolated at a single plating from a phage lambda gt11 recombinant cDNA library prepared with poly(A)-rich RNA from an n-alkane-grown yeast, Candida tropicalis, with a mixture of antibodies against the respective purified enzymes. Among them, one candidate clone carrying partial cDNA for catalase was subcloned and subjected to nucleotide sequence analysis. We succeeded in determining that the amino acid sequence deduced from the nucleotide analysis included the sequences derived from the two peptide fragments obtained from the purified enzyme.     

Purification and some properties of rat liver cysteine oxidase (cysteine dioxygenase).

Cysteine oxidase (cysteine dioxygenase, EC 1.13.11.20) was purified approximately 1000-fold from rat liver. The purified enzyme (protein-B) was obtained as an inactive form, which was activated by anaerobic preincubation with L-cysteine. The active form of protein-B was inactivated during aerobic incubation to produce cysteine sulfinate. This inactivation of protein-B was protected by a distinct protein in rat liver cytoplasm, namely stabilizing protein (protein-A). The Ka and Km values for L-cysteine were 0.8-10(-3) M and 1.3-10(-3) M respectively. The enzyme was strongly inhibited by Cu+ and/or Fe2+ chelating agents but not by Cu2+ chelating agent. The optimum pH of enzyme reaction was 8.5-9.5 while that of enzyme activation was 6.8-9.5, with a broad peak.     

Ultramicroassay of hydrogen peroxide-producing oxidases

3-Amino 1,2,4-triazole inhibits catalase irreversibly in the presence of hydrogen peroxide produced by urate oxidase and d-amino acid oxidase. Linearity can be obtained between the inhibition of catalase and the activity of the oxidases. A few microunits urate oxidase and d-amino acid oxidase, corresponding to less than 1 μg frozen-dried rat liver and kidney, respectively, can be determined by the simple assay of the remaining catalatic activity.     

Towards the physiological function of uric acid

Uric acid, or more correctly (at physiological pH values), its monoanion urate, is traditionally considered to be a metabolically inert end-product of purine metabolism in man, without any physiology value. However, this ubiquitous compound has proven to be selective antioxidant, capable especially of reaction with hydroxyl radicals and hypochlorous acid, itself being converted to innocuous products (allantoin, allantoate, glyoxylate, urea, oxalate). There is now evidence for such processes not only in vitro and in isolated organs, but also in the human lung in vivo. Urate may also serve as an oxidase cosubstrate for the enzyme cyclooxygenase. As shown for the coronary system, a major site of production of urates is the microvascular endothelium, and there is generally a net release of urate from the human myocardium in vivo. In isolated organ preparations, urate protects against reperfusion damage induced by activated granulocytes, cells known to produce a variety of radicals and oxidants. Intriguingly, urate prevents inactivation of endothelial enzymes (cyclooxygenase, angiotensin converting enzyme) and preserves the ability of the endothelium to mediate vascular dilatation in the face of oxidative stress, suggesting a particular relationship between the site of urate formation and the need for a biologically potent radical scavenger and antioxidant.