一种鉴定过氧化氢酶活性的铁染色法

采用聚丙烯酰胺凝胶电泳(PAGE)技术,建立了一种新的鉴定过氧化氢酶活性的方法──铁染色法．结果表明,细菌过氧化氢酶及牛肝过氧化氢酶显示单一的酶活性带．该方法操作简单、快速、灵敏度高、专一性强.是一种切实可行的鉴定过氧化氢酶活性染色法.     

Inactivation and degradation of rat liver catalase by mitochondrial and lysosomal proteinases

The initial phases of catalase degradation in rat hepatocytes were studied. Preparations of highly purified fractions of lysosomes and mitochondria from rat liver were obtained. The proteinase activity was measured by the radio-isotope method by the increase of the free amino groups or by the decrease of the catalase activity, using labelled catalase as a substrate. It was found that the initial step of catalase degradation occurs in the enzyme localized in the inner membrane as well as in the mitochondrial matrix and that the total degradation of catalase is completed in the lysosomal fraction of rat liver.     

A convenient method for isolation of murine erythrocyte catalase by gel filtration and DEAE cellulose chromatography

A method for isolation of catalase from small volumes of murine red blood cells is described. The purified enzyme had a specific activity of 25,000 IU/mg protein and was judged to be homogeneous by polyacrylamide and sodium dodecyl sulphate electrophoresis. The specific activity of the isolated murine erythrocyte catalase is approximately 14–25% that of human erythrocyte catalase isolated by the method described.     

An oxygen electrode-based assay of catalase activity as a rapid method for estimating the bacterial content of foods

An oxygen electrode-based assay of catalase was developed as a simple method of assessing contamination by bacteria capable of respiration. The method gave a rapid and reasonable quantification of cell numbers in pure cultures and was able to detect 10³ bacteria/ml in some cases. The sensitivity of the method was dependent on the identity of the culture and when applied to foods the sensitivity was reduced due to the presence of non-microbial catalase. The use of electropositively charged filters to remove the organisms from the food sample improved the sensitivity and the relationship between catalase activity and cell numbers in some foods.     

Nitrite-catalase interaction as an important element of nitrite toxicity

It was established that nitrite in the presence of chloride, bromide, and thiocyanate decreases the rate of hydrogen peroxide decomposition by catalase. The decrease was recorded by the permanganatometric method and by a method of dynamic calorimetry. Nitrite was not destroyed in the course of the reaction and the total value of heat produced in the process was not changed by its presence. These facts suggest that nitrite induces inhibition of catalase with no change in the essence of the enzymatic process. Even micromolar nitrite concentrations induced a considerable decrease in catalase activity. However, in the absence of chloride, bromide, and thiocyanate inhibition was not observed. In contrast, fluoride protected catalase from nitrite inhibition in the presence of the above-mentioned halides and pseudohalide. As hydrogen peroxide is a necessary factor for triggering a number of important toxic effects of nitrite, the latter increases its toxicity by inhibiting catalase. This was shown by the example of nitrite-induced hemoglobin oxidation. The naturally existing gradient of chloride and other anion concentrations between intra- and extracellular media appears to be the most important mechanism of cell protection from inhibition of intracellular catalase by nitrite. Possible mechanisms of this inhibition are discussed.     

Catalase T deficient mutants of Saccharomyces cerevisiae

A method for the isolation of catalase T deficient mutants of Saccharomyces cerevisiae is described. Ten mutants lacking catalase T and belonging to 5 complementation groups were isolated. CTT1 locus was identified as the structural gene for catalase T. It is under the control of CTT2, CTT3 and CTT4 loci.     

大鼠肝脏过氧化氢酶的分离纯化及性质

根据过氧化氢酶的催化特性,采用盐析,透析,离心等技术,从大鼠肝脏中分离纯化过氧化氢酶,提纯倍数达到26倍,酶活性回收率为57%。为一般实验室分离纯化大鼠过氧化氢酶提供了一种有效的方法。酶学性质研究表明,该酶最适温度为37℃,最适pH值为7.5,在此条件下,以过氧化氢为底物的Km值为56 mmol.L-1。     

微胶囊固定化过氧化氢酶的制取及对H_2O_2的分解作用

以乙基纤维素为膜材,用溶液干燥法制取了微胶囊固定化过氧化氢酶,探讨了制取过程中明胶的加入对微胶囊产率及固定化过氧化氢酶活性的影响,同时论述了存放时间、温度以及环境ｐＨ值对微胶囊固定化过氧化氢酶稳定性的影响．深入研究了微胶囊固定化过氧化氢酶对Ｈ２Ｏ２的分解作用,获得了十分有意义的结果     

High-level expression and purification of recombinant human catalase in Pichia pastoris

Catalase is one of the antioxidant enzymes and is involved in many pathophysiologic processes and human diseases. This study focused on high-level expression and purification of recombinant catalase in Pichia pastoris. The cDNA encoding catalase was cloned by RT-PCR from Fetal liver of Homo sapiens. After PCR and construction of expression vector pPIC9K-CAT, human catalase was expressed highly in P. pastoris yeast SMD1168 and secreted into the culture medium. The secreted catalase was purified to a purity of 95% by ammonium sulfate fractionation, anionic exchange-chromatography, and Macro-prep Ceramic Hydroxyapatite with a overall yield of 60%. This study provides a new method for large-scale expression and purification of recombinant protein catalase.     

Cellular and subcellular localization of catalase in the heart of transgenic mice.

Previous studies have described a cardiac-specific, catalase-overexpressing transgenic mouse model that was used to study myocardial oxidative injury. This study was undertaken to demonstrate cellular and subcellular localization of catalase in the hearts of transgenic mice. By the light microscopic immunoperoxidase method, we found that the overexpressed catalase was exclusively localized in cardiomyocytes. The ratios of immunoreactive cardiomyocytes in the heart were quite different among three transgenic lines examined but agreed with the elevated levels of catalase activity. In the cardiac blood vessels, positive cells were found in the walls of pulmonary veins and the vena cava, which consist of cardiomyocytes, but not in the pulmonary arteries, aorta, or cardiac valves. The electron microscopic immunogold method revealed that the elevated catalase was in sarcoplasm, nucleus, and peroxisomes, but not in mitochondria. In contrast to these distributions, catalase in the non-transgenic cardiomyocytes was in peroxisomes only. In addition, the number and size of peroxisomes in the transgenic cardiomyocytes were markedly increased, but no other ultrastructural changes were observed in comparison with those of non-transgenic mice. These results demonstrated that the elevated catalase in transgenic mouse heart is localized in cardiomyocytes and is distributed to peroxisomal and extraperoxisomal, but not mitochondrial, compartments.     

A Note on a Method for Demonstrating Yeast Catalases after Electrophoresis in Acrylamide Gels

S ummary : A method for demonstrating sites of catalase activity after electrophoresis of yeast cell extracts in acrylamide gel is described. The method yields permanent preparations of catalase patterns and thereby facilitates the recording of results.     

An examination of the oxidation of mercury vapor by rat brain homogenate

The oxidation of mercury vapor (Hg degrees) to divalent inorganic mercury (Hg2+) was studied in rat brain homogenates. By using a "degassing" method, it was possible to speciate the mercury present in the homogenate and, for the first time, to measure the rate of oxidation as a function of the substrate (Hg degrees) concentration. Mercury oxidation was first-order with respect to substrate concentration at all concentrations tested, and the first-order rate constant for the oxidation process was proportional to homogenate concentration. The role of catalase compound I in mercury vapor oxidation by brain homogenate was examined by observing the effects of two inhibitors of catalase (catalase compound I) on homogenate mercury-oxidizing activity and catalase activity. Sodium azide (50 mM) completely inhibited both mercury-oxidizing activity and catalase activity. Aminotriazole (3-amino-1H-1,2,4-triazole) (50 mM) completely inhibited only mercury-oxidizing activity; some residual catalase activity was found in the aminotriazole-treated homogenate. It was concluded that catalase compound I plays a major role in the oxidation of Hg degrees, but the possibility that catalase-independent pathways make a minor contribution cannot be excluded.     

Effect of cobalt on the synthesis and degradation of hepatic catalse in vivo

1. The administration of CoCl(2) to rats caused a decrease in hepatic catalase activity as well as a decrease in the amount of catalase protein as measured by immunological assay. The mitochondrial enzyme decreased progressively over 2 days, whereas the cytosol enzyme decreased over 12h and then remained essentially unchanged for 2 days after a single injection of cobalt. 2. Incorporation of [(14)C]glycine into catalase haem was dramatically decreased by a single injection of cobalt, but that into catalase protein remained essentially unaltered. 3. Incorporation of [(3)H]leucine into liver protein increased in rats in a steady state receiving a daily injection of cobalt, which was in contrast with a marked inhibition observed in 5-amino[(3)H]laevulinate incorporation. 4. The initial rate of [(3)H]leucine incorporation into mitochondrial and cytosol catalase did not alter or was slightly depressed in the cobalt-treated animals, whereas the incorporation of 5-amino[(3)H]laevulinate into mitochondrial and cytosol catalase was conspicuously decreased, indicating that haem synthesis was limiting catalase formation. 5. The degradation rate of catalase protein, as measured by a double-labelling method, was not changed by the cobalt treatment.     

A more sensitive modification of the catalase assay with the Clark oxygen electrode: Application to the kinetic study of the pea leaf enzyme

A modification of the method of catalase determination by means of the Clark oxygen electrode is described. The assay is based on measurement of the initial rate at which oxygen is released by catalase in an oxygen-free buffer. Displacement of oxygen was brought about by flushing with nitrogen, and the substrate used was hydrogen peroxide at a 33.5 mm final concentration. The method is rapid and can be used with crude catalase preparations. Its sensitivity is at least 20 times higher than that of previous methods; it has an interval of measurable activity of about 0.01–8.4 μmol of O₂/min and, therefore, is applicable to an 840-fold range of catalase concentrations. This modification was applied to the kinetic study of crude extracts of pea leaf catalase. An apparent K_m of 0.190 m was calculated.     

A more sensitive modification of the catalase assay with the Clark oxygen electrode : Application to the kinetic study of the pea leaf enzyme

A modification of the method of catalase determination by means of the Clark oxygen electrode is described. The assay is based on measurement of the initial rate at which oxygen is released by catalase in an oxygen-free buffer. Displacement of oxygen was brought about by flushing with nitrogen, and the substrate used was hydrogen peroxide at a 33.5 m final concentration. The method is rapid and can be used with crude catalase preparations. Its sensitivity is at least 20 times higher than that of previous methods; it has an interval of measurable activity of about 0.01–8.4 μmol of O₂/min and, therefore, is applicable to an 840-fold range of catalase concentrations. This modification was applied to the kinetic study of crude extracts of pea leaf catalase. An apparent K_m of 0.190 was calculated.     

A Simultaneous Visualization of the Antioxidant Enzymes Glutathione Peroxidase and Catalase on Polyacrylamide Gels

A simple and sensitive method for the simultaneous visualization of glutathione peroxidase and catalase on polyacrylamide gels is described. The procedure included: (I) running samples on a 7. 5% polyacryla-mide gel, (2) soaking the gel in a certain concentration of reduced glutathione (0.25-2.0 mM). (3) soaking the gel in GSH plus H_zO_z or cumene hydroperoxide, (4) finally staining with a 1% ferric chloride I% potassium ferricyanide solution. The best concentration of glutathione for simultaneous visualization of glutathione peroxidase and catalase was 0.25rnM; I.5mM glutathione was the best concentration for visualization of glutathione peroxidase alone. The method is sensitive enough to detect catalase and glutathione peroxidase in mouse liver homogenates and also it is specific for glutathione peroxidase since other peroxidases such as lactoperoxidase, horseradish peroxidase and glutathione S-transferase cannot be visualized. Using this method, it was found that unlike catalase. glutathione peroxidase is heat resistant (68°C. 1min), but sensitive to 10mM sodium iodoacetate.     

Biosynthesis of liver catalase in rats treated with allylisopropylacetylcarbamide. I. Immunochemical assay of catalase in liver cell fractions.

Rats were injected twice intraperitoneally with 20 mg of allylisopropylacetylcarbamide (Sedormid) per 100 g of body weight at an interval of 12 hr. The level of catalase [EC 1.11.1.6] in various liver cell fractions was determined both enzymatically and immunochemically 12 hr after the second injection. 1. The decrease in catalase protein assayed by the immunochemical method directly confirmed the inhibition of biosynthesis of the enzyme by this porphyrinogenic drug. 2. The occurrence of a considerable amount of catalase protein with no enzymatic activity was demonstrated both in the peroxisomes and in the supernatant fraction. 3. The amount of catalase-synthesizing polysomes in hepatic cell was reduced in Sedormid-treated rats by the extent comparable to the decrease in the concentration of liver catalase.     

Augmentation of antioxidant enzymes in vascular endothelium

The endothelium is a key site of injury from reactive oxygen species that can potentially be protected by the antioxidant enzymes superoxide dismutase and catalase. Large proteins, such as superoxide dismutase and catalase, do not readily penetrate cell membranes, which limits their efficacy in protecting cells from cellular reactions involving both intracellularly and extracellularly generated reactive oxygen species. Two methods are described that promote enzyme delivery to cultured endothelial cells and confer increased resistance to oxidative stress. The first method is to entrap the antioxidant enzymes within liposomes, which then become incorporated by endothelial cells and can increase enzyme specific activities by as much as 44-fold within 2 h. The second method involves covalent conjugation of polyethylene glycol (PEG) to superoxide dismutase and catalase, a technique that increases circulatory half-life and reduces protein immunogenicity. Conjugation of PEG to superoxide dismutase and catalase increased cellular-specific activities of these enzymes in cultured endothelial cells (but at a slower rate than for liposome entrapped enzymes) and rendered these cells more resistant to oxidative stress. Both liposome-mediated delivery and PEG conjugation offer an additional benefit over native superoxide dismutase and catalase because they can increase cellular antioxidant activities in a manner that can provide protection from both intracellular and extracellular superoxide and hydrogen peroxide.     

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.     

A Simultaneous Visualization of the Antioxidant Enzymes Glutathione Peroxidase and Catalase on Polyacrylamide Gels

A simple and sensitive method for the simultaneous visualization of glutathione peroxidase and catalase on polyacrylamide gels is described. The procedure included: (I) running samples on a 7. 5% polyacryla-mide gel, (2) soaking the gel in a certain concentration of reduced glutathione (0.25–2.0 mM). (3) soaking the gel in GSH plus H_zO_z or cumene hydroperoxide, (4) finally staining with a 1% ferric chloride I% potassium ferricyanide solution. The best concentration of glutathione for simultaneous visualization of glutathione peroxidase and catalase was 0.25rnM; I.5mM glutathione was the best concentration for visualization of glutathione peroxidase alone. The method is sensitive enough to detect catalase and glutathione peroxidase in mouse liver homogenates and also it is specific for glutathione peroxidase since other peroxidases such as lactoperoxidase, horseradish peroxidase and glutathione S-transferase cannot be visualized. Using this method, it was found that unlike catalase. glutathione peroxidase is heat resistant (68°C. 1min), but sensitive to 10mM sodium iodoacetate.