Aluminum effect on the activity of superoxide dismutase and of other antioxygenic enzymes in vitro

The effect of Al on superoxide dismutase (SOD) and on other antioxygenic enzymes: horseradish peroxidase, catalase, and glutathione peroxidase, has been investigated in vitro. In the case of SOD, the effect of metal chelators (EDTA and deferoxamine) and a possible synergistic effect with iron salts have also been tested using the pyrogallol assay. There is no significant inhibitory effect of Al on the activity of any of the above-mentioned enzymes. Noticeable increases in SOD activity were observed when metal chelators were added to the medium, but not when high concentrations of Al were present too, in the case of deferoxamine (DFO). The former fact seems to be a consequence of the chelation of transition metal ions that catalyze pyrogallol autoxidation by a mechanism not inhibitable by SOD, interfering in its action, which may account for part of the DFO antioxidant effect observed in vivo. The latter phenomenon could be owing to a saturation of the chelating capacity of DFO by an excess of Al present in the medium, which should bring the system back to the interfering conditions explained above. It can be concluded that Al, either in the presence or in the absence of iron salts, does not inhibit SOD activity in vitro. Moreover, no significant binding of Al to SOD was demonstrated, and the amounts of its metal constituents, Cu and Zn, were not affected by preincubation of the enzyme with Al. The effect of the different compounds tested on the rate of autoxidation of the indicating scavenger, pyrogallol, and a suitable hypothesis on their role in the oxidation process are also discussed.     

The peroxidase activity of mitochondrial superoxide dismutase

Manganese superoxide dismutase (MnSOD) is an integral mitochondrial protein known as a first-line antioxidant defense against superoxide radical anions produced as by-products of the electron transport chain. Recent studies have shaped the idea that by regulating the mitochondrial redox status and H₂O₂ outflow, MnSOD acts as a fundamental regulator of cellular proliferation, metabolism, and apoptosis, thereby assuming roles that extend far beyond its proposed antioxidant functions. Accordingly, allelic variations of MnSOD that have been shown to augment levels of MnSOD in mitochondria result in a 10-fold increase in prostate cancer risk. In addition, epidemiologic studies indicate that reduced glutathione peroxidase activity along with increases in H₂O₂ further increase cancer risk in the face of MnSOD overexpression. These facts led us to hypothesize that, like its Cu,ZnSOD counterpart, MnSOD may work as a peroxidase, utilizing H₂O₂ to promote mitochondrial damage, a known cancer risk factor. Here we report that MnSOD indeed possesses peroxidase activity that manifests in mitochondria when the enzyme is overexpressed.     

A mimic of superoxide dismutase activity based upon desferrioxamine B and manganese(IV)

MnO2 reacted with desferrioxamine B yielding a green, water-soluble complex, with absorption maxima at 315 and 635 nm whose extinction coefficients were 925 and 60 M-1 cm-1, respectively. Increasing the proportion of ligand to metal increased both color yield and ability to scavenge O2-, with maximal color yield and activity being achieved at a 1:1 ratio. The complex catalyzed the dismutation of O2- and 1 microM was equivalent to 1 unit of superoxide dismutase activity in the xanthine oxidase-cytochrome c assay. The complex thus exhibited approximately 0.1% as much activity as did the manganese-containing superoxide dismutase, on the basis of manganese content. The activity of the complex was not suppressed by bovine serum albumin or by the soluble proteins extracted from Lactobacillus plantarum. In contrast, the activities of Cu(II) complexes of salicylate or Gly-His-Lys were suppressed by these proteins.     

The interrelationship of superoxide dismutase and peroxidatic enzymes in the red cell.

Activities of superoxide dismutase (superoxide:superoxide oxidoreductase, EC 1.15.1.1) and catalase (hydrogen-peroxide:hydrogen-peroxide oxidoreductase, EC 1.11.1.6) were determined during the course of incubation of red cell suspensions with 1,4-naphthoquinone-2-sulfonic acid. In the absence of glucose, incubation with napthoquinone sulfonate resulted in an inhibition of catalase and superoxide dismutase. The catalase inhibitor, 3-amino-1,2,4-triazole enhanced inactivation of catalase in the presence of naphthoquinone sulfonate and this in turn led to augmented inhibition of superoxide dismutase. The presence of glucose in the incubation medium prevented napthoquinone sulfonate-induced enzyme inhibition in the absence of aminotriazole, but had little effect in the presence of aminotriazole. The relevance of these findings to the cellular interrelationship of peroxidatic enzymes and superoxide dismutase is discussed.     

Antioxidant superoxide dismutase activity in obese children

The aim of the study was to evaluate the antioxidative Cu/Zn-SOD (superoxide dismutase) response to obesity-related stress in obese children compared to a similar-aged control group. Forty-eight exogenic obese children and 11 healthy children were compared for red cell Cu/Zn-SOD, glucose, and lipid profiles and the relations between the were investigated. Antioxidant response as Cu/Zn-SOD was significantly higher in the obese group (p<0.05). Although glucose and lipid levels were statistically higher in the obese group, a certain relation with the SOD level was not established in childhood. This is the first study showing the oxidative stress caused by obesity and related antioxidative response even in the childhood period. Interventions, including diet modifications, should be kept in mind to diminish the obesity-related oxidative stress from the childhood period.     

A protective function of superoxide dismutase during respiratory chain activity.

(1) Aerobic incubation of heart muscle submitochondrial particles in phosphate buffer after treatment with NADH causes a progressive and substantial inhibition of the NADH oxidation system. Succinate oxidation remains almost unaffected by NADH treatment. (2) The loss of NADH oxidase activity is due to an inhibition of the respiratory chain-linked NADH dehydrogenase. This inhibition of the enzyme is very similar to that caused by combination of the organic mercurial mersalyl with NADH dehydrogenase. (3) The inhibition of NADH oxidation is largely prevented by compounds that are known to react with superoxide ions (02-.), including superoxide dismutase, cytochrome c, tiron and Mn2+. EDTA also has a protective effect, but a number of other metal chelating agents, and several proteins, including catalase, are without effect. (4) It is concluded that the inhibition of NADH oxidation of NADH oxidation by superoxide ions or by mersalyl is reversible and is therefore not due to the loss of oxidoreduction components from the respiratory chain or to an irreversible change in protein conformation. (6) The function of mitochondrial superxide dismutase is discussed in relation to the key role of NADH dehydrogenase in energy-conserving reactions and the formation of hydrogen peroxide during mitochondrial oxidations.     

Increase of superoxide dismutase activity in various human leukemia cells.

(1) Superoxide dismutase activity in polymorphonuclear cells from human blood is considerably lower than that in lymphocytes. Macrophages from ascites show the middle level between the other two cells. (2) In myelocytic, monocytic, and lymphocytic leukemia cells, the enzyme activities are increased compared to those in the corresponding normal cells. (3) Gel electrophoresis patterns of all normal cells reveal bands corresponding to the cytosol and mitochondrial bands reported in previous studies. However, the mitochondrial Mn-containing superoxide dismutase activities are diminished or absent in leukemia cells. CN-insensitive superoxide dismutase activity in leukemia cells is not detected under the conditions.     

Removal of superoxide dismutase activity from cytochrome C

Commercially available cytochrome c contains sufficient superoxide dismutase activity to reduce its sensitivity in superoxide anion detection. A single passage through a column of Sephadex G-50 removes the superoxide dismutase, and appreciably increased the ability to cytochrome c to detect superoxide.     

Assay of superoxide dismutase activity in animal tissues

Convenient assays for superoxide dismutase have necessarily been of the indirect type. It was observed that among the different methods used for the assay of superoxide dismutase in rat liver homogenate, namely the xanthine-xanthine oxidase ferricytochromec, xanthine-xanthine oxidase nitroblue tetrazolium, and pyrogallol autoxidation methods, a modified pyrogallol autoxidation method appeared to be simple, rapid and reproducible. The xanthine-xanthine oxidase ferricytochromec method was applicable only to dialysed crude tissue homogenates. The xanthine-xanthine oxidase nitroblue tetrazolium method, either with sodium carbonate solution, pH 10.2, or potassium phosphate buffer, pH 7·8, was not applicable to rat liver homogenate even after extensive dialysis. Using the modified pyrogallol autoxidation method, data have been obtained for superoxide dismutase activity in different tissues of rat. The effect of age, including neonatal and postnatal development on the activity, as well as activity in normal and cancerous human tissues were also studied. The pyrogallol method has also been used for the assay of iron-containing superoxide dismutase inEscherichia coli and for the identification of superoxide dismutase on polyacrylamide gels after electrophoresis.     

Enhanced superoxide dismutase activity of pulsed cytochrome oxidase

The superoxide dismutase (SOD) activity of beef heart cytochrome oxidase, both in the resting (as isolated) and pulsed (reduced and reoxidized) states, has been investigated using their ability to inhibit the autoxidation rate of pyrogallol and epinephrine. Resting oxidase showed variable SOD activity, while in the pulsed state the SOD activity of cytochrome oxidase (CcO) increased by an order of magnitude. These results are discussed in terms of a physiological role for the pulsed oxidase.     

Temperature dependence of superoxide dismutase activity in plankton

The effect of temperature (from 1 to 37 °C) on in vitro effective superoxide dismutase (SOD) activity of several organisms was investigated and compared. Antarctic plankton, cultures of the alga Nannochloropsis sp., and the cyanobacterium Synechococcus strain WH 7803, and pure bovine erythrocyte SOD was studied. It was found that in all cases SOD activity increased with decreasing temperature within the temperature range assayed, in the Polar as well as the temperate plankton cells. This behavior of SOD is counterintuitive in terms of our experience when looking at enzyme activity or any other chemical reaction. We suggest a theoretical explanation for this apparently odd behavior. The advantage of such behavior is that the same amount of antioxidant will act better under low temperatures when reactive oxygen species (ROS) increase. Moreover, this protective process would act in vivo at a faster pace than the ex novo enzyme synthesis.     

Prion-like activity of Cu/Zn superoxide dismutase

Neurodegenerative diseases belong to a larger group of protein misfolding disorders, known as proteinopathies. There is increasing experimental evidence implicating prion-like mechanisms in many common neurodegenerative disorders, including Alzheimer disease, Parkinson disease, the tauopathies, and amyotrophic lateral sclerosis (ALS), all of which feature the aberrant misfolding and aggregation of specific proteins. The prion paradigm provides a mechanism by which a mutant or wild-type protein can dominate pathogenesis through the initiation of self-propagating protein misfolding. ALS, a lethal disease characterized by progressive degeneration of motor neurons is understood as a classical proteinopathy; the disease is typified by the formation of inclusions consisting of aggregated protein within and around motor neurons that can contribute to neurotoxicity. It is well established that misfolded/oxidized SOD1 protein is highly toxic to motor neurons and plays a prominent role in the pathology of ALS. Recent work has identified propagated protein misfolding properties in both mutant and wild-type SOD1, which may provide the molecular basis for the clinically observed contiguous spread of the disease through the neuroaxis. In this review we examine the current state of knowledge regarding the prion-like properties of SOD1 and comment on its proposed mechanisms of intercellular transmission.     

Production of superoxide and activity of superoxide dismutase in rabbit epididymal spermatozoa

Mature rabbit spermatozoa from the cauda epididymidis suspended in potassium Tris phosphate buffer at 24 degrees C produced O2.-, as measured by reduction of acetylated ferricytochrome c, with an intrinsic rate of 0.20 nmol/min per 10(8) cells. This rate increased to 1.80 nmol/min per 10(8) cells in the presence of 10 mM cyanide. These spermatozoa contain 2.8 units per 10(8) cells of superoxide dismutase activity, 95% of which is sensitive, and 5% of which is insensitive, to cyanide inhibition. These activities correspond to the cytosolic Cu-Zn form and the mitochondrial Mn form of the dismutase, respectively. Only the cyanide-sensitive form is released from the sperm on hypo-osmotic treatment or sonication. Hypo-osmotically treated rabbit epididymal spermatozoa produced O2.- with an intrinsic rate of 0.24 nmol/min per 10(8) cells, which increased to 0.58 nmol/min per 10(8) cells in the presence of 10 mM cyanide. Both intact and hypo-osmotically treated cells react with O2.- in a second order reaction as inferred from the hyperbolic dependence on cell concentration of O2.- production rate in both the absence and presence of cyanide. The second order rate constant for this reaction with intact cells, kS, was calculated to be 22.9 X 10(-8) (cells/ml)-1 min-1 in its absence. For hypo-osmotically treated cells, the values of kS were 10.8 X 10(-8) (cells/ml)-1 min-1 and 8.2 X 10(-8) (cells/ml) -1 min-1, respectively. Since hypo-osmotically treated cells have lost much of their plasma membrane, the lower value of kS for the treated cells implies that this membrane is one site of reaction of O2.- with the cells. The increase in kS in the presence of cyanide, which inhibits superoxide dismutase and so increases O2.- production, suggests that the cells become more reactive with O2.- as its production rate increase, as would be expected for the occurrence of radical chain oxidation. This in turn suggests that superoxide dismutase plays a major role in protecting rabbit sperm against damage from lipid peroxidation.     

Polarographic determination of superoxide dismutase.

A polarographic procedure is described which allows determination of the catalytic constants for superoxide dismutase-catalyzed reactions. The method presents a single and rapid evaluation of the enzyme concentrations as well as determination of its activity under different conditions; e.g., pH between 9 and 13, presence of urea, guanidine, sodium dodecyl sulphate and inhibitors such as CN^? and N₃^?.The results fit very well with data previously obtained with other methods and show that this polarographic procedure can be used under conditions that render the other methods unsuitable for the measurement of the enzyme activity.     

Activity of glutathione-dependent enzymes and superoxide dismutase in peptic ulcer]

Activity of Cu, Zn-superoxide dismutase, glutathione-S-peroxidase, glutathione-S-transferase, glutathione reductase, glucoso-6-phosphate dehydrogenase and content of glutathione reduced in blood of patients with gastric and duodenal ulcer depending on the age and parallel lesion of the hepatobiliary system have been studied. Considerable inhibition of superoxide dismutase, glucoso-6-phosphate-dehydrogenase activity and decrease of the content of reduced glutathione, the most pronounced in patients with parallel lesion of the hepatobiliary system, have been revealed. Glutathione reductase activity is high in all the patients, except for aged and old people with parallel lesions of the liver and biliferous tracts. Glutathione peroxidase is essentially active in adult patients, especially in case of combined pathology. Glutathione peroxidase activity is lower in aged and old patients as compared to the age norm, while the level of glutathione-S-transferase activity is high; at the same time there are no considerable changes in the glutathione-S-transferase activity in adult patients. The mechanisms of compensation and decompensation of functioning of enzymatic antiradical and antioxidant system under the peptic ulcer depending on the age of patients and concomitant lesions of the hepatobiliary system are discussed.     

Copper increases superoxide dismutase activity in rat liver

Superoxide dismutase (SOD) activity in rat liver cytosol and submitochondrial fractions was characterized as enzymatic and nonenzymatic (due to the SOD-like activity of copper) by four approaches: (i) aerobic NBT²⁺ (nitroblue tetrazolium) photoreduction in the absence of EDTA; (ii) aerobic NBT²⁺ photoreduction in the presence of 10^?4m EDTA; (iii) anaerobic NBT²⁺ photoreduction; and (iv) o-dianisidine photooxidation. Under normal conditions nonenzymatic SOD activity has been observed only in the intermembrane space. The single subcutaneous injection of rats with CuSO₄ solution (5 mg Cu/kg body wt) led to (i) an elevation of the copper level in all submitochondrial fractions; (ii) an increase in enzymatic SOD activity in only cytosol and intermembrane spaces; (iii) the appearance of a new electrophoretic SOD activity band in the intermembrane space preparations; and (iv) the appearance of nonenzymatic SOD-like activity in the outer and inner mitochondrial membranes, and a twofold increase in lipid hydroperoxides. This suggests that the increased nonenzymatic copper in vivo has a prooxidant effect, and does not catalyze the dismutation of O₂^? as it has been shown in in vitro experiments [E. M. Russanov S. G. Ljutakova, and S. I. Leutcher (1982) Arch. Biochem. Biophys.215, 220–229]. The peculiarities of the SOD activity in the intermembrane space are explained by the lysosomal localization of the granular CuZnSOD.