Epinephrine upregulates superoxide dismutase in human coronary artery endothelial cells

Regular exercise resulting in release of catecholamines is an oxidant stress, and yet it protects humans from acute cardiac events. We designed this study to examine the effect of epinephrine on free radical release and endogenous superoxide dismutase (SOD) gene and protein expression in human coronary artery endothelial cells (HCAECs). HCAECs were incubated with epinephrine (10(-9) to 10(-5) M) alone or with the water-soluble analog of vitamin E (trolox) (10(-5) M), the lipid-soluble vitamin E (5 x 10(-5) M), or the beta(1)-adrenergic blocker atenolol (10(-5) M). At 1 and 24 h of incubation with epinephrine, superoxide anion generation increased by 102 and 81% in the HCAECs. There was a marked increase in both MnSOD and Cu/ZnSOD mRNA and protein, as determined by RT-PCR and Western Analysis, respectively. Both MnSOD and Cu/ZnSOD activities were also increased. Pretreatment of HCAECs with trolox and vitamin E decreased superoxide anion generation (p <.05 vs. epinephrine alone) and blocked the subsequent upregulation of SOD mRNA and protein. Treatment of cells with the beta-blocker atenolol also blocked the upregulation of SOD (p <.05 vs. epinephrine alone). These observations suggest that epinephrine via beta(1)-adrenoceptor activation causes superoxide anion generation, and the superoxide subsequently upregulates the endogenous antioxidant species SOD. These observations may be the basis of long-term benefits of exercise.     

Intracellular Cu/Zn superoxide dismutase (Cu/Zn-SOD) from hard clam Meretrix meretrix: its cDNA cloning, mRNA expression and enzyme activity

Hard clam (Meretrix meretrix) is an economically important bivalve in China. In the present study, a gene coding for an intracellular Cu/Zn-SOD was cloned and characterized from hard clam. The full-length cDNA of this Cu/Zn-SOD (designated as Mm-icCuZn-SOD) consisted of 1,383?bp, with a 462-bp of open reading frame (ORF) encoding 153 amino acids. Several highly conserved motifs, including the Cu/Zn binding sites [H(46), H(48), H(63), and H(119) for Cu binding; H(63), H(71), H(80), and D(83) for Zn binding], an intracellular disulfide bond and two Cu/Zn-SOD signatures were identified in Mm-icCu/Zn-SOD. The deduced amino acid sequence of Mm-icCu/Zn-SOD has a high degree of homology with the Cu/Zn-dependent SODs from other species, indicating that Mm-icCu/Zn-SOD should be a member of the intracellular Cu/Zn-dependent SOD family. Real-time PCR analysis showed that the highest level of Mm-icCu/Zn-SOD expression was in the hepatopancreas, while the lowest level occurred in the hemocytes. Hard clam challenged with Vibrio anguillarum showed a time-dependent increase in Mm-icCu/Zn-SOD expression that reached a maximum level after 6?h. Mm-icCu/Zn-SOD purified as a recombinant protein expressed in E. coli retained a high level of biological activity, 83?% after 10?min incubation at 10–50?°C, and more than 87?% after incubation in buffers with pH values between 2.2 and 10.2. These results indicated that Mm-icCu/Zn-SOD may play an important role in the innate immune system of hard clam.     

Improved procedure for detection of superoxide dismutase isoforms in potato,Solanum tuberosum L.

Superoxide dismutase (SOD) in-gel activity assay with selective inhibitors (KCN and H₂O₂) is one of the most commonly used methods for identification of SOD isoform types, i.e., FeSOD, MnSOD or Cu/ZnSOD, and evaluation of oxidative stress response in plants. However, there are potential pitfalls that surround this assay, such as problem to detect isoforms with low activity, comigration of SOD isoforms or application of inappropriate inhibitor concentration. We propose an improved method based on the combination of in-gel analysis of SOD activity and native-PAGE immunoblotting for identification of isoforms and determination of SOD isoenzyme activity pattern in potato. Depending on cultivar and growing conditions, one MnSOD, 3 FeSOD and 5–6 Cu/ZnSOD isoforms were identified in potato leaves. The most important qualitative difference between ex vitro- and in vitro-grown plants was the presence of additional FeSOD and Cu/ZnSOD isoforms in plantlets grown in vitro. Compared with results of in-gel activity assay with selective inhibitors, new method allowed accurate identification of comigrating FeSOD and Cu/ZnSOD isoforms and two protein bands of ambiguous identities. Potato SODs were also characterized by SDS-PAGE immunoblotting and single MnSOD (23.6 kDa), three Cu/ZnSOD polypeptides (17.9, 17 and 16.3 kDa) and single FeSOD (25.1 kDa) polypeptide were detected in leaves of four examined cultivars. The difference in the number of FeSOD and Cu/ZnSOD isoforms/polypeptides between native-PAGE and SDS-PAGE immunoblots suggests that SOD proteins may have undergone post-translational modifications affecting protein mobility or existence of isoforms that differ from each other in total protein charge, but not in molecular weight.     

Mitochondrial localization of superoxide dismutase is required for decreasing radiation-induced cellular damage

We investigated the importance of mitochondrial localization of the SOD2 (MnSOD) transgene product for protection of 32D cl 3 hematopoietic cells from radiation-induced killing. Four plasmids containing (1) the native human copper/zinc superoxide dismutase (Cu/ZnSOD, SOD1) transgene, (2) the native SOD2 transgene, (3), the SOD2 transgene minus the mitochondrial localization leader sequence (MnSOD-ML), and (4) the SOD2 mitochondrial leader sequence attached to the active portion of the SOD1 transgene (ML-Cu/ZnSOD) were transfected into 32D cl 3 cells and subclonal lines selected by kanamycin resistance. Clonogenic in vitro radiation survival curves derived for each cell clone showed that Cu/ZnSOD- and MnSOD-ML-expressing clones had no increase in cellular radiation resistance (D0=0.89 +/- 0.01 and 1.08 +/- 0.02 Gy, respectively) compared to parent line 32D cl 3 (D0=1.15 +/- 0.11 Gy). In contrast, cell clones expressing either SOD2 or ML-Cu/ZnSOD were significantly radioresistant (D0=2.1 +/- 0.1 and 1.97 +/- 0.17 Gy, respectively). Mice injected intraesophageally with SOD2-plasmid/liposome (MnSOD-PL) complex demonstrated significantly less esophagitis after 35 Gy compared to control irradiated mice or mice injected intraesophageally with Cu/ZnSOD-PL or MnSOD-ML-PL. Mice injected with intraesophageal ML-Cu/ZnSOD-PL showed significant radioprotection in one experiment. The data demonstrate the importance of mitochondrial localization of SOD in the in vitro and in vivo protection of cells from radiation-induced cellular damage.     

Water restriction increases renal inner medullary manganese superoxide dismutase (MnSOD)

Oxidative stress damages cells. NaCl and urea are high in renal medullary interstitial fluid, which is necessary to concentrate urine, but which causes oxidative stress by elevating reactive oxygen species (ROS). Here, we measured the antioxidant enzyme superoxide dismutases (SODs, MnSOD, and Cu/ZnSOD) and catalase in mouse kidney that might mitigate the oxidative stress. MnSOD protein increases progressively from the cortex to the inner medulla, following the gradient of increasing NaCl and urea. MnSOD activity increases proportionately, but MnSOD mRNA does not. Water restriction, which elevates renal medullary NaCl and urea, increases MnSOD protein, accompanied by a proportionate increase in MnSOD enzymatic activity in the inner medulla, but not in the cortex or the outer medulla. In contrast, Cu/ZnSOD and TNF-α (an important regulator of MnSOD) do not vary between the regions of the kidney, and expression of catalase protein actually decreases from the cortex to the inner medulla. Water restriction increases activity of mitochondrial enzymes that catalyze production of ROS in the inner medulla, but reduces NADPH oxidase activity there. We also examined the effect of high NaCl and urea on MnSOD in Madin-Darby canine kidney (MDCK) cells. High NaCl and high urea both increase MnSOD in MDCK cells. This increase in MnSOD protein apparently depends on the elevation of ROS since it is eliminated by the antioxidant N-acetylcysteine, and it occurs without raising osmolality when ROS are elevated by antimycin A or xanthine oxidase plus xanthine. We conclude that ROS, induced by high NaCl and urea, increase MnSOD activity in the renal inner medulla, which moderates oxidative stress.     

Expression of superoxide dismutases in the bovine oviduct during the estrous cycle

The superoxide dismutases (SODs) are first-line enzymatic antioxidants that dismute superoxide anion (O(2)(-)) to produce hydrogen peroxide (H(2)O(2)). The primary objective was to characterize, by western blot analysis, the expression of two SODs, the cytosolic (Cu,ZnSOD or SOD1) and the mitochondrial (MnSOD or SOD2) forms in three sections of the oviduct, i.e. isthmus (I), ishtmic-ampullary junction (IA), and ampulla (A), during the estrous cycle. The Cu,ZnSOD and MnSOD proteins were mostly expressed in the ampulla (I相似文献   

Use of cyanide and diethyldithiocarbamate in the assay of superoxide dismutases.

Eucaryotes have two major forms of superoxide dismutase (SOD), Cu,ZnSOD and MnSOD; in most tissues Cu,ZnSOD is present in higher amounts than MnSOD. To assay MnSOD, Cu,ZnSOD can be inhibited selectively by millimolar concentrations of cyanide ion. However, calculation of MnSOD activity from the differential cyanide inhibition assay is complex and small experimental errors can cause large errors in the calculated MnSOD activity. We have assessed how interaction of cyanide and hydrogen peroxide with cytochrome c can lead to further errors in the xanthine oxidase-cytochrome c assay for SOD. Alternatively, Cu,ZnSOD can be completely inactivated by 50 mM diethyldithiocarbamate (DDC) at 30 degrees C for 1 h without affecting the activity of MnSOD. Since DDC reduces cytochrome c, the treated samples must be thoroughly dialyzed or desalted before assay. In the case of lung homogenates, dialysis is not an extra step since fresh, untreated samples must also be dialyzed or desalted before assaying by the cytochrome c method. Cu,ZnSOD activity is equal to the activity in the untreated sample minus the activity in the DDC-treated portion of the sample. Another copper chelator, triethylenetetramine, did not inactivate Cu,ZnSOD and could not be used instead of DDC. For accurate measurement of both enzymes in samples where MnSOD contributes only a small fraction of the total SOD activity, the DDC method has the advantage that it provides a direct measure of the MnSOD activity without interference by Cu,ZnSOD.     

Mechanism of superoxide dismutase/H(2)O(2)-mediated nitric oxide release from S-nitrosoglutathione--role of glutamate

S-Nitrosoglutathione (GSNO), a physiologically relevant nitric oxide ((*)NO) donor, exhibits antioxidant, anti-ischemic, and antiplatelet properties. The exact mechanism of (*)NO release from GSNO in biological systems has not been determined. Both copper ions and copper-containing enzymes have been shown to catalyze (*)NO release from GSNO. In this study we observed that copper-zinc superoxide dismutase (Cu,ZnSOD) in the presence of H(2)O(2) caused a rapid decomposition of GSNO, forming oxidized glutathione (GSSG) and (*)NO. The cupric ions (Cu(2+)) released from Cu,ZnSOD were bound to the glutamate moiety of GSNO, yielding a 2:1 (GSNO)(2)Cu(2+) complex. Strong chelators of cupric ions, such as histidine and diethylenetriaminepentaacetic acid, inhibited the formation of (GSNO)(2)Cu(2+) complex, GSSG, and (*)NO. GSSG alone inhibited Cu(2+)-induced decomposition of GSNO. This effect is attributed to complexation of copper by GSSG. We conclude that binding of copper to GSNO is obligatory for (*)NO release from GSNO; however, the rate of this reaction was considerably slowed due to binding of Cu(2+) by GSSG. The glutamate moiety in GSNO and GSSG controls copper-catalyzed (*)NO release from GSNO. Cu,ZnSOD and H(2)O(2) enhanced peroxidation of unsaturated lipid that was inhibited by GSNO. The antioxidant function of GSNO is related to the sequestering of copper by GSNO and its ability to slowly release (*)NO. Implications of these findings are discussed in relation to GSNO-induced cardioprotection and to neuropathological processes.     

Overexpression of manganese superoxide dismutase attenuates neuronal death in human cells expressing mutant (G37R) Cu/Zn-superoxide dismutase

Amyotrophic lateral sclerosis (ALS) is a progressive neurodegenerative disease characterized by loss of motor function and eventual death as a result of degeneration of motor neurons in the spinal cord and brain. The discovery of mutations in SOD1, the gene encoding the antioxidant enzyme Cu/Zn-superoxide dismutase (CuZnSOD), in a subset of ALS patients has led to new insight into the pathophysiology of ALS. Utilizing a novel adenovirus gene delivery system, our laboratory has developed a human cell culture model using chemically differentiated neuroblastoma cells to investigate how mutations in SOD1 lead to neuronal death. Expression of mutant SOD1 (G37R) resulted in a time and dose-related death of differentiated neuroblastoma cells. This cell death was inhibited by overexpression of the antioxidant enzyme manganese superoxide dismutase (MnSOD). These observations support the hypothesis that mutant SOD1-associated neuronal death is associated with alterations in oxidative stress, and since MnSOD is a mitochondrial enzyme, suggest that mitochondria play a key role in disease pathogenesis. Our findings in this model of inhibition of mutant SOD1-associated death by MnSOD represent an unique approach to explore the underlying mechanisms of mutant SOD1 cytotoxicity and can be used to identify potential therapeutic agents for further testing.     

Characterization of the Bacillus stearothermophilus manganese superoxide dismutase gene and its ability to complement copper/zinc superoxide dismutase deficiency in Saccharomyces cerevisiae.

Recombinant clones containing the manganese superoxide dismutase (MnSOD) gene of Bacillus stearothermophilus were isolated with an oligonucleotide probe designed to match a part of the previously determined amino acid sequence. Complementation analyses, performed by introducing each plasmid into a superoxide dismutase-deficient mutant of Escherichia coli, allowed us to define the region of DNA which encodes the MnSOD structural gene and to identify a promoter region immediately upstream from the gene. These data were subsequently confirmed by DNA sequencing. Since MnSOD is normally restricted to the mitochondria in eucaryotes, we were interested (i) in determining whether B. stearothermophilus MnSOD could function in eucaryotic cytosol and (ii) in determining whether MnSOD could replace the structurally unrelated copper/zinc superoxide dismutase (Cu/ZnSOD) which is normally found there. To test this, the sequence encoding bacterial MnSOD was cloned into a yeast expression vector and subsequently introduced into a Cu/ZnSOD-deficient mutant of the yeast Saccharomyces cerevisiae. Functional expression of the protein was demonstrated, and complementation tests revealed that the protein was able to provide tolerance at wild-type levels to conditions which are normally restrictive for this mutant. Thus, in spite of the evolutionary unrelatedness of these two enzymes, Cu/ZnSOD can be functionally replaced by MnSOD in yeast cytosol.     

Superoxide dismutase activity in salt stressed wheat seedlings

We investigated the effect of salt stress on enzymatic activity of superoxide dismutase (SOD) isozymes in shoot and root tissues of salt tolerant and sensitive wheat (Triticum aestivum L. and Triticum durum Defs.) cultivars. Ten day old seedlings were subjected to 0.7 M NaCl stress for 3 and 5 days. Seedlings treated in the same manner without salt stress served as controls. Activity of SOD isozymes in root and shoot extracts was determined by activity staining of native polyacrylamide gels. In both shoot and root extracts of examined cultivars two isozymes of SOD, namely MnSOD and Cu/ZnSOD were identified. Cu/ZnSOD activity comprised 90 % of total SOD activity in both root and shoot tissues. Salt stress caused 1–1.5 fold increase in MnSOD activity of shoots in tolerant cultivars when compared with non-stressed controls. Under stress conditions, compared to controls all cultivars exhibited reduced MnSOD activity in root tissues. Cu/ZnSOD activity, on the other hand, was remarkably enhanced (3–4 fold) in root extracts of the tolerant cultivars, whereas it was reduced in the sensitive ones.     

Superoxide dismutase in Cryptococcus neoformans varieties gattii, grubi, and neoformans

Some clear dissimilarities occur among the varieties of Cryptococcus neoformans but there are few studies about the differences among individual yeast antioxidant enzymes. The total superoxide dismutase (SOD) activities and the copper, zinc-depend SOD (Cu,ZnSOD) and manganese-dependent SOD (MnSOD) isoenzymes of five reference C. neoformans strains belonged to A, B, C, AD and D serotypes (Table I) and other nine C. neoformans isolates (Table II) were determined. There were significant differences (p < 0.01 and p < 0.05) in total SOD activity among the varietie gattii (serotype C) and the other varieties. Cu,ZnSOD showed difference (p < 0.05) between A and D serotypes. These results point out a variety and serotype-independent SOD activity in C. neoformans reference strains and the other isolates that were evaluated.     

Regulation of superoxide dismutase expression by copper availability

The most abundant copper proteins in green tissues are plastocyanin (PC) in thylakoids and copper/zinc superoxide dismutase (Cu/ZnSOD) of which the major isoforms are found in the cytosol and in the chloroplast stroma. An iron superoxide dismutase (FeSOD) can also be found in the stroma. The expression of superoxide dismutases (SODs) has been studied mainly in the context of abiotic stress. However, the availability of metal cofactors may also determine SOD expression patterns. Indeed, in Arabidopsis thaliana , Cu/ZnSOD enzymes were only expressed when copper was sufficient. This observation was made for plants grown on sucrose-containing tissue culture media and regulation of SOD expression by copper has not been tested for other species. To investigate the effect of copper on SOD expression, we used a hydroponic set-up in which plants grew without any evident stress symptoms. We observed that A. thaliana , Brassica juncea , Lycopersicum lycopersicum , Zea mays and Oryza sativa , downregulated Cu/ZnSOD in response to copper limitation. Under this condition, FeSOD expression was upregulated to replace Cu/ZnSOD in the stroma in all plants except Z. mays , in which FeSOD was not detectable. Copper limitation did not affect PC accumulation in any of the plants except Z. mays . Comparisons of leaf copper contents and SOD expression suggest that Cu/ZnSOD and FeSOD expression levels are good indicators of impending copper deficiency. Plants that downregulate Cu/ZnSOD and upregulate FeSOD under copper limitation can maintain superoxide scavenging and save copper for use in PC, which is essential for photosynthesis.     

Overexpression of copper/zinc superoxide dismutase does not prevent neonatal lethality in mutant mice that lack manganese superoxide dismutase

There are two types of intracellular superoxide dismutases: the mitochondrial manganese SOD (MnSOD) and the cytoplasmic copper/zinc SOD (CuZnSOD). Mutant mice that lack MnSOD die shortly after birth because of cardiomyopathy and mitochondrial injury. In order to verify if CuZnSOD could compensate for MnSOD deficiency, a new mutant mouse that overexpresses CuZnSOD but is deficient in MnSOD was generated by crossing MnSOD knockout mice with CuZnSOD transgenic mice. CuZnSOD activity was significantly increased in the blood, brain, liver, and heart of MnSOD knockout, CuZnSOD transgenic mice when compared with nontransgenic mice. However, overexpression of CuZnSOD did not prevent neonatal lethality in mice that lack MnSOD, nor did it prevent oxidative aconitase inactivation, nor did it rescue MnSOD-deficient astrocytes in culture. Based on our findings, which emphasize the strong enzymatic compartmentalization of CuZnSOD and MnSOD, therapeutic antioxidant strategies should consider the final intracellular localization of the antioxidant used, especially when those strategies are directed against mitochondrial diseases.     

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.     

Cloned prokaryotic iron superoxide dismutase protects yeast cells against oxidative stress depending on mitochondrial location

Superoxide dismutase (SOD) is considered to be the first line of defense against oxygen toxicity. It exists as a family of three metalloproteins with copper,zinc (Cu,ZnSOD), manganese (MnSOD), and iron (FeSOD) forms. In this work, we have targeted Escherichia coli FeSOD to the mitochondrial intermembrane space (IMS) of yeast cells deficient in mitochondrial MnSOD. Our results show that FeSOD in the IMS increases the growth rate of the cells growing in minimal medium in air but does not protect the MnSOD-deficient yeast cells when exposed to induced oxidative stress. Cloned FeSOD must be targeted to the mitochondrial matrix to protect the cells from both physiological and induced oxidative stress. This confirms that the superoxide radical is mainly generated on the matrix side of the inner mitochondrial membrane of yeast cells, without excluding its potential appearance in the mitochondrial IMS where its elimination by SOD is beneficial to the cells.