Improvement in circulating superoxide dismutase levels: role of nonsteroidal anti-inflammatory drugs in rheumatoid arthritis

Superoxide anion radical plays a significant role in inflammation, like rheumatoid arthritis. Superoxide dismutase enzyme known to dismutate superoxide anion radical does not play any significant role in this multisystem disease. This paper reports that very low levels of circulating superoxide dismutase levels are observed in patients with rheumatoid arthritis and these levels significantly improve with NSAID therapy. The possible mechanism of the action is discussed.     

Role of oxidative stress in Drosophila aging.

We review the role that oxidative damage plays in regulating the lifespan of the fruit fly, Drosophila melanogaster. Results from our laboratory show that the lifespan of Drosophila is inversely correlated to its metabolic rate. The consumption of oxygen by adult insects is related to the rate of damage induced by oxygen radicals, which are purported to be generated as by-products of respiration. Moreover, products of activated oxygen species such as hydrogen peroxide and lipofuscin are higher in animals kept under conditions of increased metabolic rate. In order to understand the in vivo relationship between oxidative damage and the production of the superoxide radical, we generated transgenic strains of Drosophila melanogaster that synthesize excess levels of enzymatically active superoxide dismutase. This was accomplished by P-element transformation of Drosophila melanogaster with the bovine cDNA for CuZn superoxide dismutase, an enzyme that catalyzes the dismutation of the superoxide radical to hydrogen peroxide and water. Adult flies that express the bovine SOD in addition to native Drosophila SOD are more resistant to oxidative stresses and have a slight but significant increase in their mean lifespan. Thus, resistance to oxidative stress and lifespan of Drosophila can be manipulated by molecular genetic intervention. In addition, we have examined the ability of adult flies to respond to various environmental stresses during senescence. Resistance to oxidative stress, such as that induced by heat shock, is drastically reduced in senescent flies. This loss of resistance is correlated with the increase in protein damage generated in old flies by thermal stress and by the insufficient protection from cellular defense systems which includes the heat shock proteins as well as the oxygen radical scavenging enzymes. Collectively, results from our laboratory demonstrate that oxidative damage plays a role in governing the lifespan of Drosophila during normal metabolism and under conditions of environmental stress.     

The pathophysiology of superoxide: roles in inflammation and ischemia

The superoxide radical plays major roles in the neutrophil-medicated acute inflammatory response and in postischemic tissue injury, although the sources and actions of the radical are quite different in these two pathological states. While neutrophils produce superoxide for the primary purpose of aiding in the killing of ingested microbes, a second useful function has evolved. The superoxide released from actively phagocytosing neutrophils serves to attract more neutrophils by reacting with, and activating, a latent chemotactic factor present in plasma. Superoxide dismutase, by preventing the activation of this superoxide-dependent chemotactic factor, exerts potent anti-inflammatory action. During ischemia, energy-starved tissues catabolize ATP to hypoxanthine. Calcium transients in these cells appear to activate a calmodulin regulated protease which attacks the enzyme xanthine dehydrogenase, converting it to a xanthine oxidase capable of superoxide generation. When the tissue is reperfused and reoxygenated, all the necessary components are present (xanthine oxidase, hypoxanthine, and oxygen) to produce a burst of superoxide which results in extensive tissue damage. Ischemic tissues are protected by superoxide dismutase or allupurinol, an inhibitor of xanthine oxidase.     

Intratracheal injection of nickel chloride and copper-zinc superoxide dismutase activity in lung of rats.

Superoxide radical (O2-) is a free radical that may be involved in various toxic processes. Cu--Zn superoxide dismutase catalyses the dismutation of the superoxide free radical and protects cells from oxidative damage, and it has been used clinically. The concentration of Ni2+ and Cu--Zn superoxide dismutase activity were measured in lungs of rats at time intervals of 5, 12, 19, 26, 33, and 40 days following an intratracheal injection of 127 nmol of NiCl2. Nickel chloride increased nickel content and resulted in a significant increase of Cu--Zn superoxide dismutase activity in lungs. This elevation of Cu--Zn superoxide dismutase activity was highest on the 12th day (approximately threefold) and is at levels comparable to controls rats on day 40 onwards. Since Cu--Zn superoxide dismutase activity was increased in lung throughout our experimental period without corresponding increases of Cu2+ and Zn2+, we speculate that the elevation of Cu--Zn superoxide dismutase activity might be due to an increased half-life of the enzyme, induced by nickel.     

Measurement of superoxide-derived free radicals in the reperfused heart. Evidence for a free radical mechanism of reperfusion injury

There has been considerable controversy regarding the role of oxygen free radicals as important mediators of cell damage in reperfused myocardium. This controversy regards whether superoxide and hydroxyl free radicals are generated on reperfusion and if these radicals actually cause impaired contractile function. In this study, EPR studies using the spin trap 5,5-dimethyl-1-pyroline-n-oxide (DMPO) demonstrate the formation of .OH and R. free radicals in the reperfused heart. EPR signals of DMPO-OH, aN = aH = 14.9 G, and DMPO-R aN = 15.8 G aH = 22.8 G are observed, with peak concentrations during the first minute of reperfusion. It is demonstrated that these radicals are derived from .O2- since reperfusion in the presence of enzymatically active recombinant human superoxide dismutase markedly reduced the formation of these signals while inactive recombinant human superoxide dismutase had no effect. On reperfusion with perfusate pretreated to remove adventitial iron, the concentration of the DMPO-OH signal was increased 2-fold and a 4-fold decrease in the DMPO-R signal was observed demonstrating that iron-mediated Fenton chemistry occurs. Hearts reperfused with recombinant human superoxide dismutase exhibited improved contractile function in parallel with the marked reduction in measured free radicals. In order to determine if the reperfusion free radical burst results in impaired contractile function, simultaneous measurements of free radical generation and contractile function were performed. A direct relationship between free radical generation and subsequent impaired contractile function was observed. These studies suggest that superoxide derived .OH and R. free radicals are generated in the reperfused heart via Fenton chemistry. These radicals appear to be key mediators of myocardial reperfusion injury.     

Histochemical study of superoxide dismutase in the ovary of the rat during the oestrous cycle

Superoxide dismutase, an enzyme which causes the dismutation of superoxide free radical anions to generate hydrogen peroxide, has been localized in the rat ovary. The negative-staining method was used to provide photo-induced reduction of nitro-blue tetrazolium in cryostat sections of rat ovaries for histochemical localization of superoxide dismutase. Superoxide dismutase was found in growing follicles, the membrane granulosa of Graafian follicles, ovulated follicles and blood vessels. It is suggested that superoxide dismutase may play a role in regulating follicular development, ovulation and luteal functions.     

Product of extracellular-superoxide dismutase catalysis

Extracellular-superoxide dismutase is a tetrameric enzyme containing four copper atoms. It has previously been shown to catalyse the decay of the superoxide radical, but the resulting product was not determined. In a xanthine oxidase-xanthine system in which about 30% of the electron flux resulted in superoxide radical formation, accumulation of hydrogen peroxide was determined. Catalysis of superoxide radical decay by extracellular-superoxide dismutase was found to result in hydrogen peroxide formation. The catalysed reaction is thus identical to those of previously investigated superoxide dismutases. Human manganese superoxide dismutase was also found to dismute the superoxide radical to hydrogen peroxide and water.     

Changes in the levels of superoxide anion radical and superoxide dismutase during the estrous cycle of Rattus norvegicus and induction of superoxide dismutase in rat ovary by lutropin

Superoxide dismutase, which has been shown to be present in a number of tissues, exhibits cyclic changes during the reproductive cycle of rats. An inverse correlation is seen between the levels of superoxide dismutase and superoxide radical. In immature, pseudopregnant rats, primed with human Chorionic Gonadotropin, lutropin seemed to induce ovarian superoxide dismutase, which could be blocked significantly by the introduction of anti-LH serum. These results point out the specific induction of superoxide dismutase by lutropin. It is reasonable to postulate that during luteal functioning, luteinizing hormone induces superoxide dismutase which in turn seems to play a central role generating hydrogen peroxide from superoxide anion radicals. Hydrogen peroxide, thus formed, drives the peroxidase-ascorbate system, responsible for production of progesterone.     

Generation of superoxide free radical by neocarzinostatin and its possible role in DNA damage

Spectroscopic analysis of the reduction of both nitro blue tetrazolium and ferricytochrome c induced by neocarzinostatin shows that superoxide free radical is produced during the spontaneous degradation of the antibiotic. The amount of superoxide free radical produced from neocarzinostatin is not affected by the presence of thiol, although earlier work has shown that DNA damage is stimulated at least 1000-fold by thiol. Transition metals are not involved in this reaction. Although superoxide dismutase inhibits the reduction of nitro blue tetrazolium and cytochrome c induced by neocarzinostatin, neither it nor catalase interferes with the action of neocarzinostatin on DNA, whether or not drug has been activated by thiol. The pH profiles for spontaneous base release and alkali-labile base release (a measure of nucleoside 5'-aldehyde formation at a strand break) do not correspond with that for the generation of superoxide free radical from neocarzinostatin. The same holds for supercoiled DNA cutting by neocarzinostatin chromophore in the absence of a thiol, which is an acid-favored reaction. These results indicate that the generation of superoxide free radical by the drug does not correlate with DNA damage activity, whether or not thiol is present. Furthermore, the failure of hydroxyl free-radical scavengers to inhibit drug-induced single-strand breaks in supercoiled DNA in the absence of thiol also indicates that a diffusible hydroxyl free radical is most probably not involved in this reaction.     

A possible role of superoxide anion radical in the process of blastocyst implantation in Mus musculus

Superoxide anion radical and superoxide dismutase, the enzyme responsible for dismutating it, are both present in the ovary and uterus of Mus musculus during early pregnancy. The detectable, stable levels of superoxide radical and the constant high levels of superoxide dismutase in the ovary during early pregnancy suggests that these may be involved in the regulation of extended luteal steroidogenesis for the maintenance of pregnancy. An inverse correlation between the levels of superoxide anion radical and superoxide dismutase in the uterus is shown. The high levels of superoxide anion radical in the uterus on the early morning of Day 5 of pregnancy point towards a probable role for this radical in the act of implantation and in mediating the increased vascular permeability at the initiation of implantation.     

Measurement of o- and m-tyrosine as markers of oxidative damage in motor neuron disease

Abstract

Oxidative damage is thought to play an important role in many disease states. Damage caused by reactive oxygen species has been linked to degenerative conditions such as cancer, atherosclerosis, inflammatory disease, lens tissue disease, Alzheimer's disease and motor neurone disease, as well as to the aging process itself. Damage could arise through increased levels of reactive species or through alterations in levels of free radical scavenger molecules such as superoxide dismutase.     

DNA damage, repair, and antioxidant systems in brain regions: a correlative study

8-Hydroxy-2'-deoxyguanosine (oxo(8)dG) has been used as a marker of free radical damage to DNA and has been shown to accumulate during aging. Oxidative stress affects some brain regions more than others as demonstrated by regional differences in steady state oxo(8)dG levels in mouse brain. In our study, we have shown that regions such as the midbrain, caudate putamen, and hippocampus show high levels of oxo(8)dG in total DNA, although regions such as the cerebellum, cortex, and pons and medulla have lower levels. These regional differences in basal levels of DNA damage inversely correlate with the regional capacity to remove oxo(8)dG from DNA. Additionally, the activities of antioxidant enzymes (Cu/Zn superoxide dismutase, mitochondrial superoxide dismutase, and glutathione peroxidase) and the levels of the endogenous antioxidant glutathione are not predictors of the degree of free radical induced damage to DNA in different brain regions. Although each brain region has significant differences in antioxidant defenses, the capacity to excise the oxidized base from DNA seems to be the major determinant of the steady state levels of oxo(8)dG in each brain region.     

Superoxide Dismutase, Catalase, and alpha-Tocopherol Content of Stored Potato Tubers

Activated oxygen or oxygen free radical mediated damage to plants has been established or implicated in many plant stress situations. The extent of activated oxygen damage to potato (Solanum tuberosum L.) tubers during low temperature storage and long-term storage is not known. Quantitation of oxygen free radical mediated damage in plant tissues is difficult. However, it is comparatively easy to quantitate endogenous antioxidants, which detoxify potentially damaging forms of activated oxygen. Three tuber antioxidants, superoxide dismutase, catalase, and α-tocopherol were assayed from four potato cultivars stored at 3°C and 9°C for 40 weeks. Tubers stored at 3°C demonstrated increased superoxide dismutase activities (up to 72%) compared to tubers stored at 9°C. Time dependent increases in the levels of superoxide dismutase, catalase, and α-tocopherol occurred during the course of the 40 week storage. The possible relationship between these increases in antioxidants and the rate of activated oxygen production in the tubers is discussed.     

Role of cellular superoxide dismutase against reactive oxygen metabolite injury in cultured bovine aortic endothelial cells.

We examined the protective effect of cellular superoxide dismutase against extracellular hydrogen peroxide in cultured bovine aortic endothelial cells. 51Cr-labeled cells were exposed to hydrogen peroxide generated by glucose oxidase/glucose. Glucose oxidase caused a dose-dependent increase of 51Cr release. Pretreatment with diethyldithiocarbamate enhanced injury induced by glucose oxidase, corresponding with the degree of inhibition of endogenous superoxide dismutase activity. Inhibition of cellular superoxide dismutase by diethyldithiocarbamate was not associated either with alteration of other antioxidant defenses or with potentiation of nonoxidant injury. Enhanced glucose oxidase damage by diethyldithiocarbamate was prevented by chelating cellular iron. Inhibition of cellular xanthine oxidase neither prevented lysis by hydrogen peroxide nor diminished enhanced susceptibility by diethyldithiocarbamate. These results suggest that, in cultured endothelial cells: 1) cellular superoxide is involved in mediating hydrogen peroxide-induced damage; 2) superoxide, which would be generated upon exposure to excess hydrogen peroxide independently of cellular xanthine oxidase, promotes the Haber-Weiss reaction by initiating reduction of stored iron (Fe3+) to Fe2+; 3) cellular iron catalyzes the production of a more toxic species from these two oxygen metabolites; 4) cellular superoxide dismutase plays a critical role in preventing hydrogen peroxide damage by scavenging superoxide and consequently by inhibiting the generation of the toxic species.     

Role of the superoxide free radical ion in photosynthetic ascorbate oxidation and ascorbate-mediated photophosphorylation

The mechanism of ascorbate photooxidation in isolated chloroplasts has been studied. The enzyme superoxide dismutase has been used as a tool to show that ascorbate is oxidized by the superoxide free radical ion, which is formed during the autooxidation of a low-potential electron acceptor.

In the absence of an artificial, low-potential electron acceptor, addition of ascorbate stimulates photophosphorylation in isolated chloroplasts. This effect of ascorbate is abolished by superoxide dismutase, indicating that both the superoxide free radical ion and ascorbate are responsible for the stimulation of photophosphorylation. In this case, the superoxide free radical ion seems to be formed during the autooxidation of an endogenous electron acceptor.

In the presence of ferredoxin and NADP⁺, photophosphorylation in isolated chloroplasts stops as soon as the available NADP⁺ is fully reduced. If ascorbate is present in this system, however, a linear rate of photophosphorylation is maintained in spite of the fact, that NADP⁺ is fully reduced. This ascorbate-mediated photophosphorylation again is abolished by superoxide dismutase.

During the catalysis of this oxygen-dependent photophosphorylation, ascorbate consumption is not observed. These findings support the idea, that in chloroplasts ascorbate together with the superoxide free radical ion may function in providing additional ATP by an oxygen-dependent photophosphorylation.     

原核微生物铁超氧化物歧化酶的分子进化

超氧化物歧化酶（superoxide dismutase,SOD）在维持生物体内超氧阴离子自由基产生与消除的动态平衡中起着重要的作用。铁超氧化物歧化酶（ge—SOD）是原核生物和真核生物细胞器中专一的SOD酶,通过GenBank中搜集的原核生物Fe—SOD进行比对分析发现,Fe-SOD是相对保守的蛋白质,其中包含2个保守区域和1个可变区域,金属结合位点固定,Fe．SOD序列的比对可以反映物种间的进化关系,是研究原核生物分子进化的理想素材。     

Prion protein protects against DNA damage induced by paraquat in cultured cells

Exposure of cells to paraquat leads to production of superoxide anion (O2*-). This reacts with hydrogen peroxide to give the hydroxyl radical (*OH), leading to lipid peroxidation and cell death. In this study, we investigated the effects of cellular prion protein (PrPC) overexpression on paraquat-induced toxicity by using an established model system, rabbit kidney epithelial A74 cells, which express a doxycycline-inducible murine PrPC gene. PrPC overexpression was found to significantly reduce paraquat-induced cell toxicity, DNA damage, and malondialdehyde acid levels. Superoxide dismutase (total SOD and CuZn-SOD) and glutathione peroxidase activities were higher in doxycycline-stimulated cells. Our findings clearly show that PrPC overexpression plays a protective role against paraquat toxicity, probably by virtue of its superoxide dismutase-like activity.     

Free radicals in iron-containing systems

All oxidative damage in biological systems arises ultimately from molecular oxygen. Molecular oxygen can scavenge carbon-centered free radicals to form organic peroxyl radicals and hence organic hydroperoxides. Molecular oxygen can also be reduced in two one-electron steps to hydrogen peroxide in which case superoxide anion is an intermediate; or it can be reduced enzymatically so that no superoxide is released. Organic hydroperoxides or hydrogen peroxide can diffuse through membranes whereas hydroxyl radicals or superoxide anion cannot. Chain reactions, initiated by chelated iron and peroxides, can cause tremendous damage. Chain carriers are chelated ferrous ion; hydroxyl radical .OH, or alkoxyl radical .OR, and superoxide anion O2-. or organic peroxyl radical RO2.. Of these free radicals .OH and RO2. appear to be most harmful. All of the biological molecules containing iron are potential donors of iron as a chain initiator and propagator. An attacking role for superoxide dismutase is proposed in the phagocytic process in which it may serve as an intermediate enzyme between NADPH oxidase and myeloperoxidase. The sequence of reactants is O2----O2-.----H2O2----HOCl.     

Induction of superoxide dismutase, chromosomal aberrations and sister-chromatid exchanges by paraquat in Chinese hamster fibroblasts

We have recently shown that Bloom syndrome fibroblasts have elevated levels of superoxide dismutase activity compared to those of normal fibroblasts. Based on this observation we decided to test whether an increased rate of superoxide radical production could be responsible for the induction of superoxide dismutase and of chromosomal aberrations and sister-chromatid exchanges characteristic of Bloom syndrome. Utilizing the superoxide-generating herbicide paraquat in Chinese hamster fibroblasts, we assayed the cells for dismutase activity, chromosomal aberrations and sister-chromatid exchanges. All 3 parameters investigated demonstrated a dose-dependent increase with paraquat and, consequently, with the superoxide produced. Since the induction of the enzyme is mediated by its substrate, the superoxide anion radical, we concluded that the increased dismutase activity (in Bloom syndrome and paraquat-treated cells) may be a secondary manifestation of an overall imbalance in oxygen metabolism and that this elevated enzymatic activity is insufficient to detoxify the high superoxide levels, which results in elevated levels of chromosomal damage.     

Evidence of direct toxic effects of free radicals on the myocardium

The hypothesis that oxygen-derived free radicals do indeed play a role in myocardial ischemic and reperfusion injury has received a lot of support. Experimental results have shown that free radical scavengers can protect against certain aspects of myocardial ischemic injury and that on reperfusion the heart approaches a level that is more normal than those hearts not receiving additional scavenging agents. Superoxide dismutase, catalase, glutathione peroxidase, hydroxyl radical scavengers and iron chelators such as desferrioxamine have proven successful in providing an increased level of recovery. These results indicate, as would be expected, that superoxide, hydrogen peroxide and hydroxyl radicals may all, at some point, either contribute to the injury or be important in generating a subsequent radical which causes damage. In addition, solutions capable of generating free radicals have been shown to cause damage to myocardial cells and the vascular endothelium that is similar to the damage observed during myocardial ischemic and reperfusion injury. Alterations in function, structure, flow, and membrane biochemistry have been documented and compared to ischemic injury. The continued investigation of the role of free radicals in ischemic injury is warranted in the hope of further elucidating the mechanisms involved in free radical injury, the sources of their generation, and in defining a treatment that will provide significant protection against this particular aspect of ischemic damage.