Endocytosis-independent uptake of liposome-encapsulated superoxide dismutase prevents the killing of cultured hepatocytes by tert-butyl hydroperoxide

Liposome-encapsulated (LSOD) or free (FSOD), human recombinant Cu-Zn superoxide dismutase prevented the killing of cultured rat hepatocytes by tert-butyl hydroperoxide (TBHP). A dose of 32 U/ml of LSOD reduced the cell killing by 50%. By contrast, it required 288 U/ml of FSOD to similarly reduce the toxicity of TBHP by 50%. Both LSOD and FSOD increased the cell-associated superoxide dismutase activity of the cultured hepatocytes. Whereas 64 U/ml of LSOD increased cell-associated superoxide dismutase activity fourfold, it required 500 U/ml of FSOD to achieve a similar increase. Furthermore, methylamine, benzyl alcohol, cytochalasin B, oligomycin, and monensin, all inhibitors of endocytosis, prevented the increase in cell-associated superoxide dismutase produced by 500 U/ml of FSOD. These same inhibitors had no effect on the increase in cell-associated superoxide dismutase activity produced by a much lower concentration of LSOD. Thus, liposome-encapsulated superoxide dismutase prevented the cell killing by TBHP more efficiently than free superoxide dismutase because it more efficiently entered the hepatocytes by a mechanism that was independent of the endocytosis responsible for the uptake of FSOD. These data further define the conditions of the toxicity of TBHP. The target hepatocyte must contribute superoxide anions, in addition to the previously shown ferric iron. It is hypothesized that superoxide anions reduce ferric to ferrous iron; the latter then reacts with the hydroperoxide to form tert-butyl alkoxyl radicals. Such radicals are potent oxidizing agents that can initiate the peroxidation of cellular lipids previously shown to lethally injure the hepatocytes.     

Superoxide dismutase and catalase protect cultured hepatocytes from the cytotoxicity of acetaminophen

Superoxide dismutase, catalase and mannitol prevent the killing of cultured hepatocytes by acetaminophen in the presence of an inhibitor of glutathione reductase, BCNU. Under these conditions, the cytotoxicity of acetaminophen depends upon its metabolism, since beta-naphthoflavone, an inhibitor of mixed function oxidation, prevents the cell killing. In hepatocytes made resistant to acetaminophen by pretreatment with the ferric iron chelator, deferoxamine, addition of ferric or ferrous iron restores the sensitivity to acetaminophen. In such a situation, both superoxide dismutase and catalase prevent the killing by acetaminophen in the presence of ferric iron. By contrast, catalase, but not superoxide dismutase, prevents the cell killing dependent upon addition of ferrous iron. These results document the participation of both superoxide anion and hydrogen peroxide in the killing of cultured hepatocytes by acetaminophen and suggest that hydroxyl radicals generated by an iron catalyzed Haber-Weiss reaction mediate the cell injury.     

Modulation of catalase peroxidatic and catalatic activity by nitric oxide

Previously, we found that catalase enhanced the protection afforded by superoxide dismutase to Escherichia coli against the simultaneous generation of superoxide and nitric oxide (Brunelli et al., Arch. Biochem. Biophys. 316:327-334, 1995). Hydrogen peroxide itself was not toxic in this system in the presence or absence of superoxide dismutase. We therefore investigated whether catalase might consume nitric oxide in addition to hydrogen peroxide. Catalase rapidly formed a reversible complex stoichiometrically with nitric oxide with the Soret band shifting from 406 to 426 nm and two new peaks appeared at 540 and at 575 nm, consistent with the formation of a ferrous-nitrosyl complex. Catalase consumed more nitric oxide upon the addition of hydrogen peroxide. Conversely, micromolar concentrations of nitric oxide slowed the catalase-mediated decomposition of hydrogen peroxide. Catalase pretreated with nitric oxide and hydrogen peroxide regained full activity after dialysis. Our results suggest that catalase can slowly consume nitric oxide while nitric oxide modestly inhibits catalase-dependent scavenging of hydrogen peroxide. The protective effects of catalase in combination with superoxide dismutase may result from two actions; reducing peroxynitrite formation by scavenging nitric oxide and by scavenging hydrogen peroxide before it reacts with superoxide dismutase to form additional superoxide.     

Hydrogen peroxide damages the zinc-binding site of zinc-deficient Cu,Zn superoxide dismutase

Mutations in Cu,Zn superoxide dismutase (Cu,Zn SOD) account for approximately 20% of cases of familial amyotrophic lateral sclerosis (ALS), a late-onset neurodegenerative disease affecting motor neurons. These mutations decrease protein stability and lower zinc affinity. Zinc-deficient SOD (Cu,E SOD) has altered redox activities and is toxic to motor neurons in vitro. Using bovine SOD, we studied the effects of hydrogen peroxide (H(2)O(2)) on Cu,E SOD and Cu,Zn SOD. Hydrogen peroxide treatment of Cu,E SOD inactivated zinc binding activity six times faster than superoxide dismutase activity, whereas inactivation of dismutase activity occurred at the same rate for both Cu,Zn SOD and Cu,E SOD. Zinc binding by Cu,E SOD was also damaged by simultaneous generation of superoxide and hydrogen peroxide by xanthine oxidase plus xanthine. Although urate, xanthine, and ascorbate can protect superoxide dismutase activity of Cu,Zn SOD from inactivation, they were not effective at protecting Cu,E SOD. Hydrogen peroxide induced subtle changes in the tertiary structure but not the secondary structure of Cu,E SOD as detected by near and far UV circular dichroism. Our results suggest that low levels of hydrogen peroxide could potentially enhance the toxicity of zinc deficient SOD to motor neurons in ALS by rendering zinc loss from SOD irreversible.     

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.     

Effect of cytochalasin B on the oxidative metabolism of human peripheral blood granulocytes.

Pretreatment of human granulocytes with cytochalasin B before addition of opsonized zymosan particles resulted in strong inhibition of the oxygen consumption, the hydrogen peroxide production, and the hexose monophosphate shunt activity as compared to normal phagocytosing cells. In contrast, however, no effect of cytochalasin B was found on the generation of superoxide anions. These seemingly controversial results can be explained by the action of cytochalasin B on the cell membrane.     

Lysosomal origin of the ferric iron required for cell killing by hydrogen peroxide

The lysosomotropic amines methylamine (40 mM) and chloroquine (125 mM) prevented the killing of cultured hepatocytes by hydrogen peroxide generated in the medium by glucose oxidase. Maximum protection required several hours preincubation with either amine. Sensitivity of the hepatocytes to H2O2 was restored either by the addition of ferrous or ferric iron to the culture medium, or by incubating the cells for 4 hours in the absence of either amine prior to treatment with H2O2. Neither methylamine nor chloroquine had any effect on the cell killing by t-butyl hydroperoxide, a hepatotoxin that does not require iron. The protective effect of the lysosomotropic amines was distinguished from that of the ferric iron chelator deferoxamine in two ways: 1) deferoxamine protected hepatocytes from H2O2 toxicity but did not require a pretreatment period; and 2) in contrast to methylamine or chloroquine, deferoxamine had no effect on lysosomal pH as assessed by the fluorescent probe acridine orange. The data suggest that a lysosomal pool is the source of the ferric iron necessary for the killing of hepatocytes by H2O2.     

Cellularly Generated Active Oxygen Species and Hela Cell Proliferation

In HeLa cells evidence is provided that active oxygen species such as hydrogen peroxide and superoxide at low levels are important growth regulatory signals. They may constitute a novel regulatory redox system of control superimposed upon the established cell growth signal transduction pathways. Whilst for example hydrogen peroxide can be added exogenously to elicit growth responses in these cells, it is clear that cellularly generated superoxide and hydrogen peroxide are important. Experiments with superoxide dismutase, superoxide dismutase mimics and inhibitors of both superoxide dismutase and xanthine oxidase suggest that superoxide generated intracellularly and superoxide released extracellularly are both relevant to growth control in HeLa cells.     

Cellularly Generated Active Oxygen Species and Hela Cell Proliferation

In HeLa cells evidence is provided that active oxygen species such as hydrogen peroxide and superoxide at low levels are important growth regulatory signals. They may constitute a novel regulatory redox system of control superimposed upon the established cell growth signal transduction pathways. Whilst for example hydrogen peroxide can be added exogenously to elicit growth responses in these cells, it is clear that cellularly generated superoxide and hydrogen peroxide are important. Experiments with superoxide dismutase, superoxide dismutase mimics and inhibitors of both superoxide dismutase and xanthine oxidase suggest that superoxide generated intracellularly and superoxide released extracellularly are both relevant to growth control in HeLa cells.     

Superoxide-dependent redox cycling of citrate-Fe3+: evidence for a superoxide dismutaselike activity

Citrate-Fe3+, reportedly a physiological chelate, exhibits superoxide dismutaselike activity, as evidenced by the inhibition of xanthine oxidase-dependent cytochrome c reduction; the dismutation of xanthine oxidase-generated superoxide to hydrogen peroxide and oxygen, and the enhanced disproportionation of potassium superoxide. The catalytic activity of citrate-Fe3+ corresponds, on a molar basis, to 0.03% of that of copper- and zinc-containing superoxide dismutase. Although weak, this activity enables citrate-Fe3+ to inhibit superoxide and ADP-Fe3+ -dependent peroxidation of extracted microsomal lipids. Also, the dismutase activity of citrate-Fe3+ interferes with its ability to promote lipid peroxidation. It is proposed that chelation of Fe3+ by citrate may represent a protective mechanism against the deleterious consequences of superoxide generation.     

Response of Plant-Colonizing Pseudomonads to Hydrogen Peroxide

Colonization of plant root surfaces by Pseudomonas putida may require mechanisms that protect this bacterium against superoxide anion and hydrogen peroxide produced by the root. Catalase and superoxide dismutase may be important in this bacterial defense system. Stationary-phase cells of P. putida were not killed by hydrogen peroxide (H₂O₂) at concentrations up to 10 mM, and extracts from these cells possessed three isozymic bands (A, B, and C) of catalase activity in native polyacrylamide gel electrophoresis. Logarithmic-phase cells exposed directly to hydrogen peroxide concentrations above 1 mM were killed. Extracts of logarithmic-phase cells displayed only band A catalase activity. Protection against 5 mM H₂O₂ was apparent after previous exposure of the logarithmic-phase cells to nonlethal concentrations (30 to 300 μM) of H₂O₂. Extracts of these protected cells possessed enhanced catalase activity of band A and small amounts of bands B and C. A single form of superoxide dismutase and isoforms of catalase were apparent in extracts from a foliar intercellular pathogen, Pseudomonas syringae pv. phaseolicola. The mobilities of these P. syringae enzymes were distinct from those of enzymes in P. putida extracts.     

Leukocyte-mediated inactivation of alpha 1-proteinase inhibitor is inhibited by amino analogues of alpha-tocopherol.

Human leukocytes stimulated by opsonized zymosan increase their NADPH oxidase-catalysed reduction of molecular oxygen. This leads to enhanced formation of superoxyl radicals and subsequently hydrogen peroxide. The leukocyte enzyme myeloperoxidase generates the strong microbicidal oxidant hypochlorite from hydrogen peroxide and chloride anions. Hypochlorite inactivates serum alpha 1-proteinase inhibitor, a protein which protects host tissue from digestion by proteinases, that are also secreted by stimulated leukocytes. Micromolar concentrations of a water-soluble, quaternary ammonium analogue of alpha-tocopherol (vitamin E) (3,4-dihydro-6-hydroxy-N,N,N-2,5,7,8-heptamethyl-2H-1-benzopyran-2 -ethanaminium 4-methylbenzenesulfonate) and its tertiary amine derivative (3,4-dihydro-2- (2-dimethylaminoethyl)-2,5,7,8-tetramethyl-2H-1-benzopyran-6-ol hydrochloride) were able to protect alpha 1-proteinase inhibitor from inactivation by stimulated human leukocytes. The mechanism of action of the quaternary ammonium analogue was further investigated. Selective inhibition of hydrogen peroxide formation is assumed to be the reason for its protective effect. This compound rapidly reacts with superoxyl radicals, but not with hydrogen peroxide, and is only a weak hypochlorite scavenger. It neither impedes exocytosis of elastase, nor effectively inhibits NADPH oxidase or myeloperoxidase. In contrast, superoxide dismutase, which enhances hydrogen peroxide formation, cannot protect alpha 1-proteinase inhibitor from inactivation.     

Effect of iron on expression of superoxide dismutase by Aeromonas salmonicida and associated resistance to superoxide anion

Abstract Superoxide dismutase activity was detected in Aeromonas salmonicida under iron-replete and iron-limited culture conditions. Under iron-replete conditions an iron superoxide dismutase, molecular mass 50,400 Da, was identified based on inhibition by hydrogen peroxide but not by millimolar concentrations of cyanide. When the available iron in the culture medium was limited by addition of the non-assimilable iron chelator 2,2-dipyridyl, a manganese superoxide dismutase, molecular mass 45,600 Da, was identified, which was resistant to inhibition by either hydrogen peroxide or cyanide. The change in enzyme production would appear to be iron dependent, as addition of FeCl₃ in excess to iron-limited broths resulted in only the iron superoxide dismutase being synthesised. Examination of the location of the superoxide dismutase enzymes revealed that the manganese superoxide dismutase expressed under iron limitation is located in the periplasm, while the iron superoxide dismutase has a cytoplasmic location. The periplasmic manganese superoxide dismutase was able to protect A. salmonicida against extracellular riboflavin-generated superoxide, with A. salmonicida grown under iron-limited conditions exhibiting a 32-fold increase in minimum bactericidal concentration of riboflavin compared to cells cultured under iron-replete conditions. Furthermore, in a time-course study of bactericidal activity of exogenously generated superoxide against A. salmonicida , bacteria grown under iron-replete conditions and expressing cytoplasmic iron superoxide dismutase were rapidly killed, whilst those grown under iron limitation expressing periplasmic manganese superoxide dismutase survived for the duration of the experiment.     

The regulation and role of the periplasmic copper, zinc superoxide dismutase of Escherichia coli

The discovery of superoxide dismutase (CuZnSOD) within the periplasms of several Gram-negative pathogens suggested that this enzyme evolved to protect cells from exogenous sources of superoxide, such as the oxidative burst of phagocytes. However, its presence in some non-pathogenic bacteria implies that there may be a role for this SOD during normal growth conditions. We found that sodC, the gene that encodes the periplasmic SOD of Escherichia coli, is repressed anaerobically by Fnr and is among the many antioxidant genes that are induced in stationary phase by RpoS. Surprisingly, the entry of wild-type E. coli into stationary phase is accompanied by a several-hour-long period of acute sensitivity to hydrogen peroxide. Induction of the RpoS regulon helps to diminish that sensitivity. While mutants of E. coli and Salmonella typhimurium that lacked CuZnSOD were not detectably sensitive to exogenous superoxide, both were killed more rapidly than their parent strains by exogenous hydrogen peroxide in early stationary phase. This sensitivity required prior growth in air. Evidently, periplasmic superoxide is generated during stationary phase by endogenous metabolism and, if it is not scavenged by CuZnSOD, it causes an unknown lesion that augments or accelerates the damage done by peroxide. The molecular details await elucidation.     

Response of hydroperoxidase and superoxide dismutase deficient mutants of Escherichia coli K-12 to oxidative stress

In Escherichia coli, the coordinate action of two antioxidant enzymes, superoxide dismutase and hydroperoxidase (catalase), protect the cell from the deleterious effects of oxyradicals generated during normal aerobic respiration. To evaluate the relative importance of these two classes of enzymes, strains of E. coli deficient in superoxide dismutase and (or) hydroperoxidase were constructed by generalized transduction and their physiological responses to oxygen and oxidant stress examined. Superoxide dismutase was found to be more important than hydroperoxidase in preventing oxygen-dependent growth inhibition and mutagenesis, and in reducing sensitivity to redox-active compounds known to generate the superoxide anion. However, both types of enzymes were required for an effective defense against chemical oxidants that generate superoxide radicals and hydrogen peroxide.     

Topology of superoxide production from different sites in the mitochondrial electron transport chain

We measured production of reactive oxygen species by intact mitochondria from rat skeletal muscle, heart, and liver under various experimental conditions. By using different substrates and inhibitors, we determined the sites of production (which complexes in the electron transport chain produced superoxide). By measuring hydrogen peroxide production in the absence and presence of exogenous superoxide dismutase, we established the topology of superoxide production (on which side of the mitochondrial inner membrane superoxide was produced). Mitochondria did not release measurable amounts of superoxide or hydrogen peroxide when respiring on complex I or complex II substrates. Mitochondria from skeletal muscle or heart generated significant amounts of superoxide from complex I when respiring on palmitoyl carnitine. They produced superoxide at considerable rates in the presence of various inhibitors of the electron transport chain. Complex I (and perhaps the fatty acid oxidation electron transfer flavoprotein and its oxidoreductase) released superoxide on the matrix side of the inner membrane, whereas center o of complex III released superoxide on the cytoplasmic side. These results do not support the idea that mitochondria produce considerable amounts of reactive oxygen species under physiological conditions. Our upper estimate of the proportion of electron flow giving rise to hydrogen peroxide with palmitoyl carnitine as substrate (0.15%) is more than an order of magnitude lower than commonly cited values. We observed no difference in the rate of hydrogen peroxide production between rat and pigeon heart mitochondria respiring on complex I substrates. However, when complex I was fully reduced using rotenone, rat mitochondria released significantly more hydrogen peroxide than pigeon mitochondria. This difference was solely due to an elevated concentration of complex I in rat compared with pigeon heart mitochondria.     

Ferric iron and superoxide ions are required for the killing of cultured hepatocytes by hydrogen peroxide. Evidence for the participation of hydroxyl radicals formed by an iron-catalyzed Haber-Weiss reaction

Cultured hepatocytes pretreated with the ferric iron chelator deferoxamine were resistant to the toxicity of H2O2 generated by either glucose oxidase or by the metabolism of menadione (2-methyl-1,4-naphthoquinone). Ferric, ferrous, or cupric ions restored the sensitivity of the cells to H2O2. Deferoxamine added to hepatocytes previously treated with this chelator prevented the restoration of cell killing by only ferric iron. The free radical scavengers mannitol, thiourea, benzoate, and 4-methylmercapto-2-oxobutyrate protected either native cells exposed to H2O2 or pretreated hepatocytes exposed to H2O2 and given ferric or ferrous iron. Superoxide dismutase prevented the killing of native hepatocytes by either glucose oxidase or menadione. With deferoxamine-pretreated hepatocytes, superoxide dismutase prevented the cell killing dependent upon the addition of ferric but not ferrous iron. Catalase prevented the killing by menadione of deferoxamine-pretreated hepatocytes given either ferric or ferrous iron. Deferoxamine pretreatment did not prevent the toxicity of t-butyl hydroperoxide but did, however, prevent that of cumene hydroperoxide. It is concluded that both ferric iron and superoxide ions are required for the killing of cultured hepatocytes by H2O2. The toxicity of H2O2 is also dependent upon its reaction with ferrous iron to form hydroxyl radicals by the Fenton reaction. The ferrous iron needed for this reaction is formed by the reduction of cellular ferric iron by superoxide ions. Such a sequence corresponds to the so-called iron-catalyzed Haber-Weiss reaction, and the present report documents its participation in the killing of intact hepatocytes by H2O2. Cumene hydroperoxide but not t-butyl hydroperoxide closely models the toxicity of hydrogen peroxide.     

Pseudo-inhibitors of neutrophil superoxide production: evidence that soybean-derived polypeptides are superoxide dismutases

We have previously reported the purification of polypeptides from soybean which are potent inhibitors of superoxide production by human neutrophils. We now report that neither oxygen uptake nor hydrogen peroxide production by stimulated neutrophils is affected by these inhibitors. Furthermore, the E-1 and E-3 polypeptides inhibit ferricytochrome c reduction by a xanthine oxidase superoxide generation system. The inhibitory activity of E-3 in the model system is blocked by 1 mM KCN while E-1 is only slightly cyanide sensitive. Atomic absorption analysis of E-1 and E-3 polypeptides reveal copper in the latter and manganese in the former. Thus, E-3 is a copper-containing superoxide dismutase while E-1 appears to be a manganese-containing superoxide dismutase.     

New insights into the protective effect of manganese against oxidative stress

Manganese has emerged as an important trace element in bacterial physiology. The correlation between manganese accumulation and resistance to oxidative stress has led to the suggestion that, in addition to a role as a prosthetic group in superoxide dismutase, manganese could exert its antioxidant effect via non-enzymatic redox reactions. The article by Anjem et al. in the current issue of Molecular Microbiology investigates the role of manganese ions in the defence against hydrogen peroxide in Escherichia coli . The results indicate that the redox activity of manganese is not linked to its protective effect. Instead, it is suggested that manganese replaces ferrous iron in enzymes that contain divalent cations at their active site. This enables the cell to avoid oxidative stress associated with iron release in the presence of hydrogen peroxide.