Hyperthermia enhances the cytotoxic effects of reactive oxygen species to Chinese hamster cells and bovine endothelial cells in vitro.

Hyperthermia is under intensive investigation as a treatment for tumors both alone and in combination with other therapeutic agents. Hyperthermia has a profound effect on the function and structural integrity of tumor microvasculature; this has often been cited as a reason for its effectiveness in treatment of tumors. To test the role of hyperthermia in cytotoxic effects of active oxygen species, Chinese hamster, V79, and bovine endothelial cells were treated by the active oxygens, O not equal to 2 and H2O2, generated from the hypoxanthine/purine and xanthine oxidase reactions. It was found that cytotoxicity to V79 cells depends on the concentrations of purine and xanthine oxidase. A high level of cytotoxicity may be initiated in hyperthermia-treated tumors because high xanthine oxidase activity is known to be associated with tumors and endothelial cells, and degradation processes produce high concentrations of xanthine oxidase substrates in tumors. Since the cytotoxic effect can be reduced by the xanthine oxidase inhibitor, allopurinol, and the H2O2 removal enzyme, catalase, the cytotoxic effect in this experimental system is dependent on xanthine oxidase and H2O2. Adding erythrocytes at the same time as purine and xanthine oxidase could also prevent the cytotoxicity. Elevated temperatures stimulated the reaction of purine and xanthine oxidase and resulted in an increased cytotoxic effect. A similar effect is observed in growth inhibition and colony formation in endothelial cells without adding xanthine oxidase.(ABSTRACT TRUNCATED AT 250 WORDS)     

Autoinactivation of xanthine oxidase: the role of superoxide radical and hydrogen peroxide.

Xanthine oxidase suffers autoinactivation in the course of catalyzing the oxidation of acetaldehyde. When no special efforts were made to maintain a high pO2 in these reaction mixtures catalase protected the xanthine oxidase, but superoxide dismutase did not. However, when oxygen depletion was slowed or prevented by working at lower concentrations of xanthine oxidase, at lower temperatures or by vigorous agitation under an atmosphere of 100% oxygen, superoxide dismutase or catalase protected markedly when added separately and protected almost completely when added together. This result correlates with the greater production of O2-, relative to H2O2, by xanthine oxidase, at elevated pO2. Since histidine also provided some protection and the high levels of acetaldehyde used would have precluded any significant effect of OH., we conclude that singlet oxygen, or something with similar reactivity, was generated from O2- plus H2O2 and contributed significantly to the observed autoinactivation.     

Lysosomal enzyme leakage during the hypoxanthine/xanthine oxidase reaction

Impairment of lysosomal stability due to reactive oxygen species generated during the oxidation of hypoxanthine by xanthine oxidase was studied in rat liver lysosomes isolated in a discontinuous Nycodenz gradient. Production of O2.- and H2O2 during the hypoxanthine/xanthine oxidase reaction occurred for at least 5 min, while lysosomal damage, indicated by the release of N-acetyl-beta-glucosaminidase, occurred within 30 s, there being no further damage to these organelles thereafter. The extent of lysosomal enzyme release increased with increasing xanthine oxidase concentration. Superoxide dismutase and catalase did not prevent lysosomal damage during the hypoxanthine/xanthine oxidase reaction. Lysosomes reduced xanthine oxidase activity, as assessed in terms of O2 consumption, only slightly but substantially inhibited in a competitive manner the O2.- -mediated reduction of cytochrome c. This inhibition was almost completely reversed by potassium cyanide, thus pointing to the presence of a cyanide-sensitive superoxide dismutase in the lysosomal fraction. However, potassium cyanide did not affect the hypoxanthine/xanthine oxidase-mediated lysosomal damage, thus suggesting an inability of the lysosomal superoxide dismutase to protect the organelles. Negligible malondialdehyde formation was observed in the lysosomes either during the hypoxanthine/xanthine oxidase reaction or with different selective experimental approaches known to produce lipid peroxidation in other organelles such as microsomes and mitochondria.(ABSTRACT TRUNCATED AT 250 WORDS)     

The co-oxidation of ammonia to nitrite during the aerobic xanthine oxidase reaction

The xanthine oxidase reaction causes a co-oxidation of NH3 to NO2-, which was inhibitable by superoxide dismutase, catalase, hydroxyl radical scavengers, or by the chelating agents, desferrioxamine or diethylene triaminepentaacetic acid. Hydroxylamine was oxidized to NO2- much more rapidly than was NH3, and in this case superoxide dismutase or the chelating agents inhibited but catalase or the HO. scavengers did not. Hydrazine was not detectably oxidized to NO2-, and NO2- was not oxidized to NO3-, by the xanthine oxidase reaction. These results are accommodated by a reaction scheme involving (a) the metal-catalyzed production of HO. from O2- + H2O2; (b) the oxidation of H3N to H2N. by OH.; (c) the coupling of H2N. with O2- to yield peroxylamine, which hydrolyzes to hydroxylamine plus H2O2; (d) the metal-catalyzed oxidation of HO-NH2 to (Formula: see text), which couples with O2- to yield (Formula: see text), which finally dehydrates to yield NO2-.     

Characterization of free radical generation by xanthine oxidase. Evidence for hydroxyl radical generation

Xanthine oxidase has been hypothesized to be an important source of biological free radical generation. The enzyme generates the superoxide radical, .O2- and has been widely applied as a .O2- generating system; however, the enzyme may also generate other forms of reduced oxygen. We have applied electron paramagnetic resonance (EPR) spectroscopy using the spin trap 5,5'-dimethyl-1-pyrroline-N-oxide (DMPO) to characterize the different radical species generated by xanthine oxidase along with the mechanisms of their generation. Upon reaction of xanthine with xanthine oxidase equilibrated with air, both DMPO-OOH and DMPO-OH radicals are observed. In the presence of ethanol or dimethyl sulfoxide, alpha-hydroxyethyl or methyl radicals are generated, respectively, indicating that significant DMPO-OH generation occurred directly from OH rather than simply from the breakdown of DMPO-OOH. Superoxide dismutase totally scavenged the DMPO-OOH signal but not the DMPO-OH signal suggesting that .O2- was not required for .OH generation. Catalase markedly decreased the DMPO-OH signal, while superoxide dismutase + catalase totally scavenged all radical generation. Thus, xanthine oxidase generates .OH via the reduction of O2 to H2O2, which in turn is reduced to .OH. In anaerobic preparations, the enzyme reduces H2O2 to .OH as evidenced by the appearance of a pure DMPO-OH signal. The presence of the flavin in the enzyme is required for both .O2- and .OH generation confirming that the flavin is the site of O2 reduction. The ratio of .O2- and .OH generation was affected by the relative concentrations of dissolved O2 and H2O2. Thus, xanthine oxidase can generate the highly reactive .OH radical as well as the less reactive .O2- radical. The direct production of .OH by xanthine oxidase in cells and tissues containing this enzyme could explain the presence of oxidative cellular damage which is not prevented by superoxide dismutase.     

Genetic damage in CHO cells exposed to enzymically generated active oxygen species

The genetic toxicity of active oxygen species produced during the enzymic oxidation of xanthine has been investigated using Chinese hamster ovary (CHO) cells. Incubation of cells with xanthine plus xanthine oxidase resulted in extensive chromosome breakage and sister-chromatid exchange and gave a small increase in frequency of thioguanine-resistant cells (HGPRT test). Inclusion of superoxide dismutase or catalase in the xanthine/xanthine oxidase system inhibited chromosome breakage, whereas only catalase prevented SCE and mutant induction. It is concluded that hydrogen peroxide is responsible for most of the genetic effects observed in CHO cells exposed to xanthine/xanthine oxidase but that superoxide plays a key role in chromosome breakage.     

Liposome-mediated augmentation of catalase in alveolar type II cells protects against H2O2 injury

Oxidant injury to the alveolar epithelium can be mediated by exposure to oxidant gases such as O2 at high concentrations and O3, inflammatory cell-derived reactive O2 species, and the intracellular metabolism of xenobiotics such as paraquat. An in vitro model of alveolar epithelial oxidant injury was developed based on exposure of cultured rat type II pneumocytes to superoxide and hydrogen peroxide (H2O2) enzymatically generated in the culture medium. Cytotoxicity was assessed by the release of lactate dehydrogenase (LDH) into the culture medium, which was a more reliable indicator of damage than release of 51Cr by prelabeled cells. Incubation of cells for 6-8 h with xanthine plus xanthine oxidase and glucose plus glucose oxidase induced the release of greater than 50% of total intracellular LDH. Oxidant exposure also resulted in significant detachment of cells from culture dishes. Modulation of oxidant damage was accomplished using liposomes as vectors for the delivery of catalase. Treatment of cells with catalase liposomes for 2 h resulted in augmentation of cellular catalase specific activities up to 631% of controls. Catalase was partitioned into intracellular and surface-associated compartments in catalase liposome-treated cells. Partial and complete protection against oxidant injury, induced by xanthine plus xanthine oxidase and glucose plus glucose oxidase, respectively, was achieved by pretreatment of cells with catalase liposomes. LDH release during oxidant exposure was inversely related to augmentation of cellular catalase activities. Catalase liposome-treated cells also exhibited an enhanced ability to scavenge enzymatically generated H2O2 from the culture medium. These observations suggest a useful approach to modulation of alveolar injury induced by reactive O2 species.     

Allopurinol-insensitive oxygen radical formation by milk xanthine oxidase systems.

Oxygen radical generation in the xanthine- and NADH-oxygen reductase reactions by xanthine oxidase, was demonstrated using the ESR spin trap 5,5'-dimethyl-1- pyrroline-N-oxide. No xanthine-dependent oxygen radical formation was observed when allopurinol-treated xanthine oxidase was used. The significant superoxide generation in the NADH-oxygen reductase reaction by the enzyme was increased by the addition of menadione and adriamycin. The NADH-menadione and -adriamycin reductase activities of xanthine oxidase were assessed in terms of NADH oxidation. From Lineweaver-Burk plots, the Km and Vmax of xanthine oxidase were estimated to be respectively 51 microM and 5.5 s-1 for menadione and 12 microM and 0.4 s-1 for adriamycin. Allopurinol-inactivated xanthine oxidase generates superoxide and OH.radicals in the presence of NADH and menadione or adriamycin to the same extent as the native enzyme. Adriamycin radicals were observed when the reactions were carried out under an atmosphere of argon. The effects of superoxide dismutase and catalase revealed that OH.radicals were mainly generated through the direct reaction of H2O2 with semiquinoid forms of menadione and adriamycin.     

Superoxide, hydrogen peroxide, and singlet oxygen in lipid peroxidation by a xanthine oxidase system.

1. Xanthine oxidase acting aerobically upon acetaldehyde was found to cause the peroxidation of linolenate. This was demonstrated by increased absorbance at 233 nm due to diene conjugation and by the detection of a lipid peroxide spot on the thin layer chromatograms. 2. Superoxide dismutase inhibited this lipid peroxidation, as did catalase, thus indicating that both O2- and H2O2 were essential intermediates. Scavengers of singlet oxygen also inhibited the peroxidation of linolenate, whereas scavengers of hydroxyl radical did not. These effects, which were observed in the absence of iron salts, led to the proposal that O2- and H2O2 can directly give rise to a singlet oxygen, as follows: O2- + H2O2 leads to OH- + OH. + O2. 3. This proposal was further supported through the use of 2,5-dimethylfuran, as an indicating scavenger of singlet oxygen. Thus, when this compound was exposed to a known source of singlet oxygen, it gave a product which was detectable by thin layer chromatography. This product was also observed when 2,5-dimethylfuran was exposed to the xanthine oxidase system, in which case its accumulation was prevented by superoxide dismutase or by catalase, but not by scavengers of hydroxyl radical.     

Rat intestinal peroxidase: inhibition by endogenous xanthine and xanthine oxidase

The high-speed supernatant from homogenates of rat small intestine contains a heat-stable, dialyzable factor which showed a time-dependent inhibition of peroxidase activity in salt extracts of the tissue. The inhibitor was purified by chromatography on Dowex 50W-X8 and identified as xanthine. The inhibition of peroxidase by xanthine was prevented by allopurinol, an inhibitor of xanthine oxidase, and hypoxanthine was also found to be inhibitory. H2O2, produced in the reaction catalyzed by xanthine oxidase, was shown to be directly responsible for the observed inhibition. The time-dependent loss of peroxidase activity in the presence of xanthine or hypoxanthine occurred more rapidly in NH4Cl than in CaCl2 extracts of small intestine and was due to the difference in the initial concentration of H2O2 in these two extracts. The possible relationship between peroxidase and xanthine oxidase in the rat small intestine is discussed.     

Differential regulation of antioxidant enzymes in response to oxidants.

We have demonstrated the selective induction of manganese superoxide dismutase (MnSOD) or catalase mRNA after exposure of tracheobronchial epithelial cells in vitro to different oxidant stresses. Addition of H2O2 caused a dose-dependent increase in catalase mRNA in both exponentially growing and confluent cells. A 3-fold induction of catalase mRNA was seen at a nontoxic dose of 250 microM H2O2. Increase in the steady-state mRNA levels of glutathione peroxidase (GPX) and MnSOD were less striking. Expression of catalase, MnSOD, and GPX mRNA was highest in confluent cells. In contrast, constitutive expression of copper and zinc SOD (CuZnSOD) mRNA was greatest in dividing cells and was unaffected by H2O2 in both exponentially growing and confluent cells. MnSOD mRNA was selectively induced in confluent epithelial cells exposed to the reactive oxygen species-generating system, xanthine/xanthine oxidase, while steady-state levels of GPX, catalase, and CuZnSOD mRNA remained unchanged. The 3-fold induction of MnSOD mRNA was dose-dependent, reaching a peak at 0.2 unit/ml xanthine oxidase. MnSOD mRNA increases were seen as early as 2 h and reached maximal induction at 24 h. Immunoreactive MnSOD protein was produced in a corresponding dose- and time-dependent manner. Induction of MnSOD gene expression was prevented by addition of actinomycin D and cycloheximide. These data indicate that epithelial cells of the respiratory tract respond to different oxidant insults by selective induction of certain antioxidant enzymes. Hence, gene expression of antioxidant enzymes does not appear to be coordinately regulated in these cell types.     

Role of xanthine oxidase and xanthine dehydrogenase systems in thymocyte apoptosis, induced by papaverine

It has been established that papaverine as well as other xenobiotics (dexamethasone and nitrosodimethylamine) [figure: see text] provoked the thymocyte death like apoptosis. The increase of the quantity of double-strand, single-strand DNA breaks and low molecular weight fragments of DNA preceded cell death. In papaverine-induced process of thymocyte apoptosis the total activity of xanthine oxidase in thymocytes strongly elevated long before their death, the conversion of xanthine dehydrogenase (D-form) to xanthinoxidase (O-form) and accumulation of O-form in the cultural medium took place. Direct stimulating effect of papaverine on O-form of enzyme in thymocyte lysate was revealed. The used digitonin thymocytes were divided into cytoplasmic and structural component fractions. It was shown that about 80% of total xanthinoxidase activity was concentrated in cytoplasma while only 20% of its activity was found in structural components. More higher ratio of xanthinoxidase/xanthindehydrogenase (XO/XDH) was observed and papaverine-induced changes of these enzyme forms activities were expressed more brightly in the structural components, than in the thymocyte cytoplasma. During the process of developing thymocytes apoptosis caused by papaverine the reaction of lipid peroxidation was intensified. XO-hypoxanthin system displaying prooxidant influence on cells increased the cytotoxic effect of papaverine but the presence of allopurinol or catalase and superoxidedismutase decreased it. Besides, cytotoxic action on thymocytes of allopurinol itself as well as hypoxanthin itself was revealed.     

Stimulation of phospholipase A2 by xanthine oxidase in the rat corpus luteum.

The ability of the superoxide radical (SOR) generated by xanthine oxidase to activate phospholipase A2 (PLA2) was examined in microsomes prepared from luteinized rat ovaries. Treatment of microsomes with xanthine oxidase resulted in a rapid burst in SOR formation followed by an increase in PLA2 activity. Stimulation of PLA2 activity was dose related and similar in microsomes prepared from control or prostaglandin F2 alpha (PGF2 alpha)-treated rats. Activation was inhibited by the antioxidants, vitamin E and nordihydroguaiaretic acid, and by superoxide dismutase and catalase, which metabolize SOR and H2O2 to remove reactive oxygen species from the cell. The stimulation of PLA2 activity by xanthine oxidase was dependent upon the addition of calcium ions, and it was highest in samples in which cytosol was added to membranes. These results indicate that the SOR and/or H2O2 may mediate PLA2 activation, which may be involved in the luteolytic process.     

Comparison of the effects of superoxide dismutase and cytochrome c on luminol chemiluminescence produced by xanthine oxidase-catalyzed reactions

Superoxide dismutase (superoxide: superoxide oxidoreductase, EC 1.15.1.1) (SOD) and ferricytochrome c are used to check the effects on luminol chemiluminescence induced by a xanthine or hypoxanthine/xanthine oxidase/oxygen system. Luminol chemiluminescence has been attributed to superoxide anion radical (O2.-) in this system. From kinetic studies on the light intensity vs. time curves it is demonstrated that addition of SOD into the system does not affect the mechanism of O2.- generation, whilst ferricytochrome c dramatically alters the time-course of the reaction. This is interpreted as the effect of cytochrome c redox cycling by reaction with H2O2, modifying oxy-radical generation in the reaction medium. Also, an alternative mechanism for luminol chemiexcitation is proposed under certain experimental conditions.     

The contribution of vascular endothelial xanthine dehydrogenase/oxidase to oxygen-mediated cell injury.

The conversion of xanthine dehydrogenase (XDH) to xanthine oxidase (XO) and the reaction of XO-derived partially reduced oxygen species (PROS) have been suggested to be important in diverse mechanisms of tissue pathophysiology, including oxygen toxicity. Bovine aortic endothelial cells expressed variable amounts of XDH and XO activity in culture. Xanthine dehydrogenase plus xanthine oxidase specific activity increased in dividing cells, peaked after achieving confluency, and decreased in postconfluent cells. Exposure of BAEC to hyperoxia (95% O2; 5% CO2) for 0-48 h caused no change in cell protein or DNA when compared to normoxic controls. Cell XDH+XO activity decreased 98% after 48 h of 95% O2 exposure and decreased 68% after 48 h normoxia. During hyperoxia, the percentage of cell XDH+XO in the XO form increased to 100%, but was unchanged in air controls. Cell catalase activity was unaffected by hyperoxia and lactate dehydrogenase activity was minimally elevated. Hyperoxia resulted in enhanced cell detachment from monolayers, which increased 112% compared to controls. Release of DNA and preincorporated [8-14C]adenine was also used to assess hyperoxic cell injury and did not significantly change in exposed cells. Pretreatment of cells with allopurinol for 1 h inhibited XDH+XO activity 100%, which could be reversed after oxidation of cell lysates with potassium ferricyanide (K3Fe(CN)6). After 48 h of culture in air with allopurinol, cell XDH+XO activity was enhanced when assayed after reversal of inhibition with K3Fe(CN)6, and cell detachment was decreased. In contrast, allopurinol treatment of cells 1 h prior to and during 48 h of hyperoxic exposure did not reduce cell damage. After K3Fe(CN)6 oxidation, XDH+XO activity was undetectable in hyperoxic cell lysates. Thus, XO-derived PROS did not contribute to cell injury or inactivation of XDH+XO during hyperoxia. It is concluded that endogenous cell XO was not a significant source of reactive oxygen species during hyperoxia and contributes only minimally to net cell production of O2- and H2O2 during normoxia.     

Hydroxyl radical is not a product of the reaction of xanthine oxidase and xanthine. The confounding problem of adventitious iron bound to xanthine oxidase

The reaction of xanthine and xanthine oxidase generates superoxide and hydrogen peroxide. In contrast to earlier works, recent spin trapping data (Kuppusamy, P., and Zweier, J.L. (1989) J. Biol. Chem. 264, 9880-9884) suggested that hydroxyl radical may also be a product of this reaction. Determining if hydroxyl radical results directly from the xanthine/xanthine oxidase reaction is important for 1) interpreting experimental data in which this reaction is used as a model of oxidant stress, and 2) understanding the pathogenesis of ischemia/reperfusion injury. Consequently, we evaluated the conditions required for hydroxyl radical generation during the oxidation of xanthine by xanthine oxidase. Following the addition of some, but not all, commercial preparations of xanthine oxidase to a mixture of xanthine, deferoxamine, and either 5,5-dimethyl-1-pyrroline-N-oxide or a combination of alpha-phenyl-N-tert-butyl-nitrone and dimethyl sulfoxide, hydroxyl radical-derived spin adducts were detected. With other preparations, no evidence of hydroxyl radical formation was noted. Xanthine oxidase preparations that generated hydroxyl radical had greater iron associated with them, suggesting that adventitious iron was a possible contributing factor. Consistent with this hypothesis, addition of H2O2, in the absence of xanthine, to "high iron" xanthine oxidase preparations generated hydroxyl radical. Substitution of a different iron chelator, diethylenetriaminepentaacetic acid for deferoxamine, or preincubation of high iron xanthine oxidase preparations with chelating resin, or overnight dialysis of the enzyme against deferoxamine decreased or eliminated hydroxyl radical generation without altering the rate of superoxide production. Therefore, hydroxyl radical does not appear to be a product of the oxidation of xanthine by xanthine oxidase. However, commercial xanthine oxidase preparations may contain adventitious iron bound to the enzyme, which can catalyze hydroxyl radical formation from hydrogen peroxide.     

Role of superoxide radicals in cytotoxic effects of Fe-NTA on cultured normal liver epithelial cells

We studied the cytotoxic effects of ferric nitrilotriacetate (Fe-NTA) on normal rat liver epithelial cells (RL34) cultured in medium containing 10% fetal calf serum. Marked cytolysis was present in cells exposed to greater than or equal to 25 micrograms/ml iron of Fe-NTA, but not all the cells exposed to 50 micrograms/ml iron were lethally injured. The remaining cells showed anomalous growth, namely cell pile-up and aggregation. Superoxide dismutase inhibited this iron-induced cytotoxicity, whereas catalase, mannitol, dimethyl sulfoxide, and 1,4-diazabicyclo-[2.2.2.] octane did not. RL34 cells exposed to Fe-NTA actually produced a large amount of superoxide radicals (O2-.), whereas unexposed control cells produced none. Allopurinol inhibited O2-. production and prevented cell injury by Fe-NTA. These results show that the injury to cells produced by Fe-NTA depends on the generation of O2-., the source of which may be xanthine oxidase.     

Lysosomal enzyme leakage during the hypoxanthine/xanthine oxidase reaction

Impairment of lysosomal stability due to reactive oxygen species generated during the oxidation of hypoxanthine by xanthine oxidase was studied in rat liver lysosomes isolated in a discontinuous Nycodenz gradient. Production of O ₂ ^⋅ and H₂O₂ during the hypoxanthine/xanthine oxidase reaction occurred for at least 5 min, while lysosomal damage, indicated by the release of N-acetyl-β-glucosaminidase, occurred within 30 s, there being no further damage to these organelles thereafter. The extent of lysosomal enzyme release increased with increasing xanthine oxidase concentration. Superoxide dismutase and catalase did not prevent lysosomal damage during the hypoxanthine/xanthine oxidase reaction. Lysosomes reduced xanthine oxidase activity, as assessed in terms of O₂ consumption, only slightly but substantially inhibited in a competitive manner the O ₂ ^⋅ -mediated reduction of cytochrome c. This inhibition was almost completely reversed by potassium cyanide, thus pointing to the presence of a cyanide-sensitive Superoxide dismutase in the lysosomal fraction. However, potassium cyanide did not affect the hypoxanthine/xanthine oxidase-mediated lysosomal damage, thus suggesting an inability of the lysosomal superoxide dismutase to protect the organelles. Negligible malondialdehyde formation was observed in the lysosomes either during the hypoxanthine/xanthine oxidase reaction or with different selective experimental approaches known to produce lipid peroxidation in other organelles such as microsomes and mitochondria. These results are interpreted in terms of a possible lysosomal membrane permeability to O ₂ ^⋅ causing organelle impairment by a process that, though leading to enzyme-marker leakage, does not involve lipid peroxidation.     

Human umbilical vein endothelial cells submitted to hypoxia-reoxygenation in vitro: implication of free radicals, xanthine oxidase, and energy deficiency.

Ischemia-reperfusion is observed in various diseases such as myocardium infarct. Different theories have been proposed to explain the reperfusion injury, among them that the free radical generation plays a crucial role. To study the mechanisms of the reperfusion injury, a hypoxia (H)-reoxygenation (R) model upon human umbilical vein endothelial cells in culture was developed in order to mimic the in vivo situation. Different parameters were quantified and compared under H or H/R, and we found that oxygen readmission led to damage amplification after a short hypoxia period. To estimate the importance of various causes of toxicity, the effects of various protective molecules were compared. Different antioxidant molecules, iron-chelating agent, xanthine oxidase inhibitors, and energy-supplying molecules were very efficient protectors. Synergy could also be observed between the antioxidants and the energy-supplying molecules or the xanthine oxidase inhibitors. The toxic effect of O2.(-) could be lowered by the presence of SOD or glutathione peroxidase in the culture medium, whereas glutathione peroxidase was the most efficient enzyme when injected into the cells. The production of O2.(-) and of H2O2 by endothelial cells was directly estimated to be, respectively, of 0.17 and 0.035 mumol/min/mg prot during the R period. O2.(-) production was completely inhibited when allopurinol was added during H and R. In addition, a xanthine oxidase activity of 21.5 10(-6) U/mg prot could be observed by a direct assay in cells after H but not in control cells, thus confirming the previous conclusions of xanthine oxidase as a potent source of free radicals in these conditions. Thanks to the use of cultured human endothelial cells, a clear picture was obtained of the overall process leading to cell degenerescence during the reoxygenation process. We particularly could stress the importance of the low energetic state of these cells, which is a critical factor acting synergistically with the oxidant molecules to injure the cells. These results also open new possibilities for the development of new therapeutics for ischemia.     

Antioxidation activity of tetrahydrobiopterin in pheochromocytoma PC 12 cells

Rat pheochromocytoma PC 12 cells are susceptible to the oxidative toxicity caused by H2O2, nitrofurantoin, dopamine, and xanthine/xanthine oxidase reaction. The cytotoxicities of these agents are greatly reduced by the simultaneous presence of 0.1 mM tetrahydrobiopterin (BH4), 3 units/ml horseradish peroxidase, 0.2 mM NADH, and 0.1 units/ml sheep liver dihydropteridine reductase (DHPR). Individually, BH4, NADH and DHPR have no protection against H2O2 toxicity in PC 12 cells. Peroxidase alone offers 58% of protection if cells are incubated in the medium but only 3% in Dulbecco's phosphate buffered saline. The efficiency of the BH4-mediated antioxidation system in PC 12 cells is equal to or better than ascorbic acid and catalase, depending on the source of the reactive O2 species (ROS). The reactions responsible for the BH4-antioxidation system may consist of the non-enzymatic and the peroxidase-catalyzed reduction of H2O2 to H2O by BH4 and the regeneration of BH4 by DHPR using NADH as the cofactor. The components of this defence mechanism against ROS are all normal cellular constituents and are ubiquitous in nature. This DHPR-catalyzed redox cycling of BH4 may constitute an as yet little-known antioxidation system in mammalian cells.