Effect of 3,4-dihydroxyphenylalanine on Cu(2+)-induced inactivation of HDL-associated paraoxonasel and oxidation of HDL; inactivation of paraoxonasel activity independent of HDL lipid oxidation

Paraoxonase1 (PON1), one of HDL-asssociated antioxidant proteins, is known to be sensitive to oxidative stress. Here, the effect of endogenous reducing compounds on Cu²⁺-mediated inactivation of PON1 was examined. Cu²⁺-mediated inactivation of PON1 was enhanced remarkably by catecholamines, but not by uric acid or homocysteine. Furthermore, catecholamines such as 3,4-dihydroxyphenylalanine (DOPA), dopamine or norepinephrine were more effective than caffeic acid or pyrocatechol in promoting Cu²⁺-mediated inactivation of PON1, suggesting the importance of dihydroxybenzene group as well as amino group. DOPA at relatively low concentrations showed a concentration-dependent inactivation of PON1 in a concert with Cu²⁺, but not Fe²⁺. The DOPA/Cu²⁺-induced inactivation of PON1 was prevented by catalase, but not hydroxyl radical scavengers, consistent with Cu²⁺-catalyzed oxidation. A similar result was also observed when HDL-associated PON1 (HDL-PON1) was exposed to DOPA/Cu²⁺. Separately, it was found that DOPA at low concentrations (1-6 μM) acted as a pro-oxidant by enhancing Cu²⁺-induced oxidation of HDL, while it exhibited an antioxidant action at ≥10 μM. In addition, Cu²⁺-oxidized HDL lost the antioxidant action against LDL oxidation. Meanwhile, the role of DOPA/Cu²⁺-oxidized HDL differed according to DOPA concentration; HDL oxidized with Cu²⁺ in the presence of DOPA (60 or 120 μM) maintained antioxidant activity of native HDL, in contrast to an adverse effect of DOPA at 3 or 6 μM. These data indicate that DOPA at micromolar level may act as a pro-oxidant in Cu²⁺-induced inactivation of PON1 as well as oxidation of HDL. Also, it is proposed that the oxidative inactivation of HDL-PON1 is independent of HDL oxidation.     

DNA Single Strand Breakage by H2O2 and Ferric or Cupric Ions: Its Modulation by Histidine

The role of histidine on DNA breakage induced by hydrogen peroxide (H₂O₂) and ferric ions or by H₂O₂ and cupric ions was studied on purified DNA. L-histidine slightly reduced DNA breakage by H₂O₂ and Fe³⁺ but greatly inhibited DNA breakage by H₂O₂ and Cu²⁺. However, only when histidine was present, the addition of EDTA to H₂O₂ and Fe³⁺ exhibited a bimodal dose response curve depending on the chelator metal ratio. The enhancing effect of histidine on the rate of DNA degradation by H₂O₂ was maximal at a chelator metal ratio between 0.2 and 0.5, and was specific for iron. When D-histidine replaced L-histidine, the same pattern of EDTA dose response curve was observed. Superoxide dismutase greatly inhibited the rate of DNA degradation induced by H₂O₂, Fe³⁺, EDTA and L-histidine involving the superoxide radical.

These studies suggest that the enhancing effect of histidine on the rate of DNA degradation by H₂O₂ and Fe³⁺ is mediated by an oxidant which could be a ferrous-dioxygen-ferric chelate complex or a chelate-ferryl ion.     

Non-oxygen-forming pathways of hydrogen peroxide degradation by bovine liver catalase at low hydrogen peroxide fluxes

Heme catalases are considered to degrade two molecules of H₂O₂ to two molecules of H₂O and one molecule of O₂ employing the catalatic cycle. We here studied the catalytic behaviour of bovine liver catalase at low fluxes of H₂O₂ (relative to catalase concentration), adjusted by H₂O₂-generating systems. At a ratio of a H₂O₂ flux (given in μM/min^- 1) to catalase concentration (given in μM) of 10 min^- 1 and above, H₂O₂ degradation occurred via the catalatic cycle. At lower ratios, however, H₂O₂ degradation proceeded with increasingly diminished production of O₂. At a ratio of 1 min^- 1, O₂ formation could no longer be observed, although the enzyme still degraded H₂O₂. These results strongly suggest that at low physiological H₂O₂ fluxes H₂O₂ is preferentially metabolised reductively to H₂O, without release of O₂. The pathways involved in the reductive metabolism of H₂O₂ are presumably those previously reported as inactivation and reactivation pathways. They start from compound I and are operative at low and high H₂O₂ fluxes but kinetically outcompete the reaction of compound I with H₂O₂ at low H₂O₂ production rates. In the absence of NADPH, the reducing equivalents for the reductive metabolism of H₂O₂ are most likely provided by the protein moiety of the enzyme. In the presence of NADPH, they are at least in part provided by the coenzyme.     

Salivary hydrogen peroxide produced by holding or chewing green tea in the oral cavity

Tea (Camellia sinensis) catechins have been studied for disease prevention. These compounds undergo oxidation and produce H₂O₂. We have previously shown that holding tea solution or chewing tea leaves generates high salivary catechin levels. Herein, we examined the generation of H₂O₂ in the oral cavity by green tea solution or leaves. Human volunteers holding green tea solution (0.1-0.6%) developed salivary H₂O₂ with C_max = 2.9-9.6 μM and AUC_0 → ∞ = 8.5-285.3 μM min. Chewing 2 g green tea leaves produced higher levels of H₂O₂ (C_max = 31.2 μM, AUC_0 → ∞ = 1290.9 μM min). Salivary H₂O₂ correlated with catechin levels and with predicted levels of H₂O₂ (C_{max(expected)} = 36 μM vs C_{max(determined)} = 31.2 μM). Salivary H₂O₂ and catechin concentrations were similar to those that are biologically active in vitro. Catechin-generated H₂O₂ may, therefore, have a role in disease prevention by green tea.     

Oxidant-sensitive protein phosphorylation in endothelial cells

Reactive oxygen is an important regulator of vascular cell biology; however, the mechanisms involved in transducing signals from oxidants in endothelial cells are poorly defined. Because protein phosphorylation is a major mechanism for signal ransduction, cultured aortic endothelial cells were exposed to nonlethal concentrations of H₂O₂ to examine oxidant-sensitive changes in phosphorylation state. Addition of H₂O₂ increases the phosphorylation of the heat shock protein 27 (HSP27) within 2 min. This response is maximal by 20 min and remains constant for more than 45 min. Levels of intrcellular free Ca²⁺ in endothelial cells did not change following addition of 100 μM H₂O₂, nor did the ability of the cells to respond to bradykinin. H₂O₂-induced phosphorylations were either not affected or were slightly increased in cells pretreated with PKC inhibitors (H-8, staurosporin, or calphostin c). Two-dimensional analysis of phosphoproteins from homogenates of ³²P-labeled cells revealed that phorbol myristate acetate (PMA) did not cause the same degree of HSP27 phosphorylation as H₂O₂. Simultaneous addition of 10 ηM PMA and 50 μM H₂O₂ decreased the oxidant-stimulated phoshorylation of the most acidic HSP27 isoform. These data suggest that signal transduction for H₂O₂-sensitive endothelial cell responses are not only independent of PKC, but may also be suppressed by the action of the kinase.     

Turning point in apoptosis/necrosis induced by hydrogen peroxide

The turning point between apoptosis and necrosis induced by hydrogen peroxide (H₂O₂) have been investigated using human T-lymphoma Jurkat cells. Cells treated with 50 μM H₂O₂ exhibited caspase-9 and caspase-3 activation, finally leading to apoptotic cell death. Treatment with 500 μM H₂O₂ did not exhibit caspase activation and changed the mode of death to necrosis. On the other hand, the release of cytochrome c from the mitochondria was observed under both conditions. Treatment with 500 μM H₂O₂, but not with 50 μM H₂O₂, caused a marked decrease in the intracellular ATP level; this is essential for apoptosome formation. H₂O₂-reducing enzymes such as cellular glutathione peroxidase (cGPx) and catalase, which are important for the activation of caspases, were active under the 500 μM H₂O₂ condition. Prevention of intracellular ATP loss, which did not influence cytochrome c release, significantly activated caspases, changing the mode of cell death from necrosis to apoptosis. These results suggest that ATP-dependent apoptosome formation determines whether H₂O₂-induced cell death is due to apoptosis or necrosis.     

Oxidant inhibition of epithelial active sodium transport

The purpose of this study was to quantify the effects of extracellularly generated partially reduced oxygen species on active sodium (NA⁺) transport across the ventral toad skin, a well-studied epithelium. Sections of skin from decapitated toads were mounted in an Ussing chamber, bathed on both sides with electrolyte solution containing 500 μM xanthine and bubbled continuously with room air. The tissues were short-circuited, and short circuit current (Isc) and tissue resistance (R_t were monitored continuously with an automatic voltage clamp apparatus. Fifteen mU/ml of xanthine oxidase (XO), either purchased from Calbiochem or purified from cream, were instilled in either the apical (mucosal) or basolateral (serosal) baths at t = 0 and T = 10 min. Hydrogen peroxide (H₂O₂) concentrations increased to 200 μM within the first 20 min and then decreased, reaching a value of 40 μM by 60 min. Mean [H₂O₂] was 90 μM. Instillation of XO in the apical bath resulted in a large decrease in Isc and an increase in R_t, their values being 43% and 160% of their corresponding controls 85 min after the first instillation. Addition of superoxide dismutase and catalase completely prevented these changes. Instillation of XO in the basolateral bath had no effect. Similar physiological responses were obtained using the Calbiochem XO or the purified XO, which contained no measurable protease activity. It was concluded that extracellularly generated partially reduced oxygen species may interfere with active Na⁺ transport by possibly damaging apical Na⁺ channel proteins.     

Caspases are reversibly inactivated by hydrogen peroxide

Hydrogen peroxide (H₂O₂) is known to both induce and inhibit apoptosis, however the mechanisms are unclear. We found that H₂O₂ inhibited the activity of recombinant caspase-3 and caspase-8, half-inhibition occurring at about 17 μM H₂O₂. This inhibition was both prevented and reversed by dithiothreitol while glutathione had little protective effect. 100–200 μM H₂O₂ added to macrophages after induction of caspase activation by nitric oxide or serum withdrawal substantially inhibited caspase activity. Activation of H₂O₂-producing NADPH oxidase in macrophages also caused catalase-sensitive inactivation of cellular caspases. The data suggest that the activity of caspases in cells can be directly but reversibly inhibited by H₂O₂.     

Copper- and magnesium protoporphyrin complexes inhibit oxidative modification of LDL induced by hemin, transition metal ions and tyrosyl radicals

The oxidative modification of LDL may play an important role in the early events of atherogenesis. Thus the identification of antioxidative compounds may be of therapeutic and prophylactic importance regarding cardiovascular disease. Copper-chlorophyllin (Cu-CHL), a Cu²⁺-protoporphyrin IX complex, has been reported to inhibit lipid oxidation in biological membranes and liposomes. Hemin (Fe³⁺-protoporphyrin IX) has been shown to bind to LDL thereby inducing lipid peroxidation. As Cu-CHL has a similar structure as hemin, one may assume that Cu-CHL may compete with the hemin action on LDL. Therefore, in the present study Cu-CHL and the related compound magnesium-chlorophyllin (Mg-CHL) were examined in their ability to inhibit LDL oxidation initiated by hemin and other LDL oxidizing systems. LDL oxidation by hemin in presence of H₂O₂ was strongly inhibited by both CHLs. Both chlorophyllins were also capable of effectively inhibiting LDL oxidation initiated by transition metal ions (Cu²⁺), human umbilical vein endothelial cells (HUVEC) and tyrosyl radicals generated by myeloperoxidase (MPO) in presence of H₂O₂ and tyrosine. Cu- and Mg-CHL showed radical scavenging ability as demonstrated by the diphenylpicrylhydracylradical (DPPH)-radical assay and estimation of phenoxyl radical generated diphenyl (dityrosine) formation. As assessed by ultracentrifugation the chlorophyllins were found to bind to LDL (and HDL) in serum. The present study shows that copper chlorophyllin (Cu-CHL) and its magnesium analog could act as potent antagonists of atherogenic LDL modification induced by various oxidative stimuli. As inhibitory effects of the CHLs were found at concentrations as low as 1 μmol/l, which can be achieved in humans, the results may be physiologically/therapeutically relevant.     

Mechanisms of Saccharomyces Cerevisiae PMA1 H+-ATPase inactivation by Fe2+, H2O2 and Fenton reagents

Although considerably more oxidation-resistant than other P-type ATPases, the yeast PMA1 H⁺-ATPase of Saccharomyces cerevisiae SY4 secretory vesicles was inactivated by H₂O₂, Fe²⁺, Fe- and Cu-Fenton reagents. Inactivation by Fe²⁺ required the presence of oxygen and hence involved auto-oxidation of Fe²⁺ to Fe³⁺. The highest Fe^2- (100 μM) and H₂O₂ (100 mM) concentrations used produced about the same effect. Inactivation by the Fenton reagent depended more on Fe²⁺ content than on H₂O₂ concentration, occurred only when Fe²⁺ was added to the vesicles first and was only slightly reduced by scavengers (mannitol, Tris, NaN₃, DMSO) and by chelators (EDTA, EGTA, DTPA, BPDs, bipyridine, 1, 10-phenanthroline). Inactivation by Fe- and Cu- Fenton reagent was the same; the identical inactivation pattern found for both reagents under anaerobic conditions showed that both reagents act via OH^·. The lipid peroxidation blocker BHT prevented Fenton-induced rise in lipid peroxidation in both whole cells and in isolated membrane lipids but did not protect the H⁺-ATPase in secretory vesicles against inactivation. ATP partially protected the enzyme against peroxide and the Fenton reagent in a way resembling the protection it afforded against SH-specific agents. The results indicate that Fe²⁺ and the Fenton reagent act via metal-catalyzed oxidation at specific metal-binding sites, very probably SH-containing amino acid residues. Deferrioxamine, which prevents the redox cycling of Fe²⁺, blocked H⁺-ATPase inactivation by Fe²⁺ and the Fenton reagent but not that caused by H₂O₂, which therefore seems to involve a direct non-radical attack. Fe-Fenton reagent caused fragmentation of the H⁺-ATPase molecule, which, in Western blots, did not give rise to defined fragments bands but merely to smears.     

Influence of copper-(II) on colloidal carbon-induced kupffer cell-dependent oxygen uptake in rat liver: Relation to hepatotoxicity

Formation of reactive O₂ species in biological systems can be accomplished by copper-(II) (Cu²⁺) catalysis, with the consequent cytotoxic response. We have evaluated the influence of Cu²⁺ on the respiratory activity of Kupffer cells in the perfused liver after colloidal carbon infusion. Studies were carried out in untreated rats and in animals pretreated with the Kupffer cell inactivator gadolinium chloride (GdCl₃) or with the metallothionein (MT) inducing agent zinc sulphate, and results were correlated with changes in liver sinusoidal efflux of lactate dehydrogenase (LDH) as an index of hepatotoxicity. In the concentration range of 0.1-1 μM, Cu²⁺ did not modify carbon phagocytosis by Kupffer cells, whereas the carbon-induced liver O₂ uptake showed a sigmoidal-type kinetics with a half-maximal concentration of 0.23 μM. Carbon-induced O₂ uptake occurred concomitantly with an increased LDH efflux, effects that were significantly correlated and abolished by GdCl₃ pretreatment or by MT induction. It is hypothesized that Cu²⁺ increases Kupffer cell-dependent O₂ utilization by promotion of the free radical processes related to the respiratory burst of activated liver macrophages, which may contribute to the concomitant development of hepatocellular injury.     

Direct NAD(P)H hydrolysis into ADP-ribose(P) and nicotinamide induced by reactive oxygen species: a new mechanism of oxygen radical toxicity

The effect of different oxygen radical-generating systems on NAD(P)H was determined by incubating the reduced forms of the pyridine coenzymes with either Fe²⁺-H₂O₂ or Fe³⁺-ascorbate and by analyzing the reaction mixtures using a HPLC separation of adenine nucleotide derivatives. The effect of the azo-initiator 2,2'-azobis(2-methylpropionamidine)dihydrochloride was also tested. Results showed that, whilst all the three free radical-producing systems induced, with different extent, the oxidation of NAD(P)H to NAD(P)⁺, only Fe²⁺-H₂O₂ also caused the formation of equimolar amounts of ADP-ribose(P) and nicotinamide. Dose-dependent experiments, with increasing Fe²⁺ iron (concentration range 3-180 μM) or H₂O₂ (concentration range 50-1000 μM), were carried out at pH 6.5 in 50 mM ammonium acetate. NAD(P)⁺, ADP-ribose(P) and nicotinamide formation increased by increasing the amount of hydroxyl radicals produced in the medium. Under such incubation conditions NAD(P)⁺/ADP-ribose(P) ratio was about 4 at any Fe²⁺ or H₂O₂ concentration. By varying pH to 2.0, 3.0, 4.0, 4.5, 5.0, 5.5, 6.0, 7.0 and 7.4, NAD(P)⁺/ADP-ribose(P) ratio changed to 5.5, 3.2, 1.8, 1.6, 2.0, 2.5, 3.0, 5.4 and 6.5, respectively. Kinetic experiments indicated that 90-95% of all compounds were generated within 5s from the beginning of the Fenton reaction. Inhibition of ADP-ribose(P), nicotinamide and NAD(P)⁺ production of Fe²⁺-H₂O₂-treated NAD(P)H samples, was achieved by adding mannitol (10-50 mM) to the reaction mixture. Differently, selective and total inhibition of ADP-ribose(P) and nicotinamide formation was obtained by performing the Fenton reaction in an almost completely anhydrous medium, i.e. in HPLC-grade methanol. Experiments carried out in isolated postischemic rat hearts perfused with 50 mM mannitol, showed that, with respect to values of control hearts, this hydroxyl radical scavenger prevented reperfusion-associated pyridine coenzyme depletion and ADP-ribose formation. On the basis of these results, a possible mechanism of action of ADP-ribose(P) and nicotinamide generation through the interaction between NAD(P)H and hydroxyl radical (which does not involve the C-center where “conventional” oxidation occurs) is presented. The implication of this phenomenon in the pyridine coenzyme depletion observed in postischemic tissues is also discussed.     

H2O2 and Src-dependent transactivation of the EGF receptor mediates the stimulatory effect of leptin on renal ERK and Na+, K+-ATPase

We examined the mechanism through which leptin increases Na⁺, K⁺-ATPase activity in the rat kidney. Leptin was infused under anaesthesia into the abdominal aorta proximally to the renal arteries and then Na⁺, K⁺-ATPase activity was measured in the renal cortex and medulla. Leptin (1 μg/kg min) increased Na⁺, K⁺-ATPase activity after 3 h of infusion, which was accompanied by the increase in urinary H₂O₂ excretion and phosphorylation level of extracellular signal regulated kinase (ERK). The effect of leptin on ERK and Na⁺, K⁺-ATPase was abolished by catalase, specific inhibitors of epidermal growth factor (EGF) receptor, AG1478 and PD158780, as well as by ERK inhibitor, PD98059, and was mimicked by both exogenous H₂O₂ and EGF. The effect of leptin was also prevented by the inhibitor of Src tyrosine kinase, PP2. Leptin and H₂O₂ increased Src phosphorylation at Tyr⁴¹⁸. We conclude that leptin-induced stimulation of renal Na⁺, K⁺-ATPase involves H₂O₂ generation, Src kinase, transactivation of the EGF receptor, and stimulation of ERK.     

Inhibitory effects of carrier-immobilized synthetic histo-blood group A-, B-, H-, and SiaLe-oligosaccharides on H2O2 generation by human polymorphonuclear leukocytes

Carbohydrate-bearing polymers of biologically inert design are versatile tools to delineate functional aspects of oligosaccharides. Binding of synthetic N-substituted polyacrylamide (PAA) conjugates of histo-blood group (A_di, A_tri, B_di, B_tri, H_di, SiaLe^a, and SiaLe^x) to human polymorphonuclear leukocytes (PMNs), and effects on H₂O₂ generation elicited by different agonists such as digitonin, N-formyl-Met-Leu-Phe (FMLP) and the galactoside-specific lectin from Viscum album L. (VAA) were assessed. PMNs expressed binding sites for blood group-related neoglycoconjugates in the range of N10⁶–10⁷/cell with K_D-values in the μM range. Treatment of PMNs (2×10⁶ cells/ml) with PAA-probes (50 μg/ml) for 5 min did not activate the “respiratory burst”. However, it led to suppression (range 20–70%) of H₂O₂ generation of cells in the presence of elicitors. In detail, the FMLP-induced response was significantly decreased by A_di, A_tri, B_tri, H_di, SiaLe^a, and SiaLe^x conjugates, whereas for digitonin one only by A_di, A_tri, B_tri. All the seven tested PAA-probes were found to inhibit significantly VAA-mediated release of H₂O₂ from PMNs. In this case, interference can take place already, at the stage of initial binding, especially for B- and H-epitopes, but less prominently for A- and SiaLe-epitopes. These results support the notion that PAA-immobilized histo-blood group oligosaccharides can serve as effector molecules with the ability to reduce the H₂O₂-generation of PMNs, warranting further studies on the involved reaction pathway.     

Reactive oxidants regulate membrane repolarization and store-operated uptake of calcium by formyl peptide-activated human neutrophils

Although the rapid and considerable membrane depolarization response which accompanies activation of the phagocyte NADPH oxidase is due to transmembrane electron fluxes, little is known about the involvement of reactive oxidant species (ROS) in the subsequent repolarization response. In the current study, we have investigated the effects of superoxide dismutase (SOD), catalase, methionine, and the myeloperoxidase (MPO) inhibitors, sodium azide and 4-aminobenzoyl hydrazide (ABAH), as well as those of H₂O₂ and HOCl (both at 100 μM) on the alterations in membrane potential which accompany activation of human neutrophils with the chemoattractant, FMLP (1 μM), and on store-operated uptake of Ca²⁺. The generation of ROS by FMLP-activated neutrophils was monitored according to the magnitude of oxygen consumption and autoiodination, while spectrofluorimetric procedures were used to measure alterations in membrane potential and influx of Ca²⁺. Treatment of the cells with H₂O₂, and HOCl, significantly impeded membrane repolarization, while sodium azide, ABAH, methionine, and catalase exerted the opposite effects, potentiating both the rates and the magnitudes of membrane repolarization and store-operated uptake of Ca²⁺. These observations demonstrate that NADPH oxidase regulates neutrophil membrane potential and Ca²⁺ influx not only via its electrogenic activity, but also as a consequence of the generation of ROS.     

Inactivation of Heart Dihydrolipoamide Dehydrogenase by Copper Fenton Systems. Effect of Thiol Compounds and Metal Chelators

Copper Fenton systems (Cu(II)/H₂O₂ and Cu(II)/Asc) inactivated the lipoamide reductase and enhanced the diaphorase activity of pig-heart lipoamide dehydrogenase (LADH). Cupric ions alone were less effective. As a result of Cu(II)/H₂O₂ treatment, the number of titrated thiols in LADH decreased from 6 to 1 per subunit. NADH and ADP (not NAD⁺ or ATP) enhanced LADH inactivation by Cu(II). NADH also enhanced the effect of Cu(II)/H₂O₂. Dihydrolipoamide, dihydrolipoic acid, Captopril, acetylcysteine, EDTA, DETAPAC, histidine, bathocuproine, GSSG and trypanothione prevented LADH inactivation. 100 μM GSH, DL-dithiothreitol, N-(2-mercaptopropionylglicine) and penicillamine protected LADH against Cu(II)/Asc and Cu(II), whereas 1.0 mm GSH and DL-dithiothreitol also protected LADH against Cu(II)/H₂O₂. Allopurinol provided partial protection against Cu(II)/H₂O₂. EthanoI, mannitol, Na benzoate and superoxide dismutase failed to prevent LADH inactivation by Cu(II)/H₂O₂ or Cu(II). Catalase (native or denaturated) and bovine serum albumin protected LADH but that protection should be due to Cu binding. LADH inhibited deoxyribose oxidation and benzoate hydroxylation by Cu(II)/H₂O₂. It is concluded that site-specifically generated HO, radicals were responsible for LADH inactivation by Cu(II) Fenton systems. The latter effect is discussed in the context of ischemia-reoxygenation myocardial injury.     

Iron Release from Metmyoglobin, Methaemoglobin and Cytochrome C by A System Generating Hydrogen Peroxide

The reaction of H₂O₂ with resting metmyoglobin (MetMb), methaemoglobin (MetHb) and cytochrome-c (Cyt-c) was studied in the Soret and visible regions. The differences between the original and the final peak heights of the native haemproteins at 408 nm was found to be directly proportional to the loss of iron from the molecule. The release of iron from haemproteins was studied in a system generating H₂O₂ continuously at a low rate by an enzymic system, or by addition of large amounts of H₂O₂. Cytochrome-c, methaemoglobin and metmyoglobin during interaction with H₂O₂ at a concentration of 200 μM release 40%, 20% and 3%, respectively, of molecular iron after l0min. The inhibition of haem degradation and iron release by enzymatically-generated H₂O₂ was determined using several hydroxyl radical scavengers, reducing agents and antioxienzymes, such as superoxide dismutase, catalase and caeruloplasmin.     

Inactivation of Rabbit Muscle Creatine Kinase by Hydrogen Peroxide

The effects of xanthine + xanthine oxidase-generated reactive oxygen species (ROS) on rabbit muscle creatine kinase (CK) were studied. Xanthine (0.1 mM) + xanthine oxidase (30 mU/ml) inhibited activity of rabbit muscle CK (1.2mU/ml). Catalase (100/ml), but not SOD (100 U/ml), deferoxamine (100μM) or mannitol (20 mM), protected CK from inactivation; suggesting that H₂O₂ was responsible for inactivation. These results were different from previously reported findings on bovine heart CK that superoxide radicals inactivate the enzyme. Thus, enzymes with homologous structures may have different reactivities to different ROS. H₂O₂-induced inactivation of rabbit muscle CK was accompanied by a decrease in its thiol group content, whereas no significant changes in the protein structure were detected by SDS-PAGE or carbonyl content. These results suggest that oxidation of -SH groups by H₂O₂ seems to be a major mechanism of activation of rabbit muscle CK by xanthine + xanthine oxidase. Such inactivation of CK by H₂O₂ may be important in ROS-induced pathology.     

Methylmercury and H(2)O(2) provoke lysosomal damage in human astrocytoma D384 cells followed by apoptosis

Methylmercury (MeHg) is a neurotoxic agent acting via diverse mechanisms, including oxidative stress. MeHg also induces astrocytic dysfunction, which can contribute to neuronal damage. The cellular effects of MeHg were investigated in human astrocytoma D384 cells, with special reference to the induction of oxidative-stress-related events. Lysosomal rupture was detected after short MeHg-exposure (1 μM, 1 h) in cells maintaining plasma membrane integrity. Disruption of lysosomes was also observed after hydrogen peroxide (H₂O₂) exposure (100 μM, 1 h), supporting the hypothesis that lysosomal membranes represent a possible target of agents causing oxidative stress. The lysosomal alterations induced by MeHg and H₂O₂ preceded a decrease of the mitochondrial potential. At later time points, both toxic agents caused the appearance of cells with apoptotic morphology, chromatin condensation, and regular DNA fragmentation. However, MeHg and H₂O₂ stimulated divergent pathways, with caspases being activated only by H₂O₂. The caspase inhibitor z-VAD-fmk did not prevent DNA fragmentation induced by H₂O₂, suggesting that the formation of high-molecular-weight DNA fragments was caspase independent with both MeHg and H₂O₂. The data point to the possibility that lysosomal hydrolytic enzymes act as executor factors in D384 cell death induced by oxidative stress.     

Synthesis, magnetism and crystal structure of [V2O2(μ-OH)2(tpen)]I2·4H2O; a binuclear complex containing the syn-{VO(μ-OH)2VO} core (tpen = tetrakis(2-pyridylmethyl)ethylenediamine)

The reaction of N,N,N′,N′-tetrakis(2-pyridylmethyl)ethylenediamine (tpen) with VCl₃ in CH₃CN yields Cl₃V(tpen)VCl₃ which was hydrolyzed in water in the presence of oxygen affording [V₂O₂(μ-OH)₂(tpen)]I₂·2H₂O, the crystal structure of which has been determined. Asyn-{OV(μ-OH)₂VO}²⁺ core has been identified where the V(IV) centers are antiferromagnetically coupled (J = −150 cm⁻¹;g = 1.80).