Superoxide-dependent oxidation of melatonin by myeloperoxidase

Myeloperoxidase uses hydrogen peroxide to oxidize numerous substrates to hypohalous acids or reactive free radicals. Here we show that neutrophils oxidize melatonin to N(1)-acetyl-N(2)-formyl-5-methoxykynuramine (AFMK) in a reaction that is catalyzed by myeloperoxidase. Production of AFMK was highly dependent on superoxide but not hydrogen peroxide. It did not require hypochlorous acid, singlet oxygen, or hydroxyl radical. Purified myeloperoxidase and a superoxide-generating system oxidized melatonin to AFMK and a dimer. The dimer would result from coupling of melatonin radicals. Oxidation of melatonin was partially inhibited by catalase or superoxide dismutase. Formation of AFMK was almost completely eliminated by superoxide dismutase but weakly inhibited by catalase. In contrast, production of melatonin dimer was enhanced by superoxide dismutase and blocked by catalase. We propose that myeloperoxidase uses superoxide to oxidize melatonin by two distinct pathways. One pathway involves the classical peroxidation mechanism in which hydrogen peroxide is used to oxidize melatonin to radicals. Superoxide adds to these radicals to form an unstable peroxide that decays to AFMK. In the other pathway, myeloperoxidase uses superoxide to insert dioxygen into melatonin to form AFMK. This novel activity expands the types of oxidative reactions myeloperoxidase can catalyze. It should be relevant to the way neutrophils use superoxide to kill bacteria and how they metabolize xenobiotics.     

Superoxide-dependent reduction of nitroxides by thiols

It was found that superoxide can reduce certain nitroxide free radicals to their corresponding hydroxylamines in the presence of most sulfhydryl-containing compounds. The stoichiometry of the reaction was found to be three nitroxides reduced per superoxide. Evidence is presented indicating that superoxide directly reacts with a nitroxide to yield a N-hydroxy-N-hydroperoxyl compound. This product rapidly decomposes, giving a hydroxylamine and an oxidized sulfhydryl compound, which is postulated to be a sulfenyl hydroperoxide. It is proposed that this sulfenyl hydroperoxide reduces two additional nitroxyl free radicals to account for the unusual stoichiometry.     

The reaction of DNA with lipid oxidation products, metals and reducing agents

The interaction of lipid hydroperoxides and secondary oxidation products with DNA was investigated by evaluating the fluorescence formed in the presence of metals and reducing agents. We also investigated the effect of malonaldehyde, because it has been generally considered responsible for the formation of fluorescence with DNA. However, malonaldehyde usually has been estimated by the notoriously unspecific thiobarbituric acid test. At low concentration of oxidation products (1 mM), fluorescence formation required the presence of metals and ascorbic acid. In contrast, a positive thiobarbituric acid reaction was obtained with many lipid oxidation products without metals or ascorbic acid. Monohydroperoxides from autoxidized methyl linoleate and linolenate produced the highest level of fluorescence. Hydroperoxy epidioxides of linolenate and dihydroperoxides of linoleate and linolenate were among the most active secondary products in forming fluorescence with DNA. In contrast, malonaldehyde produced very little fluorescence under our conditions. The thiobarbituric acid values did not correlate with fluorescence formation. This study showed that, in our model reaction system, DNA forms fluorescent products by the breakdown of lipid oxidation products in the presence of metals and ascorbic acid into reactive materials other than malonaldehyde. Therefore, the importance of malonaldehyde in its crosslinking properties with DNA may have been exaggerated in the literature.     

Inhibition of superoxide anion production by extracellular acidification in neutrophils

Extracellular acidification inhibited formyl-Met-Leu-Phe- or C5a-induced superoxide anion (O₂⁻) production in differentiated HL-60 neutrophil-like cells and human neutrophils. A cAMP-increasing agonist, prostaglandin E₁, also inhibited the formyl peptide-induced O₂⁻ production. The inhibitory action on the O₂⁻ production by extracellular acidic pH was associated with cAMP accumulation and partly attenuated by H89, a protein kinase A inhibitor. A significant amount of mRNAs for T-cell death-associated gene 8 (TDAG8) and other proton-sensing ovarian cancer G-protein-coupled receptor 1 (OGR1)-family receptors is expressed in these cells. These results suggest that cAMP/protein kinase A, possibly through proton-sensing G-protein-coupled receptors, may be involved in extracellular acidic pH-induced inhibition of O₂⁻ production.     

The effect of reducing agents on proteolytic enzymes and oxidation of alpha 1-proteinase inhibitor

We have studied the effect of the mucolytic agent N-acetylcysteine and dithiothreitol on the oxidation of alpha 1-PI by hydrogen peroxide, and their effect on porcine pancreatic elastase and leukocyte elastase. In addition, the effect of S-(carboxymethyl)cysteine (= carbocisteine, a mucolytic agent which does not have reducing properties) was studied in vitro and in patients with chronic obstructive bronchitis. Following addition of 59.6mM N-acetylcysteine, the amidolytic activity of leukocyte elastase was decreased by 55.3% and that of porcine pancreatic elastase by 57.0%. Dithiothreitol (5.7 mM) caused the loss of 97.4% and 67.6% of amidolytic activity of leukocyte elastase and porcine pancreatic elastase respectively whereas S-(carboxymethyl)cysteine had no effect. Similar results were found for the effect on elastolytic activity. Oxidation of alpha 1-PI by 8.6mM H2O2 resulted in partial loss of inhibitory function (mean 68.7% activity of native alpha 1-PI). N-Acetylcysteine and dithiothreitol prevented oxidation of alpha 1-PI when pre-incubated with H2O2 or incubated with alpha 1-PI and H2O2 simultaneously (94.5% and 94.4% activity of native alpha 1-PI for N-acetylcysteine; 78.3% and 87.6% activity for dithiothreitol - p less than 0.025). S-(Carboxymethyl)cysteine, when pre-incubated with H2O2 or incubated concurrently with alpha 1-PI and H2O2, caused a further decrease in the porcine pancreatic elastase inhibitory capacity of alpha 1-PI (53.1% and 63.0% respectively - p less than 0.025). None of the agents reversed oxidative inactivation once it had occurred. S-(Carboxymethyl)cysteine had no effect on alpha 1-PI function in sputum at the dose used.     

Estrogen, neutrophils and oxidation

The potential role of estrogens in the prevention of cardiovascular disease (CVD) is still under debate. Previous studies from our laboratory have shown that estradiol may act as a pro oxidant at physiological concentrations, enhancing peroxidase-mediated oxidation of low density lipoprotein (LDL). In the present study, we show that physiological concentrations of estradiol enhance fMLP-mediated neutrophil degranulation and oxidative stress markers. For example, 10 nM estradiol increased myeloperoxidase (MPO), elastase, and superoxide release by 19.9 +/- 9.6% (p = 0.006), 16.3 +/- 5.2% (p = 0.09), and 36.1 +/- 19.5% (p = 0.05), respectively. The enhancement of neutrophil degranulation by estradiol resulted in an increase in the formation of LDL oxidation markers such as conjugated dienes and thiobarbituric acid-reactive substances (20.7 +/- 7.2%, p = 0.04). Thus, estradiol can act as a pro oxidant, promoting neutrophil degranulation as well as reacting with MPO to enhance the oxidation of LDL. This mechanism supports our hypothesis that oxidative stress may be beneficial towards the prevention of CVD both by promoting plasma oxidation of LDL, with its subsequent clearance by the liver, as well as by inducing a threshold antioxidant defense in the arteries. Our study also suggests that estradiol by promoting oxidation in the plasma is beneficial in preventing CVD.     

Superoxide-dependent and superoxide-independent pathways for reduction of nitroblue tetrazolium in isolated rat cardiac myocytes.

Spectroscopic studies indicated that nitroblue tetrazolium (NBT) could be reduced to blue formazan by several distinct reactions in suspensions of isolated rat cardiac myocytes. Both NADPH- and NADH-linked pathways for reduction of NBT were observed. NADPH-linked NBT reduction showed little activity in the absence of digitonin, but could be stimulated an average of 9.5-fold by digitonin permeabilization of the plasma membrane. NADH-linked NBT reduction occurred in the absence of digitonin, and could be increased an average of 3.5-fold by digitonin treatment. Analysis of the effects of cell viability on the extent of digitonin stimulation with these substrates suggested that the NADPH-linked reaction involved a cytosolic component, while the NADH-linked reaction involved an intracellular membrane enzyme system. With either NADPH or NADH, NBT reduction was completely inhibited by dicoumarol (100 microM). Dicoumarol-insensitive NBT reduction could subsequently be observed following the addition of 2 mM cyanide, a level of cyanide known to inhibit cytosolic superoxide dismutase. Cyanide-stimulated, dicoumarol-insensitive NBT reduction was augmented by the presence of either antimycin or doxorubicin, two agents which enhance superoxide formation by different mechanisms. The results indicate the existence of multiple pathways for both superoxide-independent and superoxide-dependent reduction of NBT. Dicoumarol-insensitive, cyanide-stimulated NBT reduction may be useful as a spectroscopic probe for intracellular superoxide formation.     

Superoxide-dependent formation of hydroxyl radical catalyzed by transferrin

Hydroxyl radicals are generated in the hypoxanthine-xanthine oxidase system in the presence of iron-saturated transferrin isolated from human serum. This has been demonstrated by colorimetrically measuring the hydroxylation of salicylic acid and by EPR using the spin trap DMPO (5,5-dimethyl-1-pyrroline-N-oxide). A Fenton-type Harber-Weiss reaction catalyzed by transferrin is proposed.     

Priming of human neutrophils is necessary for their activation by extracellular DNA

Extracellular plasma DNA is thought to act as a damage-associated molecular pattern causing activation of immune cells. However, purified preparations of mitochondrial and nuclear DNA were unable to induce neutrophil activation in vitro. Thus, we examined whether granulocyte-macrophage colony-stimulating factor (GM-CSF) acting as a neutrophil priming agent can promote the activation of neutrophils by different types of extracellular DNA. GM-CSF pretreatment greatly increased p38 MAPK phosphorylation and promoted CD11b/CD66b expression in human neutrophils treated with mitochondrial and, to a lesser extent, with nuclear DNA. Our experiments clearly indicate that GM-CSFinduced priming of human neutrophils is necessary for their subsequent activation by extracellular DNA.     

Reversal of copper-induced inhibition of vasopressin responsiveness by reducing agents

Copper inhibits the hydro-osmotic response to vasopressin in the urinary bladder of Bufo marinus at a site proximal to cyclic AMP production. This effect is not reversed by washing in Cu2+ -free Ringer's solution but is overcome by serosal addition of reducing agents, suggesting that vasopressin responsiveness in this tissue is modulated by either the redox potential or the sulfhydryl content of the serosal membrane.     

Chemotactic factor inactivation by stimulated human neutrophils mediated by myeloperoxidase-catalyzed methionine oxidation

Leukocyte chemoattractants were inactivated when exposed to human neutrophils and either ingestible particles or phorbol esters. Loss of biologic activity was time- and temperature-dependent, required physiologic concentrations of viable neutrophils and a halide, and was inhibited by azide or catalase. Neutrophils from patients with either hereditary myeloperoxidase deficiency or chronic granulomatous disease failed to inactivate the chemoattractants unless purified myeloperoxidase or H2O2, respectively, was added. Susceptibility to inactivation by neutrophils correlated with the presence of methionine in the attractant. Loss of chemotactic activity was blocked by low concentrations of methionine and by higher concentrations of other reducing agents, but was unaffected by oxidized methionine. Paper chromatography demonstrated that exposure of a formyl-methionyl peptide chemotactic factor to either the cellfree myeloperoxidase system or stimulated neutrophils resulted in its conversion to a molecular species whose location in the chromatographs was identical to that of the peptide containing oxidized methionine. Thus, stimulated human neutrophils inactivate peptide chemoattractants by secretion of myeloperoxidase and H2O2, which combine with halides to form oxidants that react with a critical methionine residue. We suggest that myeloperoxidase-catalyzed oxidation of thioethers may constitute an inflammatory control mechanism as well as a general means of modifying the functional properties of biologic mediators.     

Modulation of plant ion channels by oxidizing and reducing agents

Ion channels are proteins forming hydrophilic pathways through the membranes of all living organisms. They play important roles in the electrogenic transport of ions and metabolites. Because of biophysical properties such as high selectivity for the permeant ion, high turnover rate, and modulation by physico-chemical parameters (e.g., membrane potential, calcium concentration), they are involved in several physiological processes in plant cells (e.g., maintenance of the turgor pressure, stomatal movements, and nutrient absorption by the roots). As plants cannot move, plant metabolism must be flexible and dynamic, to cope with environmental changes, to compete with other living species and to prevent pathogen invasion. An example of this flexibility and dynamic behavior is represented by their handling of the so-called reactive oxygen species, inevitable by-products of aerobic metabolism. Plants cope with these species on one side avoiding their toxic effects, on the other utilizing them as signalling molecules and as a means of defence against pathogens. In this review, we present the state-of-the-art of the modulation of plant ion channels by oxidizing and reducing agents.