Quantitative generation of singlet (1Δg) oxygen from acidified aqueous peroxynitrite produced by the reaction of nitric oxide and superoxide anion

Simple acidification of aqueous alkaline peroxynitrite quantitatively generates singlet (¹Δ_g) molecular oxygen, detected and quantitated spectroscopically (1270 nm). This observation provides a chemical basis for physiological cytotoxicity of ONOO^? generated in the diffusion - controlled reaction of cellular NO^? and O. The experiments consist of (i) chemical generation of ONOO^? from NO^? gas and KO₂ powder in alkaline aqueous solution; (ii) absorption spectral identification of ONOO^? in the near-UV with maximum at 302 nm; (iii) spectroscopic identification of ¹O₂ by its emission band at 1200–1340 nm with maximum at 1275 nm; and (iv) quantitation of ¹O₂ generated in ONOO^?/H⁺ reaction by comparison of the chemiluminescence intensity at 1270 nm with that from H₂O₂/OCl^? reaction that generates ¹O₂ with unit efficiency at alkaline pH. ¹O₂ was generated with unit efficiency with respect to ONOO^? concentration by the ONOO^?/H⁺ reaction.     

Oxygen-Dependent Inhibition of Neutrophil Respiratory Burst by Nitric Oxide

Effect of nitric oxide (NO) on the respiratory burst of neutrophils was examined under different oxygen tensions. Phorbol myristate acetate (PMA) stimulated oxygen consumption and superoxide (O₂^-) generation in neutrophils by a mechanism which was inhibited reversibly by NO. The inhibitory effect of NO increased significantly with a decrease in oxygen tension in the medium. The inhibitory effect of NO was suppressed in medium containing oxyhemoglobin (HbO₂), a NO scavenging agent. In contrast, 3-morpholinosydnonimine (SIN-1), a compound that rapidly generates peroxynitrite (ONOO^-) from the released NO and O₂^-, slightly stimulated the PMA-induced respiratory burst. These results suggested that NO, but not ONOO, might reversibly inhibit superoxide generation by neutrophils especially at physiologically low oxygen tensions thereby decreasing oxygen toxicity particularly in and around hypoxic tissues.     

Analysis of the pathways of nitric oxide utilization in mitochondria

The regulatory role that mitochondria play in cell dysfunction and cell-death pathways involves the concept of a complex and multisite regulation of cellular respiration and energy production signaled by cellular and intercellular messengers. Hence, the role of nitric oxide, as a physiological regulator acting directly on the mitochondrial respiratory chain acquires further relevance. This article provides a survey of the major regulatory roles of nitric oxide on mitochondrial functions as an expression of two major metabolic pathways for nitric oxide consumption: a reductive pathway, involving mitochondrial ubiquinol and yielding nitroxyl anion and an oxidative pathway involving superoxide anion and yielding peroxynitrite. The modulation of the decay pathways for nitrogen-and oxygen-centered radicals is further analyzed as a function of the redox transitions of mitochondrial ubiquinol. The interplay among these redox processes and its implications for mitochondrial function is discussed in terms of the mitochondrial steady-state levels (and gradients) of nitric oxide and superoxide anion.     

The mechanisms for nitration and nitrotyrosine formation in vitro and in vivo: Impact of diet

The detection of 3-nitro-L-tyrosine residues associated with many disease states, including gastric cancer, has implicated a role for peroxynitrite in vivo, and thus endogenously produced nitric oxide and superoxide. Additionally, dietary nitrate has been suggested to be involved in the pathogenesis of gastric cancer through a mechanism involving reduction to nitrite and subsequent formation of potentially mutagenic nitrosocompounds. Studies have now demonstrated that a multitude of reactive nitrogen species other than peroxynitrite are capable of producing nitrotyrosine. Thus, we have reviewed the evidence that dietary nitrate, amongst other reactive nitrogen species, may contribute to the body burden of nitrotyrosine.     

Effects of a metalloporphyrinic peroxynitrite decomposition catalyst,ww-85, in a mouse model of spinal cord injury

The aim of the present study was to assess the effect of a metalloporphyrinic peroxynitrite decomposition catalyst, ww-85, in the pathophysiology of spinal cord injury (SCI) in mice. Spinal cord trauma was induced by the application of vascular clips to the dura via a four-level T5–T8 laminectomy. SCI in mice resulted in severe trauma characterized by oedema, neutrophil infiltration, production of inflammatory mediators, tissue damage and apoptosis. ww-85 treatment (30–300 µg/kg, i.p. 1 h after the SCI) significantly reduced in a dose-dependent manner: (1) the degree of spinal cord inflammation and tissue injury, (2) neutrophil infiltration (myeloperoxidase activity), (3) nitrotyrosine formation and PARP activation, (4) pro-inflammatory cytokines expression, (5) NF-κB activation and (6) apoptosis. Moreover, ww-85 significantly ameliorated the recovery of limb function (evaluated by motor recovery score) in a dose-dependent manner. The results demonstrate that ww-85 treatment reduces the development of inflammation and tissue injury associated with spinal cord trauma.     

Chemical evaluation of compounds as nitric oxide or peroxynitrite donors using the reactions with serotonin

The aim of this work was to assess the capacities of some ^·NO-donors to release ^·NO, and consequently NOx in aerobic medium, or to give peroxynitrite. The method was based on the differential reactivity of serotonin (5-HT) with either NO_x or peroxynitrite, leading in phosphate-buffered solutions to 4-nitroso- and 4-nitro-5-HT formation, respectively. Yields and formation rates of 5-HT derivatives with ^·NO-donor were compared to those obtained with authentic ^·NO or peroxynitrite in similar conditions. Aside from the capacity of diazenium diolates (SPER/NO and DEA/NO) to release ^·NO spontaneously, converting 5-HT exclusively to 4-nitroso-5-HT, all other ^·NO donors must undergo redox reactions to produce ^·NO. S-nitrosoglutathione (GSNO) and sodium nitroprus-side (SNP) modified 5-HT only in the presence of Cu²⁺, GSNO yielding 6 times more 4-nitroso-5-HT than SNP. Furthermore, in the presence of Cu⁺, the yield of ^·NO-release from GSNO was 45%. The molsidomine metabolite (SIN-1), which was presumed to release both ^·NO and O2/·- at pH 7.4, reacted with 5-HT differently, depending on the presence of reductant or oxidant. Under aerobic conditions, SIN-1 acted predominantly as a 5-HT oxidant and also as a poor ^·NO and peroxynitrite donor (15% yield of ^·NO-release and 14 % yield of peroxynitrite formation). The strong oxidant Cu²⁺, even in the presence of air oxygen, accelerated oxidation and increased ^·NO release from SIN-1 up to 86%. Only a small part of SIN-1 gave simultaneously ^·NO and O2/·- able to link together to give peroxynitrite, but other oxidants could enhance ^·NO release from SIN-1.     

Peroxynitrite oxidizes erythrocyte membrane band 3 protein and diminishes its anion transport capacity

We describe an altered membrane band 3 protein-mediated anion transport in erythrocytes exposed to peroxynitrite, and relate the loss of anion transport to cell damage and to band 3 oxidative modifications. We found that peroxynitrite down-regulate anion transport in a dose dependent relation (100–300 μmoles/l). Hemoglobin oxidation was found at all peroxynitrite concentrations studied. A dose-dependent band 3 protein crosslinking and tyrosine nitration were also observed. Band 3 protein modifications were concomitant with a decrease in transport activity. ( ? )-Epicatechin avoids band 3 protein nitration but barely affects its transport capacity, suggesting that both processes are unrelated. N-acetyl cysteine partially reverted the loss of band 3 transport capacity. It is concluded that peroxynitrite promotes a decrease in anion transport that is partially due to the reversible oxidation of band 3 cysteine residues. Additionally, band 3 tyrosine nitration seems not to be relevant for the loss of its anion transport capacity.     

(13Z)- and (9Z)-lycopene isomers are major intermediates in the oxidative degradation of lycopene by cigarette smoke and Sin-1

Abstract

The breakdown of lycopene in the presence of reactive oxygen and reactive nitrogen species has been studied in order to identify key in vitro intermediates. These compounds may in turn be produced as metabolites in the body and may have significant physiological properties, such as increased antioxidant capacity. We have studied the in vitro degradation of lycopene in solvent, in plasma and in low density lipoprotein, when challenged with freshly generated gaseous cigarette smoke or free radicals generated in situ by S-morpholinosydonimine at 37°C. The emphasis has been to establish the major intermediates and to compare the data with previous studies using different reactants. We have found that (13Z)-lycopene is the major intermediate in both cigarette smoke and S-morpholinosydonimine reactions (representing ≥60% of the converted (all-E)-lycopene at ～50% depletion). Additionally, (9Z)-lycopene and various (all-E) and (Z)-lycopene epoxides were predominant. Notably, (5Z)-lycopene appeared to be the most stable form of lycopene under the stated conditions. Previous theoretical studies of isomer thermodynamics and rotational energy barriers for carbon double bonds fully support the pattern of isomer production and stability. In contrast to β-carotene studies, nitro-derivatives of lycopene could not be detected. In conclusion, (Z)-lycopene production and (5Z)-lycopene stability may help explain elevated (Z)-lycopene in plasma over (Z)-lycopene content in lycopene-containing foods in the diet.     

Consequences of MnSOD interactions with nitric oxide: Nitric oxide dismutation and the generation of peroxynitrite and hydrogen peroxide

The present study demonstrates that manganese superoxide dismutase (MnSOD) (Escherichia coli), binds nitric oxide (^√NO) and stimulates its decay under both anaerobic and aerobic conditions. The results indicate that previously observed MnSOD-catalyzed ^√NO disproportionation (dismutation) into nitrosonium (NO⁺) and nitroxyl (NO^? ) species under anaerobic conditions is also operative in the presence of molecular oxygen. Upon sustained aerobic exposure to ^√NO, MnSOD-derived NO^? species initiate the formation of peroxynitrite (ONOO^? ) leading to enzyme tyrosine nitration, oxidation and (partial) inactivation. The results suggest that both ONOO^? decomposition and ONOO^? -dependent tyrosine residue nitration and oxidation are enhanced by metal centre-mediated catalysis. We show that the generation of ONOO^? is accompanied by the formation of substantial amounts of H₂O₂. MnSOD is a critical mitochondrial antioxidant enzyme, which has been found to undergo tyrosine nitration and inactivation in various pathologies associated with the overproduction of ^√NO. The results of the present study can account for the molecular specificity of MnSOD nitration in vivo. The interaction of ^√NO with MnSOD may represent a novel mechanism by which MnSOD protects the cell from deleterious effects associated with overproduction of ^√NO.     

Bioavailability of metalloporphyrin-based SOD mimics is greatly influenced by a single charge residing on a Mn site

Abstract

In the cell Mn porphyrins (MnPs) likely couple with cellular reductants which results in a drop of total charge from 5+ to 4+ and dramatically increases their lipophilicity by up to three orders of magnitude depending upon the length of alkylpyridyl chains and type of isomer. The effects result from the interplay of solvation, lipophilicit and stericity. Impact of ascorbate on accumulation of MnPs was measured in E. coli and in Balb/C mouse tumours and muscle; for the latter measurements, the LC/ESI-MS/MS method was developed. Accumulation was significantly enhanced when MnPs were co-administered with ascorbate in both prokaryotic and eukaryotic systems. Further, MnTnHex-2-PyP⁵⁺ accumulates 5-fold more in the tumour than in a muscle. Such data increase our understanding of MnPs cellular and sub-cellular accumulation and remarkable in vivo effects. The work is in progress to understand how coupling of MnPs with ascorbate affects their mechanism of action, in particular with respect to cancer therapy.