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.     

Cardiac mitochondrial ATP-sensitive potassium channel is activated by nitric oxide in vitro

Previous observations on the activation of the mitochondrial ATP-sensitive potassium channel (mitoK(ATP)) by nitric oxide (NO) in myocardial preconditioning were based on indirect evidence. In this study, we have investigated the direct effect of NO on the rat cardiac mitoK(ATP) after reconstitution of the inner mitochondrial membranes into lipid bilayers. We found that the mitoK(ATP) was activated by exogenous NO donor S-nitroso-N-acetyl penicillamine or PAPA NONOate. This activation was inhibited by mitoK(ATP) blockers 5-hydroxydecanoate or glibenclamide. Our observations confirm that NO can directly activate the cardiac mitoK(ATP), which may underlie its contribution to myocardial preconditioning.     

Effect of Angeli's salt on the glutamate/glutamine cycle activity and on glutamate excitotoxicity in the hamster retina

Glutamate is the main excitatory neurotransmitter in the retina, but it is toxic when present in excessive amounts. It is well known that NO is involved in glutamate excitotoxicity, but information regarding the possibility that NO-related species could reciprocally affect glutamate synaptic levels was not previously provided. The dependence of glutamatergic neurons upon glia via the glutamate/glutamine cycle to provide the precursor for neurotransmitter glutamate is well established. The aim of the present work was to comparatively analyze the effect of nitroxyl and NO on the retinal glutamate/glutamine cycle in vitro activity. For this purpose, Angeli's salt (AS) and diethylamine NONOate (DEA/NO) were used as nitroxyl and NO donor, respectively. AS and DEA/NO significantly decreased retinal l-glutamate uptake and glutamine synthetase activity, but only AS decreased l-glutamine influx. Dithiothreitol prevented all the effects of AS and DEA/NO. The intravitreal injection of DEA/NO (but not AS) or a supraphysiological concentration of glutamate induced retinal histological alterations. Although AS could increase glutamate synaptic concentration in vitro, the histological alterations induced by glutamate were abrogated by AS. These results suggest that nitroxyl could regulate the hamster retinal glutamatergic pathway by acting through differential mechanisms at pre- and postsynaptic level.     

Discriminative EPR detection of NO and HNO by encapsulated nitronyl nitroxides

Abstract

Nitric oxide, ^?NO, is one of the most important molecules in the biochemistry of living organisms. By contrast, nitroxyl, NO^?, one-electron reduced analog of ^?NO which exists at physiological conditions in its protonated form, HNO, has been relatively overlooked. Recent data show that HNO might be produced endogenously and display unique biological effects. However, there is a lack of specific and quantitative methods of detection of endogenous HNO production. Here we present a new method for discriminative ^?NO and HNO detection by nitronyl nitroxides (NNs) using electron paramagnetic resonance (EPR). It was found that NNs react with ^?NO and HNO with similar rate constants of about 10⁴ M^{? 1}s^{? 1} but yield different products: imino nitroxides and the hydroxylamine of imino nitroxides, correspondingly. An EPR approach for discriminative ^?NO and HNO detection using liposome-encapsulated NNs was developed. The membrane barrier of liposomes protects NNs against reduction in biological systems while is permeable to both analytes, ^?NO and HNO. The sensitivity of this approach for the detection of the rates of ^?NO/HNO generation is about 1 nM/s. The application of encapsulated NNs for real-time discriminative ^?NO/HNO detection might become a valuable tool in nitric oxide-related studies.     

Giardia lamblia encodes a functional flavohemoglobin

Giardia lamblia is a pathogenic protist that infects the small intestine of mammals. As a facultative anaerobe, Giardia obtains all of its energy by substrate-level phosphorylation, lacks a functioning respiratory chain, and is not thought to require heme. However, sequencing of the G. lamblia genome has identified several putative heme proteins, one of which shares high sequence similarity to flavohemoglobins found in bacteria and some single-celled eukaryotes. We have cloned and characterized the functional properties of the G. lamblia flavohemoglobin. The protein is monomeric, binds heme and flavin adenine dinucleotide, and exhibits similar behavior to known flavohemoglobins, including NADH and NADPH oxidase activity, which is stimulated by addition of the nitric oxide donor DEA/NO. Based on its structural and functional properties, the likely role of this protein is to protect Giardia against oxygen, nitric oxide, or both. The presence of a Giardia gene encoding a functional heme protein raises questions on how this organism acquires the heme cofactor, which hitherto have been unexplored.     

A novel ATP-generating machinery to counter nitrosative stress is mediated by substrate-level phosphorylation

Background

It is well-known that elevated amounts of nitric oxide and other reactive nitrogen species (RNS) impact negatively on the tricarboxylic acid (TCA) cycle and oxidative phosphorylation. These perturbations severely compromise O₂-dependent energy production. While bacteria are known to adapt to RNS, a key tool employed by macrophages to combat infections, the exact mechanisms are unknown.

Methods

The bacterium was cultured in a defined mineral medium and cell-free extracts obtained at the same growth phase were utilized for various biochemical studies Blue native polyacrylamide gel electrophoresis followed by in-gel activity assays, high performance liquid chromatography and co-immunoprecipitaton are applied to investigate the effects of RNS on the model microbe Pseudomonas fluorescens.

Results

Citrate is channeled away from the tricarboxylic acid cycle using a novel metabolon consisting of citrate lyase (CL), phosphoenolpyruvate carboxylase (PEPC) and pyruvate phosphate dikinase (PPDK). This metabolic engine comprising three disparate enzymes appears to transiently assemble as a supercomplex aimed at ATP synthesis. The up-regulation in the activities of adenylate kinase (AK) and nucleoside diphosphate kinase (NDPK) ensured the efficacy of this ATP-making machine.

Conclusion

Microbes may escape the effects of nitrosative stress by re-engineering metabolic networks in order to generate and store ATP anaerobically when the electron transport chain is defective.

General significance

The molecular configuration described herein provides further understanding of how metabolism plays a key role in the adaptation to nitrosative stress and reveals novel targets that will inform the development of antimicrobial agents to counter RNS-resistant pathogens.     

Nitric oxide modulates the expression of endothelial cell adhesion molecules involved in angiogenesis and leukocyte recruitment

Tumor angiogenesis and immune response have in common to be cell recognition mechanisms, which are based on specific adhesion molecules and dependent on nitric oxide (NO^•). The aim of the present study is to deepen the mechanisms of angiogenesis and inflammation regulation by NO^• to find out the molecular regulation processes that govern endothelial cell permeability and leukocyte transmigration.Effects of NO^•, either exogenous or produced in hypoxic conditions, were studied on microvascular endothelial cells from skin and lymph node because of their strong involvement in melanoma progression. We found that NO^• down-regulation of pseudo-vessel formation was linked to a decrease in endothelial cell ability to adhere to each other which can be explain, in part, by the inhibition of PECAM-1/CD31 expression. On the other hand, NO^• was shown to be able to decrease leukocyte adhesion on an endothelial monolayer, performed either in static or in rolling conditions, and to modulate differentially CD34, ICAM-1/CD54, ICAM-2/CD102 and VCAM-1/CD106 expression.In conclusion, during angiogenesis and leukocyte recruitment, NO^• regulates cell interactions by controlling adhesion molecule expression and subsequently cell adhesion. Moreover, each endothelial cell type presents its own organospecific response to NO^•, reflecting the functions of the tissue they originate from.     

Superoxide determines nitric oxide uptake rate by vascular smooth muscle cells

Nitric oxide (NO) is generated in endothelial cells, which diffuses to vascular smooth muscle cells (SMCs), activates soluble guanylyl cyclase, and leads to blood vessel dilation. However, this scenario does not explain how SMCs are capable of competing with erythrocytic hemoglobin for NO in vivo. Here, we have developed a competition experiment to determine the NO uptake rate by SMCs and demonstrated that the SMC-NO uptake rate is positively dependent on intracellular superoxide levels. In addition, the superoxide-elicited NO influx is able to enhance cGMP production in SMCs. Our findings imply that vascular SMCs, in vivo, may use superoxide to compete with erythrocytic hemoglobin for NO and obtain the NO bioactivity.     

Detection of Superoxide and Peroxynitrite in Model Systems and Mitochondria by the Luminol Analogue L-012

In the present study we investigated the specificity and sensitivity of the chemiluminescence (CL) dye and luminol analogue 8-amino-5-chloro-7-phenylpyrido[3,4-d]pyridazine-1,4-(2H,3H) dione (L-012) to detect reactive oxygen species (ROS) such as superoxide, peroxynitrite and hydrogen peroxide in cell free systems as well as in isolated mitochondria. The results obtained by L-012 were compared with other CL substances such as luminol, lucigenin, coelenterazine and the fluorescence dye dihydroethidine. The results indicate that the L-012-derived chemiluminescence induced by superoxide from hypoxanthine/xanthine oxidase (HX/XO) or by 3-morpholino sydnonimine (SIN-1)-derived peroxynitrite largely depends on the incubation time. Irrespective of the experimental conditions, L-012-derived CL in response to HX/XO and SIN-1 was 10–100 fold higher than with other CL dyes tested. In a cell-free system, authentic peroxynitrite yielded a higher L-012-enhanced CL signal than authentic superoxide and the superoxide-induced signal in cell-free as well as isolated mitochondria increased in the presence of equimolar concentrations of nitrogen monoxide (NO). The superoxide signal/background ratio detected by L-012-enhanced CL in isolated mitochondria with blocked respiration was 7 fold higher than that obtained by the superoxide sensitive fluorescence dye dihydroethidine. We conclude that L-012-derived CL may provide a sensitive and reliable tool to detect superoxide and peroxynitrite formation in mitochondrial suspensions.     

Biphasic effect of nitric oxide on the cardiac voltage-dependent anion channel

Nitric oxide (NO) effects on the cardiac mitochondrial voltage-dependent anion channel (VDAC) are unknown. The effects of exogenous NO on VDAC purified from rat hearts were investigated in this study. When incorporated into lipid bilayers, VDAC was inhibited directly by an NO donor, PAPA NONOate, in a concentration-dependent biphasic manner. This was prevented by an NO scavenger, 2-phenyl-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide. The effect paralleled that of NO in delaying the opening of the mitochondrial permeability transition (PT) pore. These biphasic effects on the cardiac VDAC and the mitochondrial PT pore reveal a tandem impact of NO on the two mitochondrial entities.