Detection of basal NO production in rat tissues using iron–dithiocarbamate complexes

We probe endogenous NO production in WKY rats by trapping NO with iron–dithiocarbamate complexes. The aim was to detect non-stimulated NO production in small organs like kidneys of juvenile rats. The yields of mononitrosyl Fe–dithiocarbamate complexes are small and difficult to quantify in the presence of strong contaminating signals from Cu²⁺–DETC complexes. We evaluate four methods to improve the detection of mononitrosyl Fe–dithiocarbamate adducts: progressive microwave saturation, tissue perfusion, spectral subtraction, and finally, reduction of the tissue with sodium dithionite. While the first three were only moderately useful, reduction was very helpful for quantification of the mononitrosyl Fe–dithiocarbamate yield. The increase in sensitivity allows the detection of non-stimulated NO release in small organs of juvenile rats.     

Nitrite protonation as a necessary stage in the generation of nitric oxide from nitrite in biological systems

The yields of nitric oxide from 1 mM and 10 mM sodium dithionite in 5 or 150 mM solutions of HEPES buffer (pH 7.4) differed by a factor of 200. Dithionite acted as both a strong reducing agent and an agent responsible for local acidification of the solutions without significant changes in pH. The concentration of nitric oxide was estimated by electron paramagnetic resonance (EPR) by monitoring its incorporation into water-soluble complexes of Fe with N-methyl-D-glucamine dithiocarbamate (MGD), which resulted in the formation of EPR-detectable mononitrosyl complexes of iron. Ten seconds after dithionite addition, the concentration of mononitrosyl iron complexes reached 2 μM, whereas it did not become greater than 0.01 μM in 5 mM HEPES buffer. It has been suggested that this difference results from a longer lifetime of a localized decrease in pH in a weaker buffer solution. This time could be long enough for the protonation of some nitrite molecules. Nitrous acid thus formed decomposed to nitric oxide. A difference in nitric oxide formation from nitrite in weak and strong buffer solutions was also observed in the presence of hemoglobin (0.3 mM) or serum albumin (0.5 mM). However, in the weak buffer the nitric oxide yield was only three-four times greater than in the strong buffer. An increase in the nitric oxide yield from nitrite was observed in solutions containing both proteins. A significant amount of nitric oxide from nitrite was formed in mouse liver preparation subjected to freezing and thawing procedure followed by slurrying in 150 mM HEPES buffer (pH 7.4) and dithionite addition (10 mM). We suggest that the presence of zones with lowered pH values in cells and tissues may be responsible for the predominance of the acidic mechanism of nitric oxide formation from nitrite. The contribution of nitric oxide formation from nitrite catalyzed by heme-containing proteins as nitrite reductases may be minor under these conditions.     

Multimodality imaging of nitric oxide and nitric oxide synthases

Nitric oxide (NO) and NO synthases (NOSs) are crucial factors in many pathophysiological processes such as inflammation, vascular/neurological function, and many types of cancer. Noninvasive imaging of NO or NOS can provide new insights in understanding these diseases and facilitate the development of novel therapeutic strategies. In this review, we will summarize the current state-of-the-art multimodality imaging in detecting NO and NOSs, including optical (fluorescence, chemiluminescence, and bioluminescence), electron paramagnetic resonance (EPR), magnetic resonance (MR), and positron emission tomography (PET). With continued effort over the last several years, these noninvasive imaging techniques can now reveal the biodistribution of NO or NOS in living subjects with high fidelity which will greatly facilitate scientists/clinicians in the development of new drugs and/or patient management. Lastly, we will also discuss future directions/applications of NO/NOS imaging. Successful development of novel NO/NOS imaging agents with optimal in vivo stability and desirable pharmacokinetics for clinical translation will enable the maximum benefit in patient management.     

Detection of nitric oxide from pig trachea by a fluorescence method

A nitronyl nitroxide radical covalently linked to an organic fluorophore, pyrene, was used to detect nitric oxide (NO) from freshly excited tissues. This approach is based on the phenomenon of the intramolecular fluorescence quenching of the fluorophore fragment by the nitroxide. The pyrene-nitronyl (PN) reacts with NO to yield a pyrene-imino nitroxide radical (PI) and NO(2). Conversion of PN to PI is accompanied by changes in the electron paramagnetic resonance (EPR) spectrum from a five-line pattern (two equivalent N nuclei) into a seven-line pattern (two nonequivalent N nuclei). The transformation of the EPR signal is accompanied by an increase in the fluorescence intensity since the imino nitroxide radical is a weaker quencher than the nitronyl one. The results indicate that the fluorescence measurements enable detection of nanomolar concentrations of NO compared to a sensitivity threshold of only several micromolar for the EPR technique. The method was applied to the determination of NO and S-nitroso compounds in tissue from pig trachea epithelia. The measured basal flux of S-nitroso compounds obtained from the tissues was about 1.2 nmol/g x min, and NO-synthase stimulated by extracellular adenosine 5'-triphosphate produced NO flux of 0.9 nmol/g x min.     

Estimation of nitric oxide level in vivo by microdialysis with water-soluble iron-N-methyl-d-dithiocarbamate complexes as NO traps: A novel approach to nitric oxide spin trapping in animal tissues

It was found that microdialysis, i.e., passage of aqueous solutions of iron-N-methyl-d-glucamine dithiocarbamate complexes through dialysis fibers implanted into heart, kidney and liver tissues of narcotized rats, was accompanied by effective binding of the complexes to nitric oxide from interstitial fluid. The walls of dialysis fibers used in this study were permeable for compounds with molecular weight not exceeding 5 kDa. The dialyzate samples collected every 20 min and containing diamagnetic nitrosyl Fe³⁺-MGD adducts were reduced to the paramagnetic state with sodium dithionite; their concentration was measured by the EPR method. The basic level of the adducts, which represented mononitrosyl iron complexes with MGD (MNIC–MGD), in the dialyzate samples of all tested organs were similar (1 μМ). Treatment of animals with the water-soluble nitroglycerine analog Isoket or a low-molecular dinitrosyl iron thiosulfate complex as a NO donor increased the concentration of MNIC–MGD with going out into a plateau. The novel approach allows determination of nitric oxide levels in tissue interstitial fluid from concentration of MNIC–MGD formed during microdialysis.     

Spin trapping agent,phenyl N-tert-butylnitrone,reduces nitric oxide production in the rat brain during experimental meningitis

Phenyl N-tert-butylnitrone (PBN) is a spin trapping agent previously shown to exert a neuroprotective effect in infant rat brain during bacterial meningitis. In the present study, we investigated the effect of systemic PBN administration on nitric oxide (NO) production in a rat model of experimental meningitis induced by lipopolysaccharide (LPS). We assessed the NO concentration in rat brain tissues with an electron paramagnetic resonance (EPR) NO trapping technique. In this model, rats receiving intracisternal LPS administration showed symptoms of meningitis and cerebrospinal fluid (CSF) pleocytosis. The time course study indicated that the concentration of NO in the brain reached the maximum level 8.5h after injection of LPS, and returned to the control level 24 h after the injection. When various doses of PBN (125–400 mg/kg) were injected intraperitoneally 30 min prior to LPS, NO production in the brain was reduced with increasing PBN dose (250 mg/kg suppressed 80% at 8.5h after LPS injection), and white blood cells (WBC) in CSF were significantly decreased. We concluded that reduction of NO generation during bacterial meningitis contributes to the neuroprotective effect of PBN in addition to its possible direct scavenging of reactive oxygen intermediate (ROI).     

Redox properties of iron–dithiocarbamates and their nitrosyl derivatives: implications for their use as traps of nitric oxide in biological systems

While the Fe²⁺–dithiocarbamate complexes have been commonly used as NO traps to estimate NO production in biological systems, these complexes can undergo complex redox chemistry. Characterization of this redox chemistry is of critical importance for the use of this method as a quantitative assay of NO generation. We observe that the commonly used Fe²⁺ complexes of N-methyl-D-glucamine dithiocarbamate (MGD) or diethyldithiocarbamate (DETC) are rapidly oxidized under aerobic conditions to form Fe³⁺ complexes. Following exposure to NO, diamagnetic NO–Fe³⁺ complexes are formed as demonstrated by the optical, electron paramagnetic resonance and gamma-resonance spectroscopy, chemiluminescence and electrochemical methods. Under anaerobic conditions the aqueous NO–Fe³⁺–MGD and lipid soluble NO–Fe²⁺–DETC complexes gradually self transform by reductive nitrosylation into paramagnetic NO–Fe²⁺–MGD complexes with yield of up to 50% and the balance is converted to Fe³⁺–MGD and nitrite. In dimethylsulfoxide this process is greatly accelerated. More efficient transformation of NO–Fe³⁺–MGD into NO–Fe²⁺–MGD (60–90% levels) was observed after addition of reducing equivalents such as ascorbate, hydroquinone or cysteine or with addition of excess Fe²⁺–MGD. With isotope labeling of the NO–Fe³⁺–MGD with ⁵⁷Fe, it was shown that these complexes donate NO to Fe²⁺–MGD. NO–Fe³⁺–MGD complexes were also formed by reversible oxidation of NO–Fe²⁺–MGD in air. The stability of NO–Fe³⁺–MGD and NO–Fe²⁺–MGD complexes increased with increasing the ratio of MGD to Fe. Thus, the iron–dithiocarbamate complexes and their NO derivatives exhibit complex redox chemistry that should be considered in their application for detection of NO in biological systems.     

Nitric oxide,a biological effector

Nitric oxide has been used for more than 20 years as an electron paramagnetic resonance probe of oxygen binding sites in oxygen-carriers and oxygen-metabolizing metalloenzymes. The high reactivity of NO with oxygen and the superoxide anion and its high affinity for metalloproteins led biochemists to consider NO as a highly toxic compound for a living cell. This assertion has recently been reconsidered following a number of discoveries of great significance: the finding of the activation of guanylate cyclase by NO, the recognition that NO is the precursor of nitrite and nitrate ions released in the activation of macrophages by endotoxin and cytokities, evidence that NO is an Endothelium-Derived Relaxing Factor, and the discovery of NO-biosynthesis from l-arginine, a pathway common in various biological cell-to-cell signalling processes. It is now admitted that NO plays a key bioregulatory role within mammalian cells, between cells of different types and in the host defence response. In the present review we have attempted to give a general picture of what is known of the chemical, physical, biochemical and biophysical properties of NO among the various nitrogen oxides. We have focussed on the structural information that can be obtained by electron paramagnetic resonance spectroscopy of nitrosyl-metalloprotein complexes. Finally we have shown how molecular targets of nitric oxide can be characterized, within whole cells, by electron paramagnetic resonance spectroscopy.Abbreviations BCG Bacillus Calmette-Guérin - CcO cytochrome c oxidase - cGMP cyclic GMP - Cyt. cd ₁ cytochrome cd ₁ or nitrite reductase from Pseudomonas aeruginosa - DPG 2,3-diphosphoglycerate - EDRF endothelium-derived relaxing factor - EPR electron paramagnetic resonance - GC guanylate cyclase - GMN, GDN, GTN glyceryl mono-, di-, trinitrate - GSH, GSSG reduced and oxidized glutathione - GSH-ST glutathione S-transferase - Hb hemoglobin - Hb³⁺ ferrihemoglobin - IFN- interferon gamma - IHP inositol hexaphosphate - LPS lipopolysaccharide from E. coli - Mb myoglobin - NMMA N^G-monomethyl-l-arginine - P-450 cytochrome P-450 - P-420 cytochrome P-420 - P1, P2, P3, P7 isoperoxidases from turnip - SHF superhyperfine structure - TDO tryptophan 2,3-dioxygenase from Pseudomonas fuorescens - TNF tumor necrosis factor This review is based on a talk given by YH at the first European Meeting of Groupe d'Application de la Résonance Paramagnétique Electronique in Lyon, 10–11 January 1990. It has been up-dated to December 1990 Offprint requests to: Y. Henry     

Membrane penetration of nitric oxide and its donor S-nitroso-N-acetylpenicillamine: a spin-label electron paramagnetic resonance spectroscopic study

S-nitroso-N-acetylpenicillamine (SNAP) is a pharmacological agent with diverse biological effects that are mainly attributable to its favorable characteristics as a nitric oxide (NO)-evolving agent. It is found that SNAP incorporates readily into dimyristoyl phosphatidylcholine (DMPC) bilayer membranes; and an approximate penetration profile was obtained from the depth dependence of the perturbation that it exerts on spin-labeled lipid chains. The profile of SNAP locates it deep in the hydrophobic core of both fluid- and gel-phase membranes. The spin relaxation enhancement of spin-labeled phospholipids with nitroxide group located at different depths in DMPC membranes was determined for nitric oxide (NO) and molecular oxygen (O₂), at close to atomic spatial resolution. The relaxation enhancement, which is proportional to the corresponding vertical membrane profile of the concentration-diffusion product, was measured in the gel and fluid phases of the lipid bilayer. No significant membrane penetration was observed in the gel phase for the two water-dissolved gases. In the fluid phase, the transmembrane profiles of NO and O₂ are similar and could be well described by a sigmoidal function with a maximum in the center of the bilayer, but that of NO is less steep and is shifted toward the center of the membrane, relative to that of O₂. These differences can be attributed mainly to the difference in hydrophobicity between the two gases and the presence of the donor in the NO experiments. The biological implications of the above results are discussed.     

Reduction of nitric oxide in bacterial nitric oxide reductase—a theoretical model study

The mechanism of the nitric oxide reduction in a bacterial nitric oxide reductase (NOR) has been investigated in two model systems of the heme-b₃-Fe_B active site using density functional theory (B3LYP). A model with an octahedral coordination of the non-heme Fe_B consisting of three histidines, one glutamate and one water molecule gave an energetically feasible reaction mechanism. A tetrahedral coordination of the non-heme iron, corresponding to the one of Cu_B in cytochrome oxidase, gave several very high barriers which makes this type of coordination unlikely. The first nitric oxide coordinates to heme b₃ and is partly reduced to a more nitroxyl anion character, which activates it toward an attack from the second NO. The product in this reaction step is a hyponitrite dianion coordinating in between the two irons. Cleaving an NO bond in this intermediate forms an Fe_B (IV)O and nitrous oxide, and this is the rate determining step in the reaction mechanism. In the model with an octahedral coordination of Fe_B the intrinsic barrier of this step is 16.3 kcal/mol, which is in good agreement with the experimental value of 15.9 kcal/mol. However, the total barrier is 21.3 kcal/mol, mainly due to the endergonic reduction of heme b₃ taken from experimental reduction potentials. After nitrous oxide has left the active site the ferrylic Fe_B will form a μ-oxo bridge to heme b₃ in a reaction step exergonic by 45.3 kcal/mol. The formation of a quite stable μ-oxo bridge between heme b₃ and Fe_B is in agreement with this intermediate being the experimentally observed resting state in oxidized NOR. The formation of a ferrylic non-heme Fe_B in the proposed reaction mechanism could be one reason for having an iron as the non-heme metal ion in NOR instead of a Cu as in cytochrome oxidase.     

Arginine pathways and the inflammatory response: Interregulation of nitric oxide and polyamines: Review article

Summary. An early response to an acute inflammatory insult, such as wound healing or experimental glomerulonephritis, is the conversion of arginine to the cytostatic molecule nitric oxide (NO). This anti-bacterial phase is followed by the conversion of arginine to ornithine, which is the precursor for the pro-proliferative polyamines as well as proline for the production of extracellular matrix. This latter, pro-growth phase constitutes a repair phase response. The temporal switch of arginine as a substrate for the cytostatic iNOS/NO axis to the pro-growth arginase/ ornithine/polyamine and proline axis is subject to regulation by inflammatory cytokines as well as interregulation by the arginine metabolites themselves. Arginine is also the precursor for another biogenic amine, agmatine. Here we describe the capacity of these three arginine pathways to interregulate, and propose a model whereby agmatine has the potential to serve in the coordination of the early and repair phase pathways of arginine in the inflammatory response by acting as a gating mechanism at the transition from the iNOS/NO axis to the arginase/ODC/polyamine axis. Due to the pathophysiologic and therapeutic potential, we will further examine the antiproliferative effects of agmatine on the polyamine pathway.     

Application of electron spin resonance spin-trapping technique for evaluation of substrates and inhibitors of nitric oxide synthase

The electron spin resonance (ESR) spin-trapping technique coupled with iron-dithiocarbamate complexes is one of the most specific methods for nitric oxide (NO) detection. In this study, we applied this method for the evaluation of the substrate and the inhibitors of NO synthase (NOS). A three-line ESR signal was detected from the mixture of inducible NOS (iNOS), l-arginine (Arg), nicotinamide adenine dinucleotide phosphate (NADPH), tetrahydrobiopterin, dithiothreitol, and Fe(2+)-N-(dithiocarboxy) sarcosine (DTCS-Fe), and the signal intensity increased time-dependently. The signal was not observed by excluding either Arg or NADPH, and it was decreased by the addition of hemoglobin, which is an NO scavenger, and N(G)-monomethyl-l-arginine (l-NMMA), N(G)-nitro-l-arginine (l-NAME), and aminoguanidine (AG), which are NOS inhibitors, depending on the concentration. In comparison with l-NAME and AG, l-NMMA strongly inhibited iNOS activity. By using this method, the K(m) value of Arg and the K(i) value of l-NMMA for iNOS were determined to be 12.6 and 6.1muM, respectively. These values are consistent with the reported values measured by the oxyhemoglobin and citrulline assays. These results suggest that the ESR spin-trapping technique coupled with the iron-dithiocarbamate complex can be applied for the evaluation of substrates and inhibitors of NOS, and it would be a powerful tool due to its simplicity and high specificity to NO.     

Analysis of the effects of nitric oxide and oxygen on nitric oxide production by macrophages

The interactions between NO and O(2) in activated macrophages were analysed by incorporating previous cell culture and enzyme kinetic results into a novel reaction-diffusion model for plate cultures. The kinetic factors considered were: (i) the effect of O(2) on NO production by inducible NO synthase (iNOS); (ii) the effect of NO on NO synthesis by iNOS; (iii) the effect of NO on respiratory and other O(2) consumption; and (iv) the effects of NO and O(2) on NO consumption by a possible NO dioxygenase (NOD). Published data obtained by varying the liquid depth in macrophage cultures provided a revealing test of the model, because varying the depth should perturb both the O(2) and the NO concentrations at the level of the cells. The model predicted that the rate of NO(2)(-) production should be nearly constant, and that the net rate of NO production should decline sharply with increases in liquid depth, in excellent agreement with the experimental findings. In further agreement with available results for macrophage cultures, the model predicted that net NO synthesis should be more sensitive to liquid depth than to the O(2) concentration in the headspace. The main reason for the decrease in NO production with increasing liquid depth was the modulation of NO synthesis by NO, with O(2) availability playing only a minor role. The model suggests that it is the ability of iNOS to consume NO, as well as to synthesize it, that creates very sensitive feedback control, setting an upper bound on the NO concentration of approximately 1 microM. The effect of NO consumption by other possible pathways (e.g., NOD) would be similar to that of iNOS, in that it would help limit net NO production. The O(2) utilized during enzymatic NO consumption is predicted to make the O(2) demands of activated macrophages much larger than those of unactivated ones (where iNOS is absent); this remains to be tested experimentally.     

Direct chemiluminescence detection of nitric oxide in aqueous solutions using the natural nitric oxide target soluble guanylyl cyclase

Nitric oxide (NO) is a free radical involved in many physiological processes including regulation of blood pressure, immune response, and neurotransmission. However, the measurement of extremely low, in some cases subnanomolar, physiological concentrations of nitric oxide presents an analytical challenge. The purpose of this methods article is to introduce a new highly sensitive chemiluminescence approach to direct NO detection in aqueous solutions using a natural nitric oxide target, soluble guanylyl cyclase (sGC), which catalyzes the conversion of guanosine triphosphate to guanosine 3′,5′-cyclic monophosphate and inorganic pyrophosphate. The suggested enzymatic assay uses the fact that the rate of the reaction increases by about 200 times when NO binds with sGC and, in so doing, provides a sensor for nitric oxide. Luminescence detection of the above reaction is accomplished by converting inorganic pyrophosphate into ATP with the help of ATP sulfurylase followed by light emission from the ATP-dependent luciferin–luciferase reaction. Detailed protocols for NO quantification in aqueous samples are provided. The examples of applications include measurement of NO generated by a nitric oxide donor (PAPA-NONOate), nitric oxide synthase, and NO gas dissolved in buffer. The method allows for the measurement of NO concentrations in the nanomolar range and NO generation rates as low as 100 pM/min.     

Electron paramagnetic resonance imaging of nitric oxide organ distribution in lipopolysuccaride treated mice

The recent development of electron paramagnetic resonance (EPR) permits its application for in vivo studies of nitric oxide (NO). In this study, we tried to obtain 3D EPR images of endogenous NO in the abdominal organs of lipopolysuccaride (LPS) treated mice. Male ICR mice, each weighing about 30 g, received 10 mg/kg of LPS intraperitoneally. Six hours later, a spin trapping reagent comprised of iron and an N-dithiocarboxy sarcosine complex (Fe(DTCS)₂, Fe 200 mM, DTCS/Fe = 3) were injected subcutaneously. Two hours after this treatment, the mice were fixed in a plastic holder and set in the EPR system, equipped with a loop-gap resonator and a 1 GHz microwave. NO was detected as an NO-Fe(DTCS)₂ complex, which had a characteristic 3-line EPR spectrum. NO-Fe(DTCS)₂ complexes in organ homogenates were also measured using a conventional X-band EPR system. NO-Fe(DTCS)₂ spectra were obtained in the upper abdominal area of LPS treated mice at 8 h after the LPS injection. 3D EPR tiled and stereoscopic images of the NO distribution in the hepatic and renal areas were obtained at the same time. The NO-Fe(DTCS)₂ distribution in abdominal organs was confirmed in each organ homogenate using conventional X-band EPR. This is the first known EPR image of NO in live mice kidneys.     

Dietary nitrite restores NO homeostasis and is cardioprotective in endothelial nitric oxide synthase-deficient mice

Endothelial production of nitric oxide (NO) is critical for vascular homeostasis. Nitrite and nitrate are formed endogenously by the stepwise oxidation of NO and have, for years, been regarded as inactive degradation products. As a result, both anions are routinely used as surrogate markers of NO production, with nitrite as a more sensitive marker. However, both nitrite and nitrate are derived from dietary sources. We sought to determine how exogenous nitrite affects steady-state concentrations of NO metabolites thought to originate from nitric oxide synthase (NOS)-derived NO as well as blood pressure and myocardial ischemia-reperfusion (I/R) injury. Mice deficient in endothelial nitric oxide synthase (eNOS-/-) demonstrated decreased blood and tissue nitrite, nitrate, and nitroso proteins, which were further reduced by low-nitrite (NOx) diet for 1 week. Nitrite supplementation (50 mg/L) in the drinking water for 1 week restored NO homeostasis in eNOS-/- mice and protected against I/R injury. Nitrite failed to alter heart rate or mean arterial blood pressure at the protective dose. These data demonstrate the significant influence of dietary nitrite intake on the maintenance of steady-state NO levels. Dietary nitrite and nitrate may serve as essential nutrients for optimal cardiovascular health and may provide a novel prevention/treatment modality for disease associated with NO insufficiency.     

Reaction of nitric oxide with iron bleomycin bound to DNA: properties of the nitrosyl adduct and its reaction with O2

During the ESR spectroscopic titration of nitrosyl-iron bleomycin, ON---Fe(II)Blm, with DNA, its metal domain undergoes a change in environment as the DNA base pair to drug ratio increases to 50 to 1. The ¹⁵N---O stretching frequency of ON---Fe(II)Blm occurs at 1589 cm⁻¹, similar to that for nitrosyl hemoglobin and myoglobin. Upon addition of DNA (3 base pairs per drug molecule), this vibration is substantially broadened. Injection of O₂ into a solution of ON---Fe(II)BlmDNA converts the ESR signal of the nitrosyl species to low spin Fe(III) BlmDNA. NO is largely oxidized to NO₂⁻. The combination of these products suggests that the initial reaction of ON---Fe(II)Blm with O₂ generates Fe(III)Blm and peroxynitrite, O₂NO⁻. If peroxynitrite is formed in the reaction, it does not cause detectable DNA damage. The structural integrity of a supercoiled DNA plasmid, pBR322, is not compromised and no base propenals are produced during this reaction.