Dinitrosyl iron complexes with thiolate ligands: Physico-chemistry,biochemistry and physiology

Some present-day concepts on the origin and functional activities of dinitrosyl iron complexes (DNIC) with thiolate ligands are considered. Nitric oxide (NO) including to DNIC increases its stability and ensures effective targeting of NO to organs and tissues. DNIC have a square–planar structure; unpaired electron is localized on the d_z2 orbital of the d⁷ iron atom. The formula of DNIC appears as {(RS^?)₂Fe⁺(NO⁺)₂….(^?SR)₂}^?; electron spin is S = 1/2. Conversion of an originally diamagnetic group, Fe²⁺(NO)₂ with electron configuration d⁸, into a paramagnetic Fe⁺(NO⁺)₂ group is a result of disproportionation of NO ligands and substitution of newly generated NO^? for NO. The nitrosonium ions present in DNIC impart to them high nitrosylating activity, e.g., ability to induce S-nitrosylation of thiols. The ability of S-nitrosothiols to form DNIC in a direct reaction with bivalent iron is a prerequisite to effective mutual conversions of DNIC and S-nitrosothiols. In this work, I consider some mechanisms of destructive effects of low-molecular DNIC on active centers of iron–sulfur proteins, ability of DNIC to express certain genes, to activate guanylate cyclase, to exert hypotensive, vasodilator effects, to inhibit platelet aggregation, to accelerate wound healing and to produce potent erective action. Recently a stabilized powder-like polymeric composition based on dimeric glutathione DNIC the water-soluble polymer in which was used as a filling agent was designed. The advantages of this stable DNIC-glutathione preparation include their ability to retain their physico-chemical and functional activities within at least one year. At present, the preparation undergo testing as a base for the design of a wide variety of broad-spectrum drugs.     

Dinitrosyl iron complexes with cysteine suppress the development of experimental endometriosis in rats

Administration of dinitrosyl iron complexes (DNIC) with cysteine suppressed the development of experimental (surgically induced) endometriosis in rats: the mean size of endometrioma was 1.85 times smaller if 0.5 mL of a 5 mM aqueous solution of DNIC had been injected daily for 10 days. It is supposed that NO molecules and nitrosonium ions (NO⁺), released from DNIC rapidly decomposed in the organism, prove cytotoxic for endometrioid tissue.     

Inhibition of platelet aggregation by dinitrosyl iron complexes with low molecular weight ligands

The dinitrosyl iron complexes (DNIC) with thiosulphate, cysteine or phosphate were shown to inhibit in vitro (in citrate plasma) the human platelet aggregation induced by ADP, collagen or adrenaline. This effect cannot be explained by the toxic action of DNIC on the platelet membrane, since DNIC-pretreated platelets are capable of aggregating under the action of 10(-8) M/ml of phorbol ester, which is known to cause direct activation of protein kinase C. The antiaggregatory activity of DNIC exceeds that of Na-nitroprusside and seems to be due to nitric oxide capable to activate guanylate cyclase of platelets. Using the EPR method, it was shown that addition of DNIC to platelet-enriched plasma results in a rapid transfer of Fe(NO)2 groups to the coupled RS(-)-groups proteins of plasma and, apparently, of platelet membrane proteins. These protein DNIC seem to be the source of NO which inhibits human platelet aggregation.     

Dinitrosyliron complexes are the most abundant nitric oxide-derived cellular adduct: biological parameters of assembly and disappearance

It is well established that nitric oxide (^•NO) reacts with cellular iron and thiols to form dinitrosyliron complexes (DNIC). Little is known, however, regarding their formation and biological fate. Our quantitative measurements reveal that cellular concentrations of DNIC are proportionally the largest of all ^•NO-derived adducts (900 pmol/mg protein, or 45-90 μM). Using murine macrophages (RAW 264.7), we measured the amounts, and kinetics, of DNIC assembly and disappearance from endogenous and exogenous sources of ^•NO in relation to iron and O₂ concentration. Amounts of DNIC were equal to or greater than measured amounts of chelatable iron and depended on the dose and duration of ^•NO exposure. DNIC formation paralleled the upregulation of iNOS and occurred at low physiologic ^•NO concentrations (50-500 nM). Decreasing the O₂ concentration reduced the rate of enzymatic ^•NO synthesis without affecting the amount of DNIC formed. Temporal measurements revealed that DNIC disappeared in an oxygen-independent manner (t_1/2 = 80 min) and remained detectable long after the ^•NO source was removed (> 24 h). These results demonstrate that DNIC will be formed under all cellular settings of ^•NO production and that the contribution of DNIC to the multitude of observed effects of ^•NO must always be considered.     

Evidence that lithium induces a glutamatergic: Nitric oxide-mediated response in rat brain

Studies have indicated the involvement of a glutamatergic mechanism in lithium (Li⁺) action. Glutamatergic agonists, such as kainic acid, are known to promote the synthesis of nitric oxide (NO) and to increase cGMP, while Li⁺ has displayed a similar, yet unexplained, ability to increase cGMP. NO synthesis is regarded as the principal prodromal event leading to the activation of the guanyl cyclase-cGMP transduction mechanism. In the present study, the involvement of the NO:cGMP pathway in the action of Li⁺ was examined, while the possibility of a glutamatergic mechanism in this response was also investigated. Parameters examined included cortical accumulation of cGMP and the stable oxidative metabolites of NO, viz. NO ₂ ^– and NO ₃ ^–, collectively expressed as NO ₂ ^–. A significant positive correlation was observed in the in vivo cGMP and NO ₂ ^– data throughout all the groups. Chronic treatment of rats with LiCl (0.3% m/m) engendered a significant increase in cGMP levels which was inhibited by the NO-synthase (NOS) inhibitor, N-nitro-l-arginine methyl ester (L-NAME). Acute administration of kainic acid resulted in an increased accumulation of NO ₂ ^–, also prevented by concomitant L-NAME administration. In addition, a synergistic stimulatory response on cortical NO ₂ ^– was observed in the combination of LiCl and kainic acid. Collectively, these data implicate an involvement of a glutamatergic-mediated NO:cGMP transduction mechanism in the action of Li⁺.     

Nitrosothiol Formation and Protection against Fenton Chemistry by Nitric Oxide-induced Dinitrosyliron Complex Formation from Anoxia-initiated Cellular Chelatable Iron Increase

Dinitrosyliron complexes (DNIC) have been found in a variety of pathological settings associated with ^•NO. However, the iron source of cellular DNIC is unknown. Previous studies on this question using prolonged ^•NO exposure could be misleading due to the movement of intracellular iron among different sources. We here report that brief ^•NO exposure results in only barely detectable DNIC, but levels increase dramatically after 1–2 h of anoxia. This increase is similar quantitatively and temporally with increases in the chelatable iron, and brief ^•NO treatment prevents detection of this anoxia-induced increased chelatable iron by deferoxamine. DNIC formation is so rapid that it is limited by the availability of ^•NO and chelatable iron. We utilize this ability to selectively manipulate cellular chelatable iron levels and provide evidence for two cellular functions of endogenous DNIC formation, protection against anoxia-induced reactive oxygen chemistry from the Fenton reaction and formation by transnitrosation of protein nitrosothiols (RSNO). The levels of RSNO under these high chelatable iron levels are comparable with DNIC levels and suggest that under these conditions, both DNIC and RSNO are the most abundant cellular adducts of ^•NO.     

Autowave distribution of nitric oxide and its endogenous derivatives in biosystems strongly enhances their biological effects: A working hypothesis

It is hypothesized that in cells producing nitric oxide (NO), NO and its endogenous derivatives (low-molecular S-nitrosothiols and dinitrosyl iron complexes (DNIC) with thiol-containing ligands) can move in the intracellular space not only by diffusion but also in an autowave mode. This hypothesis is based on the previously obtained data on autowave distribution of DNIC with glutathione following application of a drop of a solution of Fe²⁺ + glutathione onto the surface of a thin layer of a S-nitrosoglutathione solution. The appearance of autowaves is conditioned by a self-regulating self-sustained system arising in the process. This system consists of self-convertible DNIC and S-nitrosothiols as well as free ferrous iron ions, thiols and NO and can function in the autowave regime for several seconds with subsequent passage to a steady state maintained by chemical equilibrium between DNIC and their constituent components (free Fe²⁺ ions, thiols, S-nitrosothiols and NO). Possible advantages of autowave distribution of NO and its endogenous derivatives in the intracellular space over free diffusion, which might entail higher efficiency of their biological action, are discussed.     

The contribution of N2O3 to the cytotoxicity of the nitric oxide donor DETA/NO: an emerging role for S-nitrosylation

The relationship between the biological activity of NO and its chemistry is complex. The objectives of this study were to investigate the influence of oxygen tension on the cytotoxicity of the NO^• donor DETA/NO and to determine the effects of oxygen tension on the key RNS (reactive nitrogen species) responsible for any subsequent toxicity. The findings presented in this study indicate that the DETA/NO-mediated cytotoxic effects were enhanced under hypoxic conditions. Further investigations revealed that neither ONOO⁻ (peroxynitrite) nor nitroxyl was generated. Fluorimetric analysis in the presence of scavengers suggest for the first time that another RNS, dinitrogen trioxide may be responsible for the cytotoxicity with DETA/NO. Results showed destabilization of HIF (hypoxia inducible factor)-1α and depletion of GSH levels following the treatment with DETA/NO under hypoxia, which renders cells more susceptible to DETA/NO cytotoxicity, and could account for another mechanism of DETA/NO cytotoxicity under hypoxia. In addition, there was significant accumulation of nuclear p53, which showed that p53 itself might be a target for S-nitrosylation following the treatment with DETA/NO. Both the intrinsic apoptotic pathway and the Fas extrinsic apoptotic pathway were also activated. Finally, GAPDH (glyceraldehyde-3-phosphate dehydrogenase) is another important S-nitrosylated protein that may possibly play a key role in DETA/NO-mediated apoptosis and cytotoxicity. Therefore this study elucidates further mechanisms of DETA/NO mediated cytotoxicity with respect to S-nitrosylation that is emerging as a key player in the signalling and detection of DETA/NO-modified proteins in the tumour microenvironment.     

Influence of exogenous NO donator and variations in the Ca<Superscript>2+</Superscript> content on transport activity related to tonoplast proton pumps in ontogenesis and under hyperosmotic stress

The changes in transport activity of tonoplast proton pumps under the influence of exogenous NO donator and modulation of Ca²⁺ concentration jointly and separately were investigated at different stages of ontogenesis and under hyperosmotic stress. The results suggest that both exogenous NO donator and Ca²⁺ ions can influence the activity of transport processes related to tonoplast and this influence is especially evident in the period of growth and accumulation of metabolites. Under hyperosmotic stress, H⁺-pyrophosphatase plays a more important role than H⁺-ATPase: the activity of the former increases 2.3-fold compared to the control osmotic conditions, whereas the activity of H⁺-ATPase is practically unchanged. H⁺-pyrophosphatase was more responsive to the presence of exogenous NO donator and to variations in Ca²⁺ concentration. The effects of exogenous NO donator on tonoplast proton pumps depended on the concentration of Ca²⁺, which apparently can mediate NO action.     

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.     

Biological activity of ruthenium nitrosyl complexes

Nitric oxide plays an important role in various biological processes, such as neurotransmission, blood pressure control, immunological responses, and antioxidant action. The control of its local concentration, which is crucial for obtaining the desired effect, can be achieved with exogenous NO-carriers. Coordination compounds, in particular ruthenium(III) and (II) amines, are good NO-captors and -deliverers. The chemical and photochemical properties of several ruthenium amine complexes as NO-carriers in vitro and in vivo have been reviewed. These nitrosyl complexes can stimulate mice hippocampus slices, promote the lowering of blood pressure in several in vitro and in vivo models, and control Trypanosoma cruzi and Leishmania major infections, and they are also effective against tumor cells in different models of cancer. These complexes can be activated chemically or photochemically, and the observed biological effects can be attributed to the presence of NO in the compound. Their efficiencies are explained on the basis of the [Ru^IINO⁺]³⁺/[Ru^IINO⁰]²⁺ reduction potential, the specific rate constant for NO liberation from the [RuNO]²⁺ moiety, and the quantum yield of NO release.     

The hemerythrin-like diiron protein from Mycobacterium kansasii is a nitric oxide peroxidase

The hemerythrin-like protein from Mycobacterium kansasii (Mka HLP) is a member of a distinct class of oxo-bridged diiron proteins that are found only in mycobacterial species that cause respiratory disorders in humans. Because it had been shown to exhibit weak catalase activity and a change in absorbance on exposure to nitric oxide (NO), the reactivity of Mka HLP toward NO was examined under a variety of conditions. Under anaerobic conditions, we found that NO was converted to nitrite (NO₂⁻) via an intermediate, which absorbed light at 520 nm. Under aerobic conditions NO was converted to nitrate (NO₃⁻). In each of these two cases, the maximum amount of nitrite or nitrate formed was at best stoichiometric with the concentration of Mka HLP. When incubated with NO and H₂O₂, we observed NO peroxidase activity yielding nitrite and water as reaction products. Steady-state kinetic analysis of NO consumption during this reaction yielded a K_m for NO of 0.44 μM and a k_cat/K_m of 2.3 × 10⁵ M⁻¹s⁻¹. This high affinity for NO is consistent with a physiological role for Mka HLP in deterring nitrosative stress. This is the first example of a peroxidase that uses an oxo-bridged diiron center and a rare example of a peroxidase utilizing NO as an electron donor and cosubstrate. This activity provides a mechanism by which the infectious Mycobacterium may combat against the cocktail of NO and superoxide (O₂^•−) generated by macrophages to defend against bacteria, as well as to produce NO₂⁻ to adapt to hypoxic conditions.     

Nitric oxide and antioxidant status in glucose and oxygen deprived neonatal and adult rat brain synaptosomes

Nitric oxide (NO) has been implicated in the process of cerebral ischemia/reperfusion injury. We have examined the production of NO, as reflected by nitrite (NO₂ ⁻)+nitrate (NO₃ ⁻) accumulation, from synaptosomes isolated from neonatal or adult rat brain and subjected to a period of glucose and oxygen deprivation. There was a significant increase in the amount of NO₂ ⁻+NO₃ ⁻ production from adult synaptosomes under these conditions, whereas there was no difference compared to control in the production of NO₂ ⁻+NO₃ ⁻ from the neonatal synaptosomes. The total antioxidant status of the synaptosomes at these different stages of brain development was found to be the same. These data suggest that the vulnerability of the adult brain to ischemia/reperfusion injury may be associated with the production of NO from nerve terminals. The ratios of antioxidant capacity to NO production under such conditions have been shown here to be different between the neonatal and adult nerve terminals. Thus the well documented resistance of neonatal brain to ischemia/reperfusion injury may involve the neonatal nerve terminal being under less oxidative stress than the adult.     

Ethylene and nitric oxide are involved in maintaining ion homeostasis in <Emphasis Type="Italic">Arabidopsis</Emphasis> callus under salt stress

In the present study, the role of ethylene in nitric oxide (NO)-mediated protection by modulating ion homeostasis in Arabidopsis callus under salt stress was investigated. Results showed that the ethylene-insensitive mutant etr1-3 was more sensitive to salt stress than the wild type (WT). Under 100 mM NaCl, etr1-3 callus displayed a greater electrolyte leakage and Na⁺/K⁺ ratio but a lower plasma membrane (PM) H⁺-ATPase activity compared to WT callus. Application of exogenous 1-aminocyclopropane-1-carboxylic acid (ACC, an ethylene precursor) or sodium nitroprusside (SNP, a NO donor) alleviated NaCl-induced injury by maintaining a lower Na⁺/K⁺ ratio and an increased PM H⁺-ATPase activity in WT callus but not in etr1-3 callus. The SNP actions in NaCl stress were attenuated by a specific NO scavenger or an ethylene biosynthesis inhibitor in WT callus. Under 100 mM NaCl, the NO accumulation and ethylene emission appeared at early time, and NO production greatly stimulated ethylene emission in WT callus. In addition, ethylene induced the expression of PM H⁺-ATPase genes under salt stress. The recovery experiment showed that NaCl-induced injury was reversible, as signaled by the similar recovery of Na⁺/K⁺ ratio and PM H⁺-ATPase activity in WT callus. Taken together, the results indicate that ethylene and NO cooperate in stimulating PM H⁺-ATPase activity to modulate ion homeostasis for salt tolerance, and ethylene may be a part of the downstream signal molecular in NO action.     

Prospects of designing medicines with diverse therapeutic activity on the basis of dinitrosyl iron complexes with thiol-containing ligands

A stable hypotensive preparation (Oxacom) based on dinitrosyl iron complexes (DNIC) with glutathione has been developed. The preparation has successfully passed pharmacological trials. Tests on volunteers have shown a high hypotensive activity of the preparation: a single intravenous infusion of its aqueous solution at a dose of 0.2 μmol active substance per kg body wt led to a 20–30% decrease in arterial pressure, which persisted for 15–20 h. Similar experiments on animals demonstrated that aqueous solutions of DNIC with cysteine or glutathione also exert a hypotensive action due to their vasodilatory activity. Besides, these complexes accelerate wound healing and produce a potent erectile effect. There is reason to suppose that DNIC with thiol ligands as NO donors may be cytotoxic for pathogenic mycobacteria Mycobacterium tuberculosis and, after appropriate treatment, inhibit cancer cell proliferation. These complexes can be used as analgesics, for inhibiting the adhesion process, in treating preeclampsia, spermatogenesis pathologies, and in cosmetology for treatment of skin injury.     

The dinitrosyl-iron complexes with cysteine block the development of experimental endometriosis in rats

It has been shown that the administration of 0,5 ml of 5 mM aqueous solution of dinitrosyl-iron complexes (DNIC) with cysteine alleviated the development of experimental endometriosis in rats induced by surgical way: the size of endometriomes decreased 1.85 times when the DNIC was added every day during 10 days. The effect was suggested to be due to cytotoxic action of NO molecules and nitrosonium ions (NO+) released from rapidly decomposed DNIC in animal organism on endometriome tissues.     

Oxidation of nitric oxide by a new heterotrophic Pseudomonas sp.

A new bacterial strain isolated from soil consumed nitric oxide (NO) under oxic conditions by oxidation to nitrate. Phenotypic and phylogenetic characterization of the new strain PS88 showed that it represents a previously unknown species of the genus Pseudomonas, closely related to Pseudomonas fluorescens and Pseudomonas putida. The heterotrophic, obligately aerobic strain PS88 was not able to denitrify or nitrify; however, strain PS88 oxidized NO to nitrate. NO was not reduced to nitrous oxide (N₂O). Nitrogen dioxide (NO₂) and nitrite (NO₂ ^–) as possible intermediates of NO oxidation to nitrate (NO₃ ^–) could not be detected. NO oxidation was inhibited under anoxic conditions and by high osmolarity, but not by nitrite. NO oxidation activity was inhibited by addition of formaldehyde, HgCl₂, and antimycin, and by autoclaving or disintegrating the cells, indicating that the process was enzyme-mediated. However, the mechanism remains unclear. A stepwise oxidation at a metalloenzyme and a radical mechanism are discussed. NO oxidation in strain PS88 seems to be a detoxification or a co-oxidation mechanism, rather than an energy-yielding process. Received: 15 November 1995 / Accepted: 24 February 1996     

The role of the reactions of NO with superoxide and oxygen in biological systems: A kinetic approach

In this study we calculate the half-life of ^·NO in its reactions with superoxide and with oxygen under various conditions using the known rate constants for these reactions. The measured half-life of ^·NO in biological systems is 3–5 s, which agrees well with the calculated value for intracellular ^·NO, but not for extracellular ^·NO under normal physiological conditions. The autoxidation of ^·NO to yield NO₂ as a final product cannot be responsible for such a short measured half-life under normal as well as pathologic conditions. Therefore, if there is direct evidence for the occurrence of the reaction of ^·NO with O₂ in the medium, one has to assume that the steady state concentrations of free ^·NO are much lower than those measured. The very low concentrations of free ^·NO in biological systems may result from its reversible strong binding to biological molecules. Simulation of the mechanism of the autoxidation of ^·NO indicates that the binding constants of ^·NO to O₂ or to another ^·NO are too small to account for the very low concentration of free ^·NO in biological systems. Nevertheless, the reaction of ^·NO with oxygen cannot be neglected in biological systems if the intermediate ONOO· reacts rapidly with a biological target. The biological damage caused by ONOO′ is expected to be due to the radical itself and to peroxynitrite, which is most probably formed via the reaction of ONOO· with the biological molecule.     

Cross-talk of NO,superoxide and molecular oxygen,a majesty of aerobic life

Because nitric oxide (NO) reacts with various molecules, such as hemeproteins, superoxide and thiols including glutathione (GSH) and cysteine residues in proteins, biological effects and metabolic fate of this gaseous radical are affected by these reactants. Although the lifetime of NO is short particularly under air atmospheric conditions (where the oxygen tension is unphysiologically high), it increases significantly under physiologically low oxygen concentrations. Because oxygen tensions in human body differ from one tissue to another and change depending on their metabolism, biological activity of NO in various tissues might be affected by local oxygen tensions. To elucidate the role of NO and related radicals in the regulation of circulation and energy metabolism, their effects on arterial resistance and energy metabolism in mitochondria, mammalian cells and enteric bacteria were studied under different oxygen tensions. Kinetic analysis revealed that NO-dependent generation of cGMP in resistance arteries and their relaxation were strongly enhanced by lowering oxygen tensions in the medium. NO reversibly suppressed the respiration and ATP synthesis of isolated mitochondria and intact cells particularly under low oxygen tensions. Kinetic analysis revealed that cross-talk between NO and superoxide generated in and around endothelial cells regulates arterial resistance particularly under physiologically low oxygen tensions. NO also inhibited the respiration and ATP synthesis of E. coli particularly under low oxygen tensions. Because concentrations of NO and H⁺ in gastric juice are high, most ingested bacteria are effectively killed in the stomach. However, the inhibitory effects of NO on the respiration and ATP synthesis of H. pylori are extremely small. Kinetic analysis revealed that H. pylori generates the superoxide radical thereby inhibiting the bactericidal action of NO in gastric juice. Based on such observations, critical roles of the cross-talk of NO, superoxide and molecular oxygen in the regulation of energy metabolism and survival of aerobic and microaerophilic organisms are discussed.