[Formation of a new type of dinitrosyl iron complexes bound to cysteine modified with methylglyoxal].

It has been shown that interaction of cysteine dinitrosyl iron complexes with methylglyoxal leads to the formation of a new type of dinitrosyl iron complexes., EPR spectrum of these complexes essentially differs from spectra of dinitrosyl iron complexes containing unmodified thiol. The products of the cysteine reaction with methylglyoxal are hemithioacetals, Schiff bases and thiazolidines, which most likely serve as ligands for the new type of dinitrosyl iron complexes. It has been shown that the new type of dinitrosyl iron complexes as cysteine dinitrosyl iron complexes, which are physiological donors of nitric oxide, exert a vasodilator effect. It has also been found that the oxidative destruction of the new type of dinitrosyl iron complexes occurs at normal oxygen partial pressure, but these dinitrosyl iron complexes remain rather stable under hypoxia modeling. An assumption that the destruction of the new type of dinitrosyl iron complexes is caused by the formation of a bound peroxynitrite-containing intermediate is made.

[Formation of dinitrosyl iron complexes in cardiac mitochondria].

It has been established that, in the presence of S-nitrosothiols, cysteine, and mitochondria, dinitrosyl iron complexes (DNIC) coupled to low-molecular-weight ligands and proteins are formed. The concentration of DNIC depended on oxygen partial pressure. It was shown that, under the conditions of hypoxia, the kinetics of the formation of low-molecular DNIC was diphasic. After the replacement of anaerobic conditions of incubation to aerobic ones, the level of DNIC came down; in this case, protein dinitrosyl complexes became more stable. We proposed that iron- and sulfur-containing proteins and low-molecular-weight iron complexes are the sources of iron for DNIC formation in mitochondrial suspensions. It was shown that a combination of DNIC and S-nitrosothiols inhibited effectively the respiration of cardiomyocytes.

Superoxide formation as a result of interaction of L-lysine with dicarbonyl compounds and its possible mechanism.

The EPR signal recorded in reaction medium containing L-lysine and methylglyoxal is supposed to come from the anion radical (semidione) of methylglyoxal and cation radical of methylglyoxal dialkylimine. These free-radical intermediates might be formed as a result of electron transfer from dialkylimine to methylglyoxal. The EPR signal was observed in a nitrogen atmosphere, whereas only trace amounts of free radicals were registered under aerobic conditions. It has been established that the decay of methylglyoxal anion radical on aeration of the medium is inhibited by superoxide dismutase. Using the methods of EPR spectroscopy and lucigenin-dependent chemiluminescence, it has been shown that nonenzymatic generation of free radicals including superoxide anion radical takes place during the interaction of L-lysine with methylglyoxal--an intermediate of carbonyl stress--at different (including physiological) pH values. In the course of analogous reaction of L-lysine with malondialdehyde (the secondary product of the free radical derived oxidation of lipids), the formation of organic free radicals or superoxide radical was not observed.

[Action of a nitric oxide donor dinitrosyl complex of iron with glutathione on hemodynamics in rats and monkeys].

We studied action of a nitric oxide donor, dinitrosyl complex of iron (DNIC) with glutathione as a ligand on the hemodynamics of normotensive Wistar rats, spontaneously hypertensive rats (SHR), and monkeys. Intravenous DNIC introduction (2-120 mg/kg) rendered fast (1-2 min) hypotensive effect combined with increased heart rate by 10-25%. Second phase of the effect in Wistar rats was characterized by slowed recovery of arterial pressure and heart rate up to initial level. A gradual DNIC breakdown in blood occurred during this period associated with increased NO accumulation in organs with intensive oxidative metabolism (liver, heart, and kidney). Duration of hypotensive effect in all animals depended on dose, this dependence was most expressed in SHR.

[Antioxidant and prooxidant action of nitric oxide donors and metabolites].

It has been shown that various nitric oxide donors and metabolites have similar effects on lipid peroxidation in rat myocardium homogenate. The formation of malondialdehyde, a secondary product of lipid peroxidation, was inhibited in a dose-dependent manner by PAPA/NONO (a synthetic nitric oxide donor), S-nitrosoglutathione, nitrite, and nitroxyl anion. The inhibition of lipid peroxidation was provided most efficiently by the administration of dinitrosyl-iron complexes with dextran and PAPA/NONO. S-nitrosoglutathione also inhibited the destruction of coenzymes Q9 and Q10 during free radical oxidation of myocardium homogenate. Low-molecular-weight dinitrosyl iron complexes with cysteine also promoted lipid peroxidation, which is probably due to iron release during the destruction dinitrosyl iron complexes. It is likely that the antioxidant action of nitric oxide derivatives is related to the reduction of ferry forms of hemoproteins and interaction of nitric oxide with lipid radicals.

[Interaction between albumin-bound dinitrosyl iron complexes and reactive oxygen species].

It has been established that albumin-bound dinitrosyl iron complexes can be destroyed by superoxide radicals generated in a xanthine-xanthine oxidase system. It was shown that peroxynitrite also effectively destroyed albumin-bound dinitrosyl iron complexes. At the same time, hydrogen peroxide and tert-butyl hydroperoxide did not stimulate the destruction of albumin-bound dinitrosyl iron complexes up to concentrations one order higher than the content of NO. The data have been obtained indicating that dinitrosyl iron complexes possess the vasodilatory activity. It has been proposed that peroxynitrite and superoxide radical, by causing the destruction of albumin-bound dinitrosyl iron complexes, affect the physiological properties of nitric oxide.

[Interaction between dinitrosyl iron complexes and intermediate products of oxidative stress].

The interaction between glutathione-containing dinitrosyl iron complexes and superoxide radicals has been studied under the conditions of superoxide radical generation in mitochondria and in a model system xanthine-xanthine oxidase. It has been shown that both superoxide radical and hydroxyl radical are involved in the destruction of dinitrosyl iron complexes. At the same time, iron contained in dinitrosyl iron complex, apparently, does not catalyze the decomposition of hydrogen peroxide with the formation of hydroxyl radical. It has been found that dinitrosyl iron complexes with different anion ligands inhibit effectively the formation of phenoxyl probucol radical in a hemin-H2O2 a system. In this process, different components of the dinitrosyl iron complexes take part in the antioxidant action of these complexes.