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.     

Study of dinitrosyl-iron complexes pharmacokinetics and accumulation in depot in rat organs

Protein-bound dinitrosyl-iron complexes (DNIC) in rat whole blood and organs were studied after intravenous injection of this substance with glutathione ligand (DNIC-GH). The effect of DNIC-GH injection on NO level (including NO physiological forms) in hydrophobic areas of rat tissues was also studied in normal physiological blood circulation condition. It has been shown, that after DNIC-GH injection the concentration of protein-bound DNICs in rat whole blood and organs rapidly reached maximum values, and then gradually decreased, that pointed to decomposition of DNIC molecules, coupled with NO release. At the beginning of the experiment the rates of DNIC decay in rat heart and lung were substantially higher, as compared with those in liver and kidney. By spin trappping it has been demonstrated that DNIC-GH, as a source of NO physiological forms (including S-nitrosothiols), in normal physiological blood circulation influence heart more selectively, as compared with the other organs.     

Protein-bound dinitrosyl-iron complexes appearing in blood of rabbit added with a low-molecular dinitrosyl-iron complex: EPR studies.

The formation of protein-bound dinitrosyl-iron complexes (DNIC) in blood plasma and packed red cell fraction has been demonstrated by the EPR method in the experiments on rabbits which were i/v injected with the low-molecular DNIC with thiosulphate. This formation was ensured by transfer of Fe(+)(NO(+))(2) moieties from low-molecular DNIC onto serum albumin or hemoglobin molecules. Protein-bound DNICs appeared immediately after low-molecular DNIC injection followed with gradually decreasing their amounts. The complexes could be detected by EPR technique during more than two days. The addition of water-soluble NO scavenger, the iron complex with N-methyl-d-glucamine dithiocarbamate (MGD) resulted in decomposition of a part of protein-bound DNICs and in effective excretion of secondary products (mainly mononitrosyl-iron complexes with MGD) from the blood flow.     

The mechanisms of S-nitrosothiol decomposition catalyzed by iron.

The mechanisms of S-nitrosothiol transformation into paramagnetic dinitrosyl iron complexes (DNICs) with thiol- or non-thiol ligands or mononitrosyl iron complex (MNICs) with N-methyl-D-glucamine dithiocarbamate catalyzed by iron(II) ions under anaerobic conditions were studied by monitoring EPR or optical features of the complexes and S-nitrosothiols. The kinetic investigations demonstrated the appearance of short-living paramagnetic mononitrosyl-iron complex with L-cysteine prior to the formation of stable dinitrosyl-iron complex with cysteine in the solution of iron(II)-citrate complex (50-100 microM), S-nitrosocysteine (400 microM), and L-cysteine (20 mM) in 100 mM Hepes buffer (pH 7.4). The addition of deoxyhemoglobin (100 microM) did not influence the process, which points to a direct interaction between S-nitrosocysteine and iron(II) ions to yield DNIC. The reaction of DNIC-cysteine formation is first- and second-order in iron and S-nitrosocysteine, respectively. The third-order rate constant is (1.0 +/- 0.2) x 10(5) M(-2) s(-1) (estimated from EPR results) or (2.0 +/- 0.1) x 10(4) M(-2) s(-1) (estimated by optical method). A similar process of DNIC-cysteine formation was observed in a solution of iron(II)-citrate complex, L-cysteine, and NO-proline (200 microM) as a NO* donor. The appearance of a less stable dinitrosyl-iron complex with phosphate was detected when solutions of iron(II)-citrate containing 100 mM phosphate buffer (pH 7.4) were mixed with S-nitrosocysteine or NO-proline. The rapid formation of DNIC with phosphate was followed by its decay. When the concentration of L-cysteine in solutions was reduced from 20 to 1 mM, the life-time of the DNIC-cysteine diminished notably; this was caused by consumption of L-cysteine in the process of DNIC-cysteine formation from S-nitrosocysteine and iron. Thus, L-cysteine is consumed. Formation of DNIC with glutathione was also observed in a solution of glutathione (20 mM), S-nitrosoglutathione (400 microM), and iron(II) complex (800 microM) in 100 mM Hepes buffer (pH 7.4), but the rate of formation was about 10 times slower than the formation of the DNIC-cysteine. The rate of MNIC-MGD formation from iron(II)-MGD complexes and S-nitrosocysteine was first-order in both reactants. The second-order rate constant for this reaction, estimated from EPR measurements, was 30 +/- 5 M(-1) s(-1). Rate constants of MNIC-MGD formation from iron(II)-MGD and the more stable S-nitrosoglutathione and S-nitroso-D,L-penicillamine were equal to 3.0 +/- 0.3 and 0.3 +/- 0.05 M(-1) s(-1), respectively. Thus, the concerted mechanism of DNIC and MNIC formation from S-nitrosothiols and iron(II) ions can be suggested to be predominant.     

L-arginine--an endogenous source of nitric oxide in animal tissues in vivo]

According to EPR data, NG-mononitro-L-arginine (MNA) being intraperitoneally injected to inbred albino mice in the dose of 70-700 mg/kg strongly decreases the formation of mononitrosyl iron complexes (MNIC) with the exogenous ligand, diethyldithiocarbamate (DETC) in liver cells. Simultaneous injections of experimental mice with MNA (70 mg/kg) and L-arginine (700 mg/kg) are unaccompanied by the formation of MNIC-DETC complexes. It is concluded that nitric oxide (NO) which is produced in mouse liver in vivo and which provides for the formation of MNIC complexes with DETC is generated by L-arginine via an enzymatic reaction which is competitively inhibited by MNA. Besides, MNA causes reversible inhibition and augmented synthesis of NO formed in mouse liver after the injection of the exogenous lipopolysaccharide of E. coli.     

Cellular non-heme iron content is a determinant of nitric oxide-mediated apoptosis, necrosis, and caspase inhibition

In this report, we tested the hypothesis that cellular content of non-heme iron determined whether cytotoxic levels of nitric oxide (NO) resulted in apoptosis versus necrosis. The consequences of NO exposure on cell viability were tested in RAW264.7 cells (a cell type with low non-heme iron levels) and hepatocytes (cells with high non-heme iron content). Whereas micromolar concentrations of the NO donor S-nitroso-N-acetyl-DL-penicillamine induced apoptosis in RAW264.7 cells, millimolar concentrations were required to induce necrosis in hepatocytes. Caspase-3 activation and cytochrome c release were evident in RAW264.7 cells, but only cytochrome c release was detectable in hepatocytes following high dose S-nitroso-N-acetyl-DL-penicillamine exposure. Pretreating RAW264.7 cells with FeSO(4) increased intracellular non-heme iron to levels similar to those measured in hepatocytes and delayed NO-induced cell death, which then occurred in the absence of caspase-3 activation. Iron loading was also associated with the formation of intracellular dinitrosyl-iron complexes (DNIC) upon NO exposure. Cytosolic preparations containing DNIC as well as pure preparations of DNIC suppressed caspase activity. These data suggest that non-heme iron content is a key factor in determining the consequence of NO on cell viability by regulating the chemical fate of NO.     

Long-lasting hypotensive action of stable preparations of dinitrosyl-iron complexes with thiol-containing ligands in conscious normotensive and hypertensive rats

Previously we established the hypotensive action of nitric oxide donors, dinitrosyl-iron complexes (DNIC) with thiol-containing ligands, stored in frozen solution at 77K. In the present study, we tested recently designed water soluble dry powder preparations of DNICs keeping their characteristics in dry air for a long time. The complexes dissolved in PBS were injected intravenously into normotensive Wistar and spontaneously hypertensive SHR rats. The average arterial pressure (AAP) was recorded through preliminary implanted catheter in a carotid artery. The initial hypotensive action of DNIC with cysteine (DNIC-cys) was comparable to action of nitroprusside (SNP) but, in contrast to the latter, lasted for 20-120min depending on a doze. The blood DNIC content as detected by electronic paramagnetic resonance steadily decreased at this time. The hypotensive action of S-nitrosocysteine was similar to SNP while binding of iron in DNIC by batophenantroline-disulphonate prevented its hypotensive effect. These data suggest that long-lasting hypotensive action of DNICs may be caused by stable protein-bound DNICs forming in the process of transfer of Fe(+)(NO(+))(2) moieties from low-molecular DNICs to thiol protein ligands. The relative initial dose-dependent effect of DNIC-cys was similar in Wistar and SHR but secondary AAP reduction was more profound in SHR. A substitution of cysteine in DNIC by thiosulphate resulted in markedly less initial AAP reduction while long-lasting effect was similar and substitution by glutathione smoothed initial AAP decline and stabilized AAP level in the second phase. Prolonged AAP reduction induced by DNIC-cys was considerably shortened in narcotized rats. Thus, dry preparations of DNICs preserve prolonged hypotensive activity.     

Gamma-irradiation potentiates L-arginine-dependent nitric oxide formation in mice.

Gamma-irradiation of mongrel mice at a sublethal dose (700 Roentgen) enhanced the formation of nitric oxide (NO) in the liver, intestine, lung, kidney, brain, spleen or heart of the animals. NO formation was determined by the increase in intensity of the EPR signal due to trapping of NO into mononitrosyl iron complexes (MNIC) with exogenous diethyldithiocarbamate (DETC) injected intraperitoneally. The EPR signal of these MNIC-DETC complexes was characterized by g-factor values at g perpendicular values at g perpendicular = 2.035 and g parallel = 2.02 and a triplet hyperfine structure at g perpendicular. The NO synthase inhibitor, NG-nitro-L-arginine, prevented MNIC-DETC complex formation both in liver and intestine, demonstrating the involvement of endogenous NO formed. Thus, gamma-irradiation may enhance endogenous NO biosynthesis in these tissues, presumably by facilitating the entry of Ca2+ ions into the membrane as well as the cytosol of NO-producing cells through irradiation-induced membrane lesions.     

Nitric oxide-induced conversion of cellular chelatable iron into macromolecule-bound paramagnetic dinitrosyliron complexes

One of the most important biological reactions of nitric oxide (nitrogen monoxide, *NO) is its reaction with transition metals, of which iron is the major target. This is confirmed by the ubiquitous formation of EPR-detectable g=2.04 signals in cells, tissues, and animals upon exposure to both exogenous and endogenous *NO. The source of the iron for these dinitrosyliron complexes (DNIC), and its relationship to cellular iron homeostasis, is not clear. Evidence has shown that the chelatable iron pool (CIP) may be at least partially responsible for this iron, but quantitation and kinetic characterization have not been reported. In the murine cell line RAW 264.7, *NO reacts with the CIP similarly to the strong chelator salicylaldehyde isonicotinoyl hydrazone (SIH) in rapidly releasing iron from the iron-calcein complex. SIH pretreatment prevents DNIC formation from *NO, and SIH added during the *NO treatment "freezes" DNIC levels, showing that the complexes are formed from the CIP, and they are stable (resistant to SIH). DNIC formation requires free *NO, because addition of oxyhemoglobin prevents formation from either *NO donor or S-nitrosocysteine, the latter treatment resulting in 100-fold higher intracellular nitrosothiol levels. EPR measurement of the CIP using desferroxamine shows quantitative conversion of CIP into DNIC by *NO. In conclusion, the CIP is rapidly and quantitatively converted to paramagnetic large molecular mass DNIC from exposure to free *NO but not from cellular nitrosothiol. These results have important implications for the antioxidative actions of *NO and its effects on cellular iron homeostasis.     

Activation of soluble guanylate cyclase by NO donors--S-nitrosothiols, and dinitrosyl-iron complexes with thiol-containing ligands.

We studied the capability of dimeric forms of dinitrosyl-iron complexes and S-nitrosothiols to activate soluble guanylate cyclase (sGC) from human platelet cytosol. The dinitrosyl-iron complexes had the ligands glutathione (DNIC-GS) or N-acetylcysteine (DNIC-NAC). The S-nitrosothiols were S-nitrosoglutathione (GS-NO) or S-nitrosoacetylcysteine (SNAC). For both glutathione and N-acetylcysteine, the DNIC and S-nitrosothiol forms are equally effective activators of sGC. The activation mechanism is strongly affected by the presence of intrinsic metal ions. Pretreatment with the potent iron chelator, disodium salt of bathophenanthroline disulfonic acid (BPDS), suppressed sGC activation by GS-NO: the concentration of GS-NO producing maximal sGC activation was increased by two orders of magnitude. In contrast, activation by DNIC-GS is strongly enhanced by BPDS. When BPDS was added 10 min after supplementation of DNIC-GS or GS-NO at 4 degrees C, it exerted a similar effect on sGC activation by either NO donor: BPDS only enhanced the sGC stimulation at low concentrations of the NO donors. Our experiments demonstrated that both Fe(2+) and Cu(2+) ions contribute to the decomposition of GS-NO in the presence of ascorbate. The decomposition of GS-NO induced by Fe(2+) ions was accompanied by formation of DNIC. BPDS protected GS-NO against the destructive action of Fe(2+) but not Cu(2+) ions. Additionally, BPDS is a sufficiently strong chelator to remove the iron from DNIC-GS complexes. Based on our data, we propose that S-nitrosothiols activate sGC via a two-step iron-mediated process: In the first step, intrinsic Fe(2+) ions catalyze the formation of DNICs from S-nitrosothiols. In the secondary step, these newly formed DNICs act as the real NO donors responsible for sGC activation.     

Interaction of Oxoferrylmyoglobin and Dinitrosyl-Iron Complexes

It is shown that dinitrosyl-iron complexes (DNIC) with glutathione can reduce oxoferrylmyoglobin forming on interaction of tert-butyl hydroperoxide and metmyoglobin. A rapid decrease in the DNIC concentration was observed under the conditions of production of tert-butyl free radicals; however, destruction of DNIC in the presence of oxoferrylmyoglobin alone was negligible. It is demonstrated that DNIC reduces oxoferrylmyoglobin more than an order more efficiently than S-nitrosoglutathione and glutathione. DNIC also inhibits formation of the thiyl radicals of glutathione in a medium containing metmyoglobin and tert-butyl hydroperoxide. A mechanism of the antioxidant action of DNIC based on regeneration of the nitrosyl complexes from the products of their interaction with oxoferrylheme is proposed.     

In vivo assessment of microcystin-LR-induced hepatotoxicity in the rat using proton nuclear magnetic resonance (1H-NMR) imaging.

Microcystin-LR (MCLR)-induced hepatotoxicity was assessed in vivo in male Sprague-Dawley rats (150-350 g) using magnetic resonance imaging (MRI). Following the intraperitoneal administration of MCLR (LD(50)), a region of damage, characterised by increased signal intensity on T(2)-weighted images, was seen proximal to the hepatic portal vein in the liver. Similarly, increased signal intensity was seen in the chemical-shift selective images (CSSI) of water frequency, proximal to the hepatic portal vein in the liver. This indicates that the increased signal intensity observed in the T(2)-weighted images was due to an increased amount of magnetic resonance (MR) visible protons in the tissue which represents an oedematous response. Image analysis of regions of apparent damage around the hepatic portal vein indicated a statistically significant increase in signal intensity in this region. Mitochondrial swelling and lipid inclusions were observed by transmission electron microscopy (TEM) in samples obtained from the oedematous regions of the liver using spatial coordinates from the magnetic resonance (MR) images. Massive haemorrhagic necrosis and nuclear swelling were observed by light microscopy in the centrilobular regions of the lobules.     

The source of non-heme iron that binds nitric oxide in cultivated macrophages.

In cultured macrophages (J 774 line) a decrease in iron-sulfur centers (ISC) was not observed after 5 min treatment with nitric oxide (NO) (10(-7) M NO/10(7) cells). The content of these centers was measured by electron spin resonance (ESR) spectroscopy at 16-60 K. However, the appearance of a characteristic ESR signal at g(av) = 2.03 indicated the formation of dinitrosyl iron complex (DNIC) in these cells. These findings suggest that loosely bound non-heme iron (free iron) but not iron from ISC is mainly involved in DNIC formation. ISC might release iron for DNIC formation after their destruction induced by the products of NO oxidation (NO2, N2O3, etc).     

N-acetylcysteine inhibits in vivo nitric oxide production by inducible nitric oxide synthase.

This in vivo study evaluates the effect of N-acetylcysteine (NAC) administration on nitric oxide (NO) production by the inducible form of nitric oxide synthase (iNOS). NO production was induced in the rat by the ip administration of 2 mg/100 g lipopolysaccharide (LPS). This treatment caused: (1) a decrease in body temperature within 90 min, followed by a slow return to normal levels; (2) an increase in plasma levels of urea, nitrite/nitrate, and citrulline; (3) the appearance in blood of nitrosyl-hemoglobin (NO-Hb) and in liver of dinitrosyl-iron-dithiolate complexes (DNIC); and (4) increased expression of iNOS mRNA in peripheral blood mononuclear cells (PBMC). Rat treatment with 15 mg/100 g NAC ip, 30 min before LPS, resulted in a significant decrease in blood NO-Hb levels, plasma nitrite/nitrate and citrulline concentrations, and liver DNIC complexes. PBMC also showed a decreased expression of iNOS mRNA. NAC pretreatment did not modify the increased levels of plasma urea or the hypothermic effect induced by the endotoxin. The administration of NAC following LPS intoxication (15 min prior to sacrifice) did not affect NO-Hb levels. These results demonstrate that NAC administration can modulate the massive NO production induced by LPS. This can be attributed mostly to the inhibitory effect of NAC on one of the events leading to iNOS protein expression. This hypothesis is also supported by the lack of effect of late NAC administration.     

In vivo diffusion-perfusion magnetic resonance imaging of acute cerebral ischemia.

We compared the anatomic extent and severity of ischemic brain injury shown on diffusion-weighted magnetic resonance (MR) images, with cerebral tissue perfusion deficits demonstrated by a nonionic intravascular T2*-shortening magnetic susceptibility contrast agent used in conjunction with standard T2-weighted spin-echo and gradient-echo echo-planar images. Diffusion-weighted images displayed increased signal intensity in the vascular territory of the middle cerebral artery 25-40 min after permanent occlusion, whereas T2-weighted images without contrast were negative or equivocal for at least 2-3 h after stroke was induced. Contrast-enhanced T2-weighted and echo-planar images revealed perfusion deficits that were spatially closely related to the anatomic regions of ischemic tissue injury. These data indicate that diffusion-weighted MR images are very sensitive to early onset pathophysiologic changes induced by acute cerebral ischemia. Combined sequential diffusion-perfusion imaging enables noninvasive in vivo examination of the relationship between hypoperfusion and evolving ischemic brain injury.     

Selective delivery of nitric oxide to a cellular target: a pseudosubstrate-coupled dinitrosyl-iron complex inhibits the enteroviral protease 2A.

Nitric oxide (NO) regulates multiple biological processes. To use NO as a potential therapeutic substance, a more selective modulation of individual NO targets is desirable. Here, we tested whether peptide conjugation of the dinitrosyl-iron complex (DNIC), a potent NO donor, confers targeted NO delivery. As target, we used the protease 2A of Coxsackie-B-viruses (2A(pro)), which can cause dilated cardiomyopathy. Through S-nitrosylation, NO inhibits this protease, which is essential for viral replication. The tetrapeptide Leu-Ser-Thr-Cys (LSTC) (based on the 2A(pro) substrate recognition motif) and DNIC generated LSTC-DNIC in vitro by S-nitrosylation as evidenced by reverse-phase chromatography. In vitro, LSTC-DNIC (IC(50) 510 nM) dose-dependently inhibited purified 2A(pro) 4.7-fold more effectively than DNIC (IC(50) 2.4 microM), whereas LSTC alone had no effect. In intact cells, expression of Coxsackievirus protease 2A by transient transfection led to eIF4G-I-cleavage. LSTC-DNIC (IC(50) 23 microM) dose-dependently inhibited eIF4G cleavage in 2A(pro)-transfected cells 3.8-fold more effectively than DNIC (IC(50) 88 microM). To test the specificity of the DNIC-conjugated LSTC peptide part, we investigated its influence on Caspase-3, a known target for S-nitrosylation. LSTC-DNIC and DNIC inhibited purified Caspase-3 in vitro (IC(50) 3.7 microM) and in intact cells similarly. LSTC conjugation of DNIC enhances its fidelity for inhibition of 2A(pro) in vitro and intracellularly. Peptide-DNIC may be useful to selectively modulate cellular processes by NO, i.e., to enhance its antiviral properties.     

The potent vasodilating and guanylyl cyclase activating dinitrosyl-iron(II) complex is stored in a protein-bound form in vascular tissue and is released by thiols.

We studied the biological activity, stability and interaction of dinitrosyl-iron(II)-L-cysteine with vascular tissue. Dinitrosyl-iron(II)-L-cysteine was a potent activator of purified soluble guanylyl cyclase (EC50 10 nM with and 100 nM without superoxide dismutase) and relaxed noradrenaline-precontracted segments of endothelium-denuded rabbit femoral artery (EC50 10 nM superoxide dismutase). Pre-incubation (5 min; 310 K) of endothelium-denuded rabbit aortic segments with dinitrosyl-iron(II)-L-cysteine (0.036-3.6 mM) resulted in a concentration-dependent formation of a dinitrosyl-iron(II) complex with protein thiol groups, as detected by ESR spectroscopy. While the complex with proteins was stable for 2 h at 310 K, dinitrosyl-iron(II)-L-cysteine in aqueous solution (36-360 microM) decomposed completely within 15 min, as indicated by disappearance of its isotropic ESR signal at gav = 2.03 (293 K). Aortic segments pre-incubated with dinitrosyl-iron(II)-L-cysteine released a labile vasodilating and guanylyl cyclase activating factor. Perfusion of these segments with N-acetyl-L-cysteine resulted in the generation of a low molecular weight dinitrosyl-iron(II)-dithiolate from the dinitrosyl-iron(II) complex with proteins, as revealed by the shape change of the ESR signal at 293 K. The low molecular weight dinitrosyl-iron(II)-dithiolate accounted for an enhanced guanylyl cyclase activation and vasodilation induced by the aortic effluent. We conclude that nitric oxide (NO) produced by, or acting on vascular cells can be stabilized and stored as a dinitrosyl-iron(II) complex with protein thiols, and can be released from cells in the form of a low molecular weight dinitrosyl-iron(II)-dithiolate by intra- and extracellular thiols.