Nitrosyl complexes formation

Stadler, J., Bergonia, H. A., Di Silvio, M., Sweetland, M. A., Billiar, T. R., Simmons, R. L., and Lancaster, J. R., Jr. (1993). Nonheme iron-nitrosyl complex formation in rat hepatocytes Detection by electron paramagnetic resonance spectroscopy. Arch. Biochem. Biophys. 302, 4-11. 

IL-1 also appears to inhibit insulin secretion by modulating the mitochondrial oxidative metabolism of purified P cells. Treatment of purified P cells for 18 hr with IL-1 results in nearly complete inhibition of the oxidation of [ CJ-D-glucose to C02 (Fig. 10). This inhibition is completely prevented by NMMA (Corbett et al., 1992b). Treatment of purified a cells with lL-1 has no effect on glucose oxidation, suggesting that the effects of IL-1 are specific to the endocrine P cell (Fig. 10). These findings are further supported by the observation that lL-1 induces iron-nitrosyl complex formation and the accumulation of cGMP in the... 

If jS-cell production of nitric oxide participates in IDDM, human islets must produce nitric oxide in response to cytokines. We have shown that a combination of cytokines (lL-1, IFN, and TNF) induce the formation of nitric oxide by isolated human islets (Corbett et al., 1993b). The formation of nitric oxide has been demonstrated by cytokine-induced cGMP accumulation, nitrite formation, and EPR-detectable iron-nitrosyl complex formation (Fig. 12), all of which were prevented by NMMA. The cytokine combination of IFN and lL-1 are required for nitrite production, while TTSIF potentiates IL-1 and IFN-induced nitrite formation by human islets. The cytokine combination of lL-1, TNF, and IFN also influences the physiological function of insulin secretion by human islets. Low concentrations of this cytokine combination slightly stimulate insulin secretion, while high concentrations inhibit insulin secretion, similar to the concentration-dependent effects of lL-1 on rat islet function. NMMA partially prevents the inhibitory effects of this cytokine combination on insulin secretion from human islets, suggesting that nitric oxide may participate in )3-cell dysfunction associated with IDDM. 

Lancaster, J. R., and Hibbs, J. B. (1990). EPR demonstration of iron-nitrosyl complex formation by cytotoxic activated macrophages. Proc. Natl. Acad. Sci. LJ.S.A. 87, 1223-1227. 

In recent years, several model complexes have been synthesized and studied to understand the properties of these complexes, for example, the influence of S- or N-ligands or NO-releasing abilities [119]. It is not always easy to determine the electronic character of the NO-ligands in nitrosyliron complexes thus, forms of NO [120], neutral NO, or NO [121] have been postulated depending on each complex. Similarly, it is difficult to determine the oxidation state of Fe therefore, these complexes are categorized in the Enemark-Feltham notation [122], where the number of rf-electrons of Fe is indicated. In studies on the nitrosylation pathway of thiolate complexes, Liaw et al. could show that the nitrosylation of complexes [Fe(SR)4] (R = Ph, Et) led to the formation of air- and light-sensitive mono-nitrosyl complexes [Fe(NO)(SR)3] in which tetrathiolate iron(+3) complexes were reduced to Fe(+2) under formation of (SR)2. Further nitrosylation by NO yields the dinitrosyl complexes [(SR)2Fe(NO)2], while nitrosylation by NO forms the neutral complex [Fe(NO)2(SR)2] and subsequently Roussin s red ester [Fe2(p-SR)2(NO)4] under reductive elimination forming (SR)2. Thus, nitrosylation of biomimetic oxidized- and reduced-form rubredoxin was mimicked [121]. Lip-pard et al. showed that dinuclear Fe-clusters are susceptible to disassembly in the presence of NO [123]. 

Ligand substitution reactions of NO leading to metal-nitrosyl bond formation were first quantitatively studied for metalloporphyrins, (M(Por)), and heme proteins a few decades ago (20), and have been the subject of a recent review (20d). Despite the large volume of work, systematic mechanistic studies have been limited. As with the Rum(salen) complexes discussed above, photoexcitation of met allop or phyr in nitrosyls results in labilization of NO. In such studies, laser flash photolysis is used to labilize NO from a M(Por)(NO) precursor, and subsequent relaxation of the non-steady state system back to equilibrium (Eq. (9)) is monitored spectroscopically. 

The kinetics of reactions of NO with ferri- and ferro-heme proteins and models under ambient conditions have been studied by time-resolved spectroscopic techniques. Representative results are summarized in Table I (22-28). Equilibrium constants determined for the formation of nitrosyl complexes of met-myoglobin (metMb), ferri-cytochrome-c (Cyt111) and catalase (Cat) are in reasonable agreement when measured both by flash photolysis techniques (K= konlkQff) and by spectroscopic titration in aqueous media (22). Table I summarizes the several orders of magnitude range of kon and kQs values obtained for ferri- and ferro-heme proteins. Many k0f[ values were too small to determine by flash photolysis methods and were determined by other means. The small values of kQ result in very large equilibrium constants K for the... 

The low reactivity of both Cyt111 and Cyt11 toward NO can be attributed to occupation of the heme iron axial coordination sites by an imidazole nitrogen and by a methionine sulfur of the protein (28). Thus, unlike other heme proteins where one axial site is empty or occupied by H20, formation of the nitrosyl complex not only involves ligand displacement but also significant protein conformational changes which inhibit the reaction with NO. However, the protein does not always inhibit reactivity given that Cat and nNOS are more reactive toward NO than is the model complex Fem(TPPS)(H20)2 (Table II). Conversely, the koS values... 

At higher NO concentrations, MPO activity is inhibited through formation of an inactive ferric nitrosyl complex MPO(NO) the rate constant kori is 1.07xlO6 M-1s-1 and the dissociation rate constant, kQff, is 10.8 s-1 (pH 7.0 phosphate buffer at 10 °C) (Scheme 9, pathway A). However, the inhibitory effects of NO are reduced in the presence of plasma levels of Cl- (100 mM) where on and kQ rate constants were determined to be 1.5 x 105 M-1s-1 and 22.8 s-1, respectively. The modulating effects of NO on MPO activity parallel that of O2 which accelerates activity by serving as a substrate for compound II and inhibits activity by acting as a ligand for MPO (Scheme 9, pathway B) (29). 

Despite intense study of the chemical reactivity of the inorganic NO donor SNP with a number of electrophiles and nucleophiles (in particular thiols), the mechanism of NO release from this drug also remains incompletely understood. In biological systems, both enzymatic and non-enzymatic pathways appear to be involved [28]. Nitric oxide release is thought to be preceded by a one-electron reduction step followed by release of cyanide, and an inner-sphere charge transfer reaction between the ni-trosonium ion (NO+) and the ferrous iron (Fe2+). Upon addition of SNP to tissues, formation of iron nitrosyl complexes, which are in equilibrium with S-nitrosothiols, has been observed. A membrane-bound enzyme may be involved in the generation of NO from SNP in vascular tissue [35], but the exact nature of this reducing activity is unknown. 

The literature is rich with examples of metal-nitrosyl complexes, and it would be surprising if the generation of NO by the immune system did not result in the formation of many such adducts. Previous articles have presented summaries of metal proteins that form NO complexes (Butler et al., 1985 Henry et al., 1993), and more recently evidence has mounted that generation of NO by the immune system and by endothelial cells produces a variety of iron-nitrosyl complexes (Mulsch et al., 1993 Vanin et al., 1993 Lancaster et al., 1994). It is unclear which of the potential products will prove to be of physiological relevance, but because the enzymes that may be involved range from the central focus of oxidative cellular metabolism (LoBrutto et al., 1983) to the enzymes of DNA repair (Asahara et al., 1989), the list of potential targets is long and varied. 

Quantitative conversion of the iron in succinate dehydrogenase to this form is possible if additional cysteine is added to the reaction mixture. It is probable that not enough cysteinyl sulfur ligands are available for complex formation without addition of the extra cysteine some of the nitrosyl complex does form without any cysteine addition in these systems. 

This picture can qualitatively account for the g tensor anisotropy of nitrosyl complexes in which g = 2.08, gy = 2.01, and g == 2.00. However, gy is often less than 2 and is as small as 1.95 in proteins such as horseradish peroxidase. To explain the reduction in g from the free electron value along the y axis, it is necessary to postulate delocalization of the electron over the molecule. This can best be done by a complete molecular orbital description, but it is instructive to consider the formation of bonding and antibonding orbitals with dy character from the metal orbital and a p orbital from the nitrogen. The filled orbital would then contribute positively to the g value while admixture of the empty orbital would decrease the g value. Thus, the value of gy could be quite variable. The delocalization of the electron into ligand orbitals reduces the occupancy of the metal d/ orbital. This effectively reduces the coefficients of the wavefunction components which account for the g tensor anisotropy hence, the anisotropy is an order of magnitude less than might be expected for a pure ionic d complex in which the unpaired electron resides in the orbital. 

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