Myoglobin metMb

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... 

Recent work has resolved some of the issues that complicate direct electrochemistry of myoglobin, and, in fact, it has been demonstrated that Mb can interact effectively with a suitable electrode surface (103-113). This achievement has permitted the investigation of more complex aspects of Mb oxidation-reduction behavior (e.g., 106). In general, it appears that the primary difficulty in performing direct electrochemistry of myoglobin results from the change in coordination number that accompanies conversion of metMb (six-coordinate) to reduced (deoxy) Mb (five-coordinate) and the concomitant dissociation of the water molecule (or hydroxide at alkaline pH) that provides the distal ligand to the heme iron of metMb. 

The H64 distal ligand of wild-type myoglobin does not coordinate to the heme iron in either the reduced or the oxidized form of the native protein but stabilizes the coordination of a distally boimd water molecule of metMb. Replacement of H64 with other amino acid residues can, therefore, change the coordination environment of the heme iron in two ways. Such variants either may possess a distal residue that is able to coordinate to the heme iron or may possess a distal residue that is incapable of either coordinating to the iron or of forming a hydrogen bond with a coordinated water molecule. 

Mb. Subsequent application of this technique to reduction of various derivatives of reduced and oxidized myoglobin led to the observation that the rate of reduction by hydrated electrons depends primarily on the net charge of the protein and the dissociation constant for formation of ligand bound derivatives of metMb. 

As described above, efficient peroxidase catalysis requires rapid reaction of the enzyme with H2O2 coupled with the formation of a discrete compound I species. As initially observed by George and Irvine in 1952 (177), the reaction of metMb with H2O2 is much slower than the corresponding reaction of peroxidases. The myoglobin derivative produced by this reaction was referred to by these authors as ferryl myoglobin... 

The ferriheme protein metmyoglobin (metMb) at the physiological pH 7.4 was reported to bind the NO molecule reversibly yielding the nitrosyl adduct [metMb(NO)] the kinetics of the association and dissociation processes were investigated and a limiting dissociation mechanism was proposed (58,68). 2-His-l-Glu nonheme iron center engineered into myoglobin was reported capable to bind Fe(II) and reduce NO to N2O (69). 

---