Abstract
Abstract Electrochemistry and spectroelectrochemistry were used to study solutions of horse myoglobin, both by itself and complexed with cyanide or imidazole, at indium-tin oxide electrodes. In the absence of ligands other than water, myoglobin exhibited slow quasi-reversible heterogeneous electron transfer kinetics, with a formal heterogeneous electron transfer rate constant ( k °′) value of 1.6(±0.4)×10 −5 cm s −1 . Differences from simple simulations in the reverse sweep (anodic) cyclic voltammograms are proposed to be due to residual amounts of dioxygen in solution and/or in the protein molecule. Those differences were not seen in the anodic waveforms of simultaneously acquired derivative cyclic voltabsorptometry (DCVA) experiments. Cyanomyoglobin exhibited faster heterogeneous electron transfer kinetics, with a k °′ value of 6.0(±1.0)×10 −4 cm s −1 . Values for the homogeneous rate constants for dissociation ( k f ) and association ( k b ) of cyanide from and to the electrochemically reduced protein were determined to be 0.08(±0.03) s −1 and 0.06(±0.03) M −1 s −1 , respectively. Imidazolemyoglobin was found to transfer electrons faster than cyanomyoglobin, with a k °′ value of 2.0(±0.5)×10 −3 cm s −1 . The values for the homogeneous rate constants k f and k b were 0.40(±0.1 5) s −1 and 1.1(±0.1) M −1 s −1 , respectively.
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