Abstract
Investigations into the nature of the axial heme ligands, the strength of the heme crevice, the reactivity with cyanide, and the ascorbate reducibility of cytochrome c1 were performed to explore structure-function relationships of cytochrome c1. The existence of an absorbance band at 690 nm, which was quenched by raising the pH with a pK of 9.2 corresponding to a low spin-low transition, suggested that a methionine residue probably functioned as one of the axial heme iron ligands in this cytochrome. Spectral titrations of cytochrome c1 in the low pH range showed a markedly elevated pK for the low spin-high spin transition relative to cytochrome c. Denaturation studies with urea, the absence of any reaction with cyanide, and the evidence from other lines would appear to indicate that the heme group of cytochrome c1 was reduced by ascorbate at approximately 5% of the rate of reduction of cytochrome c but this rate dramatically increased with increasing pH concomitant with the disappearance of the 690 nm absorbance band. Circular dichroic spectra substantiated that elevated pH produced conformational changes localized to the heme crevice and probably also the regions containing aromatic residues. The enhanced rate of ascorbate reduction was perhaps a consequence of the increased accessibility of the heme iron to ascorbate. Major unfolding of the protein in 8 M urea, however, completely abolished the ascorbate reducibility of cytochrome c1. The buried nature of the heme group of cytochrome c1 would probably preclude transfer of an electron from cytochrome c1 to cytochrome c through a direct Fe-Fe or a heme-heme interaction. This poses an important question concerning the mechanism of this electron transfer between these two cytochromes not only in mitochondria but also in solution.
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