Fluoride-binding to the Escherichia coli bd-type ubiquinol oxidase studied by visible absorption and EPR spectroscopies.

Abstract

Cytochrome bd-type ubiquinol oxidase in the aerobic respiratory chain of Escherichia coli contains two hemes b (b558 and b595) and one heme d as redox metal centers. To clarify the structure of the reaction center, we analyzed the fully oxidized enzyme by visible and EPR spectroscopies using fluoride ion as a monitoring probe. The visible spectral changes upon fluoride-binding were typical of ferric iron-chlorine species, indicating heme d as a primary binding site. The negative peak at 645 nm in the difference spectrum indicates that heme b595 also provides the low-affinity fluoride-binding site. Fluoride-binding caused a complete disappearance from the EPR spectra of the low-spin signals ascribable to heme d and spectral changes in both rhombic and axial high-spin signals. After fluoride-binding, each component of the rhombic high-spin signal showed superhyperfine splitting arising from the interaction of the unpaired spin of the heme d iron with the nuclear magnetic moment of 19F. The axial high-spin species was converted to a new rhombic high-spin species assignable to heme b595-fluoride. The g = 2 component of this new species also gave 19F-superhyperfine splitting. These results indicate that both heme d and heme b595 can coordinate with a fluoride ion with different affinities in the fully oxidized state.