Structural control of electron-transfer properties in metalloproteins

Summary The factors that control long-range electron transfer between two redox centers in a protein are summarized. Rack-induced bonding in blue copper proteins is described. The protein conformation forces the Cu(II) ion into a distorted geometry, lying at least 70 kJ mol^–1 above the preferred square-planar geometry in energy. The distortion has the effect that the structural change associated with electron transfer is minimal and thus the reorganization energy small. Variations in back bonding are suggested to modulate the reduction potentials of blue proteins without any change in the energy of the charge-transfer transitions. In proton pumps there must be a structural control of the electron transfer rates (electron gating) and model studies suggest that this is best achieved by variations in the reorganization energy.