Oxidation-state-dependent protein docking between cytochrome c and cytochrome b(5): high-pressure laser flash photolysis study

To characterize the protein-protein interaction during electron transfer, we used Zn-substituted cytochrome c (ZnCytc) as a model of ferrous Cytc and determined the volume change, DeltaV(d)(Zn), for the dissociation of its complex with ferric cytochrome b(5) (Cytb(5)) by the pressure dependence of its photoinduced electron-transfer kinetics. Under ambient pressure, the dissociation constant, K(d)(Zn), of the ZnCytc/Cytb(5) complex was dependent on the buffer concentration, 1.5 and 12 microM in 2 and 10 mM Tris-HCl, pH 7.4, respectively, which was consistent with formation of salt bridges in its complexation. The dissociation of one salt bridge is usually associated with large volume changes of -10 to -30 cm(3) mol(-1), while pressure dependence of K(d)(Zn) resulted in smaller value of DeltaV(d)(Zn), -8.5 cm(3) mol(-1). Therefore, the interaction between ZnCytc and Cytb(5) cannot be explained only by salt bridge interaction, and the partial cancellation by the positive volume change due to the additional hydrophobic interaction is a plausible explanation for the observed DeltaV(d)(Zn). In addition, DeltaV(d)(Zn) of -8.5 cm(3) mol(-1) was considerably smaller than the previously reported volume change, DeltaV(d)(Fe), of -122 cm(3) mol(-1) in the ferric Cytc/Cytb(5) complex dissociation Rodgers and Sligar (1991) J. Mol. Biol. 221, 1453-1460]. ZnCytc used here has been assumed to be a reliable model of ferrous Cytc, and thus the discrepancy between our present DeltaV(d)(Zn) and the previous DeltaV(d)(Fe) is discussed on the basis of the protein docking dependent on the oxidation states of heme iron in Cytc.