Met80 and Tyr67 affect the chemical unfolding of yeast cytochrome c: comparing solution vs. immobilized state

Urea-induced denaturation of the Met80Ala and Met80Ala/Tyr67Ala variants of S. cerevisiae iso-1 cytochrome c (ycc) was studied through variable temperature diffusive cyclic voltammetry and electronic absorption, CD and MCD spectroscopies. The susceptibility to unfolding of both variants - represented by the free energy of unfolding at denaturant infinite dilution, ∆〖G°〗_u^(H_2 O)is greater compared to the species showing an intact Met/His coordination, as observed previously for the same species immobilized onto a functionalized electrode. This is consistent with the role of the axial Fe-(S)Met bond and the H-bond network involving Tyr67 in stabilizing the polypeptide matrix in the heme crevice. Notably, we find that the unfolding propensity and axial heme iron coordination of the present Fe-(S)Met bond-deprived variants is affected by the motional regime of the protein. In particular, electrostatic adsorption onto a negatively charged SAM surface - that would mimic the phospholipidic inner mitochondrial membrane - facilitates unfolding compared to the solution state, especially at room temperature. This finding has a physiological relevance related to the cytochrome c interaction with cardiolipin at the IMM in the early stages of apoptosis. Moreover, while both immobilized variants maintain the His/OH- axial heme iron coordination up to 7 M urea, the same species in solution are subjected to urea-induced replacement of the axial hydroxide ligand by a His ligand. The contribution of the enthalpic and entropic terms to ∆〖G°〗_u^(H_2 O) were found to be opposite (H-S compensation) indicating that unfolding thermodynamics are strongly affected by changes in the hydrogen bonding network in the hydration sphere of the protein.