Modulation of the mitochondrial cyclosporin A-sensitive permeability transition pore by matrix pH. Evidence that the pore open-closed probability is regulated by reversible histidine protonation.

Energized mitochondria in sucrose medium take up a Ca2+ pulse but do not show opening of the permeability transition pore (MTP) upon membrane depolarization by uncoupler. This is due to locking of the pore in the closed conformation by matrix acidification and fast Ca2+ efflux following membrane depolarization (Petronilli, V., Cola, C., & Bernardi P. (1993) J. Biol. Chem. 268, 1011-1016). Here we show that addition of diethyl pyrocarbonate (DPC) prior to membrane depolarization restores the ability of uncoupler to induce MTP opening. Since DPC does not modify the rate and extent of matrix acidification and the rate and extent of Ca2+ release following addition of uncoupler, its effects on pore opening appear to be due to modification of histidyl residues regulating the pore open-closed probability. This hypothesis was confirmed in studies with deenergized mitochondria incubated in potassium thiocyanate medium. While at acidic pH values pore opening is otherwise prevented, DPC allows Ca2(+)-dependent pore opening at pH 6.5 in a process that maintains full sensitivity to cyclosporin A. Pore induction by DPC can be completely prevented and partially reversed by hydroxylamine, indicating that the effect of DPC can be specifically traced to carbethoxylation of histidyl residue(s) rather than to reaction with tyrosyl or sulfhydryl groups, while the possible involvement of lysyl residues cannot be excluded. Since DPC increases the pore open probability even at matrix pH values between 7.0 and 7.7, we propose that reversible protonation of one or more histidyl residues on the matrix side of the MTP plays a role in the physiological modulation of pore opening.