Abstract
Any electrogenic ion-pump carrying a net-current during turnover is an electromotive device creating a transmembrane potential in tight vesicles, which can be detected by the potential sensitive fluorochrome oxonol VI. For the Na+,K+-ATPase the coupling ratio Na+:K+:ATP during physiological Na+:K+-exchange is 3:2:1, giving one positive net-charge translocated per ATP split. The same stoichiometry is found for the electrogenic Na+:Na+-exchange, whereas during uncoupled Na+-efflux this net-charge stoichiometry changes to three, in accordance with a transport stoichiometry 3:0:1. By inducing internal electrostatic potentials in the proteoliposome bilayer using the hydrophobic ions TPB or TPP+ it could be shown that the backreaction which normally translocates K+ changes from electroneutral to electrogenic during the uncoupled Na+-efflux where no ions are returned.
For Ca2+-transport a stoichiometry of close to, but lower than 2 Ca2+-ions per ATP split is found. Recent findings indicate that protons may be exchanged during this transport, but it was uncertain if this proton transport took place primarily on the Ca2+-pump, or was a secondary consequence of the established membrane pump-potential. Using the pH-sensitive fluorescent probe pyranine we have investigated these questions by measurements of generated proton gradients associated with Ca -pump turnover during conditions where the pump potential is short-circuited. From this it can be concluded that protons are countertransported during Ca2+-transport, but the stoichiometry apparently varies.