Determinants of Directionality and Efficiency of the ATP Synthase F-o Motor at Atomic Resolution

F-o subcomplex of ATP synthase is a membrane-embedded rotary motor that converts proton motive force into mechanical energy. Despite a rapid increase in the number of high-resolution structures, the mechanism of tight coupling between proton transport and motion of the rotary c-ring remains elusive. Here, using extensive all-atom free energy simulations, we show how the motor's directionality naturally arises from the interplay between intraprotein interactions and energetics of protonation of the c-ring. Notably, our calculations reveal that the strictly conserved arginine in the a-subunit (R176) serves as a jack-of-all-trades: it dictates the direction of rotation, controls the protonation state of the proton-release site, and separates the two proton-access half-channels. Therefore, arginine is necessary to avoid slippage between the proton flux and the mechanical output and guarantees highly efficient energy conversion. We also provide mechanistic explanations for the reported defective mutations of R176, reconciling the structural information on the Fo motor with previous functional and single-molecule data.

Automated summary

Through extensive all-atom free energy simulations, it is shown that the directionality of the ATP synthase F-o subcomplex motor naturally arises from the interplay between intraprotein interactions and energetics of protonation. The strictly conserved arginine in the a-subunit is crucial for dictating rotation direction, controlling protonation state, and separating proton-access channels to ensure efficient energy conversion.