Electric Field Driven Torque in ATP Synthase
Abstract
Fo-ATP synthase (Fo) is a rotary motor that converts potential energy from ions, usually protons, moving from high- to low-potential sides of a membrane into torque and rotary motion. Here we propose a mechanism whereby electric fields emanating from the proton entry and exit channels act on asymmetric charge distributions in the c-ring, due to protonated and deprotonated sites, and drive it to rotate. The model predicts a scaling between time-averaged torque and proton motive force, which can be hindered by mutations that adversely affect the channels. The torque created by the c-ring of Fo drives the gamma-subunit to rotate within the ATP-producing complex (F1) overcoming, with the aid of thermal fluctuations, an opposing torque that rises and falls with angular position. Using the analogy with thermal Brownian motion of a particle in a tilted washboard potential, we compute ATP production rates vs. proton motive force. The latter shows a minimum, needed to drive ATP production, which scales inversely with the number of proton binding sites on the c-ring.
Cite
@article{arxiv.1305.6590,
title = {Electric Field Driven Torque in ATP Synthase},
author = {John H. Miller, and Kimal I. Rajapakshe and Hans L. Infante and James R. Claycomb},
journal= {arXiv preprint arXiv:1305.6590},
year = {2013}
}
Comments
19 pages, 6 figures