Adenosine triphosphate (ATP), the universal fuel of the cell, is synthesized from adenosine diphosphate (ADP) and inorganic phosphate (P(i)) by 'ATP synthase' (F(O)F(1)-ATPase). During respiration or photosynthesis, an electrochemical potential difference of protons is set up across the respective membranes. This powers the enzyme's electrical rotary nanomotor (F(O)), which drives the chemical nanomotor (F(1)) by elastic mechanical-power transmission, producing ATP with high kinetic efficiency. Attempts to understand in detail the mechanisms of torque generation in this simple and robust system have been both aided and complicated by a wealth of sometimes conflicting data.
The enzyme ATP synthase, or F-ATPase, is present in the membranes of bacteria, chloroplasts and mitochondria. Its structure is bipartite, with a proton-conducting, integral membrane portion, F0, and a peripheral portion, F1. Solubilized F1 is composed of five different subunits, (alpha beta)3 gamma delta epsilon, and is active as an ATPase. The function of F-ATPase is to couple proton translocation through F0 with ATP synthesis in F1 (ref.3). Several lines of evidence support the spontaneous formation of ATP on F1 (refs 4,5) and its endergonic release at cooperative and rotating (or at least alternating) sites. The release of ATP at the expense of protonmotive force might involve mechanical energy transduction from F0 into F1 by rotation of the smaller subunits (mainly gamma) within (alpha beta)3, the catalytic hexagon of F1 as suggested by electron microscopy, by X-ray crystal structure analysis and by the use of cleavable crosslinkers. Here we record an intersubunit rotation in real time in the functional enzyme by applying polarized absorption relaxation after photobleaching to immobilized F1 with eosin-labelled gamma. We observe the rotation of gamma relative to immobilized (alpha beta)3 in a timespan of 100 ms, compatible with the rate of ATP hydrolysis by immobilized F1. Its angular range, which is of at least 200 degrees, favours a triple-site mechanism of catalysis, with gamma acting as a crankshaft in (alpha beta)3. The rotation of gamma is blocked when ATP is substituted with its non-hydrolysable analogue AMP-PNP.
The 2 nanomotors of rotary ATP synthase, ionmotive FO and chemically active F1, are mechanically coupled by a central rotor and an eccentric bearing. Both motors rotate, with 3 steps in F1 and 10 -15 in FO. Simulation by statistical mechanics has revealed that an elastic power transmission is required for a high rate of coupled turnover. Here, we investigate the distribution in the FOF1 structure of compliant and stiff domains. The compliance of certain domains was restricted by engineered disulfide bridges between rotor and stator, and the torsional stiffness () of unrestricted domains was determined by analyzing their thermal rotary fluctuations. A fluorescent magnetic bead was attached to single molecules of F 1 and a fluorescent actin filament to FOF1, respectively. They served to probe first the functional rotation and, after formation of the given disulfide bridge, the stochastic rotational motion. Most parts of the enzyme, in particular the central shaft in F1, and the long eccentric bearing were rather stiff (torsional stiffness > 750 pNnm). One domain of the rotor, namely where the globular portions of subunits ␥ and of F1 contact the c-ring of FO, was more compliant ( Х 68 pNnm). This elastic buffer smoothes the cooperation of the 2 stepping motors. It is located were needed, between the 2 sites where the power strokes in FO and F1 are generated and consumed.elasticity ͉ F-ATPase ͉ nanomotor
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.