Molecular mechanisms of rotational catalysis in the F(0)F(1) ATP synthase.

Rotation of the F(0)F(1) ATP synthase gamma subunit drives each of the three catalytic sites through their reaction pathways. The enzyme completes three cycles and synthesizes or hydrolyzes three ATP for each 360 degrees rotation of the gamma subunit. Mutagenesis studies have yielded considerable information on the roles of interactions between the rotor gamma subunit and the catalytic beta subunits. Amino acid substitutions, such as replacement of the conserved gammaMet-23 by Lys, cause altered interactions between gamma and beta subunits that have dramatic effects on the transition state of the steady state ATP synthesis and hydrolysis reactions. The mutations also perturb transmission of specific conformational information between subunits which is important for efficient conversion of energy between rotation and catalysis, and render the coupling between catalysis and transport inefficient. Amino acid replacements in the transport domain also affect the steady state catalytic transition state indicating that rotation is involved in coupling to transport.

Catalytic control and coupling efficiency of the Escherichia coli FoF1 ATP synthase: influence of the Fo sector and epsilon subunit on the catalytic transition state.

The rate-limiting transition state of steady-state ATP hydrolysis and synthesis reactions in the F(o)F(1) ATP synthase involves the rotation of the gamma, epsilon, and c subunits. To probe the role of the transport and coupling mechanisms in controlling catalysis, kinetic and thermodynamic parameters of ATP hydrolysis were determined for enzymes in the presence of the detergent lauryldimethylamine oxide (LDAO), which uncouples active transport and disables the inhibitory effect of the epsilon subunit. At 5 mM LDAO or greater, the inhibitory effects of epsilon subunit are abrogated in both purified F(1) and membranous F(o)F(1). In these conditions, LDAO solubilized F(o)F(1) has a higher k(cat) for ATP hydrolysis than F(1). These results indicate an influence of F(o) on F(1) even though catalysis is uncoupled from transport. The alpha(3)beta(3)gamma complex free of the epsilon subunit is activated at a lower concentration of 0.5 mM LDAO. Significantly, the gammaY205C mutant enzyme is similarly activated at 0.5 mM LDAO, suggesting that the mutant enzyme lacks epsilon inhibition. The gammaY205C F(o)F(1), which has a k(cat) for ATP hydrolysis 2-fold higher than wild type, has an ATP synthesis rate 3-fold lower than wild type, showing that coupling is inefficient. Arrhenius and isokinetic analyses indicate that enzymes that are free of epsilon subunit inhibition have a different transition-state structure from those under the influence of the epsilon subunit. We propose that the epsilon subunit is one of the factors that determines the proper transition-state structure, which is essential for efficient coupling.

Conformation of the gamma subunit at the gamma-epsilon-c interface in the complete Escherichia coli F(1)-ATPase complex by site-directed spin labeling.

Structure-function relationships of the gamma-epsilon-c subunit interface of F(O)F(1) ATP synthase, a region of subunit interactions important in coupling between catalysis and transport, were investigated by site-directed spin labeling and electron paramagnetic resonance (EPR) spectroscopy. The EPR line widths and collision accessibilities of 18 spin-labeled, unique cysteine F(1) mutants from gammaLeu198 to gammaLeu215 indicate an alternating pattern in the mobility and accessibility parameters for positions gamma201-209, which is reminiscent of a beta-strand. Labels at positions gamma204 and gamma210 show tertiary contact upon F(1) binding to F(O) and gammaD210C has reduced coupling efficiency. gammaE208C could not be spin labeled, but the uncoupling effects of gammaE208K are suppressed by second-site mutations in the polar loop of subunit c [Ketchum, C. J. and Nakamoto, R. K. (1998) J. Biol. Chem. 273, 22292-22297]. The restricted mobility and accessibility of spin labels in the odd-numbered positions between gamma201 and gamma207 plus the 2-4-fold higher values in k(cat) for ATP hydrolysis of these same mutant F(1) indicate that the interactions of these residues with the epsilon subunit mediate its inhibitory activity. Disrupted interactions with epsilon subunit also cause reduced coupling efficiency. We propose a model for the gamma-epsilon-c interface of Escherichia coli F(O)F(1) ATP synthase in which side chains from the odd-numbered residues of the gammaLys201-gammaTyr207 beta-strand directly and functionally interact with the epsilon subunit, while the even-numbered, acidic residues gammaAsp204, gammaGlu208, and gammaAsp210 interact with the F(O) sector, probably with subunit c. gamma Subunit interactions with both subunits in this region are important for coupling efficiency.