Mechanism of the actomyosin ATPase: effect of actin on the ATP hydrolysis step.

The Lymn-Taylor model for the actomyosin ATPase suggests that during each cycle of ATP hydrolysis the complex of myosin subfragment 1 (S-1) with actin must dissociate into S-1.ATP plus actin before ATP hydrolysis can occur. In the present study we tested whether such a mandatory detachment step occurs by measuring the effect of actin on the rate and magnitude of the ATP hydrolysis step (initial Pi burst) and on the steady-state ATPase rate. We find that the rate of the initial Pi burst markedly increases at high actin concentration although the Lymn-Taylor model predicts the rate should remain nearly constant or decrease. In addition, at high actin concentration, the magnitude of the initial Pi burst is much larger than is predicted by the Lymn-Taylor model. Finally, at 360 microM actin, at which more than 90% of the S-1.ATP is bound to actin, there is no inhibition of the steady-state ATPase activity although the Lymn-Taylor model predicts that 70% inhibition should occur. We conclude that the acto-S-1 complex is not dissociated by ATP during each cycle of ATP hydrolysis; in fact, the rate of the initial Pi burst appears to be even faster when S-1.ATP is bound to actin than when it is dissociated.