Structural snapshots of V/A-ATPase reveal the rotary catalytic mechanism of rotary ATPases

The rotary ATPases use a rotary catalytic mechanism to drive transmembrane proton movement powered by ATP hydrolysis. Here, the authors report a collection of V/A-ATPase V-1 domain structures, providing insights into rotary mechanism of the enzyme and potentially other rotary motor proteins driven by ATP hydrolysis. V/A-ATPase is a motor protein that shares a common rotary catalytic mechanism with FoF1 ATP synthase. When powered by ATP hydrolysis, the V-1 domain rotates the central rotor against the A(3)B(3) hexamer, composed of three catalytic AB dimers adopting different conformations (AB(open), AB(semi), and AB(closed)). Here, we report the atomic models of 18 catalytic intermediates of the V-1 domain of V/A-ATPase under different reaction conditions, determined by single particle cryo-EM. The models reveal that the rotor does not rotate immediately after binding of ATP to the V-1. Instead, three events proceed simultaneously with the 120 rotation of the shaft: hydrolysis of ATP in AB(semi), zipper movement in AB(open) by the binding ATP, and unzipper movement in AB(closed) with release of both ADP and Pi. This indicates the unidirectional rotation of V/A-ATPase by a ratchet-like mechanism owing to ATP hydrolysis in AB(semi), rather than the power stroke model proposed previously for F-1-ATPase.

Automated summary

The authors report the atomic models of 18 catalytic intermediates of the V-1 domain of V/A-ATPase under different reaction conditions, determined by single particle cryo-EM. The models reveal that the rotor does not immediately rotate after the binding of ATP, but undergoes multiple events including ATP hydrolysis and release of ADP and Pi during the rotation process.