FUSICOCCIN ACTIVATES THE PLASMA-MEMBRANE H+-ATPASE BY A MECHANISM INVOLVING THE C-TERMINAL INHIBITORY DOMAIN

Plasma membrane vesicles isolated from spinach leaves incubated with the fungal toxin fusicoccin showed a twofold increase in ATP hydrolytic activity and a threefold increase in H+ pumping compared to controls. This increase in H+-ATPase activity was largely completed within 4 min of incubation and was not due to de novo synthesis of H+-ATPase as demonstrated by immunoblotting. Incubation with fusicoccin also resulted in a decrease in the apparent K(m) for ATP of the H+-ATPase from 0.22 to 0.10 mM. The fusicoccin-mediated activation of H+-ATPase activity and the accompanying decrease in the K(m) for ATP are changes very similar to those observed upon trypsin activation of the H+-ATPase, where an autoinhibitory domain in the C-terminal region of the H+-ATPase is removed. Thus, trypsin treatment of plasma membrane vesicles from control leaves gave a twofold increase in ATP hydrolytic activity and a threefold increase in H+ pumping, as well as a decrease in the apparent K(m) for ATP of the H+-ATPase from 0.22 to 0.10 mM. Trypsin treatment of plasma membranes from fusicoccin-incubated leaves did not further enhance the H+-ATPase activity, however, and neither was the K(m) for ATP further decreased. That trypsin really removed a small segment from the fusicoccin-activated H+-ATPase was confirmed by immunoblotting, which allowed the appearance of a 90-kD band in addition to the native 100-kD H+-ATPase band upon trypsin treatment. Taken together, our data suggest that in vivo activation of the H+-ATPase by fusicoccin proceeds by a mechanism involving a displacement of the C-terminal inhibitory domain.