Mechanisms of Mechanochemical Coupling in Low and High Duty Ratio Myosins

Abstract

All myosins undergo the same ATP dependent biochemical cycle but with variations in the lifetime of the individual states of the cycle and the fraction of the total cycle time spent in each state. E.g., processive class-5 myosins are high duty ratio motors that stay most of the ATPase cycle time (> 0.5) attached to actin, whereas fast myosins such as muscle myosin-2 and some class-1 myosin members have a low duty ratio (< 0.1). The members of the respective groups are assumed to use different ways to couple conformational changes at the nucleotide binding regions to changes that occur at the actin binding sites. Conserved active-site elements termed switch-1 and switch-2 play a major role in the coupling mechanism; however, whether and to which extent small variations in the sequence of switch-1 and switch-2 affect the duty ratio of a given myosin, thus determining its ability for processive movement, fast contractility or tension bearing remains unresolved. Based on structural considerations and confirmed by mutational analyses, we identified key residues in the nucleotide binding pocket that are responsible for making ADP dissociation kinetics dependent on the concentration of free magnesium ions. The exchange of a single amino acid in switch-2 affected the motor properties of all myosins tested, but also transformed low duty ratio motors into high duty ratio and vice versa. In addition, x-ray structural analyses and molecular modeling allowed us to relate the observed changes to altered coupling between the active sites and actin binding regions. These results, together with our cell biological studies demonstrating for the first time that magnesium ions have a regulatory role on motor protein function in vivo reveal that, switch-2 can act as magnesium sensor critically determining the mechanochemical properties of myosins.