Abstract
We examined the magnesium dependence of five class II myosins, including fast skeletal muscle myosin, smooth muscle myosin, β-cardiac myosin (CMIIB), Dictyostelium myosin II (DdMII), and nonmuscle myosin IIA, as well as myosin V. We found that the myosins examined are inhibited in a Mg(2+)-dependent manner (0.3-9.0 mm free Mg(2+)) in both ATPase and motility assays, under conditions in which the ionic strength was held constant. We found that the ADP release rate constant is reduced by Mg(2+) in myosin V, smooth muscle myosin, nonmuscle myosin IIA, CMIIB, and DdMII, although the ADP affinity is fairly insensitive to Mg(2+) in fast skeletal muscle myosin, CMIIB, and DdMII. Single tryptophan probes in the switch I (Trp-239) and switch II (Trp-501) region of DdMII demonstrate these conserved regions of the active site are sensitive to Mg(2+) coordination. Cardiac muscle fiber mechanic studies demonstrate cross-bridge attachment time is increased at higher Mg(2+) concentrations, demonstrating that the ADP release rate constant is slowed by Mg(2+) in the context of an activated muscle fiber. Direct measurements of phosphate release in myosin V demonstrate that Mg(2+) reduces actin affinity in the M·ADP·Pi state, although it does not change the rate of phosphate release. Therefore, the Mg(2+) inhibition of the actin-activated ATPase activity observed in class II myosins is likely the result of Mg(2+)-dependent alterations in actin binding. Overall, our results suggest that Mg(2+) reduces the ADP release rate constant and rate of attachment to actin in both high and low duty ratio myosins.
Highlights
Magnesium may be an important physiological regulator of myosin motor activity
By examining the Mg2ϩ dependence of a number of muscle and nonmuscle myosins, we demonstrate that conserved mechanisms likely mediate the impact of free Mg2ϩ on the myosin mechanochemical cycle
Our current results demonstrate that the slowing of the ADP release rate constant as a function of increasing free Mg2ϩ concentration is a conserved feature of myosin motors
Summary
Magnesium may be an important physiological regulator of myosin motor activity. Results: Mg2ϩ inhibits the ADP release rate constant in the subset of myosins examined and reduces actin affinity in the post-hydrolysis state in myosin V. Recent studies highlight the possibility that free Mg2ϩ can modulate motor activity and physiological function in muscle myosin II and unconventional myosins I, V, and VII [3,4,5,6,7] These studies generally support a mechanism whereby Mg2ϩ alters key steps in the mechanochemical cycle, including the ADP release rate constant, which is an important determinant of duty ratio (fraction of the ATPase cycle myosin remains attached to actin). Because the ADP release step is rate-limiting in myosin V, increasing free Mg2ϩ concentration slows the myosin V ATPase activity as well as sliding velocity [9, 13] based on a detachment-limited model for in vitro motility. We demonstrate that multiple steps in the actomyosin ATPase cycle are sensitive to changes in physiological free Mg2ϩ concentrations
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