Human myosin Vc is a low duty ratio, nonprocessive molecular motor.
Abstract:
Myosin Vc is the product of one of the three genes of the class
V myosin found in vertebrates. It is widely found in secretory
and glandular tissues, with a possible involvement in
transferrin trafficking. Transient and steady-state kinetic
studies of human myosin Vc were performed using a truncated,
single-headed construct. Steady-state actin-activated ATPase
measurements revealed a V(max) of 1.8 +/- 0.3 s(-1) and a
K(ATPase) of 43 +/- 11 microm. Unlike previously studied
vertebrate myosin Vs, the rate-limiting step in the actomyosin
Vc ATPase pathway is the release of inorganic phosphate (~1.5
s(-1)), rather than the ADP release step (~12.0-16.0 s(-1)).
Nevertheless, the ADP affinity of actomyosin Vc (K(d) = 0.25 +/-
0.02 microm) reflects a higher ADP affinity than seen in other
myosin V isoforms. Using the measured kinetic rates, the
calculated duty ratio of myosin Vc was approximately 10%,
indicating that myosin Vc spends the majority of the actomyosin
ATPase cycle in weak actin-binding states, unlike the other
vertebrate myosin V isoforms. Consistent with this, a
fluorescently labeled double-headed heavy meromyosin form showed
no processive movements along actin filaments in a single
molecule assay, but it did move actin filaments at a velocity of
approximately 24 nm/s in ensemble assays. Kinetic simulations
reveal that the high ADP affinity of actomyosin Vc may lead to
elevations of the duty ratio of myosin Vc to as high as 64%
under possible physiological ADP concentrations. This, in turn,
may possibly imply a regulatory mechanism that may be sensitive
to moderate changes in ADP concentration.