Abstract
Striated muscle myosins are encoded by a large gene family in all mammals, including humans. These isoforms define several of the key characteristics of the different striated muscle fiber types, including maximum shortening velocity. We have previously used recombinant isoforms of the motor domains of seven different human myosin isoforms to define the actin·myosin cross-bridge cycle in solution. Here, we present data on an eighth isoform, the perinatal, which has not previously been characterized. The perinatal is distinct from the embryonic isoform, appearing to have features in common with the adult fast-muscle isoforms, including weak affinity of ADP for actin·myosin and fast ADP release. We go on to use a recently developed modeling approach, MUSICO, to explore how well the experimentally defined cross-bridge cycles for each isoform in solution can predict the characteristics of muscle fiber contraction, including duty ratio, shortening velocity, ATP economy, and load dependence of these parameters. The work shows that the parameters of the cross-bridge cycle predict many of the major characteristics of each muscle fiber type and raises the question of what sequence changes are responsible for these characteristics.
Highlights
1.401 Ϯ 0.101 3.022 Ϯ 0.935 a Ref. 39. b Ref. 14. c Endogenous mouse light chains are a combination of MLC1A, MLC3F, MLC1F, and MLC2F
We compared the information obtained for rabbit fast-muscle myosin with two human cardiac myosin isoforms (␣ and ) that we had characterized previously [6]
We argued that a similar load dependence is expected on the force-generating step/Pi release step, and for the values used in the cycle, a 3-fold reduction in kPi is required to slow the ATPase cycling rate under load, as has been reported for contracting muscle fibers [14, 15]
Summary
The ATPase cycle of human muscle myosin II isoforms: Adaptation of a single mechanochemical cycle for different physiological roles. We recently published a complete characterization of the kinetics of the ATPase cycle for the motor domains of six adult human muscle myosin isoforms and the embryonic isoform (6 –8) (see Table 1). We extend this data set to include the first study of the human perinatal myosin isoform. We show here that the perinatal isoform is quite distinct from the embryonic form and has more in common with adult fast-muscle isoforms With this large set of isoform data, it is possible to examine the extent to which differences in the ATPase cycle for each isoform can predict the differences in mechanochemical properties of muscle fibers expressing them. These parameters were used with the addition of the overall ATPase parameters for the cycle, the kcat (or Vmax), and Kapp
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