Abstract
Vertebrate striated muscle thin filaments are thought to be thermodynamically activated in response to an increase in Ca2+ concentration. We tested this hypothesis by measuring time intervals for gliding runs and pauses of individual skeletal muscle thin filaments in cycling myosin motility assays. A classic thermodynamic mechanism predicts that if chemical potential is constant, transitions between runs and pauses of gliding thin filaments will occur at constant rate as given by a Poisson distribution. In this scenario, rate is given by the odds of a pause, and hence, run times between pauses fit an exponential distribution that slopes negatively for all observable run times. However, we determined that relative density of observed run times fits an exponential only at low Ca2+ levels that activate filament gliding. Further titration with Ca2+, or adding excess regulatory proteins tropomyosin and troponin, shifted the relative density of short run times to fit the positive slope of a gamma distribution, which derives from waiting times between Poisson events. Events that arise during a run and prevent the chance of ending a run for a random interval of time account for the observed run time distributions, suggesting that the events originate with cycling myosin. We propose that regulatory proteins of the thin filament require the mechanical force of cycling myosin to achieve the transition state for activation. During activation, combinations of cycling myosin that contribute insufficient activation energy delay deactivation.
Highlights
The crucial, second step of a two-step process for thin filament activation of vertebrate striated muscles involves shifting of filamentous tropomyosin (Tm) on the helical backbone of Factin from a position that blocks interaction with myosin (Bposition) to a position that permits myosin crossbridge cycling (M-position) [1, 2]
Binary activation of individual regulatory units is demonstrated by clusters of myosin that form around nascent pairs of myosin in foci along a thin filament [31]
To provide an initial assessment of the quality of our assay, we exposed native thin filaments to Ca21 concentrations that bracketed the extremes of physiologically relevant Ca21
Summary
The crucial, second step of a two-step process for thin filament activation of vertebrate striated muscles involves shifting of filamentous tropomyosin (Tm) on the helical backbone of Factin from a position that blocks interaction with myosin (Bposition) to a position that permits myosin crossbridge cycling (M-position) [1, 2]. Energy required for thin filament activation most frequent for all observable intervals of time, as predicted by the exponential distribution.
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