Comparison of myoplasmic calcium movements during excitation-contraction coupling in frog twitch and mouse fast-twitch muscle fibers

Abstract

Single twitch fibers from frog leg muscles were isolated by dissection and micro-injected with furaptra, a rapidly responding fluorescent Ca2+ indicator. Indicator resting fluorescence (FR) and the change evoked by an action potential (ΔF) were measured atlong sarcomere length (16°C); ΔF/FR was scaled to units of ΔfCaD, the change in fraction of the indicator in the Ca2+-bound form. ΔfCaD was simulated with a multicompartment modelof the underlying myoplasmic Ca2+ movements, and the results were compared with previous measurements and analyses in mouse fast-twitch fibers. In frog fibers, sarcoplasmic reticulum (SR) Ca2+ release evoked by an action potential appears to be the sum of two components. The time course of the first component is similar to that of the entire Ca2+ release waveform in mouse fibers, whereas that of the second component is severalfold slower; the fractional release amounts are ̃0.8 (first component) and ̃0.2 (second component). Similarresults were obtained in frog simulations with a modified model that permitted competition between Mg2+ and Ca2+ for occupancy of the regulatory sites on troponin. An anatomical basis for two release components in frog fibers is the presence of both junctional and parajunctional SR Ca2+ release channels (ryanodine receptors [RyRs]), whereas mouse fibers (usually) have only junctional RyRs. Also, frog fibers have two RyR isoforms, RyRα and RyRβ, whereas the mouse fibers (usually) have only one, RyR1. Our simulations suggest that the second release component in frog fibers functions to supply extra Ca2+ to activate troponin, which, in mouse fibers, is not needed because of the more favorable location of their triadic junctions (near the middle of the thin filament). We speculate that, in general, parajunctional RyRs permit increased myofilament activation in fibers whose triadicjunctions are located at the z-line. © 2013 Hollingworth and Baylor.