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The force response of cardiac muscle undergoing a quick stretch is conventionally interpreted to represent stretching of attached myosin crossbridges (phase 1) and detachment of these stretched crossbridges at an exponential rate (phase 2), followed by crossbridges reattaching in increased numbers due to an enhanced activation of the thin filament (phases 3 and 4). We propose that, at least in mammalian cardiac muscle, phase 2 instead represents an enhanced detachment rate of myosin crossbridges due to stretch, phase 3 represents the reattachment of those same crossbridges, and phase 4 is a passive-like viscoelastic response with power-law relaxation. To test this idea, we developed a two-state model of crossbridge attachment and detachment. Unitary force was assigned when a crossbridge was attached, and an elastic force was generated when an attached crossbridge was displaced. Attachment rate, f(x), was spatially distributed with a total magnitude f0. Detachment rate was modeled as g(x) = g0+ g1x, where g0 is a constant and g1 indicates sensitivity to displacement. The analytical solution suggested that the exponential decay rate of phase 2 represents (f0 + g0) and the exponential rise rate of phase 3 represents g0. The depth of the nadir between phases 2 and 3 is proportional to g1. We prepared skinned mouse myocardium and applied a 1% stretch under varying concentrations of inorganic phosphate (Pi). The resulting force responses fitted the analytical solution well. The interpretations of phases 2 and 3 were consistent with lower f0 and higher g0 with increasing Pi. This novel scheme of interpreting the force response to a quick stretch does not require enhanced thin-filament activation and suggests that the myosin detachment rate is sensitive to stretch. Furthermore, the enhanced detachment rate is likely not due to the typical detachment mechanism following MgATP binding, but rather before MgADP release, and may involve reversal of the myosin power stroke. 

Background and PurposeHeart failure can reflect impaired contractile function at the myofilament level. In healthy hearts, myofilaments become more sensitive to Ca²⁺as cells are stretched. This represents a fundamental property of the myocardium that contributes to the Frank–Starling response, although the molecular mechanisms underlying the effect remain unclear. Mavacamten, which binds to myosin, is under investigation as a potential therapy for heart disease. We investigated how mavacamten affects the sarcomere‐length dependence of Ca²⁺‐sensitive isometric contraction to determine how mavacamten might modulate the Frank–Starling mechanism. Experimental ApproachMulticellular preparations from the left ventricular‐free wall of hearts from organ donors were chemically permeabilized and Ca²⁺activated in the presence or absence of 0.5‐μM mavacamten at 1.9 or 2.3‐μm sarcomere length (37°C). Isometric force and frequency‐dependent viscoelastic myocardial stiffness measurements were made. Key ResultsAt both sarcomere lengths, mavacamten reduced maximal force and Ca²⁺sensitivity of contraction. In the presence and absence of mavacamten, Ca²⁺sensitivity of force increased as sarcomere length increased. This suggests that the length‐dependent activation response was maintained in human myocardium, even though mavacamten reduced Ca²⁺sensitivity. There were subtle effects of mavacamten reducing force values under relaxed conditions (pCa 8.0), as well as slowing myosin cross‐bridge recruitment and speeding cross‐bridge detachment under maximally activated conditions (pCa 4.5). Conclusion and ImplicationsMavacamten did not eliminate sarcomere length‐dependent increases in the Ca²⁺sensitivity of contraction in myocardial strips from organ donors at physiological temperature. Drugs that modulate myofilament function may be useful therapies for cardiomyopathies.