Abstract
Small sinusoidal vibrations at 300 Hz were applied to frog sartorius muscle to measure the dynamic stiffness (Young's modulus) throughout the course of tetanus. For a peak-to-peak amplitude of 0.4% the dynamic Young's modulus increased from 1.5×105 Nm−2 in the resting state to 2×107 Nm−2 in tetanus. After correction for the external connective tissue, the dynamic Young's modulus of the muscle was almost directly proportional to the tension throughout the development of tetanus. The ratio of dynamic Young's modulus to tensile stress thus remained constant (with a value at 300 Hz of approximately 100), consistently with Huxley and Simmons' identification of the crossbridges as the source of both tension and stiffness.
For a single crossbridge the ratio of stiffness to tension was 8.2×107 m−1 at 300 Hz; it is deduced from literature data that the limiting value at high frequencies is about 1.6×108 m−1. This ratio is interpreted on Harrington's (1971) model to show that crossbridge action can be explained by a helix-coil transition of about 80 out of the 260 residues in each S-2 myosin strand. It is also shown that a helix-coil model can account for the observed rapid relaxation of muscle without invoking any complex behaviour of the crossbridge head.
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Mason, P. Dynamic stiffness and crossbridge action in muscle. Biophys. Struct. Mechanism 4, 15–25 (1978). https://doi.org/10.1007/BF00538837
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DOI: https://doi.org/10.1007/BF00538837