Thermal stress and Ca-independent contractile activation in mammalian skeletal muscle fibers at high temperatures.

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Thermal stress and Ca-independent contractile activation in mammalian skeletal muscle fibers at high temperatures.

K W Ranatunga

Department of Physiology, Medical School, University of Bristol, United Kingdom.

ABSTRACT

Temperature dependence of the isometric tension was examinedin chemically skinned, glycerinated, rabbit Psoas, muscle fibersimmersed in relaxing solution (pH approximately 7.1 at 20 degreesC, pCa approximately 8, ionic strength 200 mM); the averagerate of heating/cooling was 0.5-1 degree C/s. The resting tensionincreased reversibly with temperature (5-42 degrees C); thetension increase was slight in warming to approximately 25 degreesC (a linear thermal contraction, -alpha, of approximately 0.1%/degreeC) but became more pronounced above approximately 30 degreesC (similar behavior was seen in intact rat muscle fibers). Theextra tension rise at the high temperatures was depressed inacidic pH and in the presence of 10 mM inorganic phosphate;it was absent in rigor fibers in which the tension decreasedwith heating (a linear thermal expansion, alpha, of approximately4 x 10(-5)/degree C). Below approximately 20 degrees C, thetension response after a approximately 1% length increase (complete< 0.5 ms) consisted of a fast decay (approximately 150.s-1at 20 degrees C) and a slow decay (approximately 10.s-1) oftension. The rate of fast decay increased with temperature (Q10approximately 2.4); at 35-40 degrees C, it was approximately800.s-1, and it was followed by a delayed tension rise (stretch-activation)at 30-40.s-1. The linear rise of passive tension in warmingto approximately 25 degrees C may be due to increase of thermalstress in titin (connectin)-myosin composite filament, whereasthe extra tension above approximately 30 degrees C may arisefrom cycling cross-bridges; based on previous findings fromregulated actomyosin in solution (Fuchs, 1975), it is suggestedthat heating reversibly inactivates the troponin-tropomyosincontrol mechanism and leads to Ca-independent thin filamentactivation at high temperatures. Additionally, we propose thatthe heating-induced increase of endo-sarcomeric stress withintitin-myosin composite filament makes the cross-bridge mechanismstretch-sensitive at high temperatures.

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