OSMOTIC COMPRESSION OF SKINNED CARDIAC AND SKELETAL-MUSCLE BUNDLES - EFFECTS ON FORCE GENERATION, CA2+ SENSITIVITY AND CA2+ BINDING

Length-dependence of myofilament Ca2+ sensitivity is now considered to be an important component of the steep relationship between active force and sarcomere length along the ascending limb of the cardiac force-length curve. Studies with skinned cardiac muscle preparations have demonstrated that Ca2+-troponin C affinity is significantly increased as sarcomere length is increased over the range 1.7-2.3 mu m. Increase in sarcomere length is accompanied by a reduction in interfilament spacing. In skinned fiber preparations from both cardiac and skeletal muscle osmotic compression of the filament lattice enhances myofilament Ca2+ sensitivity. This study was undertaken to evaluate the hypothesis that a change in filament separation may contribute to the length-dependent activation seen in cardiac muscle. Moderate reduction in interfilament spacing caused by exposure to Dextran T-500 (5-10%) produced an increase in force generation in both maximally activated and partially activated preparations of skinned bovine ventricular muscle. With fiber bundles of mean sarcomere length 1.7 mu m the addition of 5% Dextran T-500 produced an increase in Ca2+ sensitivity of about 0.25 pCa units and a significant increase in Ca2+ binding in the pCa range (6.0-5.0) in which the single regulatory site of cardiac troponin C is titrated. This concentration of Dextran T-500 produced a reduction in fiber width equivalent to that produced by stretching fibers from sarcomere length 1.7 mu m to sarcomere length 2.3 mu m. Osmotic compression of skinned rabbit psoas muscle fibers also enhanced Ca2+ sensitivity but there was no significant change in Ca2+-troponin C affinity. These data suggest that 1) an important component of length-dependent Ca2+ sensitivity in both cardiac and skeletal muscle is the change in interfilament spacing, and 2) in cardiac muscle a reduction in spacing, like increase in length, leads to a specific increase in Ca2+-troponin C affinity. Thus both filament overlap and filament separation contribute to the length dependence of Ca2+ sensitivity and Ca2+ binding in cardiac muscle.