Abstract
1. We examined the hypothesis that in skeletal muscle the steep relationship between twitch tension and sarcomere length (SL) within the range 2.30 to 1.85 microns involves SL-dependent alterations in the rate of tension development. 2. In skinned preparations of both rat slow-twitch and rabbit fast-twitch skeletal muscle fibres the rate of tension redevelopment (ktr) at 15 degrees C was reduced at short SL (approximately 2.00 microns) compared with a longer SL (approximately 2.30 microns). In submaximally activated fibres, the decrease in ktr over this range of lengths was greater in fast-twitch fibres (38% reduction) than in slow-twitch fibres (14% reduction). 3. Ca2+ sensitivity of tension, as assessed as the pCa (-log[Ca2+]) for half-maximal activation, or pCa50, decreased to a greater extent in rabbit fast-twitch skeletal muscle fibres than in slow-twitch fibres from both rabbit and rat when SL was reduced from approximately 2.30 to approximately 1.85 microns. The delta pCa50 over this SL range was 0.24 +/- 0.07 pCa units in fast-twitch fibres from rabbit psoas muscle. The delta pCa50 for slow-twitch fibres from rabbit and rat soleus muscle was 0.08 +/- 0.02 and 0.10 +/- 0.04 pCa units, respectively. 4. Osmotic compression of both slow-twitch and fast-twitch fibres at a SL of 2.00 microns increased ktr to values similar to those obtained at a SL of 2.30 microns in the absence of dextran. This result indicates that the slower rate of tension redevelopment at short SL is due in large part to the increase in interfilament lattice spacing associated with shorter SL. 5. Taken together, these results suggest that length dependence of twitch tension is, in part, due to length dependence of isometric cross-bridge interaction kinetics, an effect that is mediated by length-dependent changes in interfilament lattice spacing.