Factors affecting the transient tension change after applying stepwise length change to glycerol-treated muscle fibers. Effects of temperature, divalent cations, and modification with p-chloromercuribenzoate.

Abstract

The dynamic properties of cross-bridge movement were investigated in glycerol-treated muscle fibers under various conditions by analyzing tension responses to two types of length change. First, the fiber bundles were stretched linearly with time for 0.3 s from the rest length (L0) by 2.5% of L0, suddenly released, then fixed at L0 (sudden release of the slow stretch). Second, they were stretched for 0.01 s by 2.5% of L0, then held at the plateau length (a quick stretch). 1. The transient tension responses following both length changes were divided into three phases: (i) very quick recovery of tension (0 approximately 0.05 s), (ii) quick recovery (0.05 approximately 0.3-0.4 s), and (iii) gradual recovery (0.3-0.4 s approximately several seconds). 2. The effects of activating conditions on the rates of the quick phases (0 approximately 0.3-0.4 s) were not associated with those on the nucleoside triphosphatase [EC 3.6.1.3] rates: the rates of the quick phases increased with increase in temperature and Mg2+-ATP concentration, with decrease in Ca2+ concentration, and also on replacement of Mg2+-ATP by Mg2+-ITP or Mn2+-ATP. Only a small amount of ADP, 0.07 mol per mol of myosin (Fig. 24 in the preceding paper), was liberated during the quick recovery phases. 3. The remaining slow tension recovery was concluded to be associated with one cycle of ATP splitting, and progressed very smoothly. This suggests that most of the cross-bridges do not exist in a synchronously dissociated state during one cycle of ATP splitting.