1. Joule temperature jumps (T-jumps) from 5-9-degrees-C up to 40-degrees-C were used to study the cross-bridge kinetics and thermodynamics in skinned rabbit muscle fibres. To produce a T-jump, an alternating current pulse was passed through a fibre 5 s after removing the activating solution (pCa congruent-to 4.5) from the experimental trough. The pulse frequency was congruent-to 30 kHz, amplitude less-than-or-equal-to 3 kV, and duration 0.2 ms. The pulse energy liberated in the fibre was calculated using a special analog circuit and then used for estimation of the T-jump amplitude. 2. The T-jump induced a tri-exponential tension transient. Phases 1 and 2 had rate constants k1 = 450-1750 s-1 and k2 = 60-250 s-1 respectively, characterizing the tension rise, whereas phase 3 had a rate constant k3 = 5-10 s-1 representing tension recovery due to the fibre cooling. 3. An increase from 13 to 40-degrees-C for the final temperature achieved by the T-jump led to an increase in the amplitudes of phases 1 and 2. After T-jumps to 30-40-degrees-C during phase 1, tension increased by 50-80%. During phase 2 an approximately 2-fold tension increase continued. Rate constants k1 and k2 increased with temperature and temperature coefficients (Q10) were 1.6 and 1.7, respectively. 4. To study which processes in the cross-bridges are involved in phases 1 and 2, a series of experiments were made where step length changes of -9 to +3 nm (hs)-1(nanometres per half-sarcomere length) were applied to the fibre 4 ms before the T-jump. 5. After the step shortening, the rate constant of phase 1 increased, whereas its amplitude decreased compared to those without a length change. This indicates that phase 1 is determined by some force-generating process in the cross-bridges attached to the thin filaments. This process is, most probably, the same as that producing the early tension recovery following the length change. The enthalpy change (DELTA-H) associated with the reaction controlling this process was estimated to be positive (15-30 kJ mol-1). 6. Both the rate constant k2 and the maximal tension achieved at the end of phase 2 were practically independent of the preceding length changes. This means that phase 2 is accompanied by the cross-bridge detachment and reattachment to new sites on the thin filaments. 7. A simple three-state model of the cross-bridge kinetics is proposed to explain the experimental data.
