Excitation-Contraction Coupling in a Barnacle Muscle Fiber As Examined with Voltage Clamp Technique

Abstract

Relations between the membrane potential and the tension associated with changes in membrane potential were analyzed in barnacle giant muscle fibers by using voltage clamp techniques. With a step change in membrane potential the tension reaches its final level with a time course which is expressed by the difference of two exponential functions. The time constants τ₁ (0.2–0.4 sec at 23°C) and τ₂ (0.07–0.12 sec at 23°C) are independent of the new membrane potential at least for a relatively small membrane potential change while the final level of tension is a function of the potential. Decreasing the temperature increases both τ₁ and τ₂ (Q₁₀ = -2 to -3) and the increase of the tonicity of the external medium increases τ₁ but not τ₂. The final level of tension is related by an S-shaped curve to the membrane potential. The slope of the final tension-membrane potential curve increases with increasing external Ca concentration and is reduced when a small amount of transition metal ions is added to the medium. This suggests that the influx of Ca ions through the membrane is an important factor in the development of tension.