Calcium‐sodium antagonism on the frog's heart: a voltage‐clamp study.

Abstract

In double sucrose-gap voltage-clamped frog atrial fibers the influence of [Ca]o and [Na]o on membrane current and contraction was investigated. The slow (secondary) inward current varied with [Ca]o but was almost insensitive to changes in [Na]o. The phasic (transient) contraction initiated by the slow inward current was affected by both [Ca]o and [Na]o. With moderate changes of [Ca]o and [Na]o from normal, the strength of phasic contraction at a given depolarization followed the .**GRAPHIC**. ratio approximately. This was best seen at membrane potentials near zero level. Under the same conditions, tonic (sustained) contractions associated with prolonged depolarizations were strictly correlated to the .**GRAPHIC**. ratio at any potential. No interrelation between tonic tension and steady-state current was found. With extensive changes in [Ca]o and [Na]o, the sensitivity of both phasic and tonic tension to the .**GRAPHIC**. ratio declined, the negative effect of [Na]o becoming smaller than was expected from this ratio. In Na-free choline-Ringer, a strong contracture developed followed by a spontaneous relaxation. Starting from the relaxed state, application of depolarizing clamps gave rise to phasic contractions with a very slow relaxation while tonic contractions were apparently lacking. The results are interpreted in terms of an energy-dependent carrier mechanism exchanging 1 Ca for 2 Na ions across the cell membrane. The model implies a strong asymmetry in the rate constants governing the chemical reactions on both sides of the membrane. The system is thought to operate close to equilibrium at any potential, thereby determining the steady level of myoplasmic Ca. The equilibrium itself is considered to shift upon depolarization. Assuming that [Na]1 is constant, the steady level of [Ca]1 is expected to be proportional to the .**GRAPHIC**. ratio, the scale factor being a function of membrane potential. The carrier model suggests the occurrence of a depolarization-induced inward transfer of Ca which might be involved in the generation of tonic contractions. The apparent lack of tonic contractions in the absence of external Na ions may be explained by a suppression of carrier-mediated Ca influx normally occurring upon depolarization. The antagonistic effects of [Ca]o and [Na]o on phasic contraction are understood as being due to alterations of the Ca pumping system rather than changes in slow inward current.