EFFECTS OF ALUMINUM ON ELECTRICAL AND MECHANICAL-PROPERTIES OF FROG ATRIAL MUSCLE

1 The effects of aluminium on membrane ionic currents were studied in single cardiac myocytes. Most of the work was done on frog atrial cells, but some experiments were also carried out on single cells isolated from rabbit ventricles and atria. 2 The effects of aluminium on the force of contraction of frog atrial trabeculae were also investigated. 3 Aluminium was prepared from AlCl3 as a stock 0.5 M solution which has a pH of 3.5. Before each experiment, this solution was added to the control solution, to give a final concentration of 20-100-mu-g ml-1 aluminium (0.75-3.75 mM AlCl3). The solutions were brought to a pH of 7.4 or 7.6, at which they consist of a mixture of amorphous aluminium hydroxides and a very small amount of soluble ionic aluminium complexes: free aluminium cations (less than 10 pM), aluminohydroxide anions (less than 8-mu-M). The addition of this suspension reduced the peak inward calcium currents in single rabbit atrial and ventricular cells and in frog atrial cells. In the latter, the peak current was reduced (at + 10 mV) to 45% of control (mean of 9 cells). This effect was reversible upon washout, and was obtained at all membrane potentials, with no shift of the calcium current voltage relationship along the voltage axis. 4 Aluminium also reduced the time-dependent potassium current I(K). This reduction was observed at all membrane potentials. For example, at + 10 mV, the mean reduction of I(K) (n = 9) was to 69% of the control amplitude. This effect, which was very difficult to reverse, was not due to I(K) rundown. The fully activated current-voltage relationships (obtained by standard 'tail' analysis) showed that the effect of aluminium was due mainly to a decrease in conductance and not to a shift in the activation range of I(K). The mean voltage of half activation was shifted by 8 mV in the depolarizing direction (n = 5). 5 The background potassium current IK1 was also slightly but consistently changed in a complex fashion, with an outward shift at membrane potentials positive to -60mV. For example, at a membrane potential of -40 mV, the mean shift was 22 +/- 4 pA. At more negative potentials, there was an inward shift in the current amplitudes. For example, for steps to -100 mV the current elicited was larger (more inward) by 53 pA (mean value, n = 10). The reversal potential was slightly shifted (< 10 mV) in the hyperpolarizing direction. 6 The force of contraction of frog atrial trabeculae was altered by aluminium in a complex manner, which showed marked seasonal variation. During most of the year, 50-100-mu-g ml-1 aluminium caused a biphasic change, with an early small and consistent decrease, followed by a large increase in twitch amplitude. For a short period corresponding to the (local) winter months the sensitivity to aluminium was greatly enhanced. Aluminium 100-mu-g ml-1 totally abolished contraction (n = 5), while a lower concentration (20-mu-g ml-1) produced a sustained reduction in the force of contraction. Similar biphasic and seasonal responses have been reported to be induced by lanthanum. 7 The biphasic changes in twitch amplitude were independent of the transmembrane sodium gradient. Aluminium produced the same effects when 90% of the extracellular sodium was replaced by lithium. Caffeine (5 mM) attenuated or even inverted the positive inotropic effect of aluminium. These results imply that aluminium alters the release of calcium from intracellular, caffeine-sensitive stores. This could be effected either by augmenting the amount released during each activation, and/or by increasing the loading of stores prior to release. 8 These results are discussed in light of several of the previously reported actions of aluminium.