Lead and calcium transport in human erythrocyte.

In this paper we report the lead (Pb) and calcium (Ca) uptake by erythrocyte ghosts. In both cases the transport was carried out by a passive transport system with two kinetic components (Michaelis-Menten and Hill). Pb and Ca were capable of inhibiting the transport of the other metal in a non-competitive way. Under hyperpolarization, the uptakes of Ca and Pb were enhanced and the Michaelis-Menten component prevailed. Both Ca and Pb uptakes were inhibited by N-ethyl-maleimide to the same extent. These results indicate that Pb and Ca share the same permeability pathway in human erythrocytes and that this transport system is electrogenic.

Effect of lead on the calcium transport in human erythrocyte.

In this paper we study the calcium uptake in the erythrocyte, a non-excitable cell. This uptake is performed through a passive transport system with two kinetic components (Michaelis-Menten and Hill). The uptake of calcium seems to be driven by voltage through its electrophoretical effect. Lead is capable of inhibiting calcium uptake in a non-competitive manner. As it has been described in other systems, lead is also capable of inhibiting calcium efflux by inhibiting Ca(Mg)-ATPase. Under physiological conditions, the function of ATPase reduces the effect of lead on calcium influx. However, in chronic intoxication a small increment of intracellular calcium is observed, indicating that lead is affecting calcium efflux mainly. We discuss the effects of lead on calcium equilibrium in erythrocytes.