Comparative study of the effects of propranolol and tetracaine on cation movements in resealed human red cell ghosts.

Abstract

1. The effects of two positively charged local anaesthetic amines, tetracaine and propranolol, on cation permeability were studied in resealed human red cell ghosts prepared from metabolically depleted erythrocytes. 2. The K permeability was reduced by tetracaine but increased by propranolol. The effect of tetracaine was independent of extracellular Ca concentration but was raised to 2-5 x 10(-7) M. The effect of propranolol, which was enhanced when the external Ca concentration was raised, could be completely inhibited by lowering the internal free Ca to less than 10(-7) M. 3. Propranolol, but not tetracaine, increased the intracellular Ca ion concentration by releasing up to 20% of the membrane-bound Ca to the cell interior. This increase in intracellular Ca was sufficient to mediate the observed change in K permeability. 4. Tetracaine and propranolol reduced the Ca binding capacity of the ghost membrane by about 20 and 40% respectively. The Ca permeability was increased by propranolol and was slightly reduced by tetracaine. 5. In high concentrations (2-7 mM) propranolol by itself moderately increased K and Na permeability, but supressed completely the Ca-induced increase in K permeability. Tetracaine in concentrations up to 4 mM enhanced the Ca-induced increase in K permeability. Higher concentrations of the drug caused lysis of the cells. 6. Maximally effective concentrations of tetracaine and propranolol inhibited the ATP-dependent Ca outward transport by 30 and 70% respectively. 7. The effects of tetracaine on K permeability were shared by the local anaesthetics prilocaine and lidocaine, those of propranolol were shared by practolol, a beta-adrenergic antagonist and tetraethylammonium, a ganglionic blocking agent. 8. It is suggested that the differences in the effects of tetracaine and propranolol on cation permeability reflect qualitatively different interactions of the two drugs with Ca binding sites on the inner surface of the membrane.