Cation exchange binding of rubidium and cesium by rat liver cell microsomes

The rubidium and cesium binding characteristics of rat liver cell microsomes were studied by an equilibration, centrifugation and washing procedure. Concentration dependence experiments, in which microsomes were equilibrated in media containing 0 to 400 mM rubidium or cesium chloride at pH 6.9, yielded saturation type adsorption isotherms similar to those previously reported for sodium and potassium. Mass law analysis of the data yielded apparent dissociation constants of 21 × 10^?3 eq/liter and 19 × 10^?3 eq/liter for rubidium and cesium binding, respectively. The results indicate that cesium is bound slightly more strongly than rubidium, and that both these cations may be bound more strongly than sodium or potassium. The maximum binding capacity at pH 6.9 was approximately 1.3 meq rubidium or cesium/g nitrogen. Sodium, potassium, magnesium and calcium generally associated with the isolated microsomes decreased concomitantly with increasing bound rubidium or cesium, demonstrating the ion exchange nature of the binding. Results of pH-dependence experiments showed that following equilibration of the microsomes in media containing approximately 96 mM rubidium or cesium at various pH values, bound rubidium or cesium was essentially zero at pH less than five, increased sharply between pH 5 and 7, and tended to level off at higher pH. The present results further characterize the cation binding properties of the microsomal material.