Specificities of cation permeabilities induced by some crown ethers in mitochondria

A series of macrocyclic crown ethers have been assayed as ionophores using respiring rat liver mitochondria, and the same compounds have been subjected to physicochemical investigation. Association constants and stoichiometries for the complexes with potassium, rubidium, and cesium were measured in methanol. Rates of transport of potassium bromide through aqueous/organic/aqueous systems and the partition coefficient from water into the organic phase were also measured and found to be in the same rank order as the association constants. Effective uptake by the mitochondria was clearly correlated with the complexing by the cation by one or more molecules of ionophore. Thus, for all three cations the most effective compound was the largest, i.e., di-t-butyldibenzo-30-crown-10, capable of wrapping around the cation. Other compounds giving measurable uptake were those which form sandwich complexes, one cation to two crown molecules; those containing five oxygen atoms induced greater uptake of potassium than of the other two alkali metals, while compounds containing six or seven oxygen atoms had greater effects on cesium or rubidium than on potassium. Within a structurally similar series of compounds the rank orders for uptake differed from those for the association constants; in particular, compounds having one benzene ring on an 18-membered crown compound were ineffective on all cations studied; effective compounds contained two benzene rings. In contrast to X-537A and A23187, none of the compounds caused release of magnesium from the mitochondria.