Study of the bidirectional transport of choline by blocking choline carriers from outside or inside brain nerve terminals.

Membrane carriers can operate bidirectionally. We studied, in rat neocortex synaptosomes, the choline carrier by comparing the ability of the transport inhibitor hemicholinium-3, present outside or inside the nerve terminals, to prevent uptake and release of [(3)H]choline. Because hemicholinium-3 is membrane-impermeable, it was previously entrapped into synaptosomes during homogenization of brain tissue. External and internalized hemicholinium-3 produced similar maximal inhibition (80-90%) of [(3)H]choline uptake. Also comparable (approximately 30 nM) are the potency of externally applied hemicholinium-3 and the estimated potency of the entrapped inhibitor. Exposure to ouabain elicited release of both [(3)H]acetylcholine and [(3)H]choline from synaptosomes prelabeled with [(3)H]choline. The ouabain (300 microM)-evoked release of [(3)H]choline only was blocked by externally added (IC(50) approximately 10 nM) or internalized (estimated IC(50) approximately 5 nM) hemicholinium-3. Release of previously taken up [(3)H]choline elicited by 100 microM external choline (homoexchange) was prevented by external (IC(50) approximately 30 microM) or entrapped (estimated IC(50) approximately 20 microM) hemicholinium-3. The results suggest that the choline carriers fit into the alternating-access model proposed for classical transmitter transport. Entrapping nonpermeant ligands into synaptosomes could allow investigation of the inward-facing conformation of native transporters and how cytoplasmic ligands affect the bidirectional transport of neurotransmitters. Copyright 2000 Wiley-Liss, Inc.