AJP - Cell Physiology, Vol 267, Issue 5 C1279-C1287, Copyright © 1994 by American Physiological Society

ARTICLES

Na(+)-dependent and Na(+)-independent systems of choline transport by plasma membrane vesicles of A549 cell line

A. Kleinzeller, C. Dodia, A. Chander and A. B. Fisher
Institute for Environmental Medicine, University of Pennsylvania School of Medicine, Philadelphia 19104.

Membrane vesicles of A549 lung cells accumulate choline by two pathways: the Na(+)-independent uphill uptake of choline [Michaelis-Menten constant (Km) approximately 44 microM; steady-state gradient approximately 45 at 5 microM external choline] is dependent on a transmembrane H+ gradient, is relatively insensitive to hemicholinium-3, is amiloride sensitive, and is abolished by valinomycin plus carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP). The Na(+)-dependent active choline uptake (Km approximately 4 microM, inhibitor constant for hemicholinium-3 approximately 0.1 microM), is specific for Na+, is amiloride and FCCP sensitive, and is electrogenic: the overshoot using K(+)-loaded vesicles and NaCl gradient was increased by valinomycin. The time of the overshoot peak, T was approximately 90 s in a NaSCN medium (or in presence of other lipid-soluble anions), a value close to that for alpha-aminoisobutyrate as substrate (T = approximately 1.5 min). T was lengthened in NaCl medium to approximately 10 min, and the overshoot was abolished by impermeant anions. External Cl- is not required for the choline uptake: valinomycin produced an overshoot in the presence of only impermeant anions, with T approximately 90 s. Most of the above properties are shared by the high-affinity Na(+)-dependent choline transport in synaptosomes. The characteristics of the Na(+)-dependent choline uptake by membrane vesicles of A549 cells are consistent with an electrogenic choline(+)-Na+ cotransport, with the rate-limiting anion (e.g., Cl-) influx balancing the positive charges transferred into the vesicles. The data are also consistent with an involvement of an amiloride-sensitive choline+/H+ antiport (or choline(+)-OH- symport) in the low- and high-affinity choline uptake pathways.

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