Cimetidine transport in isolated brush border membrane vesicles from bovine choroid plexus
Whittico, M.T.; Gang, Y.A.; Giacomini, K.M.
Journal of Pharmacology and Experimental Therapeutics 255(2): 615-623
1990
ISSN/ISBN: 0022-3565 PMID: 2173750 Document Number: 361617
The purpose of this study was to elucidate the mechanisms involved in the transport of cimetidine across the brush border membrane of choroid plexus epithelium. Brush border membrane vesicles were prepared from bovine choroid plexus and the uptake of [3H]cimetidine was studied using the methods of rapid vacuum filtration and scintillation counting. Cimetidine accumulated in the vesicles with time reaching equilibrium within 2 hr. The amount of cimetidine taken up by the vesicles at equilibrium decreased with increasing extravesicular media osmolarity suggesting that cimetidine accumulates in an osmotically reactive intravesicular space. Binding of cimetidine to the membrane was estimated to be less than 18%. Michaelis-Menten studies demonstrated that cimetidine transport involved both a saturable and a nonsaturable component. The Vmax and Km (mean .+-. S.E.) were 16.7 .+-. 5.9 pmol/sec/mg protein and 58.1 .+-. 3.1 .mu.M, respectively, suggesting that cimetidine is transported across the choroid plexus brush border membrane with a lower affinity and a higher capacity than across the renal brush border membrane. The organic cation, quinidine (0.1 mM), and the amino acid, histidine (20 mM), both significantly reduced the initial, but not the equilibrium, uptake of cimetidine. However, high concentrations (5 mM) of more polar organic cations including tetraethylammonium, as well as of several organic anions binding salicylate did not inhibit cimetidine transport. Studies with unlabeled cimetidine revealed a countertransport phenomenon. Attempts to drive the concentrative uptake of cimetidine with various ion gradients were unsuccessful. Of note was the fact that an outwardly directed proton gradient could significantly accelerate the uptake of cimetidine. These data are consistent with pH partitioning of the nonionic species. Alternatively, the data suggest that a proton gradient may be the driving force for cimetidine transport across the choroid plexus brush border membrane.