Basolateral transport of tetraethylammonium by a clone of LLC-PK1 cells.

In these studies, a clone of cells derived from the porcine renal epithelial line LLC-PK1 grown on porous filters was used to evaluate basolateral uptake of the organic cation tetraethylammonium (TEA). (3H) TEA (1 microM) entered cells in a saturable and time-dependent manner achieving a steady-state value at 2 to 2.5 h. Uptake was reduced by hypothermia and the metabolic inhibitors sodium azide and iodoacetate. Several other organic cations in 1 mM concentrations inhibited the majority of TEA uptake. In lower concentrations, the inhibitory potency of these was: verapamil greater than cimetidine approximately amiloride approximately quinidine greater than procainamide approximately N1-methylnicotinamide. When sodium was replaced with potassium in the uptake medium, TEA uptake was also reduced consistent with electrogenic transport. However, uptake was reduced further by 1 mM cimetidine in the presence of both NaCl and KCl buffers. TEA uptake was not significantly different when the media pH was varied from 6.0 to 8.0. In addition, results of experiments in which intracellular pH was altered with NH4Cl were not consistent with the presence of organic cation/proton exchange. TEA/TEA exchange could not be demonstrated in experiments in which cells were preloaded with 1 mM nonradioactive TEA and uptake of (3H)TEA was measured or in which nonradioactive TEA in the external medium failed to enhance efflux from cells preloaded with (3H)TEA. These results indicate that the basolateral membrane of LLC-PKc10 cells has one or more transport processes for the mediated uptake of organic cations. However, the precise mechanism(s) involved in this transport remains to be elucidated.

Tetraethylammonium transport by OK cells.

Mechanisms exist in renal proximal tubules for the mediated transepithelial secretion or reabsorption of endogenous and exogenous organic cations. In the studies presented here, the uptake of the organic cation tetraethylammonium (TEA) into confluent monolayers of opossum kidney cells was evaluated to determine if these cells might serve as an in vitro model of this transport pathway. 3H-TEA entered opossum kidney cells in a time-dependent manner. Uptake at early time points was saturable with an apparent Km of 59.1 +/- 11.2 microM and a Vmax of 1,292 +/- 210 fmol/micrograms of DNA. TEA uptake was inhibited in a dose-dependent manner by several other organic cations including amiloride, cimetidine, verapamil, procainamide, quinidine and N1-methylnicotinamide. With 1 mM concentrations of these compounds, uptake was virtually eliminated. However, another organic cation, N'-methylnicotinamide caused only minimal inhibition. TEA uptake was significantly reduced by sodium azide, suggesting dependence on oxidative phosphorylation. An alkaline medium pH enhanced TEA uptake, but, at the same pH, uptake was similar in the presence or absence of bicarbonate. When cellular pH was altered by ammonium chloride addition or removal, TEA uptake was not affected. Thus, organic cation/proton exchange, as has been demonstrated previously in apical membrane vesicles prepared from proximal tubules, is evidently not responsible for TEA uptake. Similarly, uptake does not appear to result from organic cation/organic cation exchange. These results indicate that the plasma membrane of opossum kidney cells contains a transport system(s) for the mediated uptake of organic cations and that these cells may be a useful mode for further study of renal epithelial transport of these solutes.