Chloride secretion by canine tracheal epithelium: IV. Basolateral membrane K permeability parallels secretion rate

Abstract

We evaluated the K conductance properties of the basolateral membranes of the surface cells of canine tracheal epithelium using microelectrode techniques. Studies were conducted under basal conditions (indomethacin, 10⁻⁶ m, mucosal solution) and after stimulation of electrogenic Cl secretion with epinephrine (10⁻⁶ m, serosal solution). Elevated serosal solution [K] depolarized the electrical potential differences across the apical (ψ_a) and basolateral (ψ_b) membranes in both the presence and absence of epinephrine. Serosal barium (0.5mm) also depolarized ψ_a and ψ_b and selectively increased basolateral membrane resistance threefold. We also used K-selective microelectrodes to determine cell K activity (a _c ^K ) and the driving force for K transport across the limiting membranes under basal and stimulated conditions. Stimulation of Cl secretion was not associated with significant changes in ψ_b ora _c ^K so that the driving force for k exit from cell to serosal solution (ca. 20 mV) was not altered. There was close agreement between the basolateral membrane electromotive force (E _b ) determined from prior studies (M.J. Welsh, P.L. Smith and R.A. Frizzell,J. Membrane Biol. 71:209–218, 1983) and the chemical potential difference for K across this barrier (E _b ^K ) in the presence and absence of epinephrine. These findings support the notion that the basolateral membrane is characterized by a high conductance to K under both secreting and nonsecreting conditions and indicate that the decrease in basolateral membrane resistance that accompanies stimulation of Cl secretion results from an increase in its K conductance. This obviates changes ina _c ^K , that would otherwise accompany increased Na/K pump activity and, by hyperpolarizing ψ_a establishes the electrical driving force for Cl secretion across the apical membrane.