ISSN:
1432-1424
Keywords:
tracheal epithelium
;
Cl secretion
;
anthracene-9-carboxylic acid
;
Cl permeability
;
electrophysiology
Source:
Springer Online Journal Archives 1860-2000
Topics:
Biology
,
Chemistry and Pharmacology
Notes:
Summary Canine tracheal epithelium secretes Cl from the submucosal to the mucosal surface via an electrogenic transport process that appears to apply to a wide variety of secretory epithelia. Cl exit across the apical membrane is thought to be a passive, electrically conductive process. To examine the cellular mechanism of Cl secretion we studied the effect of anthracene-9-carboxylic acid (9-AC), an agent known to inhibit the Cl conductance of muscle membrane. When added to the mucosal solution, 9-AC rapidly and reversibly decreases short-circuit current and transepithelial conductance, reflecting a reduction in electrogenic Cl secretion. The inhibition is concentration-dependent and 9-AC does not appear to compete with Cl for the transport process. The decrease in current and conductance results from a decrease in the net and both unidirectional transepithelial Cl fluxes without substantial alterations of Na fluxes. Furthermore, 9-AC specifically inhibits a Cl conductance: tissues bathed in Cl-free solutions showed no response to 9-AC. Likewise, when the rate of secretion and Cl conductance were minimized with indomethacin, addition of 9-AC did not alter transepithelial conductance. In contrast, neither removal of Na from the media nor blockade of the apical Na conductance with amiloride prevented a 9-AC-induced decrease in transepithelial conductance. We also found that the effect of 9-AC is independent of transepithelial transport: 9-AC decreases transepithelial conductance despite inhibition of Cl secretion with ouabain or furosemide. Intracellular electrophysiologic techniques were used to localize the effect of 9-AC to a reduction of the electrical conductance of the apical cell membrane: 9-AC hyperpolarizes the electrical potential difference across the apical membrane and decreases its relative conductance. 9-AC also prevents the characteristic changes in the cellular electrical potential profile, transepithelial conductance, and the ratio of membrane conductances produced by a reduction in mucosal bathing solution Cl concentration. These results indicate that 9-AC inhibits Cl secretion in tracheal epithelium by blocking an electrically conductive Cl exit step in the apical cell membrane. Thus, they support a cellular model of Cl secretion in which Cl leaves the cell across a Cl permeable apical membrane driven by its electrochemical gradient.
Type of Medium:
Electronic Resource
URL:
http://dx.doi.org/10.1007/BF01872533
Permalink
