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Chloride secretion by canine tracheal epithelium: III. Membrane resistances and electromotive forces (1983)

Welsh, Michael J. ; Smith, Phillip L. ; Frizzell, Raymond A.

Springer

The journal of membrane biology 71 (1983), S. 209-218

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ISSN: 1432-1424

Keywords: tracheal epithelium ; Cl secretion ; electrophysiology ; equivalent electrical circuit ; epinephrine

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Chemistry and Pharmacology

Notes: Summary We used intracellular microelectrode techniques and equivalent electrical circuit analysis to examine the changes in individual membrane resistances and electromotive forces that accompany stimulation of Cl secretion across canine tracheal epithelium. Tissues were pretreated with indomethacin (10−6 m, mucosal solution) to reduce basel Cl secretion rate. Subsequent addition of epinephrine (10−6 m, submucosal solution) increased the rate of electrogenic Cl secretion as indicated by an increase in the short-circuit current (I sc) and decrease in the transepithelial resistance (R t ). The reduction inR t was due to decreases in bothR a andR b (the resistances of the apical and basolateral cell membranes, respectively). At the apical membrane, a nearly 10-fold decrease inR a was accompanied by reversal of the electromotive force (E a ) from +11±9 mV to −31±3 mV. Variations in Cl secretion rate induced by indomethacin and epinephrine disclosed a direct relation betweenR a andE a . In the presence of indomethacinR a was high andE a was consistent with the chemical potential difference for Na across the apical membrane (ca. +60 mV), reflecting the predominance of Na absorption across indomethacin-treated tissues. In the presence of epinephrine,R a was low andE a was consistent with the chemical potential difference for Cl across this barrier (−31 mV), reflecting the dominance of Cl secretion across epinephrine-treated tissues. These findings suggest that the conversion from absorption to secretion primarily involves a secretogogue-induced decrease in apical membrane resistance to Cl. At the basolateral membrane, epinephrine decreasedR b threefold without markedly altering the electromotive force across this barrier (E b ). To the extent thatR b andE b represent the resistance and chemical potential difference for K diffusion across the basolateral membrane, the inverse relation betweenR b andI sc suggests that stimulation is associated with increased basolateral membrane K permeability without marked changes in intracellular K activity.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01875462

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Inhibition of chloride secretion by furosemide in canine tracheal epithelium (1983)

Welsh, Michael J.

Springer

The journal of membrane biology 71 (1983), S. 219-226

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ISSN: 1432-1424

Keywords: tracheal epithelium ; furosemide ; Cl secretion ; electrophysiology ; loop diuretic ; equivalent electrical circuit

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Chemistry and Pharmacology

Notes: Summary Furosemide inhibits Cl transport in a variety of epithelial and nonepithelial cells. To examine the mechanism of Cl secretion in canine tracheal epithelium, the effect of furosemide on transepithelial ion fluxes, membrane resistances, and electromotive forces was determined using intracellular microelectrodes and an equivalent electrical circuit analysis. There were six main observations: First, furosemide was only effective when added to the submucosal solution. Second, inhibition by furosemide (10−3 m) was specific for Cl secretion with no effect on Na absorption. Third, furosemide produced a half-maximal inhibition of Cl secretion at a concentration of 7×10−6 m. A Hill plot yielded a slope not different from unity, suggesting a one-for-one interaction of furosemide with the Cl transport process. Fourth, despite complete inhibition of Cl secretion, furosemide produced only small changes in transepithelial and apical membrane resistance, indicating that the primary effect was not an inhibition of Cl exit from the cell across the apical membrane. Fifth, basolateral membrane resistance and electromotive force were not altered by furosemide. This finding suggested that the effect of furosemide at the basolateral membrane was on an electrically neutral Cl entry process. Sixth, calculation of the intracellular Cl concentration from the electromotive force across the apical membrane indicated that furosemide decreased intracellular Cl concentration by 50%, consistent with an inhibition of Cl entry into the cell. These results indicate that Cl enters the epithelial cell via an electrically neutral process at the basolateral membrane and that furosemide selectively inhibits that process, resulting in a decreased intracellular Cl concentration and a decrease in the driving force for Cl exit across the apical membrane.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01875463

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