Acute ENaC Stimulation by cAMP in a Kidney Cell Line is Mediated by Exocytic Insertion from a Recycling Channel Pool

doi:10.1085/jgp.200409124

Published online Dec 28 2004. doi:10.1085/jgp.200409124
The Rockefeller University Press, 0022-1295 $8.00
JGP, Volume 125, Number 1, 81-101

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Acute ENaC Stimulation by cAMP in a Kidney Cell Line is Mediated by Exocytic Insertion from a Recycling Channel Pool

Michael B. Butterworth¹, Robert S. Edinger², John P. Johnson², and Raymond A. Frizzell¹

¹ Department of Cell Biology and Physiology, Renal-Electrolyte Division, School of Medicine, University of Pittsburgh, Pittsburgh, PA 15261
² Department of Medicine, Renal-Electrolyte Division, School of Medicine, University of Pittsburgh, Pittsburgh, PA 15261

Correspondence to Michael B. Butterworth: michael7{at}pitt.edu

Acute hormonal regulation of the epithelial sodium channel (ENaC)in tight epithelia increases transcellular Na⁺ transport viatrafficking of intracellular channels to the apical surface.The fate of the channels removed from the apical surface followingagonist washout is less clear. By repetitively stimulating polarizedmouse cortical collecting duct (mCCD, _MPKCCD₁₄) epithelia, weevaluated the hypothesis that ENaC recycles through an intracellularpool to be available for reinsertion into the apical membrane.Short circuit current (I_SC), membrane capacitance (C_T), andconductance (G_T) were recorded from mCCD epithelia mounted inmodified Ussing chambers. Surface biotinylation of ENaC demonstratedan increase in channel number in the apical membrane followingcAMP stimulation. This increase was accompanied by a 83 ±6% (n = 31) increase in I_SC and a 15.3 ± 1.5% (n = 15)increase in C_T. Selective membrane permeabilization demonstratedthat the C_T increase was due to an increase in apical membranecapacitance. I_SC and C_T declined to basal levels on stimuluswashout. Repetitive cAMP stimulation and washout ( $~$ 1 h each cycle)resulted in response fatigue; ${Delta}$ I_SC decreased $~$ 10% per stimulation–recoverycycle. When channel production was blocked by cycloheximide, ${Delta}$ I_SC decreased $~$ 15% per stimulation cycle, indicating that newlysynthesized ENaC contributed a relatively small fraction ofthe channels mobilized to the apical membrane. Selective blockof surface ENaC by benzamil demonstrated that channels insertedfrom a subapical pool made up >90% of the stimulated I_SC, andthat on restimulation a large proportion of channels retrievedfrom the apical surface were reinserted into the apical membrane.Channel recycling was disrupted by brefeldin A, which inhibitedENaC exocytosis, by chloroquine, which inhibited ENaC endocytosisand recycling, and by latrunculin A, which blocked ENaC exocytosis.A compartment model featuring channel populations in the apicalmembrane and intracellular recycling pool provided an adequatekinetic description of the I_SC responses to repetitive stimulation.The model supports the concept of ENaC recycling in responseto repetitive cAMP stimulation.

Key Words: cellular traffic • recycle • short-circuit current • capacitance • biotinylation

Abbreviations used in this paper: BFA, brefeldin A; CCD, corticalcollecting duct; CHX, cycloheximide; ENaC, epithelial sodiumchannel; LatA, latrunculin A; TGN, trans-Golgi network.

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