Abstract
Cystic fibrosis transmembrane conductance regulator (CFTR), which causes cystic fibrosis when nonfunctional, is an anion channel and a member of the ATP binding cassette superfamily. After phosphorylation, CFTR gates by binding and hydrolyzing ATP. We show that CFTR open probability (P(o)) also depends on the electrolyte concentration of the cytosol. Inside-out patches from Calu-3 cells were transiently exposed to solutions of 160 mm salt or solutions in which up to 90% of the salt was replaced by nonionic osmolytes such as sucrose. In lowered salt solutions, CFTR P(o) declined within 1 s to a stable lower value that depended on the electrolyte concentration, (K(1/2) approximately 80 mm NaCl). P(o) was rapidly restored in normal salt concentrations without regard to the electrolyte species. Reducing external electrolytes did not affect CFTR P(o). The same results were obtained when CFTR was stably phosphorylated with adenosine 5'-O-(thiotriphosphate). The decrease in P(o) resulted entirely from an increase in mean closed time. Increasing ATP levels up to 20-fold did not counteract the effect of low electrolytes. The same effect was observed for CFTR expressed in C127 cells but not for a different species of anion channel. Cytosolic electrolytes are an unsuspected, essential cofactor for CFTR gating.
Highlights
We have discovered an unsuspected and powerful influence on CFTR gating
An equivalent reduction of Po was observed regardless of the species of nonelectrolyte that we used for replacement, including the cyclic sugar sucrose, the linear sugar mannitol, or the amino acids L-proline and taurine (Fig. 1b). (Proline is uncharged at neutral pH, and only ϳ3% of taurine is predicted to be charged at pH 7.4.)
CFTR Po was unaffected by solutions in which Naϩ, ClϪ, or both were replaced with different ions, including the impermeant anions gluconate, sulfate, and isethionate and the impermeant cation N-methyl-D-glucamine (Figs. 1d and 2b)
Summary
We have discovered an unsuspected and powerful influence on CFTR gating. Our data indicate that CFTR senses the concentrations of cytosolic electrolytes (apparently without regard to species) and requires high levels of electrolytes (ϳ160 mM) for full activity. To determine the quantitative dependence of CFTR Po on electrolyte concentration, the cytosolic solution bathing a single excised patch was rapidly switched between control solution with 160 mM NaCl and different test solutions containing 5, 15, 30, 60, 80, or 320 mM NaCl. For most of these experiments, the nonelectrolyte was proline.
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