Understanding impact of δF508 and G551D CFTR mutations on CFTR/PKA-c interaction.

Abstract

The CFTR anion channel is an ATP Binding Cassette protein and consists of two pore-forming transmembrane domains, two cytosolic nucleotide binding domains that bind and hydrolyze ATP to drive gating, and a cytosolic regulatory (R) domain. The catalytic subunit of protein kinase A (PKA) binds to, and phosphorylates, the R domain, causing reversible and irreversible channel activation, respectively. CFTR chloride channel mutations cause the lethal and incurable disease cystic fibrosis (CF). The most common CF mutation, ΔF508, is known to impair CFTR protein processing and channel gating, while mutation G551D disrupts ATP-dependent channel gating. In addition, ΔF508 and G551D CFTR were also shown to be defective in PKA-dependent activation. As the stimulating effect of ivacaftor, the only FDA-approved CFTR potentiator drug, depends on CFTR phosphorylation, understanding the reason for the impaired CFTR-PKA interaction in the mutants is of great significance. The reduced rate of phosphorylation of G551D or ΔF508 channels might be a consequence of impaired PKA binding to CFTR. In the presence of ATP the contributions of PKA binding vs. phosphorylation to overall channel activation are difficult to deconvolve. Therefore, we tested reversible activation by PKA of unphosphorylated and phosphorylated mutant channels gating in P-ATP, an ATP analog that supports CFTR gating but cannot be used for phosphotransfer by PKA. Using macroscopic inside-out patch clamp recordings we compared the rates and fractional amplitudes of reversible stimulation by PKA for the mutants and wild-type CFTR. Our data show that channel activation by reversible binding of PKA is preserved in the mutant CFTR channels. Additional experiments are underway to decipher the molecular mechanism for slowed activation of the mutants.