Your search keyword '"Chappe, Valerie"' showing total 2 results

1. PKC phosphorylation modulates PKA-dependent binding of the R domain to other domains of CFTR

Author

Seavilleklein, Gage, Amer, Noha, Evagelidis, Alexandra, Chappe, Frederic, Irvine, Thomas, Hanrahan, John W., and Chappe, Valerie

Subjects

Protein kinases -- Properties, Phosphorylation -- Observations, Cystic fibrosis -- Development and progression, Chloride channels -- Properties, Biological sciences

Abstract

Activity of the CFTR channel is regulated by phosphorylation of its regulatory domain (RD). In a previous study, we developed a bicistronic construct called [DELTA]R-Split CFTR, which encodes the front and back halves of CVFR as separate polypeptides without the RD. These fragments assemble to form a constitutively active CFTR channel. Co-expression of the third fragment corresponding to the missing RD restores regulation by PKA, and this is associated with dramatically enhanced binding of the phosphorylated RD. In the present study, we examined the effect of PKC phosphorylation on this PKA-induced interaction. We report here that PKC alone enhanced association of the RD with [DELTA]R-Split CFTR and that binding was further enhanced when the RD was phosphorylated by both kinases. Mutation of all seven PKC consensus sequences on the RD (7CA-RD) did not affect its association under basal (unphosphorylated) conditions but abolished phosphorylation-induced binding by both kinases. Iodide efflux responses provided further support for the essential role of RD binding in channel regulation. The basal activity of AR-Split/7CA-RD channels was similar to that of [DELTA]R-Split/wild type (WT)-RD channels, whereas cAMP-stimulated iodide efflux was greatly diminished by removal of the PKC sites, indicating that 7CA-RD binding maintains channels in an inactive state that is unresponsive to PKA. These results suggest a novel mechanism for CFTR regulation in which PKC modulates PKA-induced domain-domain interactions. cystic fibrosis; the cystic fibrosis transmembrane conductance regulator chloride channel; domain-domain interactions; protein kinase A and protein kinase C phosphorylation

Published

2008

2. Stimulatory and inhibitory protein kinase C consensus sequences regulate the cystic fibrosis transmembrane conductance regulator

Author

Chappe, Valerie, Hinkson, Deborah A., Howell, L. Daniel, Evagelidis, Alexandra, Liao, Jie, Chang, Xiu-Bao, Riordan, John R., and Hanrahan, John W.

Subjects

Protein kinases, Science and technology

Abstract

Protein kinase C (PKC) phosphorylation stimulates the cystic fibrosis transmembrane conductance regulator (CFTR) channel and enhances its activation by protein kinase A (PKA) through mechanisms that remain poorly understood. We have examined the effects of mutating consensus sequences for PKC phosphorylation and report here evidence for both stimulatory and inhibitory sites. Sequences were mutated in subsets and the mutants characterized by patch clamping. Activation of a 4CA mutant (S707A/S790A/T791A/S809A) by PKA was similar to that of wild-type CFTR and was enhanced by PKC, whereas responses of 3CA (T582A/T604A/S641A) and 2CA (T682A/ $686A) channels to PKA were both drastically reduced (> 90%). When each mutation in the 3CA and 2CA constructs was studied individually in a wild-type background, T582, T604, and S686 were found to be essential for PKA activation. Responses were restored when these three residues were reintroduced simultaneously into a 9CA mutant lacking all nine PKC consensus sequences (R6CA revertant); however, PKC phosphorylation was not required for this rescue. Nevertheless, two of the sites (T604 and S686) were phosphorylated in vitro, and PKC alone partially activated wild-type CFTR, the 4CA mutant, and the point mutants T582A and T604A, but not S686A channels, indicating that PKC does act at S686. The region encompassing S641 and T682 is inhibitory, because S641A enhanced activation by PKA, and T682A channels had 4-fold larger responses to PKC compared to wild-type channels. These results identify functionally important PKC consensus sequences on CFTR and will facilitate studies of its convergent regulation by PKC and PKA.

Published

2004