Comparative pharmacology of the activity of wild-type and G551D mutated CFTR chloride channel: effect of the benzimidazolone derivative NS004.

The pharmacological activation of the cystic fibrosis transmembrane conductance regulator (CFTR) chloride channel mutated at glycine 551 (G551D-CFTR) was studied in the presence of the benzimidazolone derivative NS004 and compared to that of wild-type (wt) CFTR. Using iodide ((125)I) efflux and whole-cell patch-clamp techniques we found dose-dependent stimulation of phosphorylated wt-CFTR channels by NS004 with an EC(50) approximately 11 microM. With non-phosphorylated CFTR, the effect of NS004 was apparent only at concentration >100 microM. In G551D-CFTR-expressing CHO cells, neither forskolin (from 0.1 to 10 microM) nor NS004 (from 0.1 to 200 microM) added separately were able to stimulate channel activity. However, in the presence of 10 microM forskolin, NS004 stimulated G551D-CFTR activity in a dose-dependent manner with an EC(50) approximately 1.5 microM. We also determined the half-maximal effective concentration of forskolin ( EC(50) approximately 3.2 microM) required to stimulate G551D channel activity in presence of 1.5 micro M NS004. No inhibitory effect was observed at high concentration of NS004 with both wt- and G551D-CFTR. Whole-cell recordings of CFTR chloride currents from cells expressing wild-type or G551D-CFTR in the presence of NS004 were linear, time- and voltage-independent. The inhibitory profile of G551D-CFTR channel activity was similar to that of wild type, i.e., inhibition by glibenclamide (100 microM) and DPC (250 microM) but not by DIDS (200 microM) nor calixarene (100 nM). These results show that NS004 activates wt-CFTR channel and restores G551D-CFTR channel activity, the potency of which depends on both the concentration of NS004 and the phosphorylation status of CFTR.

Genistein modifies the activation kinetics and magnitude of phosphorylated wild-type and G551D-CFTR chloride currents.

We have studied the mechanism by which genistein activates cystic fibrosis transmembrane conductance regulator (CFTR) in CHO cells expressing wild type or G551D-CFTR. In wild-type CHO cells, after exposure to 2.5 microM forskolin, 25 microM genistein induced a further 2-fold and rapid increase of the forskolin-activated CFTR current. In both types of cells, when forskolin was added after genistein preincubation, whole-cell current density was greatly reduced compared to that measured when genistein was added after phosphorylation of CFTR, and all activation kinetic parameters were significantly altered. Genistein had no effect on the adenylate cyclase activity. Our results suggest that the occupancy of a putative genistein binding site is critical for the gating mechanism of CFTR chloride channels, which, depending on the phosphorylation status of the R-domain, drives CFTR either into a refractory state or alternatively to a highly activated state.

Correction of delF508-CFTR activity with benzo(c)quinolizinium compounds through facilitation of its processing in cystic fibrosis airway cells.

A number of genetic diseases, including cystic fibrosis, have been identified as disorders of protein trafficking associated with retention of mutant protein within the endoplasmic reticulum. In the presence of the benzo(c)quinolizinium drugs, MPB-07 and its congener MPB-91, we show the activation of cystic fibrosis transmembrane conductance regulator (CFTR) delF508 channels in IB3-1 human cells, which express endogenous levels of delF508-CFTR. These drugs were without effect on the Ca(2+)-activated Cl- transport, whereas the swelling-activated Cl- transport was found altered in MPB-treated cells. Immunoprecipitation and in vitro phosphorylation shows a 20% increase of the band C form of delF508 after MPB treatment. We then investigated the effect of these drugs on the extent of mislocalisation of delF508-CFTR in native airway cells from cystic fibrosis patients. We first showed that delF508 CFTR was characteristically restricted to an endoplasmic reticulum location in approximately 80% of untreated cells from CF patients homozygous for the delF508-CFTR mutation. By contrast, 60-70% of cells from non-CF patients showed wild-type CFTR in an apical location. MPB-07 treatment caused dramatic relocation of delF508-CFTR to the apical region such that the majority of delF508/delF508 CF cells showed a similar CFTR location to that of wild-type. MPB-07 had no apparent effect on the distribution of wild-type CFTR, the apical membrane protein CD59 or the ER membrane Ca(2+),Mg-ATPase. We also showed a similar pharmacological effect in nasal cells freshly isolated from a delF508/G551D CF patient. The results demonstrate selective redirection of a mutant membrane protein using cell-permeant small molecules of the benzo(c)quinolizinium family and provide a major advance towards development of a targetted drug treatment for cystic fibrosis and other disorders of protein trafficking.

Activation of G551D CFTR channel with MPB-91: regulation by ATPase activity and phosphorylation.

We have designed and synthesized benzo[c]quinolizinium derivatives and evaluated their effects on the activity of G551D cystic fibrosis transmembrane conductance regulator (CFTR) expressed in Chinese hamster ovary and Fisher rat thyroid cells. We demonstrated, using iodide efflux, whole cell patch clamp, and short-circuit recordings, that 5-butyl-6-hydroxy-10-chlorobenzo[c]quinolizinium chloride (MPB-91) restored the activity of G551D CFTR (EC(50) = 85 microM) and activated CFTR in Calu-3 cells (EC(50) = 47 microM). MPB-91 has no effect on the ATPase activity of wild-type and G551D NBD1/R/GST fusion proteins or on the ATPase, GTPase, and adenylate kinase activities of purified NBD2. The activation of CFTR by MPB-91 is independent of phosphorylation because 1) kinase inhibitors have no effect and 2) the compound still activated CFTR having 10 mutated protein kinase A sites (10SA-CFTR). The new pharmacological agent MPB-91 may be an important candidate drug to ameliorate the ion transport defect associated with CF and to point out a new pathway to modulate CFTR activity.