In cystic fibrosis (CF), the airway epithelium is in the process of injury and regeneration. In the context of the CF gene therapy, we previously reported that regenerating poorly differentiated (PD) cells of human airway epithelium represent preferential cell targets for recombinant adenoviral gene vectors. To define whether PD non-CF and CF epithelial cells possess a functional cystic fibrosis transmembrane conductance regulator protein (CFTR) chloride channel, we analyzed the CFTR expression and the regulation of chloride secretion under cyclic (c)AMP stimulation in these regenerating PD epithelial cells of non-CF and CF airway tissue. Moreover, we studied the effects of CFTR gene transfer mediated by a replication-defective adenovirus containing the wild-type CFTR gene (AdCFTR) on CFTR expression and on cAMP-stimulated chloride secretion. Distribution of the CFTR protein was evaluated in regenerating PD airway cells by light fluorescence microscopy and scanning laser confocal microscopy. The cAMP-mediated regulation of cell membrane chloride secretion was investigated using the whole-cell patch clamp and SPQ (6-methoxy-N-[3-sulfopropyl]quinolinium) techniques. Compared with the absence of CFTR expression and cAMP-regulated chloride secretion in nontransduced regenerating PD cells of either non-CF or CF origin, transduction with AdCFTR induces a CFTR expression and a cAMP-regulated stimulation of the cell membrane chloride secretion in the regenerating PD cells. These results suggest that, out of the context of CF, remodeled and poorly differentiated airway epithelium may present abnormalities in ion transport. Moreover, our data suggest that, in the context of CF gene therapy, adenoviral vectors can be efficient in correcting, at least partially, the chloride secretion defect in the remodeled CF airway epithelium.