Episomal expression of wild-type CFTR corrects cAMP-dependent chloride transport in respiratory epithelial cells.

The isolation of the gene responsible for the Cl- ion transport defect in cystic fibrosis (CF) has provided important information about the relationship between the disease pathology and the underlying genetic and biochemical mechanisms. In addition, new areas of investigation and therapy are now possible. Most notably, the isolation of the CF gene, the cystic fibrosis transmembrane conductance regulator (CFTR) has been led to the development of different gene therapy strategies. To circumvent possible complications due to insertional mutagenesis and virally induced immune responses, we have employed Epstein-Barr virus (EBV)-based expression vectors for correction of the cAMP-dependent Cl- transport defect associated with CF. A CFTR-containing expression construct under the regulation of the Rous sarcoma virus (RSV) long terminal repeat (LTR) (pREP5/CFTR) was introduced into transformed human airway epithelial cells defective in cAMP-dependent Cl-transport. Transfected cells were assayed for Cl- ion transport by (36)Cl- efflux, SPQ, and patch clamp and showed restoration of intact cAMP-dependent transport. CFTR transcription from pREP5/CFTR was detected by Northern hybridization. The level of response to agonists appeared to be dependent on the level of CFTR expression. When cells were tested for functional expression of CFTR after removal of selection pressure, they showed a continuous decrease in responsiveness to forskolin as a function of time after removal of selection. This decrease correlated with a loss of CFTR mRNA in the loss of the PREP5/CFTR. After 12 to 15 weeks growth without selection both cAMP-dependent Cl- transport and plasmid-derived CFTR mRNA were not detectable. However, it was still possible to rescue cAMP-dependent Cl- transport in these transfected cells by reselection suggesting the presence of the CFTR containing plasmid in a portion of the cells. Analysis of DNA indicated that the pREP5/CFTR vector copy number was reduced from 30 copies per cell with continuous selection, to approximately 0.3 copies per cell after 20 weeks without hygromycin B.

Epithelial cell specific properties and genetic complementation in a delta F508 cystic fibrosis nasal polyp cell line.

Analysis of vectorial ion transport and protein trafficking in transformed cystic fibrosis (CF) epithelial cells has been limited because the cells tend to lose their tight junctions with multiple subcultures. To elucidate ion transport and protein trafficking in CF epithelial cells, a polar cell line with apical and basolateral compartments will facilitate analysis of the efficacy of different gene therapy strategies in a "tight epithelium" in vitro. This study investigates the genotypic and phenotypic properties of a CF nasal polyp epithelial, delta F508 homozygote, cell line that has tight junctions pre-crisis. The cells (sigma CFNPE14o-) were transformed with an origin-of-replication defective SV40 plasmid. They develop transepithelial resistance in Ussing chambers and are defective in cAMP-dependent Cl- transport as measured by efflux of radioactive Cl-, short circuit current (Isc), or whole-cell patch clamp. Stimulation of the cells by bradykinin, histamine, or ATP seems to activate both K(+)- and Ca(+2)-dependent Cl- transport. Measurement of 36Cl- efflux following stimulation with A23187 and ionomycin indicate a Ca(+2)-dependent Cl- transport. Volume regulatory capacity of the cells is indicated by cell swelling conductance. Expression of the CF transmembrane conductance regulator mRNA was indicated by RT-PCR amplification. When cells are grown at 26 degrees C for 48 h there is no indication of cAMP-dependent Cl- as has been previously indicated in heterologous expression systems. Antibodies specific for secretory cell antigens indicate the presence of antigens found in goblet, serous, and mucous cells; in goblet and serous cells; or in goblet and mucous cells; but not antigens found exclusively in mucous or serous cells.(ABSTRACT TRUNCATED AT 250 WORDS)