Enhanced in vivo airway gene transfer via transient modification of host barrier properties with a surface-active agent.

Effective adenoviral gene therapy requires efficient viral vector entry into epithelial cells. Injured airway epithelia display enhanced gene transfer, reflecting in part increased vector access to protected cell populations and/or protected basolateral membranes. We tested whether adenoviral gene transfer is enhanced by modification of the epithelial barrier in mouse nasal airways with a nonionic detergent (polidocanol, PDOC). In C57BL/6 mice, 1.6 x 10(9) PFU of Ad5CMV LacZ (AdLacZ) instilled into the right nostril produced negligible gene transfer to the nasal epithelium 2 days after dosing, but significant, dose-dependent increases in gene transfer were achieved by pretreatment with PDOC. Permeation of the electron-dense tracer lanthanum into the intercellular junctions of PDOC (0.1%)-treated murine nasal epithelium, but not into intercellular junctions of vehicle controls, is consistent with PDOC-mediated increases in tight junctional permeability. In CF(-/-) mice, significant gene expression was not detectable after exposure to Ad5CBCFTR alone (1.4 x 10(9) PFU in 20 microl; AdCFTR), but PDOC pretreatment prior to AdCFTR instillation produced functional expression of CFTR (measured as deltaPD) 5 days after instillation. Because the development and testing of lung gene therapy will principally occur in children and adults with airway disease, AdLacZ gene transfer with and without PDOC pretreatment was examined in infected nasal airways. Gene expression was significantly reduced in infected as compared with uninfected airways. We conclude that the use of adjuvant surface-active and/or membrane-perturbing agents, synthetic or naturally derived, may provide a novel approach to enhancing the efficiency of adenoviral gene transfer.

Abnormal enamel development in a cystic fibrosis transgenic mouse model.

Cystic fibrosis (CF) is a hereditary condition that affects cAMP-regulated chloride channels in epithelial tissues due to a defect in the cystic fibrosis transmembrane conductance regulator (CFTR) gene. Recently, a transgenic CF mouse model was developed at UNC that exhibits no CFTR expression. Interestingly, the CF mouse demonstrates abnormal incisor enamel. Therefore, the purpose of this investigation was to characterize the enamel in this CF mouse model. Incisors from CF and normal mice were evaluated by light microscopy (LM), scanning electron microscopy (SEM), and transmission electron microscopy (TEM). The enamel proteins were examined by amino acid analysis, SDS-PAGE, and Western blot. Gross examination showed that 100% of CF mice had soft, chalky white incisor enamel, while the enamel of normal mice was hard and yellow-brown. LM indicated that the ameloblasts in the CF mice underwent premature degeneration shortly after completion of the secretory phase. The CF mouse enamel appeared to be of relatively normal thickness and showed a prism structure similar to that of normal mouse enamel. However, the CF mouse enamel crystallites appeared to have a rough granular surface compared with normal enamel. SDS-PAGE indicated that mature CF enamel retained low-molecular-weight material (approximately 20 kDa), whereas normal mature enamel did not. This low-molecular-weight material cross-reacted with anti-amelogenin antibodies in Western blot analysis. This investigation shows that abnormal CFTR expression in the mouse results in developmental abnormalities in the incisor enamel. Although further investigation is required to determine the mechanism leading to abnormal enamel formation, the CF mouse provides a potentially useful animal model for investigating aberrant enamel development.

Pathophysiology of gene-targeted mouse models for cystic fibrosis.

Pathophysiology of Gene-Targeted Mouse Models for Cystic Fibrosis. Physiol. Rev. 79, Suppl.: S193-S214, 1999. - Mutations in the gene causing the fatal disease cystic fibrosis (CF) result in abnormal transport of several ions across a number of epithelial tissues. In just 3 years after this gene was cloned, the first CF mouse models were generated. The CF mouse models generated to date have provided a wealth of information on the pathophysiology of the disease in a variety of organs. Heterogeneity of disease in the mouse models is due to the variety of gene-targeting strategies used in the generation of the CF mouse models as well as the diversity of the murine genetic background. This paper reviews the pathophysiology in the tissues and organs (gastrointestinal, airway, hepatobiliary, pancreas, reproductive, and salivary tissue) involved in the disease in the various CF mouse models. Marked similarities to and differences from the human disease have been observed in the various murine models. Some of the CF mouse models accurately reflect the ion-transport abnormalities and disease phenotype seen in human CF patients, especially in gastrointestinal tissue. However, alterations in airway ion transport, which lead to the devastating lung disease in CF patients, appear to be largely absent in the CF mouse models. Reasons for these unexpected findings are discussed. This paper also reviews pharmacotherapeutic and gene therapeutic studies in the various mouse models.

Mucociliary transport determined by in vivo microdialysis in the airways of normal and CF mice.

We report a novel method to measure mucociliary transport (MCT) in both the upper and lower airways of normal and CF mice. The in vivo microdialysis technique involves placing a small quantity of dye on the airway surface and a microdialysis probe a defined distance from the site of dye deposition. The dye is transported toward the probe by ciliary transport and, upon reaching the microdialysis probe, diffuses across the dialysis membrane and is collected in the dialysate leaving the probe. The rate of MCT is calculated from the length of time from dye deposition to recovery. The rate of tracheal MCT in normal mice was 2.2 +/- 0.45 (SE) mm/min (n = 6), a value similar to that in reports using other techniques. MCT in CF mice was not different (2.3 +/- 0.29, n = 6), consistent with previous observations suggesting that tracheal ion transport properties are not different between CF and normal mice. The rate of MCT in the nasal cavity of normal mice was slower than in the trachea (1.3 +/- 0.26, n = 4). MCT in the CF mouse nasal cavity (1.4 +/- 0.31, n = 8), a region in which the CF mouse exhibits bioelectric properties similar to the human CF patient, was, again, not different from the normal mouse, perhaps reflecting copious gland secretion offsetting Na(+) and liquid hyperabsorption. In conclusion, we have developed a versatile, simple in vivo method to measure MCT in both upper and lower airways of mice and larger animals.

Enamel mineral composition of normal and cystic fibrosis transgenic mice.

The ability of ameloblasts and the enamel organ to control the influx of ions into the developing enamel is of considerable interest. The development of transgenic mice lacking a cAMP-regulated chloride channel, the cystic fibrosis transmembrane conductance regulator (CFTR), provides a model that may prove valuable for the study of ion regulation in developing teeth. The purpose of this investigation was to characterize the mineral content of normal and CF mice. Five homozygous and five heterozygous adult mice having the CFTR knockout transgene were evaluated. The mice were killed with CO2 and their mandibular incisors removed, embedded in methacrylate, and sectioned, and enamel particles from the incisal region were then dissected for analysis. Each particle was analyzed for its calcium, phosphorus, and magnesium content. The normal mice had a mean mineral content of 80.5%, in contrast to the CF mice, that had markedly hypomineralized enamel (mean = 51.5%). The calcium/phosphorus ratios were similar for both groups of mice and were compatible with the enamel consisting primarily of hydroxyapatite mineral. The enamel magnesium content was significantly elevated in the CF mice (mean = 3560 ppm) compared with the normal mice (mean = 2280 ppm). Normal mouse enamel was highly mineralized, while the CF mouse enamel mineral content was significantly reduced and had an elevated level of magnesium. The altered mineral content of CF mouse enamel indicates that CFTR could play an important role in ion regulation and consequently mineralization of mouse enamel.