Deletion of Phe-508 (F508) is the most common mutation in the cystic fibrosis transmembrane conductance regulator (CFTR) causing cystic fibrosis. △F508-CFTR has defects in both channel gating and endoplasmic reticulum-to-plasma membrane processing. We identified six novel classes of high affinity potentiators of defective F508-CFTR Cl-channel gating by screening 100,000 diverse small molecules. Compounds were added 15min prior to assay of iodide uptake in epithelial cells co-expressing F508-CFTR and a high sensitivity halide indicator (YFP-H148Q/I152L) in which F508-CFTR was targeted to the plasma membrane by culture at 27℃ for 24h. Thirty-two compounds with submicromolar activating potency were identified; most had tetrahydrobenzothiophene, benzofuran, pyramidinetrione, dihydropyridine, and anthraquinone core structures (360-480 daltons). Further screening of>1000 structural analogs revealed tetrahydrobenzothiophenes that activated F508-CFTR Cl- conductance reversibly with Kd<100nM. Single-cell voltage clamp analysis showed characteristic CFTR currents after F508-CFTR activation. Activation required low concentrations of a cAMP agonist, thus mimicking the normal physiological response. A Bayesian computational model was developed using tetrahydrobenzothiophene structure-activity data, yielding insight into the physical character and structural features of active and inactive potentiators and successfully predicting the activity of structural analogs. Efficient potentiation of defective F508-CFTR gating was also demonstrated in human bronchial epithelial cells from a F508 cystic fibrosis subject after 27℃ temperature rescue. In conjunction with correctors of defective F508-CFTR processing, small molecule potentiators of defective F508-CFTR gating may be useful for therapy of cystic fibrosis caused by the F508 mutation.

CHIP28 is a major water transporting protein in erythrocytes and plasma membranes in kidney proxi-mal tubule and thin descending limb of Henle. Chinese hamster ovary cells were stably transfected with the coding sequence of cloned rat kidney CHIP28k using expression vectors containing cytomegalovirus or Rous sarcoma virus promoters. Clonal cell populations expressed a 1.3-kilobase mRNA on Northern blot probed by CHIP28k cDNA and a 28-kDa protein on immunoblot probed by a polyclonal CHIP28 antibody. The clone with greatest expression produced -8 X 10’copies of CHIP28k protein/cell. Plasma membrane os-motic water permeability (P f), measured by stopped-flow light scattering, was 0.004cm/s in control (vec-tor-transfected) cells (10C) and 0.014cm/s in the CHIP28k-transfected cells. P f in CHIP28k-transfected cells had an activation energy of 4.9 kcal/mol and was reversibly inhibited by HgC12. CHIP28k expression did not affect the transport of protons and the small polar non-lectrolytes urea and formamide. CHIP28k im-munoreactivity and function was then determined in subcellular fractions. P f in 6-carboxyfluorescein-la-beled endocytic vesicles, measured by a stopped-flow fluorescence quenching assay, was 0.002cm/s (control cells) and 0.011cm/s (CHIP28k-transfected cells); Pt in transfected cells was inhibited by HgC12. Immuno-blotting of fractionated endoplasmic reticulum, Golgi, and plasma membranes revealed high densities of CHIP28k (-5000 monomers/pm2 in plasma membrane) with different glycosylation patterns; functional water transport activity was present only in Golgi and plasma membrane vesicles. Antibody detection of CHIP28k by confocal fluorescence microscopy and immunogold electron microscopy revealed localization to plasma membrane and intracellular vesicles. These studies es-tablish a stably transfected somatic cell line that strongly expresses functional CHIP28k water chan-nels. As in the original proximal tubule cells, the ex-pressed CHIP28k protein is a selective water channel that is functional in endocytic vesicles and the cell plasma membrane.

Aquaporin-5 (AQP5) is a water-selective transporting protein expressed in epithelial cells of serous acini in salivary gland. We generated AQP5 null mice by targeted gene disruption. The genotype distribution from intercross of founder AQP5 heterozygous mice was 70: 69: 29 wild type: heterozygote: knockout, indicating impaired prenatal survival of the null mice. The knockout mice had grossly normal appearance, but grew; 20% slower than litter-matched wild-type mice when placed on solid food after weaning. Pilocarpine-stimulated saliva production was reduced by more than 60% in AQP5 knockout mice. Compared with the saliva from wildtype mice, the saliva from knockout mice was hypertonic (420 mosM) and dramatically more viscous. Amylase and protein secretion, functions of salivary mucous cells, were not affected by AQP5 deletion. Water channels AQP1 and AQP4 have also been localized to salivary gland; however, pilocarpine stimulation studies showed no defect in the volume or composition of saliva in AQP1 and AQP4 knockout mice. These results implicate a key role for AQP5 in saliva fluid secretion and provide direct evidence that high epithelial cell membrane water permeability is required for active, near-isosmolar fluid transport.

The mammalian lung expresses water channel aquaporin-1 (AQP1) in microvascular endothelia, AQP4 in airway epithelia, and AQP5 at the apical plasma membrane in type I cells of alveolar epithelia. We previously studied the role of AQP1 and AQP4 in lung fluid transport using knockout mice. Here, we examined the role of AQP5 using AQP5 knockout mice, which were recently shown to manifest defective saliva secretion. AQP5 deletion did not affect lung morphology at the light microscopic level, nor did it affect the distribution or expression of aquaporins 1, 3, or 4. Airspace-capillary osmotic water permeability (Pf) was measured in isolated perfused lungs by pleural surface fluorescence and gravimetric methods. Pf was reduced 10-fold by AQP5 deletion and was further reduced by 2- to 3-fold in AQP1/AQP5 double-knockout mice. Hydrostatic lung edema in response to acute increases in pulmonary artery pressure was not affected by AQP5 deletion. Active alveolar fluid absorption was measured in an in situ lung model from the increase in concentration of a volume marker in an isosmolar alveolar instillate. Interestingly, fluid absorption did not differ in litter-matched AQP5 knockout mice, nor was there an effect of AQP5 deletion when fluid absorption was maximally stimulated by pretreatment of mice with keratinocyte growth factor. These results indicate that AQP5 is responsible for the majority of water transport across the apical membrane of type I alveolar epithelial cells. The unimpaired alveolar fluid clearance in AQP5-null mice indicates that high alveolar water permeability is not required for active, near-isosmolar fluid transport.

The water and solute transporting properties of the epidermis have been proposed to be important determinants of skin moisture content and barrier properties. The water/small solute-transporting protein aquaporin-3 (AQP3) was found by immunofluorescence and immunogold electron microscopy to be expressed at the plasma membrane of epidermal keratinocytes in mouseskin. We studied the role of AQP3 in stratum corneum (SC) hydration by comparative measurements in wildtype and AQP3 null mice generated in a hairless SKH1 genetic background. The hairless AQP3 null mice had normal perinatal survival, growth, and serum chemistries but were polyuric because of defective urinary concentrating ability. AQP3 deletion resulted in a >4-fold reduced osmotic water permeability and >2-fold reduced glycerol permeability in epidermis. Epidermal, dermal, and SC thickness and morphology were not grossly affected by AQP3 deletion. Surface conductance measurements showed remarkably reduced SC water content in AQP3 null mice in the hairless genetic background (165