Apical Localization of the Coxsackie-Adenovirus Receptor by Glycosyl-Phosphatidylinositol Modification Is Sufficient for Adenovirus-Mediated Gene Transfer through the Apical Surface of Human Airway Epithelia

doi:10.1128/JVI.75.16.7703-7711.2001

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Journal of Virology, August 2001, p. 7703-7711, Vol. 75, No. 16
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.16.7703-7711.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

Apical Localization of the Coxsackie-Adenovirus Receptor by Glycosyl-Phosphatidylinositol Modification Is Sufficient for Adenovirus-Mediated Gene Transfer through the Apical Surface of Human Airway Epithelia

Robert W. Walters,¹^,²^,³ Wouter van't Hof,⁴^,⁵ Su Min P. Yi,¹^,⁶ Mary K. Schroth,⁷ Joseph Zabner,² Ronald G. Crystal,⁴^,⁵ and Michael J. Welsh¹^,²^,³^,^*

Howard Hughes Medical Institute¹ and Departments of Internal Medicine,² Physiology and Biophysics,³ and Otolaryngology,⁶ University of Iowa College of Medicine, Iowa City, Iowa 52242; Division of Pulmonary and Critical Care Medicine,⁴ and Institute of Genetic Medicine,⁵ Weill Medical College of Cornell University, New York, New York 10021; and Department of Pediatrics, University of Wisconsin Medical School, Madison, Wisconsin 53792⁷

Received 21 March 2001/Accepted 12 May 2001

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

In well-differentiated human airway epithelia, the coxsackie B and adenovirus type 2 and 5 receptor (CAR) resides primarilyon the basolateral membrane. This location may explain the observationthat gene transfer is inefficient when adenovirus vectors areapplied to the apical surface. To further test this hypothesisand to investigate requirements and barriers to apical gene transferto differentiated human airway epithelia, we expressed CAR inwhich the transmembrane and cytoplasmic tail were replaced bya glycosyl-phosphatidylinositol (GPI) anchor (GPI-CAR). As controls,we expressed wild-type CAR and CAR lacking the cytoplasmic domain(Tailless-CAR). All three constructs enhanced gene transfer withsimilar efficiencies in fibroblasts. In airway epithelia, GPI-CARlocalized specifically to the apical membrane, where it boundadenovirus and enhanced gene transfer to levels obtained whenvector was applied to the basolateral membrane. Moreover, GPI-CARfacilitated gene transfer of the cystic fibrosis transmembraneconductance regulator to cystic fibrosis airway epithelia, correctingthe Cl transport defect. In contrast, when we expressed wild-type CARit localized to the basolateral membrane and failed to increaseapical gene transfer. Only a small amount of Tailless-CAR residedin the apical membrane, and the effects on apical virus bindingand gene transfer were minimal. These data indicate that bindingof adenovirus to an apical membrane receptor is sufficient tomediate effective gene transfer to human airway epithelia andthat the cytoplasmic domain of CAR is not required for this process.The results suggest that targeting apical receptors in differentiatedairway epithelia may be sufficient for gene transfer in the geneticdisease cysticfibrosis.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The first steps in adenovirus infection involve primarily two proteins in the viral capsid: fiber and penton base (9, 11,12). The adenovirus fiber protein forms a trimer which bindsto the cell via a high-affinity receptor, the coxsackie B andadenovirus type 2 and 5 receptor (CAR) (3, 29). Recent structuraland genetic studies support a model in which the lateral cleftbetween two neighboring knob domains on fiber interact with theextracellular amino-terminal immunoglobulin V domain of CAR (4,8, 26). Interestingly, adenovirus-meditated gene transferto lymphocyte and CHO cell lines does not require the transmembraneor cytoplasmic domains of CAR, suggesting that the interactionbetween fiber-knob and CAR mediates primarily attachment to thecell surface (18, 30, 37). In addition to the fiber-CARinteraction, the penton base interacts with $alpha$ _v $beta$ ₃ and $alpha$ _v $beta$ ₅ integrins,facilitating receptor-mediated endocytosis of adenovirus (12,21, 40). Thus, CAR is required for binding and infection,and $alpha$ _v $beta$ integrins act ascoreceptors.

Human airway epithelia are a target for gene transfer in the genetic disease cystic fibrosis (CF) (27, 38). Earlier worksshowed that adenovirus infection and adenovirus-mediated genetransfer to differentiated airway epithelia are inefficient dueto lack of CAR and integrins in the apical membrane (2, 10,13, 15, 23-25, 35, 41, 42). Thus, lack of fiber-knobbinding to the apical membrane may be the rate-limiting step foradenovirus-mediated gene transfer to airway epithelia. Despiteits absence on the apical membrane, CAR is present on the basolateralmembrane (25, 35). Consequently, adenovirus infects airwayepithelia from the basolateral surface in a fiber-dependent manner(35).

These results raised the question of whether CAR localized in the apical membrane would be sufficient for adenovirus-mediatedgene transfer from the apical surface. Answering this questionis important for understanding the molecular mechanisms of adenovirusentry into human airway epithelia. The answer may also impactthe development of targeted gene delivery of the cystic fibrosistransmembrane conductance regulator (CFTR) for CF. To addressthis question we studied adenovirus-mediated gene transfer indifferentiated human airway epithelia expressing recombinant wild-typeCAR and two modified CAR proteins: CAR lacking the cytoplasmicdomain (Tailless-CAR) and CAR lacking the cytoplasmic and transmembranedomains but modified with a glycosyl-phosphatidylinositol (GPI)anchor signal sequence (GPI-CAR) to target the apical membrane(18, 30, 37). Recently, similar modifications in CAR (Tailless-and GPI-CAR) were found to localize to the apical membrane ina canine renal epithelial cell line (MDCK) (24). However, theydid not facilitate adenovirus infection until the MDCK cells weretreated with neuraminidase to remove sialic acid from the glycocalyx.To learn whether apically localized CAR facilitates gene transferto the airways and to investigate the mechanisms involved, westudied primary cultures of well-differentiated human airwayepithelia.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Cells and culture. NIH 3T3 cells were cultured on 100-mm-diameter plates (Corning Costar, Corning, N.Y.) in Eagle's minimum essential medium(EMEM) (Sigma Chemical Co., St. Louis, Mo.) supplemented with10% fetal calf serum (Sigma Chemical Co.), 1% nonessential aminoacids, penicillin (100 U/ml), and streptomycin (100 µg/ml).

Airway epithelial cells were obtained from trachea and bronchi of lungs removed for organ donation. Cells were isolated byenzyme digestion as previously described (16, 43). Freshlyisolated cells were seeded at a density of 5 × 10⁵ cells/cm² onto collagen-coated, 0.6-cm² area Millicell polycarbonate filters (Millipore Corp., Bedford,Mass.). The cells were maintained at 37°C in a humidified atmosphereof 5% CO₂ and air. Twenty-four hours after plating, the mucosalmedium was removed and the cells were grown at the air-liquidinterface (16, 43). The culture medium consisted of a 1:1mix of DMEM-Ham's F-12, 5% Ultroser G (Biosepra SA, Cergy-Saint-Christophe,France), penicillin (100 U/ml), streptomycin (100 µg/ml), 1% nonessentialamino acids, and insulin (0.12 U/ml). Airway epithelia reachedconfluence and developed a transepithelial electrical resistance,indicating the development of tight junctions and an intact barrier.Epithelia were allowed to differentiate by culturing for at least14 days after seeding, and the presence of a ciliated surfacewas tested by scanning electron microscopy (43).

Flag-tagged CAR constructs and recombinant adenoviruses. cDNAs encoding three CAR constructs were kindly provided by J. M. Bergelson (Division of Immunologic and Infectious Diseases,Children's Hospital of Philadelphia, Philadelphia, Pa.): (i) full-lengthCAR (wt-CAR), (ii) CAR which lacks the cytoplasmic domain (Tailless-CAR),and (iii) CAR which has the decay-accelerating factor signal forGPI modification in place of the transmembrane and cytoplasmicdomains (GPI-CAR) (37). All CAR constructs were modified withthe Flag epitope tag consisting of amino acids DYKDDDDK, inserteddownstream of the NH₂-terminal hydrophobic leader signal sequence,as described previously (30).

We cloned the three Flag-tagged CARs into adenovirus vectors. Recombinant adenovirus vectors expressing the Flag-tagged CARconstructs (Ad5/wt-CAR, Ad5/Tailless-CAR, and Ad5/GPI-CAR), and $beta$ -galactosidase ( $beta$ -Gal) (Ad2/ $beta$ Gal) were prepared by the Universityof Iowa Gene Transfer Vector Core at titers of ~10¹⁰ infectious units/ml (determined by plaque assay) as previouslydescribed (39). A recombinant adenovirus vector expressing greenfluorescent protein (GFP), Ad2/GFP, and CFTR (Ad2/CFTR-16) werea gift of Sam Wadsworth (Genzyme, Framingham, Mass.).

Expression of CAR. NIH 3T3 cells, which normally express low levels of CAR, were infected with control adenovirus (Ad2/ $beta$ Gal), or adenovirus expressingeither one of the three CAR constructs using Ad-CaPi coprecipiates.This method bypasses the need for the CAR receptor on target cells(6, 33). Briefly, Ad-CaPi coprecipitates were formed by addingCaCl₂ to adenovirus particles in EMEM to achieve a final Ca²⁺ concentration of 5.8 mM. Cells were then infected with Ad-CaPicoprecipitates for 30 min, rinsed three times with EMEM, and evaluatedfor susceptibility to Ad2/GFPinfection.

In airway epithelia, the CAR constructs were expressed by pretreating epithelia with 8 mM EGTA delivered in H₂O to transientlydisrupt the tight junctions. This technique results in reversibledisruption of the tight junctions and allows apically administeredadenovirus to access its endogenous receptor on the basolateralmembrane (35, 36). Immediately after treatment, epitheliawere infected with control adenovirus or adenovirus (multiplicityof infection [MOI], 10) expressing either of the three CAR constructs.Two days after infection with CAR-expressing adenoviruses, epithelialintegrity was measured with an ohmmeter (EVOM; World PrecisionInstrument Inc., Sarasota, Fla.). The transepithelial resistancevalues for all infected epithelia were >300 $Omega$ · cm². Epithelia were then evaluated or studied as describedbelow.

Analysis of Flag-tagged CAR protein expression. Expression of the adenovirus-encoded CAR constructs was evaluated by Western blot analysis of airway epithelia 2 days afterinfection with CAR-expressing adenoviruses. Protein was extractedfrom epithelia by incubation for 1 h at 4°C with lysis buffer(1% Triton X-100; 10 mM Tris-HCl, pH 7.4; 150 mM NaCl), supplementedwith protease inhibitors (10 µg each of leupeptin, aprotinin,and pepstatin A per ml). The lysates were diluted in Laemmli samplebuffer, and equal amounts were subjected to Western blotting.Flag-tagged CAR proteins on nitrocellulose membranes were detectedby incubation with a 1:500 dilution of horseradish peroxidase-conjugatedanti-Flag M2 monoclonal antibody (Sigma Chemical Co.) in 10 mMTBS (Tris-HCl, pH 7.4; 150 mM NaCl; 10 mM EDTA) containing 5%nonfat milk, and visualized after chemiluminescence by exposurefor 1 to 5 min to X-Omat film (Eastman Kodak, Rochester, N.Y.).

Cell surface distribution of Flag-tagged CAR constructs. Apical localization of Flag-tagged CAR was evaluated by immunocytochemistry in epithelia 2 days after gene transfer with CAR-expressingadenovirus. Epithelia were coinfected with Ad2/GFP at the timeof adenovirus-mediated CAR gene transfer to allow visualizationof epithelial cells. Epithelia were fixed with 4% paraformaldehydefor 15 min at 23°C. Unless otherwise noted, SuperBlock (Pierce,Rockford, Ill.) was used to wash between incubations and alsoto dilute reagents. After cells were washed twice for 10 min eachtime, mouse anti-Flag monoclonal antibody (1:600; Sigma ChemicalCo.) was placed on the apical surface of epithelia for 1 h at37°C. Then, cells were rinsed twice for 5 min each and incubatedwith donkey anti-mouse immunoglobulin G conjugated with TexasRed fluorophore (1:500; Jackson ImmunoResearch Laboratories, Inc.,West Grove, Pa.) for 1 h at 37°C. The epithelia were rinsed twicewith phosphate-buffered saline (PBS) for 5 min each then mountedonto glass slides using Vectashield (Vector Laboratories Inc.,Burlingame, Calif.). Apical staining was evaluated by laser scanningconfocal microscopy (model MRC-1024 microscope; Bio-Rad, Hercules,Calif.) at 60X magnification; images are shown as stacked XZseries.

Binding of iodinated mouse ¹²⁵I-anti-Flag antibody, prepared with IODO-GEN reagent (Pierce), to airway epithelia was performedfor quantitative analysis of the cell surface distribution ofthe Flag-tagged CAR constructs. Two days after infection, epitheliawere washed with binding buffer (EMEM containing 1% bovine serumalbumin and 10 mM HEPES, pH 7.3) and incubated for 2 h at 4°Cwith 2 µg of ¹²⁵I-anti-Flag antibody per ml (2 × 10⁵ to 4 × 10⁶ dpm/µg). Antibody was added either to the apical or the basolateralsurface of airway epithelia. After three washes with binding bufferfor 10 min at 4°C, cell-associated ¹²⁵I label was solubilized for 30 min at 23°C in 10% sodium dodecylsulfate, followed by quantification in a gamma counter. Nonspecificbinding of anti-Flag antibody was measured in parallel filtersby adding a 100-fold excess (200 µg/ml) of unlabeled antibodyalong with ¹²⁵I-labeled antibody. Specific binding was calculated by subtractingnonspecific binding from total binding. In all cases, nonspecificbinding amounted to 20 to 30% of the totalsignal.

Binding of fluorescent adenovirus. CAR constructs were expressed in airway epithelia as described above. Two days after gene transfer with CAR-expressing adenovirus,Cy3-labeled Ad5/ $beta$ Gal (MOI, 50) in 100 µl of EMEM was added tothe apical surface of epithelia maintained at 4°C. Adenoviruswas covalently labeled with the carbocyanine dye Cy3 (AmershamPharmacia Biotech, Piscataway, N.J.) (19). The labeling proceduredecreased the infectious unit/particle ratio by 5 to 35% (33).After a 30-min incubation the virus was removed, and epitheliawere rinsed twice with EMEM. Cultures were fixed with 4% paraformaldehydeat 23°C for 10 min and then rinsed three times with PBS. The cellswere stained with a 1:500 dilution of DAPI (4',6'-dianidino-2-phenylindole)in PBS (Molecular Probes, Eugene, Oreg.) for 20 min at 23°C, rinsed,and then mounted on glass slides with Vectashield (Vector LaboratoriesInc.). Binding of adenovirus to the epithelia was assessed byfluorescence microscopy (19, 33).

Gene transfer assays. CAR-expressing NIH 3T3 cells were evaluated by detecting GFP expression 1 day after gene transfer with Ad2/GFP. Cells weredissociated with 0.05% trypsin and 0.53 mM EDTA, and fluorescencefrom 50,000 individual cells was analyzed using fluorescence-activatedcell analysis (FACScan, Lysys II software; Becton Dickinson, SanJose, Calif.). The percentage of cells positive for GFP was assessedby determining the percentage of highly fluorescent cells in eachgroup and subtracting the fluorescence of controlcells.

To evaluate adenovirus-mediated gene transfer through the apical surface of human airway epithelia expressing CAR constructs,either Ad2/GFP, Ad2/ $beta$ Gal, or Ad2/CFTR 16 (MOI, 10) was deliveredto the apical surface in 100 µl of EMEM and incubated for 30 minat 37°C. Epithelia were then rinsed twice with EMEM and assayedfor gene transfer 2 days later. To assess GFP expression in airwayepithelia, Ad2/GFP-infected epithelia were studied 2 days postinfectionby fluorescence microscopy (34).

For analysis of $beta$ -Gal expression, total $beta$ -Gal activity was measured by a commercially available method (Galacto-Light; Tropix,Inc., Bedford, Mass.). Briefly, 2 days postinfection, epitheliawere rinsed with PBS and incubated with lysis buffer (25 mM Tris-phosphate,pH 7.8; 2 mM dithiothreitol; 2 mM 1,2-diaminocyclohexane-N,N,N',N'-tetraaceticacid; 10% glycerol; and 1% Triton X-100) for 15 min. Light emissionwas quantified in a luminometer (Analytical Luminescence Laboratory,San Diego, Calif.).

To assess CFTR gene transfer, epithelia were mounted in modified Ussing chambers (Jim's Instruments, Iowa City, Iowa) as previouslydescribed (43). Epithelia were bathed on the submucosal surfacewith a Ringer's solution containing 135 mM NaCl, 2.4 mM KH₂PO₄,1.2 mM CaCl₂, 1.2 mM MgCl₂, 10 mM HEPES, and 10 mM dextrose (pH7.4). The mucosal solution was identical with the exception thatNaCl was replaced with 135 mM sodium gluconate. Amiloride (10µM) was added to the mucosal solution to inhibit Na⁺ channels and transepithelial Na⁺ transport. The cyclic AMP (cAMP) agonists, 10 µM forskolin and100 µM isobutylmethylxanthine, were added to the mucosal and submucosalsolutions to stimulate transepithelial Cl current through CFTR Cl channels. To assess total Cl current, 100 µM bumetanide was added to the submucosal solution,and the change in current wasmeasured.

Cell surface modifications. Epithelia were biochemically treated to remove the glycocalyx from the apical surface. Two days after infection with CAR-expressingadenovirus, epithelia were rinsed with EMEM. Epithelia were thenincubated with either 200 mU of bacterial sialidase NA Type IIIfrom Vibrio cholerae per ml, 10 mU of O-glycosidase from Streptococcuspneumoniae per ml, or 50 U of the peptide N-glycosidase F fromFlavobacterium meningosepticum (Sigma Chemical Co.) per ml dilutedin EMEM for 1 h at 37°C (2). Assay conditions for each enzymewere optimized by first testing a range of concentrations anddetermining the maximum concentration of enzyme that did not changethe transepithelial resistance. To confirm removal of the glucocalyx,epithelia were fixed with 4% paraformaldehyde for 15 min at 23°Cand then incubated with 0.1 µg of fluorescein isothiocyanate (FITC)-labeledwheat germ agglutinin (WGA) (Vector Laboratories Inc.) for 30min at 23°C. WGA binding was quantitated by measuring averagefluorescence intensity from histogram plots of confocal images(Confocal Assistant software). To assess gene transfer, enzyme-treatedepithelia were washed with EMEM, infected with Ad2/ $beta$ Gal, and evaluated2 days later for adenovirus-mediated genetransfer.

To evaluate the requirement for the GPI anchor on GPI-CAR, airway epithelia were treated with phosphatidylinositol-specificphospholipase C (PI-PLC) (from Bacillus cereus; Molecular Probes)for 2 h at 37°C followed by three washes with EMEM prior toinfection.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

GPI-CAR, Tailless, and wt-CAR mediate adenovirus gene transfer to 3T3 cells with similar efficiencies. Adenovirus vectors were generated to express three different Flag-tagged CAR constructs: (i) full-length CAR (amino acids[aa] 1 to 365), (ii) CAR lacking the cytoplasmic domain (aa 1to 260), and (iii) CAR with the cytoplasmic and transmembranedomains replaced by a GPI anchor signal sequence (aa 1 to 235).Earlier studies showed that similar constructs were capable ofmediating adenovirus infection in cells lacking CAR; however,it is unknown whether they have similar efficiencies. To addressthis issue, we transduced NIH 3T3 cells with various amounts ofCAR-expressing adenovirus to vary the amount of CAR receptor.Then, we applied increasing concentrations of Ad2/GFP and assessedthe percentage of GFP-positive cells as a measure of gene transfer.In addition, we studied varying amounts of CAR because we werelimited by not knowing how levels of recombinant CAR compare toendogenous CAR. In cells infected with a high MOI (MOI, 50) ofAd-CAR vectors, we observed a dose-dependent increase in adenovirus-mediatedGFP gene transfer regardless of which CAR molecule was expressed(Fig. 1A). Moreover, the three CAR molecules seemed to functionwith similar efficiencies. Because differences in receptor efficiencymay be more evident at lower levels of receptor (30), we alsoexamined the dose-response of Ad2/GFP infection in cells expressinglower levels of CAR (Fig. 1B to D). As we reduced the amount ofCAR expression by applying a lower MOI of the CAR-expressing virus,gene transfer with Ad2/GFP fell. However, we found similar reductionswith all three CAR molecules. These observations are consistentwith previous reports that all three CAR receptors can facilitateadenovirus-mediated gene transfer (18, 30, 37). In addition,these data suggest that their relative efficiencies are similar.

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FIG. 1. Effect of CAR expression on adenovirus-mediated gene transfer to NIH 3T3 cells. Cells were infected with varying MOIs of Ad-CaPi coprecipitates encoding wt-CAR ( $diamond$ ). Tailless-CAR ( $open circle$ ), GPI-CAR ( $triangle$ ), or CFTR (

) as a control. One day later cells were infected with varying MOIs of Ad2/GFP. Data are the percentage of GFP-positive cells for cells infected with the Ad/CAR vectors at MOIs of 50 (A), 20 (B), 6 (C), and 1 (D).

Expression of modified CAR molecules in human airway epithelia. Given that these three receptors function with similar efficiencies in a cell line, we studied their expression, localization,and function in primary cultures of well-differentiated airwayepithelia. We delivered the CAR-expressing adenovirus vectorsto the basolateral membrane by transiently disrupting the tightjunctions, as previously reported (35). Western blot analysisshowed specific expression of each Flag-tagged CAR construct atapproximately similar amounts (Fig. 2). Naive epithelia and epitheliaexpressing $beta$ -Gal did not show a specific band at the predictedmolecular weight range for any of the CAR constructs, confirmingthat the anti-Flag antibody specifically detects the CAR constructsin human airway epithelia.

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FIG. 2. Expression of adenovirus-encoded CAR constructs in primary cultures of human airway epithelia. Differentiated human airway epithelia were mock infected (Naive), infected with Ad2/GFP (Control), or infected with adenovirus vectors encoding wt-CAR, Tailless-CAR, or GPI-CAR. Two days after infection, cellular lysates were assessed for expression of Flag-tagged CAR proteins by Western blot analysis using anti-Flag M2-HRP monoclonal antibody. Arrows indicate the observed migration profiles of full-length CAR, Tailless-CAR, and GPI-CAR; migration of the three bands was consistent with the predicted molecular masses. The band at approximately 70 kDa was nonspecific as it was also observed in naive and mock-infected cells.

GPI-CAR, Tailless, and wt-CAR show distinct patterns of cell surface distribution in differentiated airway epithelia. We analyzed apical expression of CAR proteins by applying anti-Flag antibody to the apical surface followed by immunocytochemistry.Neither the control nor epithelia expressing wt-CAR presentedFlag-tagged CAR on the apical membrane (Fig. 3A). In contrast,epithelia expressing GPI-CAR showed substantial CAR on the apicalmembrane. Epithelia expressing Tailless-CAR showed a small amountof apical staining. These observations suggest the GPI modificationtargets CAR to the apical membrane, consistent with observationsfor GPI-anchored proteins in other epithelial cell types (20).In addition, the presence of Tailless-CAR on the apical surfacesuggests the cytoplasmic domain plays an essential role in exclusivebasolateral localization of CAR in airway epithelia.

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FIG. 3. Cell surface distribution of modified CAR proteins expressed in human airway epithelia. (A) Apical localization of CAR molecules was evaluated in airway epithelia with immunocytochemistry. GFP-positive cells are shown in green, and apical Flag antibody binding is shown in red. Polarized surface distribution of CAR molecules was quantitated with a radioimmunoassay on the apical surface (B), or the basolateral surface (C). Data are means + standard errors of the means (error bars) (n = 6). *, P < 0.01 compared to control.

To obtain a more quantitative assessment of the polarized distribution of Flag-tagged CAR, we used a radioimmunoassay to measurespecific binding of anti-Flag antibody to CAR-expressing airwayepithelia. There was no specific binding of ¹²⁵I-anti-Flag antibody to the apical surface of airway epitheliaexpressing wt-CAR (Fig. 3B). This result is consistent with thelack of endogenous CAR at the apical surface (25, 35). Consistentwith the immunocytochemical localization, there was a large amountof apical binding in epithelia expressing GPI-CAR and a smallamount in epithelia expressing Tailless-CAR. In contrast, at thebasolateral membrane we observed specific binding of ¹²⁵I-anti-Flag antibody in epithelia expressing wt-CAR and Tailless-CAR,but not GPI-CAR (Fig. 3C). Hence, airway epithelia specificallysequester wt-CAR in the basolateral membrane and GPI-CAR in theapical membrane. Tailless-CAR was distributed to both membranedomains.

Expression of GPI-CAR in airway epithelia enhances apical binding of adenovirus. We also studied binding of Cy3-labeled adenovirus to the apical membrane of CAR-expressing airway epithelia. Consistent withprevious observations, adenovirus did not bind to control epitheliaexpressing $beta$ -Gal (Fig. 4) (35). Moreover, there was little orno apical binding of adenovirus to epithelia expressing recombinantwt-CAR. This is consistent with basolateral localization of theprotein (Fig. 3). However, adenovirus bound to the apical surfaceof epithelia expressing GPI-CAR and, to a lesser extent, the epitheliaexpressing Tailless-CAR. These data indicate that adenovirus canbind to the extracellular domain of CAR when it is present onthe apical surface of differentiated epithelia.

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FIG. 4. Effect of CAR expression on adenovirus binding to the apical surface of CAR-expressing human airway epithelia. Data are en face projections of Cy3-labeled adenovirus (red) bound to the apical surface of control and CAR-expressing airway epithelia. DAPI-stained nuclei are blue.

Apical localization of CAR is sufficient for adenovirus-mediated gene transfer from the apical surface. To determine if apical localization of CAR is sufficient for adenovirus infection, we investigated adenovirus-mediated genetransfer from the apical surface of epithelia expressing wt-CAR,Tailless-CAR, or GPI-CAR. Using Ad2/GFP we found minimal genetransfer in epithelia expressing wt-CAR and Tailless-CAR (Fig.5A). However, GPI-CAR expression substantially increased genetransfer. These results indicate that expression of GPI-CAR inairway epithelia is sufficient for adenovirus-mediated gene transferfrom the apical surface.

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FIG. 5. Effect of CAR expression on adenovirus-mediated gene transfer to airway epithelia. Two days after CAR gene transfer, airway epithelia were infected with Ad2/GFP from the apical surface (A), Ad2/ $beta$ Gal from the apical surface (B), Ad2/ $beta$ Gal from the apical surface following PI-PLC treatment (C), or Ad2/ $beta$ Gal from the basolateral surface (D) (each at an MOI of 10) for 30 min. Epithelia were studied 48 h later. $beta$ -Gal data are means + standard errors of the means (error bars) (n = 6). *, P < 0.01 compared to control. Lu, light units.

To obtain a more quantitative assessment of gene transfer, we measured $beta$ -Gal expression after apical application of Ad2/ $beta$ Gal.We observed a marginal increase in $beta$ -Gal activity in epitheliaexpressing either wt-CAR or Tailless-CAR as compared to control(Fig. 5B). In contrast, we found a marked increase in gene transferfrom the apical surface of airway epithelia expressing GPI-CAR.Pretreatment of GPI-CAR expressing epithelia with PI-PLC inhibitedgene transfer with Ad2/ $beta$ Gal, suggesting that gene transfer throughGPI-CAR requires the GPI modification (Fig. 5C). We also measuredgene transfer from the basolateral surface. All epithelia, includingthe controls, were readily infected with adenovirus, consistentwith basolateral localization of the endogenous receptor (Fig.5D) (25, 35). There was a slight although not statisticallysignificant increase in gene transfer from the basolateral surfacein epithelia overexpressing Tailless- and wt-CAR. Moreover, theabsolute level of transgene expression after apical addition ofvector to GPI-CAR expressing epithelia was similar to the transgeneexpression obtained after adding vector to the basolateral surfaceof control epithelia expressing only endogenous CAR (Fig. 5B and5D).

Removing apical glycocalyx does not potentiate adenovirus infection in airway epithelia. A previous study reported that expression of GPI-CAR was not sufficient for adenovirus-mediated gene transfer from the apicalsurface of a canine renal epithelial cell line (MDCK); rather,treatment with neuraminidase was also required (24). That studysuggested that the glycocalyx, specifically sialic acid, was abarrier preventing apical gene transfer. Our finding that GPI-CARefficiently rescues apical gene transfer suggests that the glycocalyxis not an absolute barrier in differentiated human airway epithelia.However, these data do not rule out the possibility that the glycocalyxconstitutes a major but not absolute barrier to gene transfer.To test this possibility, we treated CAR-expressing epitheliawith neuraminidase to remove sialic acid or with glycosidasesto remove either N- or O-linked carbohydrates. The ability ofthe enzymes to remove carbohydrate from the apical surface wasconfirmed by a decrease in FITC-WGA binding to the apical membrane(Fig. 6A); WGA binds to sialic acid (32). Since disrupting thetight junctions allows adenovirus access to endogenous CAR onthe basolateral membrane, we measured transepithelial resistanceas an indication of epithelial integrity (35). None of the enzymetreatments altered transepithelial resistance (data not shown).Furthermore, the enzyme treatments of epithelia expressing wt-CARor Tailless-CAR had no effect on gene transfer (Fig. 6B). Hence,enzyme treatments did not damage epithelial integrity and allowgene transfer through the basolateral membrane. In agreement withaforementioned results (Fig. 5), Fig. 6B shows that GPI-CAR facilitatedadenovirus-mediated gene transfer from the apical surface. Importantly,removal of the glycocalyx with neuraminidase or glycosidases didnot significantly enhance gene transfer compared to that seenwith mock-treated epithelia.

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FIG. 6. Effect of neuraminidase or glycosidase treatment on adenovirus-mediated gene transfer to CAR expressing airway epithelia. (A) Two days after CAR gene transfer, airway epithelia were pretreated with neuraminidase (Neur), O-glycosidase (O-gly), or N-glycosidase (N-gly) and stained with FITC-labeled WGA. Data are en face projections of WGA binding to the apical membrane of airway epithelia. WGA binding (in relative intensity units) decreased following treatment with neuraminidase (14.5 ± 1.9), O-glycosidase (21.0 ± 1.4), and N-glycosidase (20.3 ± 1.2) compared to control (29.5 ± 1.0) (n = 9 for each). (B) Treated epithelia were also assayed for gene transfer with Ad2/ $beta$ Gal. Fluorescence and $beta$ -Gal data are means + standard errors of the means (error bars) (n = 6).

GPI-CAR is sufficient for adenovirus-mediated gene transfer of CFTR from the apical surface of CF epithelia. Airway epithelia are a target for gene transfer in CF. Therefore, we asked whether there are gene transfer barriers in CFepithelia not found in normal epithelia and whether gene transfervia the apical membrane can correct the Cl transport defect. We measured transepithelial Cl current in CAR-expressing CF epithelia following applicationof Ad2/CFTR. The Cl current following CFTR gene transfer to wt-CAR- and Tailless-CAR-expressingepithelia was no different from that seen with the control (Fig.7). In contrast, epithelia expressing GPI-CAR showed substantialcorrection of the Cl current, approaching levels seen in normal epithelia (28 ± 1µA · cm²). These results indicate that expression of GPI-CAR was sufficientto support adenovirus-mediated gene transfer from the apical surfaceof CF epithelia. Importantly, gene transfer occurred in cellswhich are capable of CFTR-dependent Cl transport.

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FIG. 7. Effect of CAR expression on adenovirus-mediated CFTR expression by CF airway epithelia. Two days after CAR gene transfer, CF airway epithelia were infected with Ad2/CFTR-16 (MOI, 10) for 30 min from the apical surface. Forty-eight hours later the epithelia were studied in Ussing chambers. Data are changes in current (means + standard errors of the means [error bars]) after the addition of bumetanide to cyclic AMP-stimulated, amiloride-treated epithelia ( $Delta$ I_Bum) (n = 6). *, P < 0.01 compared to control.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

These results show that placing a specific binding site for adenovirus vectors on the apical surface of airway epithelia facilitatesgene transfer. In addition, the data show that similar treatmentof CF epithelia also facilitated gene transfer and correctionof the CF Cl transport defect. This study has the advantage that it used well-differentiatedhuman airway epithelia that retain many of the properties of thein vivo airways, including the resistance to adenovirus-mediatedgene transfer. Nevertheless, although the in vitro model oftenpredicts in vivo behavior, our study is limited in that therecould be other barriers to gene transfer invivo.

The apical membrane of airway epithelia contain few $alpha$ _v $beta$ ₃ or $alpha$ _v $beta$ ₅ integrins; nonetheless, GPI-CAR rescued both adenovirus bindingand gene transfer from the apical membrane. Thus, these data indicatethat the penton base-integrin interaction is not required forgene transfer. This conclusion is consistent with data obtainedfrom in vivo studies in other systems (14). GPI-anchored proteinslocalize to lipid rafts (31), which may be involved in endocyticsorting (22). In addition, GPI-anchored proteins can be foundin lipid raft domains in close proximity to caveolae or insidethe caveolae (1, 28). Hence, the activity of GPI-CAR mightbe augmented by its location in areas of the apical membrane withactive internalization (endocytosis or potocytosis), thereby maskingthe need for integrins. In either event, these results bring intoquestion the need for coreceptors which can potentiate internalization,at least when the receptor is abundant or localized in an areaof active membrane turnover. Therefore, targeting strategies toairway epithelia may not be hindered by the lack ofcoreceptors.

Previous work reported that the glycocalyx (specifically sialic acid) prevented gene transfer from the apical surface of MDCKcells (24). However, our data indicate that removing the glycocalyxdid not potentiate gene transfer to airway epithelia. There areseveral possible explanations for these different observations.First, the difference may be due to structural differences betweenthe MDCK cell lines and primary cultures of differentiated airwayepithelia. Second, the two systems used to express CAR could haveproduced different levels of the receptor. Third, the glycocalyxcould be a barrier in airway epithelia, and although the datashow that apical carbohydrate was removed, we may not have removedsufficient glycocalyx to observe a difference in gene transfer.However, when we tested more prolonged enzyme treatments, transepithelialresistance fell, which would have allowed the vector to accessbasolateral receptors. Thus, although we cannot exclude the possibilitythat the glycocalyx interferes to some extent, this interferencemay be of secondary importance compared to the presence or absenceof thereceptor.

In conclusion, expressing CAR on the apical surface by GPI modification rescues adenovirus binding and gene transfer fromthe apical surface of airway epithelia. These data suggest thattargeting binding sites on the apical surface will enhance genetransfer. This conclusion is consistent with other approachesto enhancing gene transfer. For example, increasing nonspecificapical binding of adenovirus by incorporation in CaPi coprecipitatesor complexes including cationic lipids facilitated gene transfer(6, 7). Moreover, targeting adenovirus to another GPI-linkedprotein, the urokinase plasminogen activator receptor, or to P2Yreceptors enhanced gene transfer (5, 17). Thus, perhaps numerousdifferent methods of increasing binding may be sufficient to improvegene transfer. However, we predict that targeting a high-affinityreceptor which is capable of internalization will result in themost efficient gene transfer to the airwayepithelia.

	ACKNOWLEDGMENTS

R.W.W. and W.V.H. contributed equally to thiswork.

We thank Michael Seiler, Janice Launspach, Tom Moninger, Phil Karp, Pary Weber, Tamara Nesselhauf, Theresa Mayhew, RosannaSmith, and Michele Kadnar for excellent assistance. We especiallyappreciate the help of ISOPO and IIAM for providing the humanlungs. We thank Sam Wadsworth, Genzyme, for the gift of Ad2/GFPand Ad2/CFTR and Jeffrey Bergelson, Children's Hospital of Philadelphia,for the gift of wt-CAR, Tailless-CAR, and GPI-CAR cDNAs. We appreciatethe support of the In Vitro Cell Models Core and the Universityof Iowa Gene Transfer VectorCore.

This work was supported by NHLBI grants HL51670 (J.Z. and M.J.W.) and PO1 HL51746-08 (R.G.C.); the Cystic Fibrosis Foundation(W.V.H., J.Z., R.G.C., and M.J.W.); the Will Rogers Memorial Fund(R.G.C.); GenVec, Inc. (R.G.C.); the Parker B. Francis Foundation(W.V.H.); and the Roy J. Carver Charitable Trust (J.Z.). M.J.W.is an Investigator of the Howard Hughes MedicalInstitute.

	FOOTNOTES

^* Corresponding Author. Mailing address: Howard Hughes Medical Institute, University of Iowa College of Medicine, 500 EMRB,Iowa City, IA 52242. Phone: (319) 335-7619. Fax: (319) 335-7623.E-mail: mjwelsh{at}blue.weeg.uiowa.edu.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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1.	Anderson, R. G. 1998. The caveolae membrane system. Annu. Rev. Biochem. 67:199-225[CrossRef][Medline].
2.	Arcasoy, S. M., J. Latoche, M. Gondor, S. C. Watkins, R. A. Henderson, R. Hughey, O. J. Finn, and J. M. Pilewski. 1997. MUCl and other sialoglycoconjugates inhibit adenovirus-mediated gene transfer to epithelial cells. Am. J. Respir. Cell Mol. Biol. 17:422-435[Abstract/Free Full Text].
3.	Bergelson, J. M., J. A. Cunningham, G. Droguett, E. A. Kurt-Jones, A. Krithivas, J. S. Hong, M. S. Horwitz, R. L. Crowell, and R. W. Finberg. 1997. Isolation of a common receptor for coxsackie $beta$ viruses and adenoviruses 2 and 5. Science 275:1320-1323[Abstract/Free Full Text].
4.	Bewley, M. C., K. Springer, Y. B. Zhang, P. Freimuth, and J. M. Flanagan. 1999. Structural analysis of the mechanism of adenovirus binding to its human cellular receptor, CAR. Science 286:1579-83[Abstract/Free Full Text].
5.	Drapkin, P. T., C. R. O'Riordan, S. M. Yi, J. A. Chiorini, J. Cardella, J. Zabner, and M. J. Welsh. 2000. Targeting the urokinase plasminogen activator recéptor enhances gene transfer to human airway epithelia. J. Clin. Investig. 105:589-596[Medline].
6.	Fasbender, A., J. H. Lee, R. W. Walters, T. O. Moninger, J. Zabner, and M. J. Welsh. 1998. Incorporation of adenovirus in calcium phosphate precipitates enhances gene transfer to airway epithelia in vitro and in vivo. J. Clin. Investig. 102:184-193[Medline].
7.	Fasbender, A., J. Zabner, M. Chillon, T. O. Moninger, A. P. Puga, B. L. Davidson, and M. J. Welsh. 1997. Complexes of adenovirus with polycationic polymers and cationic lipids increase the efficiency of gene transfer in vitro and in vivo. J. Biol. Chem. 272:6479-6489[Abstract/Free Full Text].
8.	Freimuth, P., K. Springer, C. Berard, J. Hainfeld, M. Bewley, and J. Flanagan. 1999. Coxsackievirus and adenovirus receptor amino-terminal immunoglobulin V-related domain binds adenovirus type 2 and fiber knob from adenovirus type 12. J. Virol. 73:1392-1398[Abstract/Free Full Text].
9.	Ginsberg, H. S. 1984. The adenoviruses. Plenum Press, New York, N.Y.
10.	Goldman, M. J., and J. M. Wilson. 1995. Expression of $alpha$ _v $beta$ ₅ integrin is necessary for efficient adenovirus-mediated gene transfer in the human airway. J. Virol. 69:5951-5958[Abstract].
11.	Greber, U. F., I. Singh, and A. Helenius. 1994. Mechanisms of virus uncoating. Trends Microbiol. 2:52-56[CrossRef][Medline].
12.	Greber, U. F., M. Willetts, P. Webster, and A. Helenius. 1993. Stepwise dismantling of adenovirus 2 during entry into cells. Cell 75:477-486[CrossRef][Medline].
13.	Grubb, B. R., R. J. Pickles, H. Ye, J. R. Yankaskas, R. N. Vick, J. F. Engelhardt, J. M. Wilson, L. G. Johnson, and R. C. J. Boucher. 1994. Inefficient gene transfer by adenovirus vector to cystic fibrosis airway epithelia of mice and humans. Nature 371:802-806[CrossRef][Medline].
14.	Hautala, T., T. Grunst, A. Fabrega, P. Freimuth, and M. J. Welsh. 1998. An interaction between penton base and alpha v integrins plays a minimal role in adenovirus-mediated gene transfer to hepatocytes in vitro and in vivo. Gene Ther. 5:1259-1264[CrossRef][Medline].
15.	Knowles, M. R., K. W. Hohneker, Z. Zhou, J. C. Olsen, T. L. Noah, P. C. Hu, M. W. Leigh, J. F. Engelhardt, L. J. Edwards, K. R. Jones, et al. 1995. A controlled study of adenoviral-vector-mediated gene transfer in the nasal epithelium of patients with cystic fibrosis. New Engl. J. Med. 333:823-831[Abstract/Free Full Text].
16.	Kondo, M., W. E. Finkbeiner, and J. H. Widdicombe. 1991. Simple technique for culture of highly differentiated cells from dog tracheal epithelium. Am. J. Physiol. 261:L106-L117[Abstract/Free Full Text].
17.	Kreda, S. M., R. J. Pickles, E. R. Lazarowski, and R. C. Boucher. 2000. G-protein-coupled receptors as targets for gene transfer vectors using natural small-molecule ligands. Nat. Biotechnol. 18:635-640[CrossRef][Medline].
18.	Leon, R. P., T. Hedlund, S. J. Meech, S. Li, J. Schaack, S. P. Hunger, R. C. Duke, and J. DeGregori. 1998. Adenoviral-mediated gene transfer in lymphocytes. Proc. Natl. Acad. Sci. USA 95:13159-13164[Abstract/Free Full Text].
19.	Leopold, P. L., B. Ferris, I. Grinberg, S. Worgall, N. R. Hackett, and R. G. Crystal. 1998. Fluorescent virions: dynamic tracking of the pathway of adenoviral gene transfer vectors in living cells. Hum. Gene Ther. 9:367-378[Medline].
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