Neutralized Adenovirus-Immune Complexes Can Mediate Effective Gene Transfer via an Fc Receptor-Dependent Infection Pathway

Neutralization of adenovirus (Ad) by anti-Ad neutralizing antibodiesin serum involves formation of Ad-immune complexes that preventthe virus from interacting with target cells. We hypothesizedthat Ad-immune complexes likely contain viable Ad vectors which,although no longer capable of gaining access to receptors ontarget cells, may be able to express transgenes in cells bearingFc receptors for immunoglobulins, i.e., that antibody-based"neutralization" of Ad vectors may be circumvented by the Fcreceptor pathway. To test this hypothesis, we expressed theFc ${gamma}$ receptor IIA (Fc ${gamma}$ R) in A549 lung epithelial cells or humandermal fibroblasts and evaluated gene transfer in the presenceof human neutralizing anti-Ad serum. Fc ${gamma}$ R-expressing cells boundand internalized copious amounts of Ad, with a distinct populationof internalized Ad trafficking to the nucleus. The dose-responsecurves for inhibition of gene transfer revealed that Fc ${gamma}$ R-expressingcells required a more-than-10-fold higher concentration of anti-Adserum to achieve 50% inhibition of Ad-encoded ß-galactosidaseexpression compared with non-Fc ${gamma}$ R-expressing cells. The discrepancybetween neutralization of Ad during infection of Fc ${gamma}$ R-expressingcells and neutralization of Ad during infection of non-Fc ${gamma}$ R-expressingcells occurred with either heat-inactivated or non-heat-inactivatedsera, was blocked by addition of purified Fc domain protein,and did not require the cytoplasmic domain of Fc ${gamma}$ R, suggestingthat immune complex internalization proceeded via endocytosisrather than phagocytosis. Fc ${gamma}$ R-mediated infection by Ad-immunecomplexes did not require expression of the coxsackie virus-Adreceptor (CAR) since similar data were obtained when CAR-deficienthuman dermal fibroblasts were engineered to express Fc ${gamma}$ R. However,interaction of the Ad penton base with cell surface integrinscontributed to the difference in neutralization between Fc ${gamma}$ R-expressingand non-Fc ${gamma}$ R-expressing cells. The data indicate that complexesformed from Ad and anti-Ad neutralizing antibodies, while compromisedwith respect to infection of non-Fc ${gamma}$ R-expressing target cells,maintain the potential to transfer genes to Fc ${gamma}$ R-expressing cells,with consequent expression of the transgene. The formation ofAd-immune complexes that can target viable virus to antigen-presentingcells may account for the success of Ad-based vaccines administeredin the presence of low levels of neutralizing anti-Ad antibody.

INTRODUCTION

Top

Introduction

One ubiquitous challenge regarding the use of viral vectorsfor gene transfer relates to the ability of immune-competenthosts to develop neutralizing humoral immunity against the viralcapsid. In the case of adenovirus (Ad) gene transfer vectorsbased on subgroup C viruses, approximately one-half of the generalpatient population has a detectable neutralizing antibody titer(3, 10, 11, 19, 21, 21, 53, 61, 65, 68). The problem is exacerbatedwhen one considers the impact of repeated administration ofAd vectors. Following each successive administration, the neutralizingantibody titer tends to increase and the efficacy of gene transferdecreases dramatically (10, 19, 33, 41, 42, 86).

Neutralization of Ad by antibodies has typically been describedwith one of two possible outcomes: intracellular neutralizationor extracellular neutralization. Intracellular neutralizationrefers to an Ad-immune complex that enters the cell but failsto accomplish gene delivery to the nucleus. With purified antibodiesagainst individual capsid proteins, several groups have demonstratedintracellular neutralization with accumulation of Ad insideorganelles in the cytoplasm (12, 52, 55, 79-81). Extracellularneutralization, in which formation of Ad-immune complexes preventsAd from interacting with target cells, is the predominant formof neutralization for unfractionated, anti-Ad sera (52, 74).However, it is not clear whether extracellularly neutralizedAd is necessarily neutralized with respect to intracellulartrafficking. In other words, there may exist viable Ad capsidsin extracellular Ad-immune complexes that could traffic to thenucleus and express viral genes if given the opportunity tointeract with cells.

The relevance of this question lies in the fact that antigen-presentingcells express receptors for immune complexes and can internalizeimmune complexes via Fc receptors. The Fc receptor family includesboth high-affinity and low-affinity receptors for the Fc portionof immunoglobulins (17). The low-affinity receptors (Fc ${gamma}$ RII andFc ${gamma}$ RIII) clear immune complexes from tissue and serum and enhancethe immune response to foreign antigens contained in the antibody-antigencomplex (30). In the event that viable viral capsids gain entryto an antigen-presenting cell via Fc receptor interaction, thereexists a potential viral gene expression with the antigen-presentingcell (14, 44), a mechanism that can lead to particularly strongimmune responses to virus-encoded antigens.

With the knowledge that formation of Ad-immune complexes preventsAd access to target cells, we hypothesized that Ad-immune complexesmay contain viable virus that is capable of intracellular traffickingand infection if the Ad-immune complex is forced to interactwith target cells via Fc receptors. To address this hypothesis,Fc ${gamma}$ receptor IIA (Fc ${gamma}$ R) was expressed in a nonhematopoietic targetcell line. This strategy was based on the fact that this isoformof Fc ${gamma}$ R was previously shown to contain an immunoreceptor tyrosine-basedactivation domain and thus was capable of directing phagocytosisof immune complexes (46). In addition, the use of nonhematopoieticand nonmyeloid cell lines avoided potential confusion from endogenousexpression of Fc ${gamma}$ R, a strategy previously validated in the literature(29, 30). Following formation of Ad-immune complexes with neutralizinganti-Ad serum, the intracellular trafficking of Ad capsids andAd-mediated gene transfer were assessed over a range of ratiosof Ad to neutralizing anti-Ad serum to determine the concentrationof anti-Ad serum that gave 50% inhibition of gene transfer (IC₅₀).

MATERIALS AND METHODS

Top

Materials and Methods

Ad vectors. All of the Ads used in this study were E1^– E3^– replication-deficient,recombinant Ad gene transfer vectors with an expression cassetteinserted into the E1 position. The expression cassette includedthe cytomegalovirus promoter-enhancer, a simian virus 40 polyadenylationsignal, and a transgene. The study included vectors encodinga ß-galactosidase transgene (Adßgal) (22),an Fc ${gamma}$ R (CD32) transgene (AdFc ${gamma}$ R) (8), a vector with a form ofthe Fc receptor that lacked the cytoplasmic domain (AdtaillessFc ${gamma}$ R)(8), and a vector that was used as a control for vector infectioninto which no cDNA had been inserted (AdNull) (22). In additionto these vectors, one tropism-modified vector was employed.The vector was identical to Adßgal except that thenucleic acid sequence encoding the penton base protein was alteredto modify the three amino acids (RGD) that confer integrin binding(Ad ${Delta}$ RGDßgal) (76). All vectors were propagated, purified,and stored as described previously (56, 57). All vectors hadparticle-to-PFU ratios of less than 100. Virus concentrationwas determined on the basis of the extinction coefficient forAd (9.09 x 10^–13 M^–1 cm^–1) (47). Covalentconjugation of the red fluorophore Cy3 to the Ad capsid wasaccomplished by succinimidyl ester chemistry as previously described(39, 49).

Cell culture. A549 lung epithelial carcinoma cells (CCL-185; American TypeCulture Collection, Manassas, VA) express the high-affinitycoxsackie virus-Ad receptor (CAR) (23) and were used as a modelfor CAR-sufficient cells. Human dermal fibroblasts are deficientin CAR expression (23). A549 cells were maintained in Dulbecco'smodified Eagle's medium supplemented with 10% fetal bovine serum,50 U/ml penicillin, and 50 µg/ml streptomycin at 37°Cin 5% CO₂. Fibroblasts were maintained in RPMI 1640 cell culturemedium supplemented with 10% fetal bovine serum, 50 U/ml penicillin,and 50 µg/ml streptomycin at 37°C in 5% CO₂. All cellculture reagents were obtained from Life Technologies, Inc.(Gaithersburg, MD).

Anti-Ad neutralizing sera, titer determination, and heat inactivation. Human neutralizing sera were obtained in the course of genetherapy clinical trials that have been previously describedin detail (19). Sera were previously assayed for neutralizinganti-Ad titer by propagation of wild-type Ad5 infection in amonolayer culture of A549 cells and were stored at –80°Cuntil use (19). Neutralizing titers of individual sera are describedin the text according to the inverse of the lowest dilutionthat gave a 90% inhibition of adenovirus serotype 5 infection.Except where noted otherwise, the neutralizing titer of theanti-Ad serum was 2,560 (i.e., a 2,560-fold dilution was thelowest dilution to give 90% inhibition of adenovirus infection).Upon thawing, sera were heat inactivated at 55°C for 60min prior to use, except where noted otherwise. This researchwas performed in compliance with the Health Information Privacyand Protection Act. This report does not contain informationon the identities of patients from whom samples were collected.

Preinfection of A549 cells or human dermal fibroblasts with AdFc ${gamma}$ R. Fc ${gamma}$ R expression was obtained by preinfecting cells with AdFc ${gamma}$ R.For A549 cells, the preinfection conditions were 1,000 particlesper cell, 60 min, 37°C. For human dermal fibroblasts, thepreinfection conditions were 10,000 particles per cell, 60 min,37°C. The use of a higher concentration of Ad to infecthuman dermal fibroblasts was previously shown to be requiredbecause of the absence of CAR (19, 39). Preinfected cells wereprepared in parallel with uninfected cells (naive), as wellas cells preinfected with AdNull as a control for vector infection.Where noted, preinfection was performed in the same manner withAdtaillessFc ${gamma}$ R. After 3 h, preinfected A549 cells or fibroblastswere replated at a density of 10⁴ cells per well on a 96-wellplate for analysis of gene transfer or at a density of 10⁴ cellsper well of a coverslip bottom dish for microscopic analysis(19, 39).

Evaluation of Ad binding and Fc ${gamma}$ R expression. Ad-immune complexes were formed as previously described, bypreparing serial dilutions of neutralizing sera (0.01, 0.03,0.1, 0.3, 1, 3, and 10%) in binding buffer (modified Eagle'smedium without phenol red [Life Technologies], 1% bovine serumalbumin [BSA; Sigma Chemical Co., St. Louis, MO], and 10 mMHEPES, pH 7.3 [BioFluids, Rockville, MD]) (19, 39). After preparationof the serial dilutions of serum, sufficient Ad was added tothe mixture to yield a concentration of 10¹¹ Cy3Ad particles/ml.The mixture was then incubated at 37°C for 5 min. Priorto infection, the cells were washed three times with bindingbuffer. A 30-µl volume of the Ad-serum mixture was addedto 10⁴ cells in the well of a coverslip bottom dish. The infectionproceeded for 10 min at 37°C. The unbound virus was thenwashed away (three times with binding buffer) and returned tocomplete cell culture medium. Cells were incubated for an additional60 min, washed three times with phosphate-buffered saline (PBS),and fixed with paraformaldehyde (4% in PBS, 20 min, 22°C;Electron Microscopy Sciences, Inc., Fort Washington, PA). Afterfixation, cells were prepared for indirect immunofluorescenceby blocking with 5% goat serum (Calbiochem, La Jolla, CA) and1% BSA in PBS plus 0.1% Triton X-100 (Sigma Chemical Co., St.Louis, MO) for 20 min. Primary antibody (fluorescein isothiocyanate-conjugatedanti-CD32; Pharmingen/BD Biosciences, San Diego, CA) or an irrelevantprimary antibody (fluorescein isothiocyanate-conjugated anti-CD64;Pharmingen/BD Biosciences) was applied to the cells at a 1:100dilution in block for 60 min. Cells were washed thoroughly with1% BSA in PBS, and nuclei were stained with 4',6'-diamidino-2-phenylindole(DAPI; Molecular Probes, Eugene, OR) at a concentration of 1µg/ml in PBS. Cells were imaged with a Nikon MicrophotSA microscope with a 60x N.A. 1.4 PlanApo differential interferencecontrast objective and DAPI, fluorescein, and Cy3 filters; aPrinceton Instruments cooled charge-coupled device camera; andMetaMorph image analysis software (Universal Imaging, Inc.,Downingtown, PA) as previously described (19, 39).

Evaluation of Ad-mediated ß-galactosidase gene expression. Monolayers of naive cells, AdNull-infected cells, or AdFc ${gamma}$ R-infectedcells were infected with Adßgal in a manner identicalto the method described for infection with Cy3Ad above, withthe exceptions that Adßgal was substituted for Cy3Adand that infection occurred in wells of a 96-well plate insteadof a coverslip bottom dish. Each condition was replicated inat least six wells per condition. After infection, cells wereincubated for 24 h and ß-galactosidase transgene expressionwas evaluated in cell lysates by quantitative chemiluminescencedetection (Tropix, Bedford, MA) and normalized to the proteinconcentration of the cell lysate with the bicinchoninic acidreagent (Bio-Rad, Hercules, CA). In A549 cells, the ß-galactosidaseactivity measured in cells infected in the absence of neutralizingserum was, on average, approximately 3 x 10⁵ relative lightunits/mg or 2,000-fold above the background. In fibroblasts,the ß-galactosidase activity measured in the absenceof neutralizing serum was 2 x 10⁴ relative light units/mg or100-fold above the background.

To determine the IC₅₀s for each condition, data were normalizedto the control value for the data set (infection in the absenceof serum). Normalized data from independent experiments wereaveraged to generate a dose-response curve for inhibition ofAd-mediated gene transfer by the serum. The data were used togenerate a summary dose-response curve and were fitted witha spline (SigmaPlot for Windows; SPSS, Inc., Chicago, IL). Thepoint at which the curve intersected a normalized transgeneexpression level of 0.5 (corresponding to 50% inhibition relativeto the control) was taken as the IC₅₀ for the experiment.

Competition with purified Fc domain. To test the dependence of Ad-immune complex-mediated gene transferon interaction of Fc domains with Fc receptors, complexes ofAdßgal with 0.1% neutralizing serum (titer of 2,560)were used to infect AdNull- or AdFc ${gamma}$ R-infected A549 cells. Infectionswere perfumed in the absence or presence of the purified Fcdomain at 1 mg/ml (Calbiochem). Infection conditions and analysisof ß-galactosidase activity were performed as describedabove.

Viability. Because of reports of cytotoxic effects of Ad-immune complexesin the literature (34-37), the viability of cells was checked1 h after the 10-min treatment with Ad-immune complexes createdwith dilutions of the serum with a titer of 2,560. Cell viabilitywas assessed with two fluorophores, one that stains live cells(calcein AM) and one that stains dead cells (ethidium homodimer1; Live-Dead Cytotoxicity Kit; Molecular Probes). Counts oflive and dead cells were performed on fluorescence micrographswith automated image analysis software (MetaMorph; UniversalImaging).

Statistics. All data are reported as the mean ± the standard error.Student's t test was used to compare conditions, with P valuesof <0.05 indicative of a significant difference.

RESULTS

Top

Results

Fc ${gamma}$ R-dependent cell association of Ad-immune complexes. Immune complexes were formed by combining Cy3Ad with a rangeof concentrations of neutralizing serum (0.01% to 10%). Theimmune complexes were applied to A549 cells previously infectedwith either AdNull or AdFc ${gamma}$ R. In AdNull-infected cells, cell-associatedAd decreased as the concentration of neutralizing serum increased,similar to data previously reported for naive A549 cells (74).At a concentration of 0.1% serum, cell-associated Cy3Ad wasnoticeably decreased and virtually all Cy3Ad was prevented fromreaching the cells at a serum concentration of 1.0% (Fig. 1A).In contrast, A549 cells expressing Fc ${gamma}$ R maintained the abilityto bind Ad-immune complexes at serum concentrations as highas 10% (Fig. 1B). Fluorescence intensity of cell-associatedCy3Ad indicated that the amount of viral capsid taken up byFc ${gamma}$ R-expressing cells exceeded the amount of Cy3Ad internalizedby a CAR-dependent mechanism in naive A549 cells. One strikingobservation concerned the ability of Cy3Ad to traffic to thenucleus. The nuclear perimeter in Fc receptor-bearing cellswas demarcated by Cy3Ad even when Cy3Ad was mixed with as muchas 1.0% neutralizing serum, indicating that some of the capsidsinternalized as Ad-immune complexes were capable of traffickingin a fashion similar to that of naive Cy3Ad. When AdNull-infectedcells were compared to AdFc ${gamma}$ R-infected cells, both in the presenceof 1% neutralizing serum, it was clear that much of the capsidassociated with Fc ${gamma}$ R-expressing cells was neutralized with respectto AdNull-infected cells. When Fc ${gamma}$ R-bearing A549 cells were exposedto Cy3Ad-immune complexes in the presence of neutralizing serum,the amount of Cy3Ad found in the cytoplasm rather than at thenucleus increased as the concentration of neutralizing serumincreased (Fig. 1B). The intense, punctate concentrations ofCy3Ad in the cytoplasm indicated that some of virus was unableto traffic to the nucleus.

View larger version (82K):
[in this window]
[in a new window]
FIG. 1. Association of Ad-immune complexes with A549 cells. A fluorochrome-conjugated Ad vector (Cy3Ad) was mixed with various concentrations of human serum (0.01% to 10%) containing anti-Ad neutralizing antibodies (undiluted titer, 2,560). After 5 min, the Cy3Ad-serum mixture was applied to monolayers of A549 cells previously infected with a control Ad (AdNull) or an Ad carrying the human Fc ${gamma}$ R gene (AdFc ${gamma}$ R). After a 10-min infection period, unbound virus was removed by washing and Cy3Ad was allowed to traffic within cells for 60 min. The subcellular localization of Ad (Cy3, red channel) and nuclei (DAPI, blue channel) was evaluated by fluorescence microscopy. (A) AdNull-infected A549 cells treated with Cy3Ad in the presence of various concentrations of anti-Ad neutralizing antiserum. Note the association of Cy3Ad with the nucleus (black arrowheads) in the absence of serum and the disappearance of Cy3Ad from A549 cells with increasing serum concentrations. (B) AdFc ${gamma}$ R-infected A549 cells treated with Cy3Ad in the presence of various concentrations of anti-Ad neutralizing antiserum. Note the sustained association of Cy3Ad with Fc ${gamma}$ R-bearing A549 cells despite the increasing concentration of serum. The association of Cy3Ad with the nuclear envelope in Fc ${gamma}$ R-expressing cells (black arrowheads) was maintained even at neutralizing serum concentrations that prevent association of Ad with AdNull-treated cells. At the highest serum concentration, no Ad was capable of trafficking to the nucleus (white arrowheads). Images were acquired and displayed under identical conditions. Bars = 10 µm.

To understand the significance of the subcellular localizationof Ad following infection of Fc ${gamma}$ R-bearing cells with Ad-immunecomplexes, localization of the Ad capsid was compared to localizationof the Fc ${gamma}$ RII protein. The amount of immune complexes associatedwith A549 cells corresponded to the level of Fc ${gamma}$ R expressionin the cells (Fig. 2A). Fc ${gamma}$ RII-positive staining was found atthe plasma membrane, as well as in a punctate pattern, typicalof intracellular, endocytic vesicles that internalize and recyclethe Fc ${gamma}$ R (Fig. 2B). The distribution of Cy3Ad included perinuclearaccumulation, as well as a punctate pattern that colocalizedwith the punctate portion of Fc ${gamma}$ RII (Fig. 2B). Colocalizationof Cy3Ad and Fc ${gamma}$ RII suggested that a portion of Cy3Ad failedto escape from Fc ${gamma}$ R-containing organelles. These data showedthat anti-Ad neutralizing serum induced primarily extracellularneutralization at lower concentrations (e.g., 1% in the caseof this serum) and induced complete intracellular neutralizationonly at higher concentrations (e.g., 10% in the case of thisserum).

View larger version (45K):
[in this window]
[in a new window]
FIG. 2. Intracellular accumulations of Ad-immune complexes in A549 cells colocalize with Fc ${gamma}$ R. Fc ${gamma}$ R-expressing A549 cells were infected with Cy3Ad in the presence of 0.1% anti-Ad neutralizing serum and processed as described in the legend to Fig. 1. After fixation, indirect immunofluorescence detection of Fc ${gamma}$ R was performed. The subcellular distribution of Cy3Ad (red), Fc ${gamma}$ R (green), and nuclei (blue) was evaluated by fluorescence microscopy. (A) Fc ${gamma}$ R-negative cells showed no interaction with Ad-immune complexes (white arrowheads), while Fc ${gamma}$ R-positive cells bound and internalized Ad-immune complexes, leading to successful trafficking of Cy3Ad to the nuclear envelope (black arrowheads). (B) High-magnification images of Cy3Ad and Fc ${gamma}$ R staining, showing colocalization. Note that colocalization of Cy3Ad and Fc ${gamma}$ R occurred in the cytoplasm (arrows), resulting in a yellow signal in the overlaid image. Bars = 10 µm.

Fc ${gamma}$ R-dependent Ad-mediated gene expression. To confirm that trafficking of Cy3Ad corresponded to successfulgene transfer, A549 cells were exposed to Ad-immune complexesthat were formed with an Ad vector carrying the ß-galactosidasetransgene (Adßgal). In earlier in vitro studies usinga different protocol for the formation of Ad-immune complexes,significant cytotoxicity was attributed to antibody-aggregatedAd (34-37). Differential cell viability could complicate theinterpretation of the gene expression results. In the presentstudies, cell cultures were assessed for cell viability followinginfection with Ad-immune complexes. A549 cells maintained >90%viability regardless of the ratio of neutralizing serum to Adparticles (not shown).

The kinetics of neutralization were compared in naive A549 cellsand A549 cells preinfected with either AdNull or Ad Fc ${gamma}$ R. Neutralizationof Adßgal in AdNull-treated A549 cells was comparableto the kinetics of neutralization in naive A549 cells (Fig.3). Ad-mediated gene expression was reduced by 50% when Ad wasexposed to a low concentration of neutralizing serum (<0.1%).In contrast, AdFc ${gamma}$ R-treated cells exhibited elevated levels ofgene transfer to A549 cells and did not reach 50% neutralizationuntil exposed to >1% serum (Fig. 3). Comparison of IC₅₀sshowed that cells expressing the Fc receptor required a 37-foldhigher concentration of this neutralizing serum in order toachieve 50% inhibition of gene transfer compared with controlAdNull-infected cells (Fig. 3). The precise shift in the IC₅₀is likely to be a unique property of a given serum and basedon the precise combination of anti-Ad epitopes and anti-Ad isotypesin the serum.

View larger version (23K):
[in this window]
[in a new window]
FIG. 3. Fc ${gamma}$ R-mediated gene transfer by neutralized Ad-immune complexes. An Ad vector expressing the ß-galactosidase transgene (Adßgal) was mixed with various concentrations of human serum (0.01% to 10%) containing anti-Ad neutralizing antibodies (titer, 2,560). After 5 min, the Adßgal-serum mixture was applied to monolayers of naive A549 cells or A549 cells previously infected with either AdNull or AdFc ${gamma}$ R. ß-Galactosidase activity was assayed after 24 h and normalized to cellular protein content (relative light units per milligram of protein). Data were normalized to Adßgal infection in the absence of serum for each target cell type (dashed line at y = 1.0). The IC₅₀ was determined as the concentration of serum that resulted in a 50% decrease in ß-galactosidase gene expression (dotted line at y = 0.5). Comparable dose-response curves were obtained in the presence of neutralizing serum during infection of either naive or AdNull-infected A549 cells, In contrast, addition of neutralizing serum during infection of AdFc ${gamma}$ R-infected A549 cells shifted the dose-response inhibition curve, resulting in a higher IC₅₀.

To test whether the shift in IC₅₀ was generally related to theneutralizing titer of the anti-Ad serum, two other sera withlower and higher neutralizing titers were evaluated. As predicted,the IC₅₀ measured in naive A549 cells corresponded to the anti-Adtiter of the serum. With the same dilution series of sera witha low or high anti-Ad neutralizing titer (undiluted titer ofeither 20 or 49,000), the observed IC₅₀ shifted correspondingly,indicating that the inhibition curve was governed by the anti-Adantibodies rather than another serum component (Fig. 4). Foreach serum, the IC₅₀ for Fc ${gamma}$ R-expressing cells was significantlyhigher than for AdNull-infected or naive cells. In fact, 50%inhibition did not occur in the serum with the lowest titer(undiluted titer, 20), even when the serum was present at thehighest concentration (10%). The IC₅₀s for one serum (undilutedtiter, 2,560), either with or without prior heat inactivation,were similar, suggesting that complement was not involved inthe interaction of Ad-immune complexes with Fc ${gamma}$ R-expressing cells(Fig. 4).

View larger version (28K):
[in this window]
[in a new window]
FIG. 4. Effect of Fc receptor expression on IC₅₀ of anti-Ad sera. Ad-immune complexes were formed and applied to naive, AdNull-infected, or AdFc ${gamma}$ R-infected A549 cells with dilutions of sera with various titers, including titers of 20, 2,560, and 49,000. In addition, anti-Ad serum (titer, 2,560) was used to form Ad-immune complexes without prior heat inactivation of the serum. IC₅₀s were determined as described in the legend to Fig. 3.

Characterization of the role of the Fc receptor in gene transfer following uptake of Ad-immune complexes. To confirm the importance of the Fc-Fc receptor interactionin the rescue of Ad-immune complexes, the uptake of Ad-immunecomplexes was assayed in the absence or presence of the purifiedFc domain, a competitive inhibitor of antibody-Fc receptor binding.AdNull-infected A549 cells supported a minimal level of transgeneexpression in the presence of 0.1% serum, regardless of thepresence or absence of the purified Fc domain (Fig. 5). In contrast,the high level of gene transfer in Fc receptor-bearing A549cells was reduced by more than 75% in the presence of the purifiedFc domain, indicating the importance of the Fc-Fc receptor interactionin uptake of Ad-immune complexes.

View larger version (18K):
[in this window]
[in a new window]
FIG. 5. Dependence of Ad-immune complex uptake on Fc-Fc receptor interaction. To demonstrate that Ad-immune complex uptake requires interaction of the Fc domain of immunoglobulins with the Fc receptor, A549 cells were infected with either AdNull or AdFc ${gamma}$ R and then exposed to Ad-immune complexes prepared by mixing Adßgal with 0.1% anti-Ad serum (titer, 2,560) in the presence or absence of the purified Fc domain at 1 mg/ml. After 24 h, ß-galactosidase activity was assessed and normalized to the protein content of the sample. RLU, relative light units.

Prior studies of Fc ${gamma}$ R have demonstrated that the cytoplasmictail is required for phagocytosis of large ligands (29). Incontrast, the cytoplasmic tail of endocytic receptors is normallyrequired for optimal internalization but is not necessary toaccomplish endocytosis of small ligands (32, 50). To test whetherthe cytoplasmic domain is required, A549 cells were preinfectedwith Ad vectors carrying either full-length Fc ${gamma}$ R or a truncatedversion of the Fc ${gamma}$ R gene that lacked the cytoplasmic domain (AdtaillessFc ${gamma}$ R).When challenged with a range of doses of neutralizing serum,A549 cells expressing the full-length Fc receptor or the taillessFc receptor had identical kinetics of inhibition, indicatingthat the cytoplasmic tail of the Fc receptor is not requiredfor binding and entry of Ad-immune complexes into cells (Fig.6).

View larger version (22K):
[in this window]
[in a new window]
FIG. 6. Lack of dependence of Ad-immune complex uptake on the Fc receptor cytoplasmic domain. To evaluate the mechanism of internalization of Ad-immune complexes, gene transfer to Fc receptor-expressing cells was evaluated in cells expressing either full-length Fc ${gamma}$ R or a truncated version of Fc ${gamma}$ R that lacks the cytoplasmic tail. A549 cells were infected with Ad Fc ${gamma}$ R or AdtaillessFc ${gamma}$ R and subsequently exposed to Ad-immune complexes prepared as described in the legend to Fig. 3. After 24 h, ß-galactosidase activity was assessed and normalized to the protein content of the sample.

Receptor dependence of Fc ${gamma}$ R-mediated rescue of neutralized Ad. A549 cells express both the Ad high-affinity receptor for theAd fiber protein (CAR) and ${alpha}$ _V integrins, which serve as the lower-affinityreceptor for the Ad penton base protein (23, 62). Since capsid-receptorinteractions play a critical role during Ad escape to the cytosol(48, 49, 63, 77), the fiber-CAR interaction and the penton base-integrininteraction were investigated.

To evaluate the effect of loss of fiber-CAR interaction, CAR-deficienthuman dermal fibroblasts previously treated with AdNull or AdFc ${gamma}$ R were evaluated for uptake of Ad-immune complexes. Each conditionwas analyzed for viral trafficking with Cy3Ad-immune complexesand for gene expression with Adßgal-immune complexes.As expected, very little Cy3Ad bound to AdNull-infected fibroblasts,regardless of the presence of serum, since the fibroblasts lackeda high-affinity receptor for either the Ad capsid or immunoglobulinsin the Ad-immune complexes. Ad Fc ${gamma}$ R-infected fibroblasts bounda small amount of Cy3Ad in the absence of serum, but in thepresence of 0.1% neutralizing anti-Ad serum, copious amountsof Cy3Ad were associated with Fc ${gamma}$ R-bearing fibroblasts (Fig.7). A smaller proportion of internalized Ad was observed atthe nuclear envelope compared to A549 cells. This differencelikely reflected the propensity of Ad to traffic to the microtubuleorganizing center, as well as the nucleus, in fibroblasts (5,66).

View larger version (31K):
[in this window]
[in a new window]
FIG. 7. Association of Ad-immune complexes with CAR-deficient human dermal fibroblasts modified to express Fc ${gamma}$ R. Cy3Ad-immune complexes were prepared and applied to human dermal fibroblasts as described in the legend to Fig. 1. The target cells used included human dermal fibroblasts previously infected with either AdNull or AdFc ${gamma}$ R. After a 10-min infection, unbound virus was removed by washing. Cells were incubated for an additional 60 min to allow Cy3Ad trafficking within the cell. After fixation, cell nuclei were stained with a fluorophore (DAPI) and the position of virus within the cell was evaluated by fluorescence microscopy. Note that 0.1% neutralizing serum was sufficient to prevent Ad association with AdNull-infected fibroblasts. However, with the same concentration of neutralizing serum, a high level of cell-associated Cy3-Ad was observed. Bar = 10 µm.

To examine gene transfer via uptake of Ad-immune complexes inthe absence of CAR, naive fibroblasts or fibroblasts previouslyinfected with AdNull or AdFc ${gamma}$ R were infected with immune complexesformed with an Ad vector that carried the ß-galactosidasetransgene (Adßgal) (Fig. 8A). The most striking aspectof the neutralization curve for Fc receptor-bearing fibroblastswas the dramatic increase in gene transfer at low concentrationsof serum. The presence of 0.3% neutralizing serum led to anincrease in gene transfer to Fc receptor-bearing fibroblastsof 64-fold compared to gene transfer in the absence of serum.The dramatic increase in gene transfer reflected the introductionof a high-affinity immunoglobulin G-Fc ${gamma}$ R interaction that enabledAd-immune complexes to bind to cells. The high level of genetransfer to Fc receptor-bearing fibroblasts was accompaniedby a 6.5-fold increase in the IC₅₀ of the neutralizing serum(Fig. 8B). The IC₅₀ for AdNull-infected fibroblasts was 0.2%serum, while the IC₅₀ for AdFc ${gamma}$ R-infected fibroblasts was 1.3%serum.

View larger version (20K):
[in this window]
[in a new window]
FIG. 8. Fc ${gamma}$ R-mediated gene transfer by neutralized Ad-immune complexes in CAR-deficient fibroblasts. To determine the contribution of the native high-affinity interaction of Ad with CAR during immune complex uptake, immune complexes were exposed to naive (CAR-deficient) fibroblasts or fibroblasts infected with AdNull or AdFc ${gamma}$ R. Immune complex formation and evaluation of gene transfer were performed as described in the legend to Fig. 3. (A) Ad-mediated gene transfer as a function of the anti-Ad serum concentration in naive, AdNull-infected, and AdFc ${gamma}$ R-infected A549 cells. (B) IC₅₀s for all of the conditions tested.

To evaluate the requirement for the penton base-integrin interactionduring Fc ${gamma}$ R-dependent infection of A549 cells, Ad-immune complexeswere created with either wild-type Ad capsid or an Ad capsidthat had been genetically altered to remove the RGD integrin-bindingmotif in the penton base (Ad ${Delta}$ RGDßgal) (76). A comparisonof the kinetics of gene transfer following formation of Adßgal-or Ad ${Delta}$ RGDßgal-immune complexes demonstrated strikingdifferences in gene transfer in the presence or absence of integrininteraction (Fig. 9A). In A549 cells expressing Fc ${gamma}$ R, differentIC₅₀s were determined for the same serum, depending on the Advector that had been incorporated into the immune complex. Strikingly,when Ad-immune complexes were formed with Ad ${Delta}$ RGDßgal,the IC₅₀ of the serum for inhibiting gene transfer to Fc ${gamma}$ R-expressingA549 cells (0.09%) was comparable to the IC₅₀ of immune complexesformed with Adßgal on non-Fc ${gamma}$ R expressing cells (0.03to 0.06%) (Fig. 9B, black bars). These data differ from theresult obtained when immune complexes were formed with Adßgal(Fig. 9B, white bars), suggesting that the penton base-integrininteraction is important for Ad-immune complexes to deliverviable Ad capsids to Fc ${gamma}$ R-expressing cells.

View larger version (20K):
[in this window]
[in a new window]
FIG. 9. Fc ${gamma}$ R-mediated gene transfer by neutralized Ad-immune complexes in the absence of penton base-integrin interaction. To determine the contribution of the penton base-integrin interaction during immune complex uptake, Ad-immune complexes were formed from either Adßgal or an Ad vector that had been modified to remove the integrin-binding RGD sequence from the penton base protein (Ad ${Delta}$ RGDßgal). The Ad-immune complexes were applied to A549 cells that had previously been infected with AdFc ${gamma}$ R. Evaluation of gene transfer was performed as described in the legend to Fig. 3. (A) Ad-mediated gene transfer to Fc ${gamma}$ R as a function of anti-Ad serum concentration with either Adßgal or Ad ${Delta}$ RGDßgal. (B) IC₅₀s for all of the conditions tested.

DISCUSSION

Top

Discussion

The experiments described herein were designed to answer thefollowing question: is neutralized Ad in Ad-immune complexesno longer infectious? This question was based on the observationthat increasing concentrations of neutralizing serum led primarilyto extracellular neutralization, i.e., abrogation of viral interactionwith cells (74). This observation left open the possibilitythat viable Ad capsids, as well as nonviable Ad capsids, werecaught in the Ad-immune complexes but that the viable Ad capsidsno longer had access to the target cell surface. To answer thisquestion, an experimental system was designed to force Ad-immunecomplexes to associate with target cells. Target cells weregenetically modified to express Fc ${gamma}$ R, a receptor for the Fc domainof immunoglobulins. While it is a formal possibility that somenonspecific effect of the exogenous membrane of a membrane proteinaccounts for the observations described here, the fact thatthe enhanced infection of Fc receptor-expressing target cellswas abrogated by an excess of the purified Fc domain arguesthat it was, in fact, the Fc-Fc receptor interaction that ledto immune complex uptake. The Fc-Fc receptor interaction isphysiologically relevant in that this receptor is expressedon tissue macrophages and dendritic cells and leads to uptakeand antigen presentation of opsonized materials in vivo. Historically,viral neutralization has been characterized on the basis ofquantitative and qualitative analyses of the neutralizing serum.This study demonstrates that viral neutralization is also afunction of the characteristics of target cells, potentiallyleading to new interpretations of viral neutralization in thecomplexity of an in vivo setting.

The data clearly demonstrated that uptake of Ad-immune complexesvia the Fc receptor not only led to elevated viral gene expressionbut also effectively changed the neutralization properties (IC₅₀)of the serum. It is important to note that the extent to whicha given serum will show a change in its IC₅₀ is likely to bedetermined by a number of factors, including the isotypes ofantibodies against the virus and the number and identity ofepitopes contributing to the antiserum. Unlike prior studiesof viral neutralization by serum in vitro which employed extendedincubations of virus with neutralizing serum prior to infectingcells, the present study intended to model the interactionsthat might occur upon administration of a gene transfer vectorto a patient with preexisting anti-Ad immunity. With the knowledgethat viable Ad capsids are quickly cleared from serum (2, 70,83), an acute in vitro model of immune complex formation andtarget cell infection was designed. To mimic acute exposureof Ad to immune sera, followed by rapid access to target cells,the experimental protocol called for mixing of Ad and anti-Adserum for only 5 min prior to infection of a monolayer of targetcells for 10 min. The concentration of virus used for the infections(10¹¹ particles per ml) is comparable to the dose of virus administeredin clinical trials for local or systemic administration (19).

In the present study, no immune complex-induced cytotoxicitywas observed. Kjellen and Ankerst used a protocol in which 2h was allowed for Ad-immune complex formation with wild-typeAd and 2 to 6 h was allowed for immune complex exposure to cells(34-37). These investigators reported cytotoxicities as highas 100%, depending on the ratio of serum to Ad and the timeof exposure of complexes to target cells. In contrast, the protocolemployed herein limited the time of formation of Ad-immune complexesand the duration of exposure of complexes to target cells asdescribed above. As a result, cell viability was >90% forall conditions. The observation that gene transfer occurredindependent of the presence of the cytoplasmic tail of the Fcreceptor underscored the likelihood that endocytosis ratherthan phagocytosis was sufficient to internalize the small Ad-immunecomplexes formed by this protocol. There exists a potentialfor formation of cytotoxic Ad-immune complexes in vivo, andimportantly, Ad-immune complexes formed with wild-type, replication-competentAd have been proposed as causative agents in the canine eyedisorder anterior uveitis and in canine and human nephrotoxicity(1, 84, 85, 87). However, cytotoxicity due to the formationof Ad-immune complexes from replication-deficient gene transfervectors has not been reported, and under the conditions usedin this study, significant cytotoxicity was not observed.

A number of avenues of research have focused on the abilityof antibodies to modulate viral infection. The effect of antibodiesreported here confirms previous reports of antibody-enhancedinfection in a number of viruses, including human immunodeficiencyvirus (HIV), coxsackie virus B4, and rhinovirus (6, 24, 25,69). Unlike the observations reported here, antibody-enhancedinfection by viruses that are tropic for Fc ${gamma}$ R-bearing cells didnot constitute a change in the tropism of the virus. The observationspresented here show that binding of neutralizing antibodiesto Ad may shift the tropism of Ad away from native target cells(CAR-expressing epithelial cells) toward a new target cell (Fc ${gamma}$ R-bearingantigen-presenting cells). This report is also distinct fromstudies in which nonneutralizing antibodies have been used toretarget Ad to Fc ${gamma}$ R-bearing cells (14, 44, 45), since modificationof tropism was observed following treatment with whole, unfractionatedneutralizing serum rather than selected monoclonal antibodies.Finally, this study is distinct from studies in which humansera have been analyzed to determine the relative contributionof neutralizing antibodies against each of the major capsidproteins (12, 52, 55, 59, 60, 67, 68, 73, 75, 79) since thosestudies examined the effects of subsets of antibodies ratherthan whole, unfractionated neutralizing serum on the infectivityof Ad. While this report does not test the hypothesis that Fcreceptor-mediated uptake of Ad-immune complexes could be a meansof propagating a wild-type infection in a host organism, itis interesting that persistent subgroup C Ad infections havebeen reported in lymphoid tissue of humans and mice (13, 15,18, 31, 38, 51, 54, 58, 64, 72), where a high concentrationof Fc receptor-bearing cells resides. Also of interest, folliculardendritic cells, T lymphocytes, and B lymphocytes are all capableof expressing Fc receptors (40, 71) and persistent Ad infectionshave been noted in patients with neutralizing anti-Ad antibodies(64). In contrast, these cell types have low or undetectablelevels of CAR expression (26-28, 78, 82). Among the three lymphoidcell types, CD4⁺ CD8⁺ CD3⁺ T lymphocytes appear to be the majorharbor for Ad in lymphoid tissue and support low levels of viralreplication, although a small but detectable population of Adwas detected in a CD4⁺ CD8⁺ CD3^– population that includeddendritic cells (16, 43). Garnett et al. (16) noted that thelevel of Ad DNA decreased with age in the study population,correlating with the age-related loss of Fc receptor expressionon follicular dendritic cells (4). The latent infection by Adin lymphoid tissue may then result from a complex interactionof viruses, anti-Ad antibodies, Fc receptor-expressing cells,and low rates of viral replication.

The observation that a virus might be capable of gene expressionin Fc ${gamma}$ R-bearing cells when it has been effectively neutralizedwith respect to infection in other cell types may have importantimplications for Ad-mediated therapeutic gene transfer and,in particular, Ad-based vaccines. The observations in the presentreport suggest a pathway for antigen presentation in which ahost with preexisting anti-Ad immunity is exposed to Ad. Afterthe formation of Ad-immune complexes, Fc ${gamma}$ R-bearing antigen-presentingcells may phagocytose the complexes, leading to presentationof viral capsid proteins via major histocompatibility complex(MHC) class II. However, some small fraction of the virus mayescape from the phagosome and productively infect the antigen-presentingcell, leading to presentation of viral proteins via MHC classI. The implication of cross-priming both in pathogenic viralinfection and in the clinical setting of viral gene transferdeserves additional study. The idea that the class I and classII pathways could be activated in a host with preexisting anti-Adneutralizing antibody titers further predicts that an Ad-basedvaccine could be effective in a patient with an anti-Ad neutralizingantibody titer. Some prior reports support this hypothesis.Although expression of marker genes cannot be detected followingsystemic administration of Ad vectors in the presence of a neutralizinganti-Ad antibody titer (9, 19, 33, 41, 42, 86), neutralizingantibodies and cytotoxic T-lymphocyte responses that can conferprotective immunity have been developed following delivery ofgene transfer vectors under similar conditions (7, 20, 60, 68).In fact, in a recent analysis of data relating to the use ofAd vectors to deliver an HIV vaccine in a human clinical trial,the trial sponsor chose to stratify the data, with one groupof patients carrying preexisting anti-Ad antibody titers of<200 while a second tier had anti-Ad antibody titers of $≥$ 200.The group with the detectable but low anti-Ad antibody titerdeveloped an immune response to the Ad-encoded HIV antigen (N.Chirmule, personal communication). Even though neutralizingantibody titers are likely to prevent therapeutic gene transferto a target cell, gene expression in antigen-presenting cellsmediated by Ad-immune complexes might provide sufficient stimulationto boost an immune response. The observation that Ad-immunecomplexes can be used to transfer genes to dendritic cells invitro (45) also supports the possibility that this phenomenoncould contribute to immune recognition of Ad-encoded gene productsin vivo.

The analysis of Ad receptors that contribute to viral gene expressionfrom Ad-immune complexes yielded important insights with implicationsfor Ad-mediated gene therapy. Fc ${gamma}$ R-mediated infection by Ad-immunecomplexes formed with the native Ad capsid versus an Ad ${Delta}$ RGD capsidin A549 cells demonstrated that the RGD sequence in the pentonbase was essential to observe the shift in IC₅₀. If uptake ofAd-immune complexes by antigen-presenting cells in vivo leadsto cross-priming through viral gene expression, then use ofan Ad ${Delta}$ RGD capsid may limit MHC class I presentation in antigen-presentingcells and therefore might blunt the cell-mediated immune responseagainst vector-encoded genes in patients with preexisting anti-Adhumoral immunity.

ACKNOWLEDGMENTS

We thank N. Mohamed for help in preparing the manuscript, B.G. Harvey (Weill Medical College) for providing characterizedhuman anti-Ad neutralizing antiserum, S. Schreiber (Universityof Pennsylvania) for Fc ${gamma}$ R constructs, and R. McKinney for technicalassistance.

These studies were supported, in part, by P01 HL59312; the WillRogers Foundation, Los Angeles, CA; and the Cystic FibrosisFoundation.

FOOTNOTES

* Corresponding author. Mailing address: Weill Medical College of Cornell University, Department of Genetic Medicine, 1300 York Avenue, W401, New York, NY 10021. Phone: (212) 746-2255. Fax: (212) 746-8824. E-mail: geneticmedicine{at}med.cornell.edu.

REFERENCES

Top