Novel, Chimpanzee Serotype 68-Based Adenoviral Vaccine Carrier for Induction of Antibodies to a Transgene Product

An E1-deletion-containing adenoviral recombinant based on thechimpanzee serotype 68 (AdC68) was developed to express therabies virus glycoprotein. Mice immunized with this construct(AdC68rab.gp) developed antibodies to rabies virus and remainedresistant to challenge with an otherwise lethal dose of rabiesvirus. In naïve mice immunized intranasally, the rabiesvirus-specific antibody responses elicited by AdC68rab.gp werecomparable with regard to both titers and isotype profiles tothose induced by an adenoviral recombinant based on human serotype5 (Adhu5) expressing the same transgene product. In contrast,subcutaneous immunization with the AdC68rab.gp vaccine resultedin markedly lower antibody responses to the rabies virus glycoproteinthan the corresponding Adhu5 vaccine. Antibodies from AdC68rab.gp-immunizedmice were strongly biased towards the immunoglobulin G2a isotype.The antibody response to the rabies virus glycoprotein presentedby Adhu5rab.gp was severely compromised in animals preexposedto the homologous adenovirus. In contrast, the rabies virus-specificantibody response to the AdC68rab.gp vaccine was at most marginallyaffected by preexisting immunity to common human adenovirusserotypes, such as 2, 4, 5, 7, and 12. This novel vaccine carrierthus offers a distinct advantage over adenoviral vaccines basedon common human serotypes.

INTRODUCTION

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Introduction

E1-deletion-containing replication-defective adenoviral recombinantsbased on human serotype 5 (Adhu5) have been tested widely ascarriers for gene therapy (2, 21). Gene therapy trials demonstratedhigh-level expression of the transgene product in a varietyof different cell types. Nevertheless, expression was transientin vivo due to clearance of adenovirus-infected cells by CD8⁺T cells directed against antigens of the adenovirus as wellas against the transgene product (4, 26). Vaccine studies basedon the rabies virus glycoprotein (22), the circumsporozoiteprotein of Plasmodium falciparum (17), the E6 and E7 oncoproteinsof human papillomavirus type 16 (HPV-16) (9), and others (9;J. Fitzgerald, G.-P. Gao, A. Reyes-Sandoval, G. N. Pavlakis,Z. Q. Xiang, A. P. Wlazlo, W. Giles-Davis, J. Wilson, and H.C. J. Ertl, submitted for publication) demonstrated that E1-deletion-containingadenoviral recombinants induce, even if given at moderate doses,superb B-cell and CD8⁺-T-cell responses in experimental animals.The immune responses to the transgene products far surpass thoseachieved with other types of subunit vaccines, such as vacciniavirus recombinants or DNA vaccines (9, 22, 23; J. Shiver, AIDSVaccines 2001, abstr. LB5, 2001). The high immunogenicity ofadenoviral recombinants relates in part to the noncytopathicnature of such viruses, which permits sustained antigen expression(22). In addition, adenoviruses that enter cells primarily,although not exclusively, through interaction with the coxsackie-adenovirusreceptor (CAR) (3) efficiently transduce dendritic cells (27),which are the main cell population able to present antigen toa naïve immune system.

Nevertheless, although E1-deletion-containing human adenoviralrecombinants have yielded highly promising results as vaccinesin rodents, canines, and nonhuman primates (9, 18, 19, 22; Fitzgeraldet al., submitted; Shiver, AIDS Vaccines 2001), preexistingimmunity in humans, who frequently encounter these ubiquitousviruses and generally seroconvert within their first years oflife, is expected to interfere with the efficacy of such vaccines.We showed previously that the efficacy of Adhu5 recombinantvaccines was impaired in mice which had had prior exposure tothe same serotype of adenovirus. The response could be rescuedeither by increasing the dose of the vaccine, which augmentsthe cost and the risk of side effects, or by using a DNA vaccineexpressing the same transgene product for priming (22, 23).However, prime booster regimens increase the cost of a vaccine,and their use is subject to logistic problems, especially inless developed countries. Furthermore, although both prime boostervaccinations and increases in the vaccine dose restored theantibody response to the transgene product in preimmune rodents,humans are expected to encounter the common serotypes of humanadenoviruses more frequently. The resulting immunological memorymay not be as readily overcome as the more moderate responsein rodents to a single immunization with a virus that failsto replicate in this species. We therefore developed an adenoviralrecombinant vaccine based on a chimpanzee serotype, i.e., serotype68 (1) using the well-defined rabies virus glycoprotein as ourmodel antigen. This serotype of adenovirus does not circulatein humans and lacks neutralizing B-cell epitopes cross-reactingwith those of common human serotypes (7).

MATERIALS AND METHODS

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Materials and Methods

Mice. Female 6- to 8-week-old C3H/He mice were purchased from JacksonLaboratory, Bar Harbor, Maine. Outbred ICR mice were purchasedfrom Charles River (Wilmington, Mass.). Mice were kept in theAnimal Facility of the Wistar Institute.

Cell lines. Mammalian cells, i.e., baby hamster kidney 21 (BHK-21) cells,E1-transfected 293 cells, thymidine kinase-negative (TK^-) 143Bhuman osteosarcoma cells (Wistar Institute), and L929 mousefibroblast cells, were propagated in Dulbecco's modified Eagle'smedium supplemented with glutamine, sodium pyruvate, nonessentialamino acids, HEPES buffer, antibiotic, and 10% fetal bovineserum.

Rabies viruses. Rabies virus of the Evelyn Rokitniki-Abelseth (ERA) and challengevirus standard 11 (CVS-11) strains were propagated on BHK-21cells. ERA was purified over a sucrose gradient, inactivatedby treatment with ß-propionolactone, and adjustedto a protein concentration of 0.1 mg/ml. CVS-11 was titratedon BHK-21 cells and by intracerebral injection into adult ICRmice (24).

Adenoviruses. Adenoviruses of the human serotypes 2, 4, 5, 7, and 12 and thechimpanzee serotype 68 were propagated and titrated on human293 cells. The recombinant Adhu5 constructs expressing the glycoproteinof rabies virus strain ERA or the L1 protein of HPV-16 havebeen described previously (11, 22). An expression system usingan E1-deletion-containing adenoviral recombinant based on thechimpanzee serotype 68 (AdC68) was developed as described previously(7). Briefly, the full-length coding sequence for the glycoproteinof rabies virus was ligated into the NotI site of the pC68-CMV-APshuttle vector, replacing the alkaline phosphatase (AP) sequence.The resulting vector, pC60CMVrab.gp, was digested with BglIIand PacI. A 4.6-kb BglII/PacI fragment containing C68 map units0 to 1, the rab.gp minigene cassette, and C68 m.u.9-11 was isolatedfrom this digestion and subcloned into the BglII and PacI sitesof the pCMVAPMU32 vector, resulting in pC68-CMVrab.gpMU36. Thisconstruct (8 µg) was cotransfected with 2 µg ofSspI-digested AdC68 genome in which E1 had been replaced withthe gene for green fluorescent protein (AdC68CMVGFP) into 293cells. White plaques were isolated and characterized as describedpreviously (7). Viruses were propagated on 293 cells transfectedwith the E1 from Adhu5 (8). Viruses were harvested by freeze-thawingof the cells. For some experiments, virus was purified by CsClgradient purification. For other experiments, cleared supernatantof the infected cells subjected to three rounds of freeze-thawingwas used. Viruses were titrated on 293 cells to determine thenumber of PFU.

Expression of the transgene product by the adenoviral recombinants. (i) Immunoprecipitation. TK^- cells (10⁶ per sample) were infected, at 5 PFU/cell, withthe AdC68rab.gp or Adhu5rab.gp construct or control constructsexpressing unrelated viral antigens. After 48 h, cells werewashed twice with sterile phosphate-buffered saline (PBS) andthen incubated for 90 min in serum-free medium prior to theaddition of 20 µl of ³⁵S-labeled cysteine and methionine(Promix; NEN, Boston, Mass.). After 4 h of incubation, cellswere washed with PBS and then treated for 20 min with 1 ml ofradioimmunoprecipitation assay buffer containing protease inhibitors.Cells and cell debris were removed from the wells, vortexedbriefly, and centrifuged for 2 min at 12,000 rpm in an Eppendorfmicrocentrifuge. The supernatant was incubated for 90 min at4°C with of ascitic fluid (15 µl/ml) containing the509-6 monoclonal antibody to the rabies virus glycoprotein.Protein G-Sepharose was added at 75 µl per sample andincubated at 4°C with mild agitation for 30 min. The sampleswere pelleted by centrifugation and washed four times with radioimmunoprecipitationassay buffer. The pellets were resuspended in 80 µl ofloading buffer and boiled for 4 min. Samples (20 µl) werethen separated over a sodium dodecyl sulfate-12% polyacrylamidegel along with a molecular weight standard. Gels were driedonto filter papers, which were exposed for 48 h to Kodak scientificimaging film (X-Omat Blue XB-1).

(ii) Immunofluorescence. L929 and TK^- cells (10⁶ per sample) were infected for 48 h with5 PFU of Adhu5rab.gp or AdC68rab.gp per cell. Control cellswere left uninfected. Cells were treated for 45 min on ice with100 µl of a 1:1,000 dilution of the 509-6 antibody inPBS or with PBS only. Cells were then washed and treated for45 min with 100 µl of a 1:100 dilution of a fluoresceinisothiocyanate-labeled anti-mouse immunoglobulin (Ig). Cellswere washed and analyzed by flow cytometry.

Immunization and challenge of mice. Mice were vaccinated with various doses of the adenovirusesor the adenoviral recombinants given in 100 µl of salinesubcutaneously or in 50 µl intranasally. Mice were challengedwith rabies virus strain CVS-11 given at 10 mean lethal doses(LD₅₀) intracerebrally. After challenge, mice were checked every24 to 48 h for at least 21 days. They were euthanized once theydeveloped complete hind leg paralysis, which is indicative ofterminal rabies virus encephalitis.

Serological assays. (i) ELISA. Enzyme-linked immunosorbent assays (ELISAs) were performed basicallyas described before (22). Mice were bled by retro-orbital puncturea various intervals after immunization. Sera were prepared andtested for antibodies to rabies virus on plates coated with0.1 µg of inactivated rabies virus per well. Sera weretested for antibodies to adenovirus on plates coated with 5x 10⁹ virus particles of purified E1-deletion-containing adenovirusrecombinants to green fluorescent protein of human serotype5 or chimpanzee serotype 68 per well. Plates were coated overnightand then blocked for 24 h with PBS containing 3% bovine serumalbumin. After washing, sera diluted in PBS-3% bovine serumalbumin were added for 60 min. After washing, a 1:100 dilutionof AP-conjugated goat anti-mouse Ig (Cappel) was added for 1h at room temperature. After washing, substrate was added for20 to 30 min at room temperature. Optical density was read at405 nm.

(ii) Isotype profile of antibodies. Isotypes of antibodies to rabies virus were determined by anELISA on plates coated with inactivated ERA virus with a Calbiochem(La Jolla, Calif.) hybridoma subisotyping kit with some minormodifications as previously described (22). Sera were testedat a 1:400 dilution.

(iii) Virus neutralization assays. Sera were tested for neutralizing antibodies to rabies virusstrain CVS-11, which is antigenically closely related to theERA strain, as described previously (25). A World Health Organizationreference serum was used for comparison. Titers are expressedin international units.

RESULTS

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Results

Expression of the rabies virus glycoprotein by the adenoviral recombinants. The AdC68rab.gp recombinant was generated in 293 cells transfectedwith E1 of human adenovirus serotype 5 (7). Viral clones wereinitially screened by indirect immunofluorescence with monoclonalantibody 509-6, which recognizes a conformation-dependent epitopeof the rabies virus glycoprotein. After selection of a stableadenoviral subclone, expression of full-length rabies virusglycoprotein by AdC68rab.gp in infected TK^- cells was confirmedby immunoprecipitation. As shown in Fig. 1, both AdC68rab.gpand Adhu5rab.gp expressed a protein of the expected size thatwas precipitated by the 509-6 antibody. Expression of correctlyfolded rabies virus glycoprotein in AdC68rab.gp-infected cellswas further demonstrated by indirect immunofluorescence followedby flow-cytometric analysis again using the 509-6 antibody.In transduced TK^- cells, the Adhu5rab.gp construct appearedto result in higher levels of rabies virus glycoprotein, asdid transduction with the AdC68rab.gp construct. However, inother cell lines (data shown only for L929 cells), such as mouseL929 fibroblasts, equal levels of transgene expression wereachieved with both vectors.

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FIG. 1. Expression of the rabies virus glycoprotein in cells transduced with the Adhu5 or AdC68 recombinants. (A) Immunoprecipitation. Radiolabeled lysates from cells infected for 48 h with 5-PFU/cell doses of the Adhu5rab.gp recombinant (lane 1), an Adhu5 construct expressing HIV-1 Gag (lane 2), an AdC68 construct expressing HIV-1 Gag (lane 3), or the AdC68rab.gp recombinant (lane 4) were immunoprecipitated with a monoclonal antibody to the rabies virus glycoprotein and separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. (B) Immunofluorescence. Uninfected, AdC68rab.gp-infected, and Adhu5rab.gp-infected L929 and TK^- cells were treated with PBS (gray line) or the 509-6 antibody (black line). Cells were then treated with a fluorescein isothiocyanate (FITC)-labeled antibody to mouse Ig and analyzed by flow cytometry. The graph shows events over green fluorescent intensity.

Induction of a B-cell response by the adenoviral recombinants to the rabies virus glycoprotein. Vaccine-induced protection to rabies virus correlates with virus-neutralizingantibodies (VNAs) (25). Our studies thus focused on stimulationof this arm of the immune system. In all experiments, mice wereimmunized either subcutaneously or intranasally with AdC68rab.gpor the previously described Adrab.gp construct (22). This recombinantis referred to here as Adhu5rab.gp.

The rabies virus-specific antibody response was tested in inbredand outbred strains of mice immunized with serial dilutionsof either of the recombinants. Sera were harvested 14 days afterimmunization and tested for antibodies to the rabies virus glycoproteinby an ELISA (Fig. 2) and a virus neutralization assay (Table1). Adenoviral recombinants encoding an unrelated viral transgeneused as controls (8) failed to induce an antibody response torabies virus detectable by either assay.

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FIG. 2. Antibody response to rabies virus. Groups of five C3H/He or ICR mice were immunized with 5 x 10⁷ ( ${blacksquare}$ ; tested in subcutaneously [s.c.] immunized C3H mice only), 5 x 10⁶ (), 5 x 10⁵ ( ${boxplus}$ ), 5 x 10⁴ ( ${square}$ ), or 5 x 10³ ( ${boxtimes}$ ; tested in intranasally [i.n.] immunized C3H and ICR mice only) PFU of Adhu5rab.gp or AdC68rab.gp virus or no virus (x). Mice were bled 2 weeks later, and sera were tested for antibodies to rabies virus by an ELISA. Data are means of duplicate values.

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TABLE 1. Induction of VNAs and protective immunity to rabies virus challenge

When administered subcutaneously, the AdC68rab.gp virus induceda less potent antibody response to the transgene product thandid the Adhu5rab.gp construct. The difference in magnitude ofthe antibody response, which was observed at all time pointstested, depended on the mouse strain and was less pronouncedin outbred ICR than in inbred C3H/He mice. In contrast, whenadministered intranasally, the vaccines induced comparable titersof antibodies as determined by ELISAs (Fig. 2) and by virusneutralization assays (Table 1).

After subcutaneous immunization, antibodies induced by the Adhu5rab.gpand AdC68rab.gp vaccines differed in their isotype profile.This difference was not observed upon intranasal immunization(Fig. 3). Both recombinants, delivered by either route of inoculation,elicited IgG2a antibodies to the antigen of rabies virus, suggestinginduction of a Th1-type immune response. Both recombinants uponintranasal immunization and Adhu5rab.gp upon subcutaneous administrationalso induced a pronounced IgG1 response indicative of Th2 help,which was lacking in the response to the AdC68rab.gp constructgiven subcutaneously.

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FIG. 3. Sera from C3H/He mice immunized with 5 x 10⁷ (), 5 x 10⁶ ( ${blacksquare}$ ), 5 x 10⁵ (), 5 x 10⁴ (), or 5 x 10³ () PFU of Adhu5rab.gp or AdC68rab.gp were tested for isotypes of antibodies to the rabies virus antigen. Normal mouse serum ( ${square}$ ) was tested for comparison. Data were obtained with a 1:400 dilution of the sera and are means of duplicate values plus standard deviations.

The pronounced Th1-linked antibody response to the transgeneproduct of AdC68rab.gp given subcutaneously may relate to the"adjuvant effect" of this particular serotype of adenovirus.Splenocytes from naive C3H/He mice cultured in vitro with anE1-deletion-containing AdC68 construct rapidly secreted interferon(IFN) which could not be neutralized by an antibody to gammainterferon (IFN- ${gamma}$ ) and thus represented IFN- ${alpha}$ /ß (Table2). This was not observed upon culture of splenocytes with acorresponding Adhu5 construct.

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TABLE 2. Adjuvant effect of the adenoviral recombinants^a

Induction of protection against challenge with a virulent strain of rabies virus. Both adenoviral recombinants induced protection against infectionof mice challenge with rabies virus (Table 1). C3H/He mice immunizedsubcutaneously with 5 x 10⁶ PFU of either of the adenoviralrecombinants remained disease-free when challenged 3 weeks laterwith 10 LD₅₀ of rabies virus of the CVS strain. This strainis antigenically closely related to the ERA strain but is morevirulent in rodents. At 5 x 10⁵ PFU, Adhu5rab.gp still providedcomplete protection while a small percentage of AdC68rab.gp-immunizedmice succumbed to infection. Further reduction of the vaccinedose resulted in loss of efficacy of the AdC68rab.gp vaccine:at 5 x 10⁴ PFU 20% of subcutaneously immunized C3H/He and 80%of subcutaneously vaccinated ICR mice succumbed to the challengewith rabies virus. With nasal immunization, both vaccines providedcomplete protection if given at 5 x 10⁵ PFU. At 5 x 10⁴ PFU,50% of mice vaccinated with Adhu5rab.gp developed progressivedisease while those immunized with this dose of AdC68rab.gpwere protected. All of the mice immunized with control adenoviralrecombinants of either serotype or with only 5 x 10³ PFU ofeither of the adenoviral recombinants to the rabies virus glycoproteindeveloped fatal rabies encephalitis.

Effect of preexisting immunity to different serotypes of human adenoviruses on the antibody response to rabies virus glycoprotein. We reported previously that mice preimmune to Adhu5 developa reduced antibody response to vaccination with the Adhu5rab.gprecombinant compared to naïve mice (23). Human adults areimmune not only to Adhu5 but also to other serotypes, including2, 4, 7, and 12 (12). To test if preexposure to any of thesecommon serotypes of human adenoviruses would inhibit the antibodyresponse to the AdC68rab.gp vaccine, groups of C3H/He mice wereimmunized with 4 x 10⁸ PFU of replication-competent adenovirusesof human serotype 2, 4, 5, 7, or 12 or with the chimpanzee serotype68 (the latter contained an E1 deletion). Two weeks later, micewere bled and sera were tested by an ELISA (Fig. 4A) for antibodiesto adenoviral antigens. Sera from mice immunized with the differentserotypes showed extensive cross-reactivity. The highest antibodytiters were achieved in mice inoculated with the homologousconstruct. Sera from mice immunized with Adhu4, whose knownsequences show $~$ 90% homology with those of AdC68, had highertiters to AdC68 than did sera from mice injected with any ofthe other human serotypes. After sera had been harvested, micewere vaccinated subcutaneously with either Adhu5rab.gp or AdC68rab.gp.Adhu5rab.gp was used at a dose of 2 x 10⁵ PFU per mouse; AdC68rab.gp,which induces only a marginal antibody response in C3H/He micewhen given subcutaneously at such a low dose, was injected at2 x 10⁷ PFU per mouse. Sera were harvested 2 weeks later andtested for antibodies to the rabies virus glycoprotein by anELISA (Fig. 4B) or a virus neutralization assay (Table 3). Therabies virus-specific response to Adhu5rab.gp in naïvemice was slightly superior to that elicited by AdC68rab.gp.The response to Adhu5rab.gp was completely inhibited in micepreimmune to Adhu5. Some reduction was also seen for rabiesvirus glycoprotein-specific ELISA titers in mice preimmune tohuman adenovirus serotypes 2, 4, 7, and 12. VNA titers showedonly a twofold reduction in Adhu2-, Adhu7-, and Adhu12-preimmunemice, which was not considered biologically significant. Adhu4-preimmunemice showed a more pronounced reduction in VNA titers to rabiesvirus.

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FIG. 4. Effect of preexisting immunity on the antibody response to the transgene product presented by Adhu5 or AdC68. (A) Cross-reactivity by different serotypes of human adenovirus. Groups of C3H/He mice were immunized subcutaneously with 4 x 10⁸ PFU of Adhu2 ( ${square}$ ), Adhu4 (•), Adhu5 ( ${boxplus}$ ), Adhu7 ( ${oplus}$ ), Adhu12 (), AdC68 (), or nothing ( ${square}$ ). Mice were bled 2 weeks later, and titers of serum antibody to Adhu5 and AdC68 were determined by an ELISA. (B) Inhibition of the transgene specific antibody response by preexposure to common human serotypes of adenovirus. Three weeks after immunization with adenoviruses of different serotypes, the groups of mice used for panel A were injected with 2 x 10⁵ PFU of Adhu5rab.gp or 2 x 10⁷ PFU of AdC68. Sera were harvested 2 weeks later and tested for antibodies to rabies virus by an ELISA using normal mouse serum (x) for comparison. Symbols are as in panel A. The bold solid and dashed lines indicate mice immunized with the homologous serotype used for preexposure and mice that had not been preexposed, respectively.

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TABLE 3. Effect of preexisting immunity to Adhu5 on vaccine efficacy^a

The rabies virus-specific antibody response to the Adhu5rab.gpvaccine was not affected in mice that had been preexposed toAdC68. The response to AdC68rab.gp was strongly inhibited inmice that were preimmune to the homologous virus. Mice thathad previously encountered Adhu2 showed a slight reduction ofthe antibody response to the rabies virus antigen presentedby the AdC68 vaccine, as seen by ELISA and virus neutralizationassays. Mice inoculated with any of the other serotypes of humanadenoviruses developed ELISA titers of antibody to rabies virusupon AdC68rab.gp immunization that were either equal to or higherthan those in mice that were naïve prior to vaccination.In particular, mice preimmune to Adhu5 developed higher antibodytiters upon vaccination with the AdC68rab.gp construct; thismay reflect the presence of cross-reactive T helper cells thatpromoted the B-cell response to the transgene product.

To further determine if at equal vaccine doses the AdC68rab.gpvaccine induced antibody titers superior to those induced byAdhu5rab.gp in mice preimmune to Adhu5, we conducted a vaccinetitration experiment. Groups of C3H/He mice were immunized subcutaneouslywith 4 x 10⁸ PFU of an E1-deletion-containing Adhu5 recombinantencoding the L1 antigen of HPV-16. Mice were vaccinated 2 weekslater with either Adhu5rab.gp or AdC68rab.gp given subcutaneouslyat various doses. Mice were bled 2 weeks later, and titers ofserum antibody to rabies virus were determined by an ELISA (notshown) and a virus neutralization assay (Table 3). Neither assayshowed a significant reduction in the antibody response to theAdC68rab.gp construct in Adhu5-immune mice. The extent of thereduction of titers of antibody to rabies virus presented bythe Adhu5 construct in mice preimmune to the homologous virusdepended on the vaccine dose. The antibody response to lowerdoses of vaccine was more affected than the response to highervaccine doses. At the highest vaccine dose, VNA titers werehalved in Adhu5-preimmune mice; at the two lower vaccine doses,titers were reduced 9- to 27-fold. At all doses tested, AdC68rab.gpinduced higher VNA titers to rabies virus in Adhu5-preimmunemice than did an equal dose of Adhu5rab.gp. The detrimentaleffect of preexisting immunity to Adhu5 on the efficacy of theAdhu5 vaccine was demonstrated further in a protection experiment(Table 3). Naïve mice immunized with 2 x 10⁵ PFU of Adhu5rab.gpor AdC68rab.gp were completely protected against challenge withCVS-11 virus. The majority (60%) of Adhu5-preimmune mice immunizedwith this dose of the Adhu5rab.gp vaccine succumbed to a rabiesvirus infection, while those vaccinated with the same dose ofAdC68rab.gp remained protected. Increasing the dose of Adhu5rab.gpto 2 x 10⁶ PFU per mouse restored the efficacy of the vaccine.

DISCUSSION

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Discussion

E1-deletion-containing Adhu5 recombinants have been used extensivelyas gene therapy vehicles. Although they efficiently transducea variety of mammalian cells, their high immunogenicity, whichresults in potent T- and B-cell-mediated immune responses toboth the adenoviral antigens and the transgene product, hasseverely limited their usefulness for long-term replacementof missing or faulty genes. Replication-competent and replication-defectiveadenoviral recombinants based on common human serotypes havebeen tested in experimental animals as vaccine carriers fora variety of antigens derived from viruses, parasites, or tumorcells. In each case, E1-deletion-containing adenoviral recombinantselicited potent cell-mediated and humoral immune responses tothe transgene product that even at low doses of vaccine providedprotection to challenge with the pathogen or the tumor cells(6, 9, 15, 22). Adhu5 is a ubiquitous common-cold virus thatinfects most humans within their first year of life. Recurrentasymptomatic reinfections result in persistent titers of antibodiesto Adhu5, and approximately one-third of human adults have highlevels of circulating neutralizing antibodies to adenovirus(7). Such antibodies have been shown in experimental animalsto reduce the efficacy of adenoviral recombinant vaccines basedon the homologous viral serotype (23; Shiver, AIDS Vaccines2001). The underlying mechanism presumably involves antibody-mediatedneutralization of the vaccine, which reduces the number of recombinantvirus particles able to infect cells and to synthesize the transgeneproduct. Additional pathways, such as lysis of adenovirus-transducedantigen-presenting cells by effector-memory CD8⁺ T cells, mayalso dampen the induction of transgene-specific immune responses;this remains to be tested.

Alternative adenoviral recombinants based on nonhuman serotypeswere developed for gene therapy to circumvent interference bycirculating neutralizing antibodies in human patients (10, 14).We developed such a recombinant as a vehicle for vaccination.The recombinant is based on an adenovirus that was initiallyisolated from mesenteric lymph nodes of a chimpanzee. Like Adhu5,AdC68 enters cells upon binding of fiber to the CAR (5). Alternativebut less efficient pathways circumventing the CAR may involveinteractions such as those between the viral penton and cellintegrins (20). It remains to be investigated if AdC68 usesthe same alternative mechanisms of transduction as Adhu5 andto what degree potential differences affect the tropism andthe vaccine efficacy of either viral recombinant.

Mice immunized subcutaneously with the AdC68rab.gp vaccine developedmarkedly lower antibody titers than did those vaccinated withthe Adhu5rab.gp construct, a difference that was not observedupon mucosal immunization. This is most likely linked to differencesin the interactions of the two viral constructs with the innateimmune system; the AdC68 construct triggered rapid release ofIFN- ${alpha}$ /ß in splenocyte cultures. A similar inductionof this cytokine in vivo would bias the immune response towardsthe Th1 pathway, as is indeed suggested by the strongly biasedIgG2a response upon subcutaneous immunization with the AdC68rab.gpvaccine. The strongly biased Th1 response to the AdC68rab.gpvaccine that was not observed upon immunization with the Adhu5rab.gpvaccine may have favored induction of cell-mediated rather thanhumoral immune responses and may thus have contributed to theless potent B-cell response to our novel vaccine carrier givensystemically. This was suggested in another system in whichthe Gag antigen of human immunodeficiency virus type 1 (HIV-1)was delivered by E1-deletion-containing Adhu5 and AdC68 recombinants.In that system, the AdC68 vaccine given systemically inducedmarkedly higher CD8⁺-T-cell responses to Gag than the correspondingAdhu5 vaccine (Fitzgerald et al., submitted).

Upon mucosal vaccination, both adenoviral vaccines induced amore balanced Th1/Th2 response, as determined by IgG2a/IgG1ratios, and accordingly induced antibody responses to the transgeneproduct that were comparable in magnitude.

Most importantly, the antibody response to the transgene productexpressed by the AdC68 recombinant was not affected by preexistingimmunity to common human adenovirus serotypes. In contrast,after preimmunization with replication-competent viruses, theimmune response to the Adhu5rab.gp vaccine was abolished inAdhu5-preimmune mice and reduced in mice preimmune to otherhuman adenoviruses, such as serotypes 2 and 4. The responseto the AdC68 recombinant was, as expected, inhibited in micepreimmune to the homologous virus. This is not of clinical concern,as AdC68 does not circulate in the human population (7) andcommon human serotypes do not share neutralizing epitopes withAdC68.

Preexposure to replication-defective Adhu5 also reduced theantibody response to the rabies virus glycoprotein encoded byAdhu5 recombinants, although the impact was not as severe asin mice previously infected with E1-containing virus. Such virusreplicates in its natural host but fails to replicate in mice.Nevertheless, even in mice, replication-competent adenovirusis expected to synthesize a higher antigenic load of structuralviral proteins than E1-deletion-containing adenoviral recombinants.Sera from mice preimmune to replication-defective Adhu5 developedreduced but readily detectable antibodies to rabies virus uponimmunization with the Adhu5rab.gp vaccine. Increasing the doseof the Adhu5rab.gp construct could in part circumvent the impactof preexisting immunity. Vaccine-induced protection againstrabies virus requires VNAs, which were not induced as efficientlyin preimmune mice by the Adhu5 vaccine, especially when it wasused at lower doses. In Adhu5-preimmune mice, the VNA responseto AdC68rab.gp was superior to that to the Adhu5 vaccine atall doses, more than compensating for the slightly lower potencyof this vaccine upon subcutaneous immunization.

AdC68 recombinants thus provide an attractive alternative asa vaccine carrier for use in humans. As shown here, they areefficacious even when applied at low doses of 2 x 10⁵ PFU throughnoninvasive routes of administration, such as the upper airways.Mucosal immunization by intranasal application has the addedadvantage of favoring induction of responses of the common mucosalimmune system (13, 16, 23), which is distinct from, albeit interconnectedwith, the central immune system targeted by injected vaccines.Most pathogens, including influenza A and B viruses, hepatitisviruses, rotaviruses, human immunodeficiency virus, and cancer-associatedtypes of human papillomaviruses, invade their hosts throughmucosal surfaces of the airways, the intestine, or the genitaltract. They might thus best be combated by vaccines that uponapplication to mucosal membranes induce robust mucosal immuneresponses, including IgA antibodies, which are poorly inducedupon systemic immunization (23). As shown here, preexistingimmunity to common serotypes of human adenoviruses found inthe majority of the human population impairs the efficacy ofrecombinants based on such human serotypes. This can in partbe overcome by increasing the dose of the vaccine or more elegantlyand cost-efficiently by using an adenoviral recombinant basedon a mammalian serotype that does not circulate in the humanpopulation, such as AdC68. E1-deletion-containing AdC68 recombinantshave another advantage over currently used replication-defectiveAdhu5 vaccines. The Adhu5 vaccines are propagated in cell linesthat transcomplement the E1 protein derived from the same virusserotype. Homologous recombination between the cell-derivedE1 gene and the E1-deletion-containing Adhu5 genome is inevitableand contaminates the vaccine preparations with replication-competentvirus. These pose an added risk to patients, especially thosewho are immunocompromised, such as the very young and the elderly.In the replication-defective AdC68 constructs, the E1 of humanserotype 5 transcomplements the E1-deletion-containing adenoviralgenome. The flanking sequences of the human serotype 5 E1 arenonhomologous with those of the AdC68 serotype, thus disallowinghomologous recombination. Vaccine preparations are thereforeless likely to carry replication-competent virus.

ACKNOWLEDGMENTS

The technical support of the Vector and Immunology Cores ofthe Institute for Human Gene Therapy is greatly appreciated.

This work was supported by NIH (NIDDK P30, NHLBI P01, NIAIDR01), CF Foundation, and Genovo. J. M. Wilson owns equity inTargeted Genetics (formerly Genovo).

FOOTNOTES

* Corresponding author. Mailing address: The Wistar Institute, 3601 Spruce St., Philadelphia, PA 19104. Phone: (215) 898-3863. Fax: (215) 898-3953. E-mail: ertl{at}wistar.upenn.edu.

REFERENCES

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