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Intradermal Delivery of Adenoviral Type-35 Vectors Leads to High Efficiency Transduction of Mature, CD8⁺ T Cell-Stimulating Skin-Emigrated Dendritic Cells

Tanja D. de Gruijl^1,2,*, Olga J. A. E. Ophorst^1,, Jaap Goudsmit, Sandra Verhaagh, Sinéad M. Lougheed^*, Katarina Radosevic, Menzo J. E. Havenga and Rik J. Scheper

^* Department of Medical Oncology, Vrije Universiteit University Medical Center, Amsterdam, The Netherlands; Department of Pathology, Vrije Universiteit University Medical Center, Amsterdam, The Netherlands; and Crucell Holland BV, Leiden, The Netherlands

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
Recombinant adenovirus (Ad) type 35 (rAd35) shows great promise as vaccine carrier with the advantage of low pre-existing immunity in human populations, in contrast to the more commonly used rAd5 vector. The rAd35 vector uses CD46 as a high-affinity receptor, which, unlike the rAd5 receptor, is expressed on human dendritic cells (DC), the most powerful APCs identified to date. In this study, we show that in contrast to rAd5, rAd35 infects migrated and mature CD83⁺ cutaneous DC with high efficiency (up to 80%), when delivered intradermally in an established human skin explant model. The high transduction efficiency is in line with high expression levels of CD46 detected on migratory cutaneous DC, which proved to be further increased upon intradermal administration of GM-CSF and IL-4. As compared with Ad5, these Ad35 infection characteristics translate into higher absolute numbers of skin-emigrated DC per explant that both express the transgene and are phenotypically mature. Finally, we demonstrate that upon intracutaneous delivery of a rAd35 vaccine encoding the circumsporozoite (CS) protein of Plasmodium falciparum, emigrated DC functionally express and process CS-derived epitopes and are capable of activating specific CD8⁺ effector T cells, as evidenced by activation of an HLA-A2-restricted CS-specific CD8⁺ T cell clone. Collectively, these data demonstrate the utility of rAd35 vectors for efficient in vivo human DC transduction.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
Dendritic cells (DC)³ are powerful APCs with the unique ability to prime naive T cells and thus initiate immune responses. They provide the link between the innate and the adaptive immune response, and as such regulate adaptive immunity at its most fundamental level (1). By way of vaccination, DC may be genetically modified to express any Ag of choice (2). By virtue of the intracellular expression of the Ag of interest, genetic vaccination ensures its processing via endogenous pathways for subsequent MHC class I-mediated presentation to CD8⁺ CTL, which are essential for an effective cell-mediated response to both viruses and tumors (3, 4, 5). The efficacy of in vivo genetic immunization has been shown to depend on DC-mediated immune activation (6, 7, 8). Massive uptake of the injected vectors by tissue-resident cells other than DC might interfere with DC transduction efficiency and subsequent effector T cell activation. It is therefore desirable to use vectors with the ability to transduce DC with high efficiency in the context of a tissue environment.

Recombinant adenovirus (Ad) type 35 (rAd35) is an attractive genetic vaccine carrier with the advantage of low pre-existing immunity in human populations, in contrast to the more commonly used rAd5 vector (9). In vitro-generated human monocyte-derived DC (MoDC) express the primary docking receptor for Ad35 (CD46), but not the receptor for Ad5. As a result, MoDC are more efficiently transduced by Ad35-based vectors than by rAd5, without interfering with the DC’s activation potential (10). Indeed, MoDC infected with Ad5F35 chimeric vectors have been used successfully to generate antitumor CD8⁺ T cell responses in vitro (11).

Unfortunately, studies in nonhuman primates could not demonstrate enhanced immunogenicity of Ad5F35 over Ad5 vectors in vivo, despite an improved in vitro transducibility of DC (12). Neither could the in vivo application of Ad5F35 circumvent pre-existent immunity to Ad5 in a mouse model (12). The latter observation can be remedied by the use of Ad35 rather than Ad5F35, thus abolishing all structural Ad5 capsid components to which immunity might exist (13, 14), while the first observation might be explained by the i.m. route of administration used, which is marked by a paucity of tissue-resident DC; the skin might be a more favorable vaccination site in this respect. Interpretation of in vivo human CD46-transgenic murine and nonhuman primate data is further complicated by the presence of CD46 on erythrocytes, which, unlike in humans, might seriously affect biodistribution of the rAd35 vector (15, 16). In conclusion, dissimilarities in the high-affinity CD46 receptor expression and anatomical barriers, which could result in differences in biodistribution characteristics, may render available preclinical in vivo models for rAd35 unrepresentative for the human situation. The exploration of alternative preclinical human models to test the dynamics of in vivo rAd35 infection is therefore warranted.

In view of these considerations, we have opted to introduce both Ad5F35 and Ad35 vectors in a near-physiological human skin explant model to explore their in vivo DC-targeting potential. Organotypic skin explant cultures allow for the study of human cutaneous DC and their functions in their natural complex tissue environment, closely maintaining the in vivo situation (17). We previously used this skin explant model successfully to assess the in situ DC infectivity potential of CD40-targeted rAd viruses and reported a high efficiency DC transduction and accompanying maturation induction (18). Our current data show that intracutaneous administration of rAd35 facilitates high efficiency transduction of mature skin-emigrated DC with an ability to specifically activate CTL, thus confirming the utility of Ad35 as an in vivo vaccine delivery vehicle.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
Viruses

E1/E3-deleted, replication-incompetent rAd5, rAd5F35, or rAd35 vectors were generated in PER.C6 or PER.C6/55K cells using pBR322-based adaptor plasmids pAdApt or pAdApt535 together with cosmids pWE.Ad.AflII-rITR.dE3, pWE.Ad35.pIX-rITR.dE3, or pWE.Ad.AflII-rITR/Fib35, respectively, as previously described (19, 20). GFP or the circumsporozoite (CS) protein of Plasmodium falciparum (Pf CS) was cloned into the adaptor plasmids under control of an immediate/early CMV promoter and an SV40 polyadenylation signal. These plasmids were linearized and transfected into PER.C6 or PER.C6/55K cells together with the linearized cosmids using lipofectamine (Invitrogen Life Technologies). Homologous recombination led to the generation of rAd5, rAd5Fib35, or rAd35 vectors containing the enhanced GFP or CS transgene. Generated vectors were analyzed for transgene expression, amplified in 24–48 triple-layer T175-cm² flasks, purified by double CsCl gradient ultracentrifugation, and dialyzed into PBS containing 5% sucrose. Purified rAd vectors were stored at –80°C. Virus particle (vp) titers were determined by HPLC, whereas IU were assessed by PFU. Equal amounts of vp/IU ratios (<30) were found with assays meeting criteria defined by Food and Drug Administration guidelines. All viruses were injected into skin explants in the same volume of 10 µl.

Ad infection of skin explants and DC migration

A detailed description of Ad infection and DC culture in the skin explant system has been published previously (18). Human skin specimens were obtained after informed consent from patients undergoing corrective breast or abdominal plastic surgery, following hosptital guidelines. Skin biopsies (6 mm) were intradermally (i.d.) injected with plain IMDM (Invitrogen Life Technologies) or with a mixture of 100 ng of GM-CSF (Schering-Plough) and 1000 IU of IL-4 (Centraal Laboratorium van de Bloedtransfusiedienst), cultured on rafts according to previously described methods (18, 21), and subsequently i.d. injected with 10⁹ vp per biopsy, or with plain medium as a negative control. Ad vectors were injected into the dermis in a total volume of 10 µl. Following injection, the explants (12–20 samples/condition) were cultured, floating freely on medium containing 5% HPS (Centraal Laboratorium van de Bloedtransfusiedienst), with their epidermal side up, before their removal 2 days later. The explants were discarded, and the medium, containing migrated cells, was harvested and pooled per test condition. Samples of the skin explant-conditioned medium were stored at –20°C for cytokine analysis. Cytokine content of the explant-conditioned medium was analyzed using the cytokine bead array (BD Biosciences) for the simultaneous flow cytometric detection of IL-10, IL-12p70, IL-6, IL-8, TNF-, and IL-1, according to the manufacturer’s instructions and using cytokine bead array analysis software (BD Biosciences). Absolute numbers of migrated DC were counted in hemocytometers using trypan blue exclusion, after which they were used for flow cytometric or functional analyses.

Dissociation of full-thickness skin explants

Fresh 6-mm biopsies (10 per condition) were immediately processed and placed in 10-cm-diameter culture dishes containing 15 ml of 0.05% trypsin (Invitrogen Life Technologies) for 4–5 h at 37°C, 5% CO₂. The epidermis and dermis were separated with tweezers and washed with IMDM 10% FCS, and single-cell suspensions were made of each by pushing through 100-µm-pore nylon cell strainers (Falcon; BD Biosciences) with the plunger of a 2-ml syringe. The cell suspensions were resuspended in 5 ml of IMDM and counted before flow cytometric analysis.

Flow cytometric analysis of DC

Cells were incubated on ice for 30 min in PBS with 0.1% BSA and 0.01% NaN₃, in the presence of appropriate dilutions of FITC- or PE-labeled mouse mAbs to CD83 (Beckman-Coulter), CD1a, CD86 (BD Pharmingen), CD46, or CD80 (BD Biosciences). A second incubation step was performed for the unconjugated mAb against coxsackievirus and Ad receptor (CAR) (RmcB (22)) with FITC-labeled goat anti-mouse Abs (Centraal Laboratorium van de Bloedtransfusiedienst). The cells were subsequently analyzed, using a FACSCalibur and CellQuest FACS analysis software (BD Biosciences).

CD8⁺ T cell activation and IFN- ELISPOT assay

The used HLA-A2-restricted CD8⁺ CTL clone, specifically recognizing the aa 327–335 epitope of Pf CS, has been described previously (20), and was provided by G. Corradin (University of Lausanne, Lausanne, Switzerland) and J. Lopez (Queensland Institute of Medical Research, Brisbane, Australia). For the readout of T cell activation, 96-well nitrocellulose plates (Multiscreen-HA; Millipore) were precoated with the anti-human IFN- mAb 1-D1K (15 µg/ml in filtered PBS; Mabtech). After overnight incubation at 4°C, the plates were washed and blocked for 1 h at 37°C with culture medium supplemented with 10% FBS. In situ transduced HLA-A2⁺ skin-emigrated DC were cocultured in the presence of the Pf CS 327–335-specific CTL clone (tested ratios 1:2 and 1:1) for 16 h at 37°C/10% CO₂. Plates were washed with PBS/0.05% Tween 20, followed by a 2- to 4-h incubation at room temperature with the biotinylated anti-human IFN- mAb 7-B6-1 (1 µg/ml in filtered PBS; Mabtech). After washing with PBS/0.05% Tween 20, plates were incubated for 1 h at room temperature with 1/2000 diluted extravidin-alkaline phosphatase conjugate (Sigma-Aldrich). Spots were developed with 5-bromo-4-chloro-3-indolyl phosphate/NBT substrate (Sigma-Aldrich) and quantitated with the aid of an Automated ELISA-Spot Assay Video Analysis System (A.EL.VIS).

Statistical analysis

Transduction efficiencies, transgene expression levels, absolute numbers of (transduced) DC, and cytokine release levels were compared after infection with Ad5 or Ad35-based vectors, using paired Student’s t test (two-sided); differences were considered significant when p < 0.05.

	Results

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
CD46 expression on cutaneous DC

A first prerequisite for successful infection of DC by Ad vectors is the expression of the relevant Ad receptor on the DC surface. CD46 has been identified as a primary docking receptor for Ad35. We therefore determined the expression of CD46 on CD1a⁺ cutaneous DC by flow cytometric analysis, both premigration (intracutaneous DC at day 0) and postmigration (skin-emigrated DC at day 2); see Fig. 1A. In single-cell suspensions derived from uncultured skin explants (Fig. 1A, day 0), CD1a⁺ DC were found to be immature (evidenced by a lack of CD83 expression) and to display barely detectable membrane expression of the Ad35 receptor CD46. In contrast, CD1a⁺ DC that had emigrated over the course of a 2-day culture period from i.d. GM-CSF- and IL-4-injected skin explants displayed a mature CD83⁺ phenotype and high membrane expression levels of CD46 (Fig. 1A, day 2). Skin-emigrated DC were gated by their characteristic side scatter and forward scatter properties, respectively, as described (see Fig. 1A). We previously reported the maturing effect of premigration i.d. injection of GM-CSF and/or IL-4 on cutaneous DC postmigration, resulting in higher levels of the classic DC maturation marker CD83 and costimulatory molecules such as CD80 and CD86 (18). Although DC migrated from explants i.d. injected with control medium already expressed CD46 (in contrast to skin DC in skin explants before culture; Fig. 1A), CD46 was further up-regulated through GM-CSF- and IL-4-induced maturation of skin-emigrated DC (see Fig. 1B). Thus, the level of membrane expression of CD46 correlated to the DC maturation state. In contrast, the Ad5 receptor CAR was not expressed on skin-emigrated DC, independent of their maturation state (Fig. 1B).

View larger version (26K): [in this window] [in a new window]   FIGURE 1. The expression of Ad docking receptors on pre- and postmigration skin DC in relation to their activation state. A, Skin explants were i.d. injected with GM-CSF and IL-4 on day 0 and cultured for 2 days, after which skin-emigrated DC were harvested. For flow cytometric analysis, skin-emigrated DC were gated by their typically high side (SSC) and forward (FSC) light scatter characteristics. Expression of the Ad35 receptor CD46 and the DC maturation marker CD83 is shown in relation to the skin DC marker CD1a in single cell suspensions of uncultured skin explants (day 0) and on skin-emigrated DC (day 2). Percentages are indicated in the corresponding quadrants. B, Expression levels (in mean fluorescence (MF) indices) of the Ad5 receptor CAR and the Ad35 receptor CD46 on skin-emigrated DC (pregated on the basis of CD1a expression), 2 days after previous i.d. injection of medium or the DC-activating cytokines GM-CSF and IL-4. Markers denote the fluorescence levels of the corresponding isotype controls, used to calculate the indicated MF indices. Results are representative of three experiments.

When either Ad5, Ad35, or Ad5F35 (i.e., an Ad5 vector equipped with an Ad35-derived fiber) vectors encoding the GFP reporter gene were i.d. injected into skin explants (at 10⁹ vp per explant) at day 0 of culture and emigrated DC were harvested 2 days later (at which time migration was complete) and tested for GFP expression by FACS, low transduction efficiencies (<20%) were observed without any significant differences between the vectors used (data not shown). This may be explained by absent or low expression of CAR and CD46 on resting CD1a⁺ DC in fresh skin explants (Fig. 1A). In combination with the relatively high expression of both receptors on other skin-resident cells such as fibroblasts and keratinocytes (shown for CD46 on the CD1a-negative population in Fig. 1A), this could hamper efficient DC transduction. Coinjection of GM-CSF and IL-4 at day 0, to increase DC maturation and concomitant CD46 expression, could not overcome this. In contrast, when explants were either injected with medium or GM-CSF and IL-4 and then cultured on nitrocellulose filter rafts at the medium/air interface (as described previously (18)) for 24 h before injection of the Ad vectors (at day 1), higher transduction efficiencies of explant-emigrated DC were observed 2 days later (Fig. 2A). Importantly, the latter regimen resulted in significantly higher DC transduction efficiencies by Ad35 and Ad5F35 as compared with Ad5 (a 2- to 3-fold increase) with particularly high transduction efficiencies of mature CD83⁺ DC (70%; see Fig. 2B). These data indicate that the expression of CD46 on migrating mature DC at the time of Ad35 or Ad5F35 encounter is essential for high efficiency transduction to occur in the context of the skin microenvironment. Ad injections 24 h subsequent to the start of explant culture were therefore used throughout the remainder of this study. GFP transgene expression levels detected by the use of this methodology were also significantly higher after Ad35-mediated transduction as compared with Ad5-mediated transduction (see Fig. 2B). These results demonstrate that transduction with Ad35 is equivalent to Ad5F35 (Fig. 2), which, in light of the low seroprevalence of Ad35 (9), makes Ad35 the preferred vector for in vivo use. Consequently, all subsequent experiments were performed with Ad35 only.

View larger version (32K): [in this window] [in a new window]   FIGURE 2. Increased transduction efficiency and GFP transgene expression levels in skin-emigrated DC upon i.d. rAd35-GFP or rAd5F35-GFP delivery as compared with rAd5-GFP. Skin explants were i.d. injected at day 0 with either medium or GM-CSF and IL-4. Ad5, Ad35, or Ad5F35 (109 vp per explant) was i.d. injected 24 h later, after preincubation of the explants on rafts (day 1 Ad injection). Skin-emigrated DC were harvested 2 days after Ad injections in all test conditions and tested for GFP and CD83 expression levels by flow cytometric analysis. Transduction efficiencies (A) and GFP expression levels (in mean fluorescence intensity; MFI) (B), among the total population of skin-emigrated DC () or the CD83+ mature DC () are shown. All results are shown as mean ± SD of 4–10 separate experiments. Asterisks denote significant differences between the Ad35-based vectors and Ad5 in Student’s t test (p < 0.05).

View larger version (40K): [in this window] [in a new window]   FIGURE 3. Increased transduction efficiency of i.d. DC and skin-emigrated DC, respectively, 24 and 48 h after i.d. Ad35-GFP delivery as compared with Ad5-GFP. Skin explants were i.d. injected at day 0 with GM-CSF and IL-4 and with medium, Ad5, or Ad35 (109 vp per explant) 24 h later, after preincubation of the explants on rafts. A, GFP expression in relation to CD1a in single-cell suspensions generated from the dermal fraction of skin explants 24 h after injection of the Ad vectors or medium control. Percentages of the total number of dermal cells are shown in the corresponding quadrants. B, Mean transduction efficiencies (±SD) of CD1a– dermal stromal cells (left panel) or i.d. CD1a+ DC (right panel), 24 h after i.d. Ad5-GFP or Ad35-GFP delivery, based on three separate experiments. C, Typical GFP expression in relation to CD83 in skin explant-emigrated DC, 48 h after i.d. injection of the Ad vectors.

Transduction efficiencies among DC, migrated over the course of 2 days from Ad-injected skin explants, remained constant for at least another 5 days up to day 7 after the i.d. administration of the Ad vectors (with maintained higher efficiencies for Ad35 as compared with Ad5; see Fig. 4A). This held true both for medium-preinjected explants and for explants injected with the DC-stimulatory cytokines GM-CSF and IL-4, 24 h before Ad injection. Although this continued transgene expression might be expected to result in long-term in vivo stimulation of specific T cells, the phenotypic development of the skin-emigrated DC differed notably between these two conditions with possible functional consequences. Whereas at day 2 a majority of the migrated DC were in a mature state irrespective of medium or cytokine injection (determined by CD83 expression; see Fig. 3C), most DC migrated from medium-conditioned explants had lost CD83 expression by day 7 and also displayed lower levels of the costimulatory molecules CD80 and CD86 (see Fig. 4B). This is in keeping with our previous observations in this model (18). Administration of Ad5 or Ad35 caused only slight and nonsignificant increases in the expression of these DC activation markers at day 7 (Fig. 4B). In contrast, a majority of DC from GM-CSF- and IL-4-conditioned explants showed stable maturation, evidenced by a conserved expression of CD83, CD80, and CD86 at day 7, irrespective of Ad5 or Ad35 infection. In all conditions, the DC activation markers were uniformly expressed, irrespective of GFP expression. In conclusion, conditioning of Ad vaccination sites with the DC-stimulating cytokines GM-CSF and IL-4 may ensure a stable mature T cell-stimulatory phenotype to accompany long-term transgene expression in Ad35-transduced DC after their migration from the skin. Ad35 infection does not interfere with this intracutaneous cytokine-induced prolongation of DC maturation.

View larger version (45K): [in this window] [in a new window]   FIGURE 4. Continued transgene expression and phenotypic development of cutaneous DC after in situ Ad transduction and migration from skin explants. Skin explants were i.d. injected at day –1 with either medium or GM-CSF and IL-4. Medium controls, Ad5, or Ad35 (109 vp per explant) were i.d. injected 24 h later, after preincubation of the explants on rafts. Skin-emigrated DC were harvested 2 or 7 days after Ad injections for all test conditions (skin explants were removed from all cultures at day 2) and tested for GFP and DC marker expression levels by flow cytometric analysis. A, Transduction efficiencies based on GFP expression in skin-emigrated DC at days 2 and 7 after i.d. delivery of medium (•), Ad5-GFP (), or Ad35-GFP (); mean results (±SD) are shown for DC derived from medium-preinjected (left panel) or GM-CSF/IL-4-preinjected skin explants (right panel); n = 3. B, Expression of CD1a, CD83, CD80, and CD86 on skin-emigrated DC, 7 days after i.d. delivery of medium (no Ad), Ad5, or Ad35 (mean fluorescence intensities (MFI) and percentage positives in relation to isotype controls are listed). Representative results are shown for three separate experiments.

In order for Ad-transduced DC to generate effective T cell-mediated immunity against viruses or tumors, it is important that sufficient numbers of mature transgene-expressing DC leave the vaccination site and migrate to draining lymph nodes to activate specific CTL. As shown in Fig. 5A for GM-CSF- and IL-4-conditioned skin explants, DC migrated in smaller absolute numbers subsequent to i.d. administration of Ad35 vectors as compared with Ad5 or medium controls. However, due to the high Ad35-mediated transduction efficienciy of CD83⁺ mature DC, the total number of DC with a mature CD83⁺ T cell-stimulatory phenotype that also expressed the GFP transgene was significantly higher after Ad35 administration as compared with Ad5 administration (p < 0.01; Fig. 5A). This mature CD83⁺ phenotype of skin-emigrated DC was further typified by the expression of CCR7, indicative of the ability of these DC to home to the paracortical T cell areas in the draining lymph nodes (21).

View larger version (20K): [in this window] [in a new window]   FIGURE 5. Migration and CD8+ T cell activation capacity of skin explant-derived DC and cytokine release upon Ad5- or Ad35-mediated transduction. Skin explants were i.d. preinjected with GM-CSF and IL-4 and 24 h later (upon culture at the air-medium interface on rafts) with medium, Ad5, or Ad35 (109 vp per explant), encoding either GFP (A and B) or the Pf CS (C). Migrated DC were harvested 48 h after injection of the Ad vectors or the medium control, counted, analyzed by FACS for CD83 and GFP expression, and used as stimulator cells in a CS-specific CD8+ T cell activation assay. A, Migration of DC in the indicated test conditions, expressed as absolute number of migrated DC per explant. Results are shown (mean ± SD) for the total DC population () and the CD83+GFP+ mature and transduced DC (); n = 4. The asterisk denotes a significant difference between migration numbers of Ad35-transduced and Ad5-transduced CD83+GFP+ DC in a two-sided t test (p < 0.01). B, Explant-conditioned medium was harvested from the explant cultures 24 h after Ad5-GFP or Ad35-GFP injection and tested for levels of IL-10 and IL-12p70. The bar graph shows means ± SD from six separate experiments. IL-12:IL-10 ratios were calculated by division of the mean IL-12p70 and IL-10 concentrations. C, CD8+ T cells from a clone recognizing an HLA-A2-restricted CS epitope were cocultured with DC migrated from explants injected with the indicated Ad5 or Ad35 vectors encoding either GFP or CS. T cell activation was subsequently tested in an IFN- ELISPOT assay. Results are shown as means ± SD of triplicate tests for two separate HLA-A2-matched skin donors at two T cell:DC ratios.

Using a CTL clone that specifically recognized an HLA-A2-restricted epitope derived from Pf CS aa 327–335 (20), we determined the ability of skin-emigrated DC from HLA-A2⁺ skin explants, i.d. injected with either Pf CS-expressing Ad5 or Ad35 vectors, to present the relevant epitope and activate CD8⁺ T cells (readout by IFN- ELISPOT assay). As shown in Fig. 5C for two separate HLA-A2⁺ skin donors, equivalent or slightly higher numbers of Pf CS-specific CD8⁺ T cells were activated in response to relatively low numbers of DC emigrated from explants injected with Pf CS-encoding Ad35 as compared with an equivalent number of DC migrated from Ad5-injected explants. Importantly, these data demonstrate the ability of skin-emigrated DC, transduced in situ by Ad35, to properly process and present epitopes from the transgene product for subsequent T cell activation.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
Their central role in the generation of both cellular and humoral immunity has made DC the major target of most novel vaccination strategies (5). DC-based genetic vaccination may allow for high-level intracellular expression of the Ag target gene of interest over long periods of time, thus optimizing the chances of in vivo effector CTL activation by the transduced DC (3). Particularly attractive in this regard would be the use of vectors with the ability to target and transduce DC with high efficiency in vivo. Such vectors would obviate the need for the costly and laborious ex vivo generation and Ag loading of autologous DC. Their ability to infect DC at high efficiency through binding to CD46 on the DC surface make subgroup B Ad vectors, including rAd35, interesting candidate vehicles for in vivo DC-targeted vaccination (10). The more commonly used rAd5 vectors, belonging to the subgroup C, are relatively poor human DC transducers due to the absence of their primary docking receptor CAR on the DC surface (10, 23). In contrast, chimeric rAd5F35 vectors, consisting of the Ad5 capsid and the Ad35 fiber shaft and knob, were shown to transduce MoDC with high efficiency (10).

Three previously reported observations have suggested a particular suitability of the rAd35-based vectors for the in vivo transduction of DC for vaccination purposes: 1) Extensive serological screening has demonstrated the absence of pre-existent immunity to several members of the Ad subgroup B family (including Ad35) in the general human population (9). This is in stark contrast to Ad5 and may allow repeated in vivo use of Ad35-based vaccines before limiting immunity arises, which might interfere with infection efficiency and longevity of the transduced DC (13). 2) rAd5F35 vectors transduce DC in vitro with conserved high efficiency in the presence of primary skin-derived fibroblasts (10). 3) rAd5F35-transduced DC are more potent in vitro CTL activators than rAd5-transduced DC, as shown for melanoma-associated transgene products by the activation of a gp100-specific CTL clone and the induction of CTL-recognized Ag on melanoma-specific and tumor-reactive CD8⁺ T cells (11).

In aggregate, the above listed data clearly indicate the possible utility of Ad35-based vectors for in vivo DC-targeted vaccination approaches. However, despite an improved DC tropism in vitro, in nonhuman primates rAd5F35 vectors were recently shown to be less immunogenic in vivo than rAd5 vectors (12). This may be explained by the used route of administration in that particular instance, because i.m. genetic vaccination is characterized by the preferential transduction of stromal cells rather than DC, which are in short supply in muscle tissues (24). In this respect, i.d. injection might be more effective, as is indeed borne out by our present findings. A relatively dense network of DC lines the skin (17) and, as shown in the current study, i.d. injection of rAd35, preceded by DC maturation induction (and concomitant CD46 up-regulation), results in high efficiency in situ infection of these cutaneous DC. Importantly, in comparison with rAd5, a higher rAd35-mediated transduction efficiency was observed among phenotypically mature DC that subsequently migrated from the skin explants. Although we did not formally demonstrate whether these DC were originally derived from epidermal Langerhans cells (LC) or from dermal DC, expression of CD1a by most of the DC and Langerin by a subpopulation with high CD1a expresson levels (data not shown) suggests most of them to be of LC origins (17, 25). This is of particular interest in view of a recent study by Rozis et al. (26), who showed that subgroup B Ad viruses preferentially infect LC and suggested that the skin might be an appropriate site for the administration of Ad35-based vaccines that target LC. Besides CD1a⁺ DC, CD1a^– cells also migrated from the skin explants. We recently reported a subpopulation of CD1a^–CD83^– cells within the DC gate to exhibit macrophage-like characteristics with both CD14 and strong diffuse CD68 expression (27). These cells expressed low levels of costimulatory molecules and failed to stimulate T cells. Of note, we found their number to increase over time subsequent to migration from the skin, unless a strong DC-maturation signal was provided before migration, such as injection of GM-CSF and IL-4. This finding was confirmed in the present study, with maintained expression of CD83, CD80, and CD86 levels following coinjection of GM-CSF and IL-4 together with the used Ad vectors, up to 7 days subsequent to skin emigration. Of note, we previously demonstrated this maintained CD83⁺ mature state of the skin-emigrated DC to be accompanied by the expression of CCR7, indicative of their ability to migrate to the T cell areas in the skin-draining lymph nodes (18, 21).

In essence, previous observations pointing to the suitability of Ad35-based vectors for in vivo DC-targeted vaccination approaches were confirmed in our present study of rAd35-mediated DC transduction in a dermal substrate (see below).

1) An important issue in the application of Ad-based vaccines is the presence of pre-existent neutralizing Abs. Whereas pre-existent neutralizing Abs to Ad5 may necessitate high initial rAd5 vaccine doses and may limit the applicability of repeated rAd5 booster vaccinations, the absence of neutralizing Abs to Ad35 in the general population allows for accurate dose control, i.e., one single effective dose of Ad35-based vectors for all vaccinees. Moreover, Ad35-based vaccines may be used for multiple vaccinations before limiting immunity arises. It was demonstrated recently that the most effective neutralizing Ab responses against rAd5 were directed at the hexon proteins on the viral capsid, also contained within the rAd5F35 vector, rather than to the Ad5 fiber knob or penton base, as was originally assumed (14). In this study, we report that rAd35 and rAd5F35 vectors are equally effective in the transduction of cutaneous DC. Besides demonstrating the applicability of rAd35 in i.d. vaccination to be equal to that of rAd5F35, this observation also indicates that the rAd35-associated improved DC transduction efficiency was not due to lower levels of Ad35-neutralizing Abs as compared with Ad5-neutralizing Abs in the pooled human serum that was used in the skin explant cultures. Rather, the improved transduction efficiency of skin-emigrated DC was the result of an intrinsically superior in situ DC infectivity of Ad35-based vectors over rAd5. This was confirmed by a maintained improved transduction efficiency with rAd35 over rAd5 in serum-free skin explant cultures or cultures containing FCS rather than human serum (data not shown).

2) In the skin microenvironment, the docking receptor of Ad35 is not exclusively expressed on DC. In fact, before activation, quiescent CD1a⁺ DC are either negative for CD46 or express it at lower levels than other (stromal) cells in the skin (see Fig. 1A). This may, at least in part, explain why immediate injection of rAd35 into the dermis did not result in a higher transduction efficiency of subsequently migrated DC as compared with rAd5 injection. In contrast, an increased transduction efficiency of rAd35 (and rAd5F35) over rAd5 became apparent upon i.d. injection of the rAd vectors subsequent to a 24-h culture of the skin explants (i.d. injected with either medium or GM-CSF and IL-4). This is most likely due to an up-regulation of the high-affinity CD46 receptor on the cutaneous DC, which accompanied their culture-induced maturation. Other contributing factors to the improved transduction efficiency may be the increased frequency of migrating and accumulated DC in the dermis at the time of i.d. rAd injection and possibly their more preferential localization in draining lymph vessels at that time, which may render the DC more easily physically accessible to the injected rAd viruses. A preferential infection of mature (CD46⁺) migrating DC would explain the considerably higher transduction efficiency among skin-emigrated DC as compared with dermal CD1a⁺ DC in situ, an observation we also previously made for CD40-targeted rAd viruses (18). Our in situ findings are in keeping with previously published in vitro observations by Rea et al. (10), revealing a preserved high efficiency transduction of DC by Ad35-based vectors, even in the presence of CD46⁺ stromal skin fibroblasts that, like the DC, were also more efficiently transduced by rAd35 than by rAd5 (see Fig. 3). Thus, rAd35 vectors do not truly target DC in the sense that they uniquely infect DC, but also other cell types. Nevertheless, they infect DC with high efficiency in the context of dermal tissue.

3) DC that were i.d. transduced by rAd35 and had subsequently migrated from the skin were able to activate CD8⁺ T cells, specifically recognizing an HLA-A2-restricted epitope contained within the transgene product (in this case the Pf CS protein). This demonstrated that the followed sequence of cutaneous DC maturation, rAd35-mediated infection, and migration allowed for the correct expression, processing, and presentation of the transgene product for subsequent CD8⁺ T cell activation: an absolute requirement for successful vaccination.

In keeping with previous reports, we did not observe rAd35-induced DC maturation (10), nor did we find an up-regulation of the T cell-stimulatory cytokine IL-12p70. In contrast, neither did we find any adverse effects of Ad35 on DC maturation or on the release of such immunostimulatory cytokines as IL-1, IL-6, or IL-12p70, as was recently reported by Iacobelli-Martinez et al. (28), who found evidence for immunosuppressive effects of rAd35 (but not rAd5) through CD46 binding and subsequent interference with IFN--induced C/EBP protein expression. In fact, we observed a significant decrease in the levels of the immunosuppressive cytokine IL-10 in skin explant-conditioned medium upon intracutaneous delivery of rAd35, suggestive of immunopotentiation rather than immunosuppression. Although we did observe a decrease in overall numbers of skin-emigrating DC upon rAd35 injection, the high rAd35-mediated transduction efficiency, as compared with rAd5, ultimately resulted in significantly higher numbers of migrated DC that were both mature and transduced. Indeed, by conditioning of the skin with GM-CSF and IL-4 before rAd35 injection, these numbers were further up-regulated, and the skin-emigrated DC were characterized both by a stable mature phenotype and a maintained transgene expression for up to 7 days after i.d. rAd35 delivery.

In conclusion, our data clearly demonstrate the feasibility of i.d. vaccination with rAd35 and warrant the further development of rAd35 vectors for DC-targeted vaccine delivery in vivo. From the results obtained in our human skin explant model, we propose the following rAd35-based i.d. vaccination scheme: 1) prior conditioning of the vaccination site with DC-stimulatory cytokines, which will ensure sufficient numbers of migrating DC in the dermis as well as sufficient expression levels of CD46 on the DC to facilitate high efficiency in situ DC transduction, followed by 2) the i.d. injection of rAd35 encoding the Ag of interest, which will result in the migration of DC with high transduction efficiencies, a stable mature T cell-stimulatory phenotype, and the ability to activate specific CD8⁺ effector T cells.

	Disclosures

Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 
The authors have no financial conflict of interest.

	Footnotes

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

¹ T.D.d.G. and O.J.A.E.O. contributed equally to this manuscript.

² Address correspondence and reprint requests to Dr. Tanja D. de Gruijl, Department of Medical Oncology, Room CCA 222, Vrije Universiteit Medical Center, De Boelelaan 1117, 1081 HV Amsterdam, The Netherlands. E-mail address: td.degruijl{at}vumc.nl

³ Abbreviations used in this paper: DC, dendritic cell; Ad, adenovirus; CAR, coxsackievirus and Ad receptor; CS, circumsporozoite; i.d., intradermal; LC, Langerhans cell; MoDC, monocyte-derived DC; Pf CS, P. falciparum CS; vp, virus particle.

Received for publication December 28, 2005. Accepted for publication May 30, 2006.

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Top Abstract Introduction Materials and Methods Results Discussion Disclosures References

 

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