Dendritic Cells Retrovirally Transduced with a Model Antigen Gene Are Therapeutically Effective against Established Pulmonary Metastases

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© The Rockefeller University Press, 0022-1007/1997/10/1213/ $5.00
The Journal of Experimental Medicine, Volume 186, Number 8, October 20, 1997 1213-1221

Articles

Dendritic Cells Retrovirally Transduced with a Model Antigen Gene Are Therapeutically Effective against Established Pulmonary Metastases

Jennifer M. Specht, Gang Wang^*, My T. Do^*, John S. Lam, Richard E. Royal^*, Mark E. Reeves^*, Steven A. Rosenberg^*, and Patrick Hwu^*

From the ^* Surgery Branch, National Cancer Institute, National Institutes of Health, Bethesda, Maryland 20892; and the Howard Hughes Medical Institute–National Institutes of Health Research Scholars Program, Bethesda, Maryland 20814

Abstract

Top
Abstract
Materials and Methods
Results
Discussion
References

Dendritic cells (DCs) are bone marrow–derived leukocytesthat function as potent antigen presenting cells capable ofinitiating T cell–dependent responses from quiescent lymphocytes.DC pulsed with tumor-associated antigen (TAA) peptide or proteinhave recently been demonstrated to elicit antigen-specific protectiveantitumor immunity in a number of murine models. Transductionof DCs with TAA genes may allow stable, prolonged antigen expressionas well as the potential for presentation of multiple, or unidentified,epitopes in association with major histocompatibility complexclass I and/or class II molecules. To evaluate the potentialefficacy of retrovirally transduced DCs, bone marrow cellsharvested from BALB/c mice were transduced with either a modelantigen gene encoding β-galactosidase (β-gal) or acontrol gene encoding rat HER-2/neu (Neu) by coculture withirradiated ecotropic retroviral producer lines. Bone marrowcells were differentiated into DC in vitro using granulocyte/macrophagecolony-stimulating factor and interleukin-4. After 7 d in culture,cells were 45–78% double positive for DC phenotypic cellsurface markers by FACS^® analysis, and DC transduced withβ-gal were 41–72% positive for β-gal expressionby X-gal staining. In addition, coculture of β-gal transducedDC with a β-gal–specific T cell line (CTLx) resultedin the production of large amounts of interferon- ${gamma}$ , demonstratingthat transduced DCs could process and present endogenously expressedβ-gal. DC transduced with β-gal and control rat HER-2/neuwere then used to treat 3-d lung metastases in mice bearingan experimental murine tumor CT26.CL25, expressing the modelantigen, β-gal. Treatment with β-gal–transducedDC significantly reduced the number of pulmonary metastaticnodules compared with treatment with Hank's balanced salt solutionor DCs transduced with rat HER-2/neu. In addition, immunizationwith β-gal–transduced DCs resulted in the generationof antigen-specific cytotoxic T lymphocytes (CTLs), which weresignificantly more reactive against relevant tumor targets thanCTLs generated from mice immunized with DCs pulsed with theL^d-restricted β-gal peptide. The results observed in thisrapidly lethal tumor model suggest that DCs transduced withTAA may be a useful treatment modality in tumor immunotherapy.

Address correspondence to Patrick Hwu, Surgery Branch, NationalCancer Institute, National Institutes of Health, Bldg. 10,Rm 2B42, 9000 Rockville Pike, Bethesda, MD 20892. Phone: 301-402-1156;FAX: 301-435-5167; E-mail: pat{at}helix.nih.gov

Dendritic cells (DCs)¹ are highly specialized APCs that possessunique immunostimulatory properties and function as the principalactivators of quiescent T cells, and thus cellular immune responsesin vivo. (1). These bone marrow–derived leukocytes expressa unique repertoire of cell-surface molecules including highlevels of MHC class I and II, adhesion molecules, and costimulatorymolecules, all of which assist in the activation of T cells.As motile cells with elaborate cytoplasmic processes and aunique veiled morphology, DCs are specialized for antigen captureand transport from the periphery to T cell–dependentareas of lymphoid organs.

The key role of DCs in the initiation of immune responses hasfocused the attention of many investigators on the potentialefficacy of these cells in tumor immunotherapy. Several groupshave demonstrated that DCs pulsed with peptides from tumorassociated antigens (TAA) can induce antigen-specific antitumorresponses in vivo in a variety of murine tumor models (2–7).The successes of TAA-pulsed DCs in murine models has supportedthe use of autologous, peptide-pulsed DCs in recent clinicaltrials (8).

In developing strategies to optimize the use of DCs in tumorimmunotherapy, retroviral transduction of DCs with TAA genesmay offer important advantages over peptide-pulsed DCs and othermethods of immunization currently in use. The efficacy of peptide-pulsedDCs might be limited in vivo, because peptides pulsed ontoDCs stay bound to the MHC molecules only transiently due tovariation in peptide binding affinities, peptide–MHC complex dissociation, and MHC turnover (9). Additionally, the use of peptide-pulsed DCs is dependent on the knowledge of theHLA haplotype of the patient, as well as the restriction elementof the peptide epitopes for any particular antigen.

However, retroviral transduction of DCs with TAA genes mayallow for constitutive expression of the full-length proteinleading to prolonged antigen presentation in vivo, and presentationof multiple or unidentified antigen epitopes in the contextof MHC class I, and possibly class II, molecules. Additionally,retrovirally transduced DCs are entirely autologous, thus abrogatingthe potential for development of neutralizing antibodies withrepeated treatments, as can occur with recombinant viral immunization modalities. TAA-transduced DCs might also be given repeatedlyand/or combined with other viral or peptide-based immunizationstrategies.

As nonreplicating, terminally differentiated cells, mature DCs are poor candidates for retroviral gene modification. However,dividing bone marrow progenitor cells can be efficiently transducedwith retroviral vectors (10–12). Because DCs can successfullybe generated in vitro from bone marrow cells in the presenceof GM-CSF–containing cytokine combinations (13–16),we used a method by which bone marrow cells were retrovirallytransduced by coculture with irradiated producer lines and thendifferentiated in vitro to DCs. This method has previouslybeen shown to be effective in human DC by retroviral transductionof CD34⁺ hematopoietic progenitor cells (HPCs) and differentiationof transduced cells in vitro to mature DC (17, 18).

In this study, we demonstrate that murine DCs retrovirally transducedwith the gene encoding β-galactosidase (β-gal) stablyexpress, process, and present the gene in the context of MHCclass I molecules, and that treatment with β-gal–transducedDCs is capable of mediating effective antitumor activity againstestablished pulmonary metastases of a murine tumor expressingβ-gal.

Materials and Methods

Top
Abstract
Materials and Methods
Results
Discussion
References

Cell Lines.
CT26.CL25, a subclone of CT26.WT, is a BALB/c (H-2^d) carcinogen-induced,undifferentiated colon carcinoma stably transduced with a retrovirusencoding the lacZ gene driven by the Moloney murine leukemiavirus long terminal repeat (LTR) promoter (19). Tumor celllines were maintained in RPMI 1640 supplemented with 10% heat-inactivatedfetal calf serum, 2 mmol/liter glutamine, 100 U/ml penicillin,100 µg/ml streptomycin (all from Biofluids, Rockville,MD), 1.25 mg/ml amphotericin B (Fungizone; GIBCO BRL, Gaithersburg,MD), and 50 µg/ml gentamicin sulfate (GIBCO BRL). TheCTL line (CTLx) which recognizes the naturally processed, H-2L^d–restricted β-gal epitope p876 to 884, has previously been described(20).

Retroviral Transduction and Differentiation of DCs from Bone Marrow Cells.
CreLacZ and CreNeu are fibroblast-derived, ecotropic-packagingcell lines encoding the lacZ and rat HER-2/neu genes, respectively,in the MFG retroviral vector backbone. CreLacZ was providedby Richard Mulligan (Children's Hospital, Boston, MA) and haspreviously been described (21). CreNeu was provided by ElizabethJaffee (Johns Hopkins University, Baltimore, MD). Bone marrowwas flushed from the long bones of the hind limbs of female8–12-wk-old BALB/c mice and depleted of erythrocytes withACK lysing buffer (Biofluids). Bone marrow cells were depletedof lymphocytes and Ia⁺ cells by incubation at 4°C in anantibody cocktail (RA3-3A1/6.1, anti–B cell surface glycoprotein;HO-2.2, anti-Lyt 2.2; B21-2, anti-I-A^b,d; and GK1.5, anti-L3T4T cell surface antigen; all from American Type Culture Collection,Rockville, MD) and cytotoxicity medium (CM; Cedarlane Labs.Ltd., Hornby, Canada). Antibody-bound cells were removed byincubation at 37°C with rabbit complement (Accurate Chemicaland Scientific Corp., Westbury, NY). Bone marrow cells (7 x10⁵ cells/ml) were plated on irradiated (5,000 rads) Cre producerlines (5 x 10³ cells/well) in DC CM and cocultured for 2 dat 37°C, 5% CO₂ in 6-well plates. Cells were cultured inDC complete medium (DC CM), which is RPMI-1640 supplementedwith 5% heat-inactivated fetal calf serum, 2 mmol/liter glutamine,100 U/ml penicillin, 100 µg/ml streptomycin, 1.25 µg/mlamphotericin B, 50 µg/ml gentamicin sulfate, 5 x 10^–5µM 2-mercaptoethanol (2-ME; GIBCO BRL), 20 ng/ml recombinantmurine GM-CSF (rmGM-CSF), and 100 ng/ml recombinant murineIL-4 (rmIL-4) (both from Peprotech, Rocky Hill, NJ). On day2, nonadherent cells were carefully removed from adherent packagingcell lines and replated at 7 x 10⁵ cells/ml in DC CM. On day4, 10 ng/ml rmGM-CSF and 50 ng/ml rmIL-4 were added to eachwell. Cells were harvested on day 6 by gentle pipetting andreplated in 100 mm tissue culture dishes at 10⁶ cells/ml withDC CM supplemented with 20 ng/ml rmGM-CSF and 100 ng/ml rmIL-4.

Cell Surface Phenotype.
Selected monoclonal antibodies against the murine molecules(B7-1, B7-2, Ia^d, CD11c, B220/CD45R, CD3, Thy1.2, Mac-1, GR-1,and appropriate isotype controls; all from PharMingen, SanDiego, CA) were obtained directly labeled with phycoerythrinor fluorescein isothiocyanate. For phenotypic analysis, 10⁶day 7 DCs or fresh syngeneic splenocytes were first incubatedwith 2.4G2, an antibody directed against the FcRII ${gamma}$ receptor,and then double stained with the indicated directly labeledantibodies. Propidium iodide was used to exclude dead cellsfrom the analysis.

Mixed Leukocyte Reaction.
The ability of DCs to stimulate quiescent T cells was assessedby the MLR. Bone marrow–derived DCs (transduced and nontransduced)or freshly prepared splenocytes were irradiated (2,000 rads)and plated in graded doses with 2 x 10⁵ allogeneic T cellsin 200 µl of RPMI-1640 media supplemented with 10% heat-inactivatedfetal calf serum, 2 mmol/liter glutamine, 100 U/ml penicillin,100 µg/ml streptomycin, 1x nonessential amino acids,1 mM sodium pyruvate (all from Biofluids), 1.25 µg/mlamphotericin B (Fungizone; GIBCO BRL), and 50 µg/ml gentamicinsulfate (GIBCO BRL) (mCM) in flat-bottomed 96-well tissue cultureplates and incubated at 37°C, 5% CO₂ for 3.5 d. AllogeneicT cells were prepared from C57BL/6 mice by passing RBC-depletedsplenocytes through an immunoaffinity column (R&D Systems,Minneapolis, MN). During the last 6 h of incubation, cultureswere pulsed with 1.0 µCi/well [³H]thymidine (New EnglandNuclear, Boston, MA). [³H]thymidine incorporation was measuredusing a β scintillation counter (Beta Plate; LKB, Gaithersburg,MD).

X-Gal Staining.
To detect β-gal expression in transduced DCs, 5 x 10⁵day 7 DCs were washed once with PBS (Biofluids) and fixed with1 ml 0.5% glutaraldehyde for 10 min at room temperature. Cellswere centrifuged, washed in PBS, and incubated in 0.5 ml X-galsolution (330 mM K₃Fe(CN)₆, 330 mM K₄Fe(CN)₆, 1 M MgCl₂, 10%Triton X-100, 67 mg/ml X-gal, PBS) for 3–5 h at 37°C,5% CO₂. Bright blue cells in each sample were counted blindlyand expressed as a percentage of the total cells.

In Vitro Cytokine Release Assays.
To determine whether endogenously expressed β-gal was processedand presented in the context of MHC class I molecules, β-gal–specificT cells (CTLx; 10⁵) were cultured with day 7 bone marrow–derivedDCs or peptide-pulsed splenocytes (10⁵) in 200 µl mCMcontaining 60 IU/ml IL-2 (Chiron, Emeryville, CA) in flat-bottomed96-well tissue culture plates and incubated at 37°C ina 5% CO₂ humidified incubator. After 24 h, the supernatant wascollected and analyzed for IFN- ${gamma}$ content with an ELISA assay(R&D Systems).

Peptides.
The peptide (βgP), TPHPARIGL, representing the naturallyprocessed H-2 L^d-restricted epitope spanning amino acids 876–884of β-gal (22) and the P1A_35–43 peptide LPYLGWLVF,presented by H-2 L^d, were synthesized by Peptide Technologies(Washington, DC) to a purity >99% as assessed by HPLC andamino acid analysis.

Antigen Pulsing of DCs.
Day 7 bone marrow–derived DC from BALB/c mice were resuspendedin reduced serum media (Optimem; GIBCO BRL) at 2 x 10⁶ cells/mland pulsed with peptide (10 µg/ml) plus human β₂-microglobulin(β₂m; 10 µg/ ml; Intergen Co., Purchase, NY) for4 h at room temperature with gentle mixing. Cells were thenwashed twice in HBSS (Biofluids) and DCs (4 x 10⁵) in 0.5 mlHBSS were injected intravenously in the tail vein. Freshly isolatedsyngeneic splenocytes (5 x 10⁶ cells/ml) were pulsed with peptidein an identical manner as DCs.

In Vivo Treatment Studies.
BALB/c mice were challenged with CT26.CL25 tumor cells (3 x10⁵) intravenously to establish pulmonary metastases. On days3 and 6 after tumor challenge, mice were treated with day 7bone marrow–derived transduced or peptide-pulsed DCsor peptide-pulsed splenocytes intravenously. All mice were randomizedbefore receiving transduced or peptide-pulsed DCs or splenocytes.Mice were killed on day 12 and metastatic lung nodules wereenumerated in a randomized and blinded manner. Numbers presentedare the mean numbers of pulmonary metastases ± SEM.The significance of differences between the groups was determinedwith the Wilcoxon rank Sums test. All P values are two-tailed.

In Vitro Antigen Restimulation.
For CTL generation, naive mice were immunized with transducedor peptide-pulsed DCs or splenocytes (4 x 10⁵ cells) on days0 and 3. 3–4 wk after the second immunization, splenocytesfrom animals immunized with transduced or peptide-pulsed DCsor splenocytes were pooled and restimulated in vitro with theL^d-restricted β-gal peptide for 6 d in EHAA medium (Biofluids)supplemented with 0.5% heat-inactivated mouse serum (Sigma ChemicalCo., St. Louis, MO) and 5 x 10^–5 µM 2-mercaptoethanol(2-ME; GIBCO BRL). On days 2 and 4, 1 ml of fresh media with60 IU/ml IL-2 (Chiron, Emeryville, CA) was added to each wellof cells. On day 7, restimulated splenocytes were tested forantigen-specific cytolytic activity and cytokine release. Restimulatedsplenocytes (10⁵) were plated in flat-bottomed 96-well tissueculture plates with 10⁵ peptide-pulsed tumor targets in 200µl media. After 24 h, the supernatant was collected andanalyzed for IFN- ${gamma}$ content with an ELISA assay (R&D Systems).

Cytotoxicity Assays.
Target cells (CT26 and CT26.CL25 tumor cells) were harvestedand labeled with 200 µCi Na₂⁵1CrO₄ (Amersham, ArlingtonHeights, IL). Restimulated splenocytes from mice immunizedwith transduced or peptide-pulsed DCs or splenocytes were harvestedand mixed in graduated doses with 5 x 10³ labeled target cellsin 150 µl mCM in round-bottomed 96-well tissue cultureplates. Cells were incubated for 4 h at 37°C in a 5% CO₂humidified incubator, the ⁵¹Cr released from the target cellswas measured with a ${gamma}$ counter (Wallac, Gaithersburg, MD), andthe percent specific lysis was calculated as follows: 100 x ([experimental release – spontaneous release]) / ([maximalrelease – spontaneous release]). Spontaneous and maximalrelease were determined in the presence of either medium or2% SDS, respectively.

Results

Top
Abstract
Materials and Methods
Results
Discussion
References

Retroviral Transduction of Bone Marrow Cells and Differentiation into DCs.
Bone marrow cells from BALB/c mice were retrovirally transducedby coculture with the irradiated, ecotropic packaging cell lines,CreLacZ and CreNeu, for 2 d. This method of gene modificationcapitalizes on the suitability of rapidly dividing bone marrowcells as targets for retroviral transduction (10–12).Transduced bone marrow cells were then differentiated intoDCs in vitro for an additional 5 d in the presence of rmGM-CSFand rmIL-4. This method of retroviral transduction consistentlygenerated a cell population composed of 45–78% DCs asdetermined by the percentage of cells double positive for characteristic DC surface molecules (B7-2, I-A^d, B7-1, CD11c) (Fig. 1).

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Figure 1 Cell surface phenotype of bone marrow–derived DCs as determined by FACS^® analysis. For phenotypic analysis, 10⁶ DCs on day 7 of culture or fresh syngeneic splenocytes were incubated with 2.4G2, an antibody directed against the FcRII ${gamma}$ receptor, and then double stained with the indicated directly labeled antibodies. Propidium iodide was used to exclude dead cells from the analysis. (A) B7-2 and I-A^d with isotype controls, (B) B7-1 and B7-2 with isotype controls, and (C) CD11c and B7-2 with isotype controls.

To determine the percent of cells expressing β-gal in the transduced cell population, day 7 DCs were X-gal stained. Transduction efficiencies between 41–72% were consistentlyobserved by this method with very low levels of backgroundstaining in the nontransduced or HER-2/neu– transducedcontrols (Table 1). Both transduced and nontransduced DCs displayeda characteristic DC morphology with prominent cytoplasmic processes(Fig. 2).

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Table 1 Expression of β-gal in Retrovirally Transduced DCs

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Figure 2 Expression of β-gal as determined by X-gal staining. On day 7 of in vitro culture, nontransduced DCs (A) and β-gal–transduced DCs (B) were fixed and stained as described in Materials and Methods. Phase contrast photomicrographs were taken at 100x.

Bone Marrow–derived, Retrovirally Transduced DCs Function as Potent Stimulators in an Allogeneic Mixed Leukocyte Reaction.
The allostimulatory capacity of the DCs were assessed by mixedleukocyte reaction (MLR) (Fig. 3). Both transduced and nontransducedDCs were potent stimulators of quiescent, allogeneic T cellsin repeated experiments. DCs were greater than 1,000-fold strongerthan fresh, bulk splenocytes in stimulating proliferation ofallogeneic T cells. No significant difference was observedamong the nontransduced, β-gal–transduced, or Neu-transducedDCs.

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Figure 3 Allogeneic MLR of bone marrow–derived DCs and splenocytes. Bone marrow cells were transduced by coculture with retroviral producer lines, CreLacZ (DC–β-gal) and CreNeu (DC–Neu), and differentiated into DCs in vitro. DCs were cocultured with allogeneic, C57BL/6 T cells, isolated from bulk splenocytes by passing cells through an immunoaffinity column. After 3.5 d in culture, cells were pulsed with [³H]thymidine as described in Materials and Methods. Results from triplicate wells were corrected for [³H]thymidine incorporation by irradiated stimulators and T cells alone, and are plotted as the mean ± SEM.

Retrovirally Transduced DCs Process and Present Endogenously Expressed β-gal.
To determine whether the β-gal transduced DCs were capableof processing and presenting β-gal peptides, transducedand peptide-pulsed DCs were cocultured with an L^d-restrictedβ-gal–specific T cell line, CTLx (20). After 24h, IFN- ${gamma}$ was measured in the culture supernatant (Table 2). DCstransduced with β-gal induced antigen-specific cytokinerelease from activated T cells indicating that the endogenouslyexpressed transgene was processed and presented in an MHC-restrictedmanner. DCs as well as fresh, syngeneic splenocytes pulsedwith the L^d-restricted βgP, also induced IFN- ${gamma}$ releasefrom CTLx as positive controls. DC transduced with HER-2/neuor pulsed with an irrelevant peptide, P1A, failed to causecytokine release, demonstrating the antigen specificity ofthe response.

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Table 2 Cytokine Release from L^d-restricted, β-gal–specific T Cell Line (CTLx) in Response to Bone Marrow–derived DCs

Retrovirally Transduced DCs Are Therapeutically Effective against Established Pulmonary Metastases.
To determine the therapeutic efficacy of retrovirally transducedand peptide-pulsed DCs against established pulmonary metastases, BALB/c mice were challenged with 3 x 10⁵ CT26.CL25 tumor cellsintravenously and treated intravenously with either 4 x 10⁵β-gal or HER-2/neu–transduced DCs, 4 x 10⁵ peptide-pulsedDCs, 4 x 10⁵ βgP-pulsed splenocytes, or HBSS on days 3and 6 after tumor challenge. On day 12, the number of pulmonarymetastastic nodules were enumerated in a blinded fashion. Micetreated with DCs transduced with β-gal (DC–β-gal)or pulsed with βgP (DC– βgP) showed a significantreduction in the number of pulmonary metastases compared withmice treated with HER-2/neu–transduced (DC–Neu)or P1A peptide-pulsed DCs (DC–P1A) (Fig. 4 A). The uniquerole of DCs in this response is evidenced by the lack of treatmenteffect seen in mice treated with βgP-pulsed splenocytes(splen– βgP). These results are representative ofdata obtained from four independent experiments.

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Figure 4 Active immunotherapy with retrovirally transduced or peptide-pulsed DCs significantly reduces the number of established pulmonary metastases in this 3-d tumor model. (A) 8–10 BALB/c mice/group were injected intravenously with 3 x 10⁵ CT26.CL25 tumor cells. On days 3 and 6 after tumor challenge, mice received intravenous injections of 4 x 10⁵ transduced or peptide-pulsed DCs, fresh peptide-pulsed splenocytes, or HBSS alone. On day 12 after tumor challenge, lungs were harvested and pulmonary nodules were enumerated in a blinded fashion. (B) BALB/c mice were challenged with 3 x 10⁵ CT26.CL25 tumor cells. On days 3 and 6 after tumor challenge, mice received intravenous injections of transduced DCs or fresh peptide-pulsed splenocytes at varying doses (4–16 x 10⁵). On day 12 after tumor challenge, lungs were harvested and pulmonary nodules were enumerated in a blinded fashion.

To assess further the efficacy of retrovirally transduced DCsin this tumor model, BALB/c mice bearing CT26.CL25 pulmonarymetastases (3 x 10⁵ tumor cells) were treated with varyingdoses of retrovirally transduced DCs or βgP-pulsed splenocytes(4 x 10⁵–1.6 x 10⁶) on days 3 and 6 after tumor challenge(Fig. 4 B). Mice receiving β-gal–transduced DCs showeda significant reduction in pulmonary metastases compared withmice receiving HER-2/neu–transduced DCs or βgP-pulsedsplenocytes at all doses tested. Increasing the dose of β-gal–transduced DCs from 4 x 10⁵ to 1.6 x 10⁶ did not significantly enhancetherapeutic efficacy. Identical studies with L^d-restricted βgP-pulsed DCs also failed to show a significant correlation between antitumor activity and increased DC dose in this model(data not shown). These studies demonstrate that in this rapidlylethal tumor model, β-gal–transduced DCs (DC–β-gal),and βgP-pulsed DCs (DC–βgP) were both capableof mediating significant, specific antitumor activity.

Generation of β-gal–specific CTLs by In Vivo Immunization with Bone Marrow–derived DCs.
To determine whether antigen-specific CTLs were generated invivo after DC administration, naive, nontumor-bearing mice wereimmunized on day 0 and day 3 with 4 x 10⁵ peptide-pulsed DCs,4 x 10⁵ β-gal–transduced DCs, or βgP-pulsedsplenocytes intravenously. 3–4 wk after the second immunization,splenocytes from immunized mice were restimulated in vitro with βgP for 6 d. On day 7, restimulated splenocytes were cocultured with tumor targets, and 24-h IFN- ${gamma}$ release was measured(Table 3).

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Table 3 Cytokine Release From CTL Generated In Vivo by Immunization with Bone Marrow–derived DCs

Splenocytes from mice immunized with either β-gal–transduced or βgP-pulsed DCs induced antigen-specific cytokine release; however, the T cells generated in mice immunizedwith β-gal–transduced DCs produced significantlymore IFN- ${gamma}$ than T cells from mice immunized with βgP-pulsedDCs. Immunization with control DCs or peptide-pulsed splenocytesfailed to generate detectable CTL activity. These results wereobserved in three independent experiments.

The ability of the CTL to lyse relevant tumor targets was alsoassessed (Fig. 5). CTLs grown from mice immunized with β-gal–transducedDCs demonstrated antigen-specific lytic activity, whereas CTLsfrom mice immunized with βgP-pulsed DCs were minimallyreactive. Immunization with control DCs or βgP-pulsedsplenocytes failed to generate lytic CTLs.

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Figure 5 Lysis of tumor targets by CTLs from mice immunized with transduced (DC–β-gal and DC–Neu) or peptide-pulsed DCs (DC–βgP and DC–P1A) or peptide-pulsed splenocytes (splen–βgP). Splenocytes from immunized animals were harvested, restimulated in vitro for 7 d with the L^d-restricted β-gal peptide_876–884, and mixed in graduated doses with 5 x 10³ ⁵¹Cr-labeled target cells. Cells were incubated for 4 h at 37°C in a 5% CO₂ humidified incubator. ⁵¹Cr released from the lysed target cells was measured. Results are plotted as the mean percent specific lysis ± SEM.

	Discussion

Top Abstract Materials and Methods Results Discussion References

The identification of tumor rejection antigens recognized bycytotoxic T cells has led to the development of vaccinationstrategies aimed at generating an immune response capable ofmediating tumor regression in cancer patients (23). As potentAPCs capable of initiating immune responses from quiescentT cells, DCs pulsed with peptides from TAA have been successfulin murine models in generating antitumor immunity and treatingestablished tumor (2–7). Retroviral gene modificationof DCs may offer important advantages over other methods ofimmunization; perhaps the most important of these being stable,prolonged expression of the full-length antigen leading to presentationof multiple epitopes in the context of MHC class I molecules.To examine the potential therapeutic efficacy of such gene-modifiedDCs, we used the well-characterized murine β-gal tumormodel (24, 25).

In generating retrovirally transduced DCs, we took advantageof the suitability of dividing bone marrow cells as targetsfor retroviral gene modification. Gene-modified cells werethen differentiated in vitro to DCs with cytokine support.This approach for the transduction of DCs has been used successfullyin human CD34⁺ hematopoietic progenitor cells to generate DCsthat stably express the MART-1 melanoma antigen (17). The datapresented here provide evidence that primary murine DCs canbe stably gene modified by retroviral transduction to expressa model TAA gene.

The ability of the transduced DCs to process and present endogenouslyexpressed β-gal was evidenced by recognition and specificcytokine release by β-gal–specific T cells. Thedifference observed in IFN- ${gamma}$ release in response to β-gal–transducedDCs and βgP-pulsed DCs is attributable to the high concentrationof peptide pulsed onto the DCs compared with the transducedDCs, where the antigen is processed and presented at physiologiclevels. A similar effect is also observed with the peptide-pulsedsplenocytes in this assay.

Although we saw no difference in specific antitumor activitybetween β-gal–transduced and β-gal peptide-pulsed DCs under the conditions tested, it is possible that further titrations of DCs and tumor dose might reveal a difference in antitumor response between these two treatments. In fact,immunization with β-gal–transduced DCs generated CTLs that were significantly more reactive in vitro than CTLs grown from mice immunized with β-gal peptide-pulsed DCs.The expression and presentation of multiple epitopes in theβ-gal–transduced DCs might lead to the generationof CTLs with multiple specificities. The presence of such additionalCTL populations in the restimulated T cells might have contributedto the enhanced reactivity observed in cytolytic activity.In addition, the difference in CTL reactivity may be due tothe prolonged presentation of β-gal in vivo by β-gal–transducedDCs compared with peptide-pulsed DCs. An increased durationof antigen presentation could lead to the generation of a greaternumber of CTLs, the expansion of which may require a longerperiod of time than the rapidly lethal, 12-d pulmonary metastases model will allow. We are currently attempting development of longer tumor models to determine whether transduced DCsmight have enhanced in vivo activity compared with peptide-pulsedDCs.

Our current and future efforts are focused on the developmentof tumor models that more closely approximate the characteristicsof the immune response to tumor in patients. The cloning andcharacterization of several shared, human, melanoma-associatedantigens that are recognized by T cells, including tyrosinase,tyrosinase-related protein-1 (TRP-1), MART-1, and gp100, provideopportunities for studying the ability of retrovirally transducedDCs to induce an immune response against nonmutated, self-antigens(26–29). In the mouse, TRP-2 has recently been identifiedas a nonmutated, melanoma-associated antigen in B16 melanoma(30). We have begun construction of retroviral vectors encodingthe murine melanoma-associated antigens, TRP-2 and gp100, expressedin B16 melanoma. The ability of transduced DCs to immunizeagainst and/or treat this nonimmunogenic tumor may be a usefulpredictor of the potential efficacy of retrovirally transducedDCs in humans.

Approaches designed to enhance the immunostimulatory functionof DCs are also being explored. These include transductionof DCs with cytokine genes in an attempt to enhance DC immunogenicity.Activation of DCs by CD40–CD40 ligand association, aswell as the use of adjuvant cytokines such as GM-CSF and IL-12,in vivo are also being investigated.

The ability to transduce a primary DC retrovirally to expressstably a foreign gene also introduces a novel, potentially powerful,approach to studying the mechanisms of DC activation and differentiationas well as protein trafficking and antigen processing in primaryDCs. Retroviral transduction of genes encoding proteins containingintracellular targeting sequences, such as the hexapeptide presentin melanosomal membrane proteins gp75 and gp100 (31), mightallow efficient trafficking of protein antigens to the MHCclass II endosomal pathway, resulting in presentation of antigenepitopes in the context of MHC class I and II molecules. Theefficient presentation of antigen in association with both classI and class II may allow the initiation of a more potent immuneresponse.

In summary, we present here evidence that murine DCs can beretrovirally transduced to express stably a model TAA gene.TAA-transduced DCs generated by this method express the transgeneat high levels, and are capable of processing and presentingthe antigen in the context of MHC class I molecules. Immunizationwith gene-modified DCs results in the production of highlyreactive, antigen-specific CTLs. Finally, treatment with TAA-transduced DCs is capable of mediating effective antitumor activity againstestablished pulmonary metastases. These results suggest thatTAA-transduced DCs may be a promising treatment modality intumor immunotherapy.

	Acknowledgments

The authors thank A. Mixon and E. Fitzgerald for assistancein FACS^® analyses, and P. Spiess and D. Jones for theirassistance with animal experiments.

Submitted: 4 June 1997
Revised: 16 July 1997

¹ Abbreviations used in this paper: β-gal, β-galactosidase;βgP, β-gal peptide; β₂m, β₂-microglobulin;CM, cytotoxicity medium; DC, dendritic cell; rm, recombinantmurine; TAA, tumor-associated antigen.

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Lung Cancer

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