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Human CTLs to Wild-Type and Enhanced Epitopes of a Novel Prostate and Breast Tumor-Associated Protein, TARP, Lyse Human Breast Cancer Cells

¹ Vaccine Branch, ² Laboratory of Molecular Biology, ³ Urologic Oncology Branch, and ⁴ Experimental Transplantation and Immunology Branch, Center for Cancer Research, National Cancer Institute, NIH, Bethesda, Maryland; ⁵ Technion-Israel Institute of Technology, Technion City, Haifa, Israel; and ⁶ Center for Immunization Research, Johns Hopkins Bloomberg School of Public Health, Baltimore, Maryland

	ABSTRACT

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Vaccine therapy for prostate and breast cancer may have potential for treating these major causes of death in males and females, respectively. Critical to the development of tumor-specific vaccines is finding and characterizing novel antigens to be recognized by CD8⁺ T cells. To define new CD8⁺ T-cell tumor antigens, we determined two wild-type HLA-A2 epitopes from a recently found tumor-associated protein, TARP (T-cell receptor alternate reading frame protein), expressed in prostate and breast cancer cells. We were also able to engineer epitope-enhanced peptides by sequence modifications. Both wild-type and enhanced epitopes induced peptide-specific CD8⁺ T-cell responses in A2K^b transgenic mice. In vitro restimulation of human CD8⁺ T cells from a prostate cancer patient resulted in CD8⁺ T cells reactive to the peptide epitopes that could lyse HLA-A2⁺ human breast cancer cells (MCF-7) expressing TARP. Epitope-specific human CD8⁺ T cells were also enumerated in patients’ peripheral blood by tetramer staining. Our data suggest that HLA-A2-binding TARP epitopes and enhanced epitopes discovered in this study could be incorporated into a potential vaccine for both breast and prostate cancer.

	INTRODUCTION

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Up to 30% of 180,000 United States patients with potentially curable early-stage breast and prostate cancer will fail standard surgical or radiotherapy in 2004. In addition, patients with metastatic prostate cancer and the majority of patients with metastatic breast cancer enjoy limited benefit of standard chemotherapy and hormone-based therapies. Immunotherapy may have great potential to improve on these results, combining the tumor specificity of cell-mediated immunity with freedom from toxic chemotherapies.

Recent immunotherapy of cancer patients has built on the finding that CD8⁺ CTLs recognize and kill tumor cells displaying peptides from tumor-associated antigens presented by MHC class I molecules. Several tumor antigens and HLA allele-specific peptides from prostate cancer-associated antigens have been identified as CD8⁺ T-cell epitopes, including HLA-A2-binding peptides derived from prostate-specific antigen (1) , prostate-specific membrane antigen (2) , prostate stem cell antigen (3) , and prostate acid phosphatase (4) , which are all now components of current vaccine trials (5, 6, 7, 8) .

Finding additional, more tumor-specific antigens, however, will be critical to the success of effective immunotherapy. In this regard, several new genes specifically expressed in human prostate and breast cancer have been identified by analysis of the expressed sequence tag database (9, 10, 11) . One of these, TARP[T-cell receptor (TCR) alternate reading frame protein], is expressed in both prostate and breast cancer cells (12 , 13) . TARPwas originally discovered because there were unusually large numbers of expressed sequence tags in prostate cancer samples that contained TCR sequences but not TCR sequences as might be expected if the prostate cancer samples used to make the expressed sequence tags contained many TCR T cells. Subsequently, it was shown that both normal prostate and prostate cancer cell line LNCaP express large amounts of a transcript that hybridizes with a TCR cDNA probe but that the mRNA was smaller than mRNAs encoding TCR present in lymph nodes and other organs (12) . Cloning and sequencing of this smaller mRNA showed that it is initiated within the J 1 exon of the TCR gene and that it encodes a 58-amino acid protein produced from a reading frame different from that of TCR. In the past several years, three groups of investigators have used cDNA arrays to analyze gene expression patterns in prostate cancer and found that prostate cancers contain RNA transcripts hybridizing with probes containing TCR sequences but not TCR transcripts and that these transcripts are elevated in prostate cancer (14, 15, 16) . The implication is that these transcripts in prostate cancers encode TARP and not TCR. Furthermore, we have used in situ hybridization to determine the cellular localization of TARP in human prostate cancer samples and shown that TARPis expressed in >90% of cancer specimens examined.⁷

In this study, we first determined human HLA-A2-presented epitopes derived from TARP, and then their immunogenicities were tested in A2K^b transgenic mice that have a chimeric MHC class I molecules composed of 1 and 2 domains from HLA-A2 and 3 domain from K^b (17) . Next, we enhanced the immunogenicity of the peptides by increasing their binding affinities to HLA-A2 molecules. Epitope enhancement can potentially increase the efficacy of a vaccine because natural tumor epitopes are not necessarily optimized for immunogenicity (18, 19, 20, 21, 22, 23) . Because it takes a stronger signal to activate a response than to be the target of a response (24) , the natural epitope may be sufficient to allow killing of the tumor by T cells raised with the enhanced epitope. Furthermore, we have detected CD8⁺ T cells reactive to the wild-type and enhanced epitopes in prostate and breast cancer patients. By in vitro restimulation of peripheral blood mononuclear cells from prostate cancer patients with peptide-loaded dendritic cells (DCs), we could detect and expand peptide-specific CD8⁺ T cells that recognized peptide/MHC complexes, mediating lysis of a human breast cancer cell line. In addition, HLA-A2 tetramers containing individual peptides made in this study allowed us to detect the presence of peptide-specific CD8⁺ T cells in both breast and prostate cancer patients. These studies provide the preclinical basis for clinical trials of TARP-directed vaccine immunotherapy of prostate and breast cancer.

	MATERIALS AND METHODS

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Animals.
A2K^b transgenic mice expressing a chimeric HLA-A2.1 transgene with the 1 and 2 domains from HLA-A2.1 and the 3 domain from H2K^b, to allow binding to mouse CD8, on a C57BL/6 background were developed at The Scripps Clinic by Linda Sherman (17) . These mice were bred and housed in appropriate animal care facilities. All procedures with animals were conducted in accordance with the institutionally approved protocols.

Peptides.
HLA-A2-binding peptides were synthesized on a Model Symphony Peptide Synthesizer (Perkin-Elmer, Boston, MA) using conventional fluorenylmethoxycarbonyl (f-MOC) chemistry and cleaved from the resin by trifluoroacetic acid. The purity and molar concentration were analyzed by reverse-phase high-performance liquid chromatography on a C18 column using a gradient of 0.1% trifluoroacetic acid in water and 0.1% trifluoroacetic acid in acetonitrile and further purified by preparative reverse-phase high-performance liquid chromatography using a similar gradient. Some peptides were purchased from Multiple Peptide Systems (San Diego, CA) at >95% purity and were single peaks by reverse-phase high-performance liquid chromatography.

Cell Lines.
The T2 cell line is deficient in TAP1 and TAP2 transporter proteins and expresses low levels of HLA-A2. The C1R-A2.1 cell line is derived from human B lymphoblastoid cell line HMYC1R transfected with HLA-A2.1. Cells were maintained in complete medium (RPMI 1640 supplemented with 10% FCS, 100 IU of penicillin, and 10 µg/ml streptomycin). RPMI 1640 and other supplements were purchased from Cellgro (Gaithersburg, MD). For C1R-A2.1 cells, 200 µg/ml Geneticin (Sigma, St. Louis, MO) was added into the medium. LNCaP, PC3, MCF-7, and DU145 cells were maintained in the complete media. For PC3-TARP cells (25) , 200 µg/ml hygromycin B (Invitrogen, Carlsbad, CA) was added into the medium.

T2 Binding Assay.
Peptide binding capacity to HLA-A2 molecules was measured by using the T2 cell line according to a protocol described previously (26) . T2 cells (3 x 10⁵ cells/well) were incubated overnight in 96-well plates with culture medium (1:1 mixture of RPMI 1640/Eagle-Hank’s amino acid containing 2.5% fetal bovine serum, 100 units/ml penicillin, and 100 µg/ml streptomycin) with 10 µg/ml ß2-microglobulin (Sigma) and different concentrations of peptides. Cells were washed twice with cold PBS containing 2% fetal bovine serum and incubated for 30 min at 4°C with anti-HLA-A2.1 BB7.2 monoclonal antibody (1:80 dilution from hybridoma supernatant). After washing, cells were stained with FITC-labeled goat antimouse immunoglobulin (PharMingen, San Diego, CA), and the level of HLA-A2 expression was measured by flow cytometry. HLA-A2 expression was quantified as fluorescence index according to the following formula: fluorescence index = (mean fluorescence intensity with peptide – mean fluorescence intensity without peptide)/mean fluorescence intensity without peptide.

Immunizations.
A2K^b transgenic mice were immunized with syngeneic peptide-loaded DCs, plasmid DNA expressing TARP, or a mixture of peptide and cytokine in incomplete Freund’s adjuvant. For DC immunization, DCs were pulsed with 10 µM peptide in serum-free RPMI 1640 for 2 h at 37°C, and then mice were immunized s.c. with 1–3 x 10⁵ DCs without washing. DCs were prepared from bone marrow as described previously (27) . Alternatively, mice were immunized i.m. with 100 µg of plasmid DNA, pcDNA5/FRT/TARP, generated by inserting the TARP DNA into the pcDNA5/FRT (Invitrogen) vector. Mice were also immunized s.c. in the base of the tail with 100 µl of an emulsion containing 1:1 incomplete Freund’s adjuvant and PBS with antigens and cytokines (50 nmol of CTL epitope, 50 nmol of Hepatitis B virus core 128–140 helper epitope, 3 µg of interleukin 12, and 5 µg of granulocyte macrophage colony-stimulating factor. Incomplete Freund’s adjuvant and cytokines were purchased from Sigma and Peprotech (Rocky Hill, NJ), respectively.

In Vitro Human CD8⁺ T-Cell Priming with DCs.
Elutriated monocytes and lymphocytes were obtained from HLA-A2⁺ patients before they underwent surgery or chemotherapy. HLA typing was performed by the Clinical Center laboratory (NIH), which uses a PCR-based low-resolution molecular technique. To prepare DCs to make an autologous peptide-specific CTL line, monocytes from prostate cancer patient 1 (in Fig. 8 ) were cultured at 10⁶ cells/ml in complete medium containing human interleukin 4 (1000 units/ml) and human granulocyte macrophage colony-stimulating factor (1000 units/ml). On days 2 and 4, half of the media was exchanged. Cells were harvested on day 7 and then pulsed with 10 µM peptides for 2 h before -irradiation. Peptide-pulsed DCs (1 x 10⁵) and autologous CD8⁺ T cells (2 x 10⁶) were mixed and cultured in 24-well plates. Interleukin 2 (10 units/ml) was added on day 2 during restimulation. Cells were restimulated every 7–9 days for approximately four to seven cycles.

View larger version (67K): [in this window] [in a new window] [Download PPT slide]   Fig. 8. HLA-A2 tetramers composed of wild-type and enhanced epitopes recognize peptide-specific CD8+ T cells in human blood samples. Tetramers of HLA-A2 and peptide were made as described in "Materials and Methods." Peripheral blood mononuclear cells from breast and prostate cancer patients and normal donors were stained with anti-CD8-FITC and tetramer-PE and then analyzed by flow cytometry. A normal donor was tested simultaneously with each patient as a negative control. Data are representative of two repeated experiments with similar results.

HLA-A2 Tetramers.
Tetrameric MHC class I/peptide complexes were synthesized as described previously (29 , 30) using a single-chain HLA-A2 construct. Briefly, purified single-chain HLA molecule in which the heavy chain and ß2-microglobulin are covalently linked using a flexible peptide linker were synthesized by means of a prokaryotic expression system (pET; R&D Systems, Minneapolis, MN). The heavy chain was modified by deletion of the transmembrane and cytosolic tail and COOH-terminal addition of a sequence containing the Bir-A enzymatic biotinylation site. Single-chain heavy chain-ß2-microglobulin and peptide were refolded by dilution into a redox-shuffling buffer system. The refolded product was isolated by ion-exchange chromatography and then biotinylated by Bir-A in the presence of biotin ligase (Avidity, Denver, CO). Streptavidin-Phycoerythrin conjugate (Jackson ImmunoResearch, West Grove, PA) was added in a 1:4 molar ratio.

Antibodies and Flow Cytometry.
FITC-labeled antimouse CD8 (53-6.7), CD11c, CD80 (B7-1), CD54 (ICAM-1), antihuman CD8 (RPA-T8), CD14 (M5E2), CD80 (B7-1), CD86 (B7-2), Vß3 TCR (JOV1.3), Vß5 TCR (MH3-2), Vß8 TCR (JR2), Vß12 TCR (S511), and Vß23 TCR (AHUT7) were used for staining of cell surface molecules. Intracellular IFN- staining followed the manufacturer’s protocol. All antibodies and reagents were purchased from PharMingen. For flow cytometric analysis of cell surface, 5 x 10⁵ cells were washed and resuspended in PBS containing 0.2% BSA and 0.1% sodium azide. Cells were incubated on ice with the appropriate antibody for 30 min and then washed. Samples were analyzed on a FACScan (BD Biosciences, Mountain View, CA). Background staining was assessed by use of an isotype control antibody. For tetramer staining, cells were incubated with tetramers for 20 min and then stained with FITC-labeled anti-CD8.

	RESULTS

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HLA-A2-Restricted Epitope Prediction and Wild-Type Peptide Binding Affinity to HLA-A2 Molecules.
Fifty-eight amino acid residues in TARP were characterized previously (Ref. 13 ; Fig. 1A ). To determine HLA-A2 epitopes from TARP, four different wild-type peptides were first predicted based on the anchor residues (Fig. 1B) , and their binding affinities to HLA-A2 molecules were measured by the T2 binding assay. As shown in Fig. 1C , only two wild-type peptides, TARP_29–37 and TARP_27–35, showed measurable binding capacity to HLA-A2 molecules. Although both peptides overlap by 7 residues, TARP_27–35 had almost 10-fold higher binding to HLA-A2 molecules than TARP_29–37. Neither TARP_2–9 nor TARP_22–30 showed any measurable binding affinity to HLA-A2 molecules. The theoretical half-life of peptide binding to HLA-A2 molecules was also predicted by running the software program for peptide motif search (31) , and the results were consistent with the data in Fig. 1C .

View larger version (23K): [in this window] [in a new window] [Download PPT slide]   Fig. 1. Prediction of wild-type HLA-A2 epitopes and their binding affinities to HLA-A2 molecules. A, amino acid sequence of the TARP protein; B, predicted-HLAA2-binding peptides. C, peptides were dissolved in double-distilled water or 20% DMSO in double-distilled water, and then different concentrations of peptides were added into the culture of TAP-deficient T2 cells. After overnight culture of the cells in medium supplemented with ß2-microglobulin, cells were stained with anti-HLA-A2. Each assay was performed in triplicate, and data in this figure are representative of two experiments with similar results.

View larger version (44K): [in this window] [in a new window] [Download PPT slide]   Fig. 2. Immunization with peptide-loaded dendritic cells (DCs) or a DNA plasmid expressing TARP results in peptide-specific CD8+ T-cell responses in A2Kb transgenic mice. A, mice were immunized s.c. with peptide-loaded (10 µM TARP29–37 or TARP27–35) bone marrow-derived DCs and boosted twice at 3-week intervals. B, mice were immunized with 100 µg of DNA plasmid i.m. and boosted four times at 3-week intervals. For both A and B, 3 weeks after the final immunization, spleen CD8+ T cells were restimulated with splenocytes in media containing 10 µM soluble peptides for 7 days. In a 5-h 51Cr release assay, Jurkat cells transfected with HLA-A2 were labeled with 51Cr and then pulsed with 10 µM peptides. Without washing, target cells were mixed with different numbers of effector cells for 5 h before harvesting. C, for intracellular cytokine staining, CD8+ T cells from the mice immunized with peptide-pulsed DCs were stimulated with the identical peptide and treated with brefeldin A for 5 h, and then cells were stained with anti-CD8-FITC and IFN--PE as described in the manufacturer’s protocol (PharMingen). In each experiment, pooled spleen CD8+ T cells of three mice were tested. Data are representative of two repeated experiments with similar results (SE < 10%).

View larger version (27K): [in this window] [in a new window] [Download PPT slide]   Fig. 3. HLA-A2 epitope enhancement by amino acid substitutions in the wild-type peptides. A, amino acid sequences of predicted enhanced epitopes. B and C, binding affinity of the substituted TARP27–35 peptides (B) or the substituted TARP29–37 peptides (C) to HLA-A2 molecules. Peptides were dissolved in double-distilled water or 20% DMSO, and then different concentrations of peptides were added into the culture of TAP-deficient T2 cells. After overnight culture of the cells in medium supplemented with ß2-microglobulin, cells were stained with anti-HLA-A2. Each assay was performed in triplicate, and data in this figure are representative of two experiments with similar results.

View larger version (49K): [in this window] [in a new window] [Download PPT slide]   Fig. 4. Immunogenicity of the enhanced epitopes in A2Kb transgenic mice. A2Kb transgenic mice were immunized s.c. with a mixture of peptide and cytokine in adjuvant as described in "Materials and Methods." A, 2 weeks after the second boost, pooled spleen CD8+ T cells from three to four mice were restimulated with 1.0 µM each peptide. During restimulation, CD8+ T cells were treated with brefeldin A for 5 h. Cells were stained with anti-CD8-FITC and IFN--PE as described in the manufacturer’s protocol (PharMingen). B, cross-reactivity on each peptide (E:T = 100:1). Two weeks after the second boost, pooled spleen CD8+ T cells from three to four mice were restimulated with irradiated splenocytes in medium containing 1.0 µM each peptide for 7 days. In a 5-h 51Cr release assay, Jurkat cells transfected with HLA-A2 were labeled with 51Cr and then pulsed with peptides. Without washing, target cells were mixed with different numbers of effector cells and then cultured for 5 h before harvesting. C, CTLs raised against the individual peptides indicated were tested on target cells pulsed with either wild-type TARP29–37 (closed symbols) or no peptide (open symbols). Lytic activity is shown as a function of E:T ratio. Bars represent SE in triplicate assay, and bars smaller than the symbols are not shown. D, relationship between peptide binding affinity and immunogenicity of each peptide. Peptide concentrations for fluorescence index value = 0.5 (FI50) from Fig. 3 were plotted versus the numbers of IFN--producing cells (A). Data were reproducible in two repeated experiments with similar results.

View larger version (28K): [in this window] [in a new window] [Download PPT slide]   Fig. 5. Human CD8+ CTLs raised by in vitro stimulation kill peptide-loaded target cells. CD8+ T cells from a prostate cancer patient were restimulated with 10 µM peptide-pulsed autologous dendritic cells (DCs). DCs were derived from the culture of autologous monocytes in granulocyte macrophage colony-stimulating factor and interleukin 4. To mature the DCs, CD40 ligand (2 µg/ml) was added on day 4, and then cells were further cultured for 2–3 days before loading peptides. After several cycles of in vitro restimulation, CD8+ T cells were used as effector cells. A, cells were stained with anti-CD8 or isotype control antibody. B, in 5-h 51Cr release assay, C1R-A2.1 cells were labeled with 51Cr and then pulsed with peptides. Closed and open circles represent target cells pulsed with and without peptides, respectively. Data are representative of two repeated experiments with similar results.

View larger version (29K): [in this window] [in a new window] [Download PPT slide]   Fig. 6. Cross-reactivity of human CD8+ CTLs to different HLA-A2 peptide epitopes. Human CD8+ CTLs were raised as described in the Fig. 5 legend. A, in a 5-h 51Cr release assay, C1R-A2.01 cells were labeled with 51Cr and then pulsed with 10 µM peptides. B, specificity and avidity of CD8+ T cells specific for TARP29–37-9V to other peptides were tested by using target cells pulsed with different concentrations of the indicated peptides. Data are representative of two repeated experiments with similar results.

View larger version (41K): [in this window] [in a new window] [Download PPT slide]   Fig. 7. Human CD8+ CTLs raised by in vitro restimulation kill human cancer cell line. A, in a 5-h 51Cr release assay, LNCaP (prostate cancer cell line; HLA-A2+TARP+), MCF-7 (breast cancer cell line; HLA-A2+TARP+), DU145 [prostate cancer cell line; HLA-A2–TARP–), and PC3-TARP (prostate cancer cell line transfected with TARP; HLA-A2–TARP+) were used as target cells. Target cells were preincubated with 1000 ng/ml human IFN- for 72 h. Data are representative of two repeated experiments with similar results, and error bars (SEM) were calculated from a triplicate assay in one experiment. B, tumor cell lines were stained with anti-HLA-A2 after incubation with or without IFN- for 72 h.

	DISCUSSION

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TARP is a newly found protein expressed in both breast and prostate cancer specimens tested. In this study, we first report that human CD8 T cells from a prostate cancer patient specific for peptides derived from TARP kill a human breast cancer cell line (13 , 25) . Therefore, TARP could be used as a target protein for vaccine immunotherapy for both prostate and breast cancer, and TARP peptides described here may serve as an effective cancer vaccine in the nearly half of the population that is HLA-A2⁺.

In this study, we have examined the potential of this new protein as an antigen for the immunotherapy of prostate or breast cancer patients and defined peptide immunogens that were enhanced by sequence modification. A first step for developing a vaccine that could induce CD8⁺ T cell-mediated immunity, a critical immune arm for cancer immunotherapy, is to identify CD8⁺ T-cell epitopes that can induce immune responses and serve as targets for lysis of tumor cells. To find HLA-A2 epitopes from the TARP protein, 8- or 9-mer peptides were predicted based on amino acid anchor residues that determine binding to HLA-A2 molecules (33, 34, 35) . TARP is composed of 58 amino acid residues and contains several hydrophobic amino acids including five leucines, but data from the T2 binding assay showed that only 2 wild-type peptides (TARP_29–37 and TARP_27–35) had a measurable binding affinity to HLA-A2 molecules. Seven of nine amino acids in both wild-type peptides overlap. Moreover, they both share two amino acids at corresponding positions, Phe at position 1 and Leu at position 9, although the residue at position 1 is not a primary anchor residue. However, TARP_27–35 showed a better binding affinity than TARP_29–37, probably because of other residues in nonanchor positions, such as Phe at position 3 in TARP_27–35. Although the other two wild-type peptides, TARP_2–9 and TARP_22–30, possess Leu at position 9 and Met or Leu at position 2, respectively, neither showed a measurable binding affinity to HLA-A2 molecules, suggesting that primary anchor residues alone are not sufficient to determine the binding affinity of peptides (33 , 35) . One may speculate that the large number of Pro residues affected the conformation of TARP_2–9 and that the Glu at position 3 may have interfered with binding of TARP_22–30. Although epitope enhancement by replacing the Glu in TARP_22–30 might have improved binding, if the wild-type binding is too weak to serve as a good target for CTLs raised against the enhanced peptide, such an enhanced peptide would not be useful.

When the wild-type peptide does bind, but perhaps not optimally, one strategy to improve the usage of self-peptides such as TARP_29–37 and TARP_27–35 is to develop enhanced epitopes that are potentially more immunogenic. Substitution of Arg at position 3 with Ala in TARP_29–37 greatly improved the peptide binding affinity to the HLA-A2 molecules. This could be explained by an adverse effect of Arg at position 3 reducing the affinity. Substitution of Leu at position 9 with Val in TARP_29–37 also resulted in increased binding affinity, and this is consistent with other reports on HLA-A2-binding peptides (33 , 35) . We have also tried to define enhanced epitopes for TARP_27–35 by substitutions for Val at position 2, Phe at position 3, and Leu at position 9 with Leu, Ala, and Val, respectively, but those substitutions did not improve the affinity. Amino acid residues associated with poor binding to HLA-A2 are Asp, Glu, and Pro at position 1; Asp and Glu at position 3; Arg, Lys, His, and Ala at position 4; Pro at position 5; Arg, Lys, and His at position 7; Asp, Glu, Arg, Lys, and His at position 8; and Arg, Lys, and His at position 9 (33 , 35) . Both TARP_27–35 and TARP_29–37 do not have any residue known to be associated with poor HLA-A2 binding at the secondary anchor positions. In contrast, as noted, the low binding affinity of the wild-type peptides, TARP_2–9 and TARP_22–30, is probably due to the Pro at position 5 and Glu at position 3, respectively.

Immunogenicities of the wild-type and enhanced peptides were compared by using A2K^b transgenic mice. The immunogenicity of each peptide was largely dependent on its affinity for HLA-A2 molecules (Fig. 4D) . Our data from the DNA immunization experiments indicate that the murine antigen processing system is not a limitation for production of peptides presented by human class I molecules. Moreover, data from our laboratory and others suggest that such HLA-transgenic mice can be used for the study of peptides recognized by CD8⁺ T cells specific for HLA-A2/peptide complex (36, 37, 38, 39, 40) . Another concern for using transgenic mice is that peptide/HLA-A2 complexes recognized by murine T cells may be different from those recognized by human T cells, explaining why the cross-reactivity of CD8⁺ T cells from mouse and human was not exactly the same. It is possible that those species differences may be due to different TCR repertoires. However, our data showed that both wild-type and enhanced epitopes resulted in the induction of peptide-specific CD8 T cells in HLA-A2 transgenic mice, and therefore these mice can be used as good predictors of human T-cell epitopes (36) .

CD8⁺ CTLs typically express clonally distributed TCRs that possess exquisite specificity for a particular MHC/peptide complex. In both mice and humans, however, CD8⁺ T cells raised with individual peptides can recognize a range of cross-reactive peptide/MHC complexes, depending on the individual CD8⁺ CTLs and peptides. The cross-reactivity observed in this study not only among variants of one peptide but between the two wild-type peptides may be explained by the fact that the two wild-type peptides overlap by seven amino acid residues. A number of recent studies have shown degenerate recognition of MHC/peptide complexes by individual TCRs: examples range from T-cell recognition of dissimilar peptides presented by the same MHC molecules to recognition of identical peptides bound to different MHC molecules (41, 42, 43, 44, 45) . For example, CD8⁺ T cells specific for one peptide of polyoma virus recognize another epitope that has no sequence homology (46) . However, those CD8⁺ T cells require a much higher concentration of the alternative peptide for recognition.

In the cross-reactivity test for human and CD8⁺ T cells, CD8⁺ T cells specific for TARP_29–37 could recognize all four peptide/MHC complexes. However, CD8⁺ T cells specific for TARP_27–35 or TARP_29–37-3A did not recognize other peptides as much as they did the immunogens. Of the enhanced peptides, only CTLs specific for TARP_29–37-9V could recognize the wild-type peptide, TARP_29–37, to a similar degree to the immunogen. In consideration of choosing peptides for immunotherapy, either TARP_29–37-9V or TARP_27–35 will likely be more useful than the other two peptides. Although TARP_29–37-3A showed the highest binding affinity and resulted in high CD8⁺ T-cell responses in transgenic mice (Fig. 4D) , CD8⁺ T cells specific for this peptide did not recognize wild-type peptide very well in the human and showed weak cross-reactivity to wild-type peptide in the mice. Most importantly for tumor killing assay, CD8⁺ T cells specific for TARP_29–37-3A showed a significant range of specific lysis only at a 100:1 E:T ratio (data not shown). At a 50:1 E:T ratio, CD8⁺ T cells specific for TARP_29–37-3A showed much lower lytic activity against tumor cells than CTLs to TARP_29–37-9V. In contrast, TARP_29–37-9V induced a higher level of CD8⁺ T-cell responses than TARP_29–37, and CD8⁺ T cells specific for TARP_29–37-9V could recognize the wild-type peptide, TARP_29–37, and could kill human tumor cells. CD8⁺ T cells specific for TARP_27–35 could kill human tumor cells as well.

Data from tetramer staining experiments support the presence of peptide-specific CD8⁺ T cells in prostate cancer patients. The frequency of tetramer-positive CD8⁺ T cells detected in this study could be influenced by the binding affinity of peptides, and thus the number in Fig. 8 may represent a lower limit on the frequency of peptide-specific CD8⁺ T cells. However, those data consistently show that a higher number of peptide-specific CD8 T cells is present in the prostate and breast cancer patients than in normal donors studied concurrently. Interestingly, the frequency of tetramer-positive CD8⁺ T cells in prostate cancer patient 1 (Fig. 8) was surprisingly high. It is not clear whether these high levels are related to the stage of tumor progression or to some other mechanism. Data from phenotype analysis of tetramer-positive CD8⁺ T cells also indicated that most CD8⁺ T cells were highly activated. It would be interesting to test the frequency of tetramer-positive CD8⁺ T cells, their functional activities, and phenotype changes over the course of the disease in the future.

Besides vaccines, another approach for immunotherapy using the TARP epitopes is the generation of recombinant antibodies that can recognize TARP/HLA-A2 complexes in a peptide-specific, MHC-restricted manner. This approach was applied recently to a number of tumor- and viral-specific epitopes (30 , 47, 48, 49, 50, 51) . Such antibodies bind with high affinity to the MHC-peptide complex in a TCR-like restricted manner and thus can be used as a targeting moiety to deliver potent toxins or drugs to eliminate a specific cell population that expresses the particular MHC/peptide complex. These antibodies were also used to visualize and quantitate the specific MHC/peptide complex on the surface of tumor cells as well as antigen-presenting cells (47, 48, 49, 50, 51) .

We conclude that the peptides TARP_27–35 and TARP_29–37-9V can potentially be used for several immunotherapeutic strategies, including immunotoxins and vaccines, whether in adjuvant or as peptide-pulsed DCs, for prostate and breast cancer patients who are positive for the HLA-A2 allele. Given that HLA-A2 is present in nearly half of the population of North America, as well as much of the world, and that the expression of TARP is common in prostate and breast cancers, a vaccine containing or expressing these peptides may be effective in a sizable fraction of prostate and breast cancer patients. If such an approach is successful in HLA-A2⁺ patients as prototype, it will provide motivation to define TARP epitopes presented by other common HLA class I alleles that could broaden the coverage. Such a vaccine may also be used in combination with other antigens for prostate or breast cancer to enhance the efficacy of vaccine therapy. To enhance CD8⁺ T-cell-mediated immune responses, recombinant vectors including adenovirus or vaccinia virus expressing those antigens can also be used. Definition of novel tumor antigens such as TARP may provide new opportunities to harness the exquisite specificity of the immune system to fight cancer.

	ACKNOWLEDGMENTS

 
We thank Drs. Jeffrey Schlom and Kwong Yok Tsang for critical reading of the manuscript and helpful suggestions and Lisa Smith for assistance in preparation of the manuscript.

	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.

Requests for reprints: Jay A. Berzofsky, Chief, Vaccine Branch, Center for Cancer Research National Cancer Institute, Building 10–Room 6B-12 (MSC-1578), NIH, Bethesda, Maryland 20892-1578. Phone: (301) 496-6874; Fax: (301) 480-0681; E-mail: berzofsk{at}helix.nih.gov

⁷ A. Bhattacharyya, T. K. Bera, and I. Pastan, unpublished data.

Received 7/18/03. Revised 1/14/04. Accepted 1/29/04.

	REFERENCES

Top ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 

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