Helper T-Cell Responses and Clinical Activity of a Melanoma Vaccine With Multiple Peptides From MAGE and Melanocytic Differentiation Antigens

Slingluff, Craig L.; Petroni, Gina R.; Olson, Walter C.; Czarkowski, Andrea; Grosh, William W.; Smolkin, Mark E.; Chianese‐Bullock, Kimberly A.; Neese, Patrice Y.; Deacon, Donna H.; Nail, Carmel J.; Merrill, Priscilla; Fink, Robyn; Patterson, James W.; Rehm, Patrice K.

doi:10.1200/jco.2008.17.3161

Cited by 106 publications

(119 citation statements)

References 15 publications

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“…5A) further suggests this phenotype signature is not unique to naBve T cells. Moreover, between 1% and 10% of all peptide-specific 50 value for all patient lymph nodeT-cell responses was significantly higher than the mean log EC 50 value for PIVR Tcells (C).…”

Section: Resultsmentioning

confidence: 99%

“…Other vaccine strategies such as the incorportation of CD4 + helper T cell coactivation at priming will be required to induce long-term memory CD8 + T cells that are also functionally competent. Recent reports have identified potential class II-restricted peptides from melanocytic proteins such as tyrosinase, Melan-A/MART-1, and gp100, which bind to dominant HLA-DR haplotypes, and stimulate CD4 + T cell proliferation and delayed type hypersensitivity responses in immunized melanoma patients (50). The combination of such potential CD4 + helper T cell -specific antigens with class Irestricted melanoma peptides may result in clinically more effective melanoma vaccines.…”

Section: Cd8mentioning

confidence: 99%

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Characterization of the Class I-Restricted gp100 Melanoma Peptide-stimulated Primary Immune Response in Tumor-Free Vaccine-draining Lymph Nodes and Peripheral Blood

Walker

Miller

Haley

et al. 2009

Clinical Cancer Research

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Purpose: The aim of this study was to characterize the primary gp100 209-2M -specific T-cell response in vaccine-draining, metastases-free lymph nodes and peripheral blood of peptidevaccinated stage I to III melanoma patients. Experimental Design: After two or three gp100 209-2M vaccinations, sentinel lymph nodes that drained both the primary tumor and adjacent vaccine sites were excised concomitant with wide excision of the tumor. Comparative 7-color flow cytometry phenotype analysis was done on gp100 tetramer-positive CD8 + T cells from sentinel lymph nodes, closely proximate timerelated peripheral blood mononuclear cells (PBMC) collected 2 to 4 weeks after sentinel lymph node excision, and on PBMC collected 6 months later after 7 or 11 more immunizations. Lymph node and peripheral blood T cells were tested for proliferative response, functional avidity, and tumor cell^induced CD107 mobilization. Results: The frequencies of gp100-specific CD8 + T cells from time-related PBMC and sentinel lymph nodes were comparable and were similar to those reported for virus-specific memory Tcells.Their respective in vitro proliferation responses were also equivalent but statistically higher than proliferation responses of peripheral blood T cells collected after completion of the entire vaccine regimen. By contrast, functional avidity and CD107 responses were significantly higher in circulating T cells. Sentinel lymph node^derived, gp100-specific CD8 + T cells predominantly expressed central and effector memory phenotype signatures, whereas there were higher frequencies of effectorTcells in the peripheral blood. Conclusion: Priming immunization with gp100 209-2M without coadministration of CD4 + helper Tcell^restricted antigens induced the effective expansion of peptide-specific central and effector memory CD8 + Tcells with high proliferation potential in vaccine-draining lymph nodes of stage I to III melanoma patients. Lymph node memoryTcells gave rise to circulating gp100-specific effectorTcells exhibiting increased functional maturation.

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Section: Resultsmentioning

confidence: 99%

Section: Cd8mentioning

confidence: 99%

Characterization of the Class I-Restricted gp100 Melanoma Peptide-stimulated Primary Immune Response in Tumor-Free Vaccine-draining Lymph Nodes and Peripheral Blood

Walker

Miller

Haley

et al. 2009

Clinical Cancer Research

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“…38 A novel melanoma vaccine comprised of 6 melanoma-associated peptides as antigenic targets for melanoma-reactive T h cells was evaluated for safety and immunogenicity in a phase 1/2 trial. 40 Vaccination with the helper peptide vaccine was well tolerated. Proliferation assays revealed induction of T-cell responses to the melanoma helper peptides in 81% of patients.…”

Section: Clinical Trials Using Polyepitope Long-peptide Vaccinesmentioning

confidence: 99%

A new era in anticancer peptide vaccines

Perez

Hofe

Kallinteris

et al. 2010

Cancer

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The use of synthetic peptides as vaccines aimed at the induction of therapeutic CD8-positive T-cell responses against tumor cells initially experienced great enthusiasm, mostly because of advances in vaccine technology, including design, synthesis, and delivery. However, despite impressive results in animal models, the application of such vaccines in humans has met with only limited success. The therapeutic activity of vaccine-stimulated, tumor-specific, CD8-positive T cells can be hampered through the physical burden of the tumor, tolerance mechanisms, and local factors within the tumor microenvironment. Recently, accumulating evidence has suggested that combining a peptide-based therapeutic vaccination with conventional chemotherapy can uncover the full potential of the antitumor immune response, increasing the success of immunotherapy. In addition, therapeutic vaccination in the preventive setting has been extremely effective in eliciting antitumor responses in preclinical tumor models and has demonstrated good promise clinically in patients with minimal residual disease. The rationale behind preventive vaccination is that patients with minimal tumor burden still have a fully competent immune system capable of developing robust antitumor responses. Finally, therapeutic CD8-positive T-cell peptide vaccines have been improved by coimmunization with T-helper epitopes expressed on long peptides.

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“…þ lymphocyte activation and proliferation), 2,5,6 HLA class II-binding peptides (stimulating CD4 þ lymphocytes), 7,8 or a combination of both HLA class I and II-directed peptides. 9,10 Directly stimulating CD8 þ lymphocytes with HLA class I peptides makes intuitive sense, because class I molecules are present on most nonhematopoietic tumor cells, allowing CD8…”

mentioning

confidence: 99%

Use of booster inoculations to sustain the clinical effect of an adjuvant breast cancer vaccine

Holmes

Clifton

Patil

et al. 2010

Cancer

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BACKGROUND:The authors are conducting clinical trials of the HER-2/neu E75-peptide vaccine in clinically diseasefree breast cancer (BC) patients. Their phase 1-2 trials revealed that the E75 þ granulocyte-macrophage colony-stimulating factor (GM-CSF) vaccine is safe and effective in stimulating clonal expansion of E75-specific CD8 þ T cells.They assessed the need for and response to a booster after completion of primary vaccination series. METHODS: BC patients enrolled in the E75 vaccine trials who were !6 months from completion of their primary vaccination series were offered boosters with E75 þ GM-CSF. Patients were monitored for toxicity. E75-specific CD8 þ T cells were quantified using the human leukocyte antigen-A2:immunoglobulin G dimer before and after boosting. RESULTS: Fiftythree patients received the vaccine booster. Median time from primary vaccination series was 9 months (range, 6-35 months), and median residual E75-specific immunity was 0.70% (range, 0-3.49%) CD8 þ lymphocytes. Elevated residual immunity (ERI) (CD8 þ E75-specific T cells >0.5%) was seen in 94.4% of patients at 6 months from primary vaccination series versus 48% of patients at >6 months (P ¼ .002). The booster was well tolerated, with only grade 1 and 2 toxicity observed. Local reactions were more robust in patients receiving the booster at 6 months from primary vaccination series compared with those at >6 months (99.4 AE 6.1 mm vs 81.8 AE 4.1 mm, P ¼ .01). In patients lacking ERI, 85% had increased ERI after vaccination (P ¼ .0014). CONCLUSIONS: The HER-2/neu E75 peptide vaccine E75 stimulates specific immunity in disease-free BC patients. However, immunity wanes with time. A vaccine booster is safe and effective in stimulating E75-specific immunity in those patients without ERI. These results suggest that the booster may be most effective at 6 months after completion of the primary vaccination series. Peptide-based vaccines are being used in clinical trials either to treat 1,2 or to prevent recurrence of malignancy. 3,4Peptide-based vaccination techniques involve inoculating patients with immunogenic epitopes from tumor-associated antigens, typically given with an immunoadjuvant, to stimulate proliferation of peptide-specific lymphocytes. Peptidespecific lymphocytes then identify and eliminate tumor cells presenting the vaccine-targeted epitope. Peptide-based vaccines are attractive immunotherapeutic options because they have no malignant potential, have low toxicity profiles, are simple and inexpensive, are easily monitored and studied, and eventually will be easily exportable to the community. The individual peptides used in cancer vaccine preparations are often major histocompatibility complex (MHC) class-restricted and human leukocyte antigen (HLA) type-specific, thus stimulating either CD4 þ or CD8 þ lymphocytes and sometimes limiting the applicability of peptides to patients with the correct HLA type. Peptide vaccination techniques

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Helper T-Cell Responses and Clinical Activity of a Melanoma Vaccine With Multiple Peptides From MAGE and Melanocytic Differentiation Antigens

Cited by 106 publications

References 15 publications

Characterization of the Class I-Restricted gp100 Melanoma Peptide-stimulated Primary Immune Response in Tumor-Free Vaccine-draining Lymph Nodes and Peripheral Blood

Characterization of the Class I-Restricted gp100 Melanoma Peptide-stimulated Primary Immune Response in Tumor-Free Vaccine-draining Lymph Nodes and Peripheral Blood

A new era in anticancer peptide vaccines

Use of booster inoculations to sustain the clinical effect of an adjuvant breast cancer vaccine

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