Twelve-year survival and immune correlates in dendritic cell–vaccinated melanoma patients
Stefanie Gross, … , Gerold Schuler, Beatrice Schuler-Thurner
Stefanie Gross, … , Gerold Schuler, Beatrice Schuler-Thurner
Published April 20, 2017
Citation Information: JCI Insight. 2017;2(8):e91438. https://doi.org/10.1172/jci.insight.91438.
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Clinical Research and Public Health Clinical trials Vaccines

Twelve-year survival and immune correlates in dendritic cell–vaccinated melanoma patients

Abstract

Background. Reports on long-term (≥10 years) effects of cancer vaccines are missing. Therefore, in 2002, we initiated a phase I/II trial in cutaneous melanoma patients to further explore the immunogenicity of our DC vaccine and to establish its long-term toxicity and clinical benefit after a planned 10-year followup.

Methods. Monocyte-derived DCs matured by TNFα, IL-1β, IL-6, and PGE2 and then loaded with 4 HLA class I and 6 class II–restricted tumor peptides were injected intradermally in high doses over 2 years. We performed serial immunomonitoring in all 53 evaluable patients.

Results. Vaccine-specific immune responses including high-affinity, IFNγ-producing CD4+ and lytic polyfunctional CD8+ T cells were de novo induced or boosted in most patients. Exposure of mature DCs to trimeric soluble CD40 ligand, unexpectedly, did not further enhance such immune responses, while keyhole limpet hemocyanin (KLH) pulsing to provide unspecific CD4+ help promoted CD8+ T cell responses — notably, their longevity. An unexpected 19% of nonresectable metastatic melanoma patients are still alive after 11 years, a survival rate similar to that observed in ipilimumab-treated patients and achieved without any major (>grade 2) toxicity. Survival correlated significantly with the development of intense vaccine injection site reactions, and with blood eosinophilia after the first series of vaccinations, suggesting that prolonged survival was a consequence of DC vaccination.

Conclusions. Long-term survival in advanced melanoma patients undergoing DC vaccination is similar to ipilimumab-treated patients and occurs upon induction of tumor-specific T cells, blood eosinophilia, and strong vaccine injection site reactions occurring after the initial vaccinations.

TRIAL REGISTRATION. ClinicalTrials.gov NCT00053391.

FUNDING. European Community, Sixth Framework Programme (Cancerimmunotherapy LSHC-CT-2006-518234; DC-THERA LSHB-CT-2004-512074), and German Research Foundation (CRC 643, C1, Z2).

Authors

Stefanie Gross, Michael Erdmann, Ina Haendle, Steve Voland, Thomas Berger, Erwin Schultz, Erwin Strasser, Peter Dankerl, Rolf Janka, Stefan Schliep, Lucie Heinzerling, Karl Sotlar, Pierre Coulie, Gerold Schuler, Beatrice Schuler-Thurner

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Figure 3

Ex vivo cell analysis.

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Ex vivo cell analysis. (A) Ex vivo multiplexed tetramer stainings were p...
(A) Ex vivo multiplexed tetramer stainings were performed in 49 patients. Ex vivo–detectable frequencies of vaccine-specific CD8+ T cells are shown as % of total CD8+ T cells. Note the logarithmic scaling. Values below the detection limit are shown with gray background. Black lines and dots represent patients with a response that met the response definition criteria (at least 10 events in the tetramer gate and at least 0.01% of CD8+ T cells). For statistical analysis, a ratio-based 2-tailed paired t test with 95% confidence level was used. (B) Downregulation of CD45RA in ex vivo–detectable vaccine-specific T cells in comparison with virus-specific and total CD8+ T cells each before and after vaccination is shown as box plots of CD45RA mean fluorescence intensity (MFI) means with 95% CI. (C) Ex vivo class II tetramer staining (Tyro-DR4) is shown for patients 07, 50, and 62 at leukapheresis time points in combination with staining for FoxP3 and CD127. In the right panel, total CD4+ T cells are overlayed with tetramer-positive CD4+ T cells (red).