An effective mouse model for adoptive cancer immunotherapy targeting neoantigens
Ken-ichi Hanada, Zhiya Yu, Gabrielle R. Chappell, Adam S. Park, Nicholas P. Restifo
Ken-ichi Hanada, Zhiya Yu, Gabrielle R. Chappell, Adam S. Park, Nicholas P. Restifo
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Resource and Technical Advance Immunology Vaccines

An effective mouse model for adoptive cancer immunotherapy targeting neoantigens

Abstract

The adoptive cell transfer (ACT) of T cells targeting mutated neoantigens can cause objective responses in varieties of metastatic cancers, but the development of new T cell–based treatments relies on accurate animal models. To investigate the therapeutic effect of targeting a neoantigen with ACT, we used T cells from pmel-1 T cell receptor–transgenic mice, known to recognize a WT peptide, gp100, and a mutated version of the peptide that has higher avidity. We gene-engineered B16 cells to express the WT or mutated gp100 epitopes and found that pmel-1–specific T cells targeting a neoantigen tumor target augmented recognition as measured by IFN-γ production. Neoantigen expression by B16 also enhanced the capacity of pmel-1 T cells to trigger the complete and durable regression of large, established, vascularized tumor and required less lymphodepleting conditioning. Targeting neoantigen uncovered the possibility of using enforced expression of the IL-2Rα chain (CD25) in mutation-reactive CD8+ T cells to improve their antitumor functionality. These data reveal that targeting of “mutated-self” neoantigens may lead to improved efficacy and reduced toxicities of T cell–based cellular immunotherapies for patients with cancer.

Authors

Ken-ichi Hanada, Zhiya Yu, Gabrielle R. Chappell, Adam S. Park, Nicholas P. Restifo

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Figure 2

Treatment of modified B16 tumor with adoptively transferred pmel-1 T cells.

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Treatment of modified B16 tumor with adoptively transferred pmel-1 T cel...
(A) Tumor treatment scheme. (B) Post-ACT tumor growth curve. Open circles represent mice receiving only irradiation and rhIL-2. Gray circles represent mice treated with 1 × 106 pmel-1 T cells in addition to radiation and rhIL-2. Red circles represent mice treated with 1 × 106 pmel-1 T cells and rVVhgp100 vaccine in addition to irradiation and rhIL-2. Four to five mice were included in each group. The results represent 1 of 3 independent experiments. Error bars indicate the mean ± SEM. *P < 0.05 and NS indicates no significant differences by Wilcoxon rank-sum test in comparison of tumor growth curve slopes between correspondent groups. (C) Effects of antigen cross-presentation. Tumor injection and irradiation were done as outlined in the scheme in A. Tumor-bearing C57BL/6 mice (black circles) or β2mKO mice (gray circles) were treated with a regimen of either rhIL-2 alone, rhIL-2 and 1 × 106 pmel-1 T cells, or rhIL-2, 1 × 106 pmel-1 T cells, and rVVhgp100 vaccination. Four to five mice were included in each group. The results represent 1 experiment. Error bars indicate the mean ± SEM. *P < 0.05 and NS indicates no significant differences by Wilcoxon rank-sum test in comparison of tumor growth curve slopes between WT and β2mKO mice.