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 5

Application of neoantigen model to discover enhanced antitumor functions of ACT.

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Application of neoantigen model to discover enhanced antitumor functions...
(A) FACS plots of pmel-1 cells transduced with MSGV1-IL2Ra or mock retrovirus. (B) Post-ACT tumor growth curve. C57BL/6 mice were injected with 5 × 105 B16, B16EGS, or B16KVP subcutaneously. Five Grays irradiation was applied to the mice on day 10, and ACT was given on day 11. All mice were given 180,000 IU of rhIL-2 after ACT for 3 days. In each tumor setting, 5 mice were included in groups receiving PBS (open circles), 1 × 106 mock-transduced pmel-1 cells (black circles), or 1 × 106 CD25-transduced pmel-1 cells (red circles). Error bars indicate the mean ± SEM. *P < 0.05 by Wilcoxon rank-sum test in comparison of tumor growth curve slopes between groups transferring with CD25- and mock-transduced pmel-1 T cells. NS, no significant differences. The results represent 1 of 2 independent experiments.