FcγRIIB is a T cell checkpoint in antitumor immunity
Clara R. Farley, Anna B. Morris, Marvi Tariq, Kelsey B. Bennion, Sayalee Potdar, Ragini Kudchadkar, Michael C. Lowe, Mandy L. Ford
Clara R. Farley, Anna B. Morris, Marvi Tariq, Kelsey B. Bennion, Sayalee Potdar, Ragini Kudchadkar, Michael C. Lowe, Mandy L. Ford
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Research Article Immunology Oncology

FcγRIIB is a T cell checkpoint in antitumor immunity

Abstract

In the setting of cancer, T cells upregulate coinhibitory molecules that attenuate TCR signaling and lead to the loss of proliferative capacity and effector function. Checkpoint inhibitors currently in clinical use have dramatically improved mortality from melanoma yet are not effective in all patients, suggesting that additional pathways may contribute to suppression of tumor-specific CD8+ T cell responses in melanoma. Here, we show that FcγRIIB, an inhibitory Fc receptor previously thought to be exclusively expressed on B cells and innate immune cells, is upregulated on tumor-infiltrating effector CD8+ T cells in an experimental melanoma model and expressed on CD8+ T cells in patients with melanoma. Genetic deficiency of Fcgr2b resulted in enhanced tumor-infiltrating CD8+ T cell responses and significantly reduced tumor burden. Adoptive transfer experiments of Fcgr2b–/– tumor antigen-specific T cells into FcγRIIB-sufficient hosts resulted in an increased frequency of tumor-infiltrating CD8+ T cells with greater effector function. Finally, FcγRIIB was expressed on CD8+ memory T cells isolated from patients with melanoma. These data illuminate a cell-intrinsic role for the FcγRIIB checkpoint in suppressing tumor-infiltrating CD8+ T cells.

Authors

Clara R. Farley, Anna B. Morris, Marvi Tariq, Kelsey B. Bennion, Sayalee Potdar, Ragini Kudchadkar, Michael C. Lowe, Mandy L. Ford

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Figure 3

Fcgr2b–/– mice have an improved antitumor response compared with WT mice.

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Fcgr2b–/– mice have an improved antitumor response compared with WT mic...
(A) Schematic of experimental design: 106 B16-OVA melanoma cells were subcutaneously injected into the right flank of C57BL/6 (WT) and Fcgr2b–/– mice on day 0. Spleen, dLN, and tumor were harvested on day 14. (B) Representative pictures of tumor growth in WT and Fcgr2b–/– mice. (C) Tumor volume in WT and Fcgr2b–/–mice. (D) Representative flow cytometry plots of tumor-infiltrating CD8+ T cells in WT and Fcgr2b–/– mice. (E) Summary data of CD8+ T cells within the tumor of WT and Fcgr2b–/– mice. (F) Differences in CD44loCD62Lhi (naive), CD44hiCD62Lhi (central memory), and CD44hiCD62Llo (effector memory) T cell populations in the tumor of WT Fcgr2b–/– (KO) mice, represented in mean. (G) Summary data of the frequency of CD44hiCD62Llo cells of the CD8+ T cell population in the dLN, spleen, and tumor. (H) Representative flow plots of CD8+ double cytokine producers (IFN-γ+TNF+) in the dLN, spleen, and tumor of WT and Fcgr2b–/– mice. (I) Summary data of double cytokine producers (IFN-γ+TNF+) in the dLN, spleen, and tumor as shown in H. Data shown are representative of 2 independent experiments; n = 4–6 mice/group/experiment. Mann-Whitney U test, *P < 0.05, ***P < 0.001, ****P < 0.0001. dLN, draining lymph node.