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 5

Human CD8+ T cells express FcγRIIB.

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Human CD8+ T cells express FcγRIIB. PBMCs were obtained from healthy sub...
PBMCs were obtained from healthy subjects or patients with stage IV melanoma after informed consent and analyzed directly ex vivo. (A) Representative flow plots of FcγRIIB expression (clone FLI8.26) on CD3+CD8+ T cells compared with FMO and CD19+ B cells (positive control). Gating strategy for FcγRIIB comprises gating on singlets, lymphocytes, and live CD3+ T cells while excluding CD14+, CD19+, and dead cells. (B) Summary of the frequency of FcγRIIB+ CD8+ T cells in healthy subjects and patients with melanoma. (C) Representative flow plots showing FcγRIIB expression across the following CD3+CD8+ T cells subsets in healthy donors: naive (Tn), central memory (Tcm), effector memory (Tem), and effector memory expressing CD45RA (Temra). (D) Summary of the frequency of FcγRIIB+ CD8+ T cells across the Tn, Tcm, Tem, and Temra subsets in healthy donors. (E) Representative flow plots showing FcγRIIB expression across the Tn, Tcm, Tem, and Temra CD3+CD8+ T cell subsets in stage 4 treatment-naive patients with melanoma. (F) Summary of the frequency of FcγRIIB+ cells across the Tn, Tcm, Tem, and Temra CD3+CD8+ T cell subsets in patients with melanoma. (G) Summary of the frequency of the Tn, Tcm, Tem, and Temra CD3+CD8+ T cells subsets in healthy donors and patients with melanoma. (H) Summary of the frequency of FcγRIIB expression of the Tn, Tcm, Tem, and Temra CD3+CD8+ T cell subsets in healthy donors and patients with melanoma. Data are representative of one experiment with n = 5 people per group. One-way ANOVA with multiple comparisons was used to compare more than 2 groups; Mann-Whitney U nonparametric, unpaired test was used to compare 2 groups. Error bar denotes mean ± SEM. *P < 0.05. FMO, fluorescence minus one.