Tumor-specific MHC-II expression drives a unique pattern of resistance to immunotherapy via LAG-3/FCRL6 engagement
Douglas B. Johnson, Mellissa J. Nixon, Yu Wang, Daniel Y. Wang, Emily Castellanos, Monica V. Estrada, Paula I. Ericsson-Gonzalez, Candace H. Cote, Roberto Salgado, Violeta Sanchez, Phillip T. Dean, Susan R. Opalenik, Daniel M. Schreeder, David L. Rimm, Ju Young Kim, Jennifer Bordeaux, Sherene Loi, Leora Horn, Melinda E. Sanders, P. Brent Ferrell Jr., Yaomin Xu, Jeffrey A. Sosman, Randall S. Davis, Justin M. Balko
Douglas B. Johnson, Mellissa J. Nixon, Yu Wang, Daniel Y. Wang, Emily Castellanos, Monica V. Estrada, Paula I. Ericsson-Gonzalez, Candace H. Cote, Roberto Salgado, Violeta Sanchez, Phillip T. Dean, Susan R. Opalenik, Daniel M. Schreeder, David L. Rimm, Ju Young Kim, Jennifer Bordeaux, Sherene Loi, Leora Horn, Melinda E. Sanders, P. Brent Ferrell Jr., Yaomin Xu, Jeffrey A. Sosman, Randall S. Davis, Justin M. Balko
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Research Article Oncology Therapeutics

Tumor-specific MHC-II expression drives a unique pattern of resistance to immunotherapy via LAG-3/FCRL6 engagement

Abstract

Immunotherapies targeting the PD-1 pathway produce durable responses in many cancers, but the tumor-intrinsic factors governing response and resistance are largely unknown. MHC-II expression on tumor cells can predict response to anti–PD-1 therapy. We therefore sought to determine how MHC-II expression by tumor cells promotes PD-1 dependency. Using transcriptional profiling of anti-PD-1–treated patients, we identified unique patterns of immune activation in MHC-II+ tumors. In patients and preclinical models, MHC-II+ tumors recruited CD4+ T cells and developed dependency on PD-1 as well as Lag-3 (an MHC-II inhibitory receptor), which was upregulated in MHC-II+ tumors at acquired resistance to anti–PD-1. Finally, we identify enhanced expression of FCRL6, another MHC-II receptor expressed on NK and T cells, in the microenvironment of MHC-II+ tumors. We ascribe this to what we believe to be a novel inhibitory function of FCRL6 engagement, identifying it as an immunotherapy target. These data suggest a MHC-II–mediated context-dependent mechanism of adaptive resistance to PD-1-targeting immunotherapy.

Authors

Douglas B. Johnson, Mellissa J. Nixon, Yu Wang, Daniel Y. Wang, Emily Castellanos, Monica V. Estrada, Paula I. Ericsson-Gonzalez, Candace H. Cote, Roberto Salgado, Violeta Sanchez, Phillip T. Dean, Susan R. Opalenik, Daniel M. Schreeder, David L. Rimm, Ju Young Kim, Jennifer Bordeaux, Sherene Loi, Leora Horn, Melinda E. Sanders, P. Brent Ferrell Jr., Yaomin Xu, Jeffrey A. Sosman, Randall S. Davis, Justin M. Balko

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Figure 7

Combinatorial activity of PD-1– and Lag-3–neutralizing antibodies in MHC-II+ tumors.

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Combinatorial activity of PD-1– and Lag-3–neutralizing antibodies in MHC...
(A) Schematic of experimental strategy. On day –10, 1 × 106 MMTV-neu cells transduced with pMX-puro or pMX-Ciita were implanted by orthotopic injection in the 4th mammary fat pad of wild-type FVB/n mice. Seven days later, a subset of mice were sacrificed for flow cytometry analysis. On day 0, therapy was initiated consisting of twice weekly i.p. injections of anti-IgG control, anti–PD-1, or anti–PD-1+anti–Lag-3, which continued for 2 weeks. Tumors were monitored for growth over the next 39 days. (B) Schematic for analyzing tumor and lymphoid compartments by flow cytometry. (C) Tumor growth curves for treated mice. CR, complete response. **P < 0.05, χ2 test across treatment groups in Ciita-expressing tumors. (D) Flow cytometry analysis of PD-1+/Lag-3+ lymphocytes by total CD3+ compartment or by CD3+/CD4+ or CD3+ CD8+ compartments in lymphoid tissues at 7 days after injection. **P < 0.01, 2-tailed Mann Whitney U test. (E) Flow cytometry analysis of PD-1+/Lag-3+ lymphocytes in tumors (TILs). *P < 0.05, Mann Whitney U test.