Lung adenocarcinoma–derived IFN-γ promotes growth by modulating CD8+ T cell production of CCR5 chemokines
Christina Kratzmeier, Mojtaba Taheri, Zhongcheng Mei, Isabelle Lim, May A. Khalil, Brandon Carter-Cooper, Rachel E. Fanaroff, Chin Siang Ong, Eric B. Schneider, Stephanie Chang, Erica Leyder, Dongge Li, Irina G. Luzina, Anirban Banerjee, Alexander Sasha Krupnick
Christina Kratzmeier, Mojtaba Taheri, Zhongcheng Mei, Isabelle Lim, May A. Khalil, Brandon Carter-Cooper, Rachel E. Fanaroff, Chin Siang Ong, Eric B. Schneider, Stephanie Chang, Erica Leyder, Dongge Li, Irina G. Luzina, Anirban Banerjee, Alexander Sasha Krupnick
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Research Article Cell biology Immunology Oncology

Lung adenocarcinoma–derived IFN-γ promotes growth by modulating CD8+ T cell production of CCR5 chemokines

Abstract

Because the lung is a mucosal barrier organ with a unique immunologic environment, mechanisms of immunoregulation in lung cancer may differ from those of other malignancies. Consistent with this notion, we found that CD8+ T cells played a paradoxical role in facilitating, rather than ameliorating, the growth of multiple lung adenocarcinoma models. These included spontaneous, carcinogen-induced, and transplantable tumor cell line models. Specifically, we found that CD8+ T cells promoted homing of CD4+Foxp3+ Tregs to the tumor bed by increasing the levels of CCR5 chemokines in the tumor microenvironment in an IFN-γ– and TNF-α–dependent manner. Contrary to their canonical role, these Th1 cytokines contributed to accelerated growth of murine lung adenocarcinomas, while suppressing the growth of other malignancies. Surprisingly, lung cancer cells themselves can serve as a dominant source of IFN-γ, and deletion of this cytokine from cancer cells using CRISPR/Cas9 decreases tumor growth. Importantly for translational applications, in patients with lung cancer, a high level of IFN-γ was also found at both the mRNA and protein levels. Our data outline what we deem a novel and previously undefined lung cancer–specific immunoregulatory pathway that may be harnessed to tailor immune-based therapy specifically for this malignancy.

Authors

Christina Kratzmeier, Mojtaba Taheri, Zhongcheng Mei, Isabelle Lim, May A. Khalil, Brandon Carter-Cooper, Rachel E. Fanaroff, Chin Siang Ong, Eric B. Schneider, Stephanie Chang, Erica Leyder, Dongge Li, Irina G. Luzina, Anirban Banerjee, Alexander Sasha Krupnick

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Figure 1

CD8+ T cells accelerate lung adenocarcinoma growth.

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CD8+ T cells accelerate lung adenocarcinoma growth. (A) Number of tumors...
(A) Number of tumors visible in the lungs of Kras G12D mice at age 12 weeks with and without CD8 depletion. Histological micrographs (original magnification, ×0.5 [low-power] and ×20 [high-power]) of lungs are below the graph, with arrows pointing to tumor foci (H&E staining). n = 14 per group. (B) Lung weights of i.v. injected LLC lung cancer and B16 melanoma cell lines in B6 versus B6CD8dep mice. Micrographs of lungs are shown above the graph (n = 10 per group of LLC; n = 8 per group of B16). (C) Tumor growth curves in B6 and B6CD8dep bearing subcutaneously injected non–lung tumor cell lines including EG7 lymphoma, B16-F10 melanoma, MC38 colon cancer, and CT26 colon cancer. (D) Tumor growth curves in B6 and B6CD8 dep mice bearing subcutaneously injected lung tumor cell lines including LLC, CMT64 lung cancer, and LKR13 lung cancer. Statistical analysis used Student’s unpaired, 2-tailed t test with Welch’s correction. *P < 0.05, **P < 0.01, and ***P < 0.001. NS = P > 0.05. Data represent the mean ± SEM.