Breast cancer–derived GM-CSF regulates arginase 1 in myeloid cells to promote an immunosuppressive microenvironment
Xinming Su, … , Samuel Achilefu, Katherine N. Weilbaecher
Xinming Su, … , Samuel Achilefu, Katherine N. Weilbaecher
Published September 14, 2021
Citation Information: J Clin Invest. 2021;131(20):e145296. https://doi.org/10.1172/JCI145296.
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Research Article Immunology Oncology

Breast cancer–derived GM-CSF regulates arginase 1 in myeloid cells to promote an immunosuppressive microenvironment

Abstract

Tumor-infiltrating myeloid cells contribute to the development of the immunosuppressive tumor microenvironment. Myeloid cell expression of arginase 1 (ARG1) promotes a protumor phenotype by inhibiting T cell function and depleting extracellular l-arginine, but the mechanism underlying this expression, especially in breast cancer, is poorly understood. In breast cancer clinical samples and in our mouse models, we identified tumor-derived GM-CSF as the primary regulator of myeloid cell ARG1 expression and local immune suppression through a gene-KO screen of breast tumor cell–produced factors. The induction of myeloid cell ARG1 required GM-CSF and a low pH environment. GM-CSF signaling through STAT3 and p38 MAPK and acid signaling through cAMP were required to activate myeloid cell ARG1 expression in a STAT6-independent manner. Importantly, breast tumor cell–derived GM-CSF promoted tumor progression by inhibiting host antitumor immunity, driving a significant accumulation of ARG1-expressing myeloid cells compared with lung and melanoma tumors with minimal GM-CSF expression. Blockade of tumoral GM-CSF enhanced the efficacy of tumor-specific adoptive T cell therapy and immune checkpoint blockade. Taken together, we show that breast tumor cell–derived GM-CSF contributes to the development of the immunosuppressive breast cancer microenvironment by regulating myeloid cell ARG1 expression and can be targeted to enhance breast cancer immunotherapy.

Authors

Xinming Su, Yalin Xu, Gregory C. Fox, Jingyu Xiang, Kristin A. Kwakwa, Jennifer L. Davis, Jad I. Belle, Wen-Chih Lee, Wing H. Wong, Francesca Fontana, Leonel F. Hernandez-Aya, Takayuki Kobayashi, Helen M. Tomasson, Junyi Su, Suzanne J. Bakewell, Sheila A. Stewart, Christopher Egbulefu, Partha Karmakar, Melisa A. Meyer, Deborah J. Veis, David G. DeNardo, Gregory M. Lanza, Samuel Achilefu, Katherine N. Weilbaecher

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Figure 4

GM-CSF and LA synergistically induce myeloid cell ARG1 expression.

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GM-CSF and LA synergistically induce myeloid cell ARG1 expression. (A) A...
(A) Arg1 mRNA expression in BMMs treated with recombinant GM-CSF or PyMT-BO1 tumor cell CM (n = 2–3). (B) FACS quantification of ARG1+ cells from YARG BMMs treated with recombinant GM-CSF or PyMT-BO1 tumor cell CM. (C) Arg1 mRNA expression in BMMs treated with tumor cell CM plus recombinant GM-CSF (n = 2–3). (D) Quantification of lactate from tumor cell CM. (E) Arg1 mRNA expression in BMMs treated with recombinant GM-CSF and LA. (F) ARG1+ cells quantified by FACS. (G) ARG1 expression in BMMs was detected by Western blotting after GM-CSF and LA treatment. (H) Lactate production from tumor cell CM (n = 3). (I) Tumor cell CM pH measurement (n = 3). (J) Arg1 mRNA expression in BMMs (n = 3). (K) ARG1+ cells quantified by FACS. (L) YARG BMMs were treated with GM-CSF. The media pH was adjusted with hydrochloric acid. (M) BO1 tumor CM were premixed with NaHCO3 at the indicated concentrations before being added to YARG BMMs. In B, F, G, and KM, data are representative of 3 independent experiments. Data are shown as the mean ± SEM. *P < 0.05, **P < 0.01, ***P < 0.001, and ****P < 0.0001, by 2-tailed, unpaired Student’s t test with Welch’s correction. SSC-H, side scatter height.