Selective inhibition of mTORC1 in tumor vessels increases antitumor immunity
Shan Wang, Ariel Raybuck, Eileen Shiuan, Sung Hoon Cho, Qingfei Wang, Dana M. Brantley-Sieders, Deanna Edwards, Margaret M. Allaman, James Nathan, Keith T. Wilson, David DeNardo, Siyuan Zhang, Rebecca Cook, Mark Boothby, Jin Chen
Shan Wang, Ariel Raybuck, Eileen Shiuan, Sung Hoon Cho, Qingfei Wang, Dana M. Brantley-Sieders, Deanna Edwards, Margaret M. Allaman, James Nathan, Keith T. Wilson, David DeNardo, Siyuan Zhang, Rebecca Cook, Mark Boothby, Jin Chen
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Research Article Immunology Oncology

Selective inhibition of mTORC1 in tumor vessels increases antitumor immunity

Abstract

A tumor blood vessel is a key regulator of tissue perfusion, immune cell trafficking, cancer metastasis, and therapeutic responsiveness. mTORC1 is a signaling node downstream of multiple angiogenic factors in the endothelium. However, mTORC1 inhibitors have limited efficacy in most solid tumors, in part due to inhibition of immune function at high doses used in oncology patients and compensatory PI3K signaling triggered by mTORC1 inhibition in tumor cells. Here we show that low-dose RAD001/everolimus, an mTORC1 inhibitor, selectively targets mTORC1 signaling in endothelial cells (ECs) without affecting tumor cells or immune cells, resulting in tumor vessel normalization and increased antitumor immunity. Notably, this phenotype was recapitulated upon targeted inducible gene ablation of the mTORC1 component Raptor in tumor ECs (RaptorECKO). Tumors grown in RaptorECKO mice displayed a robust increase in tumor-infiltrating lymphocytes due to GM-CSF–mediated activation of CD103+ dendritic cells and displayed decreased tumor growth and metastasis. GM-CSF neutralization restored tumor growth and metastasis, as did T cell depletion. Importantly, analyses of human tumor data sets support our animal studies. Collectively, these findings demonstrate that endothelial mTORC1 is an actionable target for tumor vessel normalization, which could be leveraged to enhance antitumor immune therapies.

Authors

Shan Wang, Ariel Raybuck, Eileen Shiuan, Sung Hoon Cho, Qingfei Wang, Dana M. Brantley-Sieders, Deanna Edwards, Margaret M. Allaman, James Nathan, Keith T. Wilson, David DeNardo, Siyuan Zhang, Rebecca Cook, Mark Boothby, Jin Chen

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Figure 6

GM-CSF is required for increase in CD103+ DCs and IFN-γ+CD8+ T cells in RaptorECKO tumors.

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GM-CSF is required for increase in CD103+ DCs and IFN-γ+CD8+ T cells in ...
(A) Heatmap showing relative expression levels of indicated chemokines/cytokines in LLC tumors harvested from 6 sex-matched littermate pairs of WT and RaptorECKO mice. Red indicates higher expression while green indicates lower expression in RaptorECKO tumors over WT control. (B) Quantification of GM-CSF expression in RaptorECKO tumors and WT control tumors from Luminex analysis. (C) GM-CSF ELISA on independent LLC tumor lysates to verify elevated GM-CSF expression in RaptorECKO tumors. n = 8 mice per group. (DF) Flow cytometric analysis of CD11b+, CD11b+CD11c+, or CD11c+ immune cells and CD103+ DCs in WT and RaptorECKO tumors from the LLC model (D) and PyMT model (E) or in LLC-HRE-mCherry-OVA tumors treated with low-dose RAD001 (F). (G) Schematic diagram showing the experimental procedure with GM-CSF neutralizing antibody treatment in the LLC model. (H) Representative image of bioluminescence signal from LLC tumors on RaptorECKO mice treated with anti–GM-CSF or IgG control on day 20 postimplantation. (I) Growth curves of LLC tumors on WT mice treated with IgG and RaptorECKO mice treated with anti–GM-CSF or IgG isotype antibodies. n = 8–11 mice per group. **P ≤ 0.01. Two-way ANOVA. (J) Quantification of metastatic foci on the surface of lungs harvested in I. (K and L) Flow cytometric analysis of CD11b+, CD11b+CD11c+, or CD11c+ immune cells and CD103+CD11c+ DCs (K) and IFN-γ+CD8+ T cells (L) in tumors treated with IgG control and tumors treated with anti–GM-CSF. Unless indicated, all data are presented as mean ± SD. **P ≤ 0.01. *P ≤ 0.05, Student’s 2-tailed t test.