Type III TGF-β receptor downregulation generates an immunotolerant tumor microenvironment
Brent A. Hanks, … , H. Kim Lyerly, Gerard C. Blobe
Brent A. Hanks, … , H. Kim Lyerly, Gerard C. Blobe
Published August 8, 2013
Citation Information: J Clin Invest. ;123(9):3925-3940. https://doi.org/10.1172/JCI65745.
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Research Article

Type III TGF-β receptor downregulation generates an immunotolerant tumor microenvironment

Abstract

Cancers subvert the host immune system to facilitate disease progression. These evolved immunosuppressive mechanisms are also implicated in circumventing immunotherapeutic strategies. Emerging data indicate that local tumor-associated DC populations exhibit tolerogenic features by promoting Treg development; however, the mechanisms by which tumors manipulate DC and Treg function in the tumor microenvironment remain unclear. Type III TGF-β receptor (TGFBR3) and its shed extracellular domain (sTGFBR3) regulate TGF-β signaling and maintain epithelial homeostasis, with loss of TGFBR3 expression promoting progression early in breast cancer development. Using murine models of breast cancer and melanoma, we elucidated a tumor immunoevasion mechanism whereby loss of tumor-expressed TGFBR3/sTGFBR3 enhanced TGF-β signaling within locoregional DC populations and upregulated both the immunoregulatory enzyme indoleamine 2,3-dioxygenase (IDO) in plasmacytoid DCs and the CCL22 chemokine in myeloid DCs. Alterations in these DC populations mediated Treg infiltration and the suppression of antitumor immunity. Our findings provide mechanistic support for using TGF-β inhibitors to enhance the efficacy of tumor immunotherapy, indicate that sTGFBR3 levels could serve as a predictive immunotherapy biomarker, and expand the mechanisms by which TGFBR3 suppresses cancer progression to include effects on the tumor immune microenvironment.

Authors

Brent A. Hanks, Alisha Holtzhausen, Katherine S. Evans, Rebekah Jamieson, Petra Gimpel, Olivia M. Campbell, Melissa Hector-Greene, Lihong Sun, Alok Tewari, Amanda George, Mark Starr, Andrew B. Nixon, Christi Augustine, Georgia Beasley, Douglas S. Tyler, Takayu Osada, Michael A. Morse, Leona Ling, H. Kim Lyerly, Gerard C. Blobe

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Figure 2

Loss of TGFBR3 expression generates an immunotolerant tumor microenvironment in the 4T1 murine breast cancer model.

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Loss of TGFBR3 expression generates an immunotolerant tumor microenviron...
(A) Cd8 qRT-PCR and CD3+CD8+ T cell flow analysis of 4T1-NEO and 4T1-TGFBR3 tumors. (B) Foxp3 qRT-PCR and CD4+FOXP3+ Treg flow analysis of 4T1-NEO and 4T1-TGFBR3 tumors. (A and B) qRT-PCR, 5 tumors/group, data representative of 3 independent experiments; flow analysis, 9 tumors/group, data pooled from 3 independent experiments. (C) Cd8 qRT-PCR and CD3+CD8+ T cell flow analysis of 4T1-NEO and 4T1-TGFBR3 TDLNs. 8 mice/group. Pooled from 2 independent experiments. (D) Foxp3 qRT-PCR and FOXP3+ IHC of 4T1-NEO and 4T1-TGFBR3 TDLNs. qRT-PCR, 8 mice/group, data pooled from 2 independent experiments; IHC, 5 random ×40 fields/condition, data representative of 2 independent experiments. (E) Allogeneic T cell proliferation assays using distant LN and TDLN tissues resected from 4T1-NEO and 4T1-TGFBR3 tumor-bearing mice. 5 mice/group. Representative of 2 independent experiments. (F) HER2/NEU-specific autologous T cell proliferation assays using 4T1-NEO-HER2 and 4T1-TGFBR3-HER2 TDLNs. 5 mice/group. Representative of 2 independent experiments. (G) HER2/NEU-specific IFN-γ ELISPOT assay of 4T1-NEO-HER2 and 4T1-TGFBR3-HER2 TDLNs. 5–10 mice/group. Performed in triplicate. Flow cytometry data are expressed as a percentage of viable total tumor or TDLN cell number. Data are mean ± SEM. *P < 0.05, **P < 0.005, ***P < 0.0005, 2-tailed Student’s t test.