Integrin αvβ8–expressing tumor cells evade host immunity by regulating TGF-β activation in immune cells
Naoki Takasaka, Robert I. Seed, Anthony Cormier, Andrew J. Bondesson, Jianlong Lou, Ahmed Elattma, Saburo Ito, Haruhiko Yanagisawa, Mitsuo Hashimoto, Royce Ma, Michelle D. Levine, Jean Publicover, Rashaun Potts, Jillian M. Jespersen, Melody G. Campbell, Fraser Conrad, James D. Marks, Yifan Cheng, Jody L. Baron, Stephen L. Nishimura
Naoki Takasaka, Robert I. Seed, Anthony Cormier, Andrew J. Bondesson, Jianlong Lou, Ahmed Elattma, Saburo Ito, Haruhiko Yanagisawa, Mitsuo Hashimoto, Royce Ma, Michelle D. Levine, Jean Publicover, Rashaun Potts, Jillian M. Jespersen, Melody G. Campbell, Fraser Conrad, James D. Marks, Yifan Cheng, Jody L. Baron, Stephen L. Nishimura
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Research Article Immunology

Integrin αvβ8–expressing tumor cells evade host immunity by regulating TGF-β activation in immune cells

Abstract

TGF-β is a promising immunotherapeutic target. It is expressed ubiquitously in a latent form that must be activated to function. Determination of where and how latent TGF-β (L-TGF-β) is activated in the tumor microenvironment could facilitate cell- and mechanism-specific approaches to immunotherapeutically target TGF-β. Binding of L-TGF-β to integrin αvβ8 results in activation of TGF-β. We engineered and used αvβ8 antibodies optimized for blocking or detection, which — respectively — inhibit tumor growth in syngeneic tumor models or sensitively and specifically detect β8 in human tumors. Inhibition of αvβ8 potentiates cytotoxic T cell responses and recruitment of immune cells to tumor centers — effects that are independent of PD-1/PD-L1. β8 is expressed on the cell surface at high levels by tumor cells, not immune cells, while the reverse is true of L-TGF-β, suggesting that tumor cell αvβ8 serves as a platform for activating cell-surface L-TGF-β presented by immune cells. Transcriptome analysis of tumor-associated lymphoid cells reveals macrophages as a key cell type responsive to β8 inhibition with major increases in chemokine and tumor-eliminating genes. High β8 expression in tumor cells is seen in 20%–80% of various cancers, which rarely coincides with high PD-L1 expression. These data suggest tumor cell αvβ8 is a PD-1/PD-L1–independent immunotherapeutic target.

Authors

Naoki Takasaka, Robert I. Seed, Anthony Cormier, Andrew J. Bondesson, Jianlong Lou, Ahmed Elattma, Saburo Ito, Haruhiko Yanagisawa, Mitsuo Hashimoto, Royce Ma, Michelle D. Levine, Jean Publicover, Rashaun Potts, Jillian M. Jespersen, Melody G. Campbell, Fraser Conrad, James D. Marks, Yifan Cheng, Jody L. Baron, Stephen L. Nishimura

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Figure 1

MC38 colon carcinoma tumor growth in vivo is reduced by anti-αvβ8 and eliminated in the majority of mice by combination with anti–PD-1.

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MC38 colon carcinoma tumor growth in vivo is reduced by anti-αvβ8 and el...
(A) MC38 cells express cell-surface β8. Shown is a representative histogram overlay of anti-β8 (C6D4) stained cells (gray histogram) compared with isotype control (unfilled histogram) (a representative experiment of 4 is shown). For engineering and characterization of C6D4, see Supplemental Methods and Supplemental Figure 1. (B) MC38 cells express cell-surface PD-L1. Cells were stained with anti–PD-L1 (light gray). As a positive control cells were stimulated with IFN-γ (dark gray) (10 ng/ml) for 24 hours (hr). Shown is a representative histogram overlay of PD-L1 expression of IFN-γ–stimulated or nonstimulated compared with control (a representative experiment of 4 is shown). (C) MC38 cells support αvβ8-mediated TGF-β activation. MC38 cells were cocultured with TGF-β reporter cells in the presence or absence of C6D4, isotype control, or pan–TGF-β neutralizing antibody (1D11). Dotted line indicates basal level of TGF-β activation in MC38 cells. (D–I) MC38 colon carcinoma cells (5 × 105) were s.c. implanted into the flank of C57BL/6 mice. After tumors became palpable (7 days after inoculation), isotype control (anti-SV5 and 2A3), anti-β8 (C6D4), anti–PD-1 (RMP1-14), or both in combination were injected on days 0, 3, 6 (10 mg/kg i.p.), and RMP1-14 was added alone on day 9 (10 mg/kg i.p.). Spider plots of tumor growth of each treatment arm from mice treated with isotype control (D) SV5 and 2A3 (mouse and rat IgG2a, respectively) (n = 10) and neutralizing antibodies to (E) αvβ8 (C6D4) (n = 10), (G) PD-1 (RMP1-14) (n = 9), or (H) αvβ8 and PD-1 (C6D4 and RMP1-14) (n = 10). (F) Average tumor volumes from D, E, G, and H 15 days after tumor cell injection and 7 days after antibody administration is shown. (I) Kaplan-Meier survival plots. In legends F and I, ANOVA with Tukey’s post-hoc test of day 7 volume, or day 70 survival data, respectively, is shown. *P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001. In D, E, G, H, complete response percentages (CR) and, in I, hazard ratios (Mantel-Haenszel) are shown. Arrows in F indicate antibody injection days.