Coagulation proteases modulate nucleic acid uptake and cGAS-STING-IFN induction in the tumor microenvironment
Petra Wilgenbus, Jennifer Pott, Sven Pagel, Claudius Witzler, Jennifer Royce, Federico Marini, Sabine Reyda, Thati Madhusudhan, Thomas Kindler, Anne Hausen, Matthias M. Gaida, Hartmut Weiler, Wolfram Ruf, Claudine Graf
Petra Wilgenbus, Jennifer Pott, Sven Pagel, Claudius Witzler, Jennifer Royce, Federico Marini, Sabine Reyda, Thati Madhusudhan, Thomas Kindler, Anne Hausen, Matthias M. Gaida, Hartmut Weiler, Wolfram Ruf, Claudine Graf
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Research Article Immunology Oncology Vascular biology

Coagulation proteases modulate nucleic acid uptake and cGAS-STING-IFN induction in the tumor microenvironment

Abstract

Malignancies increase the risk for thrombosis and metastasis dependent on complex interactions of innate immune cells, platelets, and the coagulation system. Immunosuppressive functions of platelets and macrophage-derived coagulation factors in the tumor microenvironment (TME) drive tumor growth. Here, we show that patients with malignancies and tumor-bearing mice have increased levels of coagulation factor (F) X–expressing circulating monocytes engaged in platelet aggregate formation. This interaction and resulting thrombin generation on platelets interferes with monocyte differentiation and antigen uptake of antigen-presenting cells (APCs). Myeloid cell–specific deletion of FX or abrogated FXa signaling via protease activated receptor 2 (PAR2) averts the suppressive activity of platelets on tumor cell debris uptake and promotes the immune stimulatory activity of APCs in the TME. Myeloid cell FXa-PAR2 signaling deficiency specifically enhances activation of the cGAS-STING-IFN-I pathway with a resulting expansion of antigen experienced progenitor exhausted CD8+ T cells. Pharmacological blockade of FXa with direct oral anticoagulants expands T cell priming–competent immune cells in the TME and synergizes with the reactivation of exhausted CD8+ T cells by immune checkpoint inhibitors for improved antitumor responses. These data provide mechanistic insights into the emerging clinical evidence demonstrating the translational potential of FXa inhibition to synergize with immunotherapy.

Authors

Petra Wilgenbus, Jennifer Pott, Sven Pagel, Claudius Witzler, Jennifer Royce, Federico Marini, Sabine Reyda, Thati Madhusudhan, Thomas Kindler, Anne Hausen, Matthias M. Gaida, Hartmut Weiler, Wolfram Ruf, Claudine Graf

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Figure 4

Myeloid cell–derived FXa recruits immune suppressive platelets.

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Myeloid cell–derived FXa recruits immune suppressive platelets. (A) Sche...
(A) Schematic overview of coagulation initiation by macrophage-expressed FX by the TF-FVIIa complex and prothrombin (FII) to thrombin (FIIa) activation by platelet localized FVa and FXa. (B) Western blot showing a representative example of FX, FII, and FVa protein expression by platelets from tumor free (pltnaive) and tumor-bearing (plttumor) PyMT-F10fl/fl or PyMT-F10fl/flLysMcre mice and by in vitro–generated macrophages from a WT mouse normalized to β actin. Cells were stimulated with LPS/IFNγ overnight to assess the effects of an inflammatory environment on protein expression. (C) GARP and LAP on platelets from tumor free (naive) or tumor bearing (tumor) mice with or without thrombin (FIIa) activation shown as histograms. (D) Quantification of released active TGFβ1 from the experiment shown in C; n = 3, mean ± SD, 2-way ANOVA with Sidak’s multiple comparison test. (E) GARP and LAP/TGFβ on the monocyte surface after 1 hour of incubation with platelets from tumor free (naive) or tumor bearing (tumor) mice. Shown is a representative dot plot and the quantification of CD41, GARP, and LAP surface levels on monocytes; n = 3, mean ± SD, 1-way ANOVA with Dunnett’s multiple comparison test. (F) Uptake of EdU labeled cell free tumor debris by BM monocyte derived WT macrophages after 2 hours of incubation. Macrophages were differentiated in the absence (control) or presence of thrombin (FIIa), platelets from tumor free (pltnaïve) or tumor bearing (plttumor) mice, or TGFβ; n = 2–4, mean ± SD, 1-way ANOVA with Dunnett’s multiple comparison test. (G) Quantification of Mb21d1 mRNA expression normalized to r18s in WT macrophages, differentiated as indicated, after exposure to cell free tumor debris for 6 hours. n = 4–8, mean ± SD, 1-way ANOVA with Dunnett’s multiple comparison test. (H) Flow cytometry analysis of cell free EdU labeled tumor debris uptake after 2 hours by iDCs differentiated with or without thrombin (FIIa) n = 6, mean ± SD, 2-sided unpaired t test. (I) Quantification of Itgae mRNA expression by iDCs normalized to r18s in WT iDCs differentiated as indicated; n = 4–8, mean ± SD, 1-way ANOVA with Dunnett’s multiple comparison test. (J) Experimental set up for monocyte-platelet aggregate formation between BM monocytes from F10fl/fl and F10flLyscMcre or PAR2WT and PAR2G37I mice and WT platelets after 60 minutes of coculture. Monocytes were pre-incubated for 4 hours with LPS/IFNγ to induce FX expression. (K and L) Shown are representative histograms for surface levels of CD41, GARP, and LAP (K) and quantification of CD41+ monocytes and surface levels of CD41 (L) on these cells; n = 3, mean ± SD, 2-way ANOVA with Sidak’s multiple comparison test. *P < 0.05; **P < 0.01; ***P < 0.001; ****P < 0.0001.