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 2

Myeloid cell FX deficiency and abrogated FXa-PAR2 signaling cause similar quantitative shifts in myeloid subpopulations in the TME.

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Myeloid cell FX deficiency and abrogated FXa-PAR2 signaling cause simila...
(AC) Coexpression analysis as determined by scRNA-seq in CD11c-selected cells from PyMT-PAR2WT and PyMT-PAR2G37I tumors (n = 3; see also Supplemental Figure 1D) and by flow cytometric quantification of TAMs and DCs from the TME of PyMT-F10fl/flLysMcre and F10fl/fl littermate control mice; n = 8–10, mean ± SD, 2-sided unpaired t test. (A) Mertk, Fcgr1, Mrc1 and Procr mRNA or CD64, MerTK, EPCR, Mrc1 protein coexpression. (B) Cells with the mRNA marker profile Itga4+Mrc1Fcgr+Itgb7+ or the protein surface profile CD64lo/–MerTKMrc1α4β7+. (C) Cells with the mRNA marker profile Itgae+Itgb7+Itga4+Btla+ or the protein surface profile CD11c+CD103+Btla+. (D) Flow cytometry quantification of total and IL12 expressing CD103+ DCs in the TME of PyMT-F10fl/flLysMcre or PyMT-F10fl/fl littermate control mice; n = 6-8, mean ± SD, 2-sided unpaired t test. *P < 0.05; **P < 0.01; ***P < 0.001.