Platelet integrin α6β1 controls lung metastasis through direct binding to cancer cell–derived ADAM9
Elmina Mammadova-Bach, Paola Zigrino, Camille Brucker, Catherine Bourdon, Monique Freund, Adèle De Arcangelis, Scott I. Abrams, Gertaud Orend, Christian Gachet, Pierre Henri Mangin
Elmina Mammadova-Bach, Paola Zigrino, Camille Brucker, Catherine Bourdon, Monique Freund, Adèle De Arcangelis, Scott I. Abrams, Gertaud Orend, Christian Gachet, Pierre Henri Mangin
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Research Article Hematology Oncology

Platelet integrin α6β1 controls lung metastasis through direct binding to cancer cell–derived ADAM9

Abstract

Metastatic dissemination of cancer cells, which accounts for 90% of cancer mortality, is the ultimate hallmark of malignancy. Growing evidence suggests that blood platelets have a predominant role in tumor metastasis; however, the molecular mechanisms involved remain elusive. Here, we demonstrate that genetic deficiency of integrin α6β1 on platelets markedly decreases experimental and spontaneous lung metastasis. In vitro and in vivo assays reveal that human and mouse platelet α6β1 supports platelet adhesion to various types of cancer cells. Using a knockdown approach, we identified ADAM9 as the major counter receptor of α6β1 on both human and mouse tumor cells. Static and flow-based adhesion assays of platelets binding to DC-9, a recombinant protein covering the disintegrin-cysteine domain of ADAM9, demonstrated that this receptor directly binds to platelet α6β1. In vivo studies showed that the interplay between platelet α6β1 and tumor cell–expressed ADAM9 promotes efficient lung metastasis. The integrin α6β1–dependent platelet-tumor cell interaction induces platelet activation and favors the extravasation process of tumor cells. Finally, we demonstrate that a pharmacological approach targeting α6β1 efficiently impairs tumor metastasis through a platelet-dependent mechanism. Our study reveals a mechanism by which platelets promote tumor metastasis and suggests that integrin α6β1 represents a promising target for antimetastatic therapies.

Authors

Elmina Mammadova-Bach, Paola Zigrino, Camille Brucker, Catherine Bourdon, Monique Freund, Adèle De Arcangelis, Scott I. Abrams, Gertaud Orend, Christian Gachet, Pierre Henri Mangin

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Figure 5

Platelet integrin α6β1 promotes platelet activation and granule release and enhances tumor cell extravasation through ADAM9.

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Platelet integrin α6β1 promotes platelet activation and granule release ...
Representative (A) scanning electron microscopy and (C) immunofluorescence microscopy images of PF4-Cre-α6+/+ and PF4-Cre-α6–/– mouse platelets adhering to recombinant DC-9 under (A and B) flow and (C and D) static conditions, respectively. (A and B) Hirudinated mouse whole blood was perfused over DC-9 (500 μg/ml) at 300 s–1. (A) The morphology of adherent platelets was examined after 3 minutes by scanning electron microscopy, and (B) the percentage of platelets extending filopodia was quantified. Scale bar: 8 μm. Mean ± SEM. *P < 0.05, Mann-Whitney test. (CF) Washed PF4-Cre-α6+/+ and PF4-Cre-α6–/– mouse platelets were allowed to adhere to (C) DC-9 (500 μg/ml) or (E) AT-3 cells. After 30 minutes, adherent platelets were stained with the anti-GPIbβ antibody, RAM.1 (green), and for P-selectin exposure (red). (C and E) Representative immunofluorescence staining of platelets adhered on (C) DC-9 or (E) AT-3 cells. Scale bar: 20 μm; 10 μm (inset). (D and F) Quantification of the ratio between P-selectin and RAM.1 signals of adherent platelets. *P < 0.05, **P < 0.01, Mann-Whitney test. Each point represents an individual mouse. (G) AT-3 control or ADAM9-silenced cancer cells were seeded on HUVECs, and tumor cell transmigration was determined in the absence or presence of PF4-Cre-α6+/+ and PF4-Cre-α6–/– platelets. *P < 0.05, Mann-Whitney test. Each point represents a separate experiment. (H) Representative fluorescent microscopy images of lung sections of PF4-Cre-α6+/+ and PF4-Cre-α6–/– mice 6 hours after i.v. injection of AT-3-CFSE cells (green). Lung vessels were stained with lectin (red). Gray and blue arrows indicate extravascular and intravascular cells, respectively. Scale bar: 10 μm. (I) The percentage of intravascular and extravascular AT-3 cells in lungs of PF4-Cre-α6+/+ and PF4-Cre-α6–/– mice. *P < 0.05, Fisher’s exact test. Four mice per each group were used. (B, D, F, and G) Box-and-whisker plots were used to graphically represent the median (line within box), upper and lower quartile (bounds of box), and maximum and minimum values (bars).