Aquaporin-1 regulates platelet procoagulant membrane dynamics and in vivo thrombosis
Ejaife O. Agbani, Christopher M. Williams, Yong Li, Marion T.J. van den Bosch, Samantha F. Moore, Adele Mauroux, Lorna Hodgson, Alan S. Verkman, Ingeborg Hers, Alastair W. Poole
Ejaife O. Agbani, Christopher M. Williams, Yong Li, Marion T.J. van den Bosch, Samantha F. Moore, Adele Mauroux, Lorna Hodgson, Alan S. Verkman, Ingeborg Hers, Alastair W. Poole
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Research Article Cell biology Hematology

Aquaporin-1 regulates platelet procoagulant membrane dynamics and in vivo thrombosis

Abstract

In response to collagen stimulation, platelets use a coordinated system of fluid entry to undergo membrane ballooning, procoagulant spreading, and microvesiculation. We hypothesized that water entry was mediated by the water channel aquaporin-1 (AQP1) and aimed to determine its role in the platelet procoagulant response and thrombosis. We established that human and mouse platelets express AQP1 and localize to internal tubular membrane structures. However, deletion of AQP1 had minimal effects on collagen-induced platelet granule secretion, aggregation, or membrane ballooning. Conversely, procoagulant spreading, microvesiculation, phosphatidylserine exposure, and clot formation time were significantly diminished. Furthermore, in vivo thrombus formation after FeCl3 injury to carotid arteries was also markedly suppressed in AQP1-null mice, but hemostasis after tail bleeding remained normal. The mechanism involves an AQP1-mediated rapid membrane stretching during procoagulant spreading but not ballooning, leading to calcium entry through mechanosensitive cation channels and a full procoagulant response. We conclude that AQP1 is a major regulator of the platelet procoagulant response, able to modulate coagulation after injury or pathologic stimuli without affecting other platelet functional responses or normal hemostasis. Clinically effective AQP1 inhibitors may therefore represent a novel class of antiprocoagulant antithrombotics.

Authors

Ejaife O. Agbani, Christopher M. Williams, Yong Li, Marion T.J. van den Bosch, Samantha F. Moore, Adele Mauroux, Lorna Hodgson, Alan S. Verkman, Ingeborg Hers, Alastair W. Poole

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Figure 3

Platelet procoagulant spreading and phosphatidylserine exposure but not membrane ballooning is markedly diminished by AQP1 ablation.

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Platelet procoagulant spreading and phosphatidylserine exposure but not ...
(A) Time course of membrane ballooning in platelets adherent to collagen in Tyrode medium containing 1 mM calcium, with 4 platelet phenotypes identified as previously reported (46). BNS, ballooned nonspread platelets; BAPS, ballooned and procoagulant-spread platelet; CSNB, conventional-spread nonballooned platelet; NBNS, nonballooned nonspread platelets. +, annexin V+ status; -, annexin V status. Images show a typical field of view of AQP1+/+ and AQP1–/– mouse platelets adherent to collagen at the 1-hour time point, with fluorescent annexin V (red) superimposed with corresponding P selectin images (green) and phase-contrast images. 3D images showing annexin V staining. Images were obtained by spinning-disk confocal microscopy (original magnification, ×100). (B) AQP1+/+ and AQP1–/– platelets adhering to a collagen-coated surface were monitored for microvesicle release in real time by imaging-based particle counting; at the 1-hour time point, microvesicles were identified (over a 70 × 90 μm field of view of extended focus images), as annexin V+ particles with diameter between 100 nm and 1 μm. Data are displayed as histogram and inset scatter plots. Box-and-whisker plot shows a comparison of microvesicles identified from adherent AQP1+/+ and AQP1–/– platelets. Data analysis was performed by Wilcoxon signed-rank test. *P < 0.05 was considered significant. Scale bar: 10 μm. Data were from 7 independent experiments.