Plasma fibronectin supports hemostasis and regulates thrombosis
Yiming Wang, … , John Freedman, Heyu Ni
Yiming Wang, … , John Freedman, Heyu Ni
Published September 2, 2014
Citation Information: J Clin Invest. 2014;124(10):4281-4293. https://doi.org/10.1172/JCI74630.
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Research Article Hematology

Plasma fibronectin supports hemostasis and regulates thrombosis

Abstract

Plasma fibronectin (pFn) has long been suspected to be involved in hemostasis; however, direct evidence has been lacking. Here, we demonstrated that pFn is vital to control bleeding in fibrinogen-deficient mice and in WT mice given anticoagulants. At the site of vessel injury, pFn was rapidly deposited and initiated hemostasis, even before platelet accumulation, which is considered the first wave of hemostasis. This pFn deposition was independent of fibrinogen, von Willebrand factor, β3 integrin, and platelets. Confocal and scanning electron microscopy revealed pFn integration into fibrin, which increased fibrin fiber diameter and enhanced the mechanical strength of clots, as determined by thromboelastography. Interestingly, pFn promoted platelet aggregation when linked with fibrin but inhibited this process when fibrin was absent. Therefore, pFn may gradually switch from supporting hemostasis to inhibiting thrombosis and vessel occlusion following the fibrin gradient that decreases farther from the injured endothelium. Our data indicate that pFn is a supportive factor in hemostasis, which is vital under both genetic and therapeutic conditions of coagulation deficiency. By interacting with fibrin and platelet β3 integrin, pFn plays a self-limiting regulatory role in thrombosis, suggesting pFn transfusion may be a potential therapy for bleeding disorders, particularly in association with anticoagulant therapy.

Authors

Yiming Wang, Adili Reheman, Christopher M. Spring, Jalil Kalantari, Alexandra H. Marshall, Alisa S. Wolberg, Peter L. Gross, Jeffrey I. Weitz, Margaret L. Rand, Deane F. Mosher, John Freedman, Heyu Ni

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Figure 4

pFn enhances the mechanical strength of the fibrin clot and controls the diameter of fibrin fibers in mice.

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pFn enhances the mechanical strength of the fibrin clot and controls the...
(AC) Representative TEG tracings and MA measured by TEG in (A) whole blood and (B) PPP. (C) Adding back purified pFn partially rescued the MA of pFn–/– blood. n = 5 in each group. (D) Confocal images of mouse pFn-fibrin network formed in vitro (z projection of 11 individual slides taken at 1-μm interval across the 10-μm thickness of the clot). Mouse pFn or BSA was added into pFn–/– mouse PPP to a final concentration of 330 μg/ml. (E) Scanning electron microscopy analysis of mouse pFn-fibrin network formed in vitro. The same volume of PBS and mouse pFn was added into pFn–/– mouse PPP (final concentration 330 μg/ml). (H) Scanning electron microscopy analysis of pFn+/+ and pFn–/– mouse pFn-fibrin network formed in vitro. pFn-fibrin network formation was initiated with 0.5 U/ml murine thrombin and 30 mM CaCl2. (F and I) Average diameter of pFn-fibrin fibers formed in vitro. (G and J) Average density of pFn-fibrin fibers formed in vitro. Average diameter and density were calculated by counting the fibers crossed by 2 diagonal lines in a 1-μm2 square. n = 9 in each group. Scale bar: 20 μm (D); 1 μm (E and H).