Tissue factor (TF) plays a central role in haemostasis and thrombosis. Following vascular damage, vessel wall TF initiates the extrinsic coagulation cascade. TF can also be exposed by monocytes. Inflammatory or infectious stimuli trigger synthesis of new TF protein by monocytes over the course of hours. It has also been suggested that monocytes can expose TF within minutes when stimulated by activated platelets. Here, we have confirmed that monocytes rapidly expose TF in whole blood and further demonstrate that platelet P-selectin exposure is necessary and sufficient. Monocyte TF exposure increased within five minutes in response to platelet activation by PAR1-AP, PAR4-AP or CRP-XL. PAR1-AP did not trigger TF exposure on isolated monocytes unless platelets were also present. In whole blood, PAR1-AP-triggered TF exposure required P-selectin and PGSL-1. In isolated monocytes, although soluble recombinant P-selectin had no effect, P-selectin coupled to 2 µm beads triggered TF exposure. Cycloheximide did not affect rapid TF exposure, indicating that de novo protein synthesis was not required. These data show that P-selectin on activated platelets rapidly triggers TF exposure on monocytes. This may represent a mechanism by which platelets and monocytes rapidly contribute to intravascular coagulation.
Tissue factor (TF; CD142) plays a central role in haemostasis and thrombosis1,2. TF is a transmembrane glycoprotein constitutively expressed in the adventitia of normal blood vessels2. In the absence of vascular injury, TF is not exposed to flowing blood. Vascular damage allows plasma FVIIa to bind to TF, initiating the extrinsic pathway of coagulation. The TF:FVIIa complex activates FX; FXa is the central component of the prothrombinase complex, leading to formation of thrombin3,4. Thrombin cleaves plasma fibrinogen to release fibrin, and activates platelets through protease-activated receptors (PARs)3,5. Exposure of TF to blood following vascular injury is therefore a key trigger for coagulation and haemostasis.
TF can also be exposed to blood in pathological circumstances. Atherosclerotic plaques contain high levels of TF that is exposed on plaque rupture6. Subsequent TF-triggered coagulation contributes to arterial thrombosis and acute coronary syndrome7,8. Blood-borne TF may also contribute to intravascular coagulation and thrombosis9,10. Monocytes are a central source of blood-borne TF following inflammatory or infectious stimuli4,11,12. Bacterial lipopolysaccharide (LPS), for example, induces increased expression of TF in monocytes12. This is dependent on synthesis of new TF protein13. TF on the monocyte surface is often shed in extracellular vesicles known as microparticles14. These circulating, TF-positive microparticles are likely to be the major source of blood-borne TF. However, this increase in TF gene expression occurs over hours12, so although on-going TF gene expression in monocytes may contribute to increased thrombosis risk in inflammatory or infectious disease states, it may be less likely to contribute to rapid arterial thrombosis if it has not previously been triggered.
However, there have been isolated reports that monocytes can expose TF on their surface much more rapidly, for example, within ten minutes (e.g.15). This has been observed in whole blood, where cells other than monocytes are also present. It has been proposed that blood platelets, when activated, bind to monocytes. In response, monocytes expose TF on their surface. This occurs without an increase in TF mRNA, suggesting that it is not dependent on synthesis of new TF protein15. In our study, we have confirmed that monocytes rapidly expose TF in whole blood. Furthermore, we used isolated cells and recombinant P-selectin to demonstrate that platelet P-selectin exposure is both necessary and sufficient.
Monocytes rapidly expose TF in response to platelet activators in whole blood
PPACK-anticoagulated blood was stimulated with the PAR1 agonist, PAR1-AP (SFLLRN-amide), and analysed by flow cytometry. Within 5 minutes of stimulation, we detected TF antigen on the surface of CD14+ monocytes in a concentration-dependent manner (Fig. 1a). In parallel, CD41a+ platelets exposed P-selectin, indicating α-granule secretion (Fig. 1b). Similar results were seen with two different platelet activators, PAR4-AP (AYPGKF-amide), a selective PAR4 activating peptide, and cross-linked collagen-related peptide (CRP-XL), a selective GPVI agonist (Fig. 1c). Both activators rapidly increased platelet surface P-selectin and monocyte surface exposure of TF. In contrast, ADP only weakly activated platelets under these conditions (shown by the relatively small increase in P-selectin), and only weakly stimulated monocyte surface exposure of TF. With all activators, the concentration-dependence of monocyte TF exposure and platelet P-selectin exposure was similar. For CRP-XL, the EC50 for TF exposure was 0.67 µg/ml and the EC50 for P-selectin exposure was 0.73 µg/ml. For PAR4-AP, the EC50 was 58 µM and 62 µM for TF and P-selectin exposure, respectively. The TF on the monocyte surface was detected by three different antibodies that detect different epitopes of TF (Supplementary Fig. 1), suggesting that this binding does indeed represent TF antigen.
Aspirin and P2Y12 antagonists are used clinically to inhibit platelet activation16. Pre-treatment of whole blood ex vivo with aspirin (100 µM) had no effect on monocyte TF or platelet P-selectin exposure under these conditions (Fig. 2). In contrast, the P2Y12 antagonist, AR-C66096 (10 µM), reduced PAR1-AP-triggered surface TF exposure to 42.4 ± 3.8% (n = 5; p < 0.01) at 10 minutes of stimulation, and to 37.8 ± 2.2% (n = 5; p < 0.01) at 30 minutes. Platelet P-selectin exposure was also inhibited, consistent with previous reports17, suggesting that the reduction in TF may be a consequence of inhibited platelet activation.
Platelets are required for rapid surface exposure of TF in monocytes
To investigate the role of platelets in the rapid surface exposure of TF in monocytes, we isolated monocytes and platelets from whole blood. Monocytes alone stimulated with PAR1-AP did not expose TF (Fig. 3a), indicating that this agonist is not acting directly on the monocytes. Similarly, TF was not detected on the surface of platelets alone when stimulated with PAR1-AP. In contrast, when monocytes and platelets were combined, TF was detected on CD14+ monocytes following stimulation with PAR1-AP (Fig. 3a). Together, these data indicate that activated platelets are required for the rapid exposure of TF.
We used two approaches to determine whether a soluble mediator released by platelets might contribute to monocyte TF exposure. First, platelets were stimulated with PAR1-AP, fixed with paraformaldehyde (PFA), then isolated by centrifugation to remove any soluble released factors (‘washed, activated-fixed’, W A-F; Fig. 3b). As a control, some platelets were left unstimulated prior to being fixed (‘washed unactivated-fixed’, W U-F). When activated-fixed platelets were added to isolated monocytes, TF was exposed to a similar level to that seen previously (Fig. 3c). Representive flow cytometry density plots are shown in SFig. 3. PAR1-AP had no further effect. Second, the supernatant (‘releasate’; Fig. 3b), which contains soluble factors released by activated platelets, was added to isolated monocytes. No surface exposure of TF was detected, even when PAR1-AP was also added (in case a soluble factor was acting in synergy with PAR1-AP). Furthermore, the releasate (and PAR1-AP) had no further effect on monocyte TF in addition to activated, fixed platelets (Fig. 3c). These results indicate that the signals from platelets that trigger monocyte TF exposure are mediated by contact between activated platelets and monocytes. Notably, activated-fixed platelets provided P-selectin to monocytes, whereas the releasate did not (Fig. 3d). This suggests that the stimulation did not trigger release of P-selectin-positive microparticles that then adhere to monocytes. In addition, these data also show that stimulated monocytes themselves do not expose P-selectin, since no P-selectin was detected in the absence of activated platelets.
P-selectin and PGSL-1 are required for rapid surface exposure of TF in monocytes
Blocking antibodies were used to determine the contribution of adhesion receptors to platelet-monocyte binding and TF exposure. Neither platelet-monocyte nor TF exposure was affected by antibodies that block ICAM1, ICAM2, CD40, CD11b, CD18, or CD42b. In contrast, platelet-monocyte binding and TF exposure was almost completely inhibited by antibodies that block either P-selectin (found on the surface of stimulated platelets) or its receptor on monocytes, PGSL-1 (Fig. 4a,b). A small molecule antagonist of platelet αIIbβ3, eptifibatide, did partially reduce platelet-monocyte binding and TF exposure (Fig. 4c; reduced to 46.1 ± 5.0%; n = 5; p < 0.05). However, under these conditions, eptifibatide also reduced platelet P-selectin exposure (Fig. 4d; reduced to 32.7 ± 1.9%; n = 5; p < 0.05).
Recombinant P-selectin triggers monocyte TF surface exposure when coupled to beads
Since P-selectin was necessary for rapid surface exposure of TF, we investigated whether P-selectin alone was sufficient. Monocytes were treated with recombinant human P-selectin (10-6250 ng/ml). Although soluble P-selectin rapidly bound to monocytes, it did not trigger surface exposure of TF after 5 or 30 minutes (Fig. 4e), despite P-selectin binding to monocytes to a level similar to that provided by activated platelets bound to monocytes (Fig. 4f). In contrast, when the same recombinant P-selectin was coupled to 2 µm beads, it could trigger surface expression of TF (Fig. 4g). This was relatively slow (compared to stimulated platelets), occurring after 30 minutes but not after 5 minutes. However, the P-selectin beads also took the same time to bind to monocytes (Fig. 4h). Untreated beads, and beads that had been chemically activated but not coupled to P-selectin, did not trigger surface expression of TF.
Rapid monocyte TF surface exposure does not require protein synthesis
In response to LPS, monocytes synthesise new TF protein within a few hours. To test whether new protein synthesis was involved in the much more rapid surface exposure of TF, whole blood was treated with cycloheximide (100 µM), an inhibitor of translation. PAR1-AP was still able to trigger rapid TF exposure in the presence of cycloheximide (Fig. 5a,b). Similarly, isolated monocytes treated with P-selectin-coupled beads also showed surface expression of TF in the presence of cycloheximide (Fig. 5c,d). This indicates that rapid surface exposure of TF in monocytes is not dependent on protein synthesis.
Monocytes are a major source of intravascular TF. In this study, we demonstrate that activated platelets can rapidly trigger surface exposure of TF in monocytes through P-selectin interaction with monocyte PSGL1 (Fig. 5e). This surface exposure of TF occurs within minutes and does not depend on synthesis of new TF protein. This represents a mechanism by which platelets and monocytes might rapidly contribute to intravascular coagulation.
Platelet activation by a range of receptor agonists rapidly led to surface exposure of TF by monocytes in whole blood. TF antigen was readily detectable in these aggregates with three different anti-TF antibodies. Although similar observations have been reported by Lindmark et al.15, which adds further confidence to our findings, that previous report was unable to determine whether platelets were essential to this response, or whether there may be direct stimulation of the monocytes (or perhaps other cells such as lymphocytes) in the whole blood assay. However, our results also demonstrate that platelets are essential to this response. Isolated monocytes did not expose TF in response to the PAR1 stimulation unless platelets were also present. Moreover, the experiments with activated, fixed platelets demonstrate that activated platelets trigger monocyte TF surface exposure even when the initial platelet activator has been removed (and so is not acting on the monocytes). These experiments demonstrate that platelets are both necessary and sufficient for rapid surface exposure of TF in monocytes.
The signal between activated platelets and monocytes appears to be entirely transduced by the P-selectin – PSGL1 interaction in our system. Activated, fixed then washed platelets were capable of fully triggering the response, whereas the platelet releasate had no effect. This suggests that a soluble factor secreted by platelets is not responsible. Monocyte TF exposure was entirely inhibited by blocking antibodies to P-selectin or to PSGL-1, showing these two adhesion molecules to be necessary. Moreover, P-selectin is sufficient to trigger the response in monocytes, as shown by the experiments with exogenous recombinant P-selectin. Interestingly, soluble monomeric P-selectin did not trigger monocyte TF exposure, despite rapidly coating the monocyte surface with P-selectin. P-selectin in platelet α-granules is found as a homodimer and is exposed on the platelet surface as a dimer following granule exocytosis18. When P-selectin was coupled to 2 µm beads it could trigger TF exposure. This suggests that clustering of PSGL-1 by P-selectin may contribute to intracellular signalling in monocytes and that the clustering of P-selectin into dimers or oligomers is important for its signalling function in platelets. Similarly, Panicker et al.19 showed that dimeric P-selectin binds to PGSL-1 with greater avidity than monomeric P-selectin, and that dimeric or oligomeric soluble P-selectin was required for inducing leukocyte signalling. It also explains the apparent discrepancy between our findings, and those of Celi et al.20 and del Conde et al.21. Although these investigators clearly showed that soluble P-selectin is capable of increasing monocyte TF over the course of several hours by increasing protein synthesis, they found no rapid effect. One possible explanation is that they used soluble monomeric P-selectin, which induced weak, slow signalling, rather than a form that might be able to cluster counter-receptors such as PSGL-1. It also suggests that circulating soluble monomeric P-selectin, which is a potential biomarker for cardiovascular disease22, might be largely ineffective, whereas cells that expose P-selectin, such as platelets, may be more effective.
Although the P-selectin-coupled beads were capable of triggering monocyte TF surface exposure, this was slower than seen with platelet activation either in whole blood or with isolated cells. We suspect that this is an artefact of our experimental conditions. During our coupling reaction, the carboxylic acid on the beads is linked to a primary amine in the recombinant P-selectin. However, there are many primary amines available in P-selectin. Not all the protein molecules will be in a productive position or orientation. This will lower the overall activity. In addition, in preliminary experiments, we found that the coupling reagent (EDAC/carbodiimide) could induce the beads to adhere to monocytes in the absence of P-selectin (presumably to primary amines in proteins on the monocyte surface); untreated beads did not adhere. The addition of BSA to quench reactive coupling reagent prevented P-selectin-independent binding, but it did slow the binding of P-selectin-coupled beads to the monocytes, and so slightly delayed the exposure of TF. Notably, this slightly delayed TF exposure was also independent of protein synthesis (see below).
Another possibility is that there are signals from activated platelets in addition to P-selectin. As discussed above, there does not appear to be a soluble secreted factor involved. However, there may be an additional platelet surface molecule involved. We have excluded several adhesion receptors on platelets or monocytes through use of blocking antibodies. If there is an additional signal on the surface of activated platelets, it does not involve CD40 or CD42 on platelets, or ICAM-1, ICAM-2, CD11b or CD18 on monocytes. The small molecule αIIbβ3 antagonist, eptifibatide, did reduce monocyte surface TF, but this was also associated with inhibition of platelet P-selectin exposure. Although it could indicate an additional role for αIIbβ3 in the platelet-monocyte interaction, it may also reflect the role of integrin outside-in signalling in amplifying platelet activation23,24. Similarly, inhibition of P2Y12 also reduced monocyte TF exposure in parallel with inhibition of platelet P-selectin exposure, and this likely reflects the role of P2Y12 in enhancing α-granule secretion17. In contrast, under our conditions, aspirin had no effect on monocyte TF exposure, consistent with a lack of effect on platelet P-selectin exposure. (Although aspirin is used as an anti-thrombotic in patients, its effect on platelet activation in vitro is often relatively weak and depends on the primary activator being used (see, for example, Blair et al.25).
Rapid platelet-dependent exposure of monocyte TF did not require de novo protein synthesis, as it was not affected by cycloheximide. Similarly, Lindmark et al.15 found no increase in TF mRNA. This suggests that TF is already expressed in unactivated monocytes, providing a small pool of TF that can be rapidly mobilised. Intracellular TF expression in unstimulated monocytes is likely to be low, and is reported to be not present by some groups, though it has been detected (at a low level) in some reports (e.g.26). Any constitutive TF expression in monocytes would need to be maintained in an intracellular compartment and/or in an inactive form to prevent intravascular coagulation. In macrophages, constitutive internalization of surface TF occurs in a dynamin- and integrin α4β1-dependent manner27. A similar mechanism may prevent surface TF exposure in unstimulated monocytes. TF activity may also be controlled by ‘encrypting’ the TF such that it does not activate FX. In addition to surface exposure, decryption of TF may be required for its activity28,29. In preliminary experiments, we have been unable to reliably detect tenase activity in isolated monocytes following rapid exposure of TF, suggesting that additional signals may be required for TF activity30,31.
We propose that monocytes could be recruited to sites of arterial injury, such as atherosclerotic plaque rupture or erosion, by adherent, activated platelets32,33,34, and that platelet P-selectin would trigger monocyte TF exposure. If the TF is active – possibly with an additional decryption signal – then activation of the extrinsic coagulation cascade may contribute to the growth of an intra-luminal thrombus that may occlude the artery. Anti-platelet drugs, such as aspirin and P2Y12 antagonists, are important treatments for the prevention of arterial thrombosis. However, all currently-approved anti-platelet drugs are associated with increased bleeding risk, owing to platelets’ role in haemostasis16. If rapid monocyte TF exposure contributes to thrombosis, then it may provide new target for treatment. This is consistent with a variety of in vivo thrombosis studies. Inhibition of P-selectin reduced arterial thrombosis35,36 and was associated with fewer leukocytes within thrombi35 in mice. P-selectin and PGSL-1 were required for TF and fibrin accumulation in a laser-induced arteriolar thrombosis murine model (although in this model it is likely to be TF-bearing microparticles from monocytes rather than monocytes themselves that promote fibrin formation)37. In a baboon arteriovenous shunt model, a blocking antibody to platelet P-selectin inhibited leukocyte accumulation and fibrin formation38. Although more experimental validation is needed, a role for rapid, P-selectin-dependent monocyte TF exposure in thrombosis is consistent with previous reports and is a potential target for anti-thrombotic therapy. Conversely, inhibition of platelet P-selectin exposure by current antiplatelet drugs such as P2Y12 antagonists may contribute to their antithrombotic benefit.
Use of human blood from healthy volunteers was approved by the Human Biology Research Ethics Committee, University of Cambridge. The volunteers gave fully-informed, written consent in accordance with the Declaration of Helsinki. The volunteers did not take any medications, including non-steroidal anti-inflammatory drugs, antihistamines, and antibiotics, for at least 14 days prior to blood acquisition. Different anticoagulants were used depending on the assay, as noted below.
Stimulation of whole blood
For whole blood experiments, blood was collected in Sample Collection/Anticoagulant Tubes containing the anticoagulant lyophilised Phe-Pro-Arg-chloromethylketone (PPACK, final concentration 75 µM, Haematologic Technologies, VT, USA). 50 µl whole blood was stimulated with agonist for defined times, stained directly conjugated primary antibodies for 5 minutes (see below), then diluted with 350 µl 1xFix/Lyse solution (eBioscience). Samples were kept on ice in the dark until analysis by flow cytometry.
Whole blood was collected in sodium citrate-containing Vacutainers (Becton Dickinson). Citrated blood was centrifuged (200 x g, 10 min, 30 °C) to obtain platelet-rich plasma (PRP). This was collected and diluted 1:1 with HBS-glucose (HEPES-buffered saline: 10 mM HEPES, 135 mM NaCl, 3 mM KCl, 0.34 mM NaH2PO4, 1 mM MgCl2.6H2O, pH 7.4; supplemented with 0.9 mg/ml D-glucose). PGE1 (prostaglandin E1, 100 nM) and apyrase (0.02 U/ml) were added to prevent platelet activation. PRP was centrifuged (600 × g, 10 min, 30 °C) and platelets resuspended in HBS-glucose. 2 mM CaCl2 was added immediately prior to stimulation.
EDTA-anticoagulated blood (1.8 mg/ml) was taken from the same respective donor as the platelets. OptiPrep density gradient (Sigma) was thoroughly mixed with the blood to increase its density. The mixture was layered under Histopaque 1077 (Sigma) in a 15 ml Falcon tube using a 15-cm blunt needle and a syringe. The blood was centrifuged (700 x g, 20 min, 20 °C). The PBMC band (at the top) was collected and the cells were washed with 0.15% BSA solution in PBS pH 7.4 and centrifuged (200 x g, 10 min, 20 °C). The cells were resuspended in HBS, pH 7.4. The monocytes were extracted from the washed PBMC by negative selection using a pan monocyte isolation kit (Miltenyi Biotec). Briefly, the cells were treated for 10 minutes with an FcR blocking reagent, then with a biotinylated antibody cocktail (specific to all white blood cells apart from monocytes) for 10 minutes. Streptavidin magnetic beads were added that bind to biotin on the antibodies and the cells were diluted and transferred to a 5-ml cylindrical tube. This was inserted into a magnet (eBioscience Affimetrix) and after 5 minutes the solution containing purified monocytes was decanted. The suspension was centrifuged, and the monocytes were resuspended in the desired volume. The purity was determined by flow cytometry using CD14 as a monocyte marker and CD41a as a platelet marker (Supplementary Fig. 2). Platelet contamination of monocyte preparations was generally 2%.
Whole blood and isolated cell samples were stained for CD14 (APC, clone Tük4, Thermo Scientific), CD41a (FITC, clone HIP8, Thermo Scientific; and PeCy7, clone CB16, eBiosciences, CA, USA), CD62P (PE, clone 555524, and FITC, clone AK-4, BD Biosciences, CA, USA), CD142 (PE, clone HTF-1, Thermo Scientific; APC, clone HTF-1, eBiosciences; PE, clone NY2, BioLegend, CA, USA; FITC, clone #5, Sino Biological), activated integrin αIIbβ3 (FITC, clone PAC-1, BD Biosciences), or CD15 (FITC, clone HI98, eBiosciences).
The samples were incubated for 5 minutes at room temperature. Isolated cell samples were fixed in 1% paraformaldehyde and whole blood samples in 1x Fix/Lyse (eBioscience) solution in ddH2O, to lyse red blood cells and fix the sample cells, for at least 15 minutes prior to data acquisition. 50 000 CD41a-positive events and at least 1000 CD14-positive events were collected per sample and analysed on a BD Accuri C6 flow cytometer (BD Biosciences). The accompanying software (BD Accuri version 1.0.264.21) was used for collecting and analysing the data. Fluorescence compensation was obtained using single stains of OneComp eBeads according to the manufacturer’s instructions (Thermo Scientific).
Preparation of P-selectin-coated beads
Isolated monocytes were stimulated using P-selectin beads containing 6.25 μg/ml of P-selectin (Recombinant Human P-Selectin/CD62P Fc Chimera Protein; R&D Systems) coupled to 2 micrometre carboxyl polystyrene beads (Polysciences). P-selectin/Fc chimera protein was attached to 50 μl of Polybead® Carboxylate Microspheres, 2 μm (5.68 × 109 particles per ml) using EDAC (carbodiimide; Sigma) dissolved in Coupling Buffer (50 mM MES, pH 5.2; 0.05% Proclin® 300) for covalent binding. The beads were resuspended in Wash/Storage Buffer (10 mM Tris, pH 8.0; 0.05% Bovine Serum Albumin [BSA], 0.05% Proclin 300) and stored at 4 °C. The P-selectin beads were warmed for 30 min at room temperature prior to use in the presence of 0.8% BSA to block non-specific binding. As a control, some beads were activated with EDAC in the absence of P-selectin. During preliminary experiments it was found that these beads also adhere to monocytes unless BSA is present in the Wash/Storage Buffer.
Inhibitors, activators and blocking antibodies
All reagents were from Sigma unless otherwise stated. AR-C66096 and eptifibatide were from Tocris (Bristol, U.K.). PAR1-AP (SFLLRN-amide) and PAR4-AP (AYPGKF-amide) were from Bachem (Weil-am-Rhein, Germany). Cross-linked collegen-related peptide (CRP-XL) was synthesised by Arkadiusz Bonna, Department of Biochemistry. Function blocking antibodies were preservative-free. The antibody clones are listed in Supplementary Table 1.
The number of repeats for experiments with whole blood and isolated cells refers to the number of experimental repeats, which took place on different days and using blood from different donors. GraphPad Prism v6 and FlowJo v10.5 were used for graphical presentation and statistical analysis. All graphs included represent mean + standard error of the mean (S.E.M.). One-way or two-way ANOVA, as appropriate, was used to determine statistical significance.
The data are available from the corresponding author on reasonable request.
Grover, S. & Mackman, N. Tissue Factor: An Essential Mediator of Hemostasis and Trigger of Thrombosis. Arterioscler. Thromb. Vasc. Biol. 38, 709–725 (2018).
Eilertsen, K. & Østerud, B. Tissue factor: (patho)physiology and cellular biology. Blood Coagul Fibrinolysis 15, 521–538 (2004).
Monroe, D. M. & Hoffman, M. What does it take to make the perfect clot? Arterioscler. Thromb. Vasc. Biol. 26, 41–48 (2006).
Mackman, N., Tilley, R. & Key, N. Role of the extrinsic pathway of blood coagulation in hemostasis and thrombosis. Arterioscler. Thromb. Vasc. Biol. 27, 1687–1693 (2007).
Hamilton, J. R. Protease-activated receptors as targets for antiplatelet therapy. Blood Rev. 23, 61–65 (2009).
Tatsumi, K. & Mackman, N. Tissue Factor and Atherothrombosis. J Atheroscler Thromb 22, 543–549 (2015).
Badimon, J. et al. Local inhibition of tissue factor reduces the thrombogenicity of disrupted human atherosclerotic plaques: effects of tissue factor pathway inhibitor on plaque thrombogenicity under flow conditions. Circulation 99, 1780–1788 (1999).
Moons, A. H., Levi, M. & Peters, R. Tissue factor and coronary artery disease. Cardiovasc. Res. 53, 313–325 (2002).
Cimmino, G., Golino, P. & Badimon, J. Pathophysiological role of blood-borne tissue factor: should the old paradigm be revisited? Intern Emerg Med 6, 29–34 (2011).
Bogdanov, V. & Versteeg, H. ‘Soluble Tissue Factor’ in the 21st Century: Definitions, Biochemistry, and Pathophysiological Role in Thrombus Formation. Semin Thromb Haemost 41, 700–707 (2015).
von Bruehl, M.-L. et al. Monocytes, neutrophils, and platelets cooperate to initiate and propagate venous thrombosis in mice in vivo. J. Exp. Med. 209, 819–835 (2012).
Mészáros, K. et al. Monocyte tissue factor induction by lipopolysaccharide (LPS): dependence on LPS-binding protein and CD14, and inhibition by a recombinant fragment of bactericidal/permeability-increasing protein. Blood 83, 2516–2525 (1994).
Oeth, P., Parry, G. & Mackman, N. Regulation of the tissue factor gene in human monocytic cells. Role of AP-1, NF-kappa B/Rel, and Sp1 proteins in uninduced and lipopolysaccharide-induced expression. Arterioscler. Thromb. Vasc. Biol. 17, 365–374 (1997).
Owens, A. & Mackman, N. Microparticles in Hemostasis and Thrombosis. Circ. Res. 108, 1284–1297 (2011).
Lindmark, E., Tenno, T. & Siegbahn, A. Role of platelet P-selectin and CD40 ligand in the induction of monocytic tissue factor expression. Arterioscler. Thromb. Vasc. Biol. 20, 2322–2328 (2000).
Franchi, F. & Angiolillo, D. J. Novel antiplatelet agents in acute coronary syndrome. Nat. Rev. Cardiol. 12, 30–47 (2015).
Harper, M. T., van den Bosch, M. T., Hers, I. & Poole, A. W. Platelet dense granule secretion defects may obscure alpha-granule secretion mechanisms: evidence from Munc13-4-deficient platelets. Blood 125, 3034–3036 (2015).
Barkalow, F., Barkalow, K. & Mayadas, T. Dimerization of P-selectin in platelets and endothelial cells. Blood 96, 3070–3077 (2000).
Panicker, S. et al. Circulating soluble P-selectin must dimerize to promote inflammation and coagulation in mice. Blood 130, 181–191 (2017).
Celi, A. et al. P-selectin induces the expression of tissue factor on monocytes. Proc Natl Acad Sci USA 91, 8767–8781 (1994).
del Conde, I. et al. Effect of P-selectin on phosphatidylserine exposure and surface-dependent thrombin generation on monocytes. Arterioscler. Thromb. Vasc. Biol. 25, 1065–1070 (2005).
Ridker, P. M., Buring, J. E. & Rifai, N. Soluble P-Selectin and the Risk of Future Cardiovascular Events. Circulation 103, 491–495 (2001).
Durrant, T., van den Bosch, M. & Hers, I. Integrin αIIbβ3 outside-in signaling. Blood 130, 1607–1619 (2017).
Judge, H., Buckland, R., Holgate, C. & Storey, R. Glycoprotein IIb/IIIa and P2Y12 receptor antagonists yield additive inhibition of platelet aggregation, granule secretion, soluble CD40L release and procoagulant responses. Platelets 16, 398–407 (2005).
Blair, T. A., Moore, S. F. & Hers, I. Circulating primers enhance platelet function and induce resistance to antiplatelet therapy. J. Thromb. Haemost. 13, 1479–1493 (2015).
Egorina, E. et al. Intracellular and surface distribution of monocyte tissue factor: application to intersubject variability. Arterioscler. Thromb. Vasc. Biol. 25, 1493–1498 (2005).
Rothmeier, A. et al. Tissue Factor Prothrombotic Activity Is Regulated by Integrin-arf6 Trafficking. Arterioscler. Thromb. Vasc. Biol. 37, 1323–1331 (2017).
Chen, V. M. & Hogg, P. J. Encryption and decryption of tissue factor. J. Thromb. Haemost. 11, 277–284 (2013).
Rao, L. V. M., Kothari, H. & Pendurthi, U. R. Tissue factor: mechanisms of decryption. Front. Biosci. (Elite Ed). 4, 1513–27 (2012).
Langer, F. et al. Rapid activation of monocyte tissue factor by antithymocyte globulin is dependent on complement and protein disulfide isomerase. Blood 121, 2324–35 (2013).
Ansari, S. A., Pendurthi, U. R. & Rao, L. V. M. The lipid peroxidation product 4-hydroxy-2-nonenal induces tissue factor decryption via ROS generation and the thioredoxin system. Blood Adv. 1, 2399–2413 (2017).
Kirchhofer, D., Riederer, M. A. & Baumgartner, H. R. Specific accumulation of circulating monocytes and polymorphonuclear leukocytes on platelet thrombi in a vascular injury model. Blood 89, 1270–1278 (1997).
Kuijper, P. et al. P-selectin and MAC-1 mediate monocyte rolling and adhesion to ECM-bound platelets under flow conditions. J. Leukoc. Biol. 64, 467–473 (1998).
Rainger, E. et al. The role of platelets in the recruitment of leukocytes during vascular disease. Platelets 26, 507–520 (2015).
Yokoyama, S. et al. Platelet P-selectin plays an important role in arterial thrombogenesis by forming large stable platelet-leukocyte aggregates. J Am Coll Cardiol 45, 1280–1286 (2005).
Prakash, P., Nayak, M. K. & Chauhan, A. K. P-selectin can promote thrombus propagation independently of both von Willebrand factor and thrombospondin1 in mice. J. Thromb. Haemost. 15, 388–394 (2017).
Falati, S. et al. Accumulation of Tissue Factor into Developing Thrombi In Vivo Is Dependent upon Microparticle P-Selectin Glycoprotein Ligand 1 and Platelet P-Selectin. J. Exp. Med. 197, 1585–1598 (2003).
Palabrica, T. et al. Leukocyte Accumulation Promoting Fibrin Deposition Is Mediated Invivo By P-Selectin On Adherent Platelets. Nature 359, 848–851 (1992).
III is supported by a British Heart Foundation PhD Studentship FS/16/53/32729 (to Prof. Martin Bennett). BHRA was supported by a Wellcome Trust Seed Award 200702/Z/16/Z. AMB is supported by BHF Programme Grant RG/15/4/31268.
The authors declare no competing interests.
Publisher’s note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
About this article
Cite this article
Ivanov, I.I., Apta, B.H.R., Bonna, A.M. et al. Platelet P-selectin triggers rapid surface exposure of tissue factor in monocytes. Sci Rep 9, 13397 (2019). https://doi.org/10.1038/s41598-019-49635-7
This article is cited by
Annals of Hematology (2020)