ALBERT

Description: Heparin-induced thrombocytopenia (HIT) is due to immunoglobulin G (IgG) antibodies, which bind platelet factor 4 (PF4) modified by polyanions, such as heparin (H). IgG/PF4/polyanion complexes directly activate platelets via Fc gamma type 2 receptor A (FcγRIIA) receptors. A bacterial protease, IgG-degrading enzyme of Streptococcus pyogenes (IdeS), cleaves the hinge region of heavy-chain IgG, abolishing its ability to bind FcγR, including FcγRIIA. We evaluated whether cleavage of anti-PF4/H IgG by IdeS could suppress the pathogenicity of HIT antibodies. IdeS quickly cleaved purified 5B9, a monoclonal chimeric anti-PF4/H IgG1, which led to the formation of single cleaved 5B9 (sc5B9), without any reduction in binding ability to the PF4/H complex. However, as compared with uncleaved 5B9, the affinity of sc5B9 for platelet FcγRIIA was greatly reduced, and sc5B9 was also unable to induce heparin-dependent platelet activation. In addition, incubating IdeS in whole blood containing 5B9 or HIT plasma samples led to cleavage of anti-PF4/H antibodies, which fully abolished the ability to induce heparin-dependent platelet aggregation and tissue factor messenger RNA synthesis by monocytes. Also, when whole blood was perfused in von Willebrand factor–coated microfluidic channels, platelet aggregation and fibrin formation induced by 5B9 with heparin was strongly reduced after IdeS treatment. Finally, IdeS prevented thrombocytopenia and hypercoagulability induced by 5B9 with heparin in transgenic mice expressing human PF4 and FcγRIIA receptors. In conclusion, cleavage of anti-PF4/H IgG by IdeS abolishes heparin-dependent cellular activation induced by HIT antibodies. IdeS injection could be a potential treatment of patients with severe HIT.

Description: Glycoprotein VI (GPVI), the main receptor for platelet activation by collagen, has been shown to play an important role in thrombosis, vascular remodelling and atherothrombosis. GPVI which belongs to the immunoglobulin receptor family, binds to fibrillar type I and type III collagens of vascular as well as non-vascular origin. 9O12.2, a high affinity monoclonal antibody directed to the GPVI extracellular domain, blocks GPVI binding to collagen and possess antithrombotic properties (Ohlmann et al J.Thromb. Haemost. 2008,6:1013). We have hypothesized that the 9O12.2 epitope overlaps, at least in part, with the collagen-binding site on GPVI and (ii) that molecules mimicking the 9O12.2 epitope can be expected to be antithrombotic by competing with platelet GPVI for binding to collagen and/or to act as tracers for collagen in vivo. A bacterial random 12 mer cyclic peptide library was screened against the 9O12.2 IgG. Twenty clones were selected. Sequencing the inserts revealed 9 peptidic motifs with 7 identical residues. One sequence was selected to synthesize a biotin-coupled constrained peptide. (designated collagelin). Surface plasmon resonance (SPR) analysis showed that 9O12.2 IgG bound to immobilized collagelin (KD 10−6M) and that binding was inhibited in the presence of soluble recombinant (sr)GPVI or after disulfide bridge reduction as expected for a molecule mimicking the 9O12.2 epitope known to be conformational (Lecut et al. J.Biol.Chem.2004, 279:52293). Using SPR and solid phase assays, we observed that collagelin bound to immobilized fibrillar collagen (KD10−7M) and that binding was inhibited by 9O12.2 IgG and by rsGPVI, indicating that collagelin mimics at least in part the collagen-binding site of GPVI. Collagelin did not inhibit collagen-induced platelet aggregation in vitro. However, histochemical analysis demonstrated that it bound to collagen on sections of rat aortas and of rat tail tendon. We then hypothesized that collagelin could be retained in vivo at sites of collagen accumulation, thus allowing isotopic imaging of fibrosis. Collagelin and a control peptide (same size and cyclic,) were labeled either indirectly using 99mTc-streptavidin or directly with 99mTc and iv injected into rats presenting fibrotic scars of myocardial infarction. Radiolabeled collagelin uptake in fibrosis areas was demonstrated in vivo by planar and tomographic scintigraphy. Mean heart-to-lung ratios were of 2.76±0.36 and 2.08±0.17 for 99m Tc-streptavidin-coupled collagelin and 99m Tc-collagelin respectively. Ex vivo, autoradiography on frozen heart sections showed a clear uptake of labeled-collagelin in the infarct collagen-rich scars with mean scar to remote myocardium activity ratios of 2.52±0.2 and 2.92±.053 for 99mTc-streptavidin-coupled collagelin and 99mTc-collagelin respectively as compared with 1.82±0.32 and 1.61±0.23 for the control peptides (p

Description: Background: Fibrin, the end product of the coagulation cascade, consolidates the platelet plug at site of thrombosis: polymerized fibrin supports platelet adhesion under low and high shear rate conditions (Hantgan RR et al., Thromb Haemost 1992) and triggers platelet procoagulant activity (Beguin S et al., Blood 1999). These responses are largely independent of the integrin αIIβ3 and are carried by a yet ill-defined receptor. Platelet glycoprotein VI (GPVI) has a well-established key role in the initiation of thrombosis since it supports collagen-mediated platelet activation but it has recently been recognized to interact with other macromolecules such as fibronectin, vitronectin and laminins. We hypothesized GPVI could be the “missing” platelet receptor of fibrin. Aim of the study: to challenge the hypothesis that glycoprotein VI (GPVI) could be a functional fibrin receptor Methods: Thrombin generation was measured using calibrated automated thrombogram (CAT) in PRP from healthy volunteers, four GPVI-deficient patients and one patient with a fibrinogen deficiency. CAT was also performed on washed platelets mixed with prothrombin complex (FII, FVII, FIX, FX), antithrombin and fibrinogen. GPVI was blocked using the Fab of the monoclonal antibody 9O12. Fibrin polymerization was blocked using the GPRP peptide. GPVI binding to fibrin was measured in vitro using recombinant soluble GPVI (GPVI-Fc). Flow based adhesion assays were performed in capillary chambers coated with polymerized fibrin at variable shear rates and platelet morphological changes analyzed by scanning electron microscopy. The formation of fibrin-platelet thrombi was visualized by perfusing recalcified blood containing A647 fibrinogen in flow chambers (Vena8 Fluoro+ Cellix) coated with collagen and tissue factor. In a second step, the perfusion of hirudinated blood in which platelets were stained by A488-RAM1 allowed to visualize platelet recruitment by fibrin rich clots. Results: Thrombin generation triggered by tissue factor was impaired in the PRP of patients with a GPVI deficiency or in the presence of the Fab 9O12 as indicated by a respective decrease in the peak height of 45 and 25% as compared to controls. This effect was observed regardless the trigger of thrombin generation and required platelet activation. Measuring thrombin generation in a purified system showed that fibrinogen dose-dependently increased the thrombin peak by up to 150% at 3 mg/mL but the Fab 9O12 blunted this effect. Moreover, the Fab 9O12 had no effect on thrombin generation in the PRP of a fibrinogen-deficient patient confirming a GPVI/fibrin(ogen)interplay. Blocking fibrin polymerization by GPRP reduced the thrombin peak in normal PRP, in fibrinogen-supplemented PRP of the fibrinogen-deficient patient and in purified conditions. In contrast GPRP had no effect on the thrombin peak in normal PRP containing the Fab 9O12 and in the PRP of GPVI-deficient patients. The proof that GPVI specifically interacts with fibrin was obtained in a binding assay showing a dose-dependent binding of GPVI-Fc to fibrin polymers that was reversed by the Fab 9O12. Platelets adhered to polymerized fibrin resulting in platelet shape change and exposure of phosphatidylserine. Platelet adhesion on a fibrin network was observed at low (300 s-1) and high (1500 s-1) shear rates with the formation of small contractile thrombi. Adhesion was decreased by 62% for 9O12-treated platelets and by 43% with the blood of GPVI-deficient mice as compared to controls. Importantly, lack of GPVI or its blockade decreased stationary adhesion indicating that GPVI is required to stabilize the interactions between platelets and fibrin. Finally when hirudinated blood was perfused at a shear rate of 1500 s-1 onto preformed fibrin-rich clots, the Fab 9O12 decreased the recruitment of platelets by up to 93%. Conclusions: Here we show for the first time that GPVI acts as a receptor for polymerized fibrin with two major functions: GPVI interaction with polymerized fibrin triggers (i) a new loop amplifying thrombin generation and (ii) platelet recruitment at the clot surface. These, so far, unrecognized properties of GPVI confer it a key role in the maturation of the thrombus by facilitating its growth and stabilization in addition to its well-known effect in the initiation of thrombus formation. Disclosures Jandrot-Perrus: Acticor Biotech: Other. Gachet:Acticor Biotech: Other.

Description: Myeloproliferative neoplasms (MPN) are associated with an increased risk of arterial and venous thrombosis. Besides clinical factors (previous history of thrombosis, age 〉 60 years, cardiovascular risk factors), procoagulant phenotype, proadhesive properties of the endothelium and secretion of inflammatory cytokines, contribute to the pathogenesis of thrombosis in MPN. Pegylated interferon alpha (IFN) has obviously a great therapeutic efficacy on hematopoietic cell proliferation but its other biological effects particularly on hemostasis and inflammation have not been determined. The aim of the study was to determine whether IFN impacts the biological profile including endothelial and platelet markers compared to MPN patients treated by hydroxyurea (HU) and non-treated (NT) patients. Patients with polycythemia vera (PV) or essential thrombocythemia (ET) treated with IFN or HU or without any cytostatic drug were included. Platelet membrane glycoproteins and platelet activation were measured by flow cytometry. We evaluated shear-induced platelet aggregation (SIPA) at 4000 sec-1 that mimics stenotic arteries. We measured coagulation proteins by their activity and endothelial parameters (von Willebrand factor (VWF) antigen and activity, soluble thrombomodulin). Thrombin generation was measured in platelet poor plasma and platelet rich plasma. Platelet accumulation on immobilized collagen was measured using whole blood perfused at 1500 sec-1 in flow chambers. Statistical analysis was performed by ANOVA to compare the 3 groups of patients (p

Description: Abstract 3194 In the blood, platelets are normally prevented from activation by endothelial inhibitors (i.e. prostacycline, ectonucleotidase). Dysfunctional endothelial cells loose their protective properties and favor platelet adhesion to matrix proteins, platelet aggregation and thrombus growth. Collagen fibers are highly thrombogenic and the platelet Glycoprotein (GP)VI predominantly mediates collagen-induced platelet responses. GPVI is a platelet specific receptor of the immunoglobulin (Ig) superfamily containing two extracellular Ig domains, a single transmembrane domain and a short cytoplasmic tail. GPVI signals through the immunoreceptor tyrosine-based activation motifs (ITAM) of the non-covalently associated immune receptor adaptor FcRg dimer. There is growing evidence that optimal binding of GPVI to collagen depends on the formation of GPVI dimers at the platelet surface: only dimeric GPVI binds to collagen and inhibits collagen-induced platelet aggregation and not monomeric GPVI. Moreover, crystallographic data showed dimerization of GPVI ectodomains. However, the valence of GPVI on resting and activated platelets is still debated. We have obtained an anti-human GPVI monoclonal antibody (9E18), that binds to dimeric GPVI with a 200 fold higher affinity than to monomeric GPVI. In flow cytometry on whole blood, while the 3J24 antibody labels 〉95% platelets, 9E18 hardly binds to resting platelets with less than 3% positive platelets. The level of 9E18-positive platelets moderately increased (10-15%) after platelet isolation suggesting it could reflect platelet activation. Binding of 9E18 was indeed significantly increased on ADP- or TRAP-activated washed platelets (25±1.9 % and 36±7% positive platelets respectively). Additionally, increased binding of 9E18 was triggered by the GPVI agonists, collagen, convulxin or the activating 9O12 IgG. At sites of vascular lesion, platelet adhesion is initiated by the shear-dependent interaction of GPIb with vWF, assumed to favor GPVI-collagen interaction. When a platelet rich plasma was submitted to a shear of 4000 s-1 for 5 min, 9E18-positive platelets increased from 3.6±1.6% to 7±2% in the whole platelet population and to 26±7.7% on small aggregates (p

Description: Heparin-induced thrombocytopenia (HIT) is a severe drug-adverse event due to platelet-activating antibodies (Abs) directed against platelet factor 4 (PF4)/heparin (H) complexes. In most patients, HIT Abs are IgG that directly activate platelets and monocytes in the presence of heparin via FcγRIIA receptors. The interaction between the Fc fragment of anti-PF4/H IgG and FcγRIIA is thus a key step for cellular activation in HIT. Several bacterial proteases such as IdeS (IgG-degrading enzyme of Streptococcus pyogenes) are cleaving IgG in the lower hinge region of heavy chain leading to the formation of single cleaved IgG (scIgG) and then of Fab'2. Importantly, cleavage of IgG by IdeS can abolish their ability to bind FcγR and suppress the cellular effects resulting from this interaction. The aim of this study was therefore to evaluate whether anti-PF4/H IgG cleavage by IdeS could inhibit cell activation induced by HIT antibodies, and their pathogenicity. To achieve this objective, we studied the effects of IdeS on platelet responses to 5B9, a monoclonal chimeric anti-PF4/H IgG1 recently developed in our laboratory, and which fully mimics the effects of human HIT antibodies (Kizlik-Masson et al, J Thromb Haemost, 2017). IdeS was demonstrated to quickly (6 minutes) cleave purified 5B9 IgG, leading to the formation of sc5B9, without any reduction in its binding ability to PF4/H complex. However, flow cytometry experiments showed that heparin-dependent binding of sc5B9 to platelets and FcγRIIA was dramatically reduced compared to those of uncleaved 5B9. In addition, functional assays (serotonin release assays and platelet aggregation tests) also confirmed that sc5B9 was unable to induce platelet activation and aggregation in the presence of heparin. Incubation of IdeS (0.02 U/µg of IgG; 6 minutes) in whole blood containing 5B9 IgG or HIT plasma samples also lead in every sample tested to the cleavage of anti-PF4/H Abs, which fully abolished their capacity to induce heparin-dependent platelet aggregation, as demonstrated by impedance aggregometry (Multiplate analyzer). As expected, no effect of IdeS was observed on platelet aggregation induced by collagen (1 µg/mL), or ADP (10 µM). Moreover, tissue factor (TF) gene expression induced in monocytes by 5B9 in the presence of heparin was also completely abolished after addition of IdeS (0.02 U/µg of IgG; 6 minutes) in whole blood, whereas no inhibitory effect of this protease on TF expression induced by LPS was evidenced. We also showed that platelet aggregation and fibrin formation induced by 5B9 with heparin was completely inhibited after IdeS treatment when whole blood was perfused in vWF-coated microfluidic channels with shear rates similar to those of venous flow (500s-1). Finally, IdeS was also showed to prevent efficiently thrombocytopenia and hypercoagulability (with no increase in thrombin/anti-thrombin plasma levels) induced by 5B9 in transgenic mice expressing human PF4 and FcγRIIA receptors, when previously treated by this protease (0.5 µg/g) before IV injection of heparin. In conclusion, the cleavage of anti-PF4/H IgG by IdeS prevents heparin-dependent cellular activation induced by HIT antibodies, thereby reducing their pathogenicity. Therefore, injection of IdeS could be considered as a potential treatment in patients with severe HIT, particularly in those who necessitate emergent cardiac surgery with cardiopulmonary bypass and thus anticoagulation with unfractionated heparin, which remains the safest and easiest anticoagulant to be used in this specific surgical procedure. Disclosures No relevant conflicts of interest to declare.

Description: The ephrin transmembrane receptor family of tyrosine kinases is involved in platelet function. We report the first EPHB2 variant affecting platelets in 2 siblings (P1 and P2) from a consanguineous family with recurrent bleeding and normal platelet counts. Whole-exome sequencing identified a c.2233C〉T variant (missense p.R745C) of the EPHB2 gene. P1 and P2 were homozygous for this variant, while their asymptomatic parents were heterozygous. The p.R745C variant within the tyrosine kinase domain was associated with defects in platelet aggregation, αIIbβ3 activation, and granule secretion induced by G-protein–coupled receptor (GPCR) agonists and convulxin, as well as in thrombus formation on collagen under flow. In contrast, clot retraction, flow-dependent platelet adhesion, and spreading on fibrinogen were only mildly affected, indicating limited effects on αIIbβ3 outside-in signaling. Most importantly, Lyn, Syk, and FcRγ phosphorylation, the initial steps in glycoprotein VI (GPVI) platelet signaling were drastically impaired in the absence of platelet–platelet contact, indicating a positive role for EPHB2 in GPVI activation. Likewise platelet activation by PAR4-AP showed defective Src activation, as opposed to normal protein kinase C activity and Ca2+ mobilization. Overexpression of wild-type and R745C EPHB2 variant in RBL-2H3 (rat basophilic leukemia) cells stably expressing human GPVI confirmed that EPHB2 R745C mutation impaired EPHB2 autophosphorylation but had no effect on ephrin ligand-induced EPHB2 clustering, suggesting it did not interfere with EPHB2-ephrin–mediated cell-to-cell contact. In conclusion, this novel inherited platelet disorder affecting EPHB2 demonstrates this tyrosine kinase receptor plays an important role in platelet function through crosstalk with GPVI and GPCR signaling.

Description: Abstract 818 Fibrinolysis, a physiological process leading to clot resorbtion, is strictly controlled by fibrin-localized plasminogen activators (tPA and uPA) and by inhibitors like plasminogen activator type-1 (PAI-1). The serpin PAI-1 is a plasmatic serine protease inhibitor, that is also stored in platelets α-granules. PAI-1 inhibits both the action of urokinase- and tissue-type plasminogen activators (uPA and tPA respectively), and is up to now considered as the principal inhibitor of fibrinolysis in vivo. Interestingly, platelets are also known to inhibit fibrinolysis by both PAI-1-dependent and PAI-1-independent mechanisms. The individual role of other serpins, specifically protease nexin-1 (PN-1) in the thrombolytic process has not been investigated so far. Indeed, we recently demonstrated that a significant amount of PN-1 is stored within the α-granules of platelets and plays an antithrombotic function in vivo. PN-1, also known as SERPINE2, deserves a special interest since it also significantly inhibits in vitro uPA, tPA and plasmin. In this study, we explored the effect of PN-1 on fibrinolysis in vitro and in vivo. We evidenced the antifibrinolytic activity of platelet PN-1 in vitro using a specific PN-1-blocking antibody and PN-1 deficient platelets and, in vivo in PN-1−/− mice. Our data directly indicate that platelet PN-1 inhibits both tPA and plasmin activities in fibrin zymography. Remarkably, whereas fibrin-bound tPA or plasmin activity is not affected by PAI-1, we showed that PN-1 inhibits both plasmin generation induced by tPA-bound to fibrin and fibrin-bound plasmin. Moreover, PN-1 blockade or PN-1 deficiency result in an increased lysis of fibrin clots generated from platelet-rich plasma indicating that PN-1 regulates endogenous tPA-mediated lysis. Rotational thromboelastometry (ROTEM®) analysis shows that platelet PN-1 significantly decreases the rate of fibrinolysis ex vivo. Futhermore, blockade or deficiency of PN-1 provides direct evidence for an acceleration of the lysis-front velocity in platelet-rich clots. To challenge the role of PN-1 on fibrinolysis in vivo, we have developed an original murine model of thrombolysis. Using a dorsal skinfold chamber, thrombus formation induced by ferric chloride injury of venules and subsequent thrombolysis were visualized by microscopy on alive animals. This new approach allows a reproducible quantification of thrombus formation and of tPA- induced thrombus lysis. We observed that thrombi are more readily lysed in PN-1-deficient mice than in wild-type mice. Moreover, in PN-1 deficient mice, the rate and the extent of reperfusion were both increased (Figure A and B). These data demonstrate that platelet PN-1 is a new negative regulator of thrombolysis activity of plasmin, both in solution and within the clot. For the first time, this study shows that PN-1 protects towards thrombolysis and therefore could give rise to new approaches for therapeutic application. Indeed, PN-1 might be a promising target for optimizing thrombolytic therapy by tPA. Figure : Effect of PN-1 on thrombolysis. (A) Representative intravital images of vessels reperfusion after tPA treatment in dorsal skinfold chamber. (B) Quantification of the incidence of reperfused vessels within 1 hour post tPA treatment Figure :. Effect of PN-1 on thrombolysis. (A) Representative intravital images of vessels reperfusion after tPA treatment in dorsal skinfold chamber. (B) Quantification of the incidence of reperfused vessels within 1 hour post tPA treatment Disclosures: No relevant conflicts of interest to declare.

Description: Key Points GPVI-dependent platelet binding and activation contribute to seal neutrophil-induced vascular damage in IC-mediated inflammation. Inflammation represents an uncommon hemostatic situation in which adhesion and activation of single platelets prevent bleeding.

Description: Key PointsGPVI interaction with polymerized fibrin triggers a new loop amplifying thrombin generation and platelet recruitment at the clot surface.