阻断血管性血友病因子与胶原结合的抗人vWF-A3单抗的鉴定和功能研究

目的 制备阻断血管性血友病因子(von Willebrand因子)A3区(vWF-A3)与胶原结合的抗vWF-A3单抗,并对其进行生化鉴定和功能研究.方法 用重组vWF-A3蛋白免疫BALB/c小鼠,经标准的方法制备单抗.用ELISA法鉴定单抗特异性,经vWF胶原结合抑制试验筛选获得抑制性单抗,用免疫印迹技术确定单抗与重组(r)vWF-A3和还原性人vWF识别的抗原分子.经胶原结合试验确定单抗对vWF与胶原结合的影响.结果 获得一组共30株抗vWF-A3单抗,其中两株确定为抑制vWF与胶原结合的单抗,分别命名为SZ-123和SZ-125,两株单抗分别与rvWF-A3和vWF强反应,而不与rvWF-A1、A2反应.免疫印迹分析显示SZ-123和SZ-125分别识别相对分子质量为27×103的rvWF-A3、250×103还原性人vWF单体和170×103的vWF酶切片段.单抗SZ-123和SZ-125不仅剂量依赖性地抑制纯化的人血浆vWF与人胎盘和牛皮肤Ⅲ型胶原结合,而且分别抑制人、猕猴或Beagle犬血浆vWF与人胎盘和牛皮肤Ⅲ型胶原结合.结论 抗vWF-A3单抗SZ-123和SZ-125是两株抑制性单抗,有望成为具有治疗潜力的抗血栓药物.     

alphaIIbbeta3 antagonism vs. antiadhesive treatment to prevent platelet interactions with vascular subendothelium.

Platelets adhering to blood vessels promote coagulation and inflammation, and release growth factors that trigger smooth muscle cell activation. We have therefore studied the pharmacological modification of platelet deposition quantitatively by comparing adhesion of flowing platelets to various subendothelial ligands in the absence or presence of an antialpha(IIb)beta(3) antagonist with the effects of antiadhesive treatment consisting of von Willebrand factor (VWF) and fibronectin neutralization or of the combined inhibition of platelet adhesion and aggregation. In vitro, perfusion of anticoagulated human blood over calf skin collagen reiterated that alpha(IIb)beta(3) antagonism prevents platelet aggregation, but not adhesion per se: single platelets strongly bound to collagen at wall shear rates of both 1300 and 2700 s(-1), largely VWF-independent. When perfused over a human umbilical vein endothelial cell-derived extracellular matrix, single alpha(IIb)beta(3)-antagonized platelets primarily adhered to matrix-bound VWF when perfused at 2700 s(-1), but at 1300 s(-1) they also adhered significantly to fibronectin. During perfusion of anticoagulated rabbit blood over de-endothelialized rabbit aorta at a wall shear rate of 1100 s(-1), alpha(IIb)beta(3) antagonism even increased the absolute numbers of adhering platelets and VWF neutralization redirected alpha(IIb)beta(3)-antagonized platelets towards other vascular ligands. Finally, in vivo, following photochemically induced blood vessel injury in mice, alpha(IIb)beta(3) antagonism inhibited platelet-rich thrombus formation, but platelet adhesion was only significantly inhibited when associated with fibronectin neutralization. In conclusion, antiadhesive platelet treatment more potently interferes with platelet deposition on injured blood vessels than alpha(IIb)beta(3) antagonism, but abrogating platelet adhesion can only be achieved by carefully selected antiplatelet drug combinations.     

Platelet adhesion to multimerin 1 in vitro: influences of platelet membrane receptors, von Willebrand factor and shear

Summary.  Background : Multimerin 1 (MMRN1) is a large, homopolymeric adhesive protein, stored in platelets and endothelium, that when released, binds to activated platelets, endothelial cells and the extracellular matrix. Objectives : The goals of our study were to determine if (i) MMRN1 supports adhesion of resting and/or activated platelets under conditions of blood flow, and (ii) if MMRN1 enhances platelet adhesion to types I and III collagen. Patients / methods : Platelet adhesion was evaluated using protein-coated microcapillaries, with or without added adhesive proteins and receptor antibodies. Platelets from healthy controls, Glanzmann thrombasthenia (GT) and severe von Willebrand factor (VWF)-deficient donors were tested. Results : MMRN1 supported the adhesion of activated, but not resting, washed platelets over a wide range of shear rates. At low shear (150 s⁻¹), this adhesion was supported by integrins αvβ3 and glycoprotein (GP) Ibα but it did not require integrins αIIbβ3 or VWF. At high shear (1500 s⁻¹), adhesion to MMRN1 was supported by β3 integrin-independent mechanisms, involving GPIbα and VWF, that did not require platelet activation when VWF was perfused over MMRN1 prior to platelets. MMRN1 bound to types I and III collagen, independent of VWF, however, its enhancing effects on platelet adhesion to collagen at high shear were VWF dependent. Conclusions : MMRN1 supports platelet adhesion by VWF-dependent and -independent mechanisms that vary by flow rate. Additionally, MMRN1 binds to, and enhances, platelet adhesion to collagen. These findings suggest that MMRN1 could function as an adhesive ligand that promotes platelet adhesion at sites of vascular injury.     

A mechanism to safeguard platelet adhesion under high shear flow: von Willebrand factor–glycoprotein Ib and integrin α2β1–collagen interactions make complementary, collagen-type-specific contributions to adhesion

BACKGROUND: Blood vessels contain different types of collagen, with types I and III being the major components of vascular collagen. Platelet adhesion under high shear stress has been suggested to depend on the binding of von Willebrand factor (VWF) to collagen. OBJECTIVE: We analyzed the collagen type specificity for the interaction with VWF and high shear stress platelet adhesion. METHODS: VWF binding to different types of immobilized collagen and effects of antibodies against glycoprotein Ib (gpIb) and integrin alpha(2)beta(1) on platelet adhesion to type I and III collagens under high shear were analyzed. RESULTS: VWF showed high-affinity, selective binding to human and bovine type III collagens, but weak or no affinity for types I, II, IV and V under static conditions. Anti-integrin alpha(2)beta(1) markedly inhibited adhesion to type I collagen, but did not affect that to type III collagen. Anti-gpIb antibody significantly inhibited adhesion to type III collagen. Adding both antibodies abrogated the adhesion to either type I or III collagen. CONCLUSIONS: Both the gpIb-VWF interaction and the integrin alpha(2)beta(1)-collagen interaction contribute to platelet adhesion to collagen under high shear stress, and integrin alpha(II)beta(1) makes a greater contribution to adhesion to type I collagen because less VWF is bound to it.     

Identification of a VWF peptide antagonist that blocks platelet adhesion under high shear conditions by selectively inhibiting the VWF-collagen interaction

Summary.  Background : Because the collagen-VWF-GPIb/IX/V axis plays an important role in thrombus formation, it represents a promising target for development of new antithrombotic agents. Objectives : We used phage display to identify potential small peptides that interfere with the VWF-collagen binding and might serve as lead products for the development of possible oral antithrombotic compounds. Methods : A random linear heptamer peptide library was used to select VWF-binding peptides. Results : We identified a phage clone, displaying the YDPWTPS sequence, further referred to as L7-phage, that bound to VWF in a specific and a dose-dependent manner. This L7-phage specifically inhibited the VWF-collagen interaction under both static and flow conditions. Epitope mapping using deletion mutants of VWF revealed that the L7-phage does not bind to the known collagen-binding A3 domain within VWF, but to the more carboxyterminal situated C domain. This inhibition was not due to steric hindrance of the A3 domain-collagen interaction by the L7-phage. Indeed, a tetrabranched multi-antigen peptide (MAP) presenting four copies of the peptide, but not the scrambled MAP, also inhibited VWF-collagen interaction under conditions of high shear stress at a concentration of 148 nmol L⁻¹. Conclusions : Based on these results, we conclude that we have identified the first peptide antagonist that binds to the VWF C domain and by this specifically inhibits the VWF binding to collagen, suppressing platelet adhesion and aggregation under high shear conditions. As a consequence, this peptide and its future derivates are potentially interesting antithrombotic agents.     

von Willebrand factor A1 domain can adequately substitute for A3 domain in recruitment of flowing platelets to collagen

BACKGROUND: Binding of von Willebrand factor (VWF) to platelet GPIbalpha and to collagen is attributed to VWF A1 and A3 domains, respectively. OBJECTIVES: Using VWF, VWF lacking A1 (DeltaA1-VWF) or A3 (DeltaA3-VWF) and VWF with defective A3 (H1786A-VWF), in combination with recombinant A1 (residues 1262-1492) or A3 (residues 1671-1878), fused to glutathione-S-transferase (GST-A1 and GST-A3), we have re-investigated the role of A1 in platelet recruitment to surfaces of collagen. METHODS AND RESULTS: In flow, measurable binding of DeltaA3-VWF occurred to horse tendon, but also to human type III collagen. GST-A1 and GST-A3 both competed for binding of DeltaA1-VWF and DeltaA3-VWF to horse tendon collagen fibrils in static conditions and to human collagen III during plasmon surface resonance studies, substantiating overlapping binding sites on both collagens for A1 and A3. Heparin did not affect A3-mediated binding of VWF and DeltaA1-VWF, but inhibited binding to horse tendon collagen of GST-A1 and DeltaA3-VWF. Furthermore, A1-mediated binding to type III collagen of DeltaA3-VWF binding was strongly salt-sensitive. During perfusions at wall shear rate 2500 s(-1) of calcein-labeled platelets in reconstituted blood, DeltaA3-VWF and H1786A-VWF triggered platelet binding to horse tendon collagen comparably and as potently as VWF, and to human type III collagen, only fivefold less potently, DeltaA1-VWF being inactive. Additional flow-controlled interaction studies with DeltaA3-VWF, H1786A-VWF, the collagen-VWF antagonist saratin, heparin and the VWF neutralizing antibody 82D6A3 confirmed that H1786A-VWF binds to collagen exclusively via A1. CONCLUSION: Hence, in shear forces the VWF A1 domain can assume the role of A3 to trigger substantial platelet recruitment to human collagen fibres.     

Von Willebrand factor and ADAMTS13 balancing primary haemostasis

Von Willebrand factor (VWF) is an adhesive, multi-functional huge multimerized protein with multiple domains harboring binding sites for collagen, platelet glycoprotein receptors and coagulation factor VIII (FVIII). The functional domains enable VWF to bind to the injured vessel wall, to recruit platelets to the site of injury by adhesion and aggregation and to bind and protect FVIII, an important cofactor of the coagulation cascade. VWF function in primary haemostasis is located in particular in the arterial and micro-circulation. This environment is exposed to high shear forces with hydrodynamic shear rates ranging over several orders of magnitude from 10?1 to 10? s-1 and requires particular mechanisms to enable platelet adhesion and aggregation under these variable conditions. The respective VWF function is strictly correlating with its multimer size. Lack or reduction of large VWF multimers is seen in patients with von Willebrand disease (VWD) type 2A which correlates with reduction of both VWF:platelet GPIb-binding and VWF:collagen binding and a bleeding phenotype. To prevent unlimited platelet adhesion and aggregation which is the cause of the microangiopathic disorder thrombotic thrombocytopenic purpura (TTP), VWF function is regulated by its specific protease ADAMTS13. Whereas a particular susceptibility of VWF to ADAMTS13 proteolysis is the cause of a frequent VWD type 2A phenotype, lack or dysfunction of ADAMTS13, either acquired by ADAMTS13 antibodies or by inherited ADAMTS13 deficiency (Upshaw-Schulman Syndrome), causes TTP. Therefore VWD and TTP represent the opposite manifestations of VWF related disorders, tightly linked to each other.     

Functional domains on von Willebrand factor. Recognition of discrete tryptic fragments by monoclonal antibodies that inhibit interaction of von Willebrand factor with platelets and with collagen

We have identified two functional domains on the von Willebrand factor (VWF) moiety of the Factor VIII-von Willebrand factor complex (FVIII-VWF), one interacting with blood platelets, and one interacting with vessel wall collagens, by means of two monoclonal antibodies directed against the VWF molecule, CLB-RAg 35 and CLB-RAg 201. The monoclonal antibody CLB-RAg 35 inhibited virtually all platelet adherence to artery subendothelium and to purified vessel wall collagen type III, at relatively high wall shear rates. CLB-RAg 35 also inhibited the ristocetin-induced platelet aggregation and the binding of FVIII-VWF to the platelet in the presence of ristocetin but did not affect the binding of FVIII-VWF to collagen. The monoclonal antibody CLB-RAg 201 inhibited the binding of FVIII-VWF to purified vessel wall collagen type I and III and all platelet adherence to collagen type III and the platelet adherence to subendothelium that was mediated by FVIII-VWF in plasma. The two functional domains on FVIII-VWF that were recognized by CLB-RAg 35 and CLB-RAg 201 were identified by means of immunoprecipitation studies of trypsin-digested FVIII-VWF. The domains resided on different polypeptide fragments, with a Mr of 48,000 for the collagen binding domain and a Mr of 116,000 for the platelet binding domain. The 116,000-mol wt fragment consisted of subunits of 52,000/56,000 mol wt and 14,000 mol wt after reduction. The 52,000/56,000-mol wt subunits possessed the epitope for CLB-RAg 35.     

Inhibition of adhesive and signaling functions of the platelet GPIb-V-IX complex by a cell penetrating GPIbα peptide

BACKGROUND: Interaction between the platelet glycoprotein (GP)Ib-V-IX complex and von Willebrand factor (VWF) is critical for initiating platelet-vessel wall contacts, particularly under high shear conditions. This interaction also plays an important role in initiating platelet activation through the generation of intracellular signals resulting in platelet shape change and integrin alpha(IIb)beta3 activation. OBJECTIVE: A cell-penetrating peptide strategy was used to study the role of the intracellular domain of the GPIbalpha subunit in VWF/GPIb-V-IX-dependent adhesion and activation. METHODS: Peptides of 11-13 amino acids, covering the 557-610 region, were coupled to a nine-arginine permeating tag (R9) and the effects of their cell entry on VWF-dependent responses were analyzed. RESULTS: The R9alpha557 peptide corresponding to the 557-569 segment reduced platelet agglutination in response to VWF, while the other peptides had no effect. The decreased platelet agglutination appeared to be an indirect consequence of adenosine diphosphate release as a normal response was restored by apyrase or a P2Y1 receptor antagonist. A more direct effect of R9alpha557 on GPIb VWF-dependent functions was observed in adhesion studies on a VWF matrix, where it decreased platelet adhesion and profoundly inhibited filopodia formation. In addition, cell adhesion was reduced and shape change absent when Chinese hamster ovary cells expressing the GPIb-IX complex were incubated with R9alpha557. CONCLUSION: This study performed in intact platelets suggests a functional role of the 557-569 domain of GPIbalpha in controlling VWF-dependent adhesion and signaling.     

A palmitylated peptide derived from the glycoprotein Ibβ cytoplasmic tail inhibits platelet activation

Summary.  The platelet receptor GPIb/IX/V mediates a crucial role in hemostasis, yet the signaling mechanisms involved are incompletely understood. The complex consists of four polypeptides GPIbα, GPIbβ, GPIX and GPV. We identified an amino acid sequence in the cytoplasmic tail of the GPIbβ subunit between residues R151 and A161 that is highly conserved across species and hypothesized that it has functional importance. To target this motif, we synthesized a corresponding cell-permeable palmitylated peptide (Pal-RRLRARARARA) and investigated its effect on platelet function. Pal-RRLRARARARA completely inhibited low dose thrombin- and ristocetin-induced aggregation in washed platelets but only partially inhibited collagen- and U46619-induced aggregation. Thromboxane production in platelets stimulated with thrombin was significantly reduced by Pal-RRLRARARARA compared with collagen. Activation of the integrin α_IIbβ₃ in response to thrombin was significantly reduced when platelets were preincubated with Pal-RRLRARARARA. The adhesion of washed platelets to von Willebrand factor (VWF) under static conditions was significantly reduced by Pal-RRLRARARARA. Under conditions of high shear, the velocity of platelets rolling on VWF was significantly increased when platelets are preincubated with Pal-RRLRARARARA. This study defines a novel function for the RRLRARARARA motif of GPIbβ in platelet activation.     

Alcohol and polyphenolic grape extract inhibit platelet adhesion in flowing blood

BACKGROUND: Moderate and prolonged alcohol consumption has been associated with decreased cardiovascular morbidity and mortality. Inhibition of platelet function in suspension attributes to these effects. Whether alcohol, red wine, or polyphenolic grape extracts (PGE) inhibit platelet adhesion is not known. We investigated platelet adhesion to fibrinogen and collagen in whole blood under standardised flow. MATERIALS AND METHODS: Before perfusion was started, citrated whole blood from 95 volunteers was preincubated for five min with different alcohol concentrations, unfractioned red wine and PGE. Then, blood was perfused in a single-passage flow chamber over coverslips coated with human fibrinogen or collagen type III at shear rates of 300 s(-1) and 1600 s(-1). RESULTS: Alcohol inhibited platelet adhesion to human fibrinogen at high shear rate (concentrations > or = 0.15 per thousand) and low shear rate (only at a concentration of 4.8 per thousand), whereas red wine (concentrations > or = 0.15 per thousand) inhibited platelet adhesion to human fibrinogen at both shear rates. In contrast, PGE (concentrations > or = 0.0225 g L(-1)) inhibited platelet adhesion to human fibrinogen only at low shear rate. None of these incubations affected adhesion to collagen. CONCLUSIONS: Alcohol, red wine and PGE inhibit adhesion to fibrinogen but not to collagen. This inhibition might contribute to the cardioprotective effects of moderate alcohol consumption.     

Inhibition of von Willebrand factor-mediated platelet activation and thrombosis by the anti-von Willebrand factor A1-domain aptamer ARC1779

Summary.  Background: von Willebrand factor (VWF) has a role in both hemostasis and thrombosis. Platelets adhere to damaged arteries by interactions between the VWF A1-domain and glycoprotein Ib receptors under conditions of high shear. This initial platelet binding event stimulates platelet activation, recruitment, and activation of the clotting cascade, promoting thrombus formation. Objective: To characterize the inhibitory activity of a VWF inhibitory aptamer. Methods: Using in vitro selection, aptamer stabilization, and conjugation to a 20-kDa poly(ethylene glycol), we generated a nuclease-resistant aptamer, ARC1779, that binds to the VWF A1-domain with high affinity ( K _D ∼ 2 n m ). The aptamer was assessed for inhibition of VWF-induced platelet aggregation. In vitro inhibition of platelet adhesion was assessed on collagen-coated slides and injured pig aortic segments. In vivo activity was assessed in a cynomolgus monkey carotid electrical injury thrombosis model. Results and Conclusion: ARC1779 inhibited botrocetin-induced platelet aggregation (IC₉₀ ∼ 300 n m ) and shear force-induced platelet aggregation (IC₉₅ ∼ 400 n m ). It reduced adhesion of platelets to collagen-coated matrices and formation of platelet thrombi on denuded porcine arteries. ARC1779 also inhibited the formation of occlusive thrombi in cynomolgus monkeys. We have discovered a novel anti-VWF aptamer that could have therapeutic use as an anti-VWF agent in the setting of VWF-mediated thrombosis.     

A monoclonal antibody directed against human von Willebrand factor induces type 2B-like alterations.

We have previously described a monoclonal antibody (mAb), 1C1E7, against von Willebrand factor (VWF), that increases ristocetin-induced platelet aggregation (RIPA) and induces a preferential binding of the high-molecular-weight multimers of VWF to platelet GPIb. Further investigations using a rotational viscometer at a shear rate of 4000 s(-1) could now demonstrate that shear-induced platelet aggregation (SIPA) is significantly increased with 1C1E7 and that this could be completely inhibited by the anti-GPIb mAb 6D1. In contrast, platelet adhesion to a collagen surface at a shear rate of 2600 s(-1), using a rectangular perfusion chamber, was significantly inhibited in the presence of 1C1E7. When citrated whole blood was incubated with 1C1E7, a spontaneous binding of VWF to the platelet GPIb could be demonstrated by flow cytometric analysis. Parallel to this, a decrease of the highest molecular weight multimers of VWF in the plasma was found. Platelets with bound VWF on their surface were able to form macroaggregates but were no longer able to adhere. These phenomena are very similar to the alterations described in von Willebrand's disease type 2B. The epitope of this mAb could be localized to the N-terminal part of the subunit; therefore a distant conformational change in the A1 domain of VWF is suggested.     

Comparison of type I,type III and type VI collagen binding assays in diagnosis of von Willebrand disease

Summary. Background: von Willebrand factor (VWF) plays a key role in coagulation by tethering platelets to injured subendothelium through binding sites for collagen and platelet GPIb. Collagen binding assays (VWF:CB), however, are not part of the routine work‐up for von Willebrand disease (VWD). Objectives: This study presents data on collagen binding for healthy controls and VWD subjects to compare three different collagens. Patients/Methods: VWF antigen (VWF:Ag), VWF ristocetin cofactor activity and VWF:CB with types I, III and VI collagen were examined for samples obtained from the Zimmerman Program. Results: Mean VWF:CB in healthy controls was similar and highly correlated for types I, III and VI collagen. The mean VWF:CB/VWF:Ag ratios for types I, III and VI collagen were 1.31, 1.19 and 1.21, respectively. In type 1 VWD subjects, VWF:CB was similar to VWF:Ag with mean VWF:CB/VWF:Ag ratios for types I, III and VI collagen of 1.32, 1.08 and 1.1, respectively. For type 2A and 2B subjects, VWF:CB was uniformly low, with mean ratios of 0.62 and 0.7 for type I collagen, 0.38 and 0.4 for type III collagen, and 0.5 and 0.47 for type VI collagen. Conclusions: Normal ranges for type I, III and VI collagen are correlated, but higher values were obtained with type I collagen as compared with types III and VI. The low VWF:CB in type 2A and 2B subjects suggests that VWF:CB may also supplement analysis of multimer distribution. However, these results reflect only one set of assay conditions per collagen type and therefore may not be generalizable to all collagen assays.     

The glycoprotein Ibα–von Willebrand factor interaction induces platelet apoptosis

Summary. Background: The interaction of glycoprotein (GP) Ibα with von Willebrand factor (VWF) initiates platelet adhesion, and simultaneously triggers intracellular signaling cascades leading to platelet aggregation and thrombus formation. Some of the signaling events are similar to those occurring during apoptosis, however, it is still unclear whether platelet apoptosis is induced by the GPIbα–VWF interaction. Objectives: To investigate whether the GPIbα–VWF interaction induces platelet apoptosis and the role of 14‐3‐3ζ in apoptotic signaling. Methods: Apoptotic events were assessed in platelets or Chinese hamster ovary (CHO) cells expressing wild‐type (1b9) or mutant GPIb–IX interacting with VWF by flow cytometry or western blotting. Results: Ristocetin‐induced GPIbα–VWF interaction elicited apoptotic events in platelets, including phosphatidylserine exposure, elevations of Bax and Bak, gelsolin cleavage, and depolarization of mitochondrial inner transmembrane potential. Apoptotic events were also elicited in platelets exposed to pathologic shear stresses in the presence of VWF; however, the shear‐induced apoptosis was eliminated by the anti‐GPIbα antibody AK2. Furthermore, apoptotic events occurred in 1b9 cells stimulated with VWF and ristocetin, but were significantly diminished in two CHO cell lines expressing mutant GPIb–IX with GPIbα truncated at residue 551 or a serine‐to‐alanine mutation at the 14‐3‐3ζ‐binding site in GPIbα. Conclusions: This study demonstrates that the GPIbα–VWF interaction induces apoptotic events in platelets, and that the association of 14‐3‐3ζ with the cytoplasmic domain of GPIbα is essential for apoptotic signaling. This finding may suggest a novel mechanism for platelet clearance or some thrombocytopenic diseases.     

The interaction of von Willebrand factor-A1 domain with collagen: mutation G1324S (type 2M von Willebrand disease) impairs the conformational change in A1 domain induced by collagen

BACKGROUND: It is established that the A3 domain in von Willebrand factor (VWF) contains the major collagen-binding site. However, there are conflicting reports describing the capacity of the A1 domain to interact with collagen types I and III. METHODS: In this study, we have used recombinant VWF-A1 polypeptides, as well as conformation-specific monoclonal antibodies (mAb), to analyze the A1-collagen interaction. RESULTS: The A1 domain bound to collagen with K(d) approximately 8.0 nm and this binding was blocked by the mAb 6G1, which blocks the interaction between ristocetin and VWF. In addition, collagen-bound A1 protein was able to support flow-dependent adhesion of platelets, demonstrating that the binding sites for collagen and glycoprotein (GP)Ib are different. Analysis with two conformation-specific mAb demonstrated that the structure of the A1 domain changed as a result of the binding to collagen. In contrast, the antibodies failed to detect conformational change in the G1324S mutant (type 2M von Willebrand disease). Thus, direct binding to collagen induces a change in the structural conformation within the VWF-A1 domain, and the G1324S substitution prevents this conformational change. CONCLUSION: This study has shown that the isolated A1 domain can simultaneously bind to collagen and platelet GPIb, supporting platelet adhesion under high-flow conditions. In addition, this study has used mAb to demonstrate that the binding of the isolated A1 domain or full-length VWF to collagen is accompanied by a conformational change in A1 domain.     

Contribution of platelet vs. endothelial VWF to platelet adhesion and hemostasis

Summary. Background: von Willebrand factor (VWF) is a glycoprotein that plays an important role in primary hemostasis. VWF is synthesized and stored in endothelial cells (ECs) and megakaryocytes/platelets. Plasma VWF is primarily derived from ECs and is generally believed to be essential for hemostasis. VWF synthesized in megakaryocytes is stored in platelet α‐granules, from which it is released following platelet activation. The relative contribution of VWF stored in ECs or megakaryocytes/platelets or present in plasma to hemostasis is not clear. Objectives: We investigated whether EC‐derived VWF plays the major role in hemostasis while the contribution of platelet‐derived VWF is negligible, or if platelet‐derived VWF also significantly contributes to hemostasis. Methods and results: Mice expressing VWF only in ECs (EC‐VWF) or platelets (Plt‐VWF) were created by reciprocal bone marrow transplantation between C57BL/6J (WT) and VWF knockout mice (VWF^?/?). Plasma VWF levels in EC‐VWF were similar to WT. Plt‐VWF mice had a trace amount of VWF in their plasma while VWF levels in platelet lysate were comparable to WT. Tail bleeding time was normal in EC‐VWF. Interestingly, Plt‐VWF showed partially corrected bleeding time and significantly decreased blood loss volume compared with VWF^?/?. Adhesion of platelets perfused over immobilized collagen under shear stress was significantly higher in both EC‐VWF and Plt‐VWF compared with VWF^?/?. Conclusion: VWF synthesized in ECs is sufficient to support hemostasis in VWF^?/? mice, and VWF produced in megakaryocytes/platelets can also contribute to hemostasis in the absence of EC‐derived VWF.     

Localization of the adhesion receptor glycoprotein Ib-IX-V complex to lipid rafts is required for platelet adhesion and activation

The platelet glycoprotein (GP) Ib-IX-V complex mediates the attachment of platelets to the blood vessel wall by binding von Willebrand factor (VWF), an interaction that also transmits signals for platelet activation and aggregation. Because the complex is extensively palmitoylated, a modification known to target proteins to lipid rafts, we investigated the role of raft localization in GP Ib-IX-V functions. In unstimulated platelets, a minor portion of the complex localized to Triton-insoluble raft fractions; this portion increased three to sixfold with platelet activation by VWF. Raft-associated GP Ib-IX-V was selectively palmitoylated, with GP Ib-IX-V-associated palmitate increasing in the raft fraction on VWF-mediated activation. The raft fraction was also the site of association between GP Ib-IX-V and the Fc receptor FcgammaRIIA. The importance of this association was demonstrated by the ability of the FcgammaRIIA antibody IV.3 to inhibit shear-induced platelet aggregation. Disruption of rafts by depleting membrane cholesterol impaired several GP Ib-IX-V-dependent platelet fractions: aggregation to VWF under static conditions and under shear stress, tyrosine phosphorylation, and adhesion to a VWF surface. Partial restoration of membrane cholesterol content partially restored shear-induced platelet aggregation and tyrosine phosphorylation. Thus, localization of the GP Ib-IX-V complex within rafts is crucial for both platelet adhesion and postadhesion signaling.     

Evaluation of platelet function under high shear condition in the small-sized collagen bead column

We previously reported that platelet retention rates as measured with collagen-coated bead columns (the conventional column) reflect the processes of platelet adhesion and aggregation under low shear stress, and that this system could serve as an easy-to-use platelet aggregometry. With this column, platelet glycoprotein (GP) VI and GPIIb/IIIa, but not the GPIb-von Willebrand factor (VWF) interaction, play major roles in platelet activation. To develop a system that can better reflect the GPIb-VWF interaction under high shear stress, we designed a column containing small-sized beads (125-212 microm) coated with porcine collagen type I. As expected, the GPIb-VWF interaction played a crucial role in platelet retention rates at higher flow rates. Adenosine 5'-diphosphate, but not thromboxane A2, appears to support platelet activation in this system. The platelet retention rates among healthy individuals with the new columns are in the range wider than the conventional columns, and this diversity could be attributed to the broad range of the VWF antigen and/or its activity. It is suggested that this new column can serve as an easy-to-use method for evaluating the VWF antigen levels and its activity and for monitoring patients with thrombotic or bleeding disorders related to the VWF-GPIb interaction.     

The aptamer ARC1779 blocks von Willebrand factor–dependent platelet function in patients with thrombotic thrombocytopenic purpura ex vivo

BACKGROUND: In thrombotic thrombocytopenic purpura (TTP), ultralarge von Willebrand factor (VWF) multimers bind platelet (PLT) glycoprotein Ib and lead to the formation of disseminated fibrin‐poor, VWF‐rich PLT thrombi. The aptamer ARC1779 blocks binding of the VWF A1 domain to PLT glycoprotein Ib. We evaluated whether ARC1779 inhibits the excessive VWF activity and VWF‐mediated PLT function in patients with TTP. STUDY DESIGN AND METHODS: We studied the ex vivo concentration response curves for ARC1779 on PLT function analyzer (PFA‐100, Dade Behring) and cone‐and‐plate analyzer (CPA, Impact‐R) PLT function tests, agonist‐induced PLT aggregation, and VWF activity of TTP patients (n = 11, three in acute phase and eight in remission) and healthy controls (n = 44). RESULTS: VWF activity and VWF‐dependent PLT plug formation were increased in TTP patients relative to healthy controls, but agonist‐induced PLT aggregation was not. ARC1779 blocked collagen/adenosine 5′‐diphosphate (ADP)‐induced PLT plug formation as measured by PFA‐100 with an inhibitory concentration (IC)₁₀₀ of approximately 1 µg/mL in citrate‐anticoagulated samples and approximately 3 to 4 µg/mL in hirudin‐anticoagulated samples. A similar concentration of ARC1779 was necessary to block shear‐dependent PLT adhesion in both TTP patients and healthy controls using the CPA assay (IC₁₀₀ of approx. 1 µg/mL for both). ARC1779 blocked VWF activity with an IC₉₀ of approximately 3 to 4 µg/mL in all subjects, but did not inhibit PLT aggregation by ADP, collagen, or arachidonic acid even at concentrations much greater than those that fully inhibited VWF‐dependent PLT function. CONCLUSIONS: ARC1779 potently and specifically inhibits VWF activity and VWF‐dependent PLT function. ARC1779 may be a promising novel therapeutic for the treatment of TTP.