Project description:Binding of platelet glycoprotein Ibα (GPIbα) to von Willebrand factor (VWF) initiates platelet adhesion to disrupted vascular surface under arterial blood flow. Flow exerts forces on the platelet that are transmitted to VWF-GPIbα bonds, which regulate their dissociation. Mutations in VWF and/or GPIbα may alter the mechanical regulation of platelet adhesion to cause hemostatic defects as found in patients with von Willebrand disease (VWD). Using a biomembrane force probe, we observed biphasic force-decelerated (catch) and force-accelerated (slip) dissociation of GPIbα from VWF. The VWF A1 domain that contains the N-terminal flanking sequence Gln(1238)-Glu(1260) (1238-A1) formed triphasic slip-catch-slip bonds with GPIbα. By comparison, using a short form of A1 that deletes this sequence (1261-A1) abolished the catch bond, destabilizing its binding to GPIbα at high forces. Importantly, shear-dependent platelet rolling velocities on these VWF ligands in a flow chamber system mirrored the force-dependent single-bond lifetimes. Adding the Gln(1238)-Glu(1260) peptide, which interacted with GPIbα and 1261-A1 but not 1238-A1, to whole blood decreased platelet attachment under shear stress. Soluble Gln(1238)-Glu(1260) reduced the lifetimes of GPIbα bonds with VWF and 1238-A1 but rescued the catch bond of GPIbα with 1261-A1. A type 2B VWD 1238-A1 mutation eliminated the catch bond by prolonging lifetimes at low forces, a type 2M VWD 1238-A1 mutation shifted the respective slip-catch and catch-slip transition points to higher forces, whereas a platelet type VWD GPIbα mutation enhanced the bond lifetime in the entire force regime. These data reveal the structural determinants of VWF activation by hemodynamic force of the circulation.

Project description:The plasmatic von Willebrand factor (VWF) circulates in a compact form unable to bind platelets. Upon shear stress, the VWF A1 domain is exposed, allowing VWF-binding to platelet glycoprotein Ib-V-IX (GPIbα chain). For a better understanding of the role of this interaction in cardiovascular disease, molecules are needed to specifically interfere with the opened VWF A1 domain interaction with GPIbα. Therefore, we in silico designed and chemically synthetized stable cyclic peptides interfering with the platelet-binding of the VWF A1 domain per se or complexed with botrocetin. Selected peptides (26-34 amino acids) with the lowest-binding free energy were: the monocyclic mono- vOn Willebrand factoR-GPIbα InTerference (ORbIT) peptide and bicyclic bi-ORbIT peptide. Interference of the peptides in the binding of VWF to GPIb-V-IX interaction was retained by flow cytometry in comparison with the blocking of anti-VWF A1 domain antibody CLB-RAg35. In collagen and VWF-dependent whole-blood thrombus formation at a high shear rate, CLB-RAg35 suppressed stable platelet adhesion as well as the formation of multilayered thrombi. Both peptides phenotypically mimicked these changes, although they were less potent than CLB-RAg35. The second-round generation of an improved peptide, namely opt-mono-ORbIT (28 amino acids), showed an increased inhibitory activity under flow. Accordingly, our structure-based design of peptides resulted in physiologically effective peptide-based inhibitors, even for convoluted complexes such as GPIbα-VWF A1.

Project description:Binding of the A1 domain of von Willebrand factor (vWF) to glycoprotein Ibα (GPIbα) results in platelet adhesion, activation, and aggregation that initiates primary hemostasis. Both the elevated shear stress and the mutations associated with type 2B von Willebrand disease enhance the interaction between A1 and GPIbα. Through molecular dynamics simulations for wild-type vWF-A1 and its eight gain of function mutants (R543Q, I546V, ΔSS, etc.), we found that the gain of function mutations destabilize the N-terminal arm, increase a clock pendulum-like movement of the α2-helix, and turn a closed A1 conformation into a partially open one favoring binding to GPIbα. The residue Arg(578) at the α2-helix behaves as a pivot in the destabilization of the N-terminal arm and a consequent dynamic change of the α2-helix. These results suggest a localized dynamics-driven affinity regulation mechanism for vWF-GPIbα interaction. Allosteric drugs controlling this intrinsic protein dynamics may be effective in blocking the GPIb-vWF interaction.

Project description:von Willebrand factor (vWF) is a multimeric plasma glycoprotein with three tandem A domains. Domains A1 and A3 bind to platelet glycoprotein Ibalpha (GPIbalpha) and collagen, respectively. Domain A2 contains the Tyr-1605-Met-1606 bond that is cleaved by the metalloprotease ADAMTS13, and this reaction inhibits platelet thrombus growth. Fluid shear stress increases the rate of cleavage, suggesting that productive interaction with ADAMTS13 requires conformational changes within or near domain A2. The influence of the adjacent A1 and A3 domains was assessed by mutagenesis of a recombinant substrate consisting of domains A1A2A3. Deletion of domain A3 did not affect cleavage by ADAMTS13, whereas deletion of domain A1 increased the rate of cleavage approximately 10-fold. Similar effects were observed with plasma ADAMTS13 and recombinant ADAMTS13 truncated after the spacer domain. Digestion of A1A2A3 by plasma ADAMTS13 was enhanced to a similar extent by a recombinant mutant fragment of platelet GPIbalpha that binds with high affinity to domain A1 or by heparin. Heparin also increased the digestion of purified plasma vWF. Neither GPIbalpha nor heparin increased the cleavage of substrate A2A3 that lacks domain A1. The results suggest that vWF domain A1 inhibits the cleavage of domain A2, and that inhibition can be relieved by interaction of domain A1 with platelet GPIbalpha or certain glycosaminoglycans. Thus, binding of vWF to its major physiological ligands may promote the feedback inhibition of platelet adhesion by stimulating the cleavage of domain A2 by ADAMTS13 independent of fluid shear stress.

Project description:A new platelet antagonist, tokaracetin, was isolated from the venom of Trimeresurus tokarensis by ion-exchange chromatography, heparin-Sepharose chromatography and hydrophobic HPLC. The purified protein showed an apparent molecular mass on SDS/PAGE of 28.9 kDa under non-reducing conditions. On reduction, 16.1 and 15.4 kDa subunits were observed, suggesting that the molecule is a heterodimer. Tokaracetin inhibited the binding of 125I-labelled bovine von Willebrand factor (vWF) and 125I-labelled human vWF in the presence of botrocetin to fixed human platelets. It did not block ADP-, collagen- or thrombin receptor agonist peptide-induced platelet aggregation in human platelet-rich plasma (PRP), or induce platelet agglutination in PRP. On reduction, tokaracetin lost its inhibitory activity on the agglutination of fixed human platelets by bovine vWF. 125I-Tokaracetin specifically bound to washed human platelets with high affinity (Kd 3.9 +/- 1.4 nM) at 47,440 +/- 2780 binding sites per platelet. Binding of tokaracetin to fixed human platelets was reversible, and was inhibited by monoclonal antibody GUR83-35, which is directed against the N-terminal vWF-binding domain of human glycoprotein Ib (GPIb). Tokaracetin completely inhibited vWF-dependent shear-induced platelet aggregation in PRP at 3 micrograms/ml. The N-terminal amino acid sequences of tokaracetin subunits showed a high degree of identity with those of alboaggregin-B. These results suggest that this new platelet antagonist may be a useful tool in the development of specific inhibitors of the vWF-GPIb interaction.

Project description:The von Willebrand factor (VWF) A1 and A3 domains are structurally isomorphic yet exhibit distinct mechanisms of unfolding. The A1 domain, responsible for platelet adhesion to VWF in hemostasis, unfolds through a molten globule intermediate in an apparent three-state mechanism, while A3 unfolds by a classical two-state mechanism. Inspection of the sequences or structures alone does not elucidate the source of this thermodynamic conundrum; however, the three-state character of the A1 domain suggests that it has more than one cooperative substructure yielding two separate unfolding transitions not present in A3. We investigate the extent to which structural elements contributing to intermediate conformations can be identified using a residue-specific implementation of the structure-energy-equivalence-of-domains algorithm (SEED), which parses proteins of known structure into their constituent thermodynamically cooperative components using protein-group-specific, transfer free energies. The structural elements computed to contribute to the non-two-state character coincide with regions where Von Willebrand disease mutations induce misfolded molten globule conformations of the A1 domain. This suggests a mechanism for the regulation of rheological platelet adhesion to A1 based on cooperative flexibility of the α2 and α3 helices flanking the platelet GPIbα receptor binding interface.

Project description:BackgroundPlatelet glycoprotein (GP) Ibα is the major ligand-binding subunit of the GPIb-IX-V complex that binds von Willebrand factor. GPIbα is heavily glycosylated, and its glycans have been proposed to play key roles in platelet clearance, von Willebrand factor binding, and as target antigens in immune thrombocytopenia syndromes. Despite its importance in platelet biology, the glycosylation profile of GPIbα is not well characterized.ObjectivesThe aim of this study was to comprehensively analyze GPIbα amino acid sites of glycosylation (glycosites) and glycan structures.MethodsGPIbα ectodomain that was recombinantly expressed or that was purified from human platelets was analyzed by Western blot, mass spectrometry glycomics, and mass spectrometry glycopeptide analysis to define glycosites and the structures of the attached glycans.ResultsWe identified a diverse repertoire of N- and O-glycans, including sialoglycans, Tn antigen, T antigen, and ABO(H) blood group antigens. In the analysis of the recombinant protein, we identified 62 unique O-glycosites. In the analysis of the endogenous protein purified from platelets, we identified 48 unique O-glycosites and 1 N-glycosite. The GPIbα mucin domain is densely O-glycosylated. Glycosites are also located within the macroglycopeptide domain and mechanosensory domain.ConclusionsThis comprehensive analysis of GPIbα glycosylation lays the foundation for further studies to determine the functional and structural roles of GPIbα glycans.

Project description:Collagen VI is abundant in the arterial subendothelium. To investigate its mechanism of interaction with von Willebrand factor (vWF), collagen VI was isolated from human placenta and from the extracellular matrix of the human lung fibroblast cell line MRC-5. Purified vWF bound to non-digested collagen VI with moderately high affinity (EC50 approximately 5 nM) and could be inhibited by the Hirudo medicinalis collagen inhibitor calin. The anti-(human vWF A1 domain) monoclonal antibody (AJvW-2), as well as aurin tricarboxylic acid (ATA), at concentrations that saturate the vWF A1 domain, also inhibited this binding. In contrast, the monoclonal anti-(human vWF A3 domain) antibody (82D6A3) inhibited vWF binding to collagens I, III and IV, but had no effect on vWF binding to collagen VI. Likewise, vWF binding to collagen VI was not inhibited by the recombinant vWF domain D4. Polyclonal anti-(collagen VI) antibodies, specifically neutralizing the binding of vWF to collagen VI, confirmed that in the intact endothelial cell extracellular matrix, collagen VI was accessible for interaction with vWF. This binding was only marginally affected by 82D6A3 but was dose-dependently inhibited by AJvW-2, ATA and the A1 domain analogue VCL (recombinant A1 domain of vWF), with IC50 values comparable to those found for the inhibition of vWF binding to isolated collagen VI. The weak interaction of isolated human platelets with collagen VI was mediated via the platelet collagen receptor (GPIa/IIa) and was competitively inhibited by vWF but not by VCL, suggesting that vWF and GPIa/IIa bind to neighbouring but distinct sites on collagen VI. We conclude that vWF binds to collagen VI primarily via its A1 domain, which distinguishes it from the vWF A3 domain-mediated binding to fibrillar collagens.

Project description:The von Willebrand factor (VWF) A1-glycoprotein (GP) Ib? interaction is of major importance during thrombosis mainly at sites of high shear stress. Inhibitors of this interaction prevent platelet-dependent thrombus formation in vivo, without major bleeding complications. However, the size and/or protein nature of the inhibitors currently in development limit oral bioavailability and clinical development. We therefore aimed to search for a small molecule protein-protein interaction inhibitor interfering with the VWF-GPIb? binding. After determination of putative small molecule binding pockets on the surface of VWF-A1 and GPIb? using site-finding algorithms and molecular dynamics, high throughput molecular docking was performed on both binding partners. A selection of compounds showing good in silico docking scores into the predicted pockets was retained for testing their in vitro effect on VWF-GPIb? complex formation, by which we identified a compound that surprisingly stimulated the VWF-GPIb? binding in a ristocetin cofactor ELISA and increased platelet adhesion in whole blood to collagen under arterial shear rate but in contrast inhibited ristocetin-induced platelet aggregation. The selected compound adhering to the predicted binding partner GPIb? could be confirmed by saturation transfer difference NMR spectroscopy. We thus clearly identified a small molecule that modulates VWF-GPIb? binding and that will now serve as a starting point for further studies and chemical modifications to fully characterize the interaction and to manipulate specific activity of the compound.

Project description:Essentials von Willebrand factor (VWF) is synthesized in endothelial cells and platelet precursors. Type 3 patients with Pro2808Leufs*24 have lower bleeding scores than other type 3s. The Pro2808Leufs*24 variant was examined in patient platelets and endothelial cells. Type 3s with this variant contain releaseable VWF, possibly reducing bleeding. SUMMARY:Background A novel variant, p.Pro2808Leufs*24, in the von Willebrand factor (VWF) gene was previously identified in the Canadian von Willebrand disease (VWD) patient population. Clinical observations of type 3 VWD patients with this variant indicate a milder bleeding phenotype compared with other type 3 patients. Objective To assess the effect of the Pro2808Leufs*24 variant on the molecular pathogenesis of VWD and correlate this with the phenotype observed in patients. Patients/Methods Phenotypic data from individuals in the Canadian type 3 VWD study were analyzed. VWF expression in platelets and plasma was assessed via immunoblotting. Cellular expression of VWF in platelets and blood outgrowth endothelial cells (BOEC) was examined via immunofluorescence microscopy and biochemical analysis in a type 3 index case and family member with Pro2808Leufs*24. Results Twenty-six individuals with the Pro2808Leufs*24 variant (16 type 3 VWD homozygous or compound heterozygous and 10 heterozygous family members) were studied. Bleeding scores were lower in type 3 patients with Pro2808Leufs*24 compared with type 3 patients with other variants, confirming a milder bleeding phenotype. Immunoblotting of platelet lysates detected VWF in the platelets of type 3 patients with Pro2808Leufs*24. Examination of an index case detected VWF within platelets via immunofluorescence microscopy, and in vitro experiments showed that this VWF was released upon platelet activation. Patient BOECs showed decreased VWF synthesis and secretion, although some VWF-containing granules were observed. Conclusion Type 3 VWD patients with the Pro2808Leufs*24 have bioavailable platelet-derived VWF that may produce a milder bleeding phenotype than other type 3s.