The interaction of factor VIII with von Willebrand factor (vWF) was investigated on a quantitative and qualitative level. Binding characteristics were determined using a solid phase binding assay and protection of factor VIII by vWF from inactivation by activated protein C (aPC) was studied using three different assays. Deletion mutants of vWF, a 31-kD N-terminal monomeric tryptic fragment of vWF that contained the factor VIII binding site (T31) and multimers of vWF of different size were compared with vWF purified from plasma. We found that deletion of the A1, A2, or A3 domain of vWF had neither an effect on the binding characteristics nor on the protective effect of vWF on factor VIII. Furthermore, no differences in binding of factor VIII were found between multimers of vWF with different size. Also, the protective effect on factor VIII of vWF was not related to the size of the multimers of vWF. A 20-fold lower binding affinity was observed for the interaction of T31 with factor VIII, and T31 did not protect factor VIII from inactivation by aPC in a fluid-phase assay. Comparable results were found for a mutant of vWF that is monomeric at the N- terminus (vWF-dPRO). The lack of multimerization at the N-terminus may explain the decreased affinity of T31 and vWF-dPRO for factor VIII. Because of this decreased affinity, only a small fraction of factor VIII was bound to T31 and to vWF-dPRO. We hypothesized that this fraction was protected from inactivation by aPC but that this protection was not observed due to the presence of an excess of unbound factor VIII in the fluid phase. Therefore, vWF, T31, and vWF-dPRO were immobilized to separate bound factor VIII from unbound factor VIII in the fluid phase. Subsequently, the protective effect of these forms of vWF on bound factor VIII was studied. In this approach, all forms of vWF were able to protect factor VIII against inactivation by aPC completely. We conclude, in contrast with earlier work, that there is no discrepancy between binding of factor VIII to vWF and protection of factor VIII by vWF from inactivation by aPC. The protective effect of T31 was not recognized in previous studies due to its low affinity for factor VIII. The absence of multimerization observed for T31 and vWF- dPRO may explain the low affinity for factor VIII. No other domains than the binding site located at the D′ domain were found to be involved in the protection of factor VIII from inactivation by aPC.
Summaryvon Willebrand factor (vWF) is a complex multimeric plasma glycoprotein, that plays a critical role in the mediation of platelet adhesion to the damaged vascular wall, and functions as a carrier protein for factor VIII. vWF has a domain structure consisting of repeated A, B, C, and D domains. The A1 domain is involved in binding to the platelet receptor glycoprotein (GP) lb, and the A3 domain has a binding site for collagen. A function of the A2 domain has not been described, although point mutations identified in von Willebrand disease (vWD) type 2A patients are localized in this domain. To study the role of the A2 domain a deletion mutant was constructed which lacked the A2 domain, ΔA2- vWF. Previous studies have shown that this approach is a powerful tool to study the function of a domain in a protein since it does not affect the activity of other domains. After expression in baby hamster kidney (BHK) cells, ΔA2-vWF was compared to wild-type (WT) vWF, and to ΔAl-vWF (Lankhof et al., Blood 86: 1035,1995). Ristocetin induced platelet binding was slightly increased but botrocetin induced platelet binding was normal as was binding to heparin and collagen type III. Adhesion studies to surface coated purified ΔA2-vWF or to ΔA2-vWF preincubated on collagen under flow conditions showed no abnormalities. Incubation with normal human plasma showed that ΔA2-vWF like WT-vWF was not sensitive to proteolysis. After addition of urea, WT-vWF becomes sensitive to the protease, indicating that unfolding of the molecule is necessary for exposure of the cleavage site. ΔA2- vWF tested under the same conditions was resistant, indicating that the protease sensitive site is located in the A2 domain.
Type 2B von Willebrand disease (vWD) is characterized by the absence of the very high molecular weight von Willebrand factor (vWF ) multimers from plasma, which is caused by spontaneous binding to platelet receptor glycoprotein Ib (GPIb). We studied two mutations in the A1 domain at position 543 in which arginine (R) was replaced by glutamine (Q) or tryptophan (W), respectively. Both mutations were previously identified in vWD type 2B patients. The mutations R543Q and R543W were cloned into a eukaryotic expression vector and subsequently transfected in baby hamster kidney cells overexpressing furin (fur-BHK). Stable cell lines were established by which the mutants were secreted in the cell culture supernatant. The subunit composition and multimeric structure of R543Q and R543W were similar to wild-type (WT) vWF. The mutants showed a spontaneous binding to GPIb. R543Q and R543W showed normal binding to collagen type III or heparin. Both mutants supported platelet adhesion under conditions of flow, usually when preincubated on a collagen type III surface. A low dose (2.5% of the concentration present in normal pooled plasma) of recombinant R543Q or R543W added to normal whole blood inhibited platelet adhesion to collagen type III. No inhibition was found when vWF was used as an adhesive surface. These results indicate that point mutations identified in vWD type 2B cause bleeding symptoms by two mechanisms: (1) the mutants cause platelet aggregation, which in vivo is followed by removal of the aggregates leading to the loss of high molecular weight multimers and thrombocytopenia, (2) on binding to circulating platelets the mutants block platelet adhesion. Relatively few molecules are required for the latter effect.
Recombinant vWF Type 2A Mutants R834Q and R834W Show a Defect in Mediating Platelet Adhesion to Collagen, Independent of Enhanced Sensitivity to a Plasma Protease
SummaryType 2A von Willebrand Disease (vWD) is characterized by the absence of high molecular weight von Willebrand factor (vWF) multimers in plasma which is caused by enhanced extracellular proteolysis or defective intracellular transport. We identified in vWD type 2A patients two mutations in the A2 domain at position 834 in which arginine (R) was substituted for glutamine (R834Q) or tryptophan (R834W). We reproduced these mutations in vWF cDNA and expressed the recombinant proteins in furin cDNA containing baby hamster kidney (fur-BHK) cells. The subunit composition and the multimeric structure of both mutants was similar to wild-type (WT) vWF. Characterization of mutant R834Q by ristocetin or botrocetin induced platelet binding, and by binding to heparin showed no abnormality. R834W had normal botrocetin induced platelet binding, but ristocetin induced platelet binding and binding to heparin were decreased. Under static conditions R834Q and R834W, at 10 μg/ml, bound equally well to collagen type III as WT-vWF. At high shear rate conditions both mutants supported platelet adhesion normally when coated to a glass surface or preincubated on collagen. When R834Q or R834W was added to the perfusate, adhesion to collagen type III was 50% of the WT-vWF value, which was not due to a decreased collagen binding under flow. A divalent cation dependent protease, purified from plasma, degraded the 2A mutants rapidly while WT-vWF was not affected. In conclusion, the mutations present in the A2 domain of vWF result in an enhanced proteolytic sensitivity to a divalent ion-dependent protease. When present in the perfusate, R834Q and R834W show a decrease in platelet adhesion to collagen type III under flow conditions, which is not caused by decreased binding of the mutant vWF to collagen or enhanced proteolysis.
The 33-kDa Platelet α-granule Membrane Protein (GMP-33) Is an N-terminal Proteolytic Fragment of Thrombospondin
SummaryGMP-33 is a platelet membrane associated protein that is recognised by RUU-SP 1.77, an antibody raised against activated platelets. GMP-33 is predominantly associated with the membrane of platelet α-granules and it is translocated to the plasma membrane upon platelet activation (Metzelaar et al. Blood 1992; 79: 372-9). In this study we have isolated the protein by immunoaffinity chromatography. The N-terminus was sequenced and was identical to the N-terminal sequence of human thrombospondin. The protein was N-glycosylated and bound to heparin as would be expected of the N-terminal part of thrombospondin. RUU-SP 1.77 reacted only with reduced thrombospondin. Plasmin and trypsin digestion of thrombospondin yielded fragments of approximately the same size as GMP 33 that reacted with RUU-SP 1.77 after reduction. No evidence for alternative splicing was found. We postulate that GMP 33 is an N-terminal proteolytic fragment of thrombospondin that is membrane associated.
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