Expression of 14 von Willebrand factor mutations identified in patients with type 1 von Willebrand disease from the MCMDM-1VWD study.

BACKGROUND: Candidate von Willebrand factor (VWF) mutations were identified in 70% of index cases in the European study 'Molecular and Clinical Markers for the Diagnosis and Management of type 1 von Willebrand Disease'. The majority of these were missense mutations. OBJECTIVES: To assess whether 14 representative missense mutations are the cause of the phenotype observed in the patients and to examine their mode of pathogenicity. METHODS: Transfection experiments were performed with full-length wild-type or mutant VWF cDNA for these 14 missense mutations. VWF antigen levels were measured, and VWF multimer analysis was performed on secreted and intracellular VWF. RESULTS: For seven of the missense mutations (G160W, N166I, L2207P, C2257S, C2304Y, G2441C, and C2477Y), we found marked intracellular retention and impaired secretion of VWF, major loss of high molecular weight multimers in transfections of mutant constructs alone, and virtually normal multimers in cotransfections with wild-type VWF, establishing the pathogenicity of these mutations. Four of the mutations (R2287W, R2464C, G2518S, and Q2520P) were established as being very probably causative, on the basis of a mild reduction in the secreted VWF or on characteristic faster-running multimeric bands. For three candidate changes (G19R, P2063S, and R2313H), the transfection results were indistinguishable from wild-type recombinant VWF and we could not prove these changes to be pathogenic. Other mechanisms not explored using this in vitro expression system may be responsible for pathogenicity. CONCLUSIONS: The pathogenic nature of 11 of 14 candidate missense mutations identified in patients with type 1 VWD was confirmed. Intracellular retention of mutant VWF is the predominant responsible mechanism.

Effect of von Willebrand disease type 2B and type 2M mutations on the susceptibility of von Willebrand factor to ADAMTS-13.

BACKGROUND: von Willebrand disease (VWD) type 2 is associated with mutations in von Willebrand factor (VWF) that affect its secretion, multimeric pattern, affinity for platelet receptors and clearance of the protein. While increased proteolysis by a disintegrin-like and metalloprotease with thrombospondin type 1 motifs-13 (ADAMTS-13) has been clearly established for VWF type 2A, only little is known about VWF types 2B and 2M in this regard. OBJECTIVES: Sensitivity of wild-type (WT) and mutated recombinant (r) VWF to proteolysis by ADAMTS-13 was investigated to better understand the role of this process in the pathophysiology of VWD. METHODS: We used human rADAMTS-13-WT to digest 11 full-length recombinant forms of VWF carrying molecular abnormalities identified in patients with VWD type 2A (E1638K and P1648S), type 2B (InsM1303, R1306W, R1308P and V1314F) and type 2M (G1324A, E1359K, K1362T, R1374H and I1425F). RESULTS: Using low ionic strength conditions, all mutations induced increased proteolysis of rVWF by rADAMTS-13 as compared with rVWF-WT. The susceptibility of mutants decreased in the following order: type 2A > type 2B > type 2M > rVWF-WT. At physiological salt concentration (150 mm NaCl) the sensitivity of all rVWF to rADAMTS-13 was significantly decreased. However, type 2A and type 2B mutants still exhibited a significantly higher susceptibility to rADAMTS-13 than rVWF-WT, whereas type 2M mutants normalized. CONCLUSIONS: Type 2M mutants and rVWF-WT exhibit a similar sensitivity to rADAMTS-13-mediated proteolysis, in agreement with the normal multimeric pattern in vivo. In VWD type 2B, the spontaneous binding to platelets and excessive degradation by ADAMTS-13 of VWF high-molecular-weight multimers may account for their clearance from plasma.

Mutations C1157F and C1234W of von Willebrand factor cause intracellular retention with defective multimerization and secretion.

The D3 domain of von Willebrand factor (VWF) is involved in the multimerization process of the protein through the formation of disulfide bridges. We identified heterozygous substitutions, C1157F and C1234W, in the VWF D3 domain in two unrelated families with unclassified and type 2A von Willebrand disease, respectively. VWF was characterized by a low plasmatic level, an abnormal binding to platelet GPIb and a high capacity of secretion from endothelial cells following DDAVP infusion. Using site-directed mutagenesis and expression in mammalian cells, we have investigated the impact of these mutations upon the multimerization, secretion and storage of VWF. Using COS-7 cells both mutated recombinant VWF (rVWF) displayed only lower molecular weight multimers. Pulse-chase analysis and endoglycosidase H digestion experiments showed the intracellular retention of mutated rVWF in pre-Golgi compartments. Study of hybrid rVWF obtained with a constant amount of wild-type (WT) DNA and increasing proportions of mutated plasmids established that both substitutions reduced the release of WT VWF in a dose-dependent manner and failed to form high molecular weight multimers. Using transfected AtT-20 stable cell lines, we observed similar granular storage of the two mutants and WT rVWF. Our data suggest that cysteines 1157 and 1234 play a crucial role in the early step of the folding of the molecule required for a normal transport pathway, maturation and constitutive secretion. In contrast, their substitution does not prevent the storage and inducible secretion of VWF.

Ten candidate ADAMTS13 mutations in six French families with congenital thrombotic thrombocytopenic purpura (Upshaw-Schulman syndrome).

ADAMTS13, the specific von Willebrand factor (VWF)-cleaving metalloprotease, prevents the spontaneous formation of platelet thrombi in the microcirculation by degrading the highly adhesive ultralarge VWF multimers into smaller forms. ADAMTS13 severe enzymatic deficiency and mutations have been described in the congenital thrombotic thrombocytopenic purpura (TTP or Upshaw-Schulman syndrome), a rare and severe disease related to multivisceral microvascular thrombosis. We investigated six French families with congenital TTP for ADAMTS13 enzymatic activity and gene mutations. Six probands with congenital TTP and their family were tested for ADAMTS13 activity in plasma using a two-site immunoradiometric assay and for ADAMTS13 gene mutations using polymerase chain reaction and sequencing. ADAMTS13 activity was severely deficient (< 5%) in the six probands and one mildly symptomatic sibling but normal (> 50%) in all the parents and the asymptomatic siblings. Ten novel candidate ADAMTS13 mutations were identified in all families, showing either a compound heterozygous or a homozygous status in all probands plus the previous sibling and a heterozygous status in the parents. The mutations were spread all over the gene, involving the metalloprotease domain (I79M, S203P, R268P), the disintegrin domain (29 bp deletion in intron/exon 8), the cystein-rich domain (acceptor splice exon 12, R507Q), the spacer domain (A596V), the 3rd TSP1 repeat (C758R), the 5th TSP1 repeat (C908S) and the 8th TSP1 repeat (R1096stop). This study emphasizes the role of ADAMTS13 mutations in the pathogenesis of congenital TTP and suggests that several structural domains of this metalloprotease are involved in both its biogenesis and its substrate recognition process.

Identification of a new type 2M von Willebrand disease mutation also at position 1324 of von Willebrand factor.

Type 2M von Willebrand disease (VWD) refers to variants with decreased platelet-dependent function that is not associated with the loss of high molecular weight (HMW) von Willebrand factor (VWF) multimers. This category includes the so-called "phenotype B" responsible for inexistent ristocetin-induced but normal botrocetin-induced binding of VWF to platelet glycoprotein lb. The missense mutation G1324S was identified in the first patient reported to display "phenotype B". We report here on the identification in four members of a French family of a missense mutation also affecting this glycine residue but changing it into an alanine residue. These individuals are heterozygous for this mutation and two of them display an additional quantitative VWF deficiency resulting from a stop codon at position 2470. After transient transfection in Cos-7 cells, the mutated recombinant protein harbouring the G1324A substitution was shown to exhibit normal multimers and inexistent ristocetin-induced but normal botrocetin-induced binding to GPIb, confirming the classification of this new mutation as a type 2M VWD mutation.

Type 2 von Willebrand disease causing defective von Willebrand factor-dependent platelet function.

Type 2 von Willebrand disease causing defective von Willebrand factor-dependent platelet function comprises mainly subtypes 2A, 2B and 2M. The diagnosis of type 2 von Willebrand disease may be guided by the observation of a disproportionately low level of ristocetin cofactor activity or collagen-binding activity relative to the von Willebrand factor antigen level. The decreased platelet-dependent function is often associated with an absence of high molecular weight multimers (types 2A and 2B), but the high molecular weight multimers may also be present (type 2M and some type 2B), and supranormal multimers may exist (as in the Vicenza variant). Today, the identification of mutations in particular domains of the pre-provon Willebrand factor is helpful to classify these variants and to provide further insight into the structure-function relationship and the biosynthesis of von Willebrand factor. Thus, mutations in the D2 domain, involved in the multimerization process, are found in patients with type 2A, formerly named IIC von Willebrand disease. Mutations in the D3 domain characterize the Vicenza variant, or type IIE patients. Mutations in the A1 domain may modify the binding of von Willebrand factor multimers to platelets, either increasing (type 2B) or decreasing (types 2M and 2A/2M) the affinity of von Willebrand factor for platelets. In type 2A disease, molecular abnormalities identified in the A2 domain, which contains a specific proteolytic site, are associated with alterations in folding that impair the secretion of von Willebrand factor or increase its susceptibility to proteolysis. Finally, a mutation localized in the C terminus cysteine knot domain, which is crucial for the dimerization of von Willebrand factor subunit, has been identified in a rare subtype 2A, formerly named IID.

Ser968Thr mutation within the A3 domain of von Willebrand factor (VWF) in two related patients leads to a defective binding of VWF to collagen.

We report the identification of a new mutation of von Willebrand Factor (VWF) gene within exon 30 occurring in two related patients (mother and daughter) with a hemorrhagic syndrome. A T-->A transvertion at nucleotide 5441 was found changing the serine 968 to threonine of the mature VWF subunit (S1731T of the preproVWF). The Ser968Thr mutation is located within the VWF A3 domain which interacts with type I and III collagens. Both patients were found to be heterozygous for the mutation. The propositus (daughter) exhibited a slightly prolonged bleeding time, levels of VWF:Ag and VWF:RCo at the lower limit of normal, contrasting with normal levels of VIII:C. Her mother exhibited borderline bleeding time and moderately decreased levels of VWF and VIII:C. In both patients multimeric structure of VWF and ristocetin- as well as botrocetin-induced binding of VWF to GPIb were normal; however both patients repeatedly showed decreased binding of VWF to collagen. The Ser968Thr substitution was reproduced by site-directed mutagenesis on the full-length cDNA of VWF. The mutated recombinant VWF (rVWF), T968rVWF, and the hybrid S/T968rVWF were transiently expressed by COS-7 cells. Both rVWF exhibited normal multimeric pattern and normal ristocetin- as well as botrocetin-induced binding to GPIb. T968rVWF showed significantly decreased binding to collagen while the hybrid S/T968rVWF bound to collagen in a similar way to that of the patients' plasma VWF. Thus, our data demonstrate that the Ser968Thr mutation of the VWF A3 domain is clearly responsible for the abnormal binding of VWF to collagen observed in both patients. The Ser968Thr substitution of the VWF is the first mutation identified in two patients leading to a decreased affinity of VWF for collagen and a normal multimeric structure.

Selective inactivation of Von Willebrand factor binding to glycoprotein IIb/IIIa and to inhibitor monoclonal antibody 9 by site-directed mutagenesis.

INTRODUCTION: The purpose of this study was to assess the requirement for the RGD sequence of von Willebrand factor (VWF) for its binding to the beta3 chain of integrins and the structural basis for the specificity of monoclonal antibody (MoAb) 9 which specifically binds to VWF and inhibits this interaction. MATERIAL AND METHODS: : Seven point mutations were introduced into VWF by site-directed mutagenesis. Mutated recombinant VWF were tested for their multimeric pattern and their ability to bind to purified GPIIb/IIIa, thrombin-activated platelets and MoAb 9. RESULTS: All recombinant VWF were fully multimerized. The conservative Arg 1744 to Lys substitution into the RGD sequence resulted in an 80% loss of function whereas the Arg to Ala change led to a total loss of function. The two substitutions however did not impair the binding to MoAb 9. In contrast Arg 1715 to Ala substitution had no effect on the binding to GPIIb/IIIa but the binding of the corresponding mutated recombinant VWF to MoAb 9 was strikingly decreased. CONCLUSION: Direct evidence of the role of the structure and the charge of Arg 1744 into the RGD sequence were established by changing Arg to Lys (KGD) and to Ala (AGD). Our results also demonstrate that Arg 1715 is not essential in the function but it is necessary for maintaining the conformation recognized by MoAb 9 specific for the GPIIb/IIIa-binding domain of VWF.

Defect of heparin binding in plasma and recombinant von Willebrand factor with type 2 von Willebrand disease mutations.

The aim of our study was to characterise heparin-binding properties of mutated von Willebrand factor (VWF) in 24 patients plasmas with type 2 von Willebrand disease (VWD). and in 15 recombinant VWF (rVWF) with the corresponding mutations. Binding of mutated rVWF or plasma VWF was compared to that of WT-rVWF or normal pool plasma VWF. Four mutations, at positions C509, V551, R552 and R611 lead to significantly decreased binding to heparin in both plasma and rVWF. Interestingly, whereas these four residues are distant in the primary structure of VWF-A1domain, they are close to each other in its three-dimensional structure. Structural analysis suggested how folding problems and destabilisation due to these mutations could induce reorganisation of surface regions involved in heparin binding. In contrast, no heparin-binding defect was found associated with different type 2 VWF mutants, at positions G561, E596, I662, R543, R545, V553, R578 or L697.

Effect of recombinant von Willebrand factor reproducing type 2B or type 2M mutations on shear-induced platelet aggregation.

The aim was to better understand the function of von Willebrand factor (vWF) A1 domain in shear-induced platelet aggregation (SIPA), at low (200) and high shear rate (4000 seconds(-1)) generated by a Couette viscometer. We report on 9 fully multimerized recombinant vWFs (rvWFs) expressing type 2M or type 2B von Willebrand disease (vWD) mutations, characterized respectively by a decreased or increased binding of vWF to GPIb in the presence of ristocetin. We expressed 4 type 2M (-G561A, -E596K, -R611H, and -I662F) and 5 type 2B (rvWF-M540MM, -V551F, -V553M, -R578Q, and -L697V). SIPA was strongly impaired in all type 2M rvWFs at 200 and 4000 seconds(-1). Decreased aggregation was correlated with ristocetin binding to platelets. In contrast, a distinct effect of botrocetin was observed, since type 2M rvWFs (-G561A, -E596K, and -I662F) were able to bind to platelets to the same extent as wild type rvWF (rvWF-WT). Interestingly, SIPA at 200 and 4000 seconds(-1) confirmed the gain-of-function phenotype of the 5 type 2B rvWFs. Our data indicated a consistent increase of SIPA at both low and high shear rates, reaching 95% of total platelets, whereas SIPA did not exceed 40% in the presence of rvWF-WT. Aggregation was completely inhibited by monoclonal antibody 6D1 directed to GPIb, underlining the importance of vWF-GPIb interaction in type 2B rvWF. Impaired SIPA of type 2M rvWF could account for the hemorrhagic syndrome observed in type 2M vWD. Increased SIPA of type 2B rvWF could be responsible for unstable aggregates and explain the fluctuant thrombocytopenia of type 2B vWD. (Blood. 2000;95:3796-3803)

Regulated von Willebrand factor (vWf) secretion is restored by pro-vWf expression in a transfectable endothelial cell line.

Von Willebrand factor (vWf) is a glycoprotein involved in primary hemostasis and synthesized in endothelial cells (EC). vWf is stored in secretory granules specific for EC called Weibel-Palade bodies (WPb). Studies on the molecular mechanisms of vWf storage and acute release are hampered by the limitations of the available endothelial cell culture models. We created a suitable model by stable transfection of the vWf-negative ECV304 endothelial cell line with pro-vWf cDNA. Pro-vWf was normally cleaved to mature vWf and stored in WPb. Acute vWf release occurred in response to the calcium ionophore A23187. Thus, vWf expression is sufficient to restore functional secretory granules in ECV304 cells. We used this model to study the role of WPb in the storage of tissue-type plasminogen activator (t-PA), a key fibrinolytic enzyme that is acutely released by EC, but whose intracellular storage compartment is still a matter of debate. We observed that restoration of WPb in ECV304 cells results in the targeting of t-PA to these storage granules.

New assay for measuring binding of platelet glycoprotein IIb/IIIa to unpurified von Willebrand factor.

Among the numerous variants of vWD, no patient with an abnormal vWF binding to GPIIb/IIIa has been described to date. To search for such potential variants, we developed a two-site assay for measuring the binding of purified GPIIb/IIIa to vWF in biological fluids and we used it to study a large series of plasmas from various types of von Willebrand disease (vWD) and recombinant vWF (rvWF). vWF in plasma or rvWF in culture medium was immobilized onto anti-vWF monoclonal antibodies (MoAb)-coated wells of microtiter plates. After incubation with either unlabeled GPIIb/IIIa and a 125I-anti-GPIIb/IIIa MoAb or 125I-GPIIb/IIIa, binding curves and binding isotherms were respectively established. Normal pool plasma and wild-type rvWF were used as reference samples. We tested plasmas from 85 normal subjects, 115 patients with different types of vWD (64 type 1, 2 type 3, 9 type 2A, 4 type 2M, 16 type 2B, 15 type 2N, 3 type IID and 2 acquired forms) and 50 patients with various bleeding disorders. Four mutated rvWF with 2A (Glu875Lys and Pro885Ser) or 2B (Dupl.Met540 and Val551Phe) substitutions and one rvWF mutated in the RGD domain of the C-terminal part of vWF-subunit (Asp1746Gly) were also studied. Among the various samples tested, only rvWF Asp1746Gly had no affinity for GPIIb/IIIa. In contrast, GPIIb/IIIa similarly bound to the other vWF, independently of the proteic environment, the factor VIII level, the degree of multimerization or the mutation of vWF. Our results indicate that subjects with an abnormal vWF binding to GPIIb/IIIa are probably rare and difficult to target for a specific screening.

Molecular genetics of von Willebrand disease.

Von Willebrand disease (vWD), the most common congenital bleeding disorder in man, is related to quantitative and/or qualitative abnormalities of von Willebrand factor (vWF). This multimeric glycoprotein serves as carrier protein of factor VIII, an essential cofactor of coagulation in plasma, and promotes platelet adhesion to the damaged vessel and platelet aggregation. Distinct abnormalities of vWF are responsible for the three types of vWD. Types 1 and 3 are characterized by a quantitative defect of vWF whereas type 2, comprising subtypes 2A, 2B, 2M and 2N, refers to molecular variants with a qualitative defect of vWF. The knowledge of the structure of the vWF gene and the use of Polymerase Chain Reaction (PCR) have led to the identification of the molecular basis of vWD in a significant number of patients. Type 2A is characterized by a decreased platelet-dependent function of vWF associated with the absence of high molecular weight (HMW) multimers of vWF. Most of the type 2A mutations have been identified in the A2 domain of vWF which contains a proteolytic site, while a few others have been found within the propeptide and the C-terminal part of vWF which are involved in its multimerization and dimerization, respectively. In type 2B, defined by an increased affinity of vWF to platelet glycoprotein Ib (GPIb), various amino-acid (aa) substitutions or insertion have been localized within the A1 domain containing the GPIb binding site. In the latter domain have been also identified the few molecular abnormalities described in type 2M which is defined by a decreased platelet-dependent function not caused by the absence of HMW multimers. In type 2N, characterized by a defective binding of vWF to factor VIII, several aa substitutions have been identified within the factor VIII-binding domain in the N-terminal part of vWF. The identification of gene defects remains difficult in types 1 and 3. Whereas various abnormalities (total, partial or point deletions, point insertions, nonsense mutations) have already been identified in type 3, the molecular basis of type 1 is still unresolved in most cases. The characterization of the molecular basis of vWD is of fundamental interest in providing further insight into the structure-function relationship and the biosynthesis of vWF.

Gene defects in 150 unrelated French cases with type 2 von Willebrand disease: from the patient to the gene. INSERM Network on Molecular Abnormalities in von Willebrand Disease.

Type 2 vWD is defined by qualitative defects of vWF and is subdivided into four subtypes: 2N, 2B, 2A and 2M. The characterization of 150 unrelated French cases with type 2 vWD emphasizes the heterogeneity of this group. In 51 cases of type 2N vWD, new mutations were found not only in the D' domain (Cys25Tyr and Cys95Phe) but also in the D3 domain (Asp116Asn and Cys297Arg). In 42 cases of type 2B vWD, no new mutation was detected. In 45 cases with type 2A phenotype, three new candidate mutations were found in the A2 domain: Gln793Arg, Val841Phe and Leu876Pro. In addition, four new candidate mutations were detected in the A1 domain: Cys509Gly, Arg545His, Arg552Cys and Cys695Tyr. Finally, five new candidate mutations were identified in 12 patients with 2M (or unclassified) phenotype: Leu513Pro, Gly561A1a, Glu596Lys, Arg611Leu and IIe662Phe. For all candidate mutations, expression studies are in progress. This study of a large number of French variants of vWD brings further insight into the relationship between phenotype and genotype.

Primary structure of the propeptide and factor VIII-binding domain of bovine von Willebrand factor.

A 2811 base-pair cDNA, encoding the amino-terminal part of the bovine pre-pro-von Willebrand factor, was characterized and sequenced. The deduced amino acid sequence shares significant homology with the human von Willebrand antigen II and the amino-terminal part of the factor VIII-binding domain of von Willebrand factor. In contrast to human, there is no RGD motif in the bovine von Willebrand antigen II. High levels of Cys, characteristic of D domains, are also found in bovine and the Cys position is markedly conserved between the two species.

Characterization of recombinant von Willebrand factors mutated on cysteine 509 or 695.

The interacting domain of vWF with platelet GPIb has been shown to overlap the large A1 loop formed by the intra-chain disulfide bond linking Cys 509 to Cys 695. In order to further investigate the role of the conformation of this region, we have expressed in COS-7 cells three mutated full-length recombinant vWFs (rvWFs) in which the substitutions Cys509Gly, Cys509Arg or Cys695Gly have been introduced by site-directed mutagenesis. SDS-agarose gel electrophoresis demonstrated an impaired multimerization of the mutants with undetectable high molecular weight multimers and a decrease of the relative amounts of the intermediate sized multimers. Binding analysis showed that rvWFC509G and rvWFC509R did not interact with botrocetin but spontaneously interacted with GPIb; the latter binding remained unchanged in the presence of ristocetin. This indicates that the substitution of Cys509 by Gly or Arg creates a conformation of vWF that increases its binding to GPIb. In contrast, rvWFC695G which did not react with botrocetin was also unable to interact with GPIb even in the presence of ristocetin, indicating that sequences interacting with GPIb are masked and/or disrupted. In conclusion, the substitution of each of the Cys509 and 695 results in mutant proteins which may be "locked" into active or inactive conformations in regard to the binding to platelet GPIb receptor.

Structure-function relationship of the A1 domain of von Willebrand factor.

von Willebrand factor (vWF) is a multimeric glycoprotein composed of multiple homologous domains. The A1 domain contains a remarkably large disulfide loop of 185 amino acids (Cys 509-695) which plays a key role in promoting platelet adhesion to the subendothelium. Following the initial binding of the A1 domain to the subendothelium, a conformational change occurs which allows its binding to platelet GPIb. In an attempt to further understand the structure-function relationship of the A1 domain, we analyzed 1) the functional properties of recombinant vWF mutated on either Cys 509 or 695 and 2) the reactivity of a monoclonal antibody (MoAb B724) with vWF conformations interacting with GPIb. Our data underline the crucial role of the 509-695 disulfide bond in the binding of vWF to GPIb and discriminate the specificity of each Cys in this binding. They also indicate that two different conformations of the A1 loop, with high or low affinity for MoAb B724, allow the exposure of its GPIb-binding site. Since the low affinity conformation is observed in type 2B vWF, MoAb B724 appears as a useful tool to probe this type of von Willebrand disease (vWD).

Epitope mapping of inhibitory monoclonal antibodies to human von Willebrand factor by using recombinant cDNA libraries.

Two recombinant expression libraries containing small (300-600 base pairs) cDNA fragments of von Willebrand Factor (vWF) were screened in order to map the epitope of monoclonal antibodies (MAbs) to vWF. Among eleven MAbs tested, seven were effectively mapped. The epitopes of MAbs 418 and 522, which inhibit the binding of vWF to Factor VIII (FVIII), were localized between Leu 2 and Arg 53 and between Glu 35 and Ile 81 of the vWF subunit respectively, within the N-terminal trypsin fragment called SpIII-T4 [amino acids (aa) 1-272] which contains a binding domain for FVIII. The epitope of MAb 710, which inhibits the binding of vWF to glycoprotein Ib (GPIb), was identified between Ser 593 and Ser 678 on the tryptic 52/48 kDa fragment (aa 449-728) which contains binding domains for GPIb, collagen, heparin, sulfatides and subendothelium extracellular matrices. The epitope of MAb 723, which does not interfere with any known function of vWF, was localized between Ser 523 and Gly 588. The epitopes of MAb 505 and MAb 400, which inhibit the binding of vWF to collagen, were identified between Leu 927 and Arg 1114 within the SPI fragment (aa 911-1365) corresponding to the central part of the vWF subunit. The epitope of MAb 9, which inhibits the binding of vWF to GPIIb/IIIa, was identified in the C-terminal part of the vWF subunit between Gln 1704 and Asp 1746, the latter being the third aa of the RGD sequence common to adhesive proteins and serving as a recognition site for integrin receptors.

Influence of mutations and size of multimers in type II von Willebrand disease upon the function of von Willebrand factor.

We compared the properties of plasma von Willebrand factor (vWF) from normal individuals and from two patients with type IIA (Glu875Lys) and type IIB (duplication of Met 540) von Willebrand disease (vWD) with the corresponding fully multimerized recombinant proteins. We included cryosupernatant from normal human plasma and type IIA plasma (Cys509Arg). Functions of vWF were analyzed by binding assays to platelets in the presence of ristocetin or botrocetin. Parameters of binding (number of binding sites per vWF subunit, and dissociation constant Kd) were quantitatively estimated from the binding isotherms of 125I-botrocetin or glycocalicin to vWF, independently of the size of the multimers. We found that ristocetin- or botrocetin-induced binding to platelets was correlated in all cases with the size of vWF multimers. In the absence of inducer, only type IIB rvWF Met-Met540 spontaneously bound to platelets. No significant difference of binding of purified botrocetin to vWF was found between normal and patients' plasma, or between wild-type rvWF (rvWF-WT) and rvWF-Lys875. In contrast, affinity of botrocetin for type IIB rvWF Met-Met540 was decreased. Botrocetin-induced binding of glycocalicin to vWF from all plasma and cryosupernatant was similar. Compared with rvWF-WT, binding of glycocalicin to rvWF-Lys875 was normal. In contrast, the affinity for type IIB rvWF Met-Met540 was 10-fold greater. Thus, our data suggest that, in the patients tested, the abnormal IIA phenotype results from the lack of large-sized multimers and is independent of the point mutations. In contrast, the type IIB mutation is directly involved by providing a conformation to the vWF subunits that allows the high molecular weight multimers to spontaneously interact with platelet glycoprotein Ib.