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.

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.

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.

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.

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.

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).

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.

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.

Functional analysis of the Arg91Gln substitution in the factor VIII binding domain of von Willebrand factor demonstrates variable phenotypic expression.

An Arg91Gln substitution in the mature von Willebrand factor (vWF) has been associated with defective binding of vWF to factor VIII (FVIII). We studied four families with members initially classified as having type I von Willebrand disease (vWD) who were either homozygous or heterozygous for the Arg91Gln change. The first family was the original case described by Nishino et al. (1) where three members were homozygous for the Gln91 allele. They had a low FVIII coagulant activity:vWF antigen (VIIIC:vWFAg) ratio, from 0.29 to 0.44, and the ability of their plasma vWF to bind FVIII was markedly decreased. All the heterozygous members had normal vWF and FVIII levels but the capacity of their plasma vWF to bind FVIII was reduced and intermediate between the homozygous members and normals. The affected individual from the second family was heterozygous for the Gln91 allele and demonstrated a VIIIC:vWFAg ratio of 0.98. The FVIII binding assay confirmed the heterozygous status indicating that the moderately low levels of vWF were due to reduced expression of both alleles. The propositus from the third family was also heterozygous and had below normal levels of vWF as well as a low VIIIC:vWFAg ratio of 0.34; however, FVIII binding to her plasma vWF was similar to that of the homozygous individuals suggesting that Gln91-vWF was the major circulating form. Her daughter who has type I vWD inherited the allele without the Gln91 mutation indicating that the expression of this allele was indeed impaired. The heterozygous patient in the fourth family had a vWF level of 24 U/dl but an VIIIC:vWFAg ratio greater than 2.(ABSTRACT TRUNCATED AT 250 WORDS)