An apparently silent nucleotide substitution (c.7056C>T) in the von Willebrand factor gene is responsible for type 1 von Willebrand disease.

BACKGROUND: Nucleotide variations not changing protein sequences are considered silent mutations; accumulating data suggest that they can, however, be important in human diseases. DESIGN AND METHODS: We report an altered splicing process induced by a silent substitution (c.7056C>T) in the von Willebrand factor gene in a case of type 1 von Willebrand disease originally classified as lacking von Willebrand factor mutations. RESULTS: The c.7056C>T synonymous substitution introduces a new donor splice site within exon 41, leading to messenger RNA lacking nucleotides 7055-7081 (c.7055_7081del). The encoded von Willebrand factor protein is predicted to lack amino acids 2352-2360 in the B2 domain. The patient's von Willebrand disease phenotype was characterized by reduced plasma and platelet von Willebrand factor, which was normal in function and multimer structure. In vitro expression studies demonstrated that co-transfection of equimolar c.7055_7081del and wild-type von Willebrand factor (mimicking the patient's heterozygous state) induced a 50% lower von Willebrand factor secretion than the wild type, while almost no von Willebrand factor secretion was seen with the mutated von Willebrand factor alone. The secreted von Willebrand factor was structurally and functionally normal, suggesting that the c.7056C>T substitution behaves like a loss-of-function allele. CONCLUSIONS: This is the first report of a synonymous von Willebrand factor substitution being responsible for von Willebrand disease. Our findings suggest the need to reconsider the role of von Willebrand factor polymorphisms in von Willebrand disease.

A novel von Willebrand factor mutation (I1372S) associated with type 2B-like von Willebrand disease: an elusive phenotype and a difficult diagnosis.

Mutations in the A1 domain of von Willebrand factor (VWF) may be associated with gain of function in the VWF-platelet GPIb interaction and consumption of large VWF multimers, as seen in type 2B von Willebrand disease (VWD). We report a new VWF abnormality associated with greater VWF-GPIb interaction in the presence of all VWF multimers. The index case is a woman with a lifelong history of bleeding, found hyperresponsive to ristocetin with spontaneous platelet aggregation (SPA). She had normal factor VIII, VWF:Ag, VWF:RCo and VWF:CB levels, normal VWF:RCo/VWF:Ag and VWF:CB/VWF:Ag ratios, and a full panel of plasma and platelet VWF multimers. A missense mutation (4115T>G) was found in exon 28 of the VWF gene, which replaced a isoleucine with a serine at position 1372 of pre-pro-VWF (I1372S) at heterozygous level. Recombinant VWF carrying the I1372S mutation and showing a normal VWF multimer organisation was capable of inducing SPA on normal platelet-rich plasma (unlike wild-type VWF), as well as a hyper-response to ristocetin in the same platelets (0.6 mg/ml ristocetin vs. 1.2 of wild-type VWF). The new I1372S VWF mutation, characterized by SPA and hyper-responsiveness to ristocetin thus has some of the features of type 2B VWD, but not the lack of large VWF multimers, so we defined this variant as type 2B-like VWD. Why I1372S VWF is associated with bleeding symptoms, despite normal VWF levels and multimer organisation, remains to be seen.