Detailed von Willebrand factor multimer analysis in patients with von Willebrand disease in the European study, molecular and clinical markers for the diagnosis and management of type 1 von Willebrand disease (MCMDM-1VWD).

BACKGROUND: Type 1 von Willebrand disease (VWD) is a congenital bleeding disorder characterized by a partial quantitative deficiency of plasma von Willebrand factor (VWF) in the absence of structural and/or functional VWF defects. Accurate assessment of the quantity and quality of plasma VWF is difficult but is a prerequisite for correct classification. OBJECTIVE: To evaluate the proportion of misclassification of patients historically diagnosed with type 1 VWD using detailed analysis of the VWF multimer structure. PATIENTS AND METHODS: Previously diagnosed type 1 VWD families and healthy controls were recruited by 12 expert centers in nine European countries. Phenotypic characterization comprised plasma VWF parameters and multimer analysis using low- and intermediate-resolution gels combined with an optimized visualization system. VWF genotyping was performed in all index cases (ICs). RESULTS: Abnormal multimers were present in 57 out of 150 ICs; however, only 29 out of these 57 (51%) had VWF ristocetin cofactor to antigen ratio below 0.7. In most cases multimer abnormalities were subtle, and only two cases had a significant loss of the largest multimers. CONCLUSIONS: Of the cases previously diagnosed as type 1 VWD, 38% showed abnormal multimers. Depending on the classification criteria used, 22 out of these 57 cases (15% of the total cohort) may be reclassified as type 2, emphasizing the requirement for multimer analysis compared with a mere ratio of VWF functional parameters and VWF:Ag. This is further supported by the finding that even slightly aberrant multimers are highly predictive for the presence of VWF mutations.

[Diagnostic standards of von Willebrand disease]. / Standardisierte Diagnostik des von-Willebrand-Syndroms.

Von Willebrand disease (VWD) is caused by quantitative and/or qualitative defects of the von Willebrand factor (VWF), a multimeric high molecular glycoprotein. Typically, it affects the primary haemostatic system, which is reflected by a mucocutaneous bleeding tendency simulating a functional platelet defect. The VWF promotes its function in two ways: It promotes platelet adhesion to the injured vessel wall under conditions of high shear forces and it functions as carrier for factor VIII in plasma. Due to its complexity diagnosis of VWD is one of the most challenging of coagulation disorders. The stepwise diagnosis of VWD includes patient's and family history, orientating procedures (bleeding time, filter tests, platelet count, aPTT), confirmatory tests (VWF:Ag, VWF:RCo, VIII:C) and tests for final classification (VWF:CB, RIPA, multimeric analysis, bWF:FVIIIB, platelet VWF). Accumulating knowledge of the different clinical phenotypes and their pathophysiological basis was translated into a classification scheme that differentiated between quantitative and qualitative defects by means of quantitative and functional parameters and by analyzing the electrophoretic pattern of VWF multimers. The advent of molecular techniques provided the opportunity for genotype/phenotype studies which recently helped not only to elucidate or confirm important functions of VWF and the steps of its posttranslational processing but also many disease causing defects.

Von Willebrand Disease type 2M "Vicenza" in Italian and German patients: identification of the first candidate mutation (G3864A; R1205H) in 8 families.

Von Willebrand disease type 2M "Vicenza" (VWD 2M V) is characterised by autosomal dominant inheritance, low von Willebrand factor (VWF) and the presence of "supranormal" multimers in plasma. This specific phenotype has been described in Italian and recently also in German patients. The molecular defect is linked to the VWF gene. However, no specific mutations have been identified until now. We analysed the complete coding region and adjacent intron sequences of the VWF gene in Italian families in comparison to German families with VWD 2M V by a PCR-based mutation screening, combined with SSC- and heteroduplex-analysis of exons 2 through 52, followed by direct sequencing. We identified the first heterozygous candidate mutation (G3864A; R1205H) in all affected members of the 7 Italian families and in 1 German patient but not in the unaffected family members nor on 100 chromosomes of normal subjects, suggesting a causal relationship between the mutation and the phenotype. Haplotype identity, with minor deviations in one Italian family, suggests a common but not very recent genetic origin of R1205H.

Results of a screening for von Willebrand disease type 2N in patients with suspected haemophilia A or von Willebrand disease type 1.

A screening program for the detection of patients with von Willebrand disease type 2N (VWD 2N) was carried out in 177 unrelated patients previously diagnosed with haemophilia A and in 199 unrelated patients with VWD type 1 in comparison. By measuring the factor VIII (FVIII) binding capacity of von Willebrand factor (VWF), we detected 13 patients with VWD 2N within 8 unrelated families. The former diagnosis has been haemophilia A in 5 index patients, and VWD in the remaining 3. Included in this study were 14 patients with suspected haemophilia A, whose molecular analysis for mutations in the FVIII gene was unsuccessful. Five of them had VWD 2N. In all patients with the VWD 2N phenotype we were able to identify specific molecular defects in the corresponding DNA sequence of the FVIII binding domain of VWF. The most common defect was R91Q. Four patients from 4 families were homozygous for R91Q, six patients from 3 families were compound heterozygous for R91Q and a silent yet unidentified allele. The VWD 2N phenotype of father, daughter, and son in one family, was based on 2 different genotypes, compound heterozygosity for R91Q and VWD type 1 in the father and the daughter, and homozygosity for R91Q in the son. Two patients from one family were compound heterozygous for T28M and delta C2680-2685 in exon 18, and one patient was compound heterozygous for a novel candidate missense mutation in exon 18(E24K) and delta C2680-2685 in exon 18 which is regarded the most common defect causing severe VWD type 3. FVIII:C values of 0.07 and 0.14 IU/ml were observed in patients with the genotype T28M/delta C2680-2685 whereas in patients being homozygous or compound heterozygous for R91Q, FVIII:C was 0.19 +/- 0.071 IU/ml. In contrast to the other genotypes, E24K/delta C2680-2685 is correlated with a more severe haemophilic phenotype with a FVIII residual activity of only 0.01-0.02 IU/ml. This emphasizes the need for inclusion of the factor VIII binding assay in the diagnostic workup of suspected haemophilia A.

Von Willebrand factor multimers in virus-inactivated plasmas and F VIII concentrates.

The von Willebrand factor (vWf) stabilizes F VIII in plasma and is involved in platelet adhesion at high shear rates. While the first function is independent of the grade of multimerization, the latter needs the full range of large vWf multimers. Recently new virus-inactivated plasmas and F VIII concentrates, double-inactivated by heat and chemical treatment, became available. To evaluate whether these treatments have detrimental effects on the structure of the vWf protein we compared some of these products with fresh frozen plasma (FFP), and the Biotest F VIII concentrate with two F VIII concentrates inactivated by pasteurization or solvent/detergent (SD) treatment. The large vWf multimeres were preserved in single-donor plasmas and laboratory plasma pools. All commercial pool products showed a loss of the largest vWf multimers. While SD-treated plasma and the F VIII concentrates from Behring and Intersero contained enough large vWf multimers to allow treatment of patients with von Willebrand disease (vWd), the Biotest F VIII concentrate showed a loss of large and some intermediate multimers and is less suitable for the treatment of patients with vWd.