Severe von Willebrand disease due to a defect at the level of von Willebrand factor mRNA expression: detection by exonic PCR-restriction fragment length polymorphism analysis

Molecular and clinical profile of VWD in a large cohort of Chinese population: application of next generation sequencing and CNVplex® technique

Von Willebrand disease (VWD), the most common inherited bleeding disorder, is characterised by a variable bleeding tendency, heterogeneous laboratory phenotype and race specific distribution of mutations. The present study aimed to determine the correlation of genotype and phenotype in 200 Chinese individuals from 90 unrelated families with VWD. Next generation sequencing (NGS) of the whole coding VWF, copy number analysis of VWF by CNVplex^® technique as well as a comprehensive phenotypic assessment were carried out in all index patients (IPs). We identified putative mutations in all IPs except five mild type 1 (85/90, 94.4 %). In total, 98 different mutations were detected, 62 (63.3 %) of which were reported for the first time (23 missense mutations, 1 regulatory mutation, 12 splice site mutations and 26 null mutations). Mutations p.Ser1506Leu and p.Arg1374His/Cys/Ser were the most frequent mutations in 2A (33 % of cases) and 2M VWD (67 % of cases), respectively. In addition, mutation p.Arg816Trp was detected repeatedly in type 2N patients, while mutation p.Arg854Gln, extremely common in Caucasians, was not found in our cohort. Thirty-three patients had two or more putative mutations. Unlike most cases of type 1 and type 2 VWD, which were transmitted dominantly, we presented seven severe type 1, two type 2A and one type 2M with autosomal recessive inheritance. Here the phenotypic data of patients with novel mutations will certainly contribute to the better understanding of the molecular genetics of VWF-related phenotypes.

Nonsense-mediated mRNA decay among coagulation factor genes

OBJECTIVES

Haemostasis prevents blood loss following vascular injury. It depends on the unique concert of events involving platelets and specific blood proteins, known as coagulation factors. The clotting system requires precise regulation and coordinated reactions to maintain the integrity of the vasculature. Clotting insufficiency mostly occurs due to genetically inherited coagulation factor deficiencies such as hemophilia.

MATERIALS AND METHODS

A relevant literature search of PubMed was performed using the keywords coagulation factors, Nonsense-mediated mRNA decay and premature translation termination codons. Search limitations included English language and human-based studies.

RESULTS

Mutations that cause premature translation termination codons probably account for one-third of genetically inherited diseases. Transcripts bearing aberrant termination codons are selectively identified and eliminated by an evolutionarily conserved posttranscriptional pathway known as nonsense-mediated mRNA decay (NMD). There are many pieces of evidence of decay among coagulation factor genes. However, the hemophilia gene (F8) does not seem to be subjected to NMD. Since the F8 gene is located on the X-chromosome, a connection between X-linked traits and mRNA decay could be assumed.

CONCLUSION

Considering that not all genes go through decay, this review focuses on the basics of the mechanism in coagulation genes. It is interesting to determine whether this translation-coupled surveillance system represents a general rule for the genes encoding components of the same physiological cascade.

Family-specific degenerate primer design: a tool to design consensus degenerated oligonucleotides

Designing degenerate PCR primers for templates of unknown nucleotide sequence may be a very difficult task. In this paper, we present a new method to design degenerate primers, implemented in family-specific degenerate primer design (FAS-DPD) computer software, for which the starting point is a multiple alignment of related amino acids or nucleotide sequences. To assess their efficiency, four different genome collections were used, covering a wide range of genomic lengths: Arenavirus (10 × 10⁴ nucleotides), Baculovirus (0.9 × 10⁵ to 1.8 × 10⁵ bp), Lactobacillus sp. (1 × 10⁶ to 2 × 10⁶ bp), and Pseudomonas sp. (4 × 10⁶ to 7 × 10⁶ bp). In each case, FAS-DPD designed primers were tested computationally to measure specificity. Designed primers for Arenavirus and Baculovirus were tested experimentally. The method presented here is useful for designing degenerate primers on collections of related protein sequences, allowing detection of new family members.

Intersection of mechanisms of type 2A VWD through defects in VWF multimerization, secretion, ADAMTS-13 susceptibility, and regulated storage

Type 2A VWD is characterized by the absence of large VWF multimers and decreased platelet-binding function. Historically, type 2A variants are subdivided into group 1, which have impaired assembly and secretion of VWF multimers, or group 2, which have normal secretion of VWF multimers and increased ADAMTS13 proteolysis. Type 2A VWD patients recruited through the T. S. Zimmerman Program for the Molecular and Clinical Biology of VWD study were characterized phenotypically and potential mutations identified in the VWF D2, D3, A1, and A2 domains. We examined type 2A variants and their interaction with WT-VWF through expression studies. We assessed secretion/intracellular retention, multimerization, regulated storage, and ADAMTS13 proteolysis. Whereas some variants fit into the traditional group 1 or 2 categories, others did not fall clearly into either category. We determined that loss of Weibel-Palade body formation is associated with markedly reduced secretion. Mutations involving cysteines were likely to cause abnormalities in multimer structure but not necessarily secretion. When coexpressed with wild-type VWF, type 2A variants negatively affected one or more mechanisms important for normal VWF processing. Type 2A VWD appears to result from a complex intersection of mechanisms that include: (1) intracellular retention or degradation of VWF, (2) defective multimerization, (3) loss of regulated storage, and (4) increased proteolysis by ADAMTS13.

Common large partial VWF gene deletion does not cause alloantibody formation in the Hungarian type 3 von Willebrand disease population

BACKGROUND

Type 3 von Willebrand disease (VWD) is an autosomal recessive bleeding disorder, characterized by virtually undetectable plasma von Willebrand factor (VWF) and consequently reduced plasma factor VIII levels. Genetic mutations responsible for type 3 VWD are very heterogeneous, scattered throughout the VWF gene and show high variability among different populations.

METHODS

Twenty-five severe VWD patients were studied by direct sequencing of the 51 coding exons of the VWF gene. The total number of VWD type 3 families in Hungary is 24, of which 23 were investigated.

RESULTS

Fifteen novel mutations were identified in 31 alleles, five being nonsense mutations (p.Q1238X, p.Q1898X, p.Q1931X, p.S2505X and p.S2568X), four small deletions and insertions resulting in frame shifts (c.1992insC, c.3622delT, c.5315insGA and c.7333delG), one a large partial deletion (delExon1-3) of the 5'-region, four candidate missense mutations (p.C35R, p.R81G, p.C295S, p.C623T) and one a candidate splice site mutation (c.1730-10C>A). Six previously described mutations were detected in 17 alleles, including the repeatedly found c.2435delC, p.R1659X and p.R1853X. Only one patient developed alloantibodies to VWF, carrying a homozygous c.3622delT.

CONCLUSION

We report the genetic background of the entire Hungarian type 3 VWD population. A large novel deletion, most probably due to a founder effect, seems to be unique to Hungarian type 3 VWD patients with high allele frequency. In contrast to previous reports, none of the five patients homozygous for the large partial deletion developed inhibitors to VWF. This discrepancy raises the possibility of selection bias in some of the reports.

Modifiers of von Willebrand factor identified by natural variation in inbred strains of mice

Type 1 von Willebrand disease (VWD) is the most common inherited human bleeding disorder. However, diagnosis is complicated by incomplete penetrance and variable expressivity, as well as wide variation in von Willebrand factor (VWF) levels among the normal population. Previous work has exploited the highly variable plasma VWF levels among inbred strains of mice to identify 2 major regulators, Mvwf1 and Mvwf2 (modifier of VWF). Mvwf1 is a glycosyltransferase and Mvwf2 is a natural variant in Vwf that alters biosynthesis. We report the identification of an additional alteration at the Vwf locus (Mvwf5), as well as 2 loci unlinked to Vwf (Mvwf6-7) using a backcross approach with the inbred mouse strains WSB/EiJ and C57BL/6J. Through positional cloning, we show that Mvwf5 is a cis-regulatory variant that alters Vwf mRNA expression. A similar mechanism could potentially explain a significant percentage of human VWD cases, especially those with no detectable mutation in the VWF coding sequence. Mvwf6 displays conservation of synteny with potential VWF modifier loci identified in human pedigrees, suggesting that its ortholog may modify VWF in human populations.

Novel missense mutation c.2685G>C (p.Q895H) in VWF gene associated with very low levels of VWF mRNA

Homozygous patients for null alleles in VWF gene show a severe von Willebrand phenotype, whereas compound heterozygous patients only show the phenotype of the expressed allele. Five members of the same family were studied. The two patients showed borderline VWF levels, a mild factor VIII (FVIII) deficiency and a decrease of the binding of VWF to exogenous FVIII. The genetic analyses of the VWF gene confirmed that the patients were compound heterozygous for c.2561G>A (R854Q) and c.2685G>C (p.Q895H) mutations. The latter, is located in the 3' extreme of exon 20, and it has not been previously described. Studies of the cDNA from platelet mRNA were performed to investigate the expression of p.H895 allele. The loss of heterozygosity at the cDNA level suggests a lack of expression of the p.H895 allele. The overall studies can explain the type 2N phenotype of the two patients, since the allele carrying the new missense mutation p.Q895H has shown a low expression of VWF gene.

Multiplex PCR and quality control of Epinotia aporema granulovirus production

A specific multiplex PCR was developed for the rapid and highly sensitive quality control of the viral DNA during Epinotia aporema granulovirus (EpapGV) production. At the beginning of this work only 2.3% of the EpapGV genomic sequence was known. In order to increase the availability of specific information, the terminal sequences of the inserts of several selected clones of EpapGV genomic libraries were determined. These data comprised 8.4% of the total DNA sequence and corresponded to regions distributed throughout the genome. Based on the small fraction of known sequence available a set of 32 primers was designed, using information theory to set the basis for this study. Each pair of designed primers was initially tested in individual PCRs to assess the correct size of the expected product and the sensitivity of the amplification. The specificity was verified in multiplex PCRs, using alternatively 1-3 sets of selected 5-6 primer pairs and EpapGV DNA preparations from different sources and degrees of purity. The results indicate that the multiplex PCR could be used for quality control in the bioinsecticide production, as well as in other applications such as the detection of latent infections in E. aporema colonies, and studies related to virus distribution, vertical transmission, host range, or persistence in the field.

Von Willebrand's disease and the mechanisms of platelet function

Von Willebrand's disease, the most common congenital bleeding disorder in humans, is the consequence of quantitative and/or qualitative defects of von Willebrand factor, a protein necessary for platelet adhesion and thrombus formation at sites of vascular injury. The definition of the molecular basis of von Willebrand's disease has helped clarify the structure of von Willebrand factor as well as its essential role in platelet function, particularly under haemodynamic conditions of high shear stress. Platelets respond rapidly to alterations of endothelial cells by attaching firmly to the site of lesion, where exposure of subendothelial components may have occurred. The first layer of platelets is in contact with the thrombogenic surface (adhesion), whereas subsequent growth of the haemostatic plug depends on platelet-platelet interactions (aggregation). Both aspects of platelet function are influenced by von Willebrand factor binding to specific platelet membrane receptors as well as subendothelial structures, such as collagen.

New concepts in von Willebrand disease

Von Willebrand factor (VWF) behaves as an extracellular adapter molecule, linking platelets to the extracellular matrix at sites of vascular injury. These interactions are crucial for hemostasis. Too little platelet adhesion causes bleeding that is typical of von Willebrand disease, whereas too much platelet adhesion may cause thrombotic thrombocytopenic purpura. Mutations in VWF or platelet glycoprotein Ib can either reduce or increase the affinity of platelet binding. Paradoxically, affinity changes in either direction cause bleeding. Crystallographic studies now suggest molecular explanations for all of these phenotypes. Clinical investigations of von Willebrand disease type 1 are defining the relationship between plasma VWF level and the risk of bleeding or thrombosis. Emerging data suggest that VWF level is a useful biomarker for the risk of either bleeding or thrombosis and could be incorporated into a comprehensive approach to treat or prevent these adverse events.

Management of severe VWD with cryoprecipitate collected by repeated apheresis of a single dedicated donor

BACKGROUND

Rare and severe forms of VWD are associated with trace or absent VWF. The feasibility of supporting a child with severe VWD from birth through age 12 with cryoprecipitate derived from DDAVP-stimulated plasma exchange of a single dedicated donor is reported.

STUDY DESIGN AND METHODS

An infant with excessive hemorrhage at circumcision was found to have Type 3 VWD. His father carried an allele with a mutation at the level of VWF mRNA expression but did not have a history of bleeding. Cryoprecipitate was prepared from serial DDAVP-stimulated plasma exchanges of the father.

RESULTS

Repeated plasma-exchange donations were performed to provide all of the VWF needed for his son. An average of 14 cryoprecipitate units was prepared from each donation, and the units contained markedly elevated levels of FVIII:C. The cryoprecipitate was stored for up to 102 months. Components tested after more than 8 years of storage showed 48 to 130 percent of original FVIII:C activity. Ninety-seven percent of the bleeding episodes, such as epistaxis, tongue-biting accidents, and other minor lacerations, were successfully managed with a single 50- to 100-percent replacement dose of FVIII. The patient experienced normal growth and development and is free of any long-term sequelae attributable to his disease.

CONCLUSIONS

Cryoprecipitate prepared by repeated plasma exchange of a VWD carrier provided excellent hemostatic function, even after storage intervals of more than a year. Plasma exchange of a committed donor was a cost-effective and safe option for long-term management of VWD.

Von Willebrand disease type 1: a diagnosis in search of a disease

Von Willebrand disease (VWD) type 1 is reported to be common but frequently is difficult to diagnose. Many people have nonspecific mild bleeding symptoms, von Willebrand factor (VWF) levels display low heritability, and low VWF levels (15% to 50% of normal) are weak risk factors for bleeding. Therefore, bleeding and low VWF levels often associate by chance. Even with stringent diagnostic criteria based on a triad of bleeding symptoms, a low VWF level, and a positive family history, the prevalence of "false-positive" VWD type 1 is comparable to the published prevalence of the disease. Consequently, many patients diagnosed with VWD type 1 do not have a specific hemorrhagic disease at all, which limits the utility of the diagnosis. This unfortunate reality is a consequence of trying to force patients into binary categories of "diseased" or "healthy" that are incompatible with the continuous biologic context in which VWF functions. The problem may be avoided by substituting an empirical epidemiologic approach like that applied to other modest risk factors for disease such as elevated cholesterol and high blood pressure. Such a risk management strategy could be generalized to include other hemorrhagic and thrombotic risk factors.

The molecular biology of von Willebrand disease

von Willebrand disease (VWD) is a common autosomally inherited bleeding disorder associated with mucosal or trauma-related bleeding in affected individuals. VWD results from either a quantitative or qualitative deficiency of von Willebrand factor (VWF)--a glycoprotein with essential roles in primary haemostasis and as a carrier of coagulation factor VIII (FVIII) in the circulation. In recent years the identification of mutations in the VWF gene in patients with VWD has improved our understanding of the structure and function of the VWF protein, and has illustrated the importance of specific regions of VWF for its interaction with other components of the vasculature. The underlying genetic lesions and associated molecular pathology have been identified in many cases of type 2A, type 2B, type 2M, type 2N and type 3 VWD. However in the most common variant, type 1 VWD, the causative molecular defect is unknown in the large majority of cases. In the absence of an understanding of the molecular pathology underlying type 1 VWD, precise diagnosis and classification of this common disorder remains problematic.

Congenital von Willebrand disease type 3: clinical manifestations, pathophysiology and molecular biology

von Willebrand disease type 3 is the most severe form of this condition. Patients present with a moderate-to-severe bleeding tendency. The plasma von Willebrand factor level in these patients is very low or undetectable. Although rare, von Willebrand disease type 3 is of major interest because of its severe clinical presentation, the need for replacement therapy and the risk of occurrence of alloantibodies after the infusion of plasma concentrates. The inheritance of type 3 disease is typically autosomal recessive. The parents are often consanguineous, although compound heterozygous inheritance does occur. The molecular basis of von Willebrand disease type 3 has recently been studied in detail, several molecular defects being identified. This chapter will focus on the clinical and molecular aspects of type 3 von Willebrand disease.

Mvwf, a dominant modifier of murine von Willebrand factor, results from altered lineage-specific expression of a glycosyltransferase

We have identified altered lineage-specific expression of an N-acetylgalactosaminyltransferase gene, Galgt2, as the gain-of-function mechanism responsible for the action of the Mvwf locus, a major modifier of plasma von Willebrand factor (VWF) level in RIIIS/J mice. A switch of Galgt2 gene expression from intestinal epithelial cell-specific to a pattern restricted to the vascular endothelial cell bed leads to aberrant posttranslational modification and rapid clearance of VWF from plasma. Transgenic expression of Galgt2 directed to vascular endothelial cells reproduces the low VWF phenotype, confirming this switch in lineage-specific gene expression as the likely molecular mechanism for Mvwf. These findings identify alterations in glycosyltransferase function as a potential general mechanism for the genetic modification of plasma protein levels.

Linkage of combined factors V and VIII deficiency to chromosome 18q by homozygosity mapping

Combined Factors V and VIII deficiency is an autosomal recessive bleeding disorder identified in at least 58 families comprising a number of different ethnic groups. Affected patients present with a moderate bleeding tendency and have Factor V and Factor VIII levels in the range of 5-30% of normal. The highest frequency of the mutant gene is found in Jews of Sephardic and Middle Eastern origin living in Israel with an estimated disease frequency of 1:100,000. We sought to identify the gene responsible for combined Factors V and VIII deficiency using a positional cloning approach. Of 14 affected individuals from 8 unrelated Jewish families, 12 were the offspring of first-cousin marriages. After a genome-wide search using 241 highly polymorphic short tandem repeat (STR) markers, 13 of the 14 affected patients were homozygous for two closely linked 18q markers. Patients and all available family members were genotyped for 11 additional STRs spanning approximately 11 cM on the long arm of chromosome 18. Multipoint linkage analysis yielded a maximal log of the odds (LOD) score of 13.22. Haplotype analysis identified a number of recombinant individuals and established a minimum candidate interval of 2.5 cM for the gene responsible for combined Factors V and VIII deficiency. The product of this locus is likely to operate at a common step in the biosynthetic pathway for these two functionally and structurally homologous coagulation proteins. Identification of this gene should provide new insight into the biology of Factor V and Factor VIII production.

von Willebrand disease

Considerable progress has been made in characterizing the specific molecular defects responsible for the heterogeneous disorder known as von Willebrand disease (VWD). A large number of molecular defects have been identified and precise characterization may now be possible in the majority of type 2A, type 2B, type 2N, and potentially also type 3 VWD cases. However, the most common variant, type 1 VWD, still remains a major challenge. Continued progress in this area will improve our understanding of the pathogenesis of VWD and lead to more rapid and precise diagnosis and classification for this common disorder. The problems of incomplete VWD penetrance and poor diagnostic sensitivity and accuracy for the currently available clinical laboratory tests provide strong incentives for the development of DNA-based diagnostics. In addition, prenatal diagnosis is now possible either at the level of single point mutations (for some subtypes) or by RFLP analysis (assuming linkage to the von Willebrand factor [VWF] gene) and will probably be applied with increasing frequency for VWD type 3 (17, 133, 175). Understanding the molecular basis of VWD also has important implications for VWF structure and function and is helping to define critical binding domains within the VWF molecule. Insights gained from these studies may eventually lead to improved therapeutic approaches not only for VWD, but also for a variety of other genetic and acquired hemorrhagic and thrombotic disorders.

Von Willebrand's disease

von Willebrand's disease (vWD) arises from abnormalities in von Willebrand factor (vWF), an adhesive glycoprotein uniquely involved in key aspects of both primary and secondary hemostasis. The current classification distinguishes disorders arising from partial (type 1) or complete (type 3) deficiencies and from qualitative defects (type 2). Type 2 vWD is further divided into four subtypes (A, B, N, and M), reflecting distinct classes of functional abnormalities. Mis-sense mutations account for most of type 2 vWD, whereas major disruptions in the vWF gene produce type 3 variants. The molecular basis of type 1 vWD is largely undefined. The laboratory diagnosis of vWD and its several variants is made on the basis of immunologic and functional studies of vWF, factor VIII levels, and specialized electrophoretic analysis (multimer gels). The mainstay of therapy for most patients with vWD in desmopressin, a pharmacologic agent that stimulates the release of endogenous pools of vWF. Cryoprecipitate and selected factor VIII concentrates are useful sources of exogenous vWF for the treatment of patients unresponsive to this desmopressin.

von Willebrand's disease in Scottish Terriers in Australia

Over a 5-year period (1988-92), von Willebrand factor antigen (vWf:Ag) assays were performed on plasma samples from 207 Scottish Terriers. Based on these tests, 47 dogs (23%) had vWf:Ag concentrations < 50 canine units (CU)/dL and were classified as heterozygous carriers of the von Willebrand's disease (vWD) gene, while 9 (4%) had concentrations below the sensitivity of the assays and were classified as homozygous. There was thus an overall prevalence of 27% for the vWD gene in the Scottish Terriers tested. The homozygous dogs (median age 0.6 years at diagnosis) consisted of 7 males and 2 females. Eight of these had haemorrhage attributable to the disease, mostly spontaneous and from the oral mucosa. Other signs included haemorrhage induced by trauma or surgery, easy bruising and epistaxis. Many haemorrhagic episodes were severe enough to warrant therapeutic intervention and there was a single fatality. Pedigree analysis, possible in 7 of the dogs, revealed that each was the progeny of a mating between dogs with vWf:Ag concentrations < 50 CU/dL, which supported an autosomal recessive mode of inheritance. A single heterozygous carrier suffered haemorrhage after surgery that, in contrast to the homozygotes, was mild and did not require therapy. The data indicate that vWD is a significant problem in Scottish Terriers in Australia. Accordingly, we recommend that steps be taken to reduce the prevalence of the disease and thereby the number of clinically affected dogs, such as the establishment of a national testing scheme to determine the vWD status of all breeding dogs.

Linkage disequilibrium patterns vary with chromosomal location: a case study from the von Willebrand factor region

Linkage disequilibrium analysis has been used as a tool for analyzing marker order and locating disease genes. Under appropriate circumstances, disequilibrium patterns reflect recombination events that have occurred throughout a population's history. As a result, disequilibrium mapping may be useful in genomic regions of < 1 cM where the number of informative meioses needed to detect recombinant individuals within pedigrees is exceptionally high. Its utility for refining target areas for candidate disease genes before initiating chromosomal walks and cloning experiments will be enhanced as the relationship between linkage disequilibrium and physical distance is better understood. To address this issue, we have characterized linkage disequilibrium in a 144-kb region of the von Willebrand factor gene on chromosome 12. Sixty CEPH and 12 von Willebrand disease families were genotyped for five PCR-based markers, which include two microsatellite repeats and three single-base-pair substitutions. Linkage disequilibrium and physical distance between polymorphisms are highly correlated (rm = -.76; P < .05) within this region. None of the five markers showed significant disequilibrium with the von Willebrand disease phenotype. The linkage disequilibrium/physical distance relationship was also analyzed as a function of chromosomal location for this and eight previously characterized regions. This analysis revealed a general trend in which linkage disequilibrium dissipates more rapidly with physical distance in telomeric regions than in centromeric regions. This trend is consistent with higher recombination rates near telomeres.

A novel case of compound heterozygosity with "Normandy"/type I von Willebrand disease (vWD). Direct demonstration of the segregation of one allele with a defective expression at the mRNA level causing type I vWD

We report the case of a family with type I von Willebrand disease (vWD), characterized by a quantitative defect in von Willebrand factor (vWF), associated with a defective binding of vWF to factor VIII (FVIII) also called the "Normandy" variant of vWD. PCR products from genomic DNA of the family members were analysed in the region coding for the binding domain of vWF to FVIII. It showed that the proposita and one of her sons were heterozygous for the Arg91Gln missense mutation, abolishing an MspI restriction enzyme site located in exon 20. The transcription of the normal and mutated alleles was tested by the amplification of cDNA after reverse transcription of platelet mRNA in this region. A total lack of expression of the normal allele was observed in the proposita, who appeared as a compound heterozygous with one allele mutated at Arg91 and a "silent" expression of the other one. The segregation of the "silent" allele was studied in the family with the exonic BstEII RFLP both at the DNA and mRNA levels. The proposita has transmitted her "silent" allele to her daughter and to another son. As this son was informative for this RFLP, the absence of expression of the allele could be demonstrated at the mRNA level, providing evidence that this defect was responsible for his type I vWD.

Recessive inheritance of von Willebrand's disease type I

The inheritance of type I von Willebrand's disease is thought to be autosomally dominant. The laboratory profile may, however, vary between affected people, even within a single family. There is also a large variation in the severity of clinical symptoms. To see if there is an association between the von Willebrand factor genotype, the laboratory profile, and the severity of the clinical symptoms we did a genetic analysis of four families with type I von Willebrand's disease. The proband of each family proved to be a compound heterozygote for defects in the von Willebrand factor gene. Simple heterozygotes in these families were either symptomless or only mildly affected. One of the identified mutations, which was shared by the probands of three of the four families, may have a carrier prevalence of 1:50 in the general population. These results suggest that the inheritance of von Willebrand's disease is often recessive rather than dominant and so have important implications for diagnosis and genetic counselling.

Nonsense mutations of the von Willebrand factor gene in patients with von Willebrand disease type III and type I

von Willebrand disease (vWD) is the most common inherited bleeding disorder in humans. The disease is caused by qualitative and quantitative abnormalities of the von Willebrand factor (vWF). Genomic DNA from 25 patients with vWD type III, the most severe form of the disease, was studied using PCR followed by restriction-enzyme analysis and direct sequencing of the products. Nonsense mutations (CGA----TGA) were detected in exons 28, 32, and 45 by screening of all the 11 CGA arginine codons of the vWF gene. Two patients were found to be homozygous and five heterozygous for the mutation. Both parents and some of the relatives of the homozygous patients carry the mutation. These are the first reported examples of homozygous point mutations associated with the severe form of vWD. In the three heterozygous probands, one of the parents carried the mutation and had vWD type I. Family studies including parents and family members with or without vWD type I indicated that these three heterozygous patients are likely to be compound heterozygous. Twenty-one individuals from these seven families with vWD type I were found to be heterozygous for the mutation.

A patient with von Willebrand's disease characterized by a compound heterozygosity for a substitution of Arg854 by Gln in the putative factor-VIII-binding domain of von Willebrand factor (vWF) on one allele and very low levels of mRNA from the second vWF allele

We describe a patient with a lifelong bleeding disorder previously classified as von Willebrand's disease (vWD) type I. The factor VIII (FVIII) level in this patient was disproportionately low and we showed that this was due to a decreased factor VIII binding capacity of her vWF. To characterize the molecular defect in this type of vWD, a cDNA-dependent polymerase chain reaction (PCR) amplification was performed using platelet RNA as a template. Direct sequencing of the amplified fragment, which encodes for the FVIII-binding domain, showed a single nucleotide change in exon 20 at codon 854, resulting in the substitution of CAG glutamine (Gln) for CGG arginine (Arg). At the level of the cDNA only the mutated sequence was found, whereas at genomic DNA level the patient was heterozygous for this mutation. This patient is therefore a compound heterozygote for a point mutation resulting in a FVIII-binding defect and a vWF allele with low transcript levels.