Type 2N von Willebrand disease: Characterization and diagnostic difficulties.

INTRODUCTION: An abnormal factor VIII (FVIII) binding capacity of von Willebrand factor (VWF) identifies type 2N von Willebrand disease (VWD). Type 2N VWD patients are identified by means of the VWF FVIII binding (VWF:FVIIIB) assay, and especially their VWF:FVIIIB/VWF:Ag ratio (VWF:FVIIIB ratio). AIM: We report on our 15-year experience of diagnosing type 2N VWD. METHODS: We have performed 2178 VWF:FVIIIB assays in bleeders and normal subjects. RESULTS: von Willebrand factor (VWF):FVIIIB was reduced in 682, but only 60 had low VWF:FVIIIB ratios (<0.74). Among nine patients who had a VWF:FVIIIB ratio below 0.3, four had normal VWF levels and were homozygotes for the p.R854Q mutation; the other five had low VWF levels due to a quantitative VWF mutation combined with p.R854Q. The VWF:FVIIIB ratio ranged between 0.3 and 0.73 in 51 subjects; 34 of them were heterozygotes for the p.R854Q mutation, while one carried the p.R760C. The heterozygotes for type 2N included subjects with or without bleeding symptoms, the former with significantly lower mean VWF levels than the latter. Among the 116 normal subjects tested, six were heterozygotes for the p.R854Q mutation (all asymptomatic). CONCLUSIONS: The prevalence of type 2N in our VWD cohort was 2.5%, and 5.2% of the general population in Northeast Italy was found heterozygous for the p.R854Q mutation. It might be difficult to reveal a type 2N defect using routine tests alone, especially when it is combined with a quantitative VWF mutation. Accordingly, we always recommend VWF:FVIIIB assay in the diagnostic workup of VWD.

Usefulness of the Total Thrombus-Formation Analysis System (T-TAS) in the diagnosis and characterization of von Willebrand disease.

INTRODUCTION: The heterogeneity of von Willebrand disease (VWD) makes its diagnosis a difficult task. METHODS: We report here on the usefulness of a microchip-based flow-chamber system, the total thrombus-formation analysis system (T-TAS), in the identification and characterization of VWD. Thirty VWD patients and 20 healthy subjects were studied with the T-TAS platelet (PL) and atherome (AR) microchips developed for the in vitro assessment of platelet thrombus formation and fibrin-rich platelet thrombus formation respectively. RESULTS: Samples from severe type 1 VWD, characterized by von Willebrand factor (VWF) levels below 10 U dL-1 , failed to occlude either the PL or the AR chip capillaries, while the occlusion times were normal in patients with mild type 1 VWD (VWF above 25 U dL-1 ). PL and/or AR chip occlusion occurred, but took longer than normal, for samples from type Vicenza and type 1 VWD patients, whose VWF levels ranged between 10 and 25 U dL-1 . No PL or AR chip capillary occlusion was seen for samples from patients with type 2A or 2B VWD featuring the absence of large VWF multimers, whereas no abnormalities emerged for type 2B patients with normal multimer patterns. CONCLUSION: The T-TAS appears to be sensitive mainly to plasma VWF concentration and the presence of large multimers. Failure of the PL and AR chips to become occluded points to a lack of large VWF multimers, or type 1 VWD with VWF levels below 10 U dL-1 . Although the T-TAS does not assure a precise VWD diagnosis, it does point us in the right direction, and thus seems a useful global preliminary test.

Severe, recessive type 1 is a discrete form of von Willebrand disease: the lesson learned from the c.1534-3C>A von Willebrand factor mutation.

Type 1 von Willebrand disease (VWD) is transmitted mainly as a dominant trait - especially in forms involving von Willebrand factor (VWF) levels below 20 U/dL - and less frequently as a recessive trait. In the latter case, mutations at heterozygous level may be associated with type 3 carrier status, while mutations at homozygous or compound heterozygous level often coincide with type 3 VWD. Here we present a recessive, severe type 1 form as a distinct type of VWD. Eight patients with severe type 1 VWD belonging to 7 unrelated families were studied. They had VWF levels below 10 U/dL, FVIII higher than 10 U/dL, and a significantly lower than normal platelet VWF content. All patients were homozygous or compound heterozygous for the c.1534-3C>A VWF mutation, that simultaneously induces the skipping of exon 14, the activation of a cryptic splice site, and a normal VWF gene transcription. This means that one of the three different mRNA generated assures the synthesis of normal VWF. The probands' relatives who were heterozygous for the c.1534-3C>A mutation always had low platelet VWF levels, sometimes with circulating VWF levels within normal range. This finding confirms the utility of measuring platelet VWF content to identify an abnormal VWF synthesis. Because the c.1534-3C>A mutation impairs, but does not abolish normal mRNA processing, it may never cause type 3 VWD. We propose a model of severe recessive type 1 VWF defect associated with mutations that sporadically go undetected by the cells' molecular machinery, as the c.1534-3C>A VWF mutation. BULLET POINTS: What is known about this topic? - Type 1 VWD is transmitted mainly as a dominant trait. - Recessive type 1 mutations at homozygous or compound heterozygous level are often associated with type 3 VWD, and at heterozygous level with type 3 VWD carrier status. What does this paper add? - There are quantitative VWF mutations, such as c.1534-3C>A, that impair, but do not abolish normal mRNA processing. - The c.1534-3C>A VWF mutation simultaneously induces the skipping of exon 14, the activation of a cryptic splice site, and a normal VWF gene transcription. - The c.1534-3C>A mutation is the archetype of mutations that cause severe recessive type 1 VWD, but never type 3 VWD. - Recessive, severe type 1 appears to be a distinct form of VWD.

Loss of cysteine 584 impairs the storage and release, but not the synthesis of von Willebrand factor.

Cysteines play a key part in von Willebrand factor (VWF) dimerisation and polymerisation, and their loss may severely affect VWF structure and function. We report on three patients with type 3 von Willebrand disease carrying the new c.1751G>T missense mutation that induces the substitution of cysteine 584 by phenylalanine (C584F), and the deletion of seven nucleotides in exon 7 (c.729_735del), producing a premature stop codon at position 454 (E244Lfs*211). VWF was almost undetectable in the patients' plasma and platelets, while a single, poorly represented, oligomer emerged on plasma VWF multimer analysis. No post-DDAVP increase in VWF and factor VIII was observed. Expressing human recombinant C584F-VWF in HEK293T cells showed that C584F-VWF was synthesised and multimerised but not secreted - apart from the first oligomer, which was slightly represented in the conditioned medium, with a pattern similar to the patients' plasma VWF. The in vitro expression of the E244Lfs*211-VWF revealed a defective synthesis of the mutated VWF, with a behavior typical of loss of function mutations. Cellular trafficking, investigated in HEK293 cells, indicated a normal C584F-VWF content in the endoplasmic reticulum and Golgi apparatus, confirming the synthesis and multimerisation of C584F-VWF. No pseudo-Weibel Palade bodies were demonstrable, however, suggesting that C584F mutation impairs the storage of C584F-VWF. These findings point to cysteine 584 having a role in the release of VWF and its targeting to pseudo-Weibel Palade bodies in vitro, as well as in its storage and release by endothelial cells in vivo.

Venous thromboembolism in patients with Cushing's syndrome: need of a careful investigation of the prothrombotic risk profile.

A high incidence of venous thromboembolic (VTE) complications has been reported in Cushing's syndrome (CS), mostly post-operatively and attributable to hypercoagulability. The prevalence of symptomatic VTE was investigated retrospectively in 58 consecutive CS patients in relation to acquired and genetic thrombotic risk factors. Eight CS patients (14 %) developed VTE (group A), 3 of them related and 5 unrelated to surgery. These patients had higher urinary free cortisol (p = 0.01) and VWF levels (p = 0.02) than the 50 patients without VTE (group B), as well an increase in the hemostatically more efficient, high-molecular-weight VWF multimers (p = 0.002). Factor V Leiden and the prothrombin gene 20210A variants (the most common inherited thrombophilic defects) were more represented in group A than in group B, as was the genotype GCAG/GCAG of the VWF gene promoter, known to hyperinduce VWF upregulation under cortisol excess. All but one of the patients with VTE unrelated to surgery had at least four acquired and at least one inherited risk factor. Severe hypercortisolism and VWF levels with increased haemostatic activity are strongly associated with VTE in CS. VTE episodes unrelated to surgery are attributable to the synergistic action of acquired and inherited thrombotic risk factors. Based on these observations, we believe that severely affected CS patients should be screened for coagulation disorders and receive antithrombotic prophylaxis whenever they have concomitant prothrombotic risk factors.

Von Willebrand factor propeptide makes it easy to identify the shorter Von Willebrand factor survival in patients with type 1 and type Vicenza von Willebrand disease.

Reduced von Willebrand factor (VWF) half-life has been suggested as a new pathogenic mechanism in von Willebrand disease (VWD). The usefulness of VWF propeptide (VWFpp) in exploring VWF half-life was assessed in 22 type 1 and 14 type Vicenza VWD patients, and in 30 normal subjects, by comparing the findings on post-Desmopressin (DDAVP) VWF t(1/2) elimination (t(1/2el)). The VWFpp/VWF antigen ratio (VWFpp ratio) was dramatically increased in type Vicenza VWD (13.02 +/- 0.49) when compared to normal subjects (1.45 +/- 0.06), whereas it appeared to be normal in all type 1 VWD patients (1.56 +/- 0.7), except for the four carrying the C1130F mutation (4.69 +/- 0.67). A very short VWF t(1/2el) was found in type Vicenza VWD (1.3 +/- 0.2 h), while all type 1 VWD patients had a t(1/2el) similar to that of the controls (11.6 +/- 1.4 and 15.4 +/- 2.5 h respectively), except for the four patients carrying the C1130F mutation, who had a significantly shorter VWF survival (4.1 +/- 0.2 h). A significant inverse correlation emerged between VWFpp ratio and VWF t(1/2el) in both VWD patients and normal subjects. The VWFpp ratio thus seemed very useful for distinguishing between type 1 VWD cases with a normal and a reduced VWF survival, as well as for identifying type Vicenza VWD.