Type 1 von Willebrand disease mutation Cys1149Arg causes intracellular retention and degradation of heterodimers: a possible general mechanism for dominant mutations of oligomeric proteins.

Some families affected by von Willebrand disease type 1 show high penetrance with exceptionally low von Willebrand factor (VWF) levels. Previously, a mutation associated with this dominant phenotype, Cys1149Arg, was found to decrease the secretion of coexpressed normal VWF, and the mutation was proposed to cause intracellular retention of pro-VWF heterodimers. To demonstrate heterodimer formation, a model was developed in which subunits could be distinguished immunologically and by size. Recombinant VWF lacking domain A1 (dA1), A3 (dA3), or both (dA13) was secreted efficiently as a full range of multimers. Cotransfection of Cys1149Arg and dA13 resulted in the secretion of multimeric VWF containing about 250 kd (Cys1149Arg) and about 210 kd (dA13). Cell lysates contained pro-VWF forms of Cys1149Arg and dA13. Immunoprecipitation with an antidomain A1 antibody recovered both subunits in heterodimers, and subunit ratios were consistent with random dimerization. Similar results were obtained for cotransfection of Cys1149Arg and dA1. Normal VWF has a Cys1149-Cys1169 intrachain bond. When cotransfected with normal VWF, Cys1149Arg or the double mutant Cys1149Arg+Cys1169Ser caused a similar decrease in VWF secretion, suggesting that an unpaired Cys1169 does not explain the intracellular retention of Cys1149Arg. VWF Cys1149Arg was not secreted from BHK cells but was degraded intracellularly within about 4 hours, and the proteasome inhibitor lactacystin delayed its clearance more than 16 hours. Thus, dominant von Willebrand disease type 1 may be caused by heterodimerization of mutant and normal subunits in the endoplasmic reticulum followed by proteasomal degradation in the cytoplasm. A similar dominant negative mechanism could cause quantitative deficiencies of other multisubunit proteins.

Localization of disulfide bonds in the cystine knot domain of human von Willebrand factor.

von Willebrand factor (VWF) is a multimeric glycoprotein that is required for normal hemostasis. After translocation into the endoplasmic reticulum, proVWF subunits dimerize through disulfide bonds between their C-terminal cystine knot-like (CK) domains. CK domains are characterized by six conserved cysteines. Disulfide bonds between cysteines 2 and 5 and between cysteines 3 and 6 define a ring that is penetrated by a disulfide bond between cysteines 1 and 4. Dimerization often is mediated by additional cysteines that differ among CK domain subfamilies. When expressed in a baculovirus system, recombinant VWF CK domains (residues 1957-2050) were secreted as dimers that were converted to monomers by selective reduction and alkylation of three unconserved cysteine residues: Cys(2008), Cys(2010), and Cys(2048). By partial reduction and alkylation, chemical and proteolytic digestion, mass spectrometry, and amino acid sequencing, the remaining intrachain disulfide bonds were characterized: Cys(1961)-Cys(2011) (), Cys(1987)-Cys(2041) (), Cys(1991)-Cys(2043) (), and Cys(1976)-Cys(2025). The mutation C2008A or C2010A prevented dimerization, whereas the mutation C2048A did not. Symmetry considerations and molecular modeling based on the structure of transforming growth factor-beta suggest that one or three of residues Cys(2008), Cys(2010), and Cys(2048) in each subunit mediate the covalent dimerization of proVWF.

Incomplete embryonic lethality and fatal neonatal hemorrhage caused by prothrombin deficiency in mice.

Deficiency of blood coagulation factor V or tissue factor causes the death of mouse embryos by 10.5 days of gestation, suggesting that part of the blood coagulation system is necessary for development. This function is proposed to require either generation of the serine protease thrombin and cell signaling through protease-activated receptors or an activity of tissue factor that is distinct from blood clotting. We find that murine deficiency of prothrombin clotting factor 2 (Cf2) was associated with the death of approximately 50% of Cf2(-/-) embryos by embryonic day 10.5 (E10.5), and surviving embryos had characteristic defects in yolk sac vasculature. Most of the remaining Cf2(-/-) embryos died by E15.5, but those surviving to E18.5 appeared normal. The rare Cf2(-/-) neonates died of hemorrhage on the first postnatal day. These studies suggest that a part of the blood coagulation system is adapted to perform a developmental function. Other mouse models show that the absence of platelets or of fibrinogen does not cause fetal wastage. Therefore, the role of thrombin in development may be independent of its effects on blood coagulation and instead may involve signal transduction on cells other than platelets.

Dominant type 1 von Willebrand disease caused by mutated cysteine residues in the D3 domain of von Willebrand factor.

No defects have been reported in moderately severe type 1 von Willebrand disease (vWD) with a clear autosomal dominant inheritance pattern, and the mechanism underlying this form of vWD remains obscure. We have studied a type 1 vWD family with such a dominant phenotype. The entire coding sequence of the von Willebrand factor (vWF) gene was analyzed by direct sequencing of DNA fragments amplified by polymerase chain reaction. Only one candidate mutation T(3445)-->C in exon 26 was detected that predicts a replacement of cysteine (C) at position 386 of the mature vWF subunit by arginine (R). Both mutant and normal vWF alleles were expressed as shown by analysis of platelet mRNA. This substitution segregates with vWD in the family and was not found in 100 unrelated individuals. The recombinant mutant vWF(C386R) was characterized by expression in 293T cells. The secretion of vWF(C386R) was greatly impaired due to retention in the endoplasmic reticulum. In cotransfections of normal and mutant vWF constructs, the vWF(C386R) subunits caused a dose-dependent decrease in the secretion of vWF. The multimer pattern remained nearly normal and consistent with a dominant vWD type 1 phenotype. The importance of the cysteine residues in the D3 domain of vWF in the pathogenesis of dominant type 1 vWD was further shown by the detection of another cysteine mutation, Cys367-->Phe, in two additional unrelated patients with a similar dominant type 1 vWD phenotype. We conclude that the loss of cysteine pairing in the D3 domain, leaving one free cysteine, can induce a purely quantitative deficiency of vWF by dominantly suppressing the secretion of normal vWF.

Molecular mechanism and classification of von Willebrand disease.

The characterization of mutations in von Willebrand disease provides useful insight into the synthesis, structure, and function of von Willebrand factor. This growing body of information has prompted a reclassification of vWD types that is intended to reflect distinct pathophysiologic mechanisms. Despite this apparent progress, many aspects of vWF biology and pathophysiology remain poorly understood. These include the mechanism by which binding of vWF to platelets is induced at sites of vascular injury, and the factors that influence the likelihood of bleeding symptoms in patients with vWD type 1.

Characterization of partial gene deletions in type III von Willebrand disease with alloantibody inhibitors.

von Willebrand factor gene deletions were characterized in four patients with severe type III von Wilebrand disease and alloantibodies to von Willebrand factor. A PCR-based strategy was used to characterize the boundaries of the deletions. Identical 30 kb von Willebrand factor gene deletions which include exons 33 through 38 were identified in two siblings of one family by this method. A small 5 base pair insertion (CCTGG) was sequenced at the deletion breakpoint. PCR analysis was used to detect the deletion in three generations of the family, including two family members who are heterozygous for the deletion. In a second family, two type III vWD patients, who are distant cousins, share an approximately 56 kb deletion of exons 22 through 43. The identification and characterization of large vWF gene deletions in these type III vWD patients provides further support for the association between large deletions in both von Willebrand factor alleles and the development of inhibitory alloantibodies.

Disulfide bonds required to assemble functional von Willebrand factor multimers.

The hemostatic functions of human von Willebrand Factor (vWF) depend on the normal assembly of disulfide-linked multimers from approximately 250-kDa subunits. Subunits initially form dimers through disulfide bonds near the COOH terminus. Dimers then form multimers through disulfide bonds near the NH2 terminus of each subunit. Previous studies of plasma vWF and recombinant vWF fragments indicate that 1 or more of the Cys residues at position 459, 462, and 464 form intersubunit disulfide bonds. No evidence has been reported that vWF multimer formation involves additional intersubunit bonds. To probe the disulfide bond requirements for multimer formation, mutant vWF proteins were expressed in which all 3 Cys residues at positions 459, 462, and 464 were changed to either Gly or Ala. Surprisingly, none of these cysteines appears to be necessary for efficient multimer assembly. Furthermore, recombinant vWF with Gly or Ala at all three positions induces platelet aggregation in the presence of ristocetin and binds to platelet glycoprotein Ib, factor VIII, and collagen in a manner similar to wild-type recombinant vWF. These results suggest that other intersubunit disulfide bonds must exist. Direct evidence for such a bond was obtained by characterization of tryptic fragments of vWF. By Edman degradation, amino acid composition, and mass spectrometry, a disulfide bond was demonstrated between Cys379 residues of adjacent vWF subunits. Thus, intersubunit disulfide bonds involving Cys379 and 1 or more of the Cys residues at positions 459, 462, and 464 connect the NH2-terminal ends of the vWF subunits in a parallel orientation.

Type IIB mutation His-505-->Asp implicates a new segment in the control of von Willebrand factor binding to platelet glycoprotein Ib.

Type IIB von Willebrand disease is characterized by increased affinity of mutant von Willebrand factor (vWF) for platelet glycoprotein Ib. Eight different missense mutations that cause this phenotype have been reported within the disulfide loop defined by Cys-509 and Cys-695 of the mature vWF subunit; this disulfide loop is required for normal binding of vWF to platelet glycoprotein Ib. A new mutation was identified in a patient with type IIB von Willebrand disease (vWD) characterized by a lifelong bleeding disorder, mild thrombocytopenia, normal levels of factor VIII, vWF antigen, and ristocetin cofactor activity but increased ristocetin-induced platelet agglutination at low concentrations of ristocetin. Exon 28 of the patient's vWF gene was amplified, cloned, and sequenced. At nucleotide 3802 (numbering the cDNA from translation initiation), a C to G transversion was identified, which changes the encoded amino acid sequence from His-505 to Asp. The corresponding mutant recombinant vWF was expressed in transiently transfected COS cells. Relative to wild type vWF, the mutant vWF exhibited markedly increased binding to platelets at low concentrations of ristocetin, confirming the association between the His-505-->Asp substitution and the type IIB vWD phenotype. The His-505-->Asp mutation lies outside the disulfide loop affected by other type IIB vWD mutations and implicates a new segment of vWF in the regulation of platelet glycoprotein Ib binding.

Recombinant von Willebrand factor Arg578-->Gln. A type IIB von Willebrand disease mutation affects binding to glycoprotein Ib but not to collagen or heparin.

von Willebrand factor (vWF) is a multimeric plasma glycoprotein that mediates platelet adhesion to the subendothelium via binding to platelet glycoprotein Ib (GPIb) and to components of the vessel wall. Recently, missense mutations that cause type IIB von Willebrand disease (vWD) were described, clustered within a disulfide loop in the A1 domain of vWF that has binding sites for GPIb, collagen, and heparin. In type IIB vWD, plasma vWF exhibits increased affinity for platelet GPIb, but decreased binding to collagen and heparin. The effect was studied of a type IIB vWD mutation, Arg578-->Gln, on the interaction of vWF with GPIb, collagen, and heparin. Recombinant wild type rvWF and mutant rvWF(R578Q) were expressed in COS-7 cells. Ristocetin-induced binding of rvWF(R578Q) to GPIb was markedly increased compared with rvWF, confirming that the Arg578-->Gln mutation causes the characteristic gain-of-function abnormality of type IIB vWD; botrocetin-induced binding was only slightly increased. Binding to collagen type III and heparin-agarose was compared for rvWF(R578Q) and plasma vWF from patients with four different type IIB mutations: Arg543-->Trp, Arg545-->Cys, Val553-->Met, Arg578-->Gln. For all of the plasma samples, binding to collagen and to heparin was reduced compared with normal plasma. In contrast, binding of rvWF(R578Q) to collagen and heparin was normal compared with wild type rvWF. Therefore, the Arg578-->Gln mutation increases the affinity of vWF for GPIb but does not directly impair vWF interaction with collagen or heparin. Arg578 may therefore be necessary to prevent normal vWF from interacting with GPIb. In type IIB vWD, the defective binding of plasma vWF to collagen and heparin may be secondary to post-synthetic modifications that occur in vivo, such as the loss of high molecular weight vWF multimers.

von Willebrand disease type B: a missense mutation selectively abolishes ristocetin-induced von Willebrand factor binding to platelet glycoprotein Ib.

von Willebrand factor (vWF) is a multimeric glycoprotein that mediates the adhesion of platelets to the subendothelium by binding to platelet glycoprotein Ib. For human vWF, this interaction can be induced in vitro by the antibiotic ristocetin or the snake venom protein botrocetin. A missense mutation, Gly-561-->Ser, was identified within the proposed glycoprotein Ib binding domain of vWF in the proband with von Willebrand disease type B, a unique variant characterized by no ristocetin-induced, but normal botrocetin-induced, binding to glycoprotein Ib. The corresponding mutant recombinant protein, rvWF(G561S), formed normal multimers and exhibited the same functional defect as the patient's plasma vWF, confirming that this mutation causes von Willebrand disease type B. These data show that botrocetin and ristocetin cofactor activities of vWF can be dissociated by a point mutation and confirm that these mediators promote vWF binding to platelets by different mechanisms. The normal botrocetin-induced binding and the defective ristocetin-induced binding of rvWF(G561S) suggest that the primary defect in von Willebrand disease type B may be a failure of normal allosteric regulation of the glycoprotein Ib binding function of vWF.

The mutation Arg (53)----Trp causes von Willebrand disease Normandy by abolishing binding to factor VIII. Studies with recombinant von Willebrand factor.

von Willebrand factor (vWF) and factor VIII (FVIII) circulate in plasma as a noncovalently linked protein complex. The FVIII/vWF interaction is required for the stabilization of procoagulant FVIII activity. Recently, we reported a new variant of von Willebrand disease (vWD) tentatively named "Normandy," characterized by plasma vWF that appears to be structurally and functionally normal except that it does not bind FVIII. Three patients from one family were found to be homozygous for a C----T transition at codon 816 converting Arg 53 to Trp in the mature vWF subunit. To firmly establish a causal relationship between this missense mutation and vWD Normandy phenotype, we have characterized the corresponding recombinant mutant vWF(R53W). Expressed in COS-7 cells or CHO cell lines, normal vWF and vWF(R53W) were processed and formed multimers with equal efficiency. However, vWF(R53W) exhibited the same defect in FVIII binding as did plasma vWF from patients with vWD Normandy, confirming that this mutation is responsible for the vWD Normandy phenotype. These results illustrate the importance of Arg 53 of the mature vWF subunit for the binding of FVIII to vWF, and identify an amino acid residue within a disulfide loop not previously known to be involved in this interaction.

Expression of von Willebrand factor "Normandy": an autosomal mutation that mimics hemophilia A.

von Willebrand disease Normandy (vWD Normandy) is a recently described phenotype in which a mutant von Willebrand factor (vWF) appears structurally and functionally normal except that it does not bind to blood coagulation factor VIII. This interaction is required for normal survival of factor VIII in the circulation; consequently, vWD Normandy can present as apparent hemophilia A but with autosomal recessive rather than X chromosome-linked inheritance. A vWF missense mutation, Thr28----Met, was identified in the propositus in or near the factor VIII binding site. The corresponding mutant recombinant vWF(T28M) formed normal multimers and had normal ristocetin cofactor activity. However, vWF(T28M) exhibited the same defect in factor VIII binding as natural vWF Normandy, confirming that this mutation causes the vWD Normandy phenotype. The distinction between hemophilia A and vWD Normandy is clinically important and should be considered in families affected by apparent mild hemophilia A that fail to show strict X chromosome-linked inheritance and, particularly, in potential female carriers with low factor VIII levels attributed to extreme lyonization.

Human von Willebrand factor gene and pseudogene: structural analysis and differentiation by polymerase chain reaction.

Structural analysis of the von Willebrand factor gene located on chromosome 12 is complicated by the presence of a partial unprocessed pseudogene on chromosome 22q11-13. The structures of the von Willebrand factor pseudogene and corresponding segment of the gene were determined, and methods were developed for the rapid differentiation of von Willebrand factor gene and pseudogene sequences. The pseudogene is 21-29 kilobases in length and corresponds to 12 exons (exons 23-34) of the von Willebrand factor gene. Approximately 21 kilobases of the gene and pseudogene were sequenced, including the 5' boundary of the pseudogene. The 3' boundary of the pseudogene lies within an 8-kb region corresponding to intron 34 of the gene. The presence of splice site and nonsense mutations suggests that the pseudogene cannot yield functional transcripts. The pseudogene has diverged approximately 3.1% in nucleotide sequence from the gene. This suggests a recent evolutionary origin approximately 19-29 million years ago, near the time of divergence of humans and apes from monkeys. Several repetitive sequences were identified, including 4 Alu, one Line-1, and several short simple sequence repeats. Several of these simple repeats differ in length between the gene and pseudogene and provide useful markers for distinguishing these loci. Sequence differences between the gene and pseudogene were exploited to design oligonucleotide primers for use in the polymerase chain reaction to selectivity amplify sequences corresponding to exons 23-34 from either the von Willebrand factor gene or the pseudogene. This method is useful for the analysis of gene defects in patients with von Willebrand disease, without interference from homologous sequences in the pseudogene.

Severe type III von Willebrand's disease caused by deletion of exon 42 of the von Willebrand factor gene: family studies that identify carriers of the condition and a compound heterozygous individual.

Southern blotting was performed with cDNA probes for the human von Willebrand factor (vWF) gene on six patients with severe type III von Willebrand's disease (vWD). A partial deletion in the 3' end of the vWF gene was demonstrated in one individual whose parents were related and who had an alloantibody inhibitor to vWF. A resulting novel 2.0-kilobase (kb) EcoRI fragment was used for carrier detection within the patient's family, and seven carriers of this recessive trait were identified. Of the six tested, five had normal or only slightly reduced levels of vWF antigen, but with generally higher levels of factor VIII. The sixth carrier had moderately severe vWD and it is proposed that this patient is heterozygous for the defective vWF gene and a second recessive vWF defect. The novel 2.0-kb EcoRI restriction fragment was cloned and sequenced, and compared with that of the corresponding normal 4.2-kb EcoRI fragment that includes exons 41 and 42 of the vWF gene. A deletion of 2,320 base pairs (bp) which included exon 42, was identified and a novel 182-bp insert was found between the breakpoints. This insert was detected by polymerase chain reaction amplification both in the patient's DNA and in his carrier relatives.

Structure of the gene for human von Willebrand factor.

von Willebrand factor is a large multimeric plasma protein composed of identical subunits which contain four types of repeated domains. von Willebrand factor is essential for normal hemostasis, and deficiency of von Willebrand factor is the most common inherited bleeding disorder of man. Four human genomic DNA cosmid libraries and one bacteriophage lambda library were screened with von Willebrand factor cDNA probes. Twenty positive overlapping clones were characterized that span the entire von Willebrand factor gene. A high-resolution restriction map was constructed for approximately 75% of the locus and a total of approximately 33.8 kilobases was sequenced on both strands including all intron-exon boundaries. The gene is approximately 178 kilobases in length and contains 52 exons. The exons vary from 40 to 1379 base pairs in length, and the introns vary from 97 base pairs to approximately 19.9 kilobases in length. The signal peptide and propeptide (von Willebrand antigen II) of von Willebrand factor are encoded by 17 exons in approximately 80 kilobases of DNA while the mature subunit of von Willebrand factor and 3' noncoding region are encoded by 35 exons in the remaining approximately 100 kilobases of the gene. A number of repetitive sequences were identified including 14 Alu repeats and a approximately 670-base pair TCTA simple repeat in intron 40 that is polymorphic. Regions of the gene that encode homologous domains have similar structures, supporting a model for their origin by gene segment duplication.