Platelet-type von Willebrand disease (PTvWD) is an autosomal dominant bleeding disorder characterized by abnormally enhanced binding of von Willebrand factor (vWF) by patient platelets. Although the platelet glycoprotein (GP) Ib/IX complex is known to constitute the platelet's ristocetia-dependent receptor for vWF, a unique structural abnormality within this complex has not previously been identified in PT-vWD. Using the polymerase chain reaction to amplify genomic DNA coding for the a chain of GP lb (GP Ibta) and then sequencing the amplified DNA following cloning into M13mpl8 and M13mpl9 phage vectors, we have found a single point mutation in the GP Iba coding region of PT-vWD DNA resulting in the substitution of valine for glycine at residue 233. This substitution within the vWF-binding region of GP Iba is likely to exert a significant influence on the conformation of the resulting protein. Competitive oligonucleotide primer assay for this mutation showed a homozygous wild-type pattern in genomic DNA from the 161 normal volunteers studied and from 6 phenotypically normal members of a PT-vWD family. All 7 affected members of this family studied were heterozygous for the mutant allele. Platelet GP Iba mRNA reverse-transcribed and studied by competitive oligonucleotide primer assay showed similar expression of the mutant and wild-tpe alleles in the affected PT-vWD patients. Absence in the normal population, tight linkage with phenotypic expression of disease, and absence of any additional abnormality of GP Iba in these patients identify the glycine-to-valine substitution as a point mutation underlying functional abnormality of the vWF receptor in PT-vWD.Platelet-type von Willebrand disease (PT-vWD) is an autosomal dominant bleeding disorder in which patients characteristically show prolonged bleeding times, borderline thrombocytopenia, and decreased von Willebrand factor (vWF) high molecular weight multimers and functional activity (1-5). PT-vWD appears to result from an abnormality of the platelet receptor for vWF, whereby patient platelets show an abnormally increased binding of circulating vWF. In the laboratory, this platelet hyperresponsiveness may be demonstrated with the use of low concentrations of ristocetin. Whereas normal platelets show little or no aggregation at ristocetin concentrations as low as 0.5 mg/ml, patient platelets typically show significant binding of vWF, together with strong aggregation, following stimulation by 0.5 mg/ml, or even lower, concentrations of ristocetin (1-3). The unique ability of desialylated vWF (asialo-vWF) to agglutinate patient platelets in the presence of the divalent-cation chelator EDTA has additionally been demonstrated (6). Platelets from patients with PT-vWD also show a characteristically increased binding of the monoclonal antibody C-34, which is directed against an epitope within the platelet glycoprotein (GP) lb/IX complex (7). Although this complex is known to constitute the platelet's ristocetin-dependent receptor for vWF (8), identification of a u...
The primary sequences of the three individual glycoprotein (GP) chains, GPIb alpha, GPIb beta, and GPIX, comprising the normal platelet GPIb/IX receptor for von Willebrand factor (vWF) have recently been determined, opening the possibility for characterization of disorders of this receptor at the molecular level. The presence of a leucine tandem repeat in each of these chains is of particular interest, because such repeats may be involved in associations between polypeptide segments. We now report an autosomal dominant variant of Bernard-Soulier disease associated with the heterozygous substitution of phenylalanine for a highly conserved leucine residue within the GPIb alpha leucine tandem repeat. Affected individuals experienced a moderate bleeding tendency, thrombocytopenia, and an increased mean platelet volume. Platelet aggregation was decreased only in response to ristocetin or to asialo- vWF. The kd for 125I-vWF binding to patients platelets was significantly increased over control values at 0.5 mg/mL ristocetin, but was normal at 1.0 or 1.5 mg/mL ristocetin. While sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed an essentially normal complement of all components of the GPIb/IX complex, a minor amount of a putative proteolytic fragment was identified that migrated faster than GPIb and was immunoreactive with polyclonal anti-GPIb alpha antibody, but not with a monoclonal antibody directed against the 45-Kd amino-terminal region of GPIb alpha. However, because the great majority of patient GPIb alpha comigrates with normal GPIb alpha, the major functional abnormalities of the patient platelets are most likely a consequence of the altered structure of the nonproteolyzed protein. Full concordance within the studied family between phenotypic expression and a heterozygous single nucleotide substitution in genomic DNA coding for a phenylalanine in place of the wild-type leucine at residue 57 of the mature GPIb alpha, absence of this substitution in 266 alleles from the normal population, and the lack of any other abnormality of patient DNA throughout the entire coding sequence for GPIb alpha provide strong support that this substitution may constitute a pathologic point mutation responsible for the observed phenotypic abnormalities. While the roles that leucine tandem repeats may normally play within the GPIb/IX complex are not yet known, the perturbation of such a repeat in GPIb alpha may impair interaction with other components of the complex and/or with the binding of vWF.
Platelets from patients with platelet-type von Willebrand disease (vWD) were used as immunogens for the production of murine monoclonal antibodies (MoAbs). One such MoAb, C-34, inhibited ristocetin-induced aggregation of patient or normal platelets, but not aggregation induced by other aggregating agents. As demonstrated by crossed-immunoelectrophoresis, C-34 recognized an epitope within the GPIb/IX complex. In indirect immunofluorescence studies on fresh platelets, the ratio of any of four different anti-GPIb MoAbs to one another was near unity (0.88-1.14) both for normals and for patients. In contrast, the ratio of the binding of C-34 to such a MoAb (AP-1) was 0.31 +/- 0.02 (means +/- SE) for normal platelets and significantly increased to 0.54 +/- 0.01 for patient platelets (P less than 0.001). In NP-40 lysates of 3H-labelled platelets, saturating concentrations of C-34 produced much fainter bands than did AS-2 or other anti-GPIb MoAbs in the GPIb and GPIX regions. In contrast to the other anti-GPIb MoAbs, C-34 did not bind to the purified 125I-labelled glycocalicin fragment of GPIb, to the glycocalicin derivative identified by crossed-immunoelectrophoresis, or to the amino-terminal approximately 40 kDa portion of GPIb alpha cleaved from 3H-labelled platelets by trypsin. C-34 appears to be the first MoAb that is quantitatively informative in identifying the abnormal platelets in platelet-type vWD. The observed differences between the patient and normal platelets may reflect an abnormality in the primary structure of the GPIb/IX complex. Alternatively, patient platelets may have an abnormality of other structures near this region that impose less of a steric hindrance upon binding of antibody to the C-34 epitope.
A bacteriophage library displaying random decapeptides was used to characterize the binding preference of C-34, a monoclonal antibody originally raised against platelet-type von Willebrand disease platelets heterozygous for the mutation 230WKQ(G -> V)233V234 in the a chain of glycoprotein lb (GPIba). Three rounds of biopanning C-34 against the library resulted in striking convergence upon the sequence WNWRYREYV. Since no portion of this sequence corresponds to a recognizable peptide sequence within human platelet GPIba, it may be considered a "mimotope" of the naturally occurring C-34 epitope, presumably bearing similarity to it in three-dimensional structure. Synthetic AWNWRYREYV peptide preincubated with C-34 fully neutralized the ability of C-34 to inhibit platelet aggregation, with an ICso0 of -6 ,ug/ml. When biotinylated AWNWRYREYV was subsequently biopanned against the original decapeptide library, the sole clone demonstrating inhibitory activity above background level in a functional platelet assay displayed the sequence RHVAWWRQGV, and chemically synthesized peptide fully inhibited ristocetin-induced aggregation, with an IC50 of 200-400 tig/ml. Synthesized RHVAWWKQGV peptide exerted only slight inhibition, whereas RHVAWWKQYV peptide showed potent inhibitory activity. Moreover, whereas synthesized wild-type 228YVWKQGVDVK237 GPIba peptide was virtually without inhibitory activity, the 228YVWKQ(G ->
The underlying molecular basis for Bernard-Soulier Disease (BSD) is currently unknown. Platelets from patients with this autosomal recessive bleeding disorder have multiple abnormalities, including a markedly reduced von Willebrand factor-dependent adhesiveness due to a deficiency of the platelet membrane glycoprotein (GP) Ib/IX complex. In the present studies, we have used an intragenic restriction fragment length polymorphism (RFLP) for Taq I in the GPIb alpha gene to study linkage between this gene and the inheritance of BSD in a family with two affected siblings. Whereas the proband was heterozygous, showing both the 0.7 and 4.0 kb bands of this polymorphism (A/B), her affected brother was homozygous for the 0.7 kb band (A/A). Accordingly, these siblings did not inherit the same pair of GPIb alpha alleles from their parents. Additionally, one child of the proband was A/A, while the second studied child was A/B, with neither showing any evidence of BSD. No construct of heterozygosity or homozygosity for GPIb alpha alleles in this family is consistent with a model in which one or more defective GPIb alpha alleles could produce BSD. RFLP analysis with BamHI or HindIII showed entirely normal patterns in the patients, indicating the absence of any gross deletion of the GPIb alpha gene. GPIb alpha mRNA from patient platelets was reverse transcribed and subsequently amplified by the polymerase chain reaction, demonstrating the presence of GPIb alpha transcript. Furthermore, trace amounts of GPIb could be shown on the surface of patient platelets. Based on these results, a defect in the GPIb alpha gene is unlikely to be the cause of BSD in this family.
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