An optimized fluorogenic ADAMTS13 assay with increased sensitivity for the investigation of patients with thrombotic thrombocytopenic purpura.

BACKGROUND: Most ADAMTS13 assays use non-physiological conditions (low ionic strength, low pH, barium chloride), are subject to interference from plasma proteins, hemoglobin and bilirubin, and have limited sensitivity, especially for inhibitors. OBJECTIVES: We addressed these constraints by designing a substrate that can be used in undiluted plasma. METHODS: A polypeptide was expressed in E. coli that corresponds to von Willebrand factor Gln(1599) -Arg(1668) , with mutations N1610C and K1617R and an N-terminal Gly. Substrate FRETS-rVWF71 was prepared by modifying Cys(1610) with DyLight 633 (abs 638 nm, em 658 nm) and the N-terminus with IRDye QC-1 (abs 500-800 nm). Assays were performed at pH 7.4 in 150 mm NaCl, 10 mm CaCl2 . RESULTS: Serum and plasma anticoagulated with citrate or heparin had equivalent ADAMTS13 activity with FRETS-rVWF71. Neither bilirubin (≤ 20 mg dL(-1) ) nor hemoglobin (≤ 20 g L(-1) ) interfered with product detection. Assays with FRETS-rVWF71 and FRETS-VWF73 gave similar results (R(2 ) = 0.95) for plasma from 80 subjects with thrombotic microangiopathy, 22 subjects with other causes of thrombocytopenia, and 20 healthy controls. The limit of detection with FRETS-rVWF71 for ADAMTS13 activity was ≤ 0.3%. Inhibitor assays with FRETS-rVWF71 gave titers ~2.5-fold higher than with FRETS-VWF73 and clearly distinguished patients with and without inhibitors. CONCLUSIONS: FRETS-rVWF71 is suitable for ADAMTS13 assays in minimally diluted plasma or serum without interference from proteins, bilirubin or free hemoglobin in plasma. Optimized detection of ADAMTS13 inhibitors will facilitate the monitoring of antibody responses during the treatment of thrombotic thrombocytopenic purpura.

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.

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.

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.