Multi‐step binding of ADAMTS‐13 to von Willebrand factor

Summary. Background: ADAMTS‐13 proteolytic activity is controlled by the conformation of its substrate, von Willebrand factor (VWF), and changes in the secondary structure of VWF are essential for efficient cleavage. Substrate recognition is mediated through several non‐catalytic domains in ADAMTS‐13 distant from the active site. Objectives: We hypothesized that not all binding sites for ADAMTS‐13 in VWF are cryptic and analyzed binding of native VWF to ADAMTS‐13. Methods: Immunoprecipiation of VWF–ADAMTS‐13 complexes using anti‐VWF antibodies and magnetic beads was used. Binding was assessed by Western blotting and immunosorbent assays. Results: Co‐immunoprecipitation demonstrated that ADAMTS‐13 binds to native multimeric VWF (K_d of 79 ± 11 nmol L^?1) with no measurable proteolysis. Upon shear‐induced unfolding of VWF, binding increased 3‐fold and VWF was cleaved. Binding to native VWF was saturable, time dependent, reversible and did not vary with ionic strength (I of 50–200). Moreover, results with ADAMTS‐13 deletion mutants indicated that binding to native VWF is mediated through domains distal to the ADAMTS‐13 spacer, probably thrombospondin‐1 repeats. Interestingly, this interaction occurs in normal human plasma with an ADAMTS‐13 to VWF stoichiometry of 0.0040 ± 0.0004 (mean ± SEM, n = 10). Conclusions: ADAMTS‐13 binds to circulating VWF and may therefore be incorporated into a platelet‐rich thrombus, where it can immediately cleave VWF that is unfolded by fluid shear stress.     

Disulfide bond reduction of von Willebrand factor by ADAMTS‐13

See also Lenting PJ, Rastegarlari G. ADAMTS‐13: double trouble for von Willebrand factor. This issue, pp 2775–7. Summary. Background: von Willebrand factor (VWF) released from endothelial cells is rich in ultra‐large (UL) multimers that are intrinsically active in binding platelets, whereas plasma‐type VWF multimers require shear stress to be activated. This functional difference may be attributed to thiols exposed on the surface of plasma‐type VWF multimers, but not on ULVWF multimers. Shear stress induces the exposed thiols to form disulfide bonds between laterally apposed plasma‐type VWF multimers, leading to enhanced VWF binding to platelets. Objectives: We tested a hypothesis that ADAMTS‐13 has a disulfide bond reducing activity that regulates shear‐induced thiol‐disulfide exchange of VWF. Methods: Thiol blocking agents and active thiol bead capturing were used to identify and locate this activity, along with truncated ADAMTS‐13 mutants. Results: ADAMTS‐13 contains a disulfide bond reducing activity that primarily targets disulfide bonds in plasma‐type VWF multimers induced by high shear stress or formed with thiol beads, but not disulfide bonds in native multimeric structures. Cysteine thiols targeted by this activity are in the VWF C‐domain and are known to participate in shear‐induced thiol‐disulfide exchange. ADAMTS‐13 contains cysteine thiols that remain exposed after being subjected to hydrodynamic forces. Blocking these active thiols eliminates this reducing activity and moderately decreases ADAMTS‐13 activity in cleaving ULVWF strings anchored to endothelial cells under flow conditions, but not under static conditions. This activity is located in this C‐terminal region of ADAMTS‐13. Conclusions: This novel disulfide‐bond‐reducing activity of ADAMTS‐13 may prevent covalent lateral association and increased platelet adherence of plasma‐type VWF multimers induced by high fluid shear stress.     

The role of ADAMTS‐13 in the coagulopathy of sepsis

Summary

The interaction between platelets and the vessel wall is mediated by various receptors and adhesive proteins, of which von Willebrand factor (VWF) is the most prominent. The multimeric size of VWF is an important determinant of a more intense platelet–vessel wall interaction, and is regulated by the VWF‐cleaving protease ADAMTS‐13. A deficiency in ADAMTS‐13 leads to higher concentrations of ultralarge VWF multimers and pathological platelet–vessel wall interactions, in its most typical and extreme form leading to thrombocytopenic thrombotic purpura, a thrombotic microangiopathy characterized by thrombocytopenia, non‐immune hemolysis, and organ dysfunction. Thrombotic microangiopathy associated with low levels of ADAMTS‐13 may be a component of the coagulopathy observed in patients with sepsis. Here, we review the potential role of ADAMTS‐13 deficiency and ultralarge VWF multimers in sepsis, and their relationship with sepsis severity and prognosis. In addition, we discuss the possible benefit of restoring ADAMTS‐13 levels or reducing the effect of ultralarge VWF as an adjunctive treatment in patients with sepsis.

     

Platelet reactive conformation and multimeric pattern of von Willebrand factor in acquired thrombotic thrombocytopenic purpura during acute disease and remission

Summary. Background: Binding of von Willebrand factor (VWF) multimers of ultra‐large size to platelets is considered the triggering mechanism of microvascular thrombosis in thrombotic thrombocytopenic purpura (TTP). Objective: To assess the potential of VWF‐related measurements as markers of disease activity and severity in TTP. Methods: VWF antigen (VWF:Ag), platelet glycoprotein‐Ib‐α binding‐conformation (GPIb‐α/BC) and multimeric pattern were investigated in 74 patients with acquired TTP during acute disease, remission or both and 73 healthy controls. In patients with both acute and remission samples available, VWF ristocetin co‐factor activity (VWF:RCo) and collagen binding (VWF:CB) were also measured. The relationships of study measurements with the presence of acute disease and remission and with markers of disease severity were assessed. Results: VWF:Ag and VWF‐GPIb‐α/BC were higher in TTP patients than controls (P < 0.001 and 0.004). However, there was no statistically significant difference in VWF‐GPIb‐α/BC between samples obtained during acute TTP and remission. Larger VWF multimers were frequently lacking in acute TTP patients, who displayed ultra‐large multimers at remission. The degree of loss of larger VWF multimers correlated with the degree of abnormality of hemoglobin, platelet counts and serum lactate dehydrogenase (LDH) and was associated with low levels of both VWF:RCo/Ag and VWF:CB/Ag ratios. Conclusions: In TTP the platelet‐binding conformation of VWF is not exclusively present in acute disease, nor is it associated with its clinical and laboratory severity. The loss of larger VWF multimers, accompanied by low VWF:RCo/Ag and VWF:CB/Ag ratio values, represents an index of disease activity and severity of acute TTP in patients with severe ADAMTS‐13 deficiency.     

血管性血友病因子vWF73和vWF114片段的表达及其在ADAMTS13活性测定中的应用

目的 构建血管性血友病因子(vWF)A2区片段vWF73和vWF114的表达质粒,在大肠杆菌中表达两种谷胱甘肽S转移酶(GST)融合蛋白,并探讨两种蛋白作为底物在测定ADAMTS13活性中的应用价值.方法 应用PCR的方法扩增vWF A2区内vWF73和vWF114的相应DNA片段,分别克隆至GST融合表达载体pGEX-6P-1进行诱导表达,Ni-NTA琼脂糖柱纯化可溶性蛋白部分.以Western blot法榆测正常人血浆、血栓性血小板减少性紫癜(TTP)患者血浆和重组ADAMTS13(rADAMTS13)水解两种重组vWF A2区片段的情况,并以此为底物用抗GST和抗His两种抗体建立酶联免疫吸附试验(ELISA)法测定血浆ADAMqS13活性的新方法.结果 成功表达和纯化了ADAMTS13的两种可溶性小分子底物GST-vWF73-H和GST-vWF114-H,均能被rADAMTS13或正常人血浆有效地水解,而遗传性和特发性TTP患者血浆则无此作用.同时,以此为底物建立了测定ADAMTS13活性的ELISA方法.结论 采用原核表达系统成功得到了vWF A2区片段vWF73和vWF114两种GST融合蛋白,可作为底物用于ADAMTS13活性的测定.

Abstract：

Objective To construct the expression vectors of vWF73 and vWF114 fragments of von Willebrand factor (vWF) A2 domain, and to express glutathione S-transferase (GST) fusion proteins in E.coli, and to explore their values in measuring ADAMTS13 activity as substrates. Methods The DNA fragments encoding vWF73 and vWF114 were generated using PCR and separately cloned into pGEX-6P-1 , a Schistosoma japonicum GST fusion expression vector. The expression of GST-vWF73-H and GST-vWF114-H was induced in liquid culture, followed by purification with Ni-NTA agarose column. The cleavage of two GST fusion proteins by recombinant ADAMTS13 ( rADAMTS13) or plasma from normal individuals and thrombotic thrombocytopenic purpura (TTP) patients were identified by Western blot. Based on an enzyme-linked immunosorbent assay ( ELISA) with anti-GST and anti-His monoclonal antibodies, GST-vWF73-H and GSTvWF114-H were used to measure plasma ADAMTS13 activity as substrates. Results Two small molecular substrates of ADAMTS13, GST-vWF73-H and GST-vWF114-H, are expressed and purified,which could be specifically cleaved by rADAMTS13 or plasma from healthy individuals, but not by plasma from congenital or idiopathic TTP patients. An ELISA assay was established to detect plasma ADAMTS13 activity using GSTvWF73-H and GST-vWF114-H as substrates. Conclusions Two GST fusion proteins in vWF A2 domain,vWF73 and vWF114, were expressed effectively using a prokaryotic expression system and could be used to detect ADAMTS13 activity as substrates.     

Measurement of von Willebrand factor cleaving protease (ADAMTS-13): results of an international collaborative study involving 11 methods testing the same set of coded plasmas

BACKGROUND: ADAMTS-13 is a von Willebrand factor (VFW)-cleaving protease. Its congenital or acquired deficiency is associated with thrombotic thrombocytopenic purpura (TTP) and more rarely with the hemolytic uremic syndrome. We report on a survey evaluating 11 methods for ADAMTS-13 measurement performed in different labs. DESIGN: Two plasmas, one normal and one from a patient with familial TTP, were mixed at the co-ordinating center to prepare 6 plasmas with 0%, 10%, 20%, 40%, 80% and 100% ADAMTS-13 levels. Each plasma was aliquoted and assembled into sets of 60 (coded from 1 to 60), each containing 10 copies of the original 6 plasmas. Plasmas were frozen and shipped in dry ice to 10 labs with a common frozen reference plasma. Laboratories were asked to measure ADAMTS-13 with their methods. Results were sent to the coordinating center for statistical analysis. RESULTS: Of the 10 methods performed under static conditions 9 were quantitative and one was semiquantitative. One method performed under flow conditions evaluated the extent of cleavage of endothelial cell-derived ultralarge VWF string-like structures and expressed results as deficient, normal, or borderline. Linearity (expected-vs-observed levels), assessed as the squared correlation coefficient, ranged from 0.98 to 0.39. Reproducibility, expressed as the coefficient of variation for repeated measurements, ranged from < 10% to 83%. The majority of methods were able to discriminate between different ADAMTS-13 levels. The majority were able to detect the plasma with 0% level and some of them to discriminate between 0% and 10%. Overall the best performance was observed for three methods measuring cleaved VWF by ristocetin cofactor, collagen binding, and immunoblotting of degraded multimers of VWF substrate, respectively. The poor interlaboratory agreement of results was hardly affected by the use of the common standard. The method performed under flow conditions identified the plasmas with 0%, 10%, 20% and 40% activity as deficient in 7, 5, 1 and 3 of the 10 replicate measurements. The plasmas with 80% and 100% were identified as normal in all of the 10 replicate measurements. CONCLUSIONS: The survey shows varied performance, but supports an optimistic view about the reliability of current methods for ADAMTS-13.     

Variations among normal individuals in the cleavage of endothelial-derived ultra-large von Willebrand factor under flow.

von Willebrand factor (VWF) freshly released from endothelial cells is normally cleaved by the ADAMTS-13 metalloprotease to prevent the direct release of these ultra-large (UL) and hyper-reactive multimers into plasma. The balance of ULVWF proteolysis may be regulated by the amount of ULVWF released and the processing capacity of ADAMTS-13. The former associates with the size of ULVWF storage pool, sensitivity of vascular endothelial cells to stimulation, and the type of agonists, whereas the latter associates with the activity of ADAMTS-13. These parameters may vary significantly among individuals. We have determined the variations of ADAMTS-13 activity in 68 normal individuals by a flow-based assay and a static assay using ULVWF strings and recombinant VWF A2 domain as substrates, respectively. We found that the levels of ADAMTS-13 activity required to cleave the platelet-decorated ULVWF strings under flow is significantly higher than that of static assays. Normal plasma diluted to 25% significantly reduced its ability to cleave ULVWF strings under flow, whereas 2% plasma retained 48% enzyme activity in static assay. ADAMTS-13 activity varied from 33 to 100% among individuals and the variations were greater at shorter incubations of plasma with the substrate. Furthermore, the production of ULVWF from endothelial cells also varied among individuals. These results suggest that the commonly used static assays may underestimate the ADAMTS-13 activity required to cleave newly released ULVWF. They also demonstrated that the proteolysis of ULVWF may vary significantly among individuals, potentially contributing to the individual's vulnerability to thrombosis so that measurement of ADAMTS-13 may serve as a marker for TTP and other thrombotic diseases.     

Cleavage of ultra-large von Willebrand factor by ADAMTS-13 under flow conditions

von Willebrand factor (VWF) is a critical ligand for platelet adhesion and aggregation. It is synthesized and released as multimers composed of various numbers of monomers. When first released from the storage granules of endothelial cells, VWF multimers are rich in the ultra-large (UL) forms that spontaneously bind the GP Ib-IX complex and aggregate platelets. These prothrombotic ULVWF multimers are rapidly cleaved by the metalloprotease ADAMTS-13 (A Disintegrin and Metalloprotease with ThromboSpondin motif) to smaller and much less active forms. Recently, several methods have been developed to measure ADAMTS-13 activity in vitro and to link its deficiency to thrombotic thrombocytopenic purpura. Correlations between the structure and functions of the metalloprotease have also been extensively studied using recombinant technologies. However, questions remain regarding the proper substrate for the metalloprotease, the time and location of ULVWF proteolysis, and the role of fluid shear stress. In this brief review, we have discussed a potential model for ULVWF proteolysis by ADAMTS-13 in vivo. In this model, ULVWF is anchored to the surface of endothelial cells to form string-like structures under fluid shear stress. Such an elongated conformation facilitates ULVWF cleavage by exposing either the cleavage or binding sites for the metalloprotease. When ADAMTS-13 is deficient, the uncleaved ULVWF accumulates in plasma and on endothelial cells to capture platelets. This leads to platelet aggregation and thromboembolism. Dissecting the process of ULVWF proteolysis is important for not only understanding the pathophysiology of thrombotic microangiopathies, but also developing more effective means to treat these deadly diseases.