Hemostatic effect of normal platelet transfusion in severe von Willebrand disease patients

Platelet von Willebrand factor (vWF) has been suggested to play an important role in the hemostatic process. Clinical and experimental data indicate that bleeding time (BT) and platelet-vessel wall interaction cannot be normalized unless the defect of platelet vWF is also corrected. We have examined the effect of normal platelet concentrate transfusion 1 hour after cryoprecipitate infusion in five type III von Willebrand disease (vWD) patients. The cryoprecipitate infusion attained normal circulating levels of ristocetin cofactor, vWF antigen, and factor VIII activity. In two patients, cryoprecipitate infusion did not modify the BT (greater than 30 minutes), whereas in the remaining three patients BT was only partially corrected (from greater than 30 to 12, 18, and 21 minutes). However, the immediate platelet transfusion completely corrected the BT in four cases, and in one case it shortened the BT to 8.30 minutes (n = 3 to 8 minutes). In the perfusion study, cryoprecipitate infusion only resulted in a slight increase in platelet deposition (surface coverage range: 2.4% to 11.3%), whereas the platelet concentrate transfusion elicited a more marked improvement (range: 8.2% to 26.4%; P less than .02 v post-cryoprecipitate). These results suggest an important in vivo role of the platelet vWF in supporting platelet-vessel wall interaction. They also give support to the occasional addition of normal platelet transfusion to the cryoprecipitate infusion for the control of serious bleeding episodes resistant to cryoprecipitate in severe vWD patients.     

Analysis of platelet von Willebrand factor antigen

Platelet lysates were obtained from suspensions of normal washed platelets by freeze-thawing or Triton X-100 lysis. The resultant platelet lysates contained 0.34 +/- 0.15 U/10(9) platelets (n = 8) of von Willebrand factor antigen (vWf:Ag) as determined by radioelectroimmunoassay using a monospecific antibody to vWf:Ag. The vWf:Ag level was higher in platelet lysates prepared from freshly drawn blood than from outdated platelet packs. Platelet lysates from patients with severe von Willebrand's disease type I (n = 2) did not contain detectable vWf:Ag. When normal platelet lysates were analyzed by radiocrossed immunoelectrophoresis in agarose using a monospecific polyclonal antibody to plasma vWf:Ag, two immunochemically identical precipitin peaks were seen. One of the platelet vWf:Ag peaks corresponded in its electrophoretic mobility to plasma vWf:Ag, while the other peak, i.e. platelet vWf:Ag-peak II, migrated to a more anodal position. The presence of the platelet vWf:Ag-peak II suggests structural differences between plasma and platelet vWf:Ag and illustrates previously unrecognized heterogeneity of platelet vWf:Ag.     

Shear-dependent tether formation during platelet translocation on von Willebrand factor.

The adhesion and aggregation of platelets at sites of vascular injury is dependent on the initial binding of the GP Ib/V/IX receptor complex to immobilized von Willebrand factor (VWF). Under flow conditions, this interaction supports platelet translocation that is characteristically stop-start in nature. High resolution imaging of platelets during surface translocation on immobilized VWF revealed that thin membrane tethers (length: 0.91 microm-47.90 microm) were pulled from the surface of these cells. Membrane tethers were dynamic structures that extended from small, localized adhesion contacts under the influence of flow. Perfusion of platelets in the presence of blocking antibodies against integrin alpha(IIb)beta(3), or over isolated A1 domains, demonstrated that the VWF-GP Ib interaction was sufficient to induce membrane tether formation. The rate and extent of tether elongation was shear-dependent (shear range: 150 s(-1)-10,000 s(-1)), with mean tether length ranging from 3.23 microm to 16.55 microm, tether frequency from 2.67% to 97.33%, and tether growth rate from 0.04 microm/sec to 8.39 microm/sec. Tether formation and retraction did not require platelet activation; however, the growth rate, lifetime, and dimensions were significantly affected by the actin polymerization inhibitor, cytochalasin D, and by chelating intracellular calcium. Single-cell analysis revealed that formation of membrane tethers regulates the stop-start phases of platelet translocation on VWF, suggesting a potentially important role for this phenomenon in regulating the dynamics of the platelet-VWF interaction under flow.     

Purification and characterization of human platelet von Willebrand factor

Summary. Platelet von Willebrand factor (vWf) was purified from human platelet concentrates. The multimeric structure of the purified platelet vWf was similar to that observed in the initial platelet lysate, and, like the platelet lysate, the purified platelet vWf contained higher molecular weight multimers than plasma vWf. The apparent molecular weight of the reduced platelet vWf subunit was similar to the plasma vWf subunit. The N-terminal amino acid of the purified platelet and plasma vWf was blocked. In concentration dependent binding to botrocetin- or ristocetin-stimulated platelets, ¹²⁵I-plasma vWf bound with a higher affinity than platelet. The ristocetin cofactor activity per mg of purified plasma vWf was 5-fold greater than the platelet vWf activity. Platelet and plasma vWf bound to collagen with similar affinities; however, platelet vWf bound to thrombin-stimulated platelets and to heparin with a higher affinity than plasma vWf. The differences in the binding affinity(s) of plasma and platelet vWf to platelet GPIb and GPIIb/IIIa and extracellular matrix proteins may reflect different roles for plasma and platelet vWf in the initial stages of haemostasis and thrombosis.     

Studies of multimerin in patients with von Willebrand disease and platelet von Willebrand factor deficiency

In normal platelet α-granules von Willebrand factor (VWF) is stored with multimerin and factor V in an eccentric electron-lucent zone. Because the platelet stores of VWF are deficient in 'platelet low' type 1 and type 3 von Willebrand disease (VWD), we investigated their electron-lucent zone proteins. The patients with VWD had partial to complete deficiencies of plasma and platelet VWF but normal α-granular multimerin and factor V, and normal α-granular fibrinogen, thrombospondin-1, fibronectin, osteonectin and P-selectin. In type 3 VWD platelets, α-granular electron-lucent zones lacking VWF-associated tubules were identified and multimerin was found in its normal α-granular location. These findings indicate that the formation of the electron-lucent zone and the sorting of multimerin to this region occur independent of VWF. The isolated abnormalities in VWF suggests a VWF gene mutation is the cause of 'platelet low' type 1 VWD.     

The role of von Willebrand factor in platelet function

von Willebrand factor (vWF) has essential functions in the very first stage of hemostasis. At the site of vascular damage vWF binds immediately to exposed collagens, thereby facilitating the adhesion of platelets. After a first layer of platelets has been formed, vWF is also crucial as a link between platelets in the forming thrombus. In this article, the current knowledge on the role of vWF in primary hemostasis is reviewed.     

Plasma and platelet von Willebrand factor defects in uremia

PURPOSE: Several mechanisms have been proposed to explain the prolonged bleeding times and clinical bleeding in chronic renal failure. Recent evidence has implicated an abnormality in the structure or function of the von Willebrand factor or in its interaction with uremic platelets. We investigated this factor in 11 patients with chronic renal failure. PATIENTS AND METHODS: Blood samples for cell counts, chemistries, and coagulation studies were obtained from 11 patients with chronic renal failure and prolonged bleeding times. Concentrations of von Willebrand factor antigen and ristocetin cofactor activity were determined in plasma and platelets. Multimeric analysis of von Willebrand factor in plasma and platelets was conducted. In eight cases, the platelets of uremic patients were purified, and the thrombin- and ristocetin-induced binding of normal von Willebrand factor to these platelets was examined. RESULTS: The mean plasma von Willebrand factor antigen and activity (ristocetin cofactor assay) were elevated 2.77 mu/ml and 1.88 mu/ml, respectively (normal, 1.01 mu/ml and 1.07 mu/ml, respectively). The ratio of activity to antigen in uremic plasma was 0.67 (normal, 1.05). The mean platelet von Willebrand factor antigen and activity in the uremic patients was decreased (0.26 and 0.50 mu/10(9) platelets, respectively) compared with normal patients (0.46 and 0.93 mu/10(9) platelets, respectively). The oligomeric structure of the uremic plasma von Willebrand factor lacked the largest multimers. Collection of the blood for analysis in several protease inhibitors and/or EDTA did not change the multimeric structure. The von Willebrand factor multimeric structure of platelets from uremic patients was normal. The ristocetin-induced platelet aggregation of the uremic platelet-rich plasma was decreased compared with normal plasma samples. Thrombin and ristocetin-induced binding of normal von Willebrand factor to uremic patients' platelets was indistinguishable from the binding to normal platelets. CONCLUSION: These data suggest that the uremic platelet-binding sites for von Willebrand factor are intact and that the defect in ristocetin-induced platelet aggregation is most likely plasmatic in nature. At least one plasmatic defect was the observed reduction or absence of the largest plasma von Willebrand factor multimer in uremic patients. The platelet von Willebrand content was significantly decreased. These defects may play a role in the prolonged bleeding time and the clinical bleeding observed in patients with uremia.     

Role for platelet von Willebrand factor in supporting platelet-vessel wall interactions in von Willebrand disease

Twelve infusions of plasma concentrates of von Willebrand factor (vWF) were given to four patients with severe (type III) von Willebrand disease (vWD). Their prolonged bleeding times were either completely or partially corrected after five infusions and had not changed after the remaining seven. In contrast, the low platelet coverage of the subendothelial surface of rabbit aorta perfused with normal washed platelets and red cells resuspended in preinfusion patient plasma was completely or partially corrected in ten instances by replacing preinfusion plasma with postinfusion plasma and remained unchanged in two. Postinfusion improvement in surface coverage was greater than that in bleeding time, suggesting that vWF from normal platelets is needed to support optimal platelet-vessel wall interactions in vWD. This possibility was further explored through other perfusion experiments. The subendothelial surface covered by platelets from an untreated patient with type III vWD (containing no measurable vWF) or from a type IIA vWD patient (containing dysfunctional vWF) resuspended in normal plasma was much smaller than that covered by normal platelets resuspended in normal plasma. These results establish that platelet vWF is important in supporting platelet-vessel wall interactions in vWD and also provide experimental support in favour of the therapeutic transfusion of normal platelets in addition to vWF concentrates to correct the bleeding time in vWD patients.     

von Willebrand factor mediates platelet adhesion to virally infected endothelial cells.

von Willebrand factor is an adhesive glycoprotein critical to normal hemostasis. It is stored in the Weibel-Palade body of endothelial cells and upon release may mediate platelet adhesion. Herpesvirus-infected endothelium is known to be prothrombotic and to support enhanced platelet adherence. We previously identified P-selectin as a monocyte receptor that is translocated from the Weibel-Palade body to the endothelial cell surface in response to the local generation of thrombin on herpesvirus infected cells. In this study, we show that viral injury to vascular endothelial cells induces secretion of von Willebrand factor which mediates enhanced platelet adhesion to these cells.     

Cleavage of human von Willebrand factor by platelet calcium-activated protease

In human platelet lysates prepared by addition of nonionic detergent (Triton X-100) or by sonication, the multimer composition and electrophoretic mobility of platelet von Willebrand factor (vWF) were consistently modified under conditions that would favor activation of the endogenous calcium-activated, sulfhydryl-dependent neutral protease (CAP). By sodium dodecylsulfate-agarose gel electrophoresis, native platelet vWF contained some multimers that were larger than those characteristic of plasma vWF. Modified platelet vWF contained a multimer population equivalent to or smaller than that of plasma vWF plus an additional fast-migrating band. In crossed immunoelectrophoresis (CIE), modified platelet vWF was characterized by a more anodic distribution and the appearance of a distinct, cross- reactive, anodic component previously designated VIIIR:Ag fragment. In the presence of calcium, radiolabeled purified plasma vWF was also degraded by the protease in question, with a decrease in the apparent molecular weight of the reduced monomer from 230,000 to 205,000. The VIIR:Ag fragment isolated from the same degraded plasma vWF by preparative CIE was shown to be composed of an identical mol wt 205,000 subunit. Because cleavage of plasma or platelet vWF was inhibited by prior addition of leupeptin, EDTA, ethylene glycol bis (beta-aminoethyl ether)-N, N, N', N'-tetraacetic acid (EGTA), or N-ethylmaleimide (agents known to inhibit platelet CAP) but was unaffected by numerous other protease inhibitors, including soybean trypsin inhibitor, benzamidine, hirudin, phenylmethylsulfonyl fluoride, aprotonin, or epsilon-aminocaproic acid (none of which inhibits platelet CAP), we conclude that proteolysis of vWF observed in this study is a direct effect of CAP and is not mediated by way of secondary proteases.     

Multimeric pattern discrepancy between platelet and plasma von Willebrand factor in type IIC von Willebrand disease

von Willebrand factor (vWF) from platelet lysate and plasma, collected in the presence of protease inhibitors, was studied in two patients with type IIC von Willebrand disease (vWD). Platelet and plasma vWF showed the smallest multimer increased, but the latter had a repeating single band whereas the former had a repeating "doublet." This platelet-plasma discrepancy observed for the first time in these patients suggests that the repeating "doublet" or single band described in other type IIC patients represent minor subgroups of type IIC vWD.     

Type 2 von Willebrand disease causing defective von Willebrand factor-dependent platelet function.

Type 2 von Willebrand disease causing defective von Willebrand factor-dependent platelet function comprises mainly subtypes 2A, 2B and 2M. The diagnosis of type 2 von Willebrand disease may be guided by the observation of a disproportionately low level of ristocetin cofactor activity or collagen-binding activity relative to the von Willebrand factor antigen level. The decreased platelet-dependent function is often associated with an absence of high molecular weight multimers (types 2A and 2B), but the high molecular weight multimers may also be present (type 2M and some type 2B), and supranormal multimers may exist (as in the Vicenza variant). Today, the identification of mutations in particular domains of the pre-provon Willebrand factor is helpful to classify these variants and to provide further insight into the structure-function relationship and the biosynthesis of von Willebrand factor. Thus, mutations in the D2 domain, involved in the multimerization process, are found in patients with type 2A, formerly named IIC von Willebrand disease. Mutations in the D3 domain characterize the Vicenza variant, or type IIE patients. Mutations in the A1 domain may modify the binding of von Willebrand factor multimers to platelets, either increasing (type 2B) or decreasing (types 2M and 2A/2M) the affinity of von Willebrand factor for platelets. In type 2A disease, molecular abnormalities identified in the A2 domain, which contains a specific proteolytic site, are associated with alterations in folding that impair the secretion of von Willebrand factor or increase its susceptibility to proteolysis. Finally, a mutation localized in the C terminus cysteine knot domain, which is crucial for the dimerization of von Willebrand factor subunit, has been identified in a rare subtype 2A, formerly named IID.     

Heterogeneous phenotypes of platelet and plasma von Willebrand factor in obligatory heterozygotes for severe von Willebrand disease

To characterize the heterogeneity of severe (type III) von Willebrand disease (vWD), plasma and platelet von Willebrand factor antigen (vWF:Ag) and ristocetin cofactor activity (Ricof) were measured in 28 obligatory heterozygotes (ie, parents or children of probands from 15 different kindreds with severe vWD). On the average, heterozygotes had low levels of vWF in both platelets and plasma. There was, however, considerable heterogeneity, with four distinct patterns. Eleven heterozygotes had concordant reduction of vWF:Ag and Ricof in both plasma and platelets; five had low levels of vWF:Ag and Ricof in plasma contrasting with normal levels in platelets; eight had a peculiar pattern, the reverse of the above (ie, low levels in platelets and normal levels in plasma); and in one, both vWF measurements were normal in plasma and platelets. These patterns were genetically determined: they were consistent in four couples of consanguineous heterozygotes and in two couples carrying the same gene deletion. Only the remaining three heterozygotes had no clearly identifiable pattern. Other findings of this study were that although most of the heterozygotes had normal bleeding times, the 7 of 28 who had prolonged bleeding times had concordantly low levels of vWF measurements in both plasma and platelets. In conclusion, this large series of obligatory heterozygotes provides evidence for phenotypic and genotypic heterogeneity of severe vWD.     

Platelet aggregation induced by type IIb platelet von Willebrand factor

Platelet lysates from five patients with a form of type IIb von Willebrand's disease (vWd), associated with spontaneous platelet aggregation and thrombocytopenia, induced platelet aggregation of normal and other vWd's platelet-rich plasma (PRP). Platelet lysate from normals, type I or type IIa vWd did not cause platelet aggregation of normal PRP. When polyclonal monospecific antibodies directed against plasma von Willebrand factor (vWf) were incubated with the type IIb platelet lysate, they inhibited the platelet aggregation. Monoclonal antibodies directed against the glycoprotein (GP) Ib binding domain of plasma vWf incubated with the type IIb platelet lysate did not inhibit the platelet aggregation. Normal platelets suspended in afibrinogenaemic plasma did not aggregate when type IIb vWd platelet lysate was added. Normal platelets incubated with monoclonal antibodies directed against the fibrinogen and vWf binding site(s) on the GPIIb/IIIa were not aggregated by the type IIb platelet lysate. Bernard-Soulier PRP aggregated when type IIb vWd platelet lysate was added, while Glanzmann's thrombasthenic platelets did not. Peptides containing the RGDS sequence or the sequence of the carboxy terminal 15 amino acids of the gamma chain of fibrinogen inhibited the type IIb vWd platelet lysate-induced platelet aggregation. These data suggest that type IIb platelet vWf can cause platelet aggregation of PRP without the addition of any agonist. This interaction is different from that observed with the plasma vWf from these patients.     

Abnormal platelet von Willebrand factor interaction in patients with TTP

Thrombotic thrombocytopenic purpura (TTP) is associated with abnormal platelet function and disturbances in coagulation; however, a specific causative factor is not defined. Plasma infusion or plasma exchange (PE) are thought to be of benefit in replacing a deficient plasma component or removing some toxic compound. In three patients with TTP, samples taken prior to initiation of PE showed high levels of vWF:Ag in the plasma (208, 264, and 321 U/dl), whereas the VIII:C levels were normal. The vWF:Ag multimer patterns of the plasma demonstrated a decrease in the amount of high molecular weight (HMW) forms. Analysis of the platelets from one patient also showed an increase in the HMW multimers. Platelets from all three patients showed a decreased ability to absorb vWF:Ag, with little or no absorption of the HMW forms. Following extensive PE and resolution of disease, the platelets regained their ability to absorb vWF:Ag in the one patient examined.     

Canine platelet von Willebrand factor: quantification and multimeric analysis

Washed canine platelets were shown to express a significant level of von Willebrand factor (vWf). Canine platelet vWf differed from canine plasma vWf by the absence of satellite bands associated with each multimer when resolved by SDS-agarose gel electrophoresis. Expression and multimeric composition of canine platelet vWf was quite similar to that of human platelet vWf. Quantification in both lysed, washed canine platelets and in releasate of washed canine platelets yielded estimates of platelet vWf at approximately 2% of circulating vWf in this species, with approximately 15% of this being released into the fluid phase on activation. This contrasts with findings in humans, in which approximately 10%-25% of circulating vWf is compartmentalized in platelets. The difference in relative levels of canine and human platelet vWf could not be accounted for by differences in platelet ultrastructure. The decreased relative level may account for reports that canine platelets contain no vWf.     

von Willebrand factor and platelet interactions with the vessel wall

von Willebrand factor (vWF) is a multimeric glycoprotein which has a dual role in haemostasis, functioning as carrier protein for Factor VIII and mediating platelet adhesion to exposed subendothelium (SE). vWF interacts with components of the SE such as collagen and heparin-like glycosaminoglycans as well as with two platelet membrane receptors: glycoprotein (GP) Ib and GPIIb/IIIa. These multiple binding functions explain its definition as an adhesive protein. vWF promotes platelet adhesion at the high shear rates which correspond to the rheologic conditions of the microcirculation or of narrowed arterial vessels. The role of the vWF-GPIb interaction in platelet adhesion is well known; that of the vWF-GPIIb/IIIa interaction has been more recently demonstrated through the use of monoclonal antibodies (MAbs) or synthetic peptides blocking vWF-binding to GPIIb/IIIa. In addition, perfusion studies in native, non-anticoagulated blood emphasize the concept that vWF is also essential for thrombus formation at high shear stress. Thus, vWF fragments, synthetic peptides or MAbs blocking the functional domains of vWF represent potential therapeutic strategies to prevent the development of thrombosis.