Uncoordinated expression of fibrinogen compared with thrombospondin and von Willebrand factor in maturing human megakaryocytes

The localization of three known alpha-granule proteins, thrombospondin (TSP), von Willebrand factor (vWF), and fibrinogen (Fg) has been studied in human megakaryocytes (MK) by immunofluorescence and immunoelectron microscopy. For this study, highly purified populations of MK were prepared from human bone marrow either by counterflow centrifugal elutriation or by cell culture from normal subjects and from two patients with megakaryoblastic leukemia. In normal bone marrow immature MK, TSP, and vWF were observed in the Golgi-associated vesicles and in small immature alpha-granules; in mature MK, they were found in the matrix of the mature large alpha-granules. Surprisingly, Fg was detected neither in the Golgi area, nor in the small precursors of alpha-granules; it was only found in the mature alpha-granules but this labeling was generally weaker than in blood platelets. In order to confirm these differences between the expression of Fg and vWF or TSP additional studies were performed on cultured maturing MK: immunofluorescent and ultrastructural immunogold labeling confirmed that vWF appeared early in the maturation while the same immature MK were negative for Fg. In the late maturation stage, the three proteins were detected in the alpha-granules. In order to know whether Fg was lately synthesized or endocytosed from the outside medium, normal MK were grown in the presence of either normal or afibrinogenemic plasma, and normal serum. Fg was detected only in the alpha-granules of MK grown in normal plasma. Similar results were observed with malignant MK, whose maturation was independent of the culture conditions. In conclusion, this study brings immunocytochemical evidence that vWF and TSP are synthesized by immature MK, whereas Fg appears later in the MK alpha-granules and its expression is dependent of the presence of an exogenous Fg source.     

Ultrastructural localization of human platelet thrombospondin, fibrinogen, fibronectin, and von Willebrand factor in frozen thin section

We have investigated the localization of thrombospondin (TSP), fibrinogen, fibronectin, and von Willebrand factor in human platelets by transmission electron microscopy of antibody-stained ultrathin frozen sections. In negatively stained thin sections, alpha granules were identified on the basis of their smooth, roughly spherical shape, size, single limiting electron-lucent 100 A membrane, and frequent presence of electron-dense nucleoid. In contrast, mitochondria exhibited characteristic double membranes and cristae. Sections were separately stained with affinity-purified polyclonal antibodies to these proteins as well as with three monoclonal anti-TSP antibodies. Antibody specificity was documented in radioimmunoassays, by immunofluorescent cross-blocking, and by staining of bands of appropriate mobility in Western blots of whole platelets. Bound antibody was visualized using a 5-nm colloidal gold-avidin conjugate. In resting cells, staining of virtually all alpha granules was observed for all four proteins. In contrast, consistent staining was absent from other organelles, including plasma membranes, mitochondria, and vacuolar structures that may represent the open canalicular system.     

Ultrastructural localization of platelet factor 4 in rat megakaryocytes and platelets by gold-labeled antibody detection

The pattern of distribution of platelet factor 4 (PF-4) was studied in rat platelets and megakaryocytes following immunohistochemical labeling with a monoclonal antibody (2E7) specific for PF-4 and visualization by a protein A-gold complex. We observed a heterogeneity in PF-4 expression among alpha granules with a minority of them being unlabeled by immunoelectron microscopy, a pattern similar in both mature, circulating platelets and developing megakaryocytes. Furthermore, the majority of the labeled alpha granules in both cell types displayed a unique, eccentric localization of the PF-4 that was mainly over the nucleoid region within each granule. This localization is similar to the microtubular localization in alpha granules reported previously for von Willebrand factor and yet distinct from the reported random distribution of fibrinogen. We also observed significant labeling of small vesicular structures in developing megakaryocytes that may be involved in the transport of PF-4 and its packaging in platelet alpha granules. This new information is important in relating patterns of PF-4 biogenesis in megakaryocytes to conditions of alpha granular dysfunction in platelets.     

An immunoelectron microscopic study of von Willebrand factor in the thoracic duct endothelium of rats

The localization of Von Willebrand factor-like immunoreactivity (VWFI) in the thoracic duct endothelium was investigated by means of preembedding immunoelectron microscopy. In the endothelial cells, VWFI was observed within rod-shaped Weibel-Palade bodies (WPBs) with an occasional tadpole-like appearance. The WPBs occasionally appeared to be associated with Golgi complexes of the endothelial cells. Some cisternae of the rough endoplasmic reticulum located in the perikarya of the endothelial cells also exhibited VWFI. There was a small number of large VWFI vesicles in the periphery of the endothelial cells. These findings provide morphological evidence for the thoracic duct as a site of VWF synthesis and suggest further that VWF is produced in the rough endoplasmic reticulum and transported into the WPBs and large vesicles occasionally via the Golgi apparatus.     

The effect of Arg-Gly-Asp-containing peptides on fibrinogen and von Willebrand factor binding to platelets.

The Arg-Gly-Asp sequence resides in the cell attachment region of fibronectin. Arg-Gly-Asp-containing peptides support fibroblast attachment, inhibit fibroblast adhesion to fibronectin, and inhibit fibronectin binding to thrombin-stimulated platelets. In view of the similarities between the binding of fibronectin, fibrinogen, and von Willebrand factor to stimulated platelets, we have examined the effects of Arg-Gly-Asp-containing peptides on the interaction of these latter two adhesive proteins with platelets. Gly-Arg-Gly-Asp-Ser-Pro was used as a prototype peptide, and this hexapeptide inhibited fibrinogen binding to ADP and thrombin-stimulated platelets in the 10-200 microM range. The inhibition exceeded 90% at high concentrations of peptide and was observed in the presence of either calcium or magnesium. Platelet aggregation was also inhibited by the peptide in this dose range. The hexapeptide inhibited fibrinogen binding to platelets with receptors fixed in an exposed state, indicating direct interference with the ligand-platelet interaction. The peptide was 1/2 to 1/3rd as potent in inhibiting fibrinogen as fibronectin binding to platelets, but fibrinogen and von Willebrand factor binding were inhibited to an identical extent. Conservative amino acid substitutions for the arginine, glycine, or aspartic acid markedly reduced inhibitory activity and the Asp-Gly-Arg sequence was inactive. These results indicate that Arg-Gly-Asp-containing peptides can inhibit the binding of the three adhesive proteins to stimulated platelets, establishing a basic common feature between the interaction of these molecules with platelets.     

ADP-dependent common receptor mechanism for binding of von Willebrand factor and fibrinogen to human platelets.

Human von Willebrand factor (vWF) and fibrinogen are adhesive plasma glycoproteins essential for formation of a platelet hemostatic plug. We investigated the role of ADP and fibrinogen in binding of vWF to platelets in vitro. Binding of 125I-labeled vWF to human platelets separated from plasma proteins and treated with ADP was specific, and time and concentration dependent, reaching equilibrium at 20 min and approaching saturation at 12 micrograms/ml. The binding was inhibited by EDTA and by prostaglandin I2, a known activator of platelet adenylate cyclase. A purine nucleotide affinity analog, 5'-p-fluorosulfonylbenzoyl adenosine (FSBA), which covalently modifies the ADP binding sites on the human platelet membrane, prevented binding of vWF induced with ADP, as well as with human thrombin and with ionophore A23187, agents known to cause platelet ADP secretion. By comparison, FSBA did not inhibit binding of vWF induced by ristocetin, indicating that the ristocetin mechanism is not dependent on ADP. Human fibrinogen inhibited in a competitive manner the ADP-induced binding of 125I-labeled vWF (9 micrograms/ml) with an IC50 of 25 micrograms/ml. Conversely, unlabeled vWF inhibited ADP-induced binding of 125I-labeled fibrinogen (60 micrograms/ml) with an IC50 of 16 micrograms/ml. A synthetic dodecapeptide (Mr, 1188), analogous with the specific platelet receptor recognition site of human fibrinogen gamma chain (gamma 400-411), inhibited binding of both 125I-labeled vWF and 125I-labeled fibrinogen to ADP-treated platelets, whereas it was without effect on binding of 125I-labeled vWF to ristocetin-treated platelets. These data indicate that vWF and fibrinogen have a common receptor mechanism for their interaction with human platelets that is dependent on ADP occupancy of its binding sites and is recognized by the sequence of 12 amino acid residues at the carboxyl terminus of the human fibrinogen gamma chain.     

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.     

Unique interactions of asialo von Willebrand factor with platelets in platelet-type von Willebrand disease

The present studies demonstrate that platelets from patients with platelet-type von Willebrand disease show specific and saturable binding of asialo von Willebrand factor (AS-vWF) under conditions where such binding is not observed with normal platelets. Although specific binding of 125I-AS-vWF to formalin-fixed normal platelets could not be demonstrated, specific binding to fixed patient platelets was seen with an apparent Kd of 1.3 micrograms/mL and specific maximally bound ligand of 0.40 micrograms/10(8) platelets. Preincubation of patient platelets with the antiglycoprotein Ib (anti-GPIb) monoclonal antibody AS-2 reduced total binding close to the level of computer-estimated nonspecific binding. In contrast, binding was not reduced by preincubation with anti-GPIIb/IIIa monoclonal antibody or with 5 mmol/L EDTA. Under stirring conditions, the binding of AS-vWF to fixed patient platelets was accompanied by a strong agglutination response. AS-vWF- induced agglutination was similarly observed in patient but not normal platelet-rich plasma (PRP) in the presence of 5 mmol/L EDTA. In the absence of EDTA, AS-vWF produced a full aggregation response in patient PRP at concentrations as low as 0.1 microgram/mL in contrast to the 2 to 20 micrograms/mL required by normal PRP. Both thromboxane B2 formation and adenosine triphosphate secretion showed an AS-vWF concentration dependence paralleling the aggregation responses. These studies show that a major difference in the platelets from patients with platelet-type von Willebrand disease is the presence of an exposed, high-affinity binding site associated with GPIb that recognizes AS-vWF.     

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.     

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.     

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.     

Hemostatic effect of platelet von Willebrand factor.

In type III von Willebrand disease (vWD) patients, the bleeding time was only partially corrected or not modified after cryoprecipitate infusion, although the levels and the multimeric structure of plasma von Willebrand factor (vWF) were normal. However, the adhesion of normal platelets on the vessel wall subendothelium in the presence of postinfusion patient plasma improved more significantly than the bleeding time. These results suggest a role of the vWF released from normal platelets which is absent in type III vWD platelets. In 5 patients transfusion of normal platelet concentrates performed 1 h after cryoprecipitate infusion without modification of the bleeding time (> 30 min) normalized this parameter, and platelet adhesion to the subendothelium elicited a marked improvement. These last results confirm the suggestion that platelet vWF plays an important 'in vivo' role in the hemostatic process, particularly in patients suffering from severe vWD.     

Inhibition of platelet adhesion to fibronectin, fibrinogen, and von Willebrand factor substrates by complex gangliosides

Gangliosides, which are complex glycosphingolipids containing sialic acid, are found in cell membranes and have been implicated in a variety of cell surface events including cellular adhesion. Complex gangliosides were observed to inhibit the adhesion of thrombin- activated platelets to substrates of fibronectin, von Willebrand factor, and fibrinogen. This adhesion, which is mediated by the glycoprotein IIb-IIIa complex, was differentially inhibited by gangliosides depending on the number of sialic acid residues present within the ganglioside. The observed order of effectiveness was GT1b greater than GD1a greater than GM1 greater than asialo-GM1. Another structurally related glycosphingolipid, globoside, exhibited little inhibitory activity. In contrast to the inhibition of platelet adhesion to von Willebrand factor mediated by the glycoprotein IIb-IIIa complex, gangliosides had no detectable effect on the ristocetin-dependent adhesion of platelets to von Willebrand factor mediated by glycoprotein Ib. These results suggest that the function of the glycoprotein IIb- IIIa complex may be modulated by gangliosides in a manner similar to that previously described for the closely related vitronectin receptor.     

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.     

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.     

Ultrastructural analysis of the distribution of von Willebrand factor and fibrinogen in platelet aggregates formed in the PFA-100

The PFA-100 is a new apparatus used to detect platelet dysfunction in vitro . Anticoagulated blood flows under constant pressure through a capillary, and across an aperture that pierces a membrane coated with collagen and either epinephrine or ADP. Through their ability to adhere and aggregate, platelets occlude the orifice and the closure time is a test of platelet function. Using electron microscopy and immunogold staining, we have analyzed the ultrastructure of platelet aggregates formed within the aperture and that are responsible for the occlusion. Standard electron microscopy showed that the aggregates formed on both collagen-epinephrine and collagen-ADP cartridges presented the same morphological features. The aggregates were exclusively composed of platelets, some of which were degranulated. Degranulation was particularly intense at the periphery of the aggregate where platelets were often totally devoid of secretory organelles. Immunogold staining on ultrathin frozen sections with polyclonal antibodies, allowed us to evaluate the distribution of adhesive proteins such as fibrinogen and von Willebrand factor (vWF) within the aggregate. The latter was found to be abundant in the intercellular spaces between adjoining platelets. Although fibrinogen was also present, its labeling was less intense suggesting that vWF is the major protein implicated in the platelet-platelet interactions in the aggregates formed in the PFA-100 system. This may be because of the high shear rate that occurs across the aperture which suggests that the PFA-100 is particularly sensitive for detecting abnormalities of vWF-platelet interactions.     

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.