Inhibition of platelet adhesion to collagen by monoclonal anti-CD36 antibodies

Monoclonal anti CD36 antibodies capable of inhibiting platelet adhesion to collagen have not previously been identified. We have now prepared two groups of monoclonal antibodies. One group was prepared using, as immunogen, highly purified (99+%) CD36 prepared by a denaturing procedure. These antibodies (Mo series) reacted strongly with CD36 on protein blots but did not immunoprecipitate native CD36 from platelet lysates nor inhibit platelet adhesion to collagen. The second group of monoclonal antibodies (131 series) was prepared using CD36 purified to >95% by a non-denaturing procedure. These antibodies reacted with control platelets, but not Nak^a-negative platelets which lack CD36, as measured by flow cytometry and by immunoprecipitation. Three monoclonal antibodies of this latter group (131.4, 131.5 and 131.7) inhibited platelet adhesion to collagen in static systems under Mg²⁺-independent conditions but had little effect in the presence of Mg²⁺. 131.4 and 131.7 also inhibited adhesion to collagen using citrated whole blood in a parallel plate flow chamber at physiological shear rates (800 s⁻¹), whereas 131.5 was without effect. These are the first anti-CD36 monoclonal antibodies shown to be capable of inhibiting platelet adhesion to collagen and provide further evidence that CD36 plays a role in platelet–collagen interaction.     

Factor VIII/von Willebrand factor in subendothelium mediates platelet adhesion

The present studies were undertaken to determine whether factor VIII/von Willebrand factor (vWF) present in the vessel wall (in addition to that in plasma) may mediate the attachment of platelets to subendothelium. Subendothelium from everted rabbit aorta was exposed to human citrated blood flowing through an annular perfusion chamber at 40 mL/min (wall shear rate of 2,600 s-1 for five minutes). The vessel segments were incubated at 37 degrees C for one hour with various dilutions of either goat-anti-rabbit factor VIII/vWF serum or an IgG fraction prepared from the serum. Control segments were incubated with serum or IgG from a nonimmunized goat. Values of platelet contact (C), platelet adhesion (C + S), and thrombus formation (T) on the subendothelium were evaluated by a morphometric technique. Compared with vessels incubated with fractions prepared from a normal goat, a significant decrease in platelet adhesion (C + S), ranging from 45% to 65%, was observed on vessels incubated with various dilutions (1:5 to 1:50) of either serum or IgG fractions of goat-anti-rabbit factor VIII/vWF. A similar decrease in platelet adhesion was observed with vessels incubated with an F(ab')2 fragment against rabbit factor VIII/vWF prepared in the goat. When goat-anti-rabbit factor VIII/vWF IgG was added to rabbit blood (1:75 dilution), platelet adhesion was reduced to the same extent (65%) on normal rabbit vessels and on vessels pre-incubated with goat-anti-rabbit factor VIII/vWF. Immunofluorescence studies revealed the presence of rabbit factor VIII/vWF in the subendothelium of rabbit aorta and the continued binding of the goat-anti-factor VIII/vWF antibodies on subendothelium during the perfusion studies. No uptake of human factor VIII/vWF on the rabbit subendothelium was observed by this immunologic technique; human factor VIII/vWF was found to be entirely associated with the attached human platelets. Thus, factor VIII/vWF in the vessel wall may mediate platelet attachment to subendothelium in a manner similar to that of plasma factor VIII/vWF.     

von Willebrand factor and factor VIII are independently required to form stable occlusive thrombi in injured veins

von Willebrand factor (VWF) protects factor VIII (FVIII) from proteolysis and mediates the initial contact of platelets with the injured vessel wall, thus playing an important role in hemostasis and thrombosis. VWF is crucial for the formation of occlusive thrombi at arterial shear rates. However, with only a few conflicting studies published, the role of VWF in venous thrombosis is still unclear. Using gene-targeted mice, we show that in ferric chloride-injured veins platelet adhesion to subendothelium is decreased and thrombus growth is impaired in VWF(-/-) mice when compared with wild type (WT). We also observed increased embolization in the VWF(-/-) mice, which was due to lower FVIII levels in these mice as recombinant factor VIII (r-FVIII) restored thrombus stability. Despite normalization of blood clotting time and thrombus stability after r-FVIII infusion, the VWF(-/-) venules did not occlude. Transgenic platelets lacking the VWF receptor GPIbalpha extracellular domain showed decreased adhesion to injured veins. But, after a delay, all the injured venules occluded in these transgenic mice. Thus, VWF likely uses other adhesion receptors besides GPIbalpha in thrombus growth under venous shear conditions. Our studies document crucial roles for VWF and FVIII in experimental thrombosis under venous flow conditions in vivo.     

Von Willebrand factor accelerates platelet adhesion and thrombus formation on a collagen surface in platelet-reduced blood under flow conditions

Plasma von Willebrand factor (VWF) has been identified as an indispensable factor for platelet adhesion and thrombus formation on a collagen surface under flow conditions. VWF binds to collagen and then tethers platelets to the collagen surface through interaction with platelet glycoprotein Ib and also contributes to the thrombus formation on the collagen surface. In the present study, we demonstrated that the addition of VWF/factor VIII complex or purified VWF (> 2 ristocetin cofactor activity units/mL) increased platelet adhesion to the collagen surface in platelet-reduced blood ( approximately 5 x 10(4) platelets/microL) to the normal level. VWF had no stimulatory effect when it was allowed to bind to the collagen surface before blood flow was initiated. Addition of an excess of FITC (fluorescein-5-isothiocyanate)-labeled VWF to platelet-reduced blood under these flow conditions demonstrated that the VWF was mainly incorporated into the platelet aggregates. These results indicated that the supplemented VWF stimulates the platelet adhesion onto the collagen surface by enhancing platelet aggregation in the platelet-reduced condition. This also suggests a possibility that supplementation of VWF to individuals with thrombocytopenia might be effective for increasing their hemostatic potential.     

Shear rate-dependent impairment of thrombus growth on collagen in nonanticoagulated blood from patients with von Willebrand disease and hemophilia A.

Thrombus formation on collagen fibrils was quantified at venous (100/s) and arterial (650/s and 2,600/s) wall shear rates in blood from patients with various subtypes of von Willebrand disease (vWD) and with hemophilia A (HA). Nonanticoagulated blood was drawn directly from an antecubital vein over purified type III collagen fibrils exposed in parallel-plate perfusion chambers. Blood-collagen interactions were differentiated and quantified by morphometry as platelet adhesion, thrombus height, thrombus volume, and deposition of fibrin strands. Sixteen patients with vWD, including four type III, six type I, four type IIA, and two type IIB, were compared with 26 normal subjects and nine patients with HA, including six severe HA and three mild HA. Platelet adhesion and thrombus formation at 2,600/s were significantly decreased in blood from patients with vWD type III, IIA, and IIB, but not in blood from patients with type I and in HA. The abnormal thrombus formation was apparently not related to the decreased levels of factor VIII (F.VIII), because thrombus height and volume were normal in severe and mild HA. Thrombus formation at 650/s was also significantly decreased in patients with vWD type III, IIA, and IIB and slightly reduced in type I. Significant reduction in thrombus volume and height was also observed in blood from patients with severe HA, but not in mild HA. Thrombus dimensions were not affected at 100/s in the vWD subtypes. However, significantly decreased thrombus height and virtually absent fibrin deposition were observed in blood from patients with severe HA. Apparently, F.VIII supports thrombus formation at low and intermediate shear conditions, presumably through the generation of thrombin. In contrast, von Willebrand factor (vWF) mediates not only platelet adhesion, but also thrombus formation at intermediate and high shear rates. Thus, the relative contribution of coagulation (F.VIII) and platelet function (vWF) in thrombus formation appears to be shear rate dependent, but having optimal effects at different shear conditions.     

Monoclonal Antibody to Human Platelet Glycoprotein I II. EFFECTS ON HUMAN PLATELET FUNCTION

S ummary . The effect on platelet function of a monoclonal platelet antibody to platelet membrane glycoprotein I was tested. This antibody, AN51, inhibited ristocetin or bovine factor VIII-induced aggregation but did not modify ADP, collagen type I or type III, thrombin or arachidonic acid induced aggregations. Furthermore, the adhesion-aggregation of platelets induced by microfibrils was also inhibited by the antibody. Platelet adhesion to rabbit aorta subendothelium was impaired by the antibody. The persistent adhesion of platelets to collagenase-treated subendothelium was also inhibited. These findings strongly suggested that platelet membrane glycoprotein I could interact with a non-collagenic microfibrillar component of subendothelium. The binding of factor VIII/von Willebrand factor to platelet membrane in the presence of ristocetin was decreased in the presence of the antibody. Platelet membrane glycoprotein I could, thus, be a binding site for factor VIII/von Willebrand factor to allow platelet adhesion to subendothelium.     

Interactions of platelets with subendothelium and endothelium

In this review, the authors summarize how platelets interact with subendothelium when the vessel wall is damaged or with intact endothelium in the inflammatory state. When subendothelium is exposed to rapidly flowing blood upon vessel damage, platelets adhere rapidly to the exposed surface, decelerate, and aggregate to arrest bleeding. Under high shear stress, such as is found in the microcirculation, the interaction between subendothelial von Willebrand factor (VWF) and its platelet receptor, glycoprotein (GP) Ib-IX-V, is required to slow down platelets and allow the platelet collagen receptors aloha2beta1 and GP VI to bind to collagen. GP VI and alpha2beta1 play important roles to activate platelets in the early stage and work with GP Ib-IX-V to fully activate platelets to form thrombi. GP Ib-IX-V and GP VI employ similar signaling pathways for platelet activation and the signals from both receptors are down-modulated by PECAM-1 (platelet-endothelial-cell adhesion molecule 1) to prevent unnecessary platelet activation under high shear. During inflammatory states, intact endothelial cells release VWF and P-selectin from their Weibel-Palade bodies. Both molecules are ligands for GP Ib-IX-V. The newly released VWF is larger and stickier than the form normally found in plasma and binds platelets spontaneously. Normally, VWF is processed by proteolysis by the plasma metalloprotease ADAMTS-13. Failure of this processing results in the microvascular thrombotic disorder thrombotic thrombocytopenic purpura. In this review, the authors also use available crystal structures of platelet receptors and ligands to explain the details of their interactions.     

Deficiency of platelet membrane glycoprotein Ia associated with a decreased platelet adhesion to subendothelium: a defect in platelet spreading

A bleeding disorder with absent collagen-induced platelet aggregation and adhesion has been described in a patient whose platelets failed to express surface glycoprotein Ia. We studied the interaction of her platelets with subendothelium in an annular perfusion chamber and the interaction with purified human collagen type III in a rectangular perfusion system under flow conditions. Platelet adherence was almost completely absent both at low and high shear rates. The few platelets which adhered remained in the contact stage without subsequent spreading and aggregate formation. Addition of a monoclonal antibody, which was directed against the von Willebrand moiety of FVIII-VWF, to the blood, completely abolished platelet adherence at high shear rates and had a partial effect at low shear rates. These data indicate that von Willebrand factor plays a role in the initial attachment (contact stage) of platelets to subendothelium. We conclude that the bleeding disorder and excessively prolonged bleeding time in our patient are caused by a new specific defect of the platelet-vessel wall interaction.     

Hybridoma antibodies to human von Willebrand factor

Hybridoma antibodies specific for seven independent topographical sites were used to characterize von Willebrand factor (vWF) and to relate the epitopes to functional loci required for vWF-mediated adhesion of platelets to subendothelium and ristocetin-induced platelet aggregation. The capacity of antibodies to influence the adhesion of human platelets to rabbit aortic subendothelium was analysed in annular perfusion chambers. At a high shear rate similar to that of the microcirculation, four monoclonal antibodies inhibited adhesion. In contrast, no inhibition was observed at low shear. Only one of the four antibodies that inhibited platelet adhesion also attenuated ristocetin-cofactor activity (VIIIR:RCo). Conversely, one antibody that inhibited VIIIR:RCo had no effect upon platelet adhesion. These data support the hypothesis that the molecular loci involved in the two biological functions of vWF are not identical. When these conclusions are considered within the context of a spatial map of the vWF protein surface developed by competitive displacement analysis, the epitopes related to platelet adhesion appear to be spaced and differ from those involved in ristocetin-induced platelet-platelet interaction.     

Factor VIII and Human Platelet Aggregation

SUMMARY Bovine factor VIII is a potent inducer of aggregation of human platelets. Upon gel filtration of five-thousand-fold purified material in 0.5 M CaCl₂, bovine factor VIII is separated into high and low molecular weight components: the former contains both a 'carrier protein'and platelet aggregating activity, the latter theproco-agulant activity (low molecular weight factor VHI, LMW-F VIII). Upon removal of Ca²⁺ ions, LMW-F VIII recombines with the 'carrier protein'. LMW-F VIII modifies aggregation by 'carrier protein', but not aggregation by undissociated bovine factor VIII, adenosine-5'-diphosphate or adrenaline. This finding indicates that the platelet aggregating activity is indeed a property of the 'carrier protein'.     

Adhesion of blood platelets to human arterial subendothelium: role of factor VIII-Von Willebrand factor.

The adhesion of human platelets to the human arterial subendothelium was investigated using everted postmortem renal arteries after the first bifurcation and reconstituted blood containing 51Cr-labelled, aspirin-treated platelets in a perfusion chamber according to Baumgartner. The accumulation of 51Cr on the arterial segment was a reliable reflection of the number of platelets that adhered. The dependence of platelet adhesion on platelet number, perfusion time, haematocrit and perfusion rate were found to be similar to what was observed with rabbit aorta previously, notwithstanding the essentially different nature of the human subendothelium, with its layers of smooth muscle cells above the internal elastic lamina. The system was used to study the role of factor VIII-von Willebrand factor (VIII-VWF). VIII-VWF was found to be the only plasma factor enhancing adhesion of platelets fo the vessel wall. No suggestion of an inhibitory substance in plasma was found. Double perfusion experiments indicated that VIII-VWF binding to subendothelium supported subsequent platelet adhesion. A good correlation was found between the amount of VIII-VWF bound and platelet adhesion. Comparison of binding of albumin, fibrinogen, gamma-globulin and VIII-VWF showed that VIII-VWF bound less. This suggests that VIII-VWF does penetrate less easily in the subendothelium, which is in agreement with immunofluorescence studies of tissues. Studies with washed platelets not treated with aspirin showed parallelism between accumulation of VIII-VWF and platelet deposition in thrombi. These data may be explained by assuming a non-easily exchangeable pool of VIII-VWF on the platelet surface and increased binding of VIII-VWF to platelets in thrombi.     

Size regulation of von Willebrand factor-mediated platelet thrombi by ADAMTS13 in flowing blood

The metalloproteinase ADAMTS13 regulates the size of released von Willebrand factor (VWF) multimers bound to endothelial cells, but it is unknown whether it can cleave plasma VWF during thrombogenesis. To address this issue, we perfused blood over immobilized VWF and used videomicroscopy to visualize an activation-independent platelet aggregation process mediated by soluble VWF at shear rates greater than 10 000 s(-1). At normal Ca2+ concentration, platelets formed rolling as well as surface-attached clusters that grew larger during the first 5 minutes but then lost more than 70% of their mass by 10 minutes. In contrast, platelet clusters were stable in size when metal ions were chelated, anti-ADAMTS13 IgG were added, or washed blood cells were perfused with purified VWF but no plasma. In the latter case, addition of recombinant ADAMTS13 reduced platelet cluster size by more than 70%. Incubating ADAMTS13 with VWF before perfusion did not prevent the initial platelet clustering, indicating that the enzyme may act on platelet-bound VWF under shear stress. At the concentrations tested, ADAMTS13 had no effect on platelet aggregates formed upon blood perfusion over collagen fibrils. ADAMTS13, therefore, may regulate thrombus size preferentially when the cohesion between platelets depends on VWF binding induced by pathologically elevated shear stress.     

New insights into von Willebrand disease and platelet function

Regulation of binding between von Willebrand factor (VWF) and the platelet receptor glycoprotein (GP) Ibα is one of the key steps in controlling hemostasis and thrombosis. On vascular injury at sites of high shear rates, the GPIbα interaction with subendothelial-bound VWF will initiate the tethering of circulating platelets to the vessel wall. Tethered platelets subsequently roll on the damaged vessel wall, a process that is amplified by the activation of the platelet integrin αΙΙbβ3 (GPIIb/IIIa). The initial tethering to VWF is rapidly followed by platelet binding to collagen through specific receptors (GPVI and α2β1), leading to firm adhesion, activation, and additional stable bonds mediated by αΙΙbβ3. The above described interactions can result in two distinct processes: physiological hemostasis and pathological thrombosis. Furthermore, VWF carries coagulation factor VIII, which is involved in thrombin formation that in addition to activating platelets, mediates fibrin formation and has several other actions. The importance of VWF in hemostasis is well known in patients suffering from von Willebrand disease (VWD) who present with a defect in both platelet plug and fibrin formation. Type 2B VWD is of special interest as it may provide further insight into the mechanism by which VWF promotes the adhesion of platelets to a thrombogenic surface under conditions of high shear stress. The variant phenotypic manifestations in patients affected with type 2B VWD, however, have raised the question of locus heterogeneity in VWD as a consequence of, for example, additional defects in receptor or signaling proteins mediating platelet adhesion and aggregation. Indeed, quite a few polymorphisms of platelet receptors have been associated with increased bleeding in VWD. However, many aspects of the disease remain to be elucidated. For instance, thrombin and platelet procoagulant activity may be important counterplayers to determine the severity of the bleeding complications associated with VWD.     

Differential aspects of the glycoprotein Ib-von Willebrand factor axis in human and pig species

BACKGROUND AND OBJECTIVE: The role of glycoprotein Ib (GPIb) in platelet adhesion to subendothelium is well established in human species. However, the interaction of GPIb and von Willebrand factor (VWF) in a widely used experimental model in thrombosis research, that of the pig, has not been clearly elucidated. We investigated the differences between human and pig species in the GPIb/VWF axis in several ways. DESIGN AND METHODS: Standard aggregometry and perfusion studies with circulating blood were applied to isolated platelets or to blood reconstituted with isolated platelets, VWF and red blood cells from the different species. Platelet aggregation to VWF in the presence of either ristocetin or botrocetin was tested. RESULTS: Human VWF and ristocetin did not agglutinate pig platelets. However, botrocetin was capable of agglutinating pig platelets. In perfusion studies (800 s(-1), 10 min), washed platelets from both species were suspended in albumin solutions containing human VWF (hVWF) or porcine VWF (pVWF) and red blood cells from the corresponding species. Reconstituted blood with high concentrations of pVWF (> or =0.25 U/mL) caused severe thrombocytopenia during the perfusion procedure when added to human platelets. Nevertheless, lower concentrations (< or =0.1 U/mL) promoted the formation of large aggregates. Under our experimental conditions, hVWF poorly supported pig platelet adhesion. INTERPRETATION AND CONCLUSIONS: In conclusion, pVWF may support human platelet adhesion and even promote aggregation, while hVWF can only partially facilitate pig platelet adhesion. Minimal concentrations of pVWF could facilitate the interaction of human platelets with subendothelium, increasing their adhesive and aggregating capabilities. Understanding the molecular differences of the GPIb-VWF axis in different species may prove useful for developing therapeutic strategies aimed at preventing excessive platelet deposition on damaged vascular surfaces.     

The role of platelet membrane glycoproteins Ib and IIb-IIIa in platelet adherence to human artery subendothelium

Platelet adherence to human artery subendothelium in blood from eight normal subjects, four patients with Glanzmann's thrombasthenia (deficiency of platelet membrane glycoproteins IIb and IIIa: GPIIb-IIIa), two patients with Bernard-Soulier syndrome (deficiency of platelet membrane glycoprotein Ib: GPIb) and one patient with von Willebrand's disease (VWD subtype III. deficient in factor VIII-von Willebrand factor: FVIII-VWF) was compared at various wall shear rates (300, 500, 1000, 1800 and 2500 s-1). Platelet adherence in blood from the patients with Glanzmann's thrombasthenia was within the normal range at shear rates below 1000 s-1. There was some decrease in adhesion at higher shear rates and platelets were less spread out on the subendothelium than normally at all shear rates. Platelet aggregate formation was almost totally absent. Platelet adherence in blood from patients with the Bernard-Soulier syndrome was strongly impaired at all shear rates. Platelet adherence in blood from the patient with VWD subtype III was normal at shear rates of 300 and 500 s-1, but impaired at shear rates above 1000 s-1. Aggregate formation was also decreased at these shear rates. Platelet adhesion was strongly inhibited by a monoclonal antibody against glycoprotein Ib, which had previously been shown to inhibit ristocetin-induced aggregation, at shear rates of 500 and 1800 s-1 but not at 300 s-1. Platelet adhesion at 1800 s-1 was also inhibited, though to a lesser extent, by two antibodies against GPIIb-IIIa. These antibodies also inhibited platelet aggregate formation. The data indicates that GPIb is involved in adhesion at the same shear rates as von Willebrand factor. Absence or inhibition of GPIIb-IIIa primarily causes a defect of aggregate formation but GPIIb-IIIa may also play a role in adhesion, particularly at high shear rates. The defect of adhesion in the Bernard-Soulier syndrome may be dependent on factors other than a deficiency of GPIb alone.     

Immunogold labelling of human von Willebrand factor adsorbed to collagen

von Willebrand factor (vWF) mediates adhesion of platelets to the exposed subendothelium at sites of vascular injury. This function is expressed through binding of vWF to both collagen and receptors on the platelet membrane. We have developed a new method using immunogold staining and electron microscopy, permitting visualization of human vWF adsorbed to collagen fibrils. The electron micrographs revealed strings of gold beads reflecting the polymeric structure of vWF. Our data showed dramatic differences in the binding of vWF to collagens of different sources: high binding density was observed using a collagen preparation isolated from aortic tissue whereas colloidal gold was virtually absent from tendon collagen. Using the immunogold labelling method we demonstrated that high shear rate enhanced vWF binding to aortic collagen.     

Functional Property of von Willebrand Factor Under Flowing Blood

von Willebrand factor (vWF) is produced in megakaryocytes and endothelial cells, is stored in the alpha-granule of platelets and in the Weibel-Palade body of endothelial cells, and is present in plasma and vascular subendothelium. This huge protein with a unique multimeric structure plays a pivotal role in both hemostasis and pathological intravascular thrombosis, in which vWF contributes to both platelet adhesion/aggregation and blood coagulation through its multiple adhesive functions for the platelet membrane receptors, glycoprotein Ib-IX-V complex, integrin alphaIIbbeta3, heparin, various types of collagen, and coagulation factor VIII. Among various functions, the most characteristic feature of vWF is its determinant role on platelet thrombus formation under high-shear-rate conditions. Indeed, at in vivo rheological situations where platelets are flowing with high speed in the bloodstream, the only reaction that can initiate mural thrombogenesis is the interaction of vWF with platelet glycoprotein Ibalpha. The recent x-ray analysis of the crystal structure of various functional domains and functional studies of this protein under experimental flow conditions have rapidly advanced and revised our knowledge of the structure-function relationships of vWF, a key protein for hemostasis and arterial thrombosis.     

Fibronectin in artery subendothelium is important for platelet adhesion

The role of subendothelial fibronectin in platelet interaction with subendothelium was studied. Human umbilical artery subendothelium was exposed to flowing blood containing 111In-labeled platelets in an annular perfusion chamber. Platelet adhesion was determined from the 111In radioactivity on the vessel wall. When perfusions were performed for five minutes at a wall shear rate of 1,800 s-1, platelet adhesion was the same whether normal plasma or fibronectin-free plasma was used. Preincubation of subendothelium with rabbit anti-human fibronectin serum, however, resulted in a marked inhibition of platelet adhesion. Preincubation with normal rabbit serum had no effect. Platelet adhesion was also diminished when the vessel wall was preincubated with anti- fibronectin IgG fraction or F(ab')2 fragment. After the latter preincubations, frozen sections of 4 micron were incubated with fluorescein isothiocyanate-conjugated goat anti-rabbit IgG, F(ab')2 fragment specific. Fluorescence was seen throughout the subendothelium both before and after perfusion. No fluorescence was seen when subendothelium was preincubated with normal rabbit IgG or F(ab')2 or with anti-fibronectin IgG that had been absorbed with purified fibronectin. After absorption of anti-fibronectin IgG with purified fibronectin, the inhibiting effect on platelet adhesion was also no longer present. Preincubation of the vessel wall with anti-fibronectin IgG reduced platelet adhesion significantly at a wall shear rate of 800 s-1. This effect was even greater at 1,800 s-1. At low shear rate (400 s-1), there was no inhibition.     

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.     

Fibronectin is required for platelet adhesion and for thrombus formation on subendothelium and collagen surfaces

Fibronectin (FN) plays a role in several adhesion mediated functions including the interaction of platelets with subendothelium. We investigated the role of plasma FN in platelet adhesion and platelet thrombus formation under flow conditions. We used two different perfusion models: the annular chamber with alpha-chymotrypsin-treated rabbit vessel segments, and the flat chamber with coverslips coated with fibrillar purified human collagen type III. Perfusates consisted of washed platelets and washed RBCs, suspended in normal or FN-depleted plasma. Perfusions were carried out for ten minutes at shear rates of 300 or 1,300 s-1. Platelet deposition and thrombus dimensions were evaluated morphometrically by a computerized system. We found that depletion of plasma fibronectin significantly reduced the percentage of total coverage surface and percentage of platelet thrombus, at both shear rates studied, and in both perfusion systems (P less than .01) (P less than .01). The dimensions of the platelet thrombi formed in perfusions at high shear rate were also significantly reduced in perfusions carried out with FN depleted plasma (P less than .01). Addition of purified FN to FN-depleted perfusates restored all values to those measured in the control perfusions. These results indicate that plasma FN is required for platelet aggregate and thrombus formation following adhesion under flow conditions.