Collagen-platelet interaction: Separate receptor sites for types I and III collagen

We have isolated a platelet membrane protein of M_r47 kDa which is responsible for the interaction of platelets with type III collagen. The 47 kDa protein was purified to apparent homogeneity by type III collagen-Sepharose 2B column chromatography and preparative slab gel electrophoreses. The 47 kDa protein blocked the adhesion of platelets to type III but not to type I collagen. Polyclonal antibodies were obtained from rabbits immunized with the purified 47 kDa protein emulsified in complete Freund's adjuvant. The polyclonal antibodies inhibited the type III collagen but not type I collagen-induced platelet aggregation. The inhibitory effect of the antibodies on type III collagen-induced platelet aggregation was dose-dependent. Cross-inhibition on platelet aggregation studies showed that type I collagen receptor antibodies (M_r65 kDa) did not inhibit type III collagen-induced platelet aggregation and type III collagen receptor antibodies did not inhibit type I collagen induced platelet aggregation. These results suggest that type I and type III collagens interact with platelets at separate sites.     

Different role of platelet glycoprotein GP Ia/IIa in platelet contact and activation induced by type I and type III collagens

The role of glycoprotein Ia/IIa was studied during platelet contact and aggregation induced by type I and type III collagen. The anti-glycoprotein Ia/IIa (6F1) antibody inhibited type I collagen-induced aggregation but did not inhibit the first contact between platelets and collagen. In contrast, it was without effect either on type III collagen-induced contact or platelet interaction with the subendothelium in a static assay. Platelet aggregation induced by type III collagen was only slightly slowed down by 6F1 but pp72 spleen tyrosine kinase phosphorylation was not modified even at concentrations of 6F1 that completely blocked platelet activation induced by type I collagen. Our results indicate that glycoprotein Ia/IIa is not a primary binding site for type I or type III collagen on the platelet membrane. This receptor is more specifically involved in type I collagen-induced platelet spreading and aggregation.     

Type I and type III collagen-platelet interaction: inhibition by type specific receptor peptides

We have previously cloned and characterized a platelet receptor for type III collagen (47 kDa) from a human bone marrow cDNA phage library and defined two active peptides. We also cloned and characterized a platelet receptor for type I collagen (65 kDa) and defined an active peptide. Our objective was to study whether there is type specificity of these active peptides. We have engineered a mutant receptor clone by replacing one of the two active peptides of the platelet receptor for type III collagen with the active peptide of the platelet receptor for type I collagen. The replacement of an active peptide at the amino terminal end (rMIII) of the platelet receptor for type III collagen with the type I collagen active peptide was done without altering the hydrophilicity of the protein. This purified recombinant protein reacts with polyclonal anti-47-kDa and anti-65-kDa active peptide antibodies. The purified recombinant protein inhibits both types I and III collagen-induced platelet aggregation. This rMIII also inhibits the adhesion of washed platelets to rabbit aortic segments (natural matrix) in a dose-dependent manner. The chemically synthesized hybrid peptide of each active peptide of platelet type I and type III collagen receptors inhibits types I and III collagen-induced platelet aggregation in a dose-dependent manner. These results suggest that there is a type specific reactive site on platelets for type I and type III collagens.     

Role of the recombinant protein of the platelet receptor for type I collagen in the release of nitric oxide during platelet aggregation

Nitric oxide plays an important role in platelet function and platelets possess the endothelial isoform of nitric oxide synthase. Several reports have indicated that nitric oxide is released upon exposure of platelets to collagen. We have reported that a non-integrin platelet protein of 65 kDa is a receptor for type I collagen. By direct measurement of NO release from washed human platelets suspended in Tyrode buffer with a ISO-NO Mark II, World Precision Instruments, Sarasota, FL, USA, p30 sensor, type I collagen, but not ADP and epinephrine, induces the release of NO in a time-dependent manner. The production of NO is inhibited either by preincubation of type I collagen with the platelet type I collagen receptor recombinant protein or by preincubation of platelets with the antibody to the receptor protein, the anti-65 antibody. However, preincubation of platelets with anti-P-selectin and anti-glycoprotein IIb/IIIa did not affect the release of NO by platelets. These results suggest that the 65 kDa platelet receptor for type I collagen is specifically linked to the generation of NO, and that the 65 kDa platelet receptor for type I collagen plays an important new role in platelet function.     

Recombinant vWF type 2A mutants R834Q and R834W show a defect in mediating platelet adhesion to collagen, independent of enhanced sensitivity to a plasma protease.

Type 2A von Willebrand Disease (vWD) is characterized by the absence of high molecular weight von Willebrand factor (VWF) multimers in plasma which is caused by enhanced extracellular proteolysis or defective intracellular transport. We identified in vWD type 2A patients two mutations in the A2 domain at position 834 in which arginine (R) was substituted for glutamine (R834Q) or tryptophan (R834W). We reproduced these mutations in vWF cDNA and expressed the recombinant proteins in furin cDNA containing baby hamster kidney (fur-BHK) cells. The subunit composition and the multimeric structure of both mutants was similar to wild-type (WT) vWF. Characterization of mutant R834Q by ristocetin or botrocetin induced platelet binding, and by binding to heparin showed no abnormality. R834W had normal botrocetin induced platelet binding, but ristocetin induced platelet binding and binding to heparin were decreased. Under static conditions R834Q and R834W, at 10 microg/ml, bound equally well to collagen type III as WT-vWF. At high shear rate conditions both mutants supported platelet adhesion normally when coated to a glass surface or preincubated on collagen. When R834Q or R834W was added to the perfusate, adhesion to collagen type III was 50% of the WT-vWF value, which was not due to a decreased collagen binding under flow. A divalent cation dependent protease, purified from plasma, degraded the 2A mutants rapidly while WT-vWF was not affected. In conclusion, the mutations present in the A2 domain of vWF result in an enhanced proteolytic sensitivity to a divalent ion-dependent protease. When present in the perfusate, R834Q and R834W show a decrease in platelet adhesion to collagen type III under flow conditions, which is not caused by decreased binding of the mutant vWF to collagen or enhanced proteolysis.     

Increase in platelet non-integrin type I collagen receptor in patients with systemic sclerosis

Microvascular injury is one of the major pathogenetic processes involved in systemic sclerosis (SSc). Interaction of the platelet types I and III collagen receptors with their respective ligand in the exposed subendothelial stroma as a result of ongoing microvascular injury in SSc patients results in platelet activation and aggregation with the release of mediators, which contribute to vascular damage and inflammation. We have found that there is a twofold increase in radiolabeled type I collagen binding to washed platelets from patients with SSc compared to platelets obtained from normal volunteers. Western blot analyses showed that the non-integrin platelet type I collagen receptor protein (65 kDa) is increased dramatically in lysates of platelet from patients with SSc. However, the integrin (alpha(2)beta(1)) and other non-integrin receptors such as glycoprotein VI, glycoprotein IV, and the platelet receptor for type III collagen remain unchanged. In addition, platelet lysates from rheumatic disease controls (rheumatoid arthritis, osteoarthritis, gout, and systemic lupus erythematosus) do not show any significant increases. There is no nitrotyrosylation on 65 kDa in patients with SSc compared to controls, suggesting this might also contribute to binding of CI to the 65-kDa CIR. These results suggest that there is a specific increase in the number of platelet type I collagen receptors in SSc patient's platelets. In addition, the activity of nitric oxide synthase is decreased in patients' platelet lysates compared to controls. The increase in platelet expression of the 65-kDa non-integrin platelet type I collagen receptor may explain the enhanced aggregation of platelets from patients with SSc to CI in vitro and microvascular thrombosis in the disease in vivo.     

Role of nitric oxide synthase in collagen-platelet interaction: involvement of platelet nonintegrin collagen receptor nitrotyrosylation

Platelets possess the endothelial isoform of nitric oxide synthase (eNOS), which plays an important role in platelet function. Other laboratories, including ours, have reported that nitric oxide (NO) is released upon exposure of platelets to collagen, but the mechanism of the interaction is not yet established. The objective of this study is to examine the possible role of nonintegrin receptor nitrotyrosylation on collagen-induced platelet aggregation. Results of the study show that two platelet proteins with M(r) of 65- and 23-kDa proteins are nitrotyrosylated in a time-dependent manner after the addition of type I collagen. The M(r) 65-kDa protein is identified as the platelet receptor for type I collagen. The recombinant protein of the platelet receptor for type I collagen can also be nitrotyrosylated. The nitrotyrosylated recombinant protein loses its ability to inhibit type I collagen-induced platelet aggregation. In addition, the polyclonal anti-65 kDa immunoprecipitates eNOS suggesting that the platelet nonintegrin receptor for type I collagen is closely linked to the eNOS. These results demonstrate that the inhibitory effect of NO on collagen-induced platelet aggregation may be mediated by the nitrotyrosylation of the 65-kDa receptor.     

ADAM 15 is an adhesion receptor for platelet GPIIb-IIIa and induces platelet activation

Cell adhesion and proteolytic matrix degradation are central processes in atherosclerosis. Being a member of the family of ADAMs ("a disintegrin and metalloproteinase"), metargidin (ADAM15) combines a metalloproteinase domain and an RGD aminoacid sequence. We studied the potential role of ADAM15 as an adhesion receptor on endothelial cells and interactions between platelets and ADAM15 with respect to platelet adhesion, activation and thrombus formation. ADAM15 was found to be expressed on cultured endothelial cells (HUVEC). Platelet adhesion to immobilized recombinant ADAM15 was effectively enhanced under both static and high shear rate conditions reaching the maximum level of adhesion to fibrinogen. Consistently, platelet adhesion onto ADAM15 overexpressing endothelial cells was significantly increased. Adhesion to ADAM15 was reduced by blockade of GPIIb-IIIa using neutralizing anti-alpha(IIb)beta3 mAbs (7E3, 2G12), but not by anti-alpha(v)beta3 (LM609). Soluble ADAM15 binds to activated but not to resting GPIIb-IIIa. Moreover, platelets adherent to ADAM15 additionally attracted platelets under high shear rates indicating an initial role of platelet-ADAM15 interactions for thrombus formation. Furthermore, incubation of platelets with soluble ADAM15 showed a dose-dependent increase in secretion of CD62P and CD40L. ADAM15 is expressed on endothelial cells and can serve as an adhesion receptor for platelets via GPIIb-IIIa binding. Platelet adhesion to ADAM15 leads to platelet activation, secretion and promotes thrombus formation. Thus, ADAM15 may represent a novel target for antithrombotic strategies in cardiovascular pathologies.     

INVOLVEMENT OF PHOSPHOPROTEIN PHOSPHATASE 1 IN COLLAGEN-PLATELET INTERACTION

The binding of type I collagen to its receptor initiates platelet aggregation, but the relationship of the receptor to other signal transduction components is not yet established. Correlation of platelet aggregation and anti-type I collagen receptor antibody immunoprecipitation of type I collagen treated [³²PO4]-labeled platelets showed that there are two phosphoproteins (M_r 53 kDa and 21 kDa) that coprecipitated with the 65 kDa platelet type I collagen receptor. In the present investigation, we have identified one of the phosphoproteins. A soluble component the 100,000×g supernatant fraction of 53 kDa protein is recognized by polyclonal anti-PP1 antibody. The activity of the precipitated phosphatase is inhibited by okadaic acid and inhibitor 1, suggesting that it is protein phosphatase 1 (PP 1). Phosphorylation decreases PP 1 activity as was found with [³²PO4]-phosphorylase b as the substrate. The immunocoprecipitation of the type-1 collagen receptor and PP 1 inot the result of cross reactivity of the anti-type I collagen receptor antibody with the PP I protein. These results indicate that the platelet type I collagen receptor, PP 1, and unidentified 21 kDa protein are in close association with the platelet type I collagen receptor upon the binding of type I collagen by the receptor. Copyright © 1996 Elsevier Science Ltd     

Interaction of platelets and purified collagens in a laminar flow model

Damage to the endothelial surface of the vessel wall can result in exposure of circulating blood components to collagen and other subendothelial structures. Collagen types I, III, IV, and V have been demonstrated in the vessel wall by chemical and immunohistological methods; type V is thrombin-sensitive, and is present on the endothelial cell surface. In an earlier study using a rocking model, both unstimulated and ADP-induced platelet adherence was (1) reduced on wells coated with type V collagen in comparison to uncoated wells; and (2) increased on plastic surfaces coated with types III and IV collagen in comparison to those coated with type V collagen. The present study was designed to determine the effect of erythrocytes and shear rate on platelet adherence to these purified collagen types in a laminar flow system. With platelet-rich plasma, adherence of labeled platelets was much lower in the laminar flow system compared with the rocking model. Erythrocytes significantly enhanced platelet adherence to surfaces that were untreated or absorbed with collagen types I, III, and IV. However, this enhancement was not seen in the presence of type V collagen. These studies provide additional evidence for the selectively nonthrombogenic nature of type V collagen.     

Coating conditions matter to collagen matrix formation regarding von Willebrand factor and platelet binding

Introduction

Von Willebrand factor (VWF) and platelet binding needs a uniform collagen matrix therefore we aimed to find an optimal condition for the preparation of human type-I and type-III collagen matrices.

Method

The effects of pH, salt and ligand concentration and binding time were tested when collagen matrices were prepared by adsorption. Surface-bound collagen and collagen-bound VWF measured by specific antibodies. Platelet adhesion was tested under flow conditions at a shear rate of 1800 s^− 1 for 2 min. Matrices and platelets were visualized by atomic force and scanning electron microscope.

Results

The extent of human collagens type-I and III binding to the surface was 10 and 4 times greater and binding was maximal under 8-16 hours, when coated from physiological buffer solution versus acid solution. Collagen fibrils were more developed and platelet adhesion was higher, with more organized and denser aggregates. VWF binding was parallel to the surface bound collagen in both collagen types.

Conclusion

Collagen coating of surfaces for VWF binding and platelet adhesion studies is very variable from acid solution. Our experiments provide evidences that neutralizing the acid and adding NaCl in physiological concentration, thereby facilitating formation of collagen fibril molecules in solution, results in efficient coating of human type-I and type III collagens, which then bind normal VWF equally well.     

F11-receptor (F11R/JAM) mediates platelet adhesion to endothelial cells: role in inflammatory thrombosis

The F11 receptor (F11R) is a cell adhesion molecule (CAM), member of the immunoglobulin superfamily found on the surface of human platelets, and determined to play a role in platelet aggregation, secretion, adhesion and spreading. The same molecule is present also at tight junctions of endothelial cells (EC) where it is known as JAM and acts as a CAM through homophilic interactions. The role of F11R/JAM in the interaction of platelets with endothelial cells was investigated in the current studies. We report here that washed human platelets adhere specifically to a matrix made of immobilized, recombinant sF11R. Furthermore, platelets adhere to cytokine- (TNF-alpha, INF-gamma) stimulated human umbilical vein endothelial cells (HUVEC), and approximately 40-60% of the adhesive force is exerted by homophilic interactions between the F11R of platelets and EC. This is evidenced by the inhibition of platelet adhesion to endothelial cells by recombinant soluble form of the F11R, and by two F11R peptides with amino acid sequences of the N-terminal region, and in the 1(st) Ig fold of the F11R, respectively. This study suggests a role for F11R in the adhesion of platelets to cytokine-inflamed endothelial cells and thus in thrombosis and atherosclerosis induced in non-denuded blood vessels by inflammatory processes. Agents that block the F11R-mediated adhesion of platelets to EC may be of therapeutic value in controlling thrombosis and preventing heart attacks and stroke.     

A recombinant protein and a chemically synthesized peptide containing the active peptides of the platelet collagen receptors inhibit ferric chloride-induced thrombosis in a rat model

We have previously reported that a recombinant protein (M(r) 47 kDa), which contains both active peptide of platelet receptors for types I and III collagen inhibits both types I and III collagen-induced platelet aggregation. In order to eliminate non-reactive portion of the protein, we have constructed a recombinant of rHyB (M r 6 kDa). In addition, we chemically synthesized a hybrid peptide with 30 amino acid residues (cHyB, M r 3 kDa) that contains each of the active peptide derived from platelet receptors for types I and III collagen and a linker of 12 amino acid residues. In the present investigation, we report that both rHyB and cHyB inhibit type I and type III collagen-induced platelet aggregation, and the adhesion of radiolabeled platelets onto rabbit aortic segments in a dose-dependent manner. We have used an animal model, which employs FeCl3 to induce thrombi formation to study the effectiveness of both rHyb and cHyB on preventing thrombi formation. We obtained results that show that both rHyB and cHyB can inhibit thrombi formation in a dose-dependent manner. These results suggest that either rHyB or cHyB may be a possible therapeutic agent in preventing thrombi formation.     

Adhesive domains in the collagen III fragment alpha1(III)CB4 that support alpha2beta1- and von Willebrand factor-mediated platelet adhesion under flow conditions.

Seven overlapping peptides derived from the bovine alpha1(III)CB4 fragment of collagen III support static platelet adhesion, and an integrin alpha2beta1-recognition site has been assigned within this fragment to residues 522-528 of the collagen alpha1(III) chain; (25). In this study we found that two of the peptides, CB4(III)-6 and -7, were able to support platelet adhesion under flow conditions, whereas the other peptides showed either very little (CB4(III)-1 and -4) or no platelet adhesion at all (CB4(III)-2, -3 and -5). Using the recombinant leech anti-platelet protein (rLAPP), known to prevent both alpha2beta1 integrin- and von Willebrand factor (vWF)-binding to collagen, we observed almost complete inhibition of platelet adhesion to peptides CB4(III)-6 and -7. In solid-phase binding assays rLAPP bound to CB4(III)-6 and -7 and to CB4(III)-6/7, containing the peptide 6/7 overlap sequence, and not to any other peptide. Our results suggest that the overlap sequence GPP*GPRGGAGPP*GPEGGK (single-letter amino acid code, P* = hydroxyproline), corresponding to residues 523-540 of the alpha1(III) collagen chain, contains a binding site for rLAPP. Monoclonal antibodies (MoAbs) directed against the alpha2 subunit of integrin alpha2beta1 inhibited platelet adhesion to both CB4(III)-6 and -7 by about 50%, showing that the alpha2beta1-recognition site in this locality in alpha1(III)CB4 detected under static conditions is of sufficient affinity to withstand shear forces. Solid-phase binding studies indicated that vWF binds to CB4(III)-7 and to a lesser extent to CB4(III)-4. Furthermore, rLAPP competed with vWF in binding to CB4(III)-7. Our results indicate that residues 541-558 of the alpha1(III)-chain may contain one of the critical vWF-binding sites involved in the initial phase of platelet adhesion to collagen III. MoAbs against vWF (A1 and A3 domain) and glycoprotein (GP)Ib confirmed that vWF is involved in adhesion to CB4(III)-7 and showed that vWF is also involved in adhesion to CB4(III)-6 despite the absence of direct binding of vWF to the peptide. The existence of alpha2beta1-, vWF- and rLAPP-binding sites all in close proximity in alpha1(III)CB4 testifies to the importance of this locus in collagen III for its platelet reactivity.     

Endothelial cell cultures on fibrillar collagen: Partial reconstitution of the vessel wall and platelet adhesion

A new in vitro system has been developed in which a bilayer structure of the Internal (luminal) side of the vessel wall has been reconstituted. Platelet adhesion to the endothelial- and fibrillar collagen-coated surfaces had been measured differentially. The reconstitution was performed in standard 16.4-mm wells of multiwell tissue culture plates (Falcon) and three systems were tested: a) well bottoms were coated with fibrillar collagen - a model of the subendothelium with widespread endothelial denudation; b) preconfluent cultures of endothelial cells from human umbilical cord were grown on fibrillar collagen - a model of the endothelial and subendothelial bilayer with focal vessel wall injuries; c) confluent cultures of endothelial cells were grown on fibrillar collagen - a model of the endothelial and the subendothelial bilayer of the undamaged vessel wall. 1) The adhesion of gel-filtered human platelets to fibrillar collagen was measured by two independent methods using ⁵¹Cr-labeling of platelets or scanning electron microscopy. It was shown that the number of adherent platelets was a linear function of the number of platelets added into incubation mixture up to 1.5–2.4 × 10⁷ platelets per well. About 20% of the added platelets adhered to collagen. 2) The overall kinetics of platelet adhesion to fibrillar collagen was studied as well as the kinetics of platelet shape change and aggregate formation in the population of adherent platelets. Adhesion was maximal at about 40 min. As the incubation time increased, the ratio between different forms of adherent platelets changed: the percentage of spheres with pseudopods decreased and the percentage of spread platelets increased. At a steady state, about 50 % of the adherent platelets were spheres with pseudopods, 20% were spread platelets, 30% formed small aggregates, and thrombi were absent. 3) Inhibition of platelet-collagen interaction was demonstrated by adding aspirin and platelet-free serum to the system. 4) It was found that endothelial cells grown on fibrillar collagen in confluent and preconfluent cultures were nonadhesive for platelets. In preconfluent cultures platelets selectively adhered to collagen-coated gaps; endothelial cells did not inhibit this interaction. 5) The proposed system can be used for the study of platelet interactions with vessel wall constituents, damage repair, and for screening of natural or artificial modulators of adhesion.     

Biochemical characterization of PECAM-1 (CD31 antigen) on human platelets.

The platelet plasma membrane expresses several membrane glycoproteins with a high molecular weight. In this study we have investigated the properties of the CD31 antigen on platelets and endothelial cells using the monoclonal antibody (MoAb) RUU-PL 7E8. Comparative studies revealed that the CD31 antigen, PECAM-1 and endoCAM are the same protein. The CD31 antigen was immunoprecipitated with a molecular mass of 125 kDa nonreduced and 135 kDa reduced from Nonidet-P40 lysates of surface labeled human platelets. The relative position in two-dimensional nonreduced/reduced SDS-PAGE and IEF-PAGE, compared to other glycoproteins of similar molecular weight, was elucidated. The position of the CD31 antigen was clearly distinct from the position of the platelet membrane glycoproteins Ia, Ib, IIa, IIb, IIIa and the granule membrane protein GMP-140. Native resting platelets bound 7,760 +/- 1,670 molecules/platelet, whereas thrombin-stimulated platelets bound 14,500 +/- 3,790 molecules/platelet. Immunoelectron microscopy revealed the presence of the CD31 antigen on the membrane of both resting and thrombin-activated platelets. Immunofluorescence studies showed the presence of the CD31 antigen in the membrane of endothelial cells on sites of cell-cell contact, suggesting that the CD31 antigen might be involved in cell-cell interaction. In functional studies, MoAb RUU-PL 7E8 did not inhibit platelet aggregation, platelet adherence to the extracellular matrix of endothelial cells and purified collagen fibrils under flow conditions, nor was any influence found on endothelial cell detachment and growth.     

The effect of pepsin solubilization on platelet aggregation by types I and III collagens

The effect of pepsin solubilization on the platelet aggregating activity of type I collagen and type III collagen was examined. Pepsin-digested type I collagen was unable to initiate platelet aggregation in either soluble form or as pre-formed fibrils. In contrast, pepsin-digested type III collagen was active in soluble form or as preformed fibrils. Mixtures of type I and type III collagen were assayed for platelet aggregating activity. In soluble form, these mixtures demonstrated elevated activity with increasing type III concentration. When the mixtures were tested as pre-formed fibrils, the rate of aggregation was relatively constant with the combination 75% type III and 25% type I manifesting the highest activity. The lag time for onset of aggregation was also minimized for this same type III/type I ratio. The combinations of the two collagen types formed fibrils which reflected the amounts of types I and III collagens in solution.     

Magnesium maintains endothelial integrity, up-regulates proteolysis of ultra-large von Willebrand factor, and reduces platelet aggregation under flow conditions

Mg (++) regulates endothelial functions and has anti-inflammatory effects. Its effects on thrombosis have been demonstrated, but the mechanism remains poorly understood. We investigated the roles of MgSO(4) in regulating the release and cleavage of the prothrombotic ultra-large (UL) von Willebrand factor (VWF) and VWF-mediated platelet adhesion and aggregation. Washed platelets were perfused over cultured endothelial cells from human umbilical cord veins under a shear stress of 2.5 dyn/cm(2). Release and cleavage of ULVWF by ADAMTS-13 was measured in the absence or presence of physiological or therapeutic levels of MgSO(4). Whole blood or plasma-free reconstituted blood was perfused over immobilized collagen to measure the effect of MgSO(4) on platelet adhesion and aggregation. Also studied were the effects of MgSO(4) on ristocetin-induced platelet aggregation andVWF-collagen interaction. Maintenance of endothelial integrity required physiological levels of MgSO(4), but exogenous MgSO(4) showed no additional benefits. Exogenous MgSO(4) significantly enhanced the cleavage of the newly released ULVWF strings by ADAMTS-13 and markedly reduced platelet aggregation on immobilized collagen under flow conditions. This effect is likely to be mediated through VWF as Mg(++) partially inhibited ristocetin-induced platelet aggregation and VWF binding to collagen. MgSO(4) is critical for maintaining endothelial integrity and regulates ULVWF proteolysis and aggregation under flow conditions. These results provide a new insight into additional mechanisms involved with magnesium therapy.     

A monoclonal antibody to the human platelet glycoprotein IIb/IIIa complex induces platelet activation

The platelet glycoprotein (GP) IIb/IIIa complex functions as the receptor for fibrinogen on activated platelets. The effects of two anti-GPIIb/IIIa monoclonal antibodies on platelet function were studied. These antibodies, 6C9 and C17, recognized different epitopes, which were exclusively present on the undissociated GPIIb/IIIa complex. Whereas C17 inhibited the binding of fibrinogen to platelets and platelet aggregation induced by adenosine diphosphate (ADP) or collagen, 6C9 caused irreversible aggregation of platelets, both in the presence and absence of extracellular fibrinogen. When incubated with unstirred (non-aggregating) platelets, 6C9 induced release of alpha and dense granule-constituents as well as binding of 125I-fibrinogen to platelets. The latter was evidently mediated in part by platelet-derived ADP, since it was inhibited to a large extent by apyrase, the ADP-hydrolyzing enzyme. F(ab')2 fragments of 6C9 did not induce platelet-release reactions but caused (slow) aggregation of platelets in the presence of extracellular fibrinogen. These results indicate that binding of an antibody to a specific site on the platelet GPIIb/IIIa complex may cause fibrinogen-mediated aggregation. The Fc part of the platelet-bound antibody appears to be involved in the induction of platelet release.     

Multicolor flow cytometry for evaluation of platelet surface antigens and activation markers

Introduction

Flow cytometry allows the analysis of multiple antigens in a single tube at a single cell level. We present a rapid and sensitive two tube flow cytometric protocol for the detection of multiple platelet antigens and activation markers gated on a pure platelet population.

Materials and methods

The presence of platelet specific antigens was analyzed in citrated whole blood of normal platelets and from patients diagnosed with platelet abnormalities. Quiescent platelets as well as stimulated platelets were analyzed using a gating strategy based on ubiquitously expressed platelet membrane markers.A ubiquitously expressed platelet marker was combined with antibodies against the activated alpha2b-beta3 (PAC-1), Lysosomal Activated Membrane Protein (CD63) and P-selectin (CD62P).

Results

We were able to detect the platelet antigens CD36, CD41, CD42a, CD42b and CD61 in one single tube. Our approach allowed the single tube determination of PAC-1, CD63 and CD62P after activation of platelets by thrombin, collagen, ADP and PAR-1, and determination of platelet abnormalities.

Conclusions

Our two tube multi-parameter screening protocol is suited for the analysis of platelet antigens expressed on quiescent and activated platelets and allows the detection of aberrancies as found in blood of patients with thrombocytopathy such as Glanzmann Thrombasthenia, storage pool disease with diminished granule content and patients treated with clopidogrel and acetylsalicylic acid.