Immunocytochemical localization of fibrinogen on washed human platelets. Lack of requirement for fibrinogen during adenosine diphosphate-induced responses and enhanced fibrinogen binding in a medium with low calcium levels

The association of fibrinogen with washed human platelets was examined by immunocytochemistry during aggregation induced by adenosine diphosphate (ADP) and during deaggregation. The platelets were suspended either in a medium containing 2 mmol/L Ca2+ or in a medium containing no added Ca2+ (20 mumol/L Ca2+). Platelets were fixed at several times during aggregation and deaggregation, embedded in Lowicryl K4M, sectioned, incubated with goat antihuman fibrinogen, washed, reacted with gold-labeled antigoat IgG, and prepared for electron microscopy. To determine whether the method detected fibrinogen associated with the platelets, the platelets were pretreated with chymotrypsin (10 U/mL) and aggregated by fibrinogen; gold particles were apparent not only in the alpha granules but on the platelet surface and between adherent platelets as well. In the medium with 2 mmol/L Ca2+, ADP caused extensive aggregation of normal platelets in the presence of fibrinogen (0.4 mg/mL), and gold particles were evident between the adherent platelets and on the platelet surface; when the platelets deaggregated, gold was no longer present on the surface. In a medium without added Ca2+, ADP caused extensive aggregation in the presence of fibrinogen, and large numbers of gold particles were on the platelet surface and even more between adherent platelets. In this medium, the platelets did not deaggregate, and by five minutes, the granules appeared to be swollen or fused. In the absence of external fibrinogen, ADP caused the formation of small aggregates, and fibrinogen was not detected between adherent platelets. Thus, the association of fibrinogen with the platelet surface enhances platelet aggregation but is not essential for the ADP-induced formation of small aggregates. The association of fibrinogen with platelets is greater under conditions in which platelets release their granule contents and do not deaggregate because both endogenous and exogenous fibrinogen take part in aggregation.     

Fibrinogen-independent aggregation and deaggregation of human platelets: studies in two afibrinogenemic patients

Platelets from two afibrinogenemic patients were used to determine whether fibrinogen is essential for platelet aggregation and to examine whether released fibrinogen contributes to the stabilization of platelet aggregates when platelets have been induced to aggregate and release their granule contents by stimulation with thrombin. The addition of adenosine diphosphate (ADP) to platelet-rich plasma (PRP) or to suspensions of washed platelets from the afibrinogenemic patients caused the formation of small aggregates, which was either not inhibited or only slightly inhibited by the F(ab')2 fragments of an antibody to fibrinogen but was inhibited by an antibody (10E5) to glycoprotein IIb/IIIa. Thus there is a component of ADP-induced platelet aggregation that is not dependent on fibrinogen or other plasma proteins but is dependent on glycoprotein IIb/IIIa. There was little difference in the extent of aggregation and the release of granule contents of normal and afibrinogenemic platelets in response to the release-inducing agents collagen, platelet-activating factor (PAF), sodium arachidonate, or thrombin. With normal or afibrinogenemic platelets, aggregation by thrombin (0.2 U/mL or higher) was not inhibited by the F(ab')2 fragments of an antibody to human fibrinogen. Deaggregation by combinations of inhibitors of platelets aggregated by 1 U/mL thrombin showed no difference between platelets from afibrinogenemic and control subjects, indicating that released fibrinogen does not make a major contribution to the stabilization of platelet aggregates formed by thrombin stimulation.     

High molecular weight kininogen inhibits thrombin-induced platelet aggregation and cleavage of aggregin by inhibiting binding of thrombin to platelets.

In this study we show that high molecular weight kininogen (HK) inhibited alpha-thrombin-induced aggregation of human platelets in a dose-dependent manner with complete inhibition occurring at plasma concentration (0.67 mumol/L) of HK. HK (0.67 mumol/L) also completely inhibited thrombin-induced cleavage of aggregin (Mr = 100 Kd), a surface membrane protein that mediates adenosine diphosphate (ADP)-induced shape change, aggregation, and fibrinogen binding. The inhibition of HK was specific for alpha- and gamma-thrombin-induced platelet aggregation, because HK did not inhibit platelet aggregation induced by ADP, collagen, calcium ionophore (A23187), phorbol myristate acetate (PMA), PMA + A23187, or 9,11-methano derivative of prostaglandin H2 (U46619). These effects were explained by the ability of HK, at physiologic concentration, to completely inhibit binding of 125I-alpha-thrombin to washed platelets. As a result of this action of HK, this plasma protein also completely inhibited thrombin-induced secretion of adenosine triphosphate, blocked intracellular rise in Ca2+ in platelets exposed to alpha- and gamma-thrombin, inhibited thrombin-induced platelet shape change, and blocked the ability of thrombin to antagonize the increase in intracellular cyclic adenosine monophosphate (cAMP) levels induced by iloprost. Because elevation of cAMP is known to inhibit binding of thrombin to platelets, we established that HK did not increase the intracellular concentration of platelet cAMP. Finally, HK did not inhibit enzymatic activity of thrombin. To study the role of HK in the plasma environment, we used gamma-thrombin to avoid fibrin formation by alpha-thrombin. Platelet aggregation induced by gamma-thrombin was also inhibited by HK in a dose-dependent manner. The EC50 (concentration to produce 50% of the maximum rate of aggregation) of gamma-thrombin for washed platelets was 7 nmol/L and increased to 102 nmol/L when platelets were suspended in normal human plasma. The EC50 for platelet aggregation induced by alpha-thrombin in plasma deficient in total kininogen was 40 nmol/L. When supplemented with HK at plasma concentration (0.67 mumol/L), the EC50 increased to 90 nmol/L, a value similar to that for normal human plasma. These results indicate that (1) HK inhibits thrombin-induced platelet aggregation and cleavage of aggregin by inhibiting binding of thrombin to platelets; (2) HK is a specific inhibitor of platelet aggregation induced by alpha- and gamma-thrombin; and (3) HK plays a role in modulating platelet aggregation stimulated by alpha-thrombin in plasma.     

Platelet aggregation occurs in congenital afibrinogenaemia despite the absence of fibrinogen or its fragments in plasma and platelets, as demonstrated by immunoenzymology

Platelet aggregation of an afibrinogenaemic patient's platelet rich plasma (PRP) was greatly decreased when ADP was used for stimulation. In the presence of collagen or arachidonic acid the changes in light transmission recorded during platelet aggregation of patient's PRP were similar to those observed with normal PRP but the size of aggregates appeared to be smaller in comparison with those observed with normal platelets. In addition, thrombin-induced aggregation of washed platelets was similar to normal platelets. The interpretation was made possible because the fibrinogen level in plasma and in platelets was found to be almost nil as demonstrated by both an Elisa procedure described here and the determination of fibrinopeptide A (fpA). Furthermore, fibrinogen fragments, which could result from abnormal synthesis and therefore replace fibrinogen in platelet aggregation, were undetectable by immunological analysis using specific antibodies against A alpha, B beta and gamma chains and 10 different monoclonal antibodies against fibrin degradation products.     

Original Article: Intracellular Ca(2+) Mobilization and Aggregatory Response to ADP and Thrombin in Aged Rat Platelets

We previously reported that thrombin-induced Ca(2+) mobilization was enhanced in aged rat platelets. Since Ca(2+) mobilization in platelets is believed to be closely associated with platelet activation, we examined Ca(2+) mobilization and the aggregatory response to ADP and thrombin in young (3 months) and aged (24 months) rat platelets. Blood levels of fibrinogen and Ca(2+) in aged rats were higher than those in young rats. ADP-induced platelet aggregation in aged rats was significantly enhanced in platelet rich plasma and in washed platelet suspension, suggesting that age-associated hyperaggregability to ADP is attributable to changes in platelets themselves. On the other hand, thrombin (0.03-0.3 unit/ml)-induced aggregation in washed platelet suspension from aged rats was comparable to that from young rats. But, thrombin (0.3 unit/ml)-induced intracellular Ca(2+)mobilization was enhanced in aged rat platelets in the presence of extracellular Ca(2+). Likewise, ADP-induced Ca(2+) mobilization was enhanced in aged rat platelets. These results suggest that enhanced Ca(2+) mobilization in aged rat platelets is associated with hyperaggregability to ADP but not to thrombin.     

Recombinant factor VIIa restores aggregation of alphaIIbbeta3-deficient platelets via tissue factor-independent fibrin generation

Recombinant factor VIIa (rFVIIa) is a safe and effective prohemostatic drug for patients with Glanzmann thrombasthenia (GT). However, the mechanism of action of rFVIIa in these patients is still unclear. Although patients with GT are characterized by a complete absence of platelet aggregation to a variety of agonists, it has been shown that GT platelets are able to form aggregates, provided polymerizing fibrin is present. We studied the effect of rFVIIa-mediated fibrin formation on aggregation of alphaIIbbeta3-deficient platelets. When washed platelets from GT patients or platelets from healthy volunteers treated with an arginyl-glycyl-aspartyl-containing peptide were activated with collagen in the presence of rFVIIa and purified coagulation factors X, II, and fibrinogen, complete aggregation occurred after a lag phase. Fibrin generation proceeded via rFVIIa-mediated thrombin generation on the activated platelet surface independently of tissue factor. Electron microscopic analysis of alphaIIbbeta3-independent platelet aggregates showed a densely packed structure suggestive of a true platelet-fibrin interaction and not via trapping of platelets into a fibrin network. Also, rFVIIa-mediated alphaIIbbeta3-independent aggregation was demonstrated under conditions of flow using a collagen-coated surface. In conclusion, the efficacy of rFVIIa in GT patients might be explained by induction of alphaIIbbeta3-independent platelet aggregation, which compensates the lack of alphaIIbbeta3-dependent aggregation.     

Protease and cyclooxygenase inhibitors synergistically prevent activation of human platelets.

Thrombin induces platelet aggregation and formation of a fibrin clot in platelet-rich plasma; leupeptin, a protease inhibitor, partially inhibits platelet aggregation, but it does not inhibit fibrin clot formation. Indomethacin does not inhibit either thrombin-induced platelet aggregation or fibrin clot formation. However, when the two drugs are given together, a synergistic inhibition of thrombin-induced platelet aggregation occurs, while fibrin clot formation remains unaffected. Thrombin-induced stimulation of the release of serotonin in washed human platelets is also synergistically inhibited by the combined actions of leupeptin and indomethacin. Thrombin and collagen, added simultaneously, induce full platelet aggregation and release of serotonin. Neither leupeptin nor indomethacin inhibits platelet responses elicited by both agonists; however, when leupeptin and indomethacin are given together, a synergistic inhibition of thrombin- and collagen-induced response is observed. These findings might be relevant in prophylaxis and treatment of thromboembolic disease.     

Plasmin inhibition of thrombin-induced platelet aggregation.

The effects of plasmin treatment upon washed human platelets were studied in an attempt to elucidate the mechanisms underlying thrombin-induced platelet aggregation. At calcium concentrations of 10-20 muM, PLASMIN (0.2 CTA U/ml) inhibited thrombin-induced aggregation almost completely, but did not diminish the thrombin-induced release of adenine nucleotides, 5-hydroxytryptamine, or calcium. Increasing the calcium concentration partially antagonized plasmin's inhibition of aggregation. Studies utilizing calcium chelators and the Kunitz soybean trypsin inhibitor (SBTI) as a plasmin inhibitor indicated that in order to achieve maximal block of aggregation, plasmin must act upon a substrate made fully available only after an initial thrombin-platelet interaction has taken place. Moreover, the time course of this inhibition parallels the time course of the thrombin-induced release reaction. Plasmin inhibition of aggregation could not be mimicked by exposing the platelets to proteolytic digests of fibrinogen at concentrations as high as 17% total platelet protein. Nor could inhibitory activity be recovered from supernatants of plasmin-treated platelets, upon centrifugation and treatment with SBTI. With the use of a "cold initiation" technique, the release by thrombin of 46.7 plus or minus 6.7 (mean plus or minus SEM) mu-g of fibrinogen immunological equivalents per mg platelet protein could be demonstrated. Platelets in which thrombin-induced aggregation was abolished by plasmin treatment (and the plasmin subsequently inactivated by STBI) aggregated normally upon addition of as little as 10 mu-g human plasma fibrinogen per mg platelet protein. It is concluded that plasmin inhibition of aggregation most likely results from its attack upon a protein that is released or becomes fully available subsequent to interaction of thrombin with a platelet receptor mediating release. The results of this study are consistent with a cofactor role for fibrinogen in the aggregation of human platelets by thrombin.     

Dissociation of Clot Retraction from Platelet Granule Fusion and Degranulation: an Ultrastructural Study of Reptilase—Human Platelet-rich Plasma Clots

Human platelet-rich plasma clots, formed with Reptilase, do not retract. Electron microscopy of such a clot reveals platelets of normal shape and ultrastructural features surrounded by fibrin. When ADP is added before Reptilase, the clot strongly retracts. A sequential ultrastructural study of this process shows that, before visible fibrin formation, the platelets form small clusters and show shape change, granule centralization and pseudopod formation. Upon immobilization of the platelets by fibrin, the pseudopods develop into large cytoplasmatic protrusions, which allow cell contact. During the retraction process, the platelet granules remain intact; some granule fusion only becomes apparent in fully retracted clots. When Thrombofax is added to platelet-rich plasma before Reptilase, the clots formed also retract. With this aggregation inducer, granule fusion occurs earlier and in more platelets. Platelet pseudopod enlargement and fibrin concentration around the platelet mass are similar to that in ADP-treated samples. Inhibitors of granule fusion and secretion (suprofen, indomethacin) do not modify ADP-Reptilase nor Thrombofax-Reptilase clot retraction but reduce the incidence of granule fusion in Thrombofax-Reptilase clots. Retraction of Thrombofax-Reptilase clots is unaffected by concentrations of apyrase which completely block ADP-Reptilase clot retraction. Prostaglandin E1, papaverine and amitryptiline inhibit both ADP-and Thrombofax-Reptilase clot retraction, platelet pseudopod formation and cell-to-cell adhesion. These findings suggest that interaction of fibrin with the mass of fused granules (granulomere) or platelet secretion are not responsible for clot retraction. Rather, contraction around adhesion sites formed by cytoplasmic protrusions from adjacent platelets would seem to be involved.     

The use of the synthetic peptide, Gly-Pro-Arg-Pro, in the preparation of thrombin-degranulated rabbit platelets

The method for preparing thrombin-degranulated platelets has been modified to avoid the use of plasmin or successive treatments with small amounts of thrombin, while still achieving more than 90% release of platelet amine storage granule contents. It was necessary to prevent the fibrinogen released from the platelets during thrombin treatment from forming an insoluble fibrin mesh that could trap the platelets and hinder their deaggregation. To accomplish this we have treated rabbit platelets with 0.73 U/ml of thrombin for 1 min in the presence of the synthetic peptide, Gly-Pro-Arg-Pro, which prevents the polymerization of fibrin molecules. We have demonstrated that it also prevents 125I, initially added as 125I-fibrinogen, from associating with the platelets in a form that was not removed by centrifuging and washing during the preparation of thrombin-degranulated platelets, and we infer that products formed from the fibrinogen released from the platelets would also be prevented from associating with them. Thrombin-degranulated platelets prepared by this method have lost 92% of their granule contents and they can be washed and resuspended. These platelets aggregate normally upon stimulation with thrombin, adenosine diphosphate (ADP), or arachidonate. Thus, Gly-Pro-Arg-Pro is useful in preparing thrombin-degranulated platelets for studying platelet reactions without the complicating effects of released materials such a ADP and fibrinogen.     

Endothelium-derived relaxing factor inhibits thrombin-induced platelet aggregation by inhibiting platelet phospholipase C.

Endothelium-derived relaxing factor (EDRF) inhibits platelet function, but the mechanism underlying this inhibitory effect is not known. To examine this, cultured acetylsalicylic acid (ASA)-treated endothelial cells (EC) from bovine aorta (BAEC) or from human umbilical vein (HUVEC) were incubated with washed, ASA-treated human platelets. Incubation of platelets with either BAEC or HUVEC resulted in inhibition of thrombin-induced platelet aggregation that was dependent on the number of EC added. This effect was potentiated by superoxide dismutase and reversed by treating EC with NG-nitro-L-arginine or by treating platelets with methylene blue, indicating that the inhibition of platelet aggregation was due to the release of EDRF by EC. EC significantly blocked the thrombin stimulated breakdown of phosphatidylinositol-4,5-bisphosphate (PIP2) and the production of phosphatidic acid in [32P]orthophosphate-labeled platelets and of inositol trisphosphate in [3H]myoinositol-labeled platelets. In addition, the thrombin-mediated activation of protein kinase C (PKC) and phosphorylation of myosin light chain were inhibited in the presence of EC. Finally, thrombin stimulated an increase in cytosolic ionized calcium concentration ([Ca2+]i) in fura2-loaded platelets that was abolished by concentrations of EC which also blocked thrombin-induced aggregation. These data indicate that EDRF blocks thrombin-induced platelet aggregation by inhibiting the activation of PIP2-specific phospholipase C and thereby suppressing the consequent activation of PKC and the mobilization of [Ca2+]i.     

Thrombin interaction with human platelets. Potentiation of thrombin-induced aggregation and release by inactivated thrombin

The possibility that thrombin acts on platelets by a mechanism other than proteolysis was investigated. The proteolytic site of thrombin was modified with phenylmethylsulfonyl fluoride (PMSF). This modified enzyme did not induce platelet aggregation or the platelet release reaction. Platelets were then incubated with the inactivated enzyme (PMS-thrombin) and later with active thrombin. In this sequence of incubation, PMS-thrombin enhanced not only platelet aggregation induced by active thrombin but also the thrombin-induced release reaction. Preincubation with PMS-thrombin was essential for this enhancement as the inhibited enzyme did not affect aggregation if added after active thrombin. The effect of PMS-thrombin was limited to thrombin-induced reactions of the platelet. The inhibited enzyme had no effect on aggregation induced by adenosine diphosphate or collagen, or on thrombin-induced coagulation of fibrinogen. These results suggest (1) that both proteolytic and binding sites for thrombin are present on the human platelet plasma membrane; and (2) that interaction of thrombin with the binding site potentiates the activity of the proteolytic site.     

Thrombospondin promotes platelet aggregation

Thrombospondin (TSP), isolated from human platelets, promotes aggregation of both nonstimulated platelets and platelets stimulated with thrombin or ADP. The TSP-promoted aggregation is specific since a monoclonal antibody against TSP inhibits the effect of exogenously added TSP and inhibits thrombin-induced platelet aggregation in the absence of added TSP. Several lines of evidence suggest that TSP mediates its effect on aggregation of nonstimulated and stimulated platelets through different platelet-surface receptor systems. The TSP- promoted aggregation of nonstimulated platelets was inhibited by a monoclonal antibody to platelet glycoprotein IV (GPIV), but not by a monoclonal antibody to the fibrinogen receptor, GPIIb-IIIa. In contrast, the antibody to GPIIb-IIIa totally inhibited the TSP- potentiated aggregation of thrombin-stimulated platelets, whereas the antibody to GPIV has no effect. Thus, these studies suggest that TSP promotes platelet aggregation by at least two mechanisms--one dependent on and one independent of the platelet fibrinogen receptor system.     

Concentration effects of platelets, fibrinogen and thrombin on platelet aggregation and fibrin clotting

The effects of varying concentrations of platelets, fibrinogen and thrombin on platelet aggregation and on fibrin clotting were investigated. The results indicated that a threshold thrombin to platelet concentration ratio may be required to cause platelet activation. Above the threshold ratio, platelets exhibited properties which enhanced thrombin action in causing aggregation and fibrin clotting. At T/P ratios below the threshold level, the presence of platelets reduced thrombin activity, in other words, platelets exerted an antithrombin action. Fibrinogen at low concentrations (0.02-1.5 mg/ml) enhanced platelet aggregation induced by thrombin; whereas, at high concentrations of fibrinogen (2.0-4.0 mg/ml), aggregation was markedly inhibited. Continuous mixing of samples of paltelets and fibrinogen at physiological concentrations with thrombin at low concentrations (less than 2.0 U/ml) resulted in platelet aggregation. On the other hand, fibrin clots formed in samples without mixing or with high thrombin concentrations (greater than or equal to 5.0 U/ml). These results suggested that the quantitative relationships between platelets, fibrinogen and thrombin, and the presence or absence of cell contact may be important factors in determining the overall hemostasis.     

Impaired platelet responses to thrombin and collagen in AKT-1-deficient mice

We investigated the role of Akt-1, one of the major downstream effectors of phosphoinositide 3-kinase (PI3K), in platelet function using mice in which the gene for Akt-1 had been inactivated. Using ex vivo techniques, we showed that Akt-1-deficient mice exhibited impaired platelet aggregation and spreading in response to various agonists. These differences were most apparent in platelets activated with low concentrations of thrombin. Although Akt-1 is not the predominant Akt isoform in mouse platelets, its absence diminished the amount of total phospho-Akt and inhibited increases in intracellular Ca(2+) concentration in response to thrombin. Moreover, thrombin-induced platelet alpha-granule release as well as release of adenosine triphosphate from dense granules was also defective in Akt-1-null platelets. Although the absence of Akt-1 did not influence expression of the major platelet receptors for thrombin and collagen, fibrinogen binding in response to these agonists was significantly reduced. As a consequence of impaired alpha(IIb)beta(3) activation and platelet aggregation, Akt-1 null mice showed significantly longer bleeding times than wild-type mice.     

Effect of neutrophil adhesion on the size of aggregates formed by agonist-activated platelets

In this study we have investigated the effect of human neutrophil on agonist-induced platelet aggregation by using the laser-light scattering method that can detect a two-phase process, formation of small aggregates followed by large aggregate formation. When nonstimulated neutrophils were added to agonist-stimulated platelet-rich plasma (PRP), the large platelet aggregates were decreased and the small ones were increased by using either collagen, thrombin or ADP as agonist. Scanning-electron microscopic observation showed marked adhesion of neutrophil to aggregated platelets. The supernatant from neutrophils cell lysate (neutrophil supernatant) showed inhibitory effect similar to that with intact neutrophils, suggesting that the inhibitory effect by neutrophils was due to soluble component(s) including proteases released from neutrophils adhered to activated platelets. We have examined the effect of inhibition of a major released protease, elastase. The addition of its potent inhibitor elafin to intact neutrophils or the neutrophil supernatant changed their antiaggregating activity. The treatment of platelets with genistein, an inhibitor of protein tyrosine kinase, decreased agonist-induced large aggregates and increased small ones, suggesting that certain protein tyrosine kinase would be involved in the transition from small to large platelet aggregates. It was also shown that the tyrosine phosphorylation induced by agonist stimulation of several high molecular-weight proteins of platelets was inhibited by coincubation with neutrophils, concurrent with increases in smaller phosphorylated proteins. In washed platelets, coincubation with neutrophils resulted in reduced formation of large aggregates when stimulated with collagen or thrombin and repressed agonist-induced activation of tyrosine protein kinases (Syk, Lyn, Src, and Pyk2), but not thrombin-induced ERK and p38 MAP kinase. These results suggest that the cleavage of platelet membrane glycoproteins at least in part by elastase which was released from neutrophils, is involved in the inhibition of the transition from small to large platelet aggregates.     

Effect of neutrophil adhesion on the size of aggregates formed by agonist-activated platelets

In this study we have investigated the effect of human neutrophil on agonist-induced platelet aggregation by using the laser-light scattering method that can detect a two-phase process, formation of small aggregates followed by large aggregate formation. When nonstimulated neutrophils were added to agonist-stimulated platelet-rich plasma (PRP), the large platelet aggregates were decreased and the small ones were increased by using either collagen, thrombin or ADP as agonist. Scanning-electron microscopic observation showed marked adhesion of neutrophil to aggregated platelets. The supernatant from neutrophils cell lysate (neutrophil supernatant) showed inhibitory effect similar to that with intact neutrophils, suggesting that the inhibitory effect by neutrophils was due to soluble component(s) including proteases released from neutrophils adhered to activated platelets. We have examined the effect of inhibition of a major released protease, elastase. The addition of its potent inhibitor elafin to intact neutrophils or the neutrophil supernatant changed their antiaggregating activity. The treatment of platelets with genistein, an inhibitor of protein tyrosine kinase, decreased agonist-induced large aggregates and increased small ones, suggesting that certain protein tyrosine kinase would be involved in the transition from small to large platelet aggregates. It was also shown that the tyrosine phosphorylation induced by agonist stimulation of several high molecular-weight proteins of platelets was inhibited by coincubation with neutrophils, concurrent with increases in smaller phosphorylated proteins. In washed platelets, coincubation with neutrophils resulted in reduced formation of large aggregates when stimulated with collagen or thrombin and repressed agonist-induced activation of tyrosine protein kinases (Syk, Lyn, Src, and Pyk2), but not thrombin-induced ERK and p38 MAP kinase. These results suggest that the cleavage of platelet membrane glycoproteins at least in part by elastase which was released from neutrophils, is involved in the inhibition of the transition from small to large platelet aggregates.     

Inhibition of some activities of thrombin by a collagen-derived octapeptide

The effect of a collagen-derived octapeptide on some properties of thrombin is presented. This peptide provoked a dose- and time-dependent prolongation of the thrombin-induced plasma and fibrinogen clotting time and inhibited the polymerization of fibrin generated from fibrinogen by thrombin. It did not affect the polymerization of fibrin monomers; it was also without effect on the coagulation of plasma or fibrinogen by reptilase. The prolongation of the fibrinogen clotting time depended on the duration of the incubation of thrombin and the octapeptide and not on the duration of the incubation of fibrinogen and the octapeptide. The inhibition was therefore ascribed to an interference with thrombin, rather than with fibrinogen. A preincubation of the octapeptide with thrombin resulted in an inhibition of the thrombin-induced platelet aggregation. The effect of the octapeptide on thrombin has been related to the presence of positively and negatively charged groups, because uncharged analogue sequences were without effect on these activities of thrombin.     

Enzymatic Basis for Platelet Aggregation and Release: The Significance of the ''Platelet Atmosphere'' and the Relationship between Platelet Function and Blood Coagulation

Summary . Blood coagulation and platelet reactions such as aggregation and release are both essential to haemostasis and, although relationships between these two processes have been demonstrated, they have been regarded as different phenomena. The results reported here show that the two are inseparable, and that platelet aggregation and release are dependent on the ‘plasmatic atmosphere’ of coagulation factors surrounding platelets. Test systems were developed for studying platelets in plasma (Han & Ardlie, 1973) and in artificial media. When coagulation factors were removed from platelets by washing, only slight reversible aggregation occurred upon the addition of ADP and fibrinogen. Trace amounts of thrombin restored aggregation and TAMe completely inhibited aggregation. Irreversible aggregation and the release reaction of platelets were shown to be dependent on the generation of thrombin by the interaction of clotting factors on the platelet surface. Polymerizing fibrin caused irreversible aggregation and, conversely, inhibitors of fibrin polymerization prevented irreversible aggregation. Irreversible aggregates were insoluble in 5 M urea and 1% monochloroacetic acid suggesting involvement of factor XIII in this aspect of aggregation. It is proposed that aggregation of platelets by ADP is mediated initially by thrombin-fibrinogen complexes between adjacent adhering platelets. It is also proposed that the nature of the bond between platelets changes when the enzymatic phase of the thrombin—fibrinogen reaction is followed by the polymerization phase, and aggregation then becomes irreversible under the influence of factor XIII, activated by thrombin. Thrombin action also results in the release of platelet constituents. A scheme for haemostasis which emerges from this unification of platelet reactions and blood coagulation is presented in Fig 15, and possible ways in which various other platelet and plasma factors may be involved in haemostasis are briefly discussed.     

Inhibition of fibrinogen binding to human platelets by the tetrapeptide glycyl-L-prolyl-L-arginyl-L-proline.

The role of fibrinogen as a cofactor in platelet aggregation is mediated by its binding to platelet receptors that are induced by stimuli such as ADP. In the present study, we demonstrate that the tetrapeptide glycyl-L-prolyl-L-arginyl-L-proline inhibits the interaction of fibrinogen with its platelet receptor. The primary effect of the peptide was on the extent rather than on the rate of fibrinogen binding. Significant inhibition occurred at a 1:1 molar ratio of peptide to fibrinogen and reached maximal levels at 100:1 ratio. The inhibition was dependent upon fibrinogen concentration and occurred in the presence of calcium or magnesium. The peptide inhibited the binding of fibrinogen to platelets with exposed receptors, suggesting that it interfered directly with the ligand-receptor interaction. Fibrinogen binding supported by epinephrine and thrombin as well as ADP was inhibited by the peptide. Fibrinogen-dependent aggregation of washed platelets by ADP was abolished by a 30-fold molar excess of the peptide. The tetrapeptide is an analog of the amino-terminal sequence of the alpha-chain of fibrin and has been shown to inhibit fibrin polymerization [Laudano, A. P. & Doolittle, R. F. (1978) Proc. Natl. Acad. Sci. USA 75, 3085-3089]. A peptide corresponding to the natural sequence, glycyl-L-prolyl-L-arginyl-L-valyl-L-valine, was also capable of inhibiting fibrinogen binding to the platelet. These results suggest that common structural features within fibrinogen may serve a dual function by permitting the molecule to participate in both platelet aggregation and fibrin formation.