Platelet P-selectin plays an important role in arterial thrombogenesis by forming large stable platelet-leukocyte aggregates

OBJECTIVES: We investigated the role of P-selectin in arterial thrombogenesis by forming large stable platelet-leukocyte aggregates. BACKGROUND: Plaque rupture followed by thrombus formation is a fundamental pathophysiology of acute coronary syndromes. Although the adhesive interaction between platelets and leukocytes via P-selectin is known to mediate platelet-rich thrombi, the true function of P-selectin in thrombus formation in vivo is unknown. METHODS: In wild-type (P(+/+)) and P-selectin-deficient (P(-/-)) mice with ferric chloride (FeCl(3))-induced carotid arterial thrombosis model, we measured in vivo platelet P-selectin expression and adenosine diphosphate (ADP)-induced ex vivo platelet aggregation. We also measured ex vivo ADP-induced whole blood aggregations and their size distribution by flow cytometry. RESULTS: Time to thrombotic occlusion was longer in P(-/-) mice than in P(+/+) mice. Spontaneous reflow after total thrombotic occlusion was observed in 8 of 10 P(-/-) mice but not in any P(+/+) mice. ADP-induced ex vivo platelet aggregation was not different between the two groups. However, ADP-induced ex vivo whole blood aggregation was inhibited in P(-/-) mice compared to P(+/+) mice. FeCl(3) application increased in vivo expressions of platelet P-selectin in P(+/+) mice but not in P(-/-) mice. The number of leukocytes within thrombi was less in P(-/-) mice than in P(+/+) mice. In flow cytometric analysis of size distribution of ADP-induced whole blood aggregates, the number of large aggregates was less in P(-/-) mice than in P(+/+) mice. Using platelet and leukocyte fluorescence makers, the large aggregates were confirmed as platelet-leukocyte aggregates. CONCLUSIONS: Platelet P-selectin plays an important role in arterial thrombogenesis by forming large stable platelet-leukocyte aggregates.     

Activation of leukocytes in whole blood samples by N-formyl-methionyl-leucyl-phenylalanine (FMLP) enhances platelet aggregability but not platelet P-selectin exposure and adhesion to leukocytes

Adhesion of platelets to neutrophils and monocytes is believed to play an important role in intercellular communication. Evidence has been provided that such heterotypic cell-cell contacts via adhesion molecules may be directly involved in intercellular signal transduction as well as facilitate the action of soluble signal transmitters, e.g. cathepsin G, PAF or nitric oxide. With respect to platelet activation, stimulatory and inhibitory effects of leukocytes have been reported, and the results obtained seem to be influenced by the experimental conditions. We investigated the effect of leukocyte stimulation on platelet behaviour in samples of human citrated whole blood. Adding the chemotactic peptide FM LP, which stimulates neutrophils and monocytes but not lymphocytes and platelets, to stirred whole blood samples resulted in a significant enhancement ( P < 0.01) of spontaneous as well as ADP-induced platelet aggregation (25 vs 33% and 66 vs 69%, respectively). In contrast stirring-induced as well as ADP-induced increase of P-selectin exposure (33 and 107%, respectively) was not affected by FMLP. In unstirred whole blood samples, about 10 to 20% of neutrophils and monocytes had bound platelets to their surfaces, and the number of these heterotypic conjugates was enhanced about twofold during spontaneous platelet aggregation. Addition of FMLP significantly reduced the stirringinduced formation of platelet-neutrophil conjugates but not of platelet-monocyte conjugates. These results indicate that neutrophil and/or monocyte activation in whole blood may enhance platelet aggregation, but not secretion (CD62P exposure) and formation of heterotypic platelet-leukocyte conjugates.     

Platelet-platelet and platelet-leukocyte interactions induced by outer membrane vesicles from N. meningitidis

A large part of native meningococcal lipopolysaccharide (LPS), i.e., LPS integrated in the outer cell membrane, is released in the form of 'blebs' from surplus outer membrane material. In the present study we investigated the effects of purified outer membrane vesicles (OMVs) on blood platelet-platelet and platelet-leukocyte interactions. Citrated whole blood was stimulated in vitro with equal amounts (on a weight basis) of OMV-integrated LPS, purified LPS (P-LPS) from the same meningococcal strain and purified E. coli -LPS. The samples were analyzed by flow cytometry. Upon OMV stimulation platelet aggregation increased 2.1-fold, platelet degranulation 1.8-fold, (measured as CD62P expression), platelet binding to monocytes 2.6-fold, whereas platelet binding to granulocytes increased 2.8-fold. Also, the fraction of large heteroconjugates, i.e., large CD45-positive cell aggregates increased 15.7-fold compared to control. P-LPS and E. coli -LPS also significantly increased platelet aggregation and heteroconjugate formation but did not influence platelet degranulation and binding of platelets to leukocytes in whole blood. When using platelet-rich plasma (PRP), OMVs increased platelet aggregation 2.1-fold and CD62P expression 1.9-fold. P-LPS and E. coli -LPS also significantly increased platelet aggregation in PRP but did not influence platelet degranulation. None of the LPS preparations induced platelet microvesiculation, either in whole blood or in PRP. Conclusion: Meningococcal-derived OMVs as well as purified meningococcal LPS, contribute to increased platelet-platelet and platelet-leukocyte aggregation and may thus be of great importance in the development of microthrombosis and organ dysfunction related to fulminant meningococcal septicemia.     

Leukocyte count and leukocyte ecto-nucleotidase are major determinants of the effects of adenosine triphosphate and adenosine diphosphate on platelet aggregation in human blood

ADP induces platelet aggregation in human whole blood and platelet-rich plasma (PRP). ATP induces aggregation in whole blood only; this involves leukocytes and is mediated by ADP. Here we studied ATP- and ADP-induced aggregation in patients with raised leukocyte counts (mean 46.2?×?10³?leukocytes/µl). Platelet aggregation was measured by platelet counting. ATP, ADP and metabolites were measured by HPLC. Aggregation to ADP (1–10?µM) and ATP (10–100?µM) was markedly reduced, but to ATP (1000?µM) was enhanced (all p?<?0.001). Aggregation to ADP in PRP was normal. Increasing the leukocyte count in normal blood reproduced the findings in the patients. Adding leukocytes (either MNLs or PMNLs) to normal PRP enabled a response to ATP and caused marked inhibition of ADP-induced aggregation. Breakdown of ATP or ADP to AMP and adenosine in leukocyte-rich plasma was rapid (t_1/2?=?4?min) and far higher than in cell-free plasma or PRP. With ATP there was also formation of ADP, maximal at 4?min. The presence of the ectonucleotidase NTPDase1 (CD39) was demonstrated on MNLs (all of the monocytes and a proportion of the lymphocytes) and all PMNLs by flow cytometry. We conclude that leukocytes provide a means of dephosphorylating ATP which enables ATP-induced aggregation via conversion to ADP, but also convert ADP to AMP and adenosine. Platelet aggregation extent is a balance between these activities, and high white cell counts influence this balance.     

Activation of leukocytes in whole blood samples by N-formyl-methionyl-leucyl-phenylalanine (FMLP) enhances platelet aggregability but not platelet P-selectin exposure and adhesion to leukocytes

Adhesion of platelets to neutrophils and monocytes is believed to play an important role in intercellular communication. Evidence has been provided that such heterotypic cell-cell contacts via adhesion molecules may be directly involved in intercellular signal transduction as well as facilitate the action of soluble signal transmitters, e.g. cathepsin G, PAF or nitric oxide. With respect to platelet activation, stimulatory and inhibitory effects of leukocytes have been reported, and the results obtained seem to be influenced by the experimental conditions. We investigated the effect of leukocyte stimulation on platelet behaviour in samples of human citrated whole blood. Adding the chemotactic peptide FM LP, which stimulates neutrophils and monocytes but not lymphocytes and platelets, to stirred whole blood samples resulted in a significant enhancement ( P < 0.01) of spontaneous as well as ADP-induced platelet aggregation (25 vs 33% and 66 vs 69% , respectively). In contrast stirring-induced as well as ADP-induced increase of P-selectin exposure (33 and 107% , respectively) was not affected by FMLP. In unstirred whole blood samples, about 10 to 20% of neutrophils and monocytes had bound platelets to their surfaces, and the number of these heterotypic conjugates was enhanced about twofold during spontaneous platelet aggregation. Addition of FMLP significantly reduced the stirring-induced formation of platelet-neutrophil conjugates but not of platelet-monocyte conjugates. These results indicate that neutrophil and/or monocyte activation in whole blood may enhance platelet aggregation, but not secretion (CD62P exposure) and formation of heterotypic platelet-leukocyte conjugates.     

P-selectin in arterial thrombosis

P-selectin is a transmembrane protein present in the alpha granules of platelets and the Weibel-Palade bodies of endothelial cells. Following activation, it is rapidly translocated to the cell surface. P-selectin expression in platelets has been shown to be elevated in disorders associated with arterial thrombosis such as coronary artery disease, acute myocardial infarction, stroke, and peripheral artery disease. P-selectin mediates rolling of platelets and leukocytes on activated endothelial cells as well as interactions of platelets with leukocytes. Platelet P-selectin interacts with P-selectin glycoprotein ligand-1 (PSGL-1) on leukocytes to form platelet-leukocyte aggregates. Furthermore, this interaction of P-selectin with PSGL-1 induces the upregulation of tissue factor, several cytokines in leukocytes and the production of procoagulant microparticles, thereby contributing to a prothrombotic state. P-selectin is also involved in platelet-platelet interactions, i. e. platelet aggregation which is a major factor in arterial thrombosis. P-selectin interacts with platelet sulfatides, thereby stabilizing initial platelet aggregates formed by GPIIb/IIIa-fibrinogen bridges. Inhibtion of the P-selectin-sulfatide interaction leads to a reversal of platelet aggregation. Thus, P-selectin plays a significant role in platelet aggregation and platelet- leukocyte interactions, both important mechanisms in the development of arterial thrombosis.     

Platelet P-selectin is required for pulmonary eosinophil and lymphocyte recruitment in a murine model of allergic inflammation

Platelets are necessary for lung leukocyte recruitment in a murine model of allergic inflammation, and platelet-leukocyte aggregates are formed in circulating blood of patients with asthma after allergen exposure. However, it is unknown how platelets induce pulmonary leukocyte recruitment in asthma. Here, we have investigated the importance of platelet adhesion molecule expression on pulmonary eosinophil and lymphocyte recruitment and on leukocyte CD11b and very late antigen (VLA)-4 expression in mice. Pulmonary leukocyte recruitment in platelet-depleted mice (sensitized and exposed to ovalbumin) transfused with fixed, unstimulated platelets (FUSPs) was abolished, whereas transfusion with platelets stimulated and fixed (FSPs), expressing P-selectin and P-selectin glycoprotein ligand-1 (PSGL-1), restored eosinophil and lymphocyte recruitment. Transfusion with platelets from P-selectin-deficient mice, or with FSPs stimulated in the presence of a blocking anti-P-selectin antibody, were unable to restore pulmonary leukocyte recruitment. Flow cytometric analysis revealed increased expression of CD11b and VLA-4 on leukocytes attached to platelets after allergen exposure, and CD11b expression on leukocytes was suppressed in thrombocytopenic mice but was restored with the transfusion of FSPs, but not FUSPs, a phenomenon concurrent with the formation of platelet-leukocyte complexes. P-selectin expression on the surfaces of platelets is a major requirement for pulmonary eosinophil and lymphocyte recruitment, allowing circulating platelets to bind to and stimulate leukocytes for endothelial attachment.     

Increased platelet activation in subjects chronically exposed to cadmium: A pilot study

Cadmium exposure has been reported to be associated with the risk of vascular disorders. Here, we investigated platelet activity in subjects with chronic cadmium exposure. Eighteen and 15 women participated in this study as chronically cadmium-exposed and control non-exposed subjects, respectively. Plasma P-selectin and CD40 ligand (CD40L), soluble markers of platelet activation, were measured. Platelet aggregation in whole blood, P-selectin and activated glycoprotein (aGP) IIb/IIIa expression on platelets and platelet–leukocyte aggregates were determined. The levels of plasma P-selectin and CD40L increased in subjects with chronic cadmium exposure compared with control subjects. Platelet aggregation induced by adenosine diphosphate (ADP) was higher in cadmium-exposed subjects than control subjects. Cadmium-exposed subjects had higher baseline and ADP-induced aGPIIb/IIIa expression on platelets than control subjects. Platelet–neutrophil aggregates also increased in cadmium-exposed subjects. Blood cadmium correlated with ADP-induced aggregation, aGPIIb/IIIa expression and platelet–neutrophil aggregates, while urinary cadmium correlated with soluble P-selectin. However, cadmium only at high concentration (15?µM) could potentiate ADP-induced platelet activation in vitro. In conclusion, our pilot data show that cadmium-exposed subjects have increased baseline platelet activation and reactivity.     

Platelet-platelet and platelet-leukocyte interactions induced by outer membrane vesicles from N. meningitidis

A large part of native meningococcal lipopolysaccharide (LPS), i.e., LPS integrated in the outer cell membrane, is released in the form of 'blebs' from surplus outer membrane material. In the present study we investigated the effects of purified outer membrane vesicles (OMVs) on blood platelet-platelet and platelet-leukocyte interactions. Citrated whole blood was stimulated in vitro with equal amounts (on a weight basis) of OMV-integrated LPS, purified LPS (P-LPS) from the same meningococcal strain and purified E. coli-LPS. The samples were analyzed by flow cytometry. Upon OMV stimulation platelet aggregation increased 2.1-fold, platelet degranulation 1.8-fold, (measured as CD62P expression), platelet binding to monocytes 2.6-fold, whereas platelet binding to granulocytes increased 2.8-fold. Also, the fraction of large heteroconjugates, i.e., large CD45-positive cell aggregates increased 15.7-fold compared to control. P-LPS and E. coli-LPS also significantly increased platelet aggregation and heteroconjugate formation but did not influence platelet degranulation and binding of platelets to leukocytes in whole blood. When using platelet-rich plasma (PRP), OMVs increased platelet aggregation 2.1-fold and CD62P expression 1.9-fold. P-LPS and E. coli-LPS also significantly increased platelet aggregation in PRP but did not influence platelet degranulation. None of the LPS preparations induced platelet microvesiculation, either in whole blood or in PRP. CONCLUSION: Meningococcal-derived OMVs as well as purified meningococcal LPS, contribute to increased platelet-platelet and platelet-leukocyte aggregation and may thus be of great importance in the development of microthrombosis and organ dysfunction related to fulminant meningococcal septicemia.     

Platelet-leukocyte cross talk in whole blood

Thrombosis and inflammation involve complex platelet-leukocyte interaction, the details of which are not fully elucidated. Therefore, we investigated cross talk between platelets and leukocytes in whole blood, under the following physiological conditions: at 37 degrees C, with normal calcium concentrations, and with shear force. Platelet P-selectin and leukocyte CD11b expression were used to monitor platelet and leukocyte activation, respectively, and platelet-leukocyte aggregation (PLA) was analyzed. The leukocyte-specific agonist N:-formyl-methionyl-leucyl-phenylalanine (10(-6) mol/L) increased P-selectin-positive platelets from 2.5+/-0. 1% to 5.1+/-0.6% (P:<0.05). The increase was inhibited by either the platelet-activating factor (PAF) antagonist SR27417, the superoxide anion scavenger superoxide dismutase, the 5-lipoxygenase inhibitor Zileuton, or the 5-lipoxygenase-activating protein inhibitor MK-886, suggesting the involvement of PAF, superoxide anion, and 5-lipoxygenase products in leukocyte-induced platelet activation. The platelet-specific agonist collagen (1 microg/mL) increased leukocyte CD11b expression from 2.94+/-0.52 to 3.81+/-0.58 (P:<0. 05); this was not inhibited by the thromboxane A(2) receptor antagonist ICI 192.605 or the PAF antagonist SR27417. Platelet P-selectin expression induced by N:-formyl-methionyl-leucyl-phenylalanine and leukocyte CD11b expression induced by collagen could be suppressed by glycoprotein IIb/IIIa blockade or P-selectin blockade. This study documents platelet-leukocyte cross talk under conditions that mimic a physiological state and suggests that this involves multiple mediators and mechanisms. Furthermore, new evidence of integrin and selectin involvement in intracellular and intercellular signaling during platelet-leukocyte cross talk is provided.     

Activated platelets induce Weibel-Palade-body secretion and leukocyte rolling in vivo: role of P-selectin

The presence of activated platelets and platelet-leukocyte aggregates in the circulation accompanies major surgical procedures and occurs in several chronic diseases. Recent findings that activated platelets contribute to the inflammatory disease atherosclerosis made us address the question whether activated platelets stimulate normal healthy endothelium. Infusion of activated platelets into young mice led to the formation of transient platelet-leukocyte aggregates and resulted in a several-fold systemic increase in leukocyte rolling 2 to 4 hours after infusion. Rolling returned to baseline levels 7 hours after infusion. Infusion of activated P-selectin-/- platelets did not induce leukocyte rolling, indicating that platelet P-selectin was involved in the endothelial activation. The endothelial activation did not require platelet CD40L. Leukocyte rolling was mediated solely by the interaction of endothelial P-selectin and leukocyte P-selectin glycoprotein ligand 1 (PSGL-1). Endothelial P-selectin is stored with von Willebrand factor (VWF) in Weibel-Palade bodies. The release of Weibel-Palade bodies on infusion of activated platelets was indicated by both elevation of plasma VWF levels and by an increase in the in vivo staining of endothelial P-selectin. We conclude that the presence of activated platelets in circulation promotes acute inflammation by stimulating secretion of Weibel-Palade bodies and P-selectin-mediated leukocyte rolling.     

Effects of Different Thrombolytic Treatment Regimen with Abciximab and Tirofiban on Platelet Aggregation and Platelet-Leukocyte Interactions: A Subgroup Analysis from the GUSTO V and FASTER Trials

Background: Due to considerably high rates of reocclusion under standard thrombolytic therapy GP IIb/IIIa inhibitors have been combined with thrombolytics to improve therapeutic outcomes. Potential reasons for arterial reocclusion may be increased platelet activation, interaction of platelets with other cell types such as leukocytes and inadequate drug dosing due to lack of ideal platelet monitoring. We compared combination therapy regimens consisting of GP IIb/IIIa inhibitors and thrombolytics with respect to platelet inhibition and platelet-leukocyte interactions. Methods and results: From the GUSTO V trial (standard rPA vs. reduced dose rPA and abciximab) and the FASTER trial (standard TNK-tPA vs. reduced dose TNK-tPA and tirofiban) 15 patients were monitored by platelet aggregometry, rapid platelet function assay (RPFA) and flow cytometry (FC). rPA alone (n = 5) caused initial increases in platelet aggregation. However, platelet aggregation was significantly (p < 0.05) and sufficiently (>80%) inhibited by abciximab/rPA (n = 5) and tirofiban/TNK-tPA (n = 5). The platelet inhibitory effect of tirofiban/TNK-tPA was more pronounced compared to abciximab/rPA with a significant difference after 2 h (p < 0.05). Tirofiban/TNK-tPA and abciximab/rPA caused decreases in platelet-leukocyte aggregates as well as in binding of specific antibodies to the platelet vitronectin receptor and P-selectin (p < 0.05, respect.). No differences among the treatment groups were seen with respect to antibody binding to MAC-1 and CD154/CD40 ligand. Conclusions: Taken together, GP IIb/IIIa inhibitors overcome the platelet activating effect of thrombolytics resulting in sufficient platelet inhibition. RPFA is a suitable monitoring tool to accurately assess platelet inhibition. Within the given combination treatment regimen tirofiban appears to be more effective compared to abciximab and to exert effects beyond the inhibition of GP IIb/IIIa.     

Formation of platelet-leukocyte conjugates in whole blood

The purpose of this investigation was to obtain information on platelet-leukocyte conjugate formation in whole blood and on factors that affect it. We also measured platelet and leukocyte activation by quantitating the expression of CD62P and CD11b. In both cases a flow cytometric approach was used. The results show that platelet-monocyte and platelet-polymorphonuclear leukocyte (PMNL) conjugate formation is enhanced by simply stirring blood, with optimum conjugate formation occurring after 10 min. In the case of monocytes, conjugate formation was enhanced by adenosine diphosphate (ADP). Both monocyte and PMNL conjugate formation was enhanced by phorbol myristate acetate (PMA), but either without effect (monocytes) or inhibitory (PMNL). EDTA also inhibited conjugate formation (implying involvement of divalent cations), as did dextran sulphate (implying involvement of P-selectin CD62P). Interestingly GR144053F, which acts at GpIIb-IIIa on platelets to interfere with fibrinogen binding, and also glycyl prolyl arginyl proline (GPRP), a peptide that interferes with the interaction between CD11c on leukocytes and fibrinogen, did not inhibit platelet-monocyte conjugate formation, but did inhibit the platelet-PMNL interaction; this indicates that GpIIb-IIIa on platelets and CD11c on leukocytes and fibrinogen are involved in mediating the interaction between platelets and PM NL but not platelets and monocytes. Surprisingly arginyl glycyl aspartyl serine (RGDS) inhibited the formation of both types of conjugate but this may be because it also inhibited both platelet and leukocyte activation as measured by CD62P and CD11b exposure and or interfers with the binding of adhesion molecules other than fibrinogen. The results show that a flow cytometric procedure can be effective in obtaining rapid information on platelet-leukocyte conjugate formation in whole blood and on factors that are involved in its regulation. It is suggested that the technique may be applicable to the study of platelet-leukocyte conjugate formation in whole blood in disease, and also to study the effects of drugs interfering with conjugate formation. -formyl methionyl lysyl proline (FMLP) was L     

Formation of platelet-leukocyte conjugates in whole blood

The purpose of this investigation was to obtain information on platelet-leukocyte conjugate formation in whole blood and on factors that affect it. We also measured platelet and leukocyte activation by quantitating the expression of CD62P and CD11b. In both cases a flow cytometric approach was used. The results show that platelet-monocyte and platelet-polymorphonuclear leukocyte (PMNL) conjugate formation is enhanced by simply stirring blood, with optimum conjugate formation occurring after 10 min. In the case of monocytes,conjugate formation was enhanced by adenosine diphosphate (ADP). Both monocyte and PMNL conjugate formation was enhanced by phorbol myristate acetate (PMA), but L-formyl methionyl lysyl proline (FMLP) was either without effect (monocytes) or inhibitory (PMNL). EDTA also inhibited conjugate formation (implying involvement of divalent cations), as did dextran sulphate (implying involvement of P-selectin = CD62P).Interestingly GR144053F, which acts at GpIIb-IIIa on platelets to interfere with fibrinogen binding, and also glycyl prolyl arginyl proline (GPRP), a peptide that interferes with the interaction between CD11c on leukocytes and fibrinogen, did not inhibit platelet-monocyte conjugate formation, but did inhibit the platelet-PMNL interaction; this indicates that GpIIb-IIIa on platelets and CD11c on leukocytes and fibrinogen are involved in mediating the interaction between platelets and PMNL but not platelets and monocytes. Surprisingly arginyl-glycyl aspartyl serine (RGDS) inhibited the formation of both types of conjugate but this may be because it also inhibited both platelet and leukocyte activation as measured by CD62P and CD11b exposure and/or interferes with the binding of adhesion molecules other than fibrinogen. The results show that a flow cytometric procedure can be effective in obtaining rapid information on platelet-leukocyte conjugate formation in whole blood and on factors that are involved in its regulation. It is suggested that the technique may be applicable to the study of platelet-leukocyte conjugate formation in whole blood in disease, and also to study the effects of drugs interfering with conjugate formation.     

Leukocyte count and leukocyte ecto-nucleotidase are major determinants of the effects of adenosine triphosphate and adenosine diphosphate on platelet aggregation in human blood

ADP induces platelet aggregation in human whole blood and platelet-rich plasma (PRP). ATP induces aggregation in whole blood only; this involves leukocytes and is mediated by ADP. Here we studied ATP- and ADP-induced aggregation in patients with raised leukocyte counts (mean 46.2x10(3) leukocytes/microl). Platelet aggregation was measured by platelet counting. ATP, ADP and metabolites were measured by HPLC. Aggregation to ADP (1-10 microM) and ATP (10-100 microM) was markedly reduced, but to ATP (1000 microM) was enhanced (all p<0.001). Aggregation to ADP in PRP was normal. Increasing the leukocyte count in normal blood reproduced the findings in the patients. Adding leukocytes (either MNLs or PMNLs) to normal PRP enabled a response to ATP and caused marked inhibition of ADP-induced aggregation. Breakdown of ATP or ADP to AMP and adenosine in leukocyte-rich plasma was rapid (t1/2=4 min) and far higher than in cell-free plasma or PRP. With ATP there was also formation of ADP, maximal at 4 min. The presence of the ectonucleotidase NTPDase1 (CD39) was demonstrated on MNLs (all of the monocytes and a proportion of the lymphocytes) and all PMNLs by flow cytometry. We conclude that leukocytes provide a means of dephosphorylating ATP which enables ATP-induced aggregation via conversion to ADP, but also convert ADP to AMP and adenosine. Platelet aggregation extent is a balance between these activities, and high white cell counts influence this balance.     

Platelet reactivity among Asian Indians and Caucasians

Asian Indians are reported to have higher mortality and morbidity from coronary artery disease (CAD) than other ethnic groups. This variation in events cannot be explained only by differences in conventional risk factors. Platelet activation is an important factor in the pathogenesis of CAD, however, there are limited data concerning platelet reactivity in Asian Indians. Therefore, we aimed to examine platelet reactivity in healthy Asian Indians vs. Caucasians. Thirty-five healthy, nonsmoking Asian Indians (mean age 30.1?±?3.6 years, 31.4% women) were matched for age and sex with 35 healthy, nonsmoking Caucasians (mean age 30.8?±?5 years, 31.4% women). Platelet reactivity was evaluated by measuring platelet aggregation, platelet leukocyte aggregates (PLA) formation in response to a 6-mer thrombin receptor agonist peptide (TRAP) at a final concentration of 40?µM and flow cytometry determined P-selectin expression induced by ADP, TRAP and arachidonic acid (AA). In addition, P-Selectin glycoprotein ligand-1 (PSGL-1) density on leukocytes was measured. There were no differences in platelet aggregation, basal PLA or PSGL-1 density on leukocytes between the two groups. AA-stimulated P-selectin expression was significantly higher in Asian Indians than in Caucasians (6.1?±?0.51 vs. 4.2?±?0.41 MFI, P?<?0.02). After stimulation with TRAP, platelets from Asian Indians had increased PLA formation compared with Caucasians (41.6?±?2.9% vs. 31.4?±?2.7%, P?<?0.02). AA induced P-selectin expression and TRAP stimulated PLA formation is increased in Asian Indians compared with Caucasians. These differences indicate an increase in measures of platelet reactivity among Asian Indians and may help elucidate the reported disparity in cardiovascular disease rates between the two ethnic groups.     

Relationship between age and platelet activation in patients with stable and unstable angina

The objective of this study was to examine platelet reactivity and activation as a function of age in patients with both stable and unstable angina. This was a retrospective cohort study to compare platelet function in older patients with and without acute coronary syndromes. Participants were 55 individuals presenting with acute coronary syndromes and 54 with stable angina whose age ranged from 38 to 92 years. Platelet reactivity was assessed by ADP-induced aggregation and activation was measured by p-selectin, total and active GPIIb/IIIa expression, and platelet-leukocyte aggregates in. Multiple regression was used to identify independent predictors for each platelet variable. Aggregation and receptor expression decreased with advancing age only among patients with acute coronary syndromes. In multivariate analyses, age was the strongest predictor of decreased aggregation (beta=-0.558, R(2)=0.353, p<0.0001), reduced labeling with PAC-1 (beta=-0.561, R(2)=0.276, p<0.0001) and reduced p-selectin (beta=-0.442, R(2)=0.240, p<0.0001). However, age did not predict total GPIIb/IIIa labeling or platelet-leukocyte aggregates in either acute coronary syndrome or stable patients. In conclusion, older patients with acute coronary syndromes demonstrate decreased platelet reactivity and activation at presentation. These findings may provide a mechanism to explain increased bleeding observed in elderly patients treated with GPIIb/IIIa inhibitors and fibrinolytic therapy for unstable coronary syndromes.     

Effects of platelet glycoprotein IIb-IIIa number and glycoprotein IIIa Leu33Pro polymorphism on platelet aggregation and sensitivity to glycoprotein IIb-IIIa antagonists

We investigated the influence of glycoprotein (GP) IIIa Leu33Pro polymorphism, platelet GP IIb-IIIa number, and plasma fibrinogen concentration on platelet aggregation and antiaggregatory action of GP IIb-IIIa antagonists. Healthy volunteers with GP IIIa Pro33(?) (Leu33Leu33, n?=?20) and Pro33(+) (Leu33Pro33, n?=?13, and Pro33Pro33, n?=?2) genotypes were included into the study. GP IIIa Leu33Pro substitution was associated with the increase of the level and rate of platelet microaggregate formation induced by GP IIb-IIIa activating antibody CRC54 (100,?200,?400?µg/ml) against the epitope within 1–100 residues of GP IIIa N-terminal part (p from 0.001 to 0.047). No significant differences were detected between parameters of platelet aggregation induced by ADP (1.25,?2.5,?5.0,?20?µM) in GP IIIa Pro33(+) and Pro33(?) donors. GP IIb-IIIa antagonist Monafram (F(ab’)₂ fragment of GP-IIb-IIIa blocking antibody CRC64) (1,?2,?3?µg/ml), but not eptifibatide (50,?100,?150?ng/ml) inhibited ADP-induced aggregation slightly less efficiently in GP IIIa Pro33(+) group (p?<?0.05 at 1 and 2?µg/ml Monafram). GP IIb-IIIa number (evaluated as maximal binding of ¹²⁵I-labelled antibody CRC64) varied from 40.5 to 80.8?×?10³ per platelet with no significant influence of GP IIIa genotype. Consistent correlations were revealed between GP IIb-IIIa quantity and the level and rate of ADP-induced aggregation (r from 0.353 to 0.583, p from <0.001 to 0.037) as well as resistance (level of residual aggregation) to both GP IIb-IIIa antagonists (r from 0.345 to 0.602, p from <0.001 to 0.042). ADP-induced aggregation was considerably increased and efficiency of GP IIb-IIIa antagonists decreased in donors with high in comparison with low GP IIb-IIIa quantity (>60 and 40–50?×?10³ per platelet respectively, p?<?0.01 for most tests). No correlations were observed between all tested parameters and plasma fibrinogen concentration. Our results indicate that inter-individual variability of platelet GP IIb-IIIa number significantly affects platelet aggregation and antiaggregatory effects of GP IIb-IIIa antagonists. Contribution of this factor is higher than that of GP IIIa Leu33Pro polymorphism and variations of fibrinogen concentration.     

Role of GPIIb-IIIa in platelet-monocyte and platelet-neutrophil conjugate formation in whole blood

Platelets in stirred whole blood can be induced to form aggregates and also to form heterotypic platelet-monocyte (P/M) and platelet-neutrophil (P/N) conjugates. Here we have investigated the effects of three GPIIb-IIIa antagonists (GR144053F, MK-852 and Reopro, a CD62P-blocking antibody, GA6, and EDTA on the conjugate formation that occurs on stirring whole blood and in response to adding ADP and PAF. We have confirmed the identities of the conjugates by light microscopy after cell sorting. Platelet aggregation was measured by platelet counting. Monocytes, neutrophils, P/M and P/N were detected and quantitated using immunofluorescence and flow cytometry. Stirring whole blood resulted in both platelet aggregation and formation of P/M but not P/N. Adding ADP or PAF to whole blood caused rapid platelet aggregation and generation of both P/M and P/N. All of the GPIIb-IIIa antagonists studied had similar effects: inhibition of stirring-induced platelet aggregation and P/M formation, and inhibition of ADP-induced platelet aggregation and P/N formation. In contrast, they accelerated ADP induced-P/M conjugate formation and PAF-induced formation of both P/M and P/N. Both EDTA and GA6 completely inhibited P/M and P/N, which is commensurate with CD62P being involved in platelet-leucocyte conjugate formation. The results of these investigations suggest that GPIIb-IIIa has a dual role in determining the interaction between platelets and leukocytes.     

高脂血症患者血清补体C3、C4、备解素和白细胞补体调节蛋白CD35、CD55、CD59的表达

目的:探讨高脂血症患者血清补体和外周血白细胞补体调节蛋白的表达及其在动脉粥样硬化中的意义。方法:选高脂血症患者46例(高脂血症组),年龄、性别、体重指数匹配的正常人20例作为正常对照组,用免疫散射比浊法测血清补体C3、C4、备解素(Pf);用流式细胞术测定外周血中性粒细胞、淋巴细胞和单核细胞CD35、CD55、CD59的表达,观察上述指标在高脂血症组中的变化,分析影响因素。结果:高脂血症组血清C3、C4、Pf水平较正常对照组明显升高(P<0.01);补体C3、C4水平与血清总胆固醇(TC)、甘油三酯(TG)、低密度脂蛋白胆固醇(LDLC)明显正相关(P<0.01),Pf与TC、LDLC正相关(P<0.01)。CD35阳性淋巴细胞、单核细胞、粒细胞百分率较正常对照组升高(P<0.05),CD35阳性淋巴细胞、粒细胞百分率与TG呈正相关(P<0.05～0.01);CD55阳性淋巴细胞平均荧光强度较正常对照组下降(P<0.05);CD59阳性淋巴细胞、单核细胞百分率较正常对照组下降(P<0.05)。结论:高脂血症患者血清补体C3、C4、Pf升高,白细胞补体调节蛋白表达改变,补体及补体调节蛋白的改变与血脂水平相关,表明脂代谢紊乱可影响补体及补体调节蛋白的表达,提示补体及补体调节蛋白可能参与动脉粥样硬化的病理生理过程。