Neutrophil rolling, arrest, and transmigration across activated, surface-adherent platelets via sequential action of P-selectin and the beta 2-integrin CD11b/CD18

Platelets bound to thrombogenic surfaces have been shown to support activation-dependent firm adhesion of neutrophils in flow following selectin-mediated tethering and rolling. The specific receptor(s) responsible for mediating adhesion-strengthening interactions between neutrophils and platelets has not previously been identified. Furthermore, the ability of adherent platelets to support the migration of bound neutrophils has not been tested. We studied neutrophil interactions with activated, surface-adherent platelets as a model for leukocyte binding in vascular shear flow and emigration at thrombogenic sites. Our results demonstrate that the beta 2-integrin Mac-1 (CD11b/CD18) is required for both firm attachment to and transmigration of neutrophils across surface-adherent platelets. In flow assays, neutrophils from patients with leukocyte adhesion deficiency-1 (LAD-I), which lack beta 2-integrin receptors, formed P-selectin-mediated rolling interactions, but were unable to develop firm adhesion to activated platelets, in contrast to healthy neutrophils, which developed firm adhesion within 5 to 30 seconds after initiation of rolling. Furthermore, the adhesion-strengthening interaction observed for healthy neutrophils could be specifically inhibited by monoclonal antibodies (mAbs) to Mac-1, but not to lymphocyte function-associated antigen-1 (LFA-1; CD11a/CD18) or intercellular adhesion molecule-2 (ICAM-2; CD102). Further evidence for a beta 2-integrin-dependent neutrophil/platelet interaction is demonstrated by the complete inhibition of interleukin (IL)-8-induced neutrophil transmigration across platelets bound to fibronectin-coated polycarbonate filters by mAbs to Mac-1. Thus, Mac-1 is required for firm adhesion of neutrophils to activated, adherent platelets and may play an important role in promoting neutrophil accumulation on and migration across platelets deposited at sites of vascular injury.     

Comparative evaluation of the role of the adhesion molecule CD177 in neutrophil interactions with platelets and endothelium

Neutrophil-specific glycoprotein CD177 is expressed on a subset of human neutrophils and has been shown to be a counter-receptor for platelet endothelial cell adhesion molecule-1 (PECAM-1, CD31). Previous studies have demonstrated that the interaction of CD177 with endothelial PECAM-1 supports neutrophil transendothelial migration resulting in preferential transmigration of the CD177-expressing neutrophil subset. As PECAM-1 is also abundantly expressed on platelets, we addressed a follow-up suggestion that CD177/PECAM-1 adhesive interaction may mediate platelet-neutrophil interactions and CD177-positive neutrophils may have a competitive advantage over CD177-negative neutrophils in binding platelets. Here, we report that CD177-positive and CD177-negative neutrophils do not differ significantly in their capacity to form platelet-neutrophil conjugates as assayed in whole blood and in mixed preparations of isolated platelets and neutrophils. Under flow conditions, neither platelet nor neutrophil activation resulted in preferential binding of platelets to CD177-expressing neutrophils. Furthermore, no significant difference was found in the ability of both neutrophil subsets to adhere to and migrate across surface-adherent activated platelets, whereas predominantly CD177-positive neutrophils migrated across HUVEC monolayers. In addition, we demonstrated that S(536) N dimorphism of PECAM-1, which affects CD177/PECAM-1 interaction, did not influence the equal capacity of the two neutrophil subsets to interact with platelets but influenced significantly the transendothelial migration of CD177-expressing neutrophils. Thus, CD177/PECAM-1 adhesive interaction, while contributing to neutrophil-endothelial cell interaction in neutrophil transendothelial migration, does not contribute to or is redundant in platelet-neutrophil interactions.     

DDAVP enhances the ability of blood monocytes to form rosettes with activated platelets by increasing the expression of P-selectin sialylated ligands on the monocyte surface

The mechanism through which DDAVP (1-deamino-8-d-arginine vasopressin) promotes blood coagulation is not completely understood. As blood monocytes have been identified as a target for DDAVP, we investigated whether this drug increased monocyte adhesion to activated platelets, which would result in the close intercellular contact that is necessary for a juxtacrine effect on platelets and/or endothelium at sites of vascular injury. Monolayers of non-confluent monocytes adhered to glass slides were incubated with thrombin-activated, formaldehyde-fixed platelets before and after the adherent monocytes were stimulated with DDAVP or n-formyl-methyl-leucyl-phenylalanine (fMLP). The number of platelets involved in rosettes with monocytes was quantified, and the effect of DDAVP or fMLP on the monocyte surface expression of P-selectin ligands and CD11b/CD18 was assessed. DDAVP or fMLP increased the number of activated platelets involved in rosettes with monocytes by 2.8- and 4.9-fold respectively. EDTA and inhibitors of the P-selectin/counter-receptor interaction decreased the platelet numbers in rosettes by 80-90%, whereas inhibitors of the integrin-mediated adhesion reduced rosettes by 40-50%. Blocking the P-selectin glycoprotein ligand-1 (PSGL-1) with the monoclonal antibody, Pl-1, decreased the platelet numbers in rosettes by only 50%. In contrast, surface expression of the sialylated ligands of P-selectin and, to a lesser extent, of CD11b/CD18 increased upon monocyte activation with DDAVP or fMLP, whereas it decreased slightly with PSGL-1. These results indicate that DDAVP enhanced the ability of blood monocytes to bind activated platelets, mainly by increasing the expression of P-selectin sialylated ligands on the monocyte surface. A similar effect was achieved with fMLP.     

Role of P-selectin and leukocyte activation in polymorphonuclear cell adhesion to surface adherent activated platelets under physiologic shear conditions (an injury vessel wall model)

Carbohydrate moieties on leukocytes adhere to activated platelets via P- selectin under static binding condition studies. We characterize polymorphonuclear cell (PMN) surface interactions with surface adherent platelets and the PMNs response, under physiologic flow conditions corresponding to a shear of 100 s-1, in an in vitro flow chamber. Fluorescent labeled PMNs with red blood cells were drawn through a transparent flow channel and visually quantitated over 30 minutes, interacting with a confluent monolayer of activated, shear-spread platelets expressing P-selectin. PMN adhesion was saturable (2,250 +/- 350/mm2), and time and cation (Ca2+, Mg2+) dependent, and PMNs did not bind to the experimental surface in the absence of a platelet monolayer. P-selectin antibodies completely abolished PMN adhesion in a concentration-dependent manner with half inhibition at 70 micrograms/mL. Antibodies to a putative P-selectin receptor CD15 (80H5 and MMA) maximally inhibited PMN adhesion by 73% and 10%, respectively. Adherent PMNs appeared morphologically activated and flow cytometric analysis of adherent PMNs confirmed activation because CD11b and CD18 surface expression was upregulated (100% and 27%, respectively), whereas L-selectin was downregulated (55%) compared with control nonadherent PMNs. In the presence of the metabolic inhibitor sodium azide (0.02% and 0.1%) there was a 23% +/- 9% and 51% +/- 3% decrease, respectively, in PMN adhesion at 100 s-1. Thus, P-selectin is required for PMN adhesion to a pathophysiologic surface of activated adherent platelets at physiologic shear rates. Furthermore, a secondary step involving PMN activation after platelet binding appears necessary for complete (irreversible) adhesion to occur. This unique flow cell provides a model to explore, under controlled conditions, biologic mechanisms and ligands involved in leukocyte-platelet binding that play important roles in PMN localization at sites of thrombosis and vascular injury.     

Platelet receptors for collagens

Collagens belong to the constituents that determine the thrombogenicity of the vessel wall. Seven genetically distinct collagens-type I, III, IV, V, VI, VIII and XIII-have been identified in the vessel wall. The interaction of platelets with collagens is a complex process since collagens are not only potent platelet agonists but also adhesive proteins. In recent years several platelet membrane glycoproteins have been shown to be involved in platelet-collagen interactions. The mechanisms of platelet-collagen interaction can be divided into primary, direct interactions and secondary, indirect interactions. A number of direct receptors for the collagens have been proposed. The glycoprotein complex Ia/IIa, also called VLA(2), α(2)β(1) integrin or CD49b/CD29, meets several criteria as the major platelet receptor for different types of collagens. There is some evidence that glycoprotein IIIb, also called glycoprotein IV or CD36, functions at the earliest stages of collagen adhesion as a platelet collagen receptor. CD36 seems to be essential for type V collagen-induced platelet aggregation and adhesion. Another putative platelet-collagen receptor is P62, a glycoprotein with a molecular weight of 62 kDa under reducing conditions.     

Conversion of platelets from a proaggregatory to a proinflammatory adhesive phenotype: role of PAF in spatially regulating neutrophil adhesion and spreading

The ability of platelets to provide a highly reactive surface for the recruitment of other platelets and leukocytes to sites of vascular injury is critical for hemostasis, atherothrombosis, and a variety of inflammatory diseases. The mechanisms coordinating platelet-platelet and platelet-leukocyte interactions have been well defined and, in general, it is assumed that increased platelet activation correlates with enhanced reactivity toward other platelets and neutrophils. In the current study, we demonstrate a differential role for platelets in supporting platelet and neutrophil adhesive interactions under flow. We demonstrate that the conversion of spread platelets to microvesiculated procoagulant (annexin A5-positive [annexin A5+ve]) forms reduces platelet-platelet adhesion and leads to a paradoxical increase in neutrophil-platelet interaction. This enhancement in neutrophil adhesion and spreading is partially mediated by the proinflammatory lipid, platelet-activating factor (PAF). PAF production, unlike other neutrophil chemokines (IL-8, GRO-alpha, NAP-2, IL-1beta) is specifically and markedly up-regulated in annexin A5+ve cells. Physiologically, this spatially controlled production of PAF plays an important role in localizing neutrophils on the surface of thrombi. These studies define for the first time a specific proinflammatory function for annexin A5+ve platelets. Moreover, they demonstrate an important role for platelet-derived PAF in spatially regulating neutrophil adhesion under flow.     

Effects of human neutrophil elastase (HNE) on neutrophil function in vitro and in inflamed microvessels

The primary objective of this study was to test the hypothesis that human neutrophil elastase (HNE) affects neutrophil infiltration (adhesion and emigration) into inflamed vessels. To determine whether HNE contributes to neutrophil adhesion in vivo, intravital microscopy was used to study neutrophil-endothelial cell interactions in single inflamed postcapillary venules. Superfusion of platelet-activating factor (PAF) (100 nmol/L) onto the mesentery caused an increase in neutrophil-neutrophil interactions, neutrophil adhesion to postcapillary venules, and cellular emigration out of the vasculature. Both L658 758 (an elastase-specific inhibitor), and Eglin C (an elastase and cathepsin G inhibitor) significantly attenuated all of these parameters in vivo. To further characterize the mechanism(s) involved, various in vitro parameters were assessed. HNE, but not trypsin, caused a dose-dependent (0.01 to 1.0 microgram/mL) increase in the expression of the beta subunit (CD18) of the CD11/CD18 adhesive glycoprotein complex on neutrophils. An HNE-dependent increase in CD11b expression was also observed; however, HNE did not affect the expression of other neutrophil adhesion molecules (L-selectin), superoxide production, or degranulation. PAF-enhanced CD18 expression on neutrophils and neutrophil migration were both abolished by L658 758 but PAF-induced neutrophil adhesion to endothelial monolayers was not affected by the antiproteinase. The in vitro data suggest that the antiproteinases do not directly prevent neutrophil adhesion in vivo but may be important in other CD18-dependent events such as neutrophil- neutrophil interaction or neutrophil infiltration (chemotaxis). These results translate into an important, rate-limiting role for elastase in the process of leukocyte infiltration and accumulation in inflamed microvessels.     

Glycoprotein IIb and IIIa retention on fibrinogen-coated surfaces after lysis of adherent platelets

The platelet-membrane glycoprotein IIb-IIIa (GPIIb-IIIa) complex is essential for platelet aggregation and is involved in the attachment of platelets to thrombogenic surfaces. This study shows the retention of GPIIb and GPIIIa on immobilized fibrinogen after Triton X-100 (Sigma Chemical Co, St Louis, MO) lysis of adherent platelets. Glycoproteins were detected using subunit specific monoclonal antibodies in a modified enzyme-linked immunosorbent assay procedure. GPIIb-IIIa retention was judged to be specific relative to GPIb recovery, and was modulated by platelet activation. Platelet exposure to adenosine diphosphate or thrombin, but not A23187 or chymotrypsin, markedly enhanced GPIIb and GPIIIa recovery relative to that observed with unstimulated platelets, or prostaglandin E1-treated platelets. Moreover, lysis of adherent platelets in the presence of 10 mmol/L EDTA, under conditions promoting GPIIb-IIIa complex dissociation (pH 8.1, 60 minutes, 37 degrees C), had no effect on GPIIb or GPIIIa subunit recovery. Platelet activation with Zn+2 also enhanced GPIIb and GPIIIa recovery on fibrinogen-coated surfaces over that observed with unstimulated platelets, but GPIIb and IIIa retention was EDTA sensitive. This correlated with the EDTA-reversible nature of Zn+2- activated platelet adhesion to fibrinogen-coated surfaces. The data (1) show that platelet adhesion to fibrinogen is accompanied by the induction of high-affinity interactions between GPIIb-IIIa and immobilized fibrinogen that are EDTA-resistant and enhanced by platelet activation with some but not all agonists, and (2) implicate these interactions in stabilizing platelet contacts with fibrinogen-coated surfaces.     

Minimal platelet deposition and activation in models of injured vessel wall ensure optimal neutrophil adhesion under flow conditions.

Platelets at injured vessel wall form an adhesive surface for leukocyte adhesion. The precise relation between platelet adhesion and activation and leukocyte adhesion, however, is not known. We therefore used various models of injured vessel wall to form different patterns of platelet adhesion. The interaction of polymorphonuclear neutrophils (PMNs) was subsequently studied under flow conditions. In the absence of platelets, not only endothelial cell, smooth muscle cell, and fibroblast matrices but also purified matrix proteins (fibrinogen, collagen, and fibronectin) barely support PMN adhesion. The presence of platelets, however, strongly enhances PMN adhesion. PMN adhesion shows a proportional increase with platelet coverage up to 15%. Although PMNs roll over the scarcely scattered platelets, they speed up again when encountering surfaces without platelets. This "hopping" interaction of PMNs vanishes with platelet coverage >15%. Unobstructed rolling of PMNs is than observed and soon leads to a maximal adhesion of 1000 to 1200 cells/mm2. The mean rolling velocity of PMNs continues to decrease with higher platelet coverage. Platelet aggregate formation is an accepted indicator of platelet activation. The presence of platelet aggregates instead of contact or spread platelets, however, does not increase PMN adhesion. Also, additional stimulation of surface-associated platelets by thrombin fails to influence PMN adhesion. Moreover, indomethacin as an inhibitor of platelet activation and aggregation does not change the subsequent PMN interaction. In conclusion, approximately 15% of platelet coverage is sufficient for optimal PMN adhesion. Increasing platelet coverage increases the availability of platelet-associated receptors that lower PMN rolling velocity. Additional activation of adherent platelets makes no difference in the expression of relevant adhesion receptors. Therefore, minimal vascular damage in vivo and only scarce platelet adhesion will already evoke significant colocalization of leukocytes.     

Platelet‐induced expression of tissue factor procoagulant activity in freshly isolated human mononuclear cells: implications for experimental use

Summary Monocytes express tissue factor (TF) as a result of cytokine stimulation or endothelial adherence. We evaluated monocyte–platelet interaction in vitro as another trigger for monocyte TF enhancement in human mononuclear cells isolated by density gradient centrifugation from peripheral blood. Cell TF procoagulant activity (TF‐PCA) was quantitated by a one‐stage recalcification clotting time assay. Platelets were counted and identified by whole blood flow cytometry as CD61 positive particles, activated platelets were characterized by P‐Selectin (CD62) expression, and monocytes by surface CD14 expression. A significant correlation between normalized TF‐PCA of isolated mononuclear cells and platelet count was shown (r = 0.43, P < 0.001). Percentage of activated platelets in baseline samples was 4.2 ± 3.5 while adenosine diphosphate (ADP) increased platelet positivity to 34 ± 17% (P < 0.001). After isolation, 52 ± 12% of platelets within suspensions were activated (P < 0.0001). Percentage of CD62‐positive monocytes (CD14⁺ particles) increased from baseline 5% to 13 ± 6% in ADP‐stimulated samples to 53 ± 17% after isolation (P < 0.001). These findings suggest that density gradient centrifugation activates platelets and that an adhesive interaction between monocytes and platelets may promote TF‐PCA expression in isolated mononuclear suspensions. Enhanced monocyte TF expression as a result of an activated platelet–monocyte interaction seems to be an important laboratory effect requiring consideration when utilizing this technique in an experimental setup.     

Granulocyte colony-stimulating factor (G-CSF) increases neutrophil migration across vascular endothelium independent of an effect on adhesion: comparison with granulocyte-macrophage colony-stimulating factor (GM-CSF)

Granulocyte colony-stimulating factor (G-CSF) increases neutrophil counts, and enhances and primes many neutrophil functions, implicating a role for this growth factor in host defence. This study investigated whether G-CSF is able to directly influence the transendothelial migration of neutrophils, and how such effects might be related to other effects on neutrophil adhesive properties. G-CSF, like GM-CSF, increased surface levels of the adhesive receptor, CD11b/CD18, but down-regulated L-selectin expression on neutrophils. Unlike GM-CSF, however, G-CSF had no effect on neutrophil adhesion to endothelium. Despite the lack of effect on neutrophil adhesion, G-CSF was able to produce significant enhancement of neutrophil transmigration across unstimulated endothelium in vitro . When used at an optimal concentration of 100 ng/ml, G-CSF increased neutrophil migration to 217 ± 19% of baseline levels ( P <0.001, n  = 10). This effect was similar to that previously demonstrated for GM-CSF (which increased migration to 271 ± 40%, P <0.001, n  = 12). G-CSF-induced transmigration, like GM-CSF induced migration, was independent of concentration gradients, suggesting that these are not simply chemotactic effects. G-CSF differs from GM-CSF, however, in that although GM-CSF inhibited neutrophil migration across IL-1-activated endothelium (33 ± 8% inhibition, n  = 6, P <0.01), G-CSF had no effect on neutrophil migration across IL-1 activated endothelium. Hence G-CSF, despite having no effect on neutrophil adhesion to endothelium, is a powerful stimulator of transmigration, and, unlike GM-CSF, does not inhibit cell movement across inflamed endothelium. These results suggest that G-CSF is able to influence neutrophil recruitment into local infective sites, and, further, that G-CSF mobilized cells would be competent to migrate into tissues in response to inflammatory stimuli.     

Involvement of a CD47-dependent pathway in platelet adhesion on inflamed vascular endothelium under flow

Resting platelet adhesion to inflammatory vascular endothelium is thought to play a causal role in secondary thrombus formation or microcirculatory disturbance after vessel occlusion. However, though adhesion receptors involved in platelet-matrix interactions have been extensively studied, the molecular mechanisms involved in platelet-endothelium interactions are incompletely characterized and have been mainly studied under static conditions. Using human platelets or platelets from wild-type and CD47-/- mice in whole blood, we demonstrated that at low shear rate, CD47 expressed on human and mouse platelets significantly contributes to platelet adhesion on tumor necrosis factor-alpha (TNF-alpha)-stimulated vascular endothelial cells. Using the CD47 agonist peptide 4N1K and blocking monoclonal antibodies (mAbs), we showed that CD47 binds the cell-binding domain (CBD) of endothelial thrombospondin-1 (TSP-1), inducing activation of the platelet alphaIIbbeta3 integrin that in turn becomes able to link the endothelial receptors intercellular adhesion molecule 1 (ICAM-1) and alphavbeta3. Platelet CD36 and GPIbalpha are also involved because platelet incubation with blocking mAbs directed against each of these 2 receptors significantly decreased platelet arrest. Given that anti-CD47 treatment of platelets did not further decrease the adhesion of anti-CD36-treated platelets and CD36 is a TSP-1 receptor, it appears that CD36/TSP-1 interaction could trigger the CD47-dependent pathway. Overall, CD47 antagonists may be potentially useful to inhibit platelet adhesion on inflamed endothelium.     

Cytosolic calcium changes in a process of platelet adhesion and cohesion on a von Willebrand factor-coated surface under flow conditions.

Recent flow studies indicated that platelets are transiently captured onto and then translocated along the surface through interaction of glycoprotein (GP) Ib with surface-immobilized von Willebrand factor (vWF). During translocation, platelets are assumed to be activated, thereafter becoming firmly adhered and cohered on the surface. In exploring the mechanisms by which platelets become activated during this process, we observed changes in platelet cytosolic calcium concentrations ([Ca(2+)]i) concomitantly with the real-time platelet adhesive and cohesive process on a vWF-coated surface under flow conditions. Reconstituted blood containing platelets loaded with the Ca(2+) indicators Fura Red and Calcium Green-1 was perfused over a vWF-coated glass surface in a flow chamber, and changes in [Ca(2+)]i were evaluated by fluorescence microscopy based on platelet color changes from red (low [Ca(2+)]i) to green (high [Ca(2+)]i) during the platelet adhesive and cohesive process. Under flow conditions with a shear rate of 1,500 s(-1), no change in [Ca(2+)]i was observed during translocation of platelets, but [Ca(2+)]i became elevated apparently after platelets firmly adhered to the surface. Platelets preincubated with anti-GP IIb-IIIa antibody c7E3 showed no firm adhesion and no [Ca(2+)]i elevation. The intracellular Ca(2+) chelator dimethyl BAPTA did not inhibit firm platelet adhesion but completely abolished platelet cohesion. Although both firm adhesion and cohesion of platelets have been thought to require activation of GP IIb-IIIa, our results indicate that [Ca(2+)]i elevation is a downstream phenomenon and not a prerequisite for firm platelet adhesion to a vWF-coated surface. After platelets firmly adhere to the surface, [Ca(2+)]i elevation might occur through the outside-in signaling from GP IIb-IIIa occupied by an adhesive ligand, thereby leading to platelet cohesion on the surface.     

Activated platelets mediate Staphylococcus aureus deposition on subendothelial extracellular matrix: the role of glycoprotein Ib

Extracellular matrix (ECM) derived from bovine corneal endothelial cells was used as a model to study the role of platelets in Staphylococcus aureus interaction with the vascular subendothelium. In whole blood, S. aureus activated platelets, as demonstrated by P-selectin expression on the platelet membrane. Subjecting platelet-rich plasma (PRP) to the ECM under oscillatory conditions resulted in platelet adhesion and aggregation. S. aureus increased platelet deposition on ECM depending on the bacterium-platelet ratio. Scanning electron microscopy revealed that S. aureus adhered to and formed clusters on ECM-bound platelets. These findings were confirmed by using [3H]thymidine-labeled bacteria that adhered to the surface more extensively after deposition of platelets on ECM. Platelet pre-treatment with prostaglandin E1 resulted in inhibition of bacterial adherence. Glycoprotein (GP)Ib was involved in the bacterium-platelet interaction, as indicated by the following: (i) S. aureus diminished the binding of GPIb but not of GPIX or GPIIb-IIIa monoclonal antibodies (Mab) to washed fixed platelets; (ii) GPIb Mab inhibited S. aureus -induced platelet aggregation in a dose-dependent fashion; (iii) blockade of von Willebrand factor (vWf) binding to GPIb by a recombinant vWf fragment reversed the enhanced platelet deposition on ECM in the presence of S. aureus but did not affect platelet deposition in the absence of bacteria. The results indicate that S. aureus activates platelets and promotes their deposition on ECM via GPIb-dependent mechanism and that adherent platelets mediate S. aureus deposition on the subendothelium. These interactions might play a role in the pathogenesis of bacterial endocarditis.     

Activated platelets mediate Staphylococcus aureus deposition on subendothelial extracellular matrix: the role of glycoprotein Ib

Extracellular matrix (ECM) derived from bovine corneal endothelial cells was used as a model to study the role of platelets in Staphylococcus aureus interaction with the vascular subendothelium. In whole blood, S. aureus activated platelets, as demonstrated by P-selectin expression on the platelet membrane. Subjecting platelet-rich plasma (PRP) to the ECM under oscillatory conditions resulted in platelet adhesion and aggregation. S. aureus increased platelet deposition on ECM depending on the bacterium-platelet ratio. Scanning electron microscopy revealed that S. aureus adhered to and formed clusters on ECM-bound platelets. These findings were confirmed by using [3H]thymidine-labeled bacteria that adhered to the surface more extensively after deposition of platelets on ECM. Platelet pre-treatment with prostaglandin E1 resulted in inhibition of bacterial adherence. Glycoprotein (GP)Ib was involved in the bacterium-platelet interaction, as indicated by the following: (i) S. aureus diminished the binding of GPIb but not of GPIX or GPIIb-IIIa monoclonal antibodies (Mab) to washed fixed platelets; (ii) GPIb Mab inhibited S. aureus -induced platelet aggregation in a dose-dependent fashion; (iii) blockade of von Willebrand factor (vWf) binding to GPIb by a recombinant vWf fragment reversed the enhanced platelet deposition on ECM in the presence of S. aureus but did not affect platelet deposition in the absence of bacteria. The results indicate that S. aureus activates platelets and promotes their deposition on ECM via GPIb-dependent mechanism and that adherent platelets mediate S. aureus deposition on the subendothelium. These interactions might play a role in the pathogenesis of bacterial endocarditis.     

Treatment of rolling neutrophils with antineutrophil cytoplasmic antibodies causes conversion to firm integrin-mediated adhesion

OBJECTIVE: The vascular lesions associated with autoimmune small-vessel vasculitis may arise from activation of circulating neutrophils by antineutrophil cytoplasmic antibodies (ANCA), resulting in increased adhesion of these neutrophils to the vessel wall. The present study examined the effects of ANCA-positive IgG (ANCA IgG), derived from patients with small-vessel vasculitis, on neutrophil adhesion. METHODS: An in vitro, flow-based adhesion assay was used to determine the effects of ANCA IgG on neutrophils rolling on P-selectin presented by a monolayer of activated platelets. The platelets act as a surrogate vessel wall and can also support beta2 integrin-mediated immobilization of neutrophils if they are purposefully activated (e.g., by FMLP). RESULTS: In the absence of any added agents, neutrophils rolled continuously over the platelet monolayer. Superfusion of ANCA IgG over rolling cells resulted in conversion to stationary adhesion accompanied by shape change. The ANCA-mediated response was transient, peaking at 5-6 minutes and returning to baseline by 15 minutes, even in the continued presence of ANCA. In contrast, normal (ANCA-negative) IgG and ANCA F(ab')2 fragments caused minimal conversion to stationary adhesion. Pretreatment of neutrophils with blocking antibodies directed toward Fc gamma receptor type IIA or the integrin chain CD11b completely inhibited the ANCA-mediated conversion, confirming that ANCA-mediated activation occurred through Fc gamma receptors and that neutrophil immobilization was mediated by the activated beta2 integrin (CD11b/CD18). CONCLUSION: These findings support the concept that ANCA can directly activate neutrophils to become firmly adherent to vessel walls, where they may obstruct flow, initiate tissue damage, and contribute to pathogenesis of vasculitis.     

Boundary events: contact-dependent and contact-facilitated signaling between platelets

The theme of this review is that formation of a stable hemostatic plug requires adhesive interactions and signaling events that continue beyond the initial phases of platelet aggregation. These interactions and events are facilitated and, in some cases made possible, by the persistent close contacts between platelets that can only occur after the onset of aggregation. The molecules that are involved include integrins, cell adhesion molecules, receptor tyrosine kinases, and ligands that are either attached to or shed from the surface of activated platelets. The picture that emerges is one in which events after aggregation are nearly as complex as those that precede aggregation and the initiation of platelet plug formation.     

Immobilized platelets support human colon carcinoma cell tethering, rolling, and firm adhesion under dynamic flow conditions

Accumulating evidence suggests that successful metastatic spread may depend on the ability of tumor cells to undergo extensive interactions with platelets. However, the mechanisms mediating tumor cell adhesion to platelets under conditions of flow remain largely unknown. Therefore, this study was designed to analyze the ability of 3 human colon carcinoma cell lines (LS174T, COLO205, and HCT-8) to bind to surface-anchored platelets under flow and to identify the receptors involved in these processes. Immobilized platelets support LS174T cell adhesion at wall shear stresses up to 1.4 dyn/cm(2). Our data suggest that platelets primarily recruit LS174T cells through a 2-step, sequential process of adhesive interactions that shares common features but is distinct from that elaborated for neutrophils. Platelet P-selectin mediates LS174T cell tethering and rolling in a PSGL-1- and CD24-independent manner. Moreover, platelet alpha(IIb)beta(3)-integrins appear to be capable of directly capturing LS174T cells from the fluid stream, and also convert instantaneously transient tethers initiated by P-selectin into stable adhesion. This step is at least partially mediated by von Willebrand factor, but not fibrinogen or fibronectin, that bridges platelet alpha(IIb)beta(3) with a yet unidentified receptor on the LS174T cell surface via an RGD-dependent mechanism. The sequential engagement of platelet P-selectin and alpha(IIb)beta(3) is also requisite for the optimal adhesion of COLO205. Furthermore, HCT-8 cells, which fail to interact with P-selectin, tether minimally to surface-anchored platelets under flow, despite their extensive adhesive interactions under static conditions. This cascade of events depicts an efficacious process for colon carcinoma arrest at sites of vascular injury. (Blood. 2000;96:1789-1797)     

Platelet adhesion onto a polystyrene surface under static conditions: role of specific platelet receptors and effect of divalent cations

An experimental model was used to elucidate the basic mechanisms involved in the interaction of platelets with an artificial surface. The role of divalent cations and the involvement of specific platelet membrane receptors were evaluated. Isolated platelets were allowed to interact with a polystyrene surface for 20 min in the presence of divalent cations (Ca2+, Mg2+ or Zn2+), a chelating agent (ethylenediaminetetraacetic, EDTA), and specific antibodies to the main platelet receptors, glycoproteins (GP) Ib and IIb-IIIa. The degree of platelet interaction was evaluated using light and electron microscopy. Morphometric analysis was performed to follow up the progression of platelet shape changes after surface activation. Neither Ca2+ nor Mg2+ influenced the number of adherent platelets or the degree of spreading on the polymer. Only Zn2+ induced a statistically significant increase in the rate of platelet adhesion (P<0.01) with higher proportion of fully spread platelets (P<0.01). Chelation of internal pools of divalent cations did not modify the rates of platelet adhesion but prevented platelet spreading. Presence of monoclonal antibodies to GPIb and GP IIb-IIIa did not result in significant differences in the studied parameters. These results suggest that platelet adhesion onto artificial surfaces, in the absence of flow and plasma proteins, is more dependent on cellular motility, where Zn2+ could play an important role, and less dependent on major receptorial mechanisms.     

Platelet-induced neutrophil activation: platelet-expressed fibrinogen induces the oxidative burst in neutrophils by an interaction with CD11C/CD18

Summary. Mutual contacts and platelet-expressed fibrinogen seem to be required for the stimulation of neutrophils by activated platelets. The β₂-integrins CDllb/CD18 and CDllc/CD18 are potential receptors for fibrinogen on neutrophils. In order to investigate whether binding of fibrinogen to these integrins is involved, monoclonal antibodies (MoAbs) and Gly-Pro-Arg-Pro (GPRP) peptide that inhibits fibrinogen binding to CDllc/CD18 were checked for their effects on the interaction of activated platelets and neutrophils. The luminol-amplified chemilumi-nescence (CL) as a measure for the oxidative burst of neutrophils was recorded simultaneously to the platelet aggregation in mixed cell suspensions. The adhesion of platelets and neutrophils was determined microscopically. The thromboxane A₂ mimetic U46619 was used as a potent platelet agonist but that does not stimulate neutrophils. Stimulation of the platelets with U46619-induced platelet aggregation and a strong CL of neutrophils. The platelet-induced activation of neutrophils required added fibrinogen which fibronectin or thrombospondin could not substitute for. Cytochalasin D (Cyto D) that blocks actin polymerization totally abrogated the platelet-induced CI of neutrophils. The MoAb OKM1 against CDllb, which blocks fibrinogen binding to CDllb/CD18 as well as the MoAbs I0T16 and IOT18 directed against CDlla and CD18, respectively, had no effect. In contrast, the MoAb LeuM5 which inhibits the binding of fibrinogen to CDllc/CD18 revealed a strong inhibition. Furthermore, GPRP peptide which CDllc/CD18 recognizes on the Aa-chain of fibrinogen also strongly inhibited the platelet-induced CL of neutrophils, whereas control peptides such as Gly-His-Arg-Pro (GHRP) or Gly-Pro-Gly-Gly (GPGG) had no effect. In contrast to the platelet-induced CL of neutrophils, Cyto D, MoAb against CD11c and GPRP peptide did not inhibit the CL induced by FMLP and PAF in pure neutrophil suspensions. They also did not affect U46619-induced platelet aggregation. The adhesion of platelets and neutrophils was neither dependent on added fibrinogen nor inhibited by Cyto D, MoAb against CD1 lc and the GPRP-peptide. Therefore fibrinogen and actin polymerization seem not to be required for the adhesion of neutrophils to platelets. However, the activation of neutrophils depends on the interaction of CDllc/CD18 with the Aa-chain of platelet-expressed fibrinogen and the contractile system of neutrophils.