Platelets are thought to play a causal role during atherogenesis. Platelet-endothelial interactions in vivo and their molecular mechanisms under shear are, however, incompletely characterized. Here, an in vivo platelet homing assay was used in hypercholesterolemic rabbits to track platelet adhesion to plaque predilection sites. The role of platelet versus aortic endothelial cell (EC) activation was studied in an ex vivo flow chamber. Pathways of human platelet immobilization were detailed during in vitro perfusion studies. In rabbits, a 0.125% cholesterol diet induced no lesions within 3 months, but fatty streaks were found after 12 months. ECs at segmental arteries of 3- month rabbits expressed more von Willebrand factor (VWF) and recruited 5-fold more platelets than controls (P < .05, n = 5 and 4, respectively). The 3-month ostia had an increased likelihood to recruit platelets compared to control ostia (56% versus 18%, P < .0001, n = 89 and 63, respectively). Ex vivo, the adhesion of 3-month platelets to 3-month aortas was 8.4-fold increased compared to control studies (P < .01, n = 7 and 5, respectively). In vitro, endothelial VWF–platelet glycoprotein (GP) Ib and platelet P-selectin– endothelial P-selectin glycoprotein ligand 1 interactions accounted in combination for 83% of translocation and 90% of adhesion (P < .01, n = 4) of activated human platelets to activated human ECs. Platelet tethering was mainly mediated by platelet GPIbα, whereas platelet GPIIb/IIIa contributed 20% to arrest (P < .05). In conclusion, hypercholesterolemia primes platelets for recruitment via VWF, GPIbα, and P-selectin to lesion-prone sites, before lesions are detectable.

Platelets can be identified in atherosclerotic lesions at all stages.1,2 A contribution of platelets to the early stages of atherosclerotic lesion development has been postulated.3 4 Experimental evidence demonstrating platelet recruitment to the endothelial layer at lesion-prone sites in response to atherogenic stimuli is, however, lacking.

Platelet-endothelial interactions have been characterized in static assays and in venous shear conditions, but the adhesion pathways involved in interactions requiring higher tensile strength, as prevailing in the arterial vasculature, remain elusive. In static adhesion assays, the integrin αIIbβ3, bridging with various partners on endothelial cells (ECs), among which intercellular adhesion molecule 1 (ICAM-1), αvβ3 integrin, and possibly glycoprotein Ibα (GPIbα), played the major role in mediating platelet adhesion to activated human umbilical vein endothelial cells (HUVECs).5 In arterial shear conditions, even at sites of turbulent flow, the contribution of individual adhesion pathways may vary.

The interaction of platelets with subendothelial matrix in high shear conditions has been well characterized and is primarily mediated by engagement of platelet GPIbα with von Willebrand factor (VWF), present in the subendothelial matrix of healthy and diseased vessels.6-8 VWF is synthesized by ECs, stored in the Weibel-Palade bodies, and secreted on endothelial activation.9 Increased plasma VWF levels are associated with cardiovascular disease.10 VWF mediates the interaction between platelets and inflamed microvascular ECs in rather low shear conditions.11 

In arterial shear conditions activated platelets can deliver monocytes to activated ECs via P-selectin.12 Activated mesentery venule endothelium also supports platelet adhesion through endothelial P-selectin.13 Gene targeting studies have established that lesion development is delayed in atherosclerosis-susceptible mice that lack P-selectin. The role of P-selectin for leukocyte versus platelet recruitment could not, however, be distinguished.14 The link between atherogenic endothelial activation, VWF, and P-selectin and platelet recruitment to lesion-prone sites has therefore not been established.

In the present study in vivo, ex vivo, and in vitro approaches were used to examine whether experimental hyperlipidemia induces platelet recruitment from the bloodstream to the endothelial layer at lesion-prone sites and to identify shear-dependent adhesion pathways involved.

Reagents and materials

Cell culture reagents, Hanks balanced salt solution (HBSS), phosphate-buffered saline (PBS), trypsin/EDTA, fetal bovine serum (FBS), and penicillin/streptomycin (10 000 U/mL and 10 000 μg/mL) were purchased from Gibco, Life Technologies (Paisley, United Kingdom). Formaldehyde, paraformaldehyde, and microscopic glass coverslips were from VEL (Haasrode, Belgium), sterilized in 70% propanol, washed in PBS, and coated with tissue culture grade calf skin collagen I from Boehringer Mannheim (Mannheim, Germany). Tissue culture dishes were from Becton Dickinson Labware (Maylan Cedex, France). Uncoated Petri dishes were from Sterilin (Staffordshire, United Kingdom). For flow chamber experiments, rinsing of HUVECs or Ea.hy926 monolayers and reconstitution of perfusate with packed red blood cells (Red Cross, Leuven, Belgium) to a hematocrit of 20%, was done with 1% bovine serum albumin (Boehringer Mannheim), 2 mM CaCl2, and 2 mM MgCl2 (Sigma, St Louis, MO), added to HBSS. For the preparation of pH 6.5 acid-citrate-dextrose (ACD), Na3citrate (75 mM) and dextrose (100 mM) were purchased from VEL. Citric acid (38 mM) was obtained from Sigma. 2′,7′-bis-(2-carboxyethyl)-5-6-carboxyfluorescein-acetoxymethyl ester (BCECF-am), cell tracker green (5-chloromethylfluorescein [CTG]), and cell tracker red (5-chloromethylrhodamine [CTR], Molecular Probes Europe, Leiden, The Netherlands) were dissolved in dimethyl sulfoxide (DMSO), aliquoted, and stored at −20°C until use. The human 14–amino acid form (SFLLRNPNDKYEPF; single-letter amino acid codes) of thrombin receptor-activating peptide (TRAP) was custom synthesized by Eurogentec (Seraing, Belgium).

Monoclonal antibodies

The neutralizing monoclonal anti–P-selectin antibody CLB-Thromb/6 (mouse IgG1, Immunotech, Marseille, France) was used at 2.5 μg/mL. The anti-CD34 control antibody, Birma-K3 (mouse IgG1, Dako, Glostrup, Denmark) was used at concentrations corresponding to those of the blocking antibodies. The GPIIb/IIIa blocking antibody MA-16N7C215 and the GPIbα blocking antibody G19H10 were raised and characterized in our laboratory, as described elsewhere.16 A nonblocking anti-GPIbα antibody raised in the laboratory was also used as a control. The VWF-A1 domain-blocking antibody AJvW-2 was from Ajinomoto (Yokohama, Japan).17 The monoclonal anti–P-selectin antibody WAPS12.2 was purchased from American Type Culture Collection (Rockville, MD).

Animal protocols

All animal procedures have been approved by the local Institutional Review Board. New Zealand white rabbits were placed on a chow sprayed with ether-dissolved pure cholesterol to achieve a concentration of 0.125% (wt/wt) cholesterol. Control rabbits received the same chow without cholesterol. The diet regimen was maintained for the indicated times. For injection of anesthetics and labeled platelets in the homing assays, a 22-gauge catheter was inserted into the ear vein of conscious rabbits. For withdrawal of blood, the ear artery was instrumented with a 20-gauge catheter. Lipid profiles were determined in arterial blood in the university hospital routine laboratory. To euthanize, rabbits were sedated with ketamine (10 mg/kg) and xylazine (10 mg/kg) intramuscularly. Pentobarbital (5 mg/kg) was injected intravenously to maintain adequate anesthesia.

Platelet isolation

Rabbit or human whole blood was drawn on 0.1 vol ACD and centrifuged at 150g for 10 minutes to obtain platelet-rich plasma (PRP), which was diluted 1:1 with ACD and centrifuged at 600g for 10 minutes. The resulting pellet was resuspended in HBSS, and 0.3 vol ACD was added before the final washing step at 600g for 10 minutes. Platelets were counted, resuspended in HBSS, and stored at room temperature for use within 3 hours.

Platelet homing assay

Rabbits used as recipients for the homing assays (ie, control and 3-month groups), were age-matched. Pooled autologous rabbit platelets were adjusted to 300 000/μL and CTG was added at 1 μM for 30 minutes at 37°C. Platelets were washed at 600g, resuspended in HBSS, and left resting at 37°C for 20 minutes to facilitate sulfatation and cytosolic entrapment of the dye. These platelets aggregated comparably to unlabeled washed platelets for labeling concentrations of CTG up to 1 μM (data not shown). Circulating labeled platelets were detectable until 48 hours after injection (data not shown). Then, 1 × 109 CTG-labeled platelets/kg body weight were slowly injected intravenously. Aortas were harvested 72 hours after platelet injection. Low-molecular-weight heparin (500 IU) was injected to avoid artificial postmortem platelet adhesion. The chest was opened and 10 mL blood was drawn from a left ventricular cannula for lipid profiles. Then, 0.9% saline containing 1 IU heparin/mL was infused at 80 mm Hg from a pressure bag until no blood was flowing from a caval venotomy at the level of the renal veins. The aorta was dissected from the arch until the bifurcation. Adventitial tissue was carefully removed and the vessel was opened longitudinally. To facilitate recognition of the endothelial cell plane, the whole aorta was counterstained in 10 mL HBSS containing 1 μM CTR for 45 minutes. The vessel was carefully rinsed and placed in binding buffer until examined by confocal scanning laser microscopy on the same day (LSM510, Zeiss, Oberkochen, Germany). All ostia of segmental arteries as well as the superior and inferior mesenteric artery ostia were examined for green- and red-labeled platelets. The total number of platelets per aorta as well as the number of ostia that did or did not recruit platelets was recorded.

Flow cytometry

P-selectin on platelets from hypercholesterolemic or control rabbits was stained using monoclonal antibody (mAb) Psel.KO.2.10, kindly provided by Dr. Pizcueta (Barcelona, Spain). Hence, 10 μL PRP, supplemented with CaCl2 to 1 mM and with the GPIIb/IIIa antagonist G4120 (Genentech, San Francisco, CA) to 10 μg/mL in a volume of 25 μL, was added directly to an equal volume of spent medium of this antibody or was first activated for 15 minutes with 50 μg/mL equine tendon collagen (Horm collagen, Nycomed Arzneimittel, München, Germany). Platelets were washed via centrifugation after 30 minutes and resuspended in 50 μL tris(hydroxymethyl) aminomethane–buffered saline (TBS). Then 2.5 μL secondary goat antimouse Ig antibodies, conjugated to fluorescein isothiocyanate (FITC; Dako) were added for 15 minutes, following which samples were 10-fold diluted in TBS. Gated by forward versus side scatter, the percentage of fluophor-labeled platelets was determined by flow cytometry (FACScan Calibur, Becton Dickinson) at wavelength 488 nm and the mean fluorescence calculated as a marker of platelet activation.

Sudan black staining

To determine lesion coverage of aortic surface, vessels were fixed in 4% formaldehyde overnight, stored in PBS, and transferred to 70% ethanol for 2 hours before staining. Vessels were incubated in a saturated and filtered solution of Sudan black B (Merck, Darmstadt, Germany) in 70% ethanol for 90 minutes and then washed repeatedly in 70% ethanol. The aortas were scanned en face. The total vessel area and the stained area were measured using NIH-Image 1.62. Data are presented as percentage lesion coverage.

Scanning electron microscopy

To exclude that platelets in the ex vivo experiments were recruited to subendothelial matrix at sites where ECs had been removed, segments after flow chamber experiments were examined by scanning electron microscopy. After completion of the superfusion, the vessel segment was washed with buffer in the flow chamber. Immersion fixation was achieved by perfusing the chamber with cacodylate buffer (0.1 M, pH 7.4) containing 1.5% glutaraldehyde for 20 minutes at 4°C; then the vessel was cut into 1-cm segments and placed in fresh cacodylate-glutaraldehyde buffer overnight at 4°C. Vessels were dehydrated for 15 minutes in 30%, 50%, 70%, and 90% acetone at 4°C followed by a 100% acetone step at room temperature. Tissues were critical point dried, mounted on an aluminum stub, and covered with a thin layer of gold (20 nm). Specimens were examined with a scanning electron microscope (Philips, XL-20, Eindhoven, The Netherlands).18 

Platelet-endothelial interactions in an ex vivo flow chamber model

The descending thoracic aorta of control and 3-month rabbits was dissected, freed from adventitial tissue, and opened longitudinally. The vessel was divided into 3 segments of approximately 2 cm length each and one segment at a time was mounted face down on the slit of a flow chamber module. The flow chamber was 0.5 mm wide and 1.5 cm long. The vessel was spread across the ceiling of the flow chamber with a semilunar piece of elastic polyethylene tubing. This maneuver sealed the chamber when the lid was screwed down. After washing, platelets from control or hypercholesterolemic rabbits were labeled with 2 μM BCECF-am. Platelet-free, reconstituted blood was spiked with 10 000 BCECF-labeled platelets/μL. This suspension was superfused for 5 minutes at 24 dynes/cm2 using a Harvard Instruments precision pump in volume displacement mode. Five movies from 5 different high-power fields were recorded to analyze dynamic interactions between platelets and aortic endothelium. At the superfusion end, 15 high-power fields (0.9 mm2 in total) were recorded. Details of the off-line analysis of translocating and firmly adhering platelets are described elsewhere.12 

In vivo VWF expression

AJvW-2 was labeled with 125I in PBS, using Iodogen-labeled beads (Pierce, Rockford, IL) for 15 minutes at a protein concentration of 2 mg/mL and 2 beads/mL. Nonbound radioactivity was removed by gel filtration on a PM10 column (Pharmacia, Uppsala, Sweden). Aortas from 3-month rabbits and control rabbits were rinsed with saline and opened longitudinally, spread, and pinned onto a solid support, following which 125I-AJvW-2 (106cpm/mL, 0.2 mg AJvW-2/mL) was deposited onto the luminal surface and incubated overnight at 4°C in a humidified tank. Following 3 rinsing steps of 5 minutes with saline, the vessels were exposed to autoradiography for 3 days at −80°C. Autoradiographs were developed, scanned, and superimposed on the aorta segments to spatially match the radioactive spots and the branching of the segmental arteries.

In vitro flow chamber studies

The Ea.hy926 endothelial cells from passage 98 to 111 or HUVECs (passage 3-5) were grown in Dulbecco modified Eagle medium (DMEM) or medium 199 supplemented with 10% FBS or 10% human serum, 100 mg/mL penicillin, and 100 U/mL streptomycin. Endothelial monolayers were established on glass coverslips as described previously.12 These monolayers were stained immunohistochemically for the presence of VWF (rabbit anti-VWF antibodies from Dako, coupled to peroxidase), P-selectin (monoclonal anti–P-selectin antibody WAPS12.2, ATCC), and GPIbα using the homemade mAb G28E5.19 In all experiments, Ea.hy926 cells or HUVECs were activated overnight by addition of 5 μM palmitoyl-lysophosphatidylcholine (LPC) to the media.20Confluent coverslips were mounted in a conventional parallel plate flow chamber. Human platelets at 300 000/μL were activated with 100 μM TRAP for 10 minutes immediately prior to spiking of reconstituted blood with 10 000 platelets/μL. This suspension was superfused over the coverslips at 24 dynes/cm2. Blocking antibodies were added to the platelet suspension 5 minutes prior to superfusions. The protocol for the parallel plate flow chamber studies and analysis of the data are described elsewhere.12 

Data analysis and statistical methods

Data were processed in InStat 2.03, GraphPad Software (San Diego, CA). For overall comparison between groups nonparametric Kruskal-Wallis ANOVA was performed. For detection of differences between groups, Wilcoxon testing was used. To assess differences in platelet recruitment at the segmental artery ostia, Fisher exact test was used. P < .05 was considered significant. Data are reported as mean ± SEM.

Lipid profiles and atherosclerotic lesion formation

The cholesterol diet induced mild low-density lipoprotein (LDL) hypercholesterolemia at 3 months that persisted over 12 months with a concomitant increase in high-density lipoprotein (HDL). Triglycerides were not affected by the diet (Table 1). In rabbits that were on a control diet or on a cholesterol diet for 3 months (3 mo) no lesions were found in the aortic arch in hematoxylin-eosin–stained microscopic sections. The diet proved, however, to be atherogenic, because in rabbits that were maintained on the cholesterol diet for 12 months (12 mo), rather large fatty streak lesions were found in the arch (Figure1A). In en face stainings, 21% ± 6% of the surface of 12 mo aortas (n = 3) was covered with Sudan black staining lesions, typically spreading out from arterial branching points. Only 2.7% ± 0.9% of 3 mo (n = 4,P < .05 versus 12 mo) and 1.6% ± 0.5% of control aorta surfaces (n = 4, P < .05 versus 12 mo,P = NS versus 3 mo) were stained by Sudan black (Figure 1B).

Table 1.

Effect of the 0.125% cholesterol diet on plasma lipid profiles

DietTotal cholesterol (mg/dL)LDL cholesterol (mg/dL)HDL cholesterol (mg/dL)Triglycerides (mg/dL)
Control 26 ± 2 2 ± 1.5 17 ± 2 49 ± 7 
3 mo 140 ± 35* 87 ± 30* 42 ± 8* 49 ± 9 
12 mo 110 ± 12* 45 ± 9* 49 ± 7* 54 ± 24 
DietTotal cholesterol (mg/dL)LDL cholesterol (mg/dL)HDL cholesterol (mg/dL)Triglycerides (mg/dL)
Control 26 ± 2 2 ± 1.5 17 ± 2 49 ± 7 
3 mo 140 ± 35* 87 ± 30* 42 ± 8* 49 ± 9 
12 mo 110 ± 12* 45 ± 9* 49 ± 7* 54 ± 24 
*

P < .05 versus control.

Fig. 1.

Hypercholesterolemia-induced platelet recruitment to lesion-prone sites in vivo as established by a platelet homing assay.

(A) Rabbit thoracic aortas developed prominent lesions after 12 months of a 0.125% cholesterol diet (right panel), whereas after 3 months no lesions were observed in hematoxylin/eosin staining (left panel). (B) Sudan black staining revealed no detectable lesions in en face preparations of control and 3 mo aortas (left and middle panels) used to quantify platelet homing, whereas 12 mo aortas (right panel) displayed profound lesion development at segmental artery branching points; arrows indicate mesenteric artery ostia; arrowheads, segmental artery ostia. (C) Following injection of autologous platelets labeled with the fluophor CTG, the aortas were dissected after 72 hours. They were counterstained with 1 μM CTR to facilitate recognition of the endothelial plane in en facescanning confocal microscopy. Homed platelets are detected by FITC-fluorescence and display fluorescent double-staining appearing yellow (arrows). (D) Five-fold more platelets were recruited to lesion-prone sites of cholesterol-fed rabbits compared to controls. No platelets were detected at the anterior aspect of the aorta or elsewhere outside of branching points. (E) In diet rabbits the likelihood for a segmental artery ostium to recruit platelets in 72 hours was significantly increased.

Fig. 1.

Hypercholesterolemia-induced platelet recruitment to lesion-prone sites in vivo as established by a platelet homing assay.

(A) Rabbit thoracic aortas developed prominent lesions after 12 months of a 0.125% cholesterol diet (right panel), whereas after 3 months no lesions were observed in hematoxylin/eosin staining (left panel). (B) Sudan black staining revealed no detectable lesions in en face preparations of control and 3 mo aortas (left and middle panels) used to quantify platelet homing, whereas 12 mo aortas (right panel) displayed profound lesion development at segmental artery branching points; arrows indicate mesenteric artery ostia; arrowheads, segmental artery ostia. (C) Following injection of autologous platelets labeled with the fluophor CTG, the aortas were dissected after 72 hours. They were counterstained with 1 μM CTR to facilitate recognition of the endothelial plane in en facescanning confocal microscopy. Homed platelets are detected by FITC-fluorescence and display fluorescent double-staining appearing yellow (arrows). (D) Five-fold more platelets were recruited to lesion-prone sites of cholesterol-fed rabbits compared to controls. No platelets were detected at the anterior aspect of the aorta or elsewhere outside of branching points. (E) In diet rabbits the likelihood for a segmental artery ostium to recruit platelets in 72 hours was significantly increased.

Close modal

Platelet homing assay

The platelet suspension used for homing assays contained less than 1% leukocytes. Virtually all platelets were detectable in fluorescence microscopy and flow cytometry (data not shown). At the time of death, 72 hours later, adherent platelets were exclusively detected in the immediate vicinity of segmental arteries (Figure 1C). No platelets were found adherent to the endothelium overlaying the anterior aspect of the aorta, which is not considered a plaque predilection site, except for the ostia of the 2 large mesenteric arteries, where platelets had been recruited in some rabbits. On average, 17 ostia were examined. In rabbits fed the cholesterol chow for 3 months, 14 ± 2.6 platelets were detected on all segmental artery ostia (P = .015) compared to 3.3 ± 0.85 platelets on all segmental artery ostia of control aortas (n = 4) (Figure 1d). One to 3 platelets were found per ostium. In normal rabbits only 18% of 63 examined ostia had recruited platelets compared to 56% of 89 ostia examined in hyperlipidemic rabbits (P < .0001; Figure 1E).

Role of platelet versus EC activation for platelet adhesion ex vivo

Perfusion experiments yielded individual platelets adhering to the endothelial monolayer of the aortas. The endothelial layer was intact until after the perfusions as evidenced by scanning electron microscopy (Figure 2A). On aortic segments from control rabbits 9.1 ± 5.8 platelets/50 s (n = 7) translocated in the EC plane (Figure 2B). This resulted in 32 ± 8.6 firmly adhering platelets/0.9 mm2 at the end of the experiment (Figure 2C). Translocation and adhesion of 3 mo platelets were 3.2-fold (P < .05, n = 5) and 3-fold increased (P < .05, n = 5). Platelets from 12 mo rabbits translocated 4.8-fold (P < .05, n = 4) and adhered 3.8-fold (P < .05, n = 4) more avidly to control segments compared to control platelets. The 3 mo and 12 mo platelet translocation and adhesion were similar. The 3 mo aortas recruited 3.2-fold (P < .01, n = 5) more translocating and 4.3-fold (P < .01, n = 5) more adhering control platelets compared to control endothelium. When 3 mo platelets and 3 mo aortic segments were combined in the flow chamber, a further 1.7-fold increase (P < .01, n = 5) in translocating and a 2-fold increase (P < .05, n = 5) in adhering platelets was observed compared to the control/control combination. Translocation and adhesion of 12 mo platelets superfused over 3 mo aortic segments was similarly increased.

Fig. 2.

Augmented platelet recruitment in response to hyperlipidemia.

Segments of the thoracic aorta were mounted face down in a flow chamber and perfused at 24 dynes/cm2 with reconstituted blood spiked with 10 000 platelets/μL that had been labeled with BCECF-am. (A) Hypercholesterolemia itself already induced a more irregular appearance of the endothelial monolayer (upper panels). The endothelial monolayer remained intact but the perfusion protocol induced slight morphologic changes, as evidenced by the rougher endothelial surface after perfusion in scanning electron microscopy, which were not different between groups (lower panels). (B,C) Hypercholesterolemia caused platelet activation as evidenced by increased translocation and firm adhesion of platelets isolated from rabbits on the diet for 3 months (3 mo) compared to control platelets on control aortas. Interestingly, the presence of lesions in the arterial tree of rabbits on the diet for a year (12 mo) did not further augment platelet translocation. Superfusion of control platelets over aortas from cholesterol-fed rabbits demonstrated an independent role for endothelial activation in response to hyperlipidemia. Endothelial and platelet activation were additive in augmenting the interaction (*P < .05; **P < .01).

Fig. 2.

Augmented platelet recruitment in response to hyperlipidemia.

Segments of the thoracic aorta were mounted face down in a flow chamber and perfused at 24 dynes/cm2 with reconstituted blood spiked with 10 000 platelets/μL that had been labeled with BCECF-am. (A) Hypercholesterolemia itself already induced a more irregular appearance of the endothelial monolayer (upper panels). The endothelial monolayer remained intact but the perfusion protocol induced slight morphologic changes, as evidenced by the rougher endothelial surface after perfusion in scanning electron microscopy, which were not different between groups (lower panels). (B,C) Hypercholesterolemia caused platelet activation as evidenced by increased translocation and firm adhesion of platelets isolated from rabbits on the diet for 3 months (3 mo) compared to control platelets on control aortas. Interestingly, the presence of lesions in the arterial tree of rabbits on the diet for a year (12 mo) did not further augment platelet translocation. Superfusion of control platelets over aortas from cholesterol-fed rabbits demonstrated an independent role for endothelial activation in response to hyperlipidemia. Endothelial and platelet activation were additive in augmenting the interaction (*P < .05; **P < .01).

Close modal

Although hypercholesterolemia was associated ex vivo with increased rolling of platelets over endothelium, flow cytometry did not detect an increase of platelet P-selectin expression on the surface of platelets circulating in rabbits fed a cholesterol-rich diet for more than 6 months.

Role of endothelial VWF for platelet recruitment

To elucidate the adhesion pathway responsible for platelet recruitment to aortic endothelium, studies using the VWF-A1 domain-blocking mAb AJvW-2 were carried out in the ex vivo flow chamber. When present during the experiment, the antibody dramatically reduced the number of 3 mo platelets translocating on and adhering to 3 mo aortic endothelium to 25% and 30% of that observed in 3 mo/3 mo experiments (P < .01, n = 4; Figure3A). To test whether VWF presented by the endothelium at predilection sites could contribute to augmented platelet recruitment, we performed autoradiographs on the aortas to probe for VWF. The iodine-labeled anti-VWF mAb AJvW-2 revealed pronounced VWF staining at segmental artery branching points in aortas of rabbits on the diet for 3 months, whereas no signal enhancement was observed in control aorta branching points (Figure 3B).

Fig. 3.

Endothelial VWF recruits platelets to the vessel wall.

(A) In the ex vivo flow chamber inhibition of the VWF-A1 domain by the blocking mAb AJvW-2 reduced translocation and firm adhesion almost to control levels (*P < .01). (B) In autoradiographs for VWF expression with the iodine-labeled antibody AJvW-2, control arteries (n = 2) did not show localized enhancement of radioactive signal. Aortas from rabbits on a diet for 3 months (n = 6, right panel) expressed VWF primarily at segmental artery ostia, indicating that hyperlipidemia induces endothelial VWF expression before lesions develop.

Fig. 3.

Endothelial VWF recruits platelets to the vessel wall.

(A) In the ex vivo flow chamber inhibition of the VWF-A1 domain by the blocking mAb AJvW-2 reduced translocation and firm adhesion almost to control levels (*P < .01). (B) In autoradiographs for VWF expression with the iodine-labeled antibody AJvW-2, control arteries (n = 2) did not show localized enhancement of radioactive signal. Aortas from rabbits on a diet for 3 months (n = 6, right panel) expressed VWF primarily at segmental artery ostia, indicating that hyperlipidemia induces endothelial VWF expression before lesions develop.

Close modal

In vitro flow chamber studies—characterization of the model

Because a wide range of adhesion molecules cannot readily be blocked in rabbits and also to extend our observations to the adhesion pathways relevant in man, we modeled the in vivo activation of platelets and ECs, as observed in the ex vivo flow chamber system, in vitro. Platelets do not readily interact with ECs if resting.13 Contact with the subendothelial lining will readily activate platelets. Platelet reactivity is enhanced in hypercholesterolemia.21 Thrombin plays a role in platelet activation during atherogenesis.3 We used platelets activated with TRAP, the synthetic thrombin receptor–activating peptide, to reproduce the observed diet-induced platelet activation. The ex vivo studies had also pointed to EC activation as a major contributor to platelet recruitment. LPC is an important bioactive component of oxidatively modified LDL and activates ECs through the platelet-activating factor (PAF) receptor as has previously been shown.20 We therefore induced EC preactivation by incubating HUVECs or the HUVEC-derived cell line Ea.hy926 overnight with palmitoyl-LPC.

If in this model TRAP-activated platelets were superfused over the HUVEC-derived immortalized EC line Ea.hy926 that had been activated with LPC, translocation increased to 23 ± 1 platelets/50 s compared to 10 ± 0.9 resting platelets/50 s (P < .001, n = 8/7, Figure 4). Firm adhesion was 2.8-fold increased (49 ± 5.6 versus 138 ± 16.4 platelets/0.9 mm2, P < .001, n = 8/7). Very similar results were obtained if primary ECs (HUVECs) were examined: HUVECs activated with LPC recruited 36 ± 3 TRAP-activated human platelets for translocation (n = 5). Translocation translated into 1300 ± 270 firmly adhering platelets/0.9 mm2 (n = 4, not shown).

Fig. 4.

Identification of the adhesion molecules mediating the interaction between activated platelets and activated endothelium.

Translocation of TRAP-activated platelets was increased 2.5 times in comparison to that of resting platelets in the in vitro flow chamber and was largely mediated by endothelial VWF-platelet GPIbα interactions and platelet P-selectin–P-selectin glycoprotein ligand 1 interactions. Platelet GPIIb/IIIa contributed for 20% to platelet adhesion (*P < .05, **P < .001).

Fig. 4.

Identification of the adhesion molecules mediating the interaction between activated platelets and activated endothelium.

Translocation of TRAP-activated platelets was increased 2.5 times in comparison to that of resting platelets in the in vitro flow chamber and was largely mediated by endothelial VWF-platelet GPIbα interactions and platelet P-selectin–P-selectin glycoprotein ligand 1 interactions. Platelet GPIIb/IIIa contributed for 20% to platelet adhesion (*P < .05, **P < .001).

Close modal

Role of VWF

Blocking the A1 domain of VWF with mAb AJvW-2 decreased translocation on Ea.hy926 cells by 60% and their adhesion by 70% (Figure 4; P < .001, n = 4). On HUVECs, the VWF-blocking mAb AJvW-2 reduced translocation by 47% and adhesion by 75% (n = 4, P < .01).

Role of P-selectin

Inhibition of P-selectin reduced translocation of activated platelets on Ea.hy926 cells by 52% and adhesion by 70% (Figure. 4;P < .001, n = 4). On HUVECs, P-selectin inhibition reduced translocation by 62% and adhesion by 48% (n = 3,P < .05).

Role of GPIb and GPIIb/IIIa

Inhibition of GPIb reduced translocation on the cell line by 45% (P < .01, n = 4); adhesion was reduced by 20% (P < .05, n = 4). No effect of GPIIb/IIIa inhibition on adhesion of resting platelets was observed (data not shown). A nonsignificant trend for decreased translocation of platelets onto Ea.hy926 cells was observed when GPIIb/IIIa was blocked. On the contrary, the adhesion of activated platelets was reduced by 20% (Figure 4; P < .05, n = 4).

Combined inhibition of VWF, P-selectin, GPIb, and GPIIb/IIIa

Combined VWF and P-selectin inhibition reduced translocation of TRAP-activated platelets on the cell line by 83% and adhesion by 90% (P < .001 versus TRAP-activated platelets andP < .05 versus AJvW-2 alone, n = 4; Figure5). Combined inhibition of GPIIb/IIIa and VWF resulted in an additional 53% inhibition of platelet adhesion on Ea.hy926 cells compared to AJvW-2 alone (P < .05, n = 4). Inhibition of GPIbα in addition to VWF inhibition significantly reduced translocation by 56% (P < .05, n = 4) and firm adhesion by 65% (P < .01, n = 4) compared to AJvW-2 alone. Use of the irrelevant control antibody against CD34 did not result in significant inhibition in either EC type (Figure 5).

Fig. 5.

GPIb-VWF–independent contributions to platelet translocation.

Combined VWF-A1 domain and P-selectin inhibition potently inhibited both translocation and adhesion, indicating that the GPIbα-mediated interactions occurred largely with the VWF-A1 domain. However, the small but significant increment in inhibition when GPIbα was blocked in addition to the VWF-A1 domain leaves some room for alternate high shear-resistant partners of GPIbα besides VWF. GPIIb/IIIa inhibition in addition to VWF-A1 domain blocking also yielded some further inhibition of adhesion, compatible with a role for GPIIb/IIIa-VWF RGD interactions during the adhesion of activated platelets (*P < .05; **P < .01).

Fig. 5.

GPIb-VWF–independent contributions to platelet translocation.

Combined VWF-A1 domain and P-selectin inhibition potently inhibited both translocation and adhesion, indicating that the GPIbα-mediated interactions occurred largely with the VWF-A1 domain. However, the small but significant increment in inhibition when GPIbα was blocked in addition to the VWF-A1 domain leaves some room for alternate high shear-resistant partners of GPIbα besides VWF. GPIIb/IIIa inhibition in addition to VWF-A1 domain blocking also yielded some further inhibition of adhesion, compatible with a role for GPIIb/IIIa-VWF RGD interactions during the adhesion of activated platelets (*P < .05; **P < .01).

Close modal

Mild LDL hypercholesterolemia specifically induced in vivo platelet recruitment to segmental artery ostia that represent plaque predilection sites before lesions become histologically detectable. No platelets were found at the anterior aspect of the aorta remote from vessel branching points. The absolute number of detectable platelets and the likelihood for individual predilection sites to recruit platelets were increased by the mild cholesterol diet. Platelet adhesion to aortic endothelium was due to increased VWF expression on the endothelial surface at lesion-prone sites. Ex vivo, platelet and endothelial activation contributed equally to increased platelet-endothelial interactions in response to hyperlipidemia and were additive. In vitro, the main adhesion pathways involved in the recruitment of TRAP-activated platelets to LPC-activated endothelial cells in flow were the VWF-GPIb axis and P-selectin.

The prominent role of platelets for thrombus formation and vessel occlusion on plaque rupture is well established.3,22Platelets may, however, also play a pivotal role in early atherogenesis before plaque fissuring or rupturing occurs.3,4 This has been suggested by the histologic identification of platelets in atherosclerotic lesions at almost all stages.2,7,8,23Platelets carry inflammatory mediators, chemokines, and growth factors such as platelet-derived growth factor (PDGF) and are capable of generating vasoactive and proaggregatory substances such as thromboxane A2.3,4 The findings presented here place the platelet at the level of endothelial injury where release of proatherogenic substances could aggravate or perpetuate endothelial injury and accelerate lesion development. Resident platelets are able to recruit leukocytes from the bloodstream and could thereby facilitate their extravasation to the subendothelial space.24 In addition, joint release of chemotactic substances by platelet and endothelium may augment monocyte adhesion to the endothelium,1 25 which is considered the first step in atherosclerotic lesion development.

Our ex vivo data support the view that activation of ECs and of circulating platelets and leukocytes occurs in the presence of atherogenic stimuli.21,26,27 Platelet and EC activation induced by hypercholesterolemia were additive in augmenting platelet margination and firm adhesion. The interaction of platelets from hypercholesterolemic rabbits with the aortic endothelium at an arterial shear rate of 24 dynes/cm2 was to a large extent mediated by VWF as evidenced by an 80% inhibition of translocation and adhesion on VWF neutralization. Evidence that patients with bleeding disorders due to the lack of functional VWF may be protected from atherosclerosis is inconclusive.28-31 Studies in cholesterol-fed pigs with VWF disease have likewise produced controversial results.32-34 VWF may bind to the endothelial surface and mediate platelet rolling in inflamed venules of the mesenteric circulation. Neither GPIbα nor a number of integrin receptors mediate VWF immobilization on endothelium, suggesting that the molecule might be held in place by endothelial heparan sulfate binding sites.11 Andre and coworkers11 observed transient VWF expression on the endothelial surface following inflammatory activation; we, however, demonstrate sustained increase of VWF expression at arterial branching points in hypercholesterolemic but not in control aortas. VWF expressed during hypercholesterolemia appears to be accessible for blood-borne platelets. VWF immobilized on the platelet surface and engaging ligands on the endothelial surface may additionally contribute to platelet recruitment. A recent study by Methia et al35 has shown that murine VWF is involved in the development of atherosclerosis in LDLR−/− mice and that half of all lesions were located at the branch points of the renal and mesenteric arteries, whereas lesions in these areas were not as prominent in VWF mice. Hence, our own and these findings show in 2 different animal models that VWF is up-regulated at branch points and is involved in platelet recruitment, in association with lesion development at these sites.

To characterize the adhesion pathways in more detail, we superfused in vitro human TRAP-activated platelets over LPC-activated ECs. LPC, a phospholipid moiety contained in oxidatively modified LDL, activates ECs through engagement of the PAF receptor, leading to Ca++signaling, vascular cell adhesion molecule 1 (VCAM-1), and ICAM-1 expression and monocyte recruitment20 36 and has thus proven to be a good activation mode for in vitro studies. Studies with mAb AJvW-2 that blocks the VWF-A1 domain, confirmed the major contribution of VWF to platelet-endothelial interactions, as had been found ex vivo.

Simultaneous inhibition of VWF and the VWF-binding domain of GPIbα suggested that a minor portion of the GPIb-mediated adhesion is independent of VWF. Mice lacking VWF still experience arterial thrombosis on vascular injury.37 The GPIb partner for this event is unknown. GPIb can engage P-selectin.38Preliminary evidence suggests that GPIb can also engage thrombospondin-1 to realize platelet adhesion at high shear.39 Our finding that Ea.hy926 cells express low amounts of GPIbα could suggest that endothelial GPIb may interact with rolling platelets through platelet ligands other than VWF.

It has been suggested that GPIIb/IIIa mediates the adhesion of platelets to cultured ECs in the absence of shear forces.5GPIIb/IIIa will, however, not support high shear interactions prevailing at the arterial wall.40 Adhesion through GPIIb/IIIa indeed disappears at shear rates more than 600 s−1.41 Fibrinogen-dependent GPIIb/IIIa interaction occurs after high tensile strength interactions between the matrix-immobilized VWF-A1 domain and platelet-GPIbα have slowed down the platelet.40 In the present study the VWF-dependent interaction was only marginally mediated through GPIIb/IIIa, which accounted for only about 20% of platelet tethering, but did contribute to arrest of translocating platelets. When the VWF-A1 domain was blocked by AJvW-2, GPIIb/IIIa inhibition further reduced platelet adhesion, presumably via the distinct Arg-Gly-Asp site located in the VWF-C1 domain. Other GPIIb/IIIa-dependent bridging interactions5 were not tested in this study. In view of the small residual interactions when VWF and GPIIb/IIIa-blocking mAbs were combined, and in view of a role for GPIbα in those interactions, it seems unlikely that ICAM-1 or αvβ3 plays a major role for platelet immobilization at high shear.

P-selectin is another VWF-independent effector of platelet adhesion. In mice lacking both the apolipoprotein E and the P-selectin gene, atherosclerotic lesion development was significantly retarded.14 However, because P-selectin plays an important role not only for platelet adhesion but also for leukocyte adhesion to activated endothelium, these data do not constitute proof that platelet recruitment is indispensable for atherosclerotic lesion development. P-selectin is sufficient for mediating tethering of platelets to inflamed endothelium in venous flow conditions.13 At arterial shear conditions, platelet rather than endothelial P-selectin is responsible for platelet-monocyte conjugate delivery to activated endothelium in vitro.12 Here, P-selectin also mediated an important portion of the adhesion of individual platelets to activated endothelium, because antibody-mediated inhibition of P-selectin reduced platelet translocation by 52%. Previous studies suggested that endothelial P-selectin recruits individual platelets for dynamic interactions.13 In our hands, activated but not resting platelets were recruited through P-selectin to LPC-activated endothelial cells, indicating that platelet P-selectin mediates platelet-endothelial interactions at high shear. The lack of P-selectin expression on circulating platelets of hyperlipidemic rabbits could suggest that platelets carrying P-selectin are rapidly cleared from the circulation, potentially as a result of platelet-EC interactions, as observed during video microscopy in atherogenic mice.35The increased interaction ex vivo of 3 mo diet platelets with normal endothelium then probably is initiated via low membrane levels of platelet P-selectin, below the limit of flow cytometric detection.

In conclusion, the present study demonstrates in hypercholesterolemic rabbits that platelets are recruited to lesion-prone sites of the arterial tree before atherosclerotic lesions are present. Thereby platelets can aggravate or perpetuate endothelial injury. Moreover, platelets adhering to endothelium overlying plaque predilection sites may provide a docking site for monocyte recruitment to the subendothelial space. High tensile strength interactions between platelets and ECs are mainly mediated through VWF, GPIb, and P-selectin. These adhesion pathways may therefore constitute therapeutic targets to prevent development of premature atherosclerosis.

Supported by the Fonds voor Wetenschappelijk Onderzoek Vlaanderen (project G.0376.01) and the Interuniversitaire Attractiepolen (program 4/34). G.T. received a postdoctoral fellowship from the Deutsche Forschungsgemeinschaft, Germany. C.M. is Research Associate of the FNRS (National Funds for Research, Belgium).

The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked “advertisement” in accordance with 18 U.S.C. section 1734.

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Author notes

Marc F. Hoylaerts, Center for Molecular and Vascular Biology, Katholieke Universiteit Leuven, Campus Gasthuisberg, O&N, Herestraat 49, B-3000 Leuven, Belgium; e-mail:marc.hoylaerts@med.kuleuven.ac.be.

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