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(American Journal of Pathology. 2005;166:945-952.)
© 2005 American Society for Investigative Pathology

L- and P-Selectins Collaborate to Support Leukocyte Rolling in Vivo When High-Affinity P-Selectin-P-Selectin Glycoprotein Ligand-1 Interaction Is Inhibited

From the Cardiovascular Research Unit, University of Sheffield, Sheffield, United Kingdom

	Abstract

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P-selectin glycoprotein ligand-1 (PSGL-1) binding to P-selectin controls early leukocyte rolling during inflammation. Interestingly, antibodies and pharmacological inhibitors (eg, rPSGL-Ig) that target the N-terminus of PSGL-1 reduce but do not abolish P-selectin-dependent leukocyte rolling in vivo whereas PSGL-1-deficient mice have almost no P-selectin-dependent rolling. We have investigated mechanisms of P-selectin-dependent, PSGL-1-independent rolling using intravital microscopy. Initially we used fluorescent microspheres to study the potential of L-selectin and the minimal selectin ligand sialyl Lewis^x (sLe^x) to interact with postcapillary venules in the absence of PSGL-1. Microspheres coated with combinations of L-selectin and sLe^x interacted with surgically stimulated cremaster venules in a P-selectin-dependent manner. Microspheres coated with either L-selectin or sLe^x alone showed less evidence of interaction. We also investigated leukocyte rolling in the presence of PSGL-1 antibody or inhibitor (rPSGL-Ig), both of which partially inhibited P-selectin-dependent leukocyte rolling. Residual rolling was substantially inhibited by L-selectin-blocking antibody or a previously described sLe^x mimetic (CGP69669A). Together these data suggest that leukocytes can continue to roll in the absence of optimal P-selectin/PSGL-1 interaction using an alternative mechanism that involves P-selectin-, L-selectin-, and sLe^x-bearing ligands.

Natural ligand mimicry is a common drug development approach. Elements of PSGL-1 required for high-affinity P-selectin recognition include a sialylated, fucosylated O-glycan and tyrosine sulfation at appropriate positions near the N-terminus.⁸ Drugs mimicking one or more of these elements could theoretically inhibit P-selectin. Inhibitors based on the carbohydrate selectin ligand, sLe^x, are effective, albeit in high doses, against E-selectin-dependent leukocyte rolling in vivo but have no measurable effect on established P-selectin-dependent rolling.⁹ Closer imitations of PSGL-1 are more effective. A recombinant fusion protein, rPSGL-Ig, of 47 amino acids from the NH₂-terminal of human PSGL-1 linked to the Fc portion of human immunoglobulin-1 (IgG₁)¹⁰ reduces established P-selectin-dependent leukocyte rolling in murine postcapillary venules by up to 60% whereas glycosulfopeptides, synthesized to mimic the high-affinity binding region of human PSGL-1,^8,11 reduce rolling by up to 70%. Antibodies targeting human or murine PSGL-1 also inhibit, but do not abolish, P-selectin-dependent rolling in vivo.^12-15 In contrast, PSGL-1-deficient mice develop negligible P-selectin-dependent leukocyte rolling in venules after surgical stimulation.¹⁶

The relevance of low-affinity ligand binding to P-selectin function in vivo is uncertain although P-selectin-dependent/PSGL-1-independent rolling has been demonstrated using an in vitro flow chamber wherein microspheres coated with a high density of sLe^x rolled on a P-selectin-coated surface.¹⁷ Although the interactions of leukocytes rolling in vivo are undoubtedly more complex than that those of beads rolling in vitro, we believe that interactions between P-selectin and low-affinity sLe^x-bearing ligands might permit some leukocyte rolling in situations in which optimal binding is absent. Such low-affinity interactions might explain the portion of leukocyte rolling that is resistant to P-selectin antagonists and PSGL-1-blocking antibodies and allow P-selectin-dependent rolling of cells that do not express fully functional PSGL-1.

Here, we investigate mechanisms of P-selectin-dependent rolling occurring in the absence of optimal P-selectin-PSGL-1 interaction. We find that coating fluorescent microspheres with a combination of L-selectin and sLe^x supports P-selectin-dependent interaction with postcapillary venules in vivo and that a sLex mimetic, CGP69669A, inhibits P-selectin-dependent leukocyte rolling that remains after treatment with either rPSGL-Ig- or PSGL-1-blocking antibody.

	Materials and Methods

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Reagents

Anti-P-selectin (RB40.34, rat IgG₁), anti-L-selectin (Mel-14, rat IgG₁), anti-mouse PSGL-1 (2PH1, rat IgG₁), RB6–8C5 (IgG_2b), and isotype control antibodies were purchased from BD Biosciences (Oxford, UK). Anti-E-selectin antibody (10E6, rat IgG_2b) was a kind gift from Dr. B. Wolitzky (Hoffman-LaRoche, Nutley, NJ). Nonfluorescent, yellow-green, and red fluorescent 1-µm Neutravidin-coated microspheres, BlockAid, and biotin-labeling kits were obtained from Molecular Probes (Eugene, OR). Human IgG was obtained from Sigma (Dorset, UK). Biotinylated sLe^x was purchased from Syntesome (Munich, Germany). Murine L-selectin/Fc chimera were purchased from R&D Systems (Oxford, UK). rPSGL-Ig was a kind gift from Dr. R. Schaub (Wyeth, Inc., Andover, MA). CGP69669A was a kind gift from Dr. G. Thoma (Novartis Pharma AG, Basel, Switzerland). All inhibitors were applied at doses previously determined to provide maximum blockade of their respective ligands.^9,14,18,19

Microspheres

IgG and L-selectin were biotinylated using a kit according to the manufacturer’s (Molecular Probes) instructions. Conditions for coating microspheres with biotinylated reagents were determined by attaching different fluorescent biotinylated ligands to nonfluorescent microspheres followed by flow cytometry. For in vivo studies, yellow-green or red fluorescent microspheres (0.07 ml, 1 µm in diameter) were coated with biotinylated human IgG, sLe^x, L-selectin, or a combination of both L-selectin and sLe^x. L-selectin coating was performed at a concentration (10 µg/ml) 1/10th that determined previously to support L-selectin-dependent rolling²⁰ and biotinylated sLe^x coating was performed at 200 µg/ml to saturate the remaining 90% of the microsphere surface. Saturating concentrations (200 µg/ml) of IgG were used for control microspheres. After coating with ligands of interest, microspheres were incubated with a commercial solution (BlockAid) according to the manufacturer’s instructions to ensure covering of all reactive sites on the bead surface and reduce nonspecific bead interactions in vivo.

Animals

Male C57BL/6 (Harlan, Oxford, UK) and L-selectin knockout mice (25 to 30 g) were used.²¹ All procedures were approved by the University of Sheffield ethics committee and performed in accordance with the UK Home Office Animals (Scientific Procedures) Act 1986.

Intravital Microscopy

Observations of leukocyte and microsphere interactions in venules of the mouse cremaster were performed as described.²² Mice were anesthetized with an intraperitoneal injection (12.5 µl/g) of a mixture consisting of 10 mg/ml of ketamine hydrochloride (Ketaset; Willows Francis Veterinary, Crawley, UK), 1 mg/ml of xylazine hydrochloride (Bayer, Suffolk, UK), and 0.02 mg/ml of atropine sulfate (Phoenix Pharmaceuticals Ltd., Gloucester, UK). Cannulations of the trachea, jugular vein, and carotid artery were performed, and the cremaster muscle exposed and spread over a specialized viewing platform. Temperature was controlled using a thermistor-regulated heating pad (PDTronics, Sheffield, UK) and the cremaster was superfused with thermocontrolled (36°C) bicarbonate-buffered saline. Venules were observed 10 to 30 minutes after surgical stimulation of cremaster, when leukocyte rolling is exclusively P-selectin-dependent.¹⁸ Mice were treated with a neutrophil-depleting antibody (RB6-8C5, 10 µg, i.v.) before experiments studying microsphere interactions. Depleting neutrophils in this manner prevents leukocyte rolling without altering microsphere interactions with P-selectin.²²

Venules were observed using a Nikon E600 FN microscope (Nikon UK) equipped with a water immersion objective (x20/0.5 W). Passage of fluorescent microspheres through observed venules was observed by dual-flash stroboscopic (100 s^–1, Strobex 11360; Chadwick Helmuth, Mountain View, CA) epifluorescence illumination. Rolling leukocytes were observed by bright-field illumination.

Fluorescent images were recorded using a silicone-intensified target camera (VE1000SIT; Dage MTI Inc., MI) and bright-field images were recorded using a charge-coupled device camera (DC330EX; Dage MTI Inc.) onto sVHS videocassettes for later analysis. Microspheres injected into the carotid artery in 50-µl boluses could be observed in the cremaster circulation within 20 seconds and typically circulated for 1 to 2 minutes. These kinetics allowed microspheres with different coatings to be studied within the same vessels. Centerline velocities of observed venules were either measured using commercially available hardware and software (Microvessel Velocity OD-RT System; Circusoft Instrumentation LLC, Hockessin, DE) or estimated from the velocities of free-flowing microspheres occupying a central position in the vessel.

Data Analysis

Data describing behavior of leukocytes and microspheres in venules were obtained using established methods.^22,23 Leukocyte rolling fluxes before and after treatments were normalized and expressed as percentage of control rolling. In some studies we directly observed initial tethering of leukocytes to postcapillary venules. Control tethering rate within a defined region was determined before application of treatments. Tethering was then studied within the same region 1 minute after treatments. Tethering data are presented as percentage of control tethers. Velocities of leukocytes and microspheres passing through observed venules were measured from digitized video sequences using freely available software (available on the Internet at http://rsb.info.nih.gov/nih-image) and custom written macros.²³ For some vessels we also calculated critical velocity (V_Crit) as described.²⁴ Velocity of microspheres moving below V_Crit cannot be explained by hydrodynamic factors alone and thus implies adhesive interactions between the microsphere and the vessel.

Statistical Analysis

Data were analyzed using the Instat statistical analysis program (GraphPad Software, San Diego, CA). One-way analysis of variance was performed and followed by Bonferroni’s test for multiple comparisons. Results were considered significant if P < 0.05.

	Results

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L-Selectin- and sLe^x-Mediated Interaction of Fluorescent Microspheres with Surgically Stimulated Cremaster Venules

To investigate the potential for PSGL-1-independent, P-selectin-dependent adhesion under the conditions that prevail in living microvessels, we studied the interaction of fluorescent microspheres in mouse cremaster venules as described.²² Microsphere circulation times were limited to 1 to 2 minutes after injection, allowing repeated measurements of all microsphere coatings to be made in the same vessels. Although microsphere injection volumes were typically small and had a negligible effect on blood flow velocity we randomized the order of injections between animals to account for any such effect. Results in Figure 1, A and D , are normalized to the centerline velocity (typically 2 to 4 mm/second) of observed vessels allowing data from a large number of treatments to be compared. All bead coatings were compared in all venules and similar trends were seen when microsphere velocities were compared within single vessels or normalized by V_Crit (not shown).

View larger version (25K): [in this window] [in a new window]   Figure 1. Interaction of differently coated microspheres in postcapillary venules. Velocities of IgG-coated (open circles), L-selectin-coated (open squares), sLex-coated (closed circles), and L-selectin/sLex-coated (closed squares) microspheres were tracked through surgically stimulated mouse cremaster venules. Average velocity profiles (expressed as percentage of microspheres traveling within defined velocity bins for each venule studied) for each coating are shown in A. Results are presented as percentage of the VCL for the vessels in which velocities were studied. Lower values represent flow closer to the vessel wall and potentially adhesion. Point by point velocity profiles for three representative L-selectin + sLex- and IgG-coated microspheres are shown in B and C, respectively. Velocities here are shown in mm/second and Vcrit for the studied venule is indicated by the horizontal line. Velocities below Vcrit indicate adhesive interaction. Effect of anti-P-selectin antibody (RB40.34, 30 µg/mouse) on average velocity of L-selectin/sLex-coated microspheres is shown in D (open diamonds before RB40.34, closed squares after RB40.34). All observations were repeated in 9 to 12 venules from at least four mice and averages are presented as mean ± SEM. In preliminary experiments we observed direct attachment of some microspheres to rolling neutrophils. To focus on microspheres interacting directly with venules we depleted neutrophils using RB6–8C5. Velocities of sLex + PSGL-1-coated beads in mice with and without neutrophils are compared in supplemental Figure 1.

Microspheres coated with equivalent densities of either L-selectin or sLe^x alone traveled faster than those with the dual coating (Figure 1A) , but slower than those coated with IgG. L-selectin- or sLe^x-coated microspheres did not exhibit the irregular velocity profile measured for microspheres with the dual coating (not shown) however, suggesting that any interactions with the vessel wall were too brief to detect with our system. Such interactions may be detectable using high-temporal resolution videomicroscopy, as recently described for L-selectin-dependent adhesion in vitro,²⁵ and might explain the lower average velocity of L-selectin- or sLe^x-coated microspheres measured using our system that is restricted to 25 frames per second.

Interestingly, the velocity of dual-coated microspheres increased after treatment with a P-selectin-blocking antibody (Figure 1D) . All mice were treated with neutrophil-depleting antibody (RB6–8C5) before experiments, which prevents leukocyte rolling but leaves endothelial P-selectin intact.²² Furthermore, centerline velocity in observed vessels was not altered by addition of P-selectin-blocking antibodies (1.5 ± 0.08 mm/second before and 1.3 ± 0.05 mm/second after RB40.34). Increased bead velocity cannot, therefore, be ascribed to improved blood flow or inhibition of leukocyte rolling and thus suggests direct interaction of these microspheres with endothelial P-selectin.

Combined Selectin Inhibitors Abolish P-Selectin-Dependent Leukocyte Rolling

Leukocyte rolling in cremaster venules was predominantly P-selectin-dependent 10 to 30 minutes after surgical trauma (Figure 2A) ,¹⁸ but resistant to L-selectin antibody and the sLe^x mimetic, CGP69669A (Figure 2B) .^9,18 Anti-PSGL-1 antibodies inhibit, but do not abolish established surgically induced rolling (Figure 2C) .^12-15,19 Interestingly, both L-selectin antibody and CGP69669A reduced leukocyte rolling when administered after PSGL-1-antibody (Figure 2C) . Videos 1 to 3 compare control rolling with that after PSGL-1 antibody and subsequent CGP69669A. Video 2 shows that a substantial amount of rolling persists after PSGL-1 antibody. This rolling is essentially absent after addition of CGP69669A (video 3). Almost no rolling was seen after a combination of PSGL-1 antibody, L-selectin antibody, and CGP69669A (Figure 2C) . PSGL-1-antibody also caused a greater reduction of leukocyte rolling in L-selectin knockout mice than wild-type mice (Figure 2C) . Rolling after anti-PSGL-1 treatment was not altered by E-selectin-blocking antibody.

View larger version (19K): [in this window] [in a new window]   Figure 2. Effect of combined selectin inhibitors against P-selectin-dependent leukocyte rolling. A: P-selectin antibody (RB40.34, 30 µg/mouse) against surgically induced leukocyte rolling. **, P < 0.001 compared to control rolling. B: Control antibody (rat IgG1, 100 µg/mouse), L-selectin antibody (Mel-14, 100 µg/mouse), or CGP69669A (30 mg/kg) against surgically induced rolling. C: Anti-PSGL-1 (2PH1, 100 µg/mouse) alone or combined with L-selectin-blocking antibody, CGP69669A, L-selectin-deficiency, or E-selectin antibody. **, P < 0.01 compared to baseline rolling; , P < 0.01 compared to rolling after anti-PSGL-1; #, P < 0.05 compared to anti-PSGL-1 + anti-L-selectin or anti-PSGL-1 + CGP69669A. D: rPSGL-Ig (100 mg/kg) alone or in combination with L-selectin-blocking antibody or CGP69669A. **, P < 0.01 compared to baseline rolling; , P < 0.01 compared to rolling after rPSGL-Ig. All results are presented as mean ± SEM for n = 9 to 12 venules from at least four mice per group.

The data presented in Figure 2 are potentially subject to influence by hemodynamic factors including vessel diameter, blood flow velocity, and systemic concentration of leukocytes. These factors were not altered by any of the antibodies or antagonists used (Table 1) . Combined treatments were not significantly different from individual treatments (not shown).

View larger version (28K): [in this window] [in a new window]   Figure 3. Further effects of selectin inhibitors on P-selectin-dependent leukocyte rolling. A: Effect of anti-PSGL-1 (2PH1, 100 µg/mouse) given before or 30 minutes after cremaster surgery. Results are expressed as mean ± SEM, n = 5 to 6. **, P < 0.01 compared to control rolling; ++, P < 0.01 compared to anti-PSGL-1 after surgery. B: Effect of anti-PSGL-1 (2PH1, 100 µg/mouse) and subsequent anti-L-selectin (Mel-14, 100 µg/mouse) or sLex mimetic (CGP69669A, 30 mg/kg) on tethering. Results are expressed as mean ± SEM, n = 6 to 8. **, P < 0.01 compared to tethering after anti-PSGL-1 alone; ++, P < 0.01 compared to tethering after anti-PSGL-1 + anti-L-selectin. C and D: Rolling velocities before and after administration of IgG control antibody (100 µg/mouse, rat IgG1) or anti-PSGL-1, and also after subsequent administration of anti-L-selectin antibody (MEL-14, 100 µg/mouse) or CGP69669A (30 mg/kg). Velocity results are presented as cumulative velocity histograms for at least 50 cells per treatment.

We also investigated the consequences of anti-L-selectin and CGP69669A on leukocyte-rolling velocity. Consistent with their lack of effect on leukocyte-rolling flux, neither L-selectin or CGP69669A altered rolling velocity if given in combination with control antibody (Figure 3C) . Anti-PSGL-1 antibody increased rolling velocity in surgically stimulated cremaster venules (Figure 3D) . Subsequently added L-selectin antibody did not alter rolling velocity whereas CGP69669A caused a dramatic further velocity increase (Figure 3D) . E-selectin-blocking antibody did not alter leukocyte-rolling velocity in these experiments. These findings support the conclusion that L-selectin is primarily required for tethering the leukocyte to endothelium and that subsequent rolling is determined by P-selectin-dependent recognition of sLe^x-bearing ligands on the leukocyte.

	Discussion

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The dominant mechanism supporting rapid induction of leukocyte rolling in postcapillary venules has been clear for some time. In surgically stimulated venules P-selectin rapidly translocates to the luminal surface of endothelial cells, interacts with constitutively expressed PSGL-1 on leukocytes, and initiates rolling within minutes.^14,16,18 Our data do not refute the importance of this mechanism, but do suggest that additional mechanisms compensate when P-selectin-PSGL-1 interaction is inhibited by antibodies targeting the N-terminus of PSGL-1 or the selectin antagonist, rPSGL-Ig. We have demonstrated that beads coated with a combination of L-selectin and sLe^x engage in measurable interactions with P-selectin in vivo. We have also confirmed that some P-selectin-dependent leukocyte rolling persists after treatment with PSGL-1 antibody or rPSGL-Ig and that this rolling can be abolished by treatments (L-selectin antibody, CGP69669A) that do not usually influence P-selectin-dependent leukocyte rolling in vivo.

The surface of a leukocyte is decorated with many structures capable of initiating or stabilizing interactions with postcapillary venules. One strategy for studying the contributions of individual components of that surface is to coat artificial microspheres with purified or recombinant versions of molecules of interest. We and others have used this strategy in the past to investigate the capacity of PSGL-1 and other adhesion molecules to mediate rolling in vitro^27-30 and in vivo.^20,22,31 Ideally, the properties (size, ligand density, deformabilty, and so forth) of microspheres used for such investigations will closely match those of leukocytes, allowing direct comparisons to be made. For this reason, most in vitro investigations have used microspheres of 8 to 10 µm in diameter. Smaller (1 to 2 µm) microspheres must be used for in vivo experiments however, because trapping in capillaries prevents larger microspheres from reaching postcapillary venules. Leukocytes overcome this trapping by deforming as they pass through capillaries. Our current results with microspheres suggest that PSGL-1-independent interactions with P-selectin can occur via L-selectin and sLe^x and are also consistent with the subsequent studies in which L-selectin blockade or CGP69669A inhibit P-selectin-dependent leukocyte rolling after PSGL-1 inhibition. Nevertheless, it should be noted that because of size differences, greater forces will be exerted on interacting leukocytes than microspheres.

There is a discrepancy between studies using PSGL-1-deficient mice and antibodies raised against the N-terminus of PSGL-1. Like P-selectin-deficient mice, PSGL-1-deficient mice have little or no surgically induced rolling.¹⁶ In contrast, PSGL-1-blocking antibodies only partially inhibit established surgically induced rolling in wild-type mice.^12,14,15 One interpretation of this is that PSGL-1 is the only important P-selectin ligand on rolling neutrophils, but that it can interact with endothelial P-selectin in two ways. Optimal type 1 interaction involving the widely studied N-terminus of PSGL-1 dominates when present, whereas a different type 2 interaction is revealed if the type 1 interaction is blocked by antibody. Our results suggest that the type 2 mechanism is distinct from type 1 because it is sensitive to L-selectin blockade or a sLe^x mimetic (CGP69669A) previously found to only affect E-selectin-dependent rolling.

Susceptibility of PSGL-1 antibody/rPSGL-Ig resistant, P-selectin-dependent rolling to the sLe^x mimetic CGP69669A suggests that the mechanisms mediating type-2 rolling involve simpler molecular interactions than those between P-selectin and fully functional PSGL-1. This presents the question of why PSGL-1 should be the only molecule capable of supporting residual leukocyte rolling on P-selectin when many other sialylated/fucosylated molecules (eg, L-selectin,³² ESL-1,³³ CD24,³⁴ and CD18^35,36 ) exist on the surface of leukocytes and are capable of interacting with the selectins. Explaining PSGL-1-independent, P-selectin-dependent leukocyte rolling is not straightforward, given the absence of surgically induced rolling in PSGL-1-deficient mice,¹⁶ but we believe that our findings with PSGL-1 antibody pretreatment and recent data from others²⁶ offer a plausible solution.

Consistent with earlier in vitro studies,^37-39 Sperandio and colleagues²⁶ have demonstrated that >1 hour after surgery, attached leukocytes and leukocyte fragments present selectin ligands (primarily PSGL-1) to other leukocytes thus promoting further recruitment in postcapillary venules. If attachment of the first wave of leukocytes is prevented by P-selectin antibody²⁶ then this secondary capture mechanism is prevented. Such rolling is absent from PSGL-1-deficient mice because PSGL-1 is critically required for the first wave of recruitment. This led us to hypothesize that PSGL-1 antibody, given as a pretreatment, would be more effective than the same dose of the same antibody given after rolling had established. Consistent with this, PSGL-1 pretreatment essentially reproduced the phenotype of the PSGL-1 knockout mouse, giving a much stronger level of inhibition than the same antibody given after rolling was established. We therefore suggest that leukocyte rolling in vivo is initially fully dependent on both P-selectin and PSGL-1 but becomes partially PSGL-1-independent as the response develops. Applying this model to the schematic in Figure 4 , we propose that L-selectin-dependent tethering to PSGL-1 on already adherent leukocytes (or leukocyte fragments) is followed by binding of P-selectin to sLe^x-bearing ligands that may include but are not entirely limited to PSGL-1.

View larger version (22K): [in this window] [in a new window]   Figure 4. A: Type 1 interaction. P-Selectin/PSGL-1 interaction dominates leukocyte rolling in the early stages of an acute inflammatory response. This rolling can be abolished by P-selectin-blocking antibodies, but is only partially inhibited by anti-PSGL-1 antibody or rPSGL-Ig. B: Type 2 interaction. Residual, anti-PSGL-1/rPSGL-Ig-resistant rolling requires L-selectin for tethering and can be inhibited by CGP69669A suggesting importance of sialylated, fucosylated glycans.

PSGL-1-blocking antibodies and rPSGL-Ig do not target the same molecules but do inhibit the same event (ie, P-selectin/PSGL-1 binding). PSGL-1-blocking antibodies bind to the high-affinity P-selectin recognition domain near the N-terminus of PSGL-1,^14,41 whereas rPSGL-Ig is directed toward the high-affinity binding site of endothelial P-selectin. Our previous observations that rPSGL-Ig¹⁹ and other PSGL-1-based inhibitors do not abolish P-selectin-dependent rolling in vivo suggested to us that P-selectin recognizes the high-affinity binding domain of PSGL-1 in one way and other ligands in quite another. Such a possibility is supported by the three-dimensional structures of P-selectin co-crystallized with different ligands.⁴² P-selectin co-crystallized with sLe^x closely resembles the conformation of unligated P-selectin and the three-dimensional structure of E-selectin co-crystallized with sLe^x. P-Selectin bound to a high-affinity fragment of PSGL-1, on the other hand, adopts a markedly different conformation permitting extended contacts with the elements of PSGL-1 required for high-affinity binding. Preferred conformations adopted by membrane-bound P-selectin under physiological conditions are not known. Our data support the possibility of a high-affinity (type 1) conformation that dominates leukocyte rolling under normal circumstances and is inhibited by PSGL-1-blocking antibodies and by rPSGL-Ig, and a low-affinity (type 2) conformation that can be inhibited by sLe^x and similar molecules.

The rPSGL-Ig used in our investigations carries all of the posttranslational modifications required for high-affinity interaction with P-selectin including expression of sialyl Lewis^x or similar structures.⁴³ Why this does not confer the ability to abolish P-selectin-dependent leukocyte rolling in vivo, unless additional free sLe^x mimetic is given, requires further consideration. Clearly, CGP69669A added at 30 mg/kg represents a vast molar excess of sLe^x-like material, when compared with amounts of sLe^x (or similar structures) attached to 30 mg/kg of rPSGL-Ig. Thus, we simply may not be giving enough carbohydrate to prevent type 2 interactions when treating with rPSGL-Ig at 30 to 100 mg/kg. Alternatively, P-selectin in the type 2 conformation may be inaccessible to rPSGL-Ig. Testing these possibilities is not currently possible because practical reasons prevent us from administering doses of rPSGL-Ig higher than 100 mg/kg.

In summary, we find that a combination of sLe^x and L-selectin support detectable interaction of microspheres with P-selectin in postcapillary venules in vivo, suggesting the possibility of a cooperative mechanism for P-selectin-dependent/PSGL-1-independent rolling in vivo. Cooperation between L-selectin and a sLe^x-bearing ligand also supports significant leukocyte rolling although such interaction is only revealed after inhibition of high-affinity P-selectin/PSGL-1 interaction. P-Selectin inhibitors that target type 1 P-selectin/PSGL-1 interaction do not inhibit all P-selectin-dependent leukocyte rolling, whereas inhibitors targeting type 2 interaction have no measurable effect unless combined with an inhibitor of type 1 interaction. These findings may have important implications for the efficacy of P-selectin inhibitors in clinical trials.

	Footnotes

 
Address reprint requests to Keith Norman, Clinical Sciences Centre, Northern General Hospital, Sheffield, S5 7AU, UK. E-mail: k.norman{at}shef.ac.uk

Supported by a project grant from the British Heart Foundation (PG/2000026). V.C.R. is the recipient of an Intermediate Fellowship from the British Heart Foundation (FS/02004). Equipment was funded by grant 057108 from the Wellcome Trust.

Accepted for publication October 14, 2004.

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Top Abstract Materials and Methods Results Discussion References

 

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