Abstract
Sphingosine-1-phosphate (S1P) participates in inflammation; however, its role in leukocyte rolling is still unclear. Here we use intravital microscopy in inflamed mouse cremaster muscle venules and human endothelial cells to show that S1P contributes to P-selectin-dependent leukocyte rolling through endothelial S1P receptor 3 (S1P3) and Gαq, PLCβ and Ca2+. Intra-arterial S1P administration increases leukocyte rolling, while S1P3 deficiency or inhibition dramatically reduces it. Mast cells involved in triggering rolling also release S1P that mobilizes P-selectin through S1P3. Histamine and epinephrine require S1P3 for full-scale effect accomplishing it by stimulating sphingosine kinase 1 (Sphk1). In a counter-regulatory manner, S1P1 inhibits cAMP-stimulated Sphk1 and blocks rolling as observed in endothelial-specific S1P1−/− mice. In agreement with a dominant pro-rolling effect of S1P3, FTY720 inhibits rolling in control and S1P1−/− but not in S1P3−/− mice. Our findings identify S1P as a direct and indirect contributor to leukocyte rolling and characterize the receptors mediating its action.
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Introduction
Sphingosine-1-phospate (S1P) is a bioactive lysophospholipid with important functions in the immune and cardiovascular systems and has been implicated in different aspects of inflammatory disorders1. High S1P concentrations have been measured locally at inflammatory sites2,3, where it is generated by sphingosine kinases activated through inflammatory cytokines, lipopolysaccharide (LPS) or thrombin. This suggests a role for S1P in the propagation of the inflammatory response4. In contrast, S1P opposes the pathologically increased endothelial permeability common to all inflammatory processes and prevents vascular leakage caused by LPS, thrombin or platelet-activating factor5,6,7. There is also evidence both for stimulatory and inhibitory effects of S1P on leukocyte recruitment in inflammation. In favour of a pro-inflammatory role, exogenous S1P induces endothelial vascular cell adhesion molecule 1 (VCAM-1) and E-selectin, while endogenous S1P mediates the stimulatory effect of tumor-necrosis factor (TNF)-α and LPS on adhesion molecules, which is suppressed by S1P1 short interfering RNA8,9,10. In support, chronic overexpression of sphingosine kinase 1 augments VCAM-1 and E-selectin expression and enhances neutrophil adhesion after TNF-α11. In contrast, both S1P and S1P1 agonists have been demonstrated to inhibit TNF-α-induced endothelial adhesion molecule expression and adherence of inflammatory cells by interfering with endothelial NF-κB and stimulating nitric oxide production12,13,14. Several explanations have been put forward for these apparent discrepancies such as the assumption that S1P receptors may be differentially expressed among endothelial beds, and that the wide range of S1P concentrations employed in the individual studies may have led to contrary effects as observed for S1P in other systems15. However, in all these studies the focus has been on S1P1, while any involvement of S1P receptor 3 (S1P3) has not been addressed.
In contrast to the effects of S1P on firm leukocyte adhesion, its role on leukocyte rolling—the crucial initial step of inflammatory cell recruitment—has not been investigated in detail. Recently, sphingosine kinase-1 has been shown to contribute to histamine-induced leukocyte rolling, but the mechanism of action has remained elusive16. In general, leukocyte capture and rolling is mediated by the selectin family of adhesion molecules consisting of three selectins: L-, E- and P-selectin17,18. L-selectin is expressed on most leukocytes and mediates leukocyte capture and rolling through binding to selectin ligands found on high endothelial venules of lymphoid organs. E-selectin and P-selectin are expressed on the activated vascular endothelium during inflammation and mediate rolling through binding to carbohydrate moieties of selectin ligands on leukocytes17,18. Among the selectins, P-selectin contributes to disease pathology in many experimental models including myocardial and renal infarction, thrombosis, stroke, atherosclerosis, cerebral malaria and sickle cell disease19, as has been shown using P-selectin-blocking antibodies and knockout strategies in mouse, feline and baboon models20,21,22,23.
We have recently identified leukocyte recruitment defects in S1P3−/− mice in atherosclerosis and peritoneal inflammation that were caused by both haematopoietic and non-haematopoietic S1P3 deficiency3. In addition, treatment with the S1P analogue FTY720 severely reduced leukocyte recruitment into the inflamed peritoneum3. Currently, it is controversial if S1P in general and S1P3 in particular affect leukocyte rolling.
In this study, we address this issue by studying P-selectin-dependent leukocyte rolling in surgically prepared post-capillary venules of the mouse cremaster muscle in vivo. These studies are complemented by experiments in a novel in vitro system to investigate the mechanisms of the rapid P-selectin mobilization that occurs within minutes in endothelial cells and stems from the exocytosis of Weibel–Palade bodies. Our results demonstrate a unique role of S1P and S1P3 in P-selectin-dependent rolling both by direct action as well as by contributing to P-selectin mobilization by other agonists.
Results
S1P3 deficiency and inhibition reduce leukocyte rolling
To examine whether S1P3 plays a role in P-selectin-dependentleukocyte rolling in vivo, we employed intravital microscopy to monitor rolling in post-capillary venules of the surgically exteriorized mouse cremaster muscle24,25. In this model, profound spontaneous leukocyte rolling is induced by the surgical preparation of the cremaster (hence termed trauma), which exclusively depends on the rapid mobilization of P-selectin from endothelial Weibel–Palade bodies to the luminal surface in its initial phase (<45 min after exteriorization of the cremaster muscle)17,26,27,28. Elegant studies from the 1990s have shown that the endothelial P-selectin mobilization is in large part caused by activation products of tissue mast cells released upon mechanical manipulation during surgery29. Here we employed this model to study leukocyte rolling in S1P3−/− mice and observed that their rolling flux fraction (as a measure of rolling) was greatly diminished compared with C57Bl6 controls (Fig. 1a). Neither microvascular/haemodynamic conditions nor leukocyte rolling velocities differed between groups excluding any bias by these variables (Table 1 and Supplementary Fig. 1). Systemic application of a P-selectin-blocking antibody completely abrogated leukocyte rolling in both genotypes (Fig. 1a) confirming the dependence of rolling on P-selectin in this model and both genotypes, respectively. In addition, whole-mount immunohistochemistry for intravascular P-selectin clearly showed the appearance of luminal P-selectin in controls but not in S1P3−/− mice (Fig. 1a). Of note, S1P3-deficient leukocytes had no intrinsic defect in rolling as we determined in an ex vivo flow chamber system30, where blood was diverted from the carotid artery into microflow chambers coated with immobilized murine P-selectin31 (Fig. 1b). We also assessed cell surface expression of P-selectin glycoprotein ligand-1 as the main, if not only, functional P-selectin ligand on neutrophils, and found no differences between S1P3−/− and C57Bl6 mice (Supplementary Table 1).
We next tested the effect of TY-52156, a highly specific S1P3 inhibitor32, on leukocyte rolling in C57Bl6 mice. As TY-52156 is not commercially available, we synthesized it according to published protocols32 and confirmed its specificity for S1P3 in comparison to S1P1 (Supplementary Figs 2,3). Intraperitoneal administration of TY-52156 (1.25 mg per kg body weight) 30 min before the experiment leads to a dramatic reduction in leukocyte rolling (Fig. 1c). To test whether the opposite–stimulation of the vasculature by exogenous S1P–would increase rolling, we injected S1P directly into the carotid artery (30 μg per kg body weight) in C57Bl6 mice and measured leukocyte rolling immediately thereafter. Indeed, we observed that rolling was dramatically enhanced by S1P (Fig. 1d).
S1P3 induces P-selectin and rolling via Gq, PLC and Ca2+
Exposure of cell surface P-selectin on luminal endothelial cells is the prerequisite for trauma-induced leukocyte rolling in the experimental model we have used here17,26,27,28. To pursue the mechanism by which S1P and S1P3 affect P-selectin mobilization, we established an assay for quantitative assessment of cell surface P-selectin using flow cytometry in human umbilical endothelial cells (HUVECs) as the only system applicable for such studies. Nevertheless, HUVECs are still extremely difficult to work with in respect to studying P-selectin as they express it only under certain culture conditions and lose ability for mobilizing it already after one to two passages. Nevertheless, we successfully established the assay and validated it extensively using histamine and H1 and H2 receptor antagonists (Supplementary Fig. 4). Using this assay, we observed that stimulation of HUVEC with 1 μM S1P resulted in an extremely rapid (within 5 min) appearance of P-selectin on the cell surface (Fig. 2a). In contrast, the agonist of the S1P1 receptor SEW2871 was ineffective (Fig. 2a). In agreement with a role of S1P3 in the process, preincubation with 10 μM TY-52156 for 30 min substantially diminished P-selectin mobilization by S1P (Fig. 2a).
We then addressed the signalling pathways downstream of S1P/S1P3 responsible for P-selectin mobilization. Phospholipase C (PLC) and Ca2+ are known to play a role in the exocytosis of Weibel–Palade bodies33, and S1P has been shown to activate PLC in CHO cells overexpressing S1P3 (ref. 34, 35). Thus, we added the PLC inhibitor U73122 (3 μM) 2 min before S1P stimulation and observed a clear reduction in P-selectin mobilization (Fig. 2b). To address the role of Ca2+, we depleted internal Ca2+ pools by adding thapsigargin (3 μM) for 5 min before stimulation with S1P, while simultaneously preventing the extracellular Ca2+ influx by EGTA (3 mM) added for the last minute. This treatment substantially suppressed P-selectin mobilization (Fig. 2b).
Although S1P3 couples to three G proteins (Gq, Gi and G12/13), the predominant signalling pathway it exercises is through Gq (ref. 36). To test for an involvement of Gq in leukocyte rolling in our model in general, we employed mice deficient for Gq in endothelial cells on a global G11-deficient background (Gq/11−/− mice)37. We observed them to have a substantial reduction in leukocyte rolling (Fig. 2c). Administration of TY-52156 did not reduce rolling any further in Gq/11−/− mice (Fig. 2c), suggesting that under normal circumstances S1P3 enhances rolling through Gq.
FTY720 and S1P lyase blockade suppress rolling by impacting on S1P3
On the basis of our results so far, we hypothesized that downregulation of S1P3 by FTY720 would inhibit leukocyte rolling to a similar extent as does S1P3 deficiency or a S1P3 inhibitor. Furthermore, if S1P3 were the only receptor inducing P-selectin mobilization by S1P, FTY720 should not decrease rolling any further in S1P3−/− mice. Indeed, administration of 1.25 mg per kg FTY720 either 30 min or 24 h before the experiment dramatically attenuated leukocyte rolling (Fig. 3a). In agreement with our second hypothesis, we observed no additional inhibition of rolling by FTY720 in S1P3−/− mice (Fig. 3b). Finally, treatment with the S1P lyase inhibitor 4-deoxypyridoxine (DOP) that elevates plasma and tissue S1P and downregulates all S1P receptors38 also inhibited rolling (Fig. 3c). Rolling velocities did not differ significantly between the experimental groups (Supplementary Fig. 1), and P-selectin-mediated rolling was independent of putative DOP effects on plasma or leukocytes as no differences in rolling were observed on immobilized P-selectin (Supplementary Fig. 5).
We then went further to examine the effect of FTY720 on P-selectin mobilization in vitro. Pretreatment of HUVEC with the active, phosphorylated form of FTY720 (pFTY720, 10 μM for 30 min) almost completely abolished S1P-induced mobilization of P-selectin (Fig. 3d). PhosphoFTY720 itself (1 μM) had only a minor, almost negligible effect on P-selectin compared with 1 μM S1P after 5 min and no effect at all after 30 min (a time when the S1P effect was still clearly visible; Fig. 3d). This may seem surprising in light of the agonistic effect of pFTY720 known for all S1P receptors except S1P2 before their subsequent cell surface downregulation. However, we have previously shown that pFTY720 activates only the Gi and not the Gq signalling pathway of S1P3 and also inhibits Gq-transmitted S1P3 signalling by native S1P39. Here we observed something very similar in respect to P-selectin: addition of a 10-fold higher concentration of pFTY720 simultaneously with S1P resulted in a clear inhibition of S1P-induced P-selectin mobilization (Fig. 3d). In agreement, addition of S1P or pFTY720 for 30 min to another cellular system — S1P3-overexpressing CHO cells — followed by removal and subsequent (30 min later) S1P stimulation abolished S1P3-dependent signalling such as Erk MAPK activation (Supplementary Fig. 6).
S1P3 conveys part of the P-selectin mobilization by histamine
P-selectin mobilization and consecutive leukocyte rolling in the trauma-stimulated cremaster muscle venules that we have examined here are known to be predominantly mediated by products of tissue mast cells activated upon mechanical manipulation during surgery29. Of these products, histamine accounts for approximately half of the effect on rolling as elegantly shown using H1 and H2 histamine receptor antagonists29. Recently, Sun et al.16 demonstrated that histamine superfusion of the cremaster muscle induces leukocyte rolling dependent on sphingosine kinase 1 (Sphk1), but the mechanism has remained unidentified. We asked the question whether S1P3 might be involved in histamine-induced P-selectin mobilization. To tackle this, we first titrated down the histamine concentration from 25 μM (routinely used in the vast majority of the literature) to a 100-fold lower concentration of 0.25 μM (Fig. 4a). This much lower histamine concentration still leads to a substantial P-selectin mobilization in HUVEC within 5 min (Fig. 4a). The well-characterized sphingosine kinase inhibitor 4-[[4-(4-chlorophenyl)-2-thiazolyl]amino]-phenol (SKi, 25 μM (ref. 40)) suppressed P-selectin mobilization at both histamine concentrations, but was particularly effective at the lower one (Fig. 4a). Remarkably, administration of exogenous S1P in addition to SKi partially restored P-selectin mobilization by histamine (Fig. 4a), arguing for a S1P receptor conveying Sphk1-mediated, histamine-dependent P-selectin mobilization. We then tested whether the responsible S1P receptor may be S1P3. Indeed, preincubation with the S1P3 inhibitor TY-52156 for 30 min dramatically reduced P-selectin mobilization by 0.25 μM histamine (Fig. 4b). Thus, the reduction of histamine to lower and presumably more physiological concentrations in our model allowed us to assign part of its P-selectin-mobilizing effect to the engagement of S1P3 through endogenous Sphk1-generated S1P. Finally, we observed that leukocyte rolling was substantially reduced in cremaster muscle venules of Sphk1−/− mice in vivo compared with C57Bl6 controls (Fig. 4c). Altogether, our data suggest that part of the histamine effect on P-selectin-mediated rolling is mediated by its activation of Sphk1, production of endogenous S1P and subsequent stimulation of P-selectin mobilization by endothelial S1P3.
cAMP induces P-selectin and rolling through Sphk1 and S1P3
Several other agents besides histamine such as thrombin, vasopressin receptor agonists, purine nucleotides and epinephrine are well known to induce rapid P-selectin mobilization41. Many of them elevate intracellular cAMP through activation of the Gs/adenylate cyclase (AC) pathway; however, the exact mechanisms leading to subsequent P-selectin mobilization are not entirely clear. In our hands, epinephrine (9 μM) potently induced P-selectin mobilization in HUVEC (Fig. 5a). Remarkably, the S1P3 inhibitor TY-52156 substantially albeit not entirely suppressed epinephrine-induced P-selectin mobilization (Fig. 5a). Assuming that the cAMP/AC pathway is involved, we applied forskolin (10 μM) as an established tool to directly stimulate AC. Indeed, forskolin potently mobilized P-selectin mobilization in HUVEC (Fig. 5b). Interestingly, this was clearly inhibited by S1P3 inhibitor TY-52156 (Fig. 5b). These data suggested that a mechanism involving AC activation and relying on S1P3 is in part responsible for P-selectin mobilization by cAMP-generating agents such as epinephrine and forskolin. Forskolin has been shown to activate Sphk1 in pheochromocytoma cells42. We thus hypothesized that this may be the case in endothelial cells as well. Thus, we determined enzymatic Sphk1 activity after forskolin stimulation by measuring the conversion of C17-sphingosine to C17-S1P using mass spectrometry. Indeed, C17-S1P production was clearly increased after forskolin (10 μM) treatment of HUVEC for 30 min (Fig. 5c). To explore the consequences for P-selectin mobilization, we employed forskolin and the nondegradable cAMP analogue cpt-cAMP, respectively, to activate Sphk and added the Sphk inhibitor SKi. Indeed, both forskolin (10 μM) and cpt-cAMP (0.3 mM) induced P-selectin mobilization, and in both cases SKi treatment substantially reduced it (Fig. 5d). Finally, we sought to reproduce these findings at the level of leukocyte rolling in vivo and applied forskolin (1.3 mg kg−1) intraperitoneally in our cremaster model. In agreement with its induction of P-selectin in vitro, forskolin clearly stimulated leukocyte rolling in vivo (Fig. 5e). In summary, these data have identified a novel cAMP-dependent mechanism of P-selectin mobilization that acts through Sphk1 activation and employs subsequent S1P3 signalling.
Mast cell-derived S1P induces P-selectin in HUVEC via S1P3
According to previous studies, histamine release from mast cells accounts for half of the leukocyte rolling in the cremaster model that by itself is completely mast cell-dependent29. Although S1P is not contained in mast cell granules, mast cell can release large amounts of S1P when allergically stimulated43,44,45. Thus, we hypothesized that tissue mast cells may be another source of S1P in our model thereby causing P-selectin mobilization and rolling. Physical stimuli such as pressure and temperature are known to induce mast cell activation in vitro and in vivo46,47. As surrogate for the physical stimulus of mechanical mast cell manipulation occurring during cremaster muscle exteriorization, we employed transient exposure of isolated peritoneal mast cells to a temperature of 53 °C for 2 min as commonly employed to activate mast cell without adverse effects on viability46,47. We then added the mast cell supernatants immediately to HUVEC and measured P-selectin surface expression (Fig. 6). To exclude effects of histamine released under these conditions, we added diphenhydramine and cimetidine in concentrations sufficient to completely block P-selectin mobilization by 0.25 μM histamine (Supplementary Fig. 4). The mast cell supernatants induced an impressive four- to fivefold increase in cell surface P-selectin expression compared with supernatants of unchallenged mast cells after 10 min (Fig. 6). Remarkably, this increase was suppressed by more than half by the S1P3 inhibitor TY-52156 (Fig. 6). Mass spectrometry of the identical supernatants revealed that S1P had been released (90±41 pmol S1P per 106 mast cells) resulting in a 64.73±7.95 nM S1P concentration in the mast cell supernatants that the HUVEC had been exposed to. Another proof of biologically active S1P being present in the mast cell supernatants was their ability to activate Erk MAPK in S1P1-overexpressing CHO cells and the inhibition thereof by a S1P1 antagonist (Supplementary Fig. 7).
Rolling is increased in endothelial S1P1 deficiency
Finally, we examined leukocyte rolling in mice deficient for the endothelial S1P1 receptor (S1P1SCL-Cre-ERT) and observed it to be increased compared with respective controls (Fig. 7a). Furthermore, administration of FTY720 reduced rolling in S1P1SCL-Cre-ERT mice to the same lower than basal levels observed with FTY720 in control mice and C57Bl6 mice, respectively, and S1P3−/− mice (Fig. 7b). Microvascular and haemodynamic parameters as well as rolling velocities were unaffected (Table 1 and Supplementary Fig. 1). Interestingly, the highly specific S1P1 agonist AUI 954 (ref. 48) inhibited forskolin-induced C17-S1P generation in HUVEC in vitro along with inhibiting cAMP generation (Supplementary Fig. 8). These results suggest that S1P1 negatively regulates cAMP-stimulated Sphk1 and by reducing S1P generation possibly inhibits P-selectin-dependent rolling, hence acting as an opponent to S1P3.
Discussion
Our study reveals the following six important and novel findings (Fig. 8): (1) we provide evidence that S1P is a direct agonist of P-selectin mobilization and leukocyte rolling; (2) we identify S1P3 as the major responsible S1P receptor; (3) we show that several P-selectin agonists employ S1P and S1P3 as mediators of their P-selectin-mobilizing effects by activating Sphk1; (4) we characterize a novel cAMP-dependent mechanism of Sphk1 activation and P-selectin mobilization; (5) we identify a rolling-inhibitory effect of endothelial S1P1; and (6) we show that pharmacological inhibition or downregulation of S1P3 for example by FTY720 attenuates leukocyte rolling in a physiological setting. Only few studies have addressed S1P in the context of processes related to leukocyte rolling: (1) S1P has been demonstrated to both induce and inhibit the exocytosis of von Willebrand factor through different pathways49; (2) Sphk1 was suggested to play no role in basal leukocyte rolling but to promote rolling after exogenous histamine administration16; (3) although S1P promoted firm neutrophil adhesion in vitro50, neutrophil recruitment was inhibited during acute inflammatory lung injury in S1P lyase-deficient mice51, with S1P lyase inhibitors52 and by S1P administration53, respectively, and (4) FTY720 was shown to suppress neutrophil recruitment in several disease models3,53,54. This has made general conclusions on the role of S1P and its receptors in leukocyte rolling or their mode of action rather difficult.
Our findings add some new evidence that helps to better understand the role of S1P in rolling. First, it is crucial to distinguish acute S1P effects on pre-stored P-selectin occurring within minutes from S1P effects on cytokine-induced P-selectin transcription that takes hours. Second, the acute S1P effects on P-selectin are different from those caused by continuous exposure to high S1P levels or the lack of S1P receptors. Third, the effects of S1P analogues such as FTY720 may differ considerably from the effects of genuine S1P at the receptor level55. In respect to rapid P-selectin mobilization, we have clearly shown that S1P is a direct P-selectin agonist and leads to increased P-selectin-dependent leukocyte rolling within minutes of its direct administration into the circulation. It is known that despite the high amounts of S1P already present in the blood, intravascular injection of S1P can still cause functional effects on the endothelium such as attenuation of vascular leakage, vasodilatation and protection against reperfusion injury53,56,57. Accordingly, the reduced leukocyte rolling we observed after pharmacological S1P3 inhibition and in S1P3−/− mice, respectively, are strong arguments for the causal and direct positive contribution of endothelial S1P signalling to P-selectin-dependent leukocyte rolling. However, we have also found evidence that endothelial S1P1 plays an opposite role in rolling as its deletion led to a rolling increase. However, the pro-rolling effect of S1P3 appears to be dominant over the anti-rolling effect of S1P1 as the net effect of acute intravascular S1P administration in wild-type mice (where both receptors are being engaged) was an overall increase in rolling. However, in the absence of S1P3, anti-rolling effects of S1P1 may also contribute to the reduction in rolling. In fact, there was a minor but significant increase in rolling with FTY720 in S1P3 deficiency that may have occurred because of S1P1 downregulation by FTY720. Accordingly, in the absence of endothelial S1P1, the increase in rolling may be due to a combination of the loss of anti-rolling S1P1 effects and the still intact and potent pro-rolling S1P3 effects. Indeed, in S1P1−/− mice, FTY720 inhibited rolling to lower than basal levels.
We have identified two possible sources of endogenous S1P involved in P-selectin mobilization in our model: interstitial mast cells and endothelial cells (Fig. 8). Interstitial mast cell activation following mechanical cremaster muscle manipulation is entirely responsible for the leukocyte rolling occurring there, and histamine release accounts for ~50% of it (ref. 29). As S1P can be released by allergically activated mast cells45, and physical stimuli such as pressure and heat can activate mast cells46,47, we hypothesized that S1P may be another mast cell product contributing to the remaining part of leukocyte rolling. The physical stimulus we employed to test this in mast cells was a short, harmless temperature elevation46,47. Indeed, we found them to release S1P within minutes that mobilized P-selectin in HUVEC in part in a S1P3-dependent manner. Whether this occurs in vivo and actually contributes to leukocyte rolling in our model should be addressed by future studies. Although platelets are the major source of P-selectin, elaborate studies have shown that platelet P-selectin does not play a role in leukocyte rolling58,59, and, in our hands, S1P had no effect on basal or thrombin-stimulated P-selectin in platelets; neither was platelet activation altered in Sphk1−/− mice (Supplementary Fig. 9).
We have identified endothelial cells as the second source of endogenous S1P capable of inducing P-Selectin mobilization. Sphk1 activation has been known to occur after stimulation with inflammatory cytokines as well as histamine; however, the pathway by which it contributes to rolling has remained unclear16. We provide evidence that S1P produced by histamine-activated Sphk1 contributes to full-blown histamine mobilization of P-selectin through S1P3. The evidence stems from two observations: (1) the partial inhibition of P-selectin mobilization after histamine by the blockade of Sphk1 or S1P3 and (2) the elimination of the inhibitory effect of Sphk1 blockade on P-selectin by exogenous S1P. Coincidently, the S1P3 receptor, the H1 histamine receptor and the thrombin PAR-1 receptor41 not only all mobilize P-selectin but also couple to Gq; on the other side, pharmacological Gq inhibition has been shown to inhibit P-selectin exocytosis at least in platelets60. This offers a plausible explanation of why S1P3 effects have gone unnoticed in experiments employing H1 blockers or Gq inhibitors. Our finding that endothelial-specific Gq/11−/− mice have reduced P-selectin-dependent leukocyte rolling can certainly be explained by the blockade of several Gq-coupled receptors including S1P3. Indeed, all these agonists have their own S1P-independent pathways of inducing P-selectin as neither S1P3 nor Sphk1 deletion/inhibition was able to completely inhibit P-selectin mobilization. However, part of the histamine effect can be attributed to S1P3. Our observation that rolling could not be reduced any further by pharmacological S1P3 inhibition in Gq/11−/− mice argues that Gq mediates the pro-rolling effect of S1P3. The site of action of S1P released by interstitial mast cells or by endothelial cells exposed to histamine from the same mast cells would primarily be on the abluminal side of the vascular endothelium. This complies with an oriented signalling mode as the abluminal side should be reached first by any locally released interstitial agents. This scenario is in line with the dynamic signalling model proposed by Camerer et al.7 of how abluminal S1P signalling maintains endothelial integrity despite high S1P levels in blood.
We were also intrigued by the observation that not only histamine but another P-selectin-mobilizing agonist such as epinephrine41 that couples with Gs and not Gq employed Sphk1 and S1P3 for full-scale P-selectin mobilization (Fig. 8). We have demonstrated that epinephrine also activated Sphk1 but through a cAMP-dependent mechanism and — similar to histamine — also employed S1P and S1P3 to help mobilize P-selectin. Indeed, direct stimulation of Sphk1 by forskolin (as measured by the conversion of C17-sphingosine to C17-S1P) mobilized P-selectin through S1P3 in vitro and induced leukocyte rolling in vivo. In agreement with a role for cAMP, forskolin has been shown to activate Sphk1 in pheochromocytoma cells years ago42. However, S1P3 or Sphk1 inhibition did not completely abrogate the effects of epinephrine or forskolin, suggesting that there must be additional pathways of how cAMP mobilizes P-selectin41. Interestingly, the pathway of cAMP-stimulated Sphk1 provides a putative mechanism of how S1P1, with its established inhibitory effect on cAMP generation4, may be exerting its antirolling effect. Indeed, the highly specific S1P1 agonist AUI 954 (ref. 48) inhibited C17-S1P generation after forskolin along with lowering cAMP (Supplementary Fig. 8). This suggests that S1P1 may be attenuating cAMP-induced Sphk1 activation in a negative-feedback manner, thereby restricting the amounts of S1P available for P-selectin mobilization by S1P3. The reduced leukocyte rolling we have observed in Sphk1−/− mice is in line with Sphk1/S1P serving as a general transmission/amplification hub for different incoming P-selectin mobilization signals. While the S1P1 receptor has often been implicated in Sphk1 signalling, there is to our knowledge only scarce evidence for an involvement of S1P3 in conveying Sphk1 signals: only one study has implied S1P3 as a mediator of thrombin-induced Sphk1 effects in dendritic cells61. The requirement of S1P3 for full efficiency of several P-selectin agonists may also serve another purpose: S1P3 downregulation or desensitization after engagement by endogenous S1P may help ameliorate excessive P-selectin stimulation and help turn it off.
Acute S1P effects on P-selectin mobilization should be distinguished from those caused by continuous exposure to S1P or S1P analogues. High S1P levels after S1P lyase inhibition or deficiency and administration of FTY720 have been shown to downregulate S1P receptors1,62,63 including S1P3 (ref. 64) and impair lymphocyte trafficking. Accordingly, the reduced neutrophil recruitment found in S1P lyase-deficient mice51 or after FTY720 treatment53,54 may be due to downregulation of S1P3. In line with this, we have observed that FTY720 had no additional inhibitory effect on rolling in S1P3−/− mice. However, another mechanism may also be involved: we have previously shown that pFTY720 is a potent inhibitor of Gq-mediated S1P-induced S1P3 signalling39. In the present study, we extended this observation to P-selectin mobilization by S1P3. Thus, both mechanisms could be taking place simultaneously as: (1) preincubation with pFTY720 abolished S1P-induced P-selectin mobilization in endothelial cells as well as S1P3-dependent S1P signalling in S1P3-CHO cells; (2) pFTY720 had a minor and very short-lived positive effect on P-selectin compared with S1P, while (3) its simultaneous application together with S1P abolished P-selectin mobilization by S1P. In line with this interpretation, another P-selectin-dependent process, the recruitment of early thymic progenitors to the thymic endothelium, has been shown to be inhibited by FTY720 (ref. 65), although the responsible receptor was not identified.
In summary, our study suggests an important role for S1P and S1P3 in the induction of rapid endothelial P-selectin mobilization and consecutive P-selectin-dependent leukocyte rolling. S1P acts thereby both directly as an agonist and, indirectly, as a contributor to P-selectin mobilization by other P-selectin agonists.
Methods
Mice
S1P3−/− mice were provided by Jerold Chun, Scripps Research Institute to B.L. and crossbred to C57Bl6J for more than six generations. Sphk1−/− mice were provided to M.H.G. by Richard Proia (NIH) and Tie2-Cre-ER(T2); Gαqflox/flox;Gα11−/− were from S.O. Mice deficient for the endothelial S1P1 receptor were generated by crossbreeding S1P1flox/flox mice66 with endothelial-SCL-Cre-ERT mice, in which the tamoxifen-inducible Cre-ERT recombinase is driven by the 5′-endothelial enhancer of the stem cell leukaemia (SCL) locus67 (Supplementary Fig. 11). Cre-negative S1P1SCL-Cre-ERT littermates treated with the same tamoxifen regimen were used as controls. Recombination was induced by daily intraperitoneal injections of tamoxifen (40 mg per kg body weight) for five consecutive days, and the experiments were performed 6 weeks later. Successful recombination was shown in lung endothelial cells isolated using CD31-coated magnetic beads (Dynabeads) by site-specific PCR for the excised exon. All mice used in the study were male and at least 10 weeks of age. All procedures were performed in accordance with the institutional guidelines for health and care of experimental animals and were approved by the Regierung von Baden Württemberg and Oberbayern, respectively.
Substances and antibodies
S1P was purchased from Enzo Life Science. The S1P3 inhibitors TY-52156 (Supplementary Fig. 2) and FTY720 were synthesized as described32. AUY 954 was a kind gift from Klaus Seuwen (Novartis). In vivo, FTY720 and TY-52156 were applied intraperitoneally at 1.25 mg per kg and forskolin at 1.3 mg per kg body weight 30 min or 24 h before the experiment as indicated. S1P was injected via a carotid artery catheter at 30 μg per kg body weight (125 μM S1P solution in 2% BSA per 0.9% NaCl). The S1P lyase inhibitor DOP (Sigma Aldrich) was supplemented in the drinking water (30 mg l−1) for 1 week. W146 and C17 sphingosine were from Avanti polar lipids, the SKi 4-[[4-(4-chlorophenyl)-2-thiazolyl]amino]-phenol (SKi, SKI II and SPHK I2), pFTY720, SEW2871 and U73122 from Cayman Chemical Co; epinephrine from Sanofi Aventis; forskolin from Calbiochem; IBMX, cpt-cAMP, diphenhydramine and cimetidine from Sigma Aldrich; and thapsigargin from AppliChem. S1P1-CHO and S1P3-CHO cells were from Novartis. The following antibodies were used: CD62P-PE (phycoerythrin) anti-mouse (eBioscience, 12-0626-82, 3:100), CD4-PE anti-mouse (eBioscience, 12-0041, 1:100), CD8-PE anti-mouse (eBioscience, 12-0081, 1.4:100), Ter119-PE anti-mouse (Miltenyi, 130-091-783, 3:100), Ly6G&Ly6C-PE anti-mouse (BD Pharmingen, 553128, 1.6:100), CD45R-PE anti-mouse (BD Pharmingen, 553089, 1.6:100), CD34-AlexaFluor700 anti-mouse (BD Pharmingen, 1.6:100), CD16/32-PerCpCy5.5 anti-mouse (BD Pharmingen, 560540, 1.65:100), LyA/E-FITC anti-mouse (BD Pharmingen, 557405, 1.1:100), CD117-PE-Cy7 anti-mouse (BD Pharmingen, 558163, 1.7:100), CD450-V450 anti-mouse (BD Pharmingen, 560697, 1.8:100) and P-selectin glycoprotein ligand-1-PE anti-mouse (BD Pharmingen, 555306, 1:1,000). The P-selectin-blocking rat-anti-mouse monoclonal antibody RB40.34 was a generous gift from Dietmar Vestweber (MPI Münster).
Flow chamber assay for rolling on immobilized P-selectin
Rectangular glass capillaries (0.4 × 0.04 mm, VitroCom) were used for ex vivo flow chamber experiments as described31. Chambers were coated with recombinant murine (rm)P-selectin (CD62-P, 20 μg ml−l, R&D Systems). Following overnight incubation at 4 °C, flow chambers were blocked with 5% casein (Sigma-Aldrich) in PBS for 2 h. For experiments, one end of the chamber was attached to a carotid artery catheter, while the other was left open to regulate blood flow through the microflow chamber. Microscopy was performed using a modified Olympus BX51 upright microscope (LaVision Biotec) with a saline immersion objective (40/0.8 numerical aperture (NA), Olympus). Leukocyte rolling was recorded over 10 min per microflow chamber with a CCD (charge-coupled device) video camera (model CF8/1; Kappa) connected to a Panasonic S-VHS recorder and analysed offline.
Intravital microscopy of the cremaster muscle
Intravital microscopy of postcapillary venules of the mouse cremaster muscle was used to study leukocyte rolling under different inflammatory conditions25,27. Briefly, mice were anaesthetized by intraperitoneal injection of ketamine and xylazine (100 and 20 mg per kg body weight, respectively), after which a tracheal tube was inserted and the carotid artery cannulated for blood sampling and systemic application of substances. Thereafter, the scrotum was opened, the cremaster muscle exteriorized, spread over a cover glass and superfused with warmed (35 °C) bicarbonate-buffered saline. Observation of postcapillary venules was conducted on an upright microscope (Olympus BX51) with a saline immersion objective ( × 40/0.8 NA). To abolish P-selectin-dependent rolling, the P-selectin-blocking monoclonal antibody RB40.34 (30 μg per mouse) was diluted in 200 μl saline and injected via the carotid artery catheter. Experiments were recorded via a CCD camera system (model CF8/1; Kappa) on a Panasonic S-VHS recorder. Systemic blood samples (10 μl) were obtained before and during the experiment, stained using Turck’s solution and assessed for white blood cell count using a haemocytometer. Data analysis was performed offline using the video tapes from in vivo experiments. Diameter, segment length of postcapillary venules and venular centreline blood flow velocity were assessed using a digital image-processing system and a digital online cross-correlation programme, respectively (Circusoft Instrumentation)24. Leukocyte rolling flux fraction was calculated from the number of rolling cells that crossed a perpendicular line through a given vessel within 1 min in relation to the total number of circulating leukocytes.
Whole-mount immunohistochemistry
For immunohistochemical detection of luminal endothelial P-selectin expression in cremaster muscle whole mounts, primary monoclonal antibody against P-selectin RB40.34 (30 μg per mouse) was systemically injected after 20-min superfusion of the exteriorized right cremaster muscle ensuring binding to P-selectin on the luminal vessel surface. To remove excess antibody, the inferior vena cava was cut and animals were perfused with 10 ml of 0.9% NaCl. The left cremaster muscle was exteriorized post mortem to serve as unstimulated negative control. The cremaster muscles were then mounted on adhesive slides (Superfrost), transferred into −20° acetone over night and stored at −80 °C until further processing. For staining of P-selectin expression, cremaster whole mounts were permeabilized with saponin (0.03% in Tris-buffer) and incubated with 2 μg ml−l biotinylated secondary goat anti-rat IgG (Southern Biotechnology Associates Inc, Cat. No 3030-08). Detection of antigen–antibody complexes was carried out with a commercial biotinylated horseradish peroxidase/avidin complex (Vectastain ABC, Vector Laboratories) according to the manufacturer’s instructions. Slides were counterstained using Mayer’s Hemalaun and analysed using a Zeiss microscope with a × 100, 1.4 NA oil immersion objective.
P-selectin mobilization in HUVEC
HUVECs (passage 1–4) were cultured in 20% human serum/RPMI. After incubation in serum-free medium for 4 h, cells were stimulated with histamine (0.25 or 25 μM), S1P (1 μM), SEW2871 (1 μM) and epinephrine (9 μM)/IBMX (100 nM), respectively, for the indicated times. Before histamine or S1P stimulation, the S1P3 inhibitor TY-52156, SKi or phosphorylated FTY720 (10 μM) were added for 30 min; with forskolin, inhibitors were added 10 min before stimulation. Five minutes before the end of the experiment, PE-conjugated anti-P-selectin antibody (eBioscience; 1.6:100) was added directly into the 500 μl of incubation medium after which the cells were washed twice and analysed immediately by flow cytometry.
Stimulation with supernatants of activated mast cells
Mouse peritoneal mast cells were isolated by a Percoll gradient as described68 and characterized as CD45+, Lin− (CD45R, Ly6G, Ly6C, Ter119, CD4 and CD8), CD117+, Sca-1+, CD16/32+ and CD34+ cells by flow cytometry and consecutive toluidine blue staining68,69. The yield was 0.05–0.1 × 106 mast cells per mouse. All peritoneal cells were incubated with 10 μM sphingosine for 30 min at 37 °C before the Percoll gradient isolation procedure. Stimulation was performed by adding 250 μl warm (53 °C) 2% BSA/alphaMEM to 0.5 × 106 mast cells and subsequent incubation for 2 min at 53 °C as described46,47. For stimulation of HUVEC, 100 μl of the mast cell supernatant was supplemented with diphenhydramine and cimetidine (10 μM each) and added to confluent HUVEC cultured in 200 μl RPMI for 10 min. PE-conjugated anti-P-selectin antibody was added directly into the 300 μl at the time of stimulation. Cells were washed twice with serum-free medium, trypsinized and analysed by flow cytometry.
Measurements of Sphk1 activity using C17-sphingosine
Five μM C17-sphingosine was added together with 10 μM forskolin to HUVEC in RPMI with 2 mg per ml BSA fraction V (Serva) for 30 min. Cells were washed extensively and lysed in 50 mM Tris/HCl (pH 7.5), 0.5%NP-40, 10% glycerol, 250 mM NaCl, 5 mM EDTA, 0.5 mM phenylmethyl sulphonyl fluoride, 5 μg ml−l leupeptin and aprotinin. Protein concentration was measured using the Pierce BCA Protein Assay Kit (Thermo Scientific). C17-S1P was determined by mass spectrometry as described70 and expressed per milligram cell protein.
Statistics
For pair-wise comparison between experimental groups, a Wilcoxon rank sum test or paired Student’s t-test was performed. For multiple comparisons, a Kruskal–Wallis nonparametric analysis of variance on ranks was performed followed by Dunn’s post hoc test. A P value<0.05 was considered statistically significant. All statistical analyses were carried out with GraphPad Prism 5.2 (PraphPad Software Inc, La Jolla). Data are presented as mean±s.e.m. Sample size has been provided for each experiment in the figure legend (no exclusion criteria, randomization or blinding).
Additional information
How to cite this article: Nussbaum, C. et al. Sphingosine-1-phosphate receptor 3 promotes leukocyte rolling by mobilizing endothelial P-selectin. Nat. Commun. 6:6416 doi: 10.1038/ncomms7416 (2015).
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Acknowledgements
We thank Susanne Bierschenk for her invaluable help in performing flow chamber experiments. We thank Klaus Seuwen (Novartis) for the kind provision of AUY 954. We are grateful to Franziska Röstel and Mareike Lipinski for lipid extractions and Christina-Maria Reimann for performing lipid analyses. This work was supported by the Deutsche Forschungsgemeinschaft to B.L. (LE940/4-2), M.S. (SP621/4-1), M.H.G. (GR 1943/2-2), B.L., G.H., V.P.P. (SFB656 project A6) and M.S. (SFB914 project B1). M.S. received support from the Deutsches Zentrum für Herz- und Kreislaufforschung. C.F.G.-d.-A., I.R., H.C.d.C.F.N. and M.S. have received funding from the European Community's Seventh Framework Programme [FP7-2007-2013] under grant agreement no. HEALTH-F4-2011-282095.
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C.N., S.B., C.F.G.-d.-A., P.K., V.P.P., I.R., G.H., K.v.W.L. and H.K. performed research, collected data, analysed and interpreted data, performed statistical analysis, wrote the manuscript. M.H.G., H.C.d.C.F.N., J.G., G.H., B.L.-S. and S.O. contributed vital reagents or analytical tools and interpreted data. M.S. and B.L. designed research, analysed and interpreted data, and wrote the manuscript.
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Nussbaum, C., Bannenberg, S., Keul, P. et al. Sphingosine-1-phosphate receptor 3 promotes leukocyte rolling by mobilizing endothelial P-selectin. Nat Commun 6, 6416 (2015). https://doi.org/10.1038/ncomms7416
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