Semaphorins are cell surface proteins sharing an extracellular Sema motif that binds to plexin family receptors, among others [1]. We have shown previously that Sema4D is expressed by platelets, serving as a contact-dependent amplifier of platelet activation by promoting activation of the tyrosine kinase, Syk, downstream of the collagen receptor, GP VI/FcRγ [2–4]. Deletion of Sema4D impairs thrombus growth in mice by reducing the number of fully-activated, stably-adherent platelets in the region closest to the vessel wall [5]. Sema4D(−/−) platelets have diminished responses to collagen, but normal responses to thrombin, TxA2 and ADP [2, 4]. Collagen-induced Syk activation and the subsequent activation of phospholipase Cγ2 are most robust when Sema4D is present and platelets are allowed to form stable contacts [4].
These observations have helped to define the role of platelet Sema4D. In the setting of vascular injury, Syk is activated by binding to a phosphorylated immunoreceptor tyrosine-based activation motif (ITAM) in FcRγ. However, while our previous studies show that Sema4D does not amplify G protein-dependent signaling, left unsettled was whether signal amplification is specific for GPVI or applies to other ITAM receptors as well. Here we have addressed that issue. Human platelets express two other ITAM-containing receptors, Clec-2 and FcR-IIA. Mouse platelets express Clec-2 [6]. Unlike GPVI/FcRγ and FcR-IIA, Clec-2 contains only half of an ITAM motif or “hemi-ITAM” (YXXL). Signaling occurs when two molecules of phosphorylated Clec-2 engage a single molecule of Syk [6, 7]. The known Clec-2 ligands are the snake venom toxin, rhodocytin [6] and podoplanin. Podoplanin/Clec-2 interactions play an essential role in separating the lymphatic and vascular systems during embryonic development [8–10].
Reagents and procedures
Rhodocytin was purified from Calloselasma rhodosoma venom [11]. Two separate batches differing somewhat in potency were used for these studies. Anti-phosphotyrosine (4G10P; Millipore, Billerica, MA), anti-Syk (N19; Santa Cruz Biotechnology, Santa Cruz, CA), anti- Clec-2 (17D9; Abcam, Cambridge, MA), and anti-phospho-Syk Y519/520 (Cell Signaling, Danvers, MA, USA). Lec3.2.8.1 CHO cells stably expressing hSema4D (1–657) containing a C-terminal His tag [12] were provided by Dr. Yvonne Jones (University of Oxford). Sema4D(−/−) mice [13] were backcrossed onto a C57 BL/6 background for >10 generations. Comparisons were made with mice obtained from heterozygous crosses. Platelet isolation. Blood was collected from the inferior vena cava of anesthetized mice. Platelets were isolated by centrifugation and resuspended in modified Tyrode’s buffer. Immunoprecipitation and immunoblotting. Platelets were lysed with buffer (1% NP-40, 50 mM Tris, 150 mM NaCl, 1 mM EDTA) containing protease (Sigma-Aldrich) and phosphatase inhibitors (Calbiochem, San Diego, CA). Immunoprecipitation and immunoblotting were performed as described [4].
Loss of Sema4D expression produces a defect in rhodocytin-induced platelet aggregation that can be reversed with recombinant Sema4D
As others have noted, rhodocytin has a steep dose response curve [14]. Decreasing the concentration delays the onset of aggregation without markedly affecting the extent of aggregation (Figure 1A&B). Loss of Sema4D yielded a defect that could be overcome by raising the rhodocytin concentration (Figure 1B&C) or adding soluble Sema4D (Figure 1D&E). We next examined rhodocytin-induced Syk phosphorylation. In WT platelets, phosphorylation increased as the platelets began to aggregate (Figure 1F). This increase was blunted either by omitting stirring or by blocking aggregation with the αIIbβ3 antagonist, Integrilin, indicating that Clec-2-dependent Syk phosphorylation, like GPVI/FcRγ-dependent Syk phosphorylation, is contact-dependent (Figure 1G). Consistent with the aggregation studies, maximal Syk and Clec-2 phosphorylation were delayed in the absence of Sema4D (Figure 1F, H&I).
Thus, our studies show that Sema4D supports maximal Syk phosphorylation downstream of Clec-2 in a contact-dependent manner, just as it does for GPVI/FcRγ [4]. Notably, however, there are differences as well as similarities between Clec-2 and GPVI/FcRγ. As already noted, GPVI/FcRγ forms a 1:1 complex with Syk, while Clec-2 has a modified ITAM and forms a 2:1 complex. GPVI/FcRγ is phosphorylated by Src family members [15], while Clec-2 is phosphorylated by Syk in a positive feedback loop following rhodocytin-induced receptor clustering [14, 16]. Although we observed previously that GPVI/FcRγ phosphorylation occurs normally in Sema4D(−/−) platelets [4], here we found that loss of Sema4D impairs Clec-2 phosphorylation as well, presumably because of the involvement of Syk.
In summary, these results indicate for the first time that optimal Syk activation downstream of Clec-2 , like optimal activation downstream of GPVI, is dependent on contacts between platelets and on Sema4D. The observed reduction in Clec-2 signaling in the absence of Sema4D reflects a decrease in both Clec-2 phosphorylation and Syk activation. Collectively, these results suggest that the contribution of Sema4D in platelets applies to ITAM-containing receptors as a class, and is not limited to GPVI/FcRγ.
Acknowledgements
We thank Mark Kahn for critically reading the manuscript. These studies were supported by NIH P50-HL81012 (L.F.B.) and the American Heart Association 10POST3420003 (K.M.W.).
Footnotes
Author Contributions
K. M. Wannemacher designed the study, performed experiments, analyzed the data, and wrote the paper. H. Jiang performed experiments. P. R. Hess. performed experiments. Y. Shin and K. Suzuki-Inoue provided reagents/analytical tools. L. F. Brass designed the study, analyzed data and wrote the paper.
Conflict-of-interest disclosures
The authors declare no competing financial interests.
References
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