Nagaharu Tsukiji

C‐type lectin‐like receptor 2 promotes hematogenous tumor metastasis and prothrombotic state in tumor‐bearing mice

Essentials The role of C‐type lectin‐like receptor‐2 (CLEC‐2) in cancer progression is unclear. CLEC‐2‐depleted mouse model is generated by using a rat anti‐mouse CLEC‐2 monoclonal antibody. CLEC‐2 depletion inhibits hematogenous tumor metastasis of podoplanin‐expressing B16F10 cells. CLEC‐2 depletion prolongs cancer survival by suppressing thrombosis and inflammation.

Podoplanin-positive periarteriolar stromal cells promote megakaryocyte growth and proplatelet formation in mice by CLEC-2

Megakaryopoiesis is the hierarchical differentiation of hematopoietic stem cells into megakaryocytes. Differentiating megakaryocytes undergo maturation characterized by endomitosis and produce numerous platelets through proplatelet formation. C-type lectin-like receptor 2 (CLEC-2) is a podoplanin (PDPN) receptor mainly expressed on platelets and megakaryocytes. Deletion of platelet/megakaryocyte CLEC-2 causes thrombocytopenia in mice; however, its contribution to megakaryopoiesis remains unknown. Here, we show that megakaryopoiesis is promoted through the CLEC-2/PDPN interaction in the vicinity of arterioles in the bone marrow (BM). We have also identified PDPN-expressing BM arteriolar stromal cells, tentatively termed as BM fibroblastic reticular cell (FRC)-like cells. Platelet/megakaryocyte-specific CLEC-2 conditional knockout (cKO) mice showed a decrease in the number of immature megakaryocytes. CLEC-2 wild-type megakaryocyte expansion was augmented in vitro by the addition of recombinant PDPN, but not cKO megakaryocytes. Moreover, megakaryocyte colonies were colocalized with periarteriolar BM FRC-like cells in the BM. Coculture of megakaryocytes with BM FRC-like cells augmented megakaryocyte expansion, which was dependent upon the CLEC-2/PDPN interaction. Furthermore, we found that the CLEC-2/PDPN interaction induces BM FRC-like cells to secrete chemokine (C-C motif) ligand 5 (CCL5) to facilitate proplatelet formation. These observations indicate that a reciprocal interaction between CLEC-2 on megakaryocytes and PDPN on BM FRC-like cells contributes to the periarteriolar megakaryopoietic microenvironment in mouse BM.

A novel regulatory element for Shh expression in the lung and gut of mouse embryos

Hedgehog (Hh) signaling plays pivotal roles in morphogenesis of several embryonic tissues, including the primitive gut. In the mouse embryo, Sonic hedgehog (Shh) is expressed in endodermal epithelia from the oral cavity to the intestine, and contributes to cell proliferation in the underlying mesenchyme and subsequent differentiation into the gastrointestinal smooth muscle. Three evolutionary conserved non-coding sequences in the region upstream of the Shh coding sequence contain endoderm-specific enhancers for Shh expression. Although Shh expression in the endodermal epithelial lining is mostly attributed to these three enhancers, none of them regulates gene expression in the gastroesophageal epithelium. Here, we found that a 1.7Kb fragment located 100Kb upstream of the Shh coding sequence contains a functional element for Shh expression in endodermal organs, including the esophagus and stomach. Compared with the three known endodermal enhancers, this novel enhancer shows less evolutionary conservation, even among rodents. In mouse embryonic endodermal tissues, the seamless expression of Shh is achieved by a patchwork of multiple enhancers with different rates of evolution.

Vascular Smooth Muscle Cells Stimulate Platelets and Facilitate Thrombus Formation through Platelet CLEC-2: Implications in Atherothrombosis.

The platelet receptor CLEC-2 is involved in thrombosis/hemostasis, but its ligand, podoplanin, is expressed only in advanced atherosclerotic lesions. We investigated CLEC-2 ligands in vessel walls. Recombinant CLEC-2 bound to early atherosclerotic lesions and normal arterial walls, co-localizing with vascular smooth muscle cells (VSMCs). Flow cytometry and immunocytochemistry showed that recombinant CLEC-2, but not an anti-podoplanin antibody, bound to VSMCs, suggesting that CLEC-2 ligands other than podoplanin are present in VSMCs. VSMCs stimulated platelet granule release and supported thrombus formation under flow, dependent on CLEC-2. The time to occlusion in a FeCl3-induced animal thrombosis model was significantly prolonged in the absence of CLEC-2. Because the internal elastic lamina was lacerated in our FeCl3-induced model, we assume that the interaction between CLEC-2 and its ligands in VSMCs induces thrombus formation. Protein arrays and Biacore analysis were used to identify S100A13 as a CLEC-2 ligand in VSMCs. However, S100A13 is not responsible for the above-described VSMC-induced platelet activation, because S100A13 is not expressed on the surface of normal VSMCs. S100A13 was released upon oxidative stress and expressed in the luminal area of atherosclerotic lesions. Suspended S100A13 did not activate platelets, but immobilized S100A13 significantly increased thrombus formation on collagen-coated surfaces. Taken together, we proposed that VSMCs stimulate platelets through CLEC-2, possibly leading to thrombus formation after plaque erosion and stent implantation, where VSMCs are exposed to blood flow. Furthermore, we identified S100A13 as one of the ligands on VSMCs.

The platelet-activating receptor C-type lectin receptor-2 plays an essential role in liver regeneration after partial hepatectomy in mice

Essentials Regeneration role of C‐type lectin receptor‐2 (CLEC‐2) after 70% hepatectomy (HPx) was investigated. Wild‐type or CLEC‐2 deleted from platelets of chimeric mice (flKO) underwent HPx. The liver/body weight ratio was significantly lower in the flKO than in the wild‐type. CLEC‐2 plays an essential role in liver regeneration after HPx.

Platelet CLEC-2: Roles Beyond Hemostasis

&NA; C‐type lectin‐like receptor 2 (CLEC‐2) has been identified on the surface of platelets as a receptor for a platelet activating snake venom, rhodocytin/aggretin. CLEC‐2 belongs to a C‐type lectin superfamily and binds to a sialoglycoprotein, podoplanin, in vivo. Platelets play a crucial role in hemostasis and thrombosis, but recent studies have uncovered multiple roles of platelets beyond hemostasis in physiology and pathology. The interaction between platelet CLEC‐2 and podoplanin is the key to several roles of platelets beyond hemostasis. The spatial and temporal expression patterns of podoplanin regulate vascular/lymphatic development, maintenance of vascular integrity, tissue regeneration, and some pathological processes including tumor metastasis and thromboinflammation. CLEC‐2 facilitates blood/lymphatic vessel separation during embryonic development by binding to podoplanin on lymphatic endothelial cells. The leakage of platelets from hyperpermeable vessels for maintaining vascular integrity during inflammation depends on CLEC‐2. During wound healing, the expression of podoplanin in keratinocytes is upregulated, which helps in the process. Podoplanin is expressed on the surface of tumor cells and facilitates hematogenous metastasis by inducing platelet aggregation through CLEC‐2. During thrombotic processes, such as development of deep vein thrombosis, podoplanin is upregulated on unknown cells in the vessel wall in the area of inflammation, facilitates thrombus formation, and promotes further inflammation by binding to CLEC‐2. In this article, the roles of platelets beyond hemostasis are comprehensively reviewed.

Functional characterization of recombinant snake venom rhodocytin: rhodocytin mutant blocks CLEC-2/podoplanin-dependent platelet aggregation and lung metastasis

Essentials We generated recombinant rhodocytin that could aggregate platelets via CLEC‐2. Recombinant wild‐type rhodocytin formed heterooctamer with four α‐ and β‐subunits. Asp 4 in α‐subunit of rhodocytin was required for binding to CLEC‐2. Inhibitory mutant of rhodocytin blocked podoplanin‐dependent hematogenous metastasis.

Measurement of soluble C-type lectin-like receptor 2 in human plasma

Abstract Detection of platelet activation in vivo is useful to identify patients at risk of thrombotic diseases. Platelet factor 4 (PF4) and β-thromboglobulin (β-TG) are used for this purpose; however, they are easily released upon the minimal platelet activation that occurs during sampling. Soluble forms of several platelet membrane proteins are released upon platelet activation; however, the soluble form of C-type lectin-like receptor 2 (sCLEC-2) has not yet been fully investigated. Western blotting with an anti-CLEC-2 antibody showed that sCLEC-2 was released from washed human platelets stimulated with collagen mimetics. To detect sCLEC-2 in plasma, we established a sandwich enzyme-linked immunosorbent assay (ELISA) using F(ab′)2 anti-CLEC-2 monoclonal antibodies. Although plasma mixed with citrate, adenosine, theophylline and adenosine (CTAD) is needed for the PF4 and β-TG assays, effects of anti-coagulants (EDTA, citrate and CTAD) on the sCLEC-2 ELISA were negligible. Moreover, while special techniques are required for blood sampling and sample preparation for PF4 and β-TG assay, the standard blood collections procedures used in daily clinical laboratory tests have shown to suffice for sCLEC-2 analysis. In this study, we found that two forms of sCLEC-2 are released after platelet activation: a shed fragment and a microparticle-bound full-length protein, both of which are detected by the sCLEC-2 ELISA. The average concentration of sCLEC-2 in the plasma of 10 healthy individuals was 97 ± 55 pg/ml, whereas that in the plasma of 25 patients with diabetes mellitus (DM) was 149 ± 260 pg/ml. A trend towards an increase in sCLEC-2 concentration in the DM patients may reflect in vivo platelet activation in the patients, suggesting that sCLEC-2 may have clinical significance as a biomarker of in vivo platelet activation.

Platelets play an essential role in murine lung development through Clec-2/podoplanin interaction

Platelets participate in not only thrombosis and hemostasis but also other pathophysiological processes, including tumor metastasis and inflammation. However, the putative role of platelets in the development of solid organs has not yet been described. Here, we report that platelets regulate lung development through the interaction between the platelet-activation receptor, C-type lectin-like receptor-2 (Clec-2; encoded by Clec1b), and its ligand, podoplanin, a membrane protein. Clec-2 deletion in mouse platelets led to lung malformation, which caused respiratory failure and neonatal lethality. In these embryos, α-smooth muscle actin-positive alveolar duct myofibroblasts (adMYFs) were almost absent in the primary alveolar septa, which resulted in loss of alveolar elastic fibers and lung malformation. Our data suggest that the lack of adMYFs is caused by abnormal differentiation of lung mesothelial cells (luMCs), the major progenitor of adMYFs. In the developing lung, podoplanin expression is detected in alveolar epithelial cells (AECs), luMCs, and lymphatic endothelial cells (LECs). LEC-specific podoplanin knockout mice showed neonatal lethality and Clec1b-/--like lung developmental abnormalities. Notably, these Clec1b-/--like lung abnormalities were also observed after thrombocytopenia or transforming growth factor-β depletion in fetuses. We propose that the interaction between Clec-2 on platelets and podoplanin on LECs stimulates adMYF differentiation of luMCs through transforming growth factor-β signaling, thus regulating normal lung development.

Cobalt hematoporphyrin inhibits CLEC-2–podoplanin interaction, tumor metastasis, and arterial/venous thrombosis in mice

The platelet activation receptor C-type lectin-like receptor 2 (CLEC-2) interacts with podoplanin on the surface of certain types of tumor cells, and this interaction facilitates tumor metastasis. CLEC-2 is also involved in thrombus formation and its stabilization. Because CLEC-2-depleted mice are protected from experimental lung metastasis and thrombus formation and do not show increased bleeding time, CLEC-2 may serve as a good target for antimetastatic or antithrombotic drugs. We screened 6770 compounds for their capability to inhibit CLEC-2-podoplanin binding using an enzyme-linked immunosorbent assay. In the first screening round, 63 compounds were identified and further evaluated by flow cytometry using CLEC-2-expressing cells. We identified protoporphyrin IX (H2-PP) as the most potent inhibitor and modified its hematoporphyrin moiety to be complexed with cobalt (cobalt hematoporphyrin [Co-HP]), which resulted in an inhibitory potency much stronger than that of H2-PP. Surface plasmon resonance analysis and molecular docking study showed that Co-HP binds directly to CLEC-2 at N120, N210, and K211, previously unknown podoplanin-binding sites; this binding was confirmed by analysis of CLEC-2 mutants with alterations in N120 and/or K211. Co-HP at a concentration of 1.53 μM inhibited platelet aggregation mediated through CLEC-2, but not that mediated through other receptors. IV administration of Co-HP to mice significantly inhibited hematogenous metastasis of podoplanin-expressing B16F10 cells to the lung as well as in vivo arterial and venous thrombosis, without a significant increase in tail-bleeding time. Thus, Co-HP may be a promising molecule for antimetastatic and antiplatelet treatment that does not cause bleeding tendency.