Julia Etulain

P-selectin promotes neutrophil extracellular trap formation in mice

Neutrophil extracellular traps (NETs) can be released in the vasculature. In addition to trapping microbes, they promote inflammatory and thrombotic diseases. Considering that P-selectin induces prothrombotic and proinflammatory signaling, we studied the role of this selectin in NET formation. NET formation (NETosis) was induced by thrombin-activated platelets rosetting with neutrophils and was inhibited by anti-P-selectin aptamer or anti-P-selectin glycoprotein ligand-1 (PSGL-1) inhibitory antibody but was not induced by platelets from P-selectin(-/-) mice. Moreover, NETosis was also promoted by P-selectin-immunoglobulin fusion protein but not by control immunoglobulin. We isolated neutrophils from mice engineered to overproduce soluble P-selectin (P-selectin(ΔCT/ΔCT) mice). Although the levels of circulating DNA and nucleosomes (indicative of spontaneous NETosis) were normal in these mice, basal neutrophil histone citrullination and presence of P-selectin on circulating neutrophils were elevated. NET formation after stimulation with platelet activating factor, ionomycin, or phorbol 12-myristate 13-acetate was significantly enhanced, indicating that the P-selectin(ΔCT/ΔCT) neutrophils were primed for NETosis. In summary, P-selectin, cellular or soluble, through binding to PSGL-1, promotes NETosis, suggesting that this pathway is a potential therapeutic target for NET-related diseases.

Regulation of neutrophil extracellular trap formation by anti-inflammatory drugs

The formation of neutrophil extracellular traps (NETs) is a newly described phenomenon that increases the bacteria-killing ability and the inflammatory response of neutrophils. Because NET generation occurs in an inflammatory microenvironment, we examined its regulation by anti-inflammatory drugs. Treatment of neutrophils with dexamethasone had no effect, but acetylsalicylic acid (ASA) treatment prevented NET formation. NETosis was also abrogated by the presence of BAY 11-7082 [(E)-3-[4-methylphenylsulfonyl]-2-propenenitrile] and Ro 106-9920 [6-(phenylsulfinyl)tetrazolo[1,5-b]pyridazine], two structurally unrelated nuclear factor-κB (NF-κB) inhibitors. The decrease in NET formation mediated by ASA, BAY-11-7082, and Ro 106-9920 was correlated with a significant reduction in the phosphorylation of NF-κB p65 subunit, indicating that the activation of this transcription factor is a relevant signaling pathway involved in the generation of DNA traps. The inhibitory effect of these drugs was also observed when NET generation was induced under acidic or hyperthermic conditions, two stress signals of the inflammatory microenvironment. In a mouse peritonitis model, while pretreatment of animals with ASA or BAY 11-7082 resulted in a marked suppression of NET formation along with increased bacteremia, dexamethasone had no effect. Our results show that NETs have an important role in the local control of infection and that ASA and NF-κB blockade could be useful therapies to avoid undesired effect of persistent neutrophil activation.

Acidosis downregulates platelet haemostatic functions and promotes neutrophil proinflammatory responses mediated by platelets

Acidosis is one of the hallmarks of tissue injury such as trauma, infection, inflammation, and tumour growth. Although platelets participate in the pathophysiology of all these processes, the impact of acidosis on platelet biology has not been studied outside of the quality control of laboratory aggregation assays or platelet transfusion optimization. Herein, we evaluate the effect of physiologically relevant changes in extracellular acidosis on the biological function of platelets, placing particular emphasis on haemostatic and secretory functions. Platelet haemostatic responses such as adhesion, spreading, activation of αIIbβ3 integrin, ATP release, aggregation, thromboxane B2 generation, clot retraction and procoagulant activity including phosphatidilserine exposure and microparticle formation, showed a statistically significant inhibition of thrombin-induced changes at pH of 7.0 and 6.5 compared to the physiological pH (7.4). The release of alpha granule content was differentially regulated by acidosis. At low pH, thrombin or collagen-induced secretion of vascular endothelial growth factor and endostatin were dramatically reduced. The release of von Willebrand factor and stromal derived factor-1α followed a similar, albeit less dramatic pattern. In contrast, the induction of CD40L was not changed by low pH, and P-selectin exposure was significantly increased. While the generation of mixed platelet-leukocyte aggregates and the increased chemotaxis of neutrophils mediated by platelets were further augmented under acidic conditions in a P-selectin dependent manner, the increased neutrophil survival was independent of P-selectin expression. In conclusion, our results indicate that extracellular acidosis downregulates most of the haemostatic platelet functions, and promotes those involved in amplifying the neutrophil-mediated inflammatory response.

Regulation of platelet responses triggered by Toll-like receptor 2 and 4 ligands is another non-genomic role of nuclear factor-kappaB.

INTRODUCTION Platelets express Toll-like receptors (TLRs) that recognise molecular components of pathogens and, in nucleated cells, elicit immune responses through nuclear factor-kappaB (NF-κB) activation. We have shown that NF-κB mediates platelet activation in response to classical agonists, suggesting that this transcription factor exerts non-genomic functions in platelets. The aim of this study was to determine whether NF-κB activation is a downstream signal involved in TLR2 and 4-mediated platelet responses. MATERIAL AND METHODS Aggregation and ATP release were measured with a Lumi-aggregometer. Fibrinogen binding, P-selectin and CD40 ligand (CD40L) levels and platelet-neutrophil aggregates were measured by cytometry. I kappa B alpha (IκBα) degradation and p65 phosphorylation were determined by Western blot and von Willebrand factor (vWF) by ELISA. RESULTS Platelet stimulation with Pam3CSK4 or LPS resulted in IκBα degradation and p65 phosphorylation. These responses were suppressed by TLR2 and 4 blocking and synergised by thrombin. Aggregation, fibrinogen binding and ATP and vWF release were triggered by Pam3CSK4. LPS did not induce platelet responses per se, except for vWF release, but it did potentiate thrombin-induced aggregation, fibrinogen binding and ATP secretion. Pam3CSK4, but not LPS, induced P-selectin and CD40L expression and mixed aggregate formation. All of these responses, except for CD40L expression, were inhibited in platelets treated with the NF-κB inhibitors BAY 11-7082 or Ro 106-9920. CONCLUSION TLR2 and 4 agonists trigger platelet activation responses through NF-κB. These data show another non-genomic function of NF-κB in platelets and highlight this molecule as a potential target to prevent platelet activation in inflammatory or infectious diseases.

Platelet‐mediated angiogenesis is independent of VEGF and fully inhibited by aspirin

Platelets are major players in every step of vessel development through the local delivery of angiogenesis‐modulating factors, including the pro‐angiogenic protein VEGF and the anti‐angiogenic endostatin. Although thrombin is a potent agonist and is highly elevated in angiogenesis‐related diseases, studies regarding its action on the release of platelet angiogenic factors are scarce and controversial. Herein, we have investigated the role of thrombin not only in VEGF and endostatin release but also in net platelet angiogenic activity.

Control of angiogenesis by galectins involves the release of platelet-derived proangiogenic factors.

Platelets contribute to vessel formation through the release of angiogenesis-modulating factors stored in their α-granules. Galectins, a family of lectins that bind β-galactoside residues, are up-regulated in inflammatory and cancerous tissues, trigger platelet activation and mediate vascularization processes. Here we aimed to elucidate whether the release of platelet-derived proangiogenic molecules could represent an alternative mechanism through which galectins promote neovascularization. We show that different members of the galectin family can selectively regulate the release of angiogenic molecules by human platelets. Whereas Galectin (Gal)-1, -3, and -8 triggered vascular endothelial growth factor (VEGF) release, only Gal-8 induced endostatin secretion. Release of VEGF induced by Gal-8 was partially prevented by COX-1, PKC, p38 and Src kinases inhibitors, whereas Gal-1-induced VEGF secretion was inhibited by PKC and ERK blockade, and Gal-3 triggered VEGF release selectively through a PKC-dependent pathway. Regarding endostatin, Gal-8 failed to stimulate its release in the presence of PKC, Src and ERK inhibitors, whereas aspirin or p38 inhibitor had no effect on endostatin release. Despite VEGF or endostatin secretion, platelet releasates generated by stimulation with each galectin stimulated angiogenic responses in vitro including endothelial cell proliferation and tubulogenesis. The platelet angiogenic activity was independent of VEGF and was attributed to the concerted action of other proangiogenic molecules distinctly released by each galectin. Thus, secretion of platelet-derived angiogenic molecules may represent an alternative mechanism by which galectins promote angiogenic responses and its selective blockade may lead to the development of therapeutic strategies for angiogenesis-related diseases.

Hyperthermia inhibits platelet hemostatic functions and selectively regulates the release of alpha-granule proteins

Summary.  Background: Hyperthermia is one of the main disturbances of homeostasis occurring during sepsis or hypermetabolic states such as cancer. Platelets are important mediators of the inflammation that accompanies these processes, but very little is known about the changes in platelet function that occur at different temperatures. Objectives: To explore the effect of higher temperatures on platelet physiology. Methods: Platelet responses including adhesion, spreading (fluorescence microscopy), αIIbβ3 activation (flow cytometry), aggregation (turbidimetry), ATP release (luminescence), thromboxane A2 generation, alpha‐granule protein secretion (ELISA) and protein phosphorylation from different signaling pathways (immunoblotting) were studied. Results: Preincubation of platelets at temperatures higher than 37 °C (38.5–42 °C) inhibited thrombin‐induced hemostasis, including platelet adhesion, aggregation, ATP release and thromboxane A2 generation. The expression of P‐selectin and CD63, as well as vascular endothelial growth factor (VEGF) release, was completely inhibited by hyperthermia, whereas von Willebrand factor (VWF) and endostatin levels remained substantially increased at high temperatures. This suggested that release of proteins from platelet granules is modulated not only by classical platelet agonists but also by microenvironmental factors. The observed gradation of response involved not only antiangiogenesis regulators, but also other cargo proteins. Some signaling pathways were more stable than others. While ERK1/2 and AKT phosphorylation were resistant to changes in temperature, Src, Syk, p38 phosphorylation and IkappaB degradation were decreased in a temperature‐dependent fashion. Conclusions: Higher temperatures, such as those observed with fever or tissue invasion, inhibit the hemostatic functions of platelets and selectively regulate the release of alpha‐granule proteins.

Expression and functionality of type I interferon receptor in the megakaryocytic lineage

Summary.  Background: Type I interferons (IFN‐I) negatively regulate megakaryo/thrombopoiesis. However, expression of the IFN‐I receptor (IFNAR) in the megakaryocytic lineage is poorly characterized. Objectives: To study the expression and functionality of IFNAR in the megakaryocytic lineage. Methods and results: Although IFNAR mRNA was found in every cell type studied, its protein expression showed differences between them. According to flow cytometry and immunofluorescence, IFNAR1 was observed in Meg‐01, Dami, CD34+ cells and megakaryocytes, but not in proplatelets or platelets. Immunoblotting assays showed that IFNAR1 and IFNAR2 were highly expressed in all cell types, except in platelets where it was barely detectable. Regarding IFNAR1, 130‐ and 90‐kDa bands were detected in Meg‐01 and Dami, whereas 130‐ and 60‐kDa bands were found in CD34+ cells and megakaryocytes. Activation of megakaryocytic IFNAR by IFN‐β induced pSTAT1/2 and upregulated the antiviral genes IRF7 and MXA. The latter response was completely suppressed by IFNAR blockade. In contrast, the low levels of IFNAR in platelets were not functional as pSTAT1/2, aggregation and P‐selectin expression were not induced by IFN‐I. In addition, megakaryocytes increased IFN‐I transcript levels and produced IFN‐β upon stimulation with PolyI:C, a synthetic dsRNA that mimics viral infection. Conclusions: Early progenitors and mature megakaryocytes, but not platelets, express functional IFNAR and synthetize/release IFN‐β, revealing not only that megakaryo/thrombopoiesis regulation by IFN‐I is associated with a specific interaction with its receptor, but also that megakaryocytes may play a role in the antiviral defense by being both IFN producers and responders.

Expression and functionality of Toll‐like receptor 3 in the megakaryocytic lineage

In addition to their key role in hemostasis, platelets and megakaryocytes regulate immune and inflammatory responses, in part through their expression of Toll‐like receptors (TLRs). Among the TLRs, TLR3 recognizes dsRNA associated with viral infection. Thrombocytopenia is a frequent complication of viral infection. However, the expression and functionality of TLR3 in megakaryocytes and platelets is not yet well understood.

Glycobiology of platelet-endothelial cell interactions

Under normal conditions, platelets do not interact with blood vessel walls; however, upon activation, platelets firmly attach to endothelial cells. Communication between platelets and endothelial cells during the normal or activated state takes place at multiple levels. Cross-talk may occur over a distance via transient interactions or through receptor-mediated cell-cell adhesion. Platelets may release or transfer substances that affect endothelial cell function and vice versa. Excessive dialogue between platelets and the endothelium exists in several disease states as a causative factor and/or as a consequence of the disease process. Glycans are covalent assemblies of sugars that exist in either free form or in covalent complexes with proteins or lipids. Among other functions, glycans confer stability to the proteins to which they are attached, play key roles in signal transduction and control cell development and differentiation. Glycans not only influence the structure and function of hemostatic molecules but are also increasingly recognized as key molecules regulating platelet-endothelial interactions. The present review outlines the current knowledge regarding glycan-mediated interactions between platelets and endothelial cells and their role in physiopathological processes.