The plaque lipid lysophosphatidic acid stimulates platelet activation and platelet-monocyte aggregate formation in whole blood: involvement of P2Y1 and P2Y12 receptors

Haserück, Nadine; Erl, Wolfgang; Pandey, Dharmendra; Tigyi, Gábor; Ohlmann, Philippe; Ravanat, Catherine; Gachet, Christian; Siess, Wolfgang

doi:10.1182/blood-2003-04-1127

Cited by 112 publications

(102 citation statements)

References 39 publications

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“…The activation of platelets via chemokines and low levels of primary agonists such as ADP have been shown to be dependent on the purinergic P2Y 1 receptor rather than the P2Y 12 receptor , which is believed to have a greater role in sustained thrombus formation (Leon et al, 2003;Nylander et al, 2003;Mazzucato et al, 2004). Furthermore, P2Y 1 is involved in platelet-monocyte complex formation when platelets are stimulated by lysophosphatidic acid (Haseruck et al, 2004). Although the phenomenon of platelet-leukocyte complex formation and adhesion has not been tested after platelet activation via chemokines, ADP signalling through P2Y 1 may contribute to the initial stages of platelet activation in an inflammatory setting.…”

Section: Purinergic Receptor Antagonistsmentioning

confidence: 99%

Novel uses for anti‐platelet agents as anti‐inflammatory drugs

Pitchford

2007

British J Pharmacology

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An alteration in the character and function of platelets is manifested in patients with inflammatory diseases, and these alterations have been dissociated from the well‐characterized involvement of platelets in thrombosis and haemostasis. Recent evidence reveals platelet activation is sometimes critical in the development of inflammation. The mechanisms by which platelets participate in inflammation are diverse, and offer numerous opportunities for future drug intervention. There is now acceptance that platelets act as innate inflammatory cells in immune responses, with roles as sentinel cells undergoing surveillance, responding to microbial invasion, orchestrating leukocyte recruitment, and migrating through tissue, causing damage and influencing repair processes in chronic disease. Some of these processes are targeted by drugs that are being developed to target platelet participation in atherosclerosis. The actions of platelets therefore influence the pathogenesis of diverse inflammatory diseases in various body compartments, encompassing parasitic and bacterial infection, allergic inflammation (especially asthma and rhinitis), and non‐atopic inflammatory conditions, for example, chronic obstructive pulmonary disease (COPD), rheumatoid arthritis (RA), inflammatory bowel disease (IBD) and atherosclerosis. This review will first discuss the evidence for platelet activation in these various inflammatory diseases, and secondly discuss the mechanisms by which this pathogenesis occurs and the various anti‐platelet agents which have been developed to combat platelet activation in atherosclerosis and their potential future use for the treatment of other inflammatory diseases.British Journal of Pharmacology (2007) 152, 987–1002; doi:10.1038/sj.bjp.0707364; published online 2 July 2007

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Section: Purinergic Receptor Antagonistsmentioning

confidence: 99%

Novel uses for anti‐platelet agents as anti‐inflammatory drugs

Pitchford

2007

British J Pharmacology

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“…LPA 5 couples to G 12/13 -mediated Rho activation and G q -mediated phospholipase C activation. Similarly in platelets, LPA stimulates Rho and Ca 2ϩ mobilization; low LPA concentrations induce Rho/ Rho kinase-mediated shape change, and higher LPA concentrations stimulate an increase of cytosolic Ca 2ϩ and aggregation (25)(26)(27)(28). LPA 5 can also mediate an increase in intracellular cAMP production independent of G s (18), and cAMP formation inhibits platelet activation, which implies that LPA 5 activation could inhibit platelet aggregation.…”

mentioning

confidence: 99%

Unique Ligand Selectivity of the GPR92/LPA5 Lysophosphatidate Receptor Indicates Role in Human Platelet Activation

Williams

Khandoga²,

Goyal³

et al. 2009

Journal of Biological Chemistry

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138

140

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Lysophosphatidic acid (LPA) is a ligand for LPA 1-3 of the endothelial differentiation gene family G-protein-coupled receptors, and LPA 4 -8 is related to the purinergic family G-protein-coupled receptor. Because the structure-activity relationship (SAR) of GPR92/LPA 5 is limited and whether LPA is its preferred endogenous ligand has been questioned in the literature, in this study we applied a combination of computational and experimental site-directed mutagenesis of LPA 5 residues predicted to interact with the headgroup of LPA. Four residues involved in ligand recognition in LPA 5 were identified as follows: R2.60N mutant abolished receptor activation, whereas H4.64E, R6.62A, and R7.32A greatly reduced receptor activation. We also investigated the SAR of LPA 5 using LPA analogs and other non-lysophospholipid ligands. SAR revealed that the rank order of agonists is alkyl glycerol phosphate > LPA > farnesyl phosphates Ͼ Ͼ N-arachidonoylglycine. These results confirm LPA 5 to be a bona fide lysophospholipid receptor. We also evaluated several compounds with previously established selectivity for the endothelial differentiation gene receptors and found several that are LPA 5 agonists. A pharmacophore model of LPA 5 binding requirements was developed for in silico screening, which identified two non-lipid LPA 5 antagonists. Because LPA 5 transcripts are abundant in human platelets, we tested its antagonists on platelet activation and found that these non-lipid LPA 5 antagonists inhibit platelet activation. The present results suggest that selective inhibition of LPA 5 may provide a basis for future anti-thrombotic therapies.Lysophosphatidic acid (LPA, 2 1-radyl-2-hydroxy-sn-3-glycero phosphate) specifically interacts with several protein targets that regulate physiological and pathophysiological processes (1-3). LPA targets include specific G-protein-coupled receptors (GPCRs) that mediate a wide variety of biological effects, including cell proliferation (4), cell survival (5), cell migration (6), and platelet aggregation (7,8). GPCRs are the largest family of transmembrane receptors and represent targets of many therapeutics (9). Eight LPA-specific mammalian GPCRs, LPA 1-8 , have been identified to date (10 -12). Among the eight LPA receptors, LPA 1 , LPA 2 , and LPA 3 are members of the endothelial differentiation gene (EDG) family (13), and the transmembrane domains of human LPA 1-3 show 81% homology with each other (14). The five other members of the EDG family are specific for the related lysophospholipid sphingosine 1-phosphate (S1P). The structural foundation for LPA selectivity over S1P has been linked to a single amino acid at position 3.29, a conserved glutamine in the LPA-specific and glutamate in the S1P-specific members of the EDG family (14 -16). However, the recently identified non-EDG family LPA receptors, LPA 4 /p2y9 (13), LPA 5 /GPR92 (17, 18), LPA 6 /GPR87 (19), LPA 7 /p2y5 (12), and LPA 8 /p2y10 (10), are more closely related to the purinoreceptor gene cluster and share less than 20% amino acid...

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“…The exposure of human platelets to LPA triggers shape change (3)(4)(5), fibronectin matrix assembly (6), and platelet-leukocyte interactions (7). LPA is also a weak activator of human platelet aggregation and potentiates the effects of other agonists such as ADP and epinephrine (3,8,9); although interestingly, platelets isolated from ϳ20% of normal donors are selectively unresponsive to LPA (10,11).…”

mentioning

confidence: 99%

Autotaxin/Lysopholipase D and Lysophosphatidic Acid Regulate Murine Hemostasis and Thrombosis

Pamuklar

Federico

Liu

et al. 2009

Journal of Biological Chemistry

131

132

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The lipid mediator lysophosphatidic acid (LPA) is a potent regulator of vascular cell function in vitro, but its physiologic role in the cardiovasculature is largely unexplored. To address the role of LPA in regulating platelet function and thrombosis, we investigated the effects of LPA on isolated murine platelets. Although LPA activates platelets from the majority of human donors, we found that treatment of isolated murine platelets with physiologic concentrations of LPA attenuated agonist-induced aggregation. Transgenic overexpression of autotaxin/lysophospholipase D (Enpp2), the enzyme necessary for production of the bulk of biologically active LPA in plasma, elevated circulating LPA levels and induced a bleeding diathesis and attenuation of thrombosis in mice. Intravascular administration of exogenous LPA recapitulated the prolonged bleeding time observed in Enpp2-Tg mice. Enpp2 ؉/؊ mice, which have ϳ50% normal plasma LPA levels, were more prone to thrombosis. Plasma autotaxin associated with platelets during aggregation and concentrated in arterial thrombus, and activated but not resting platelets bound recombinant autotaxin/ lysoPLD in an integrin-dependent manner. These results identify a novel pathway in which LPA production by autotaxin/lysoPLD regulates murine hemostasis and thrombosis and suggest that binding of autotaxin/lysoPLD to activated platelets may provide a mechanism to localize LPA production.

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The plaque lipid lysophosphatidic acid stimulates platelet activation and platelet-monocyte aggregate formation in whole blood: involvement of P2Y1 and P2Y12 receptors

Cited by 112 publications

References 39 publications

Novel uses for anti‐platelet agents as anti‐inflammatory drugs

Novel uses for anti‐platelet agents as anti‐inflammatory drugs

Unique Ligand Selectivity of the GPR92/LPA5 Lysophosphatidate Receptor Indicates Role in Human Platelet Activation

Autotaxin/Lysopholipase D and Lysophosphatidic Acid Regulate Murine Hemostasis and Thrombosis

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