Claudia Tersteeg1, Harry F Heijnen, Anita Eckly, Gerard Pasterkamp, Rolf T Urbanus, Coen Maas, Imo E Hoefer, Rienk Nieuwland, Richard W Farndale, Christian Gachet, Philip G de Groot, Mark Roest. 1. From the Laboratory of Clinical Chemistry and Haematology (C.T., H.F.H., R.T.U., C.M., P.G.d.G., M.R.), Laboratory of Experimental Cardiology (C.T., G.P., I.E.H.), and Cell Microscopy Center, Department of Cell Biology (H.F.H.), UMC Utrecht, Utrecht, The Netherlands; UMR-S949 INSERM, EFS-Alsace, Université de Strasbourg, Strasbourg, France (A.E., C.G.); Department of Clinical Chemistry, AMC Amsterdam, Amsterdam, The Netherlands (R.N.); and Department of Biochemistry, University of Cambridge, Cambridge, United Kingdom (R.W.F.).
Abstract
RATIONALE: Platelets are the most important cells in the primary prevention of blood loss after injury. In addition, platelets are at the interface between circulating leukocytes and the (sub)endothelium regulating inflammatory responses. OBJECTIVE: Our aim was to study the dynamic process that leads to the formation of procoagulant and proinflammatory platelets under physiological flow. METHODS AND RESULTS: In the present study, we describe the formation of extremely long, negatively charged membrane strands that emerge from platelets adhered under flow. These flow-induced protrusions (FLIPRs) are formed in vitro on different physiological substrates and are also detected in vivo in a mouse carotid injury model. FLIPRs are formed downstream the adherent and activated platelets and reach lengths of 250 μm. FLIPR formation is shear-dependent and requires cyclophilin D, calpain, and Rac1 activation. It is accompanied by a disassembly of the F-actin and microtubule organization. Monocytes and neutrophils roll over FLIPRs in a P-selectin/P-selectin glycoprotein ligand-1-dependent manner, retrieving fragments of FLIPRs as microparticles on their surface. Consequently, monocytes and neutrophils become activated, as demonstrated by increased CD11b expression and L-selectin shedding. CONCLUSIONS: The formation of long platelet membrane extensions, such as the ones presented in our flow model, may pave the way to generate an increased membrane surface for interaction with monocytes and neutrophils. Our study provides a mechanistic model for platelet membrane transfer and the generation of monocyte/neutrophil-microparticle complexes. We propose that the formation of FLIPRs in vivo contributes to the well-established proinflammatory function of platelets and platelet-derived microparticles.
RATIONALE: Platelets are the most important cells in the primary prevention of blood loss after injury. In addition, platelets are at the interface between circulating leukocytes and the (sub)endothelium regulating inflammatory responses. OBJECTIVE: Our aim was to study the dynamic process that leads to the formation of procoagulant and proinflammatory platelets under physiological flow. METHODS AND RESULTS: In the present study, we describe the formation of extremely long, negatively charged membrane strands that emerge from platelets adhered under flow. These flow-induced protrusions (FLIPRs) are formed in vitro on different physiological substrates and are also detected in vivo in a mouse carotid injury model. FLIPRs are formed downstream the adherent and activated platelets and reach lengths of 250 μm. FLIPR formation is shear-dependent and requires cyclophilin D, calpain, and Rac1 activation. It is accompanied by a disassembly of the F-actin and microtubule organization. Monocytes and neutrophils roll over FLIPRs in a P-selectin/P-selectin glycoprotein ligand-1-dependent manner, retrieving fragments of FLIPRs as microparticles on their surface. Consequently, monocytes and neutrophils become activated, as demonstrated by increased CD11b expression and L-selectin shedding. CONCLUSIONS: The formation of long platelet membrane extensions, such as the ones presented in our flow model, may pave the way to generate an increased membrane surface for interaction with monocytes and neutrophils. Our study provides a mechanistic model for platelet membrane transfer and the generation of monocyte/neutrophil-microparticle complexes. We propose that the formation of FLIPRs in vivo contributes to the well-established proinflammatory function of platelets and platelet-derived microparticles.
Authors: Secil Koseoglu; Christian G Peters; Jennifer L Fitch-Tewfik; Omozuanvbo Aisiku; Lydia Danglot; Thierry Galli; Robert Flaumenhaft Journal: Blood Date: 2015-05-21 Impact factor: 22.113
Authors: Silvia H De Paoli; Tseday Z Tegegn; Oumsalama K Elhelu; Michael B Strader; Mehulkumar Patel; Lukas L Diduch; Ivan D Tarandovskiy; Yong Wu; Jiwen Zheng; Mikhail V Ovanesov; Abdu Alayash; Jan Simak Journal: Cell Mol Life Sci Date: 2018-02-09 Impact factor: 9.261
Authors: Petrus Linge; Paul R Fortin; Christian Lood; Anders A Bengtsson; Eric Boilard Journal: Nat Rev Rheumatol Date: 2018-03-21 Impact factor: 20.543
Authors: Paul Vulliamy; Lucy Z Kornblith; Matthew E Kutcher; Mitchell J Cohen; Karim Brohi; Matthew D Neal Journal: Platelets Date: 2020-01-27 Impact factor: 3.862
Authors: Luc H Boudreau; Anne-Claire Duchez; Nathalie Cloutier; Denis Soulet; Nicolas Martin; James Bollinger; Alexandre Paré; Matthieu Rousseau; Gajendra S Naika; Tania Lévesque; Cynthia Laflamme; Geneviève Marcoux; Gérard Lambeau; Richard W Farndale; Marc Pouliot; Hind Hamzeh-Cognasse; Fabrice Cognasse; Olivier Garraud; Peter A Nigrovic; Helga Guderley; Steve Lacroix; Louis Thibault; John W Semple; Michael H Gelb; Eric Boilard Journal: Blood Date: 2014-07-31 Impact factor: 22.113
Authors: Frederik Denorme; Bhanu Kanth Manne; Irina Portier; Alicia S Eustes; Yasuhiro Kosaka; Benjamin T Kile; Matthew T Rondina; Robert A Campbell Journal: Blood Date: 2020-02-06 Impact factor: 25.476