Endothelial Cell VE-cadherin Functions as a Receptor for the β15–42 Sequence of Fibrin
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Cited by 118 publications
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Fibrin deposition and exudation of plasma fibrinogen (Fg) have long been recognized as hallmarks of inflammation, cardiovascular disease and neoplasia. The Fg-b 15-42 domain binds to the endothelial cell adhesion molecule, VE-cadherin, promoting endothelial cell proliferation, angiogenesis and leukocyte diapedesis. Furthermore, spontaneous blood-borne and lymphatic metastasis of some types of tumor emboli requires plasma fibrin(ogen); however, the molecular mechanisms by which this occurs are poorly understood. We sought to determine whether Fg-b 15-42 and VEcadherin binding interactions promote endothelial barrier permeability and breast cancer cell transendothelial migration (TEM) using transwell insert culture systems. Synthetic peptides containing/missing residues b 15-17 critical for In 1865, Armand Trousseau reported the observation that patients with an increased incidence of coagulopathies would later manifest visceral malignancies, which became known as Trousseau's syndrome. Ironically, Trousseau diagnosed himself with his own syndrome in 1866 and died of gastric cancer the following year. Causal factors linked to the prothrombotic state of Trousseau's syndrome also facilitate cancer metastasis, including thrombin, tissue factor, selectins, platelets, endothelial cells (EC) and fibrin. 1 Deposition of fibrinogen (Fg) 5 and fibrin commonly occurs within the stroma of most solid tumors, 2 and elevated levels of plasma Fg and fibrin degradation products (FDPs) correlate positively with lymph node involvement and metastasis of colon, ovarian, lung and breast cancers. 1 Studies by Degen and co-workers 3-5 have firmly established that plasma fibrin(ogen) and platelets play critical roles in spontaneous cancer metastasis through both the circulation and lymphatic systems, in part by protecting tumor cells from natural killer cell-mediated lysis.Expression of interleukin (IL)-6 during systemic inflammation upregulates expression of specific plasma proteins in the liver, including Fg. 6 Excessive fibrin deposition is accompanied by local expression of proinflammatory mediators, vascular leakage, and inflammatory cell recruitment and activation leading to amplification of the inflammatory response. 2,7,8 Residues 15-42 on the b chain of Fg have been implicated in functional attributes ascribed to fibrin(ogen). Although the primary structure of fibrinopeptide B (FPB) is poorly conserved across species, the fibrin b 15-42 domain is highly conserved, implying evolutionary conservation of function. 9 The b 15-42 region constitutes a cryptic domain in soluble Fg that is exposed in fibrin after thrombin cleavage. 10 Newly exposed residues, b15-GHRP-18, promote lateral aggregation of fibrin monomers during polymerization and insoluble clot formation in secondary hemostasis. 10 Furthermore, exposure of the b 15-42 domain mediates fibrin binding to EC surfaces, 11 promotes EC adhesion and spreading, 12 and stimulates proliferation of EC, fibroblasts and cancer cells. 13,14 Cadherins mediate homophilic cell-cell adhesion...
Fibrin deposition and exudation of plasma fibrinogen (Fg) have long been recognized as hallmarks of inflammation, cardiovascular disease and neoplasia. The Fg-b 15-42 domain binds to the endothelial cell adhesion molecule, VE-cadherin, promoting endothelial cell proliferation, angiogenesis and leukocyte diapedesis. Furthermore, spontaneous blood-borne and lymphatic metastasis of some types of tumor emboli requires plasma fibrin(ogen); however, the molecular mechanisms by which this occurs are poorly understood. We sought to determine whether Fg-b 15-42 and VEcadherin binding interactions promote endothelial barrier permeability and breast cancer cell transendothelial migration (TEM) using transwell insert culture systems. Synthetic peptides containing/missing residues b 15-17 critical for In 1865, Armand Trousseau reported the observation that patients with an increased incidence of coagulopathies would later manifest visceral malignancies, which became known as Trousseau's syndrome. Ironically, Trousseau diagnosed himself with his own syndrome in 1866 and died of gastric cancer the following year. Causal factors linked to the prothrombotic state of Trousseau's syndrome also facilitate cancer metastasis, including thrombin, tissue factor, selectins, platelets, endothelial cells (EC) and fibrin. 1 Deposition of fibrinogen (Fg) 5 and fibrin commonly occurs within the stroma of most solid tumors, 2 and elevated levels of plasma Fg and fibrin degradation products (FDPs) correlate positively with lymph node involvement and metastasis of colon, ovarian, lung and breast cancers. 1 Studies by Degen and co-workers 3-5 have firmly established that plasma fibrin(ogen) and platelets play critical roles in spontaneous cancer metastasis through both the circulation and lymphatic systems, in part by protecting tumor cells from natural killer cell-mediated lysis.Expression of interleukin (IL)-6 during systemic inflammation upregulates expression of specific plasma proteins in the liver, including Fg. 6 Excessive fibrin deposition is accompanied by local expression of proinflammatory mediators, vascular leakage, and inflammatory cell recruitment and activation leading to amplification of the inflammatory response. 2,7,8 Residues 15-42 on the b chain of Fg have been implicated in functional attributes ascribed to fibrin(ogen). Although the primary structure of fibrinopeptide B (FPB) is poorly conserved across species, the fibrin b 15-42 domain is highly conserved, implying evolutionary conservation of function. 9 The b 15-42 region constitutes a cryptic domain in soluble Fg that is exposed in fibrin after thrombin cleavage. 10 Newly exposed residues, b15-GHRP-18, promote lateral aggregation of fibrin monomers during polymerization and insoluble clot formation in secondary hemostasis. 10 Furthermore, exposure of the b 15-42 domain mediates fibrin binding to EC surfaces, 11 promotes EC adhesion and spreading, 12 and stimulates proliferation of EC, fibroblasts and cancer cells. 13,14 Cadherins mediate homophilic cell-cell adhesion...
Endothelial cell contacts control the permeability of the blood vessel wall. This allows the endothelium to form a barrier for solutes, macromolecules, and leukocytes between the vessel lumen and the interstitial space. Loss of this barrier function in pathophysiological situations can lead to extracellular oedema. The ability of leukocytes to enter tissue at sites of inflammation is dependent on molecular mechanisms that allow leukocytes to adhere to the endothelium and to migrate through the endothelial cell layer and the underlying basal lamina. It is a commonly accepted working hypothesis that inter‐endothelial cell contacts are actively opened and closed during this process. Angiogenesis is another important process that requires well‐controlled regulation of inter‐endothelial cell contacts. The formation of new blood vessels by sprouting from pre‐existing vessels depends on the loosening of established endothelial cell contacts and the migration of endothelial cells that form the outgrowing sprouts. This review focuses on the molecular composition of endothelial cell surface proteins and proteins of the cytoskeletal undercoat of the plasma membrane at sites of inter‐endothelial cell contacts and discusses the current knowledge about the potential role of such molecules in the regulation of endothelial cell contacts. Copyright © 2000 John Wiley & Sons, Ltd.
Originally published in: Protein Folding Handbook. Part II. Edited by Johannes Buchner and Thomas Kiefhaber. Copyright © 2005 Wiley‐VCH Verlag GmbH & Co. KGaA Weinheim. Print ISBN: 3‐527‐30784‐2 The sections in this article are Introduction Overview: Protein Fibers Formed in vivo Amyloid Fibers Silks Collagens Actin, Myosin, and Tropomyosin Filaments Intermediate Filaments/Nuclear Lamina Fibrinogen/Fibrin Microtubules Elastic Fibers Flagella and Pili Filamentary Structures in Rod‐like Viruses Protein Fibers Used by Viruses and Bacteriophages to Bind to Their Hosts Overview: Fiber Structures Study of the Structure of β‐sheet‐containing Proteins Amyloid Paired Helical Filaments β‐Silks β‐Sheet‐containing Viral Fibers α‐Helix‐containing Protein Fibers Collagen Tropomyosin Intermediate Filaments Protein Polymers Consisting of a Mixture of Secondary Structure Tubulin Actin and Myosin Filaments Methods to Study Fiber Assembly Circular Dichroism Measurements for Monitoring Structural Changes Upon Fiber Assembly Theory of CD Experimental Guide to Measure CD Spectra and Structural Transition Kinetics Intrinsic Fluorescence Measurements to Analyze Structural Changes Theory of Protein Fluorescence Experimental Guide to Measure Trp Fluorescence Covalent Fluorescent Labeling to Determine Structural Changes of Proteins with Environmentally Sensitive Fluorophores Theory on Environmental Sensitivity of Fluorophores Experimental Guide to Labeling Proteins With Fluorophores 1‐Anilino‐8‐Naphthalensulfonate ( ANS ) Binding to Investigate Fiber Assembly Theory on Using ANS Fluorescence for Detecting Conformational Changes in Proteins Experimental Guide to Using ANS for Monitoring Protein Fiber Assembly Light Scattering to Monitor Particle Growth Theory of Classical Light Scattering Theory of Dynamic Light Scattering Experimental Guide to Analyzing Fiber Assembly Using DLS Field‐flow Fractionation to Monitor Particle Growth Theory of FFF Experimental Guide to Using FFF for Monitoring Fiber Assembly Fiber Growth‐rate Analysis Using Surface Plasmon Resonance Theory of SPR Experimental Guide to Using SPR for Fiber‐growth Analysis Single‐fiber Growth Imaging Using Atomic Force Microscopy Theory of Atomic Force Microscopy Experimental Guide for Using AFM to Investigate Fiber Growth Dyes Specific for Detecting Amyloid Fibers Theory on Congo Red and Thioflavin T Binding to Amyloid Experimental Guide to Detecting Amyloid Fibers with CR and Thioflavin Binding Methods to Study Fiber Morphology and Structure Scanning Electron Microscopy for Examining the Low‐resolution Morphology of a Fiber Specimen Theory of SEM Experimental Guide to Examining Fibers by SEM Transmission Electron Microscopy for Examining Fiber Morphology and Structure Theory of TEM Experimental Guide to Examining Fiber Samples by TEM Cryo‐electron Microscopy for Examination of the Structure of Fibrous Proteins Theory of Cryo‐electron Microscopy Experimental Guide to Preparing Proteins for Cryo‐electron Microscopy Structural Analysis from Electron Micrographs Atomic Force Microscopy for Examining the Structure and Morphology of Fibrous Proteins Experimental Guide for Using AFM to Monitor Fiber Morphology Use of X ‐ray Diffraction for Examining the Structure of Fibrous Proteins Theory of X ‐Ray Fiber Diffraction Experimental Guide to X ‐Ray Fiber Diffraction Fourier Transformed Infrared Spectroscopy Theory of FTIR Experimental Guide to Determining Protein Conformation by FTIR Conclusions Acknowledgements
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