Atomic force microscopy-based molecular recognition of a fibrinogen receptor on human erythrocytes.

The established hypothesis for the increase on erythrocyte aggregation associated with a higher incidence of cardiovascular pathologies is based on an increase on plasma adhesion proteins concentration, particularly fibrinogen. Fibrinogen-induced erythrocyte aggregation has been considered to be caused by its nonspecific binding to erythrocyte membranes. In contrast, platelets are known to have a fibrinogen integrin receptor expressed on the membrane surface (the membrane glycoprotein complex alpha(IIb)beta(3)). We demonstrate, by force spectroscopy measurements using an atomic force microscope (AFM), the existence of a single molecule interaction between fibrinogen and an unknown receptor on the erythrocyte membrane, with a lower but comparable affinity relative to platelet binding (average fibrinogen--erythrocyte and --platelet average (un)binding forces were 79 and 97 pN, respectively). This receptor is not as strongly influenced by calcium and eptifibatide (an alpha(IIb)beta(3) specific inhibitor) as the platelet receptor. However, its inhibition by eptifibatide indicates that it is an alpha(IIb)beta(3)-related integrin. Results obtained for a Glanzmann thrombastenia (a rare hereditary bleeding disease caused by alpha(IIb)beta(3) deficiency) patient show (for the first time) an impaired fibrinogen--erythrocyte binding. Correlation with genetic sequencing data demonstrates that one of the units of the fibrinogen receptor on erythrocytes is a product of the expression of the beta(3) gene, found to be mutated in this patient. This work demonstrates and validates the applicability of AFM-based force spectroscopy as a highly sensitive, rapid and low operation cost nanotool for the diagnostic of genetic mutations resulting in hematological diseases, with an unbiased functional evaluation of their severity.

[1]  L. Parise,et al.  Integrin alpha 4 beta 1 and glycoprotein IV (CD36) are expressed on circulating reticulocytes in sickle cell anemia. , 1993, Blood.

[2]  W. Dean,et al.  INCREASED ABILITY OF ERYTHROCYTES TO AGGREGATE IN SPONTANEOUSLY HYPERTENSIVE RATS , 2002, Clinical and experimental hypertension.

[3]  R F Doolittle,et al.  A detailed consideration of a principal domain of vertebrate fibrinogen and its relatives , 1992, Protein science : a publication of the Protein Society.

[4]  Fania Szlam,et al.  A Novel Method to Assess Platelet Inhibition by Eptifibatide with Thrombelastograph® , 2004, Anesthesia and analgesia.

[5]  Tomasz Grodzicki,et al.  Erythrocyte stiffness probed using atomic force microscope. , 2005, Biorheology.

[6]  M. Humphries,et al.  Regulation of the extracellular ligand binding activity of integrins. , 1998, Frontiers in bioscience : a journal and virtual library.

[7]  Klaus Schulten,et al.  Molecular basis of fibrin clot elasticity. , 2008, Structure.

[8]  S. Diamond,et al.  Adhesion of normal erythrocytes at depressed venous shear rates to activated neutrophils, activated platelets, and fibrin polymerized from plasma. , 2002, Blood.

[9]  B E Sobel,et al.  Variable responses to inhibition of fibrinogen binding induced by tirofiban and eptifibatide in blood from healthy subjects. , 1999, The American journal of cardiology.

[10]  S. Lo,et al.  Protein sequence of endothelial glycoprotein IIIa derived from a cDNA clone. Identity with platelet glycoprotein IIIa and similarity to "integrin". , 1987, The Journal of biological chemistry.

[11]  V. Dupres,et al.  Stretching polysaccharides on live cells using single molecule force spectroscopy , 2009, Nature Protocols.

[12]  Thomas Aigner,et al.  Nanomedicine: AFM tackles osteoarthritis. , 2009, Nature nanotechnology.

[13]  Li Zhang,et al.  Ligand Binding to Integrins* , 2000, The Journal of Biological Chemistry.

[14]  Normand Voyer,et al.  Chemical modifications of AFM tips for the study of molecular recognition events. , 2008, Chemical communications.

[15]  T. Sugihara,et al.  Thrombospondin mediates adherence of CD36+ sickle reticulocytes to endothelial cells. , 1992, Blood.

[16]  N. Maeda,et al.  Fibrinogen-induced erythrocyte aggregation: erythrocyte-binding site in the fibrinogen molecule. , 1987, Biochimica et biophysica acta.

[17]  Marek Szymoński,et al.  Dynamic force measurements of avidin-biotin and streptavdin-biotin interactions using AFM. , 2006, Acta biochimica Polonica.

[18]  A. Haeberli,et al.  Force spectroscopy of the fibrin(ogen)–fibrinogen interaction , 2008, Biopolymers.

[19]  M. Rampling The binding of fibrinogen and fibrinogen degradation products to the erythrocyte membrane and its relationship to haemorheology. , 1981, Acta biologica et medica Germanica.

[20]  G. Laurent,et al.  Fibrinogen , 1968, Reactions Weekly.

[21]  Y. Missirlis,et al.  Measuring the force of single protein molecule detachment from surfaces with AFM. , 2010, Colloids and surfaces. B, Biointerfaces.

[22]  André E. X. Brown,et al.  Forced unfolding of coiled-coils in fibrinogen by single-molecule AFM. , 2007, Biophysical journal.

[23]  Chih-Kung Lee,et al.  Atomic force microscopy: determination of unbinding force, off rate and energy barrier for protein-ligand interaction. , 2007, Micron.

[24]  G. I. Bell Models for the specific adhesion of cells to cells. , 1978, Science.

[25]  W. Dean,et al.  Involvement of fibrinogen specific binding in erythrocyte aggregation , 2002, FEBS letters.

[26]  R. Marchant,et al.  Molecular interaction studies of hemostasis: fibrinogen ligand-human platelet receptor interactions. , 2003, Ultramicroscopy.

[27]  M. McElfresh,et al.  Nonlinearly additive forces in multivalent ligand binding to a single protein revealed with force spectroscopy. , 2006, Langmuir : the ACS journal of surfaces and colloids.

[28]  R. Saxena,et al.  Molecular defects in ITGA2B and ITGB3 genes in patients with Glanzmann thrombasthenia , 2009, Journal of thrombosis and haemostasis : JTH.

[29]  J. Rao,et al.  Nanomechanical analysis of cells from cancer patients. , 2007, Nature nanotechnology.

[30]  Miguel A R B Castanho,et al.  An overview of the biophysical applications of atomic force microscopy. , 2003, Biophysical chemistry.

[31]  J. Bennett,et al.  Structure and function of the platelet integrin αIIbβ3 , 2005 .

[32]  Daniel J. Muller,et al.  AFM: a nanotool in membrane biology. , 2008, Biochemistry.

[33]  F Durand,et al.  [Erythrocyte aggregation and vascular pathology]. , 1990, Journal des maladies vasculaires.

[34]  E. Evans,et al.  Dynamic strength of molecular adhesion bonds. , 1997, Biophysical journal.

[35]  R. Eisman,et al.  Structure of the platelet membrane glycoprotein IIb. Homology to the alpha subunits of the vitronectin and fibronectin membrane receptors. , 1987, The Journal of biological chemistry.

[36]  Rustem I. Litvinov,et al.  Multi-Step Fibrinogen Binding to the Integrin αIIbβ3 Detected Using Force Spectroscopy , 2005 .

[37]  D. Frappaz,et al.  Molecular Study of Glanzmann Thrombasthenia in 3 Patients Issued from 2 Different Families , 1995, Thrombosis and Haemostasis.

[38]  A. Manodori Sickle erythrocytes adhere to fibronectin-thrombospondin-integrin complexes exposed by thrombin-induced endothelial cell contraction. , 2001, Microvascular research.

[39]  A. Nurden,et al.  Glanzmann thrombasthenia , 2006, Orphanet journal of rare diseases.

[40]  J. George,et al.  Glanzmann's thrombasthenia: the spectrum of clinical disease. , 1990, Blood.

[41]  B G De Grooth,et al.  Biomolecular interactions measured by atomic force microscopy. , 2000, Biophysical journal.

[42]  D. French,et al.  Platelet glycoprotein IIb/IIIa receptors and Glanzmann's thrombasthenia. , 2000, Arteriosclerosis, thrombosis, and vascular biology.

[43]  P. Nurden,et al.  Platelet glycoprotein IIb/IIIa inhibitors: basic and clinical aspects. , 1999, Arteriosclerosis, thrombosis, and vascular biology.

[44]  J. Moake,et al.  Unusually large von willebrand factor multimers preferentially promote young sickle and nonsickle erythrocyte adhesion to endothelial cells , 1993, American journal of hematology.