Subscribe to RSS
Please copy the URL and add it into your RSS Feed Reader.
https://www.thieme-connect.de/rss/thieme/en/10.1055-s-00035024.xml
Download PDF
Thromb Haemost 1999; 82(03): 1053-1060
DOI: 10.1055/s-0037-1614328
DOI: 10.1055/s-0037-1614328
Letters to the Editor
Surface-dependent Conformations of Human Fibrinogen Observed by Atomic Force Microscopy under Aqueous Conditions
Further Information
Publication History
Received
15 February 1999
Accepted after revision
14 May 1999
Publication Date:
09 December 2017 (online)
Summary
Conformational differences in human fibrinogen under aqueous conditions on hydrophobic, positively charged and negatively charged surfaces, were examined by atomic force microscopy (AFM). Hydrophobic and positively charged surfaces were prepared by depositing octadecyltrichlorosilane (OTS) and 3-aminopropyltriethoxysilane (APTES) respectively on cleaned glass coverslips forming self-assembled monolayers. The negatively charged surface was prepared by freshly cleaving muscovite mica. AFM operated in fluid tapping mode with an ultrasharp carbon spike probe was used to obtain the molecular scale images. Fibrinogen displayed a characteristic trinodular structure on all three surfaces, although additional U-shaped conformations were observed on mica. In its native hydrated state, fibrinogen is well represented by three connected ellipsoids in close proximity. Quantitative dimensional analysis, which yielded structural information in three dimensions, indicates that surface-dependent structural deformation or spreading of fibrinogen increases according to the order: mica < APTES < OTS. Molecular length, and D and E domain widths of fibrinogen are increased, while the corresponding heights are decreased. The results provide direct evidence that material surface properties affect the conformational state of interacting fibrinogen.
-
References
- 1 Hantgan RR, Francis CW, Marder VJ. Fibrinogen structure and physiology. In: Hemostasis and Thrombosis: Basic Principles and Clinical Practice. Colman RW, Hirsh J, Marder VJ, Salzman EW. eds. Third edition. Philadelphia, PA: J.B. Lippincott; 1994: 277-300.
- 2 Bini A, Fenoglio JJ, Mesa-Tejada R, Kudryk B, Kaplan KL. Identification and distribution of fibrinogen, fibrin, and fibrin(ogen) degradation products in atherosclerosis. Use of monoclonal antibodies. Atheroscler 1989; 9: 109-21.
- 3 Davies MJ. A macroscopic and microscopic view of coronary thrombosis. Circulation 1990; 82 suppl. II 38-44.
- 4 Valenzuela RJ, Shainoff JR, Dibello PM, Urbanic DA, Anderson JM, Matsueda GR, Kudryk BJ. Immunoelectrophoretic and immunohistochemical characterization of fibrinogen derivatives in atherosclerotic aortic intimas and vascular prosthesis pseudo-intimas. Am J Pathol 1992; 141: 861-80.
- 5 Hanson SR. Device thrombosis and thromboembolism. Cardiovasc Path 1993; 2: 157S-65S.
- 6 Anderson JM, Kottke-Marchant K. Platelet interactions with biomaterials and artificial devices. In: Fundamental aspects of blood compatibility. Vol. 1 Williams D. ed. Boca Raton, FL: CRC Press; 1987
- 7 Horbett TA. Principles underlying the role of adsorbed plasma proteins in blood interactions with foreign materials. Cardiovasc Pathol 1993; 2: 137S-48S.
- 8 Savage B, Saldivar E, Ruggeri ZM. Initiation of platelet adhesion by arrest onto fibrinogen or translocation on von Willebrand factor. Cell 1996; 84: 289-97.
- 9 Cottonaro CN, Roohk HV, Shimizu G, Sperling DR. Quantitation and characterization of competitive protein binding to polymers. ASAIO Trans 1981; 27: 391-5.
- 10 Collen D, Tytgat GN, Claeys H. Metabolism and distribution of fibrinogen. I. Fibrinogen turnover in physiological conditions in humans. Br J Haematol 1972; 22: 681-700.
- 11 Hoeprich PD, Doolittle RF. Dimeric half molecules of human fibrinogen are joined through disulfide bonds in an antiparallel orientation. Biochemistry 1983; 22: 2049-55.
- 12 Gårlund B, Hessel B, Marguerie G. Primary structure of human fibrinogen: Characterizations of disulfide-containing cyanogen-bromide fragments. Eur J Biochem 1977; 77: 595-610.
- 13 Hall CE, Slayter HS. The fibrinogen molecule: Its size, shape and mode of polymerization. J Biophys Biochem Cytol 1959; 5: 11-7.
- 14 Doolittle RF, Everse SJ, Spraggon G. Human fibrinogen: anticipating a 3-dimensional structure. FASEB J 1996; 10: 1464-70.
- 15 Weisel JW, Phillips GN, Cohen C. A model from electron microscopy for the molecular structure of fibrinogen and fibrin. Nature 1981; 289: 263-7.
- 16 Cohen C, Weisel JW, Phillips GN. The structure of fibrinogen and fibrin. I. Electron microscopy and x-ray crystallography of fibrinogen. Ann NY Acad Sci 1983; 408: 194-213.
- 17 Weisel JW, Stauffacher CV, Bullit E, Cohen C. A model for fibrinogen: Domains and sequence. Science 1985; 230: 1388-91.
- 18 Lal R, John SA. Biological applications of atomic force microscopy. Am J Physiol 1994; 266: C1-21.
- 19 Hansma H, Hoh JH. Biomolecular imaging with the atomic force microscope. Ann Rev Biophys Biomed Struct 1994; 23: 115-39.
- 20 Siedlecki CA, Marchant RE. Atomic force microscopy for characterization of the biomaterial interface. Biomaterials 1998; 19: 441-54.
- 21 Florin E-L, Moy VT, Gaub HE. Adhesion forces between individual ligand-receptor pairs. Science 1994; 264: 415-7.
- 22 A-Hassan E, Heinz WF, Antonik MD, D’Costa NP, Nageswaren S, Schoenenberger CA, Hoh JH. Relative microelastic mapping of living cells by atomic force microscopy. Biophys J 1998; 1564-78.
- 23 Lyubchenko YL, Jacobs BL, Lindsay SM, Stasiak A. Atomic force microscopy of nucleoprotein complexes. Scanning Microsco 1995; 9: 705-24.
- 24 Radmacher M, Fritz M, Hansma HG, Hansma PK. Direct observation of enzyme activity with the atomic force microscope. Science 1994; 265: 1577-9.
- 25 Siedlecki CA, Lestini BJ, Kottke-Marchant K, Eppell SJ, Wilson D, Marchant RE. Shear dependent changes in the three dimensional structure of human von Willebrand factor. Blood 1996; 88: 2939-50.
- 26 Marchant RE, Barb MD, Shainoff JR, Eppell SJ, Wilson DL, Siedlecki CA. Three dimensional structure of human fibrinogen under aqueous conditions visualized by atomic force microscopy. Thromb Haemost 1997; 77: 1048-51.
- 27 Taatjes DJ, Quinn AS, Jenny RJ, Hale P, Bovill EG, McDonagh J. Tertiary structure of the hepatic cell protein fibrinogen in fluid revealed by atomic force microscopy. Cell Biol Internat 1997; 21: 715-26.
- 28 Siedlecki CA, Eppell SJ, Marchant RE. Interactions of human von Willebrand factor with a hydrophobic self-assembled monolayer studied by atomic force microscopy. J Biomed Mater Res 1994; 28: 971-80.
- 29 Bailey SW. Micas. In: Reviews in Mineralogy. Chelsea, Michigan: Book-Crafters, Inc.; 1984: 584.
- 30 Eppell SJ, Simmons SR, Albrecht RM, Marchant RE. Cell-surface receptors and proteins on platelet membranes imaged by scanning force microscopy using immunogold contrast enhancement. Biophys J 1995; 68: 671-80.
- 31 Wilson DL, Kump K, Eppell SJ, Marchant RE. Morphological restoration of atomic force microscopy images. Langmuir 1995; 11: 265-72.
- 32 Wilson DL, Dalal P, Kump K, Benard W, Xue P, Marchant RE, Eppell SJ. Morphological modeling of atomic force microscopy imaging including nanostructure probes and fibrinogen molecules. J Vac Sci Technol B 1996; 14: 2407-16.
- 33 Namba K, Pattanayek R, Stubbs G. Visualization of protein-nucleic acid interactions in a virus. J Mol Biol 1989; 208: 307-25.
- 34 Zenhausern F, Adrian M, Emch R, Taborelli M, Jobin M, Descouts P. Scanning force microscopy and cryo-electron microscopy of tobacco mosaic virus as a test specimen. Ultramicroscopy 1992; 42-44: 1168-72.
- 35 Israelachvili JN. Intermolecular and surface forces. Second edition. San Diego, CA: Academic Press; 1995: 450.
- 36 Brash JL, Horbett TA. Proteins at interfaces: an overview. In: Proteins at interfaces II: Fundamentals and Applications. York, PA: Maple Press; 1995: 1-23.
- 37 Feng F, Andrade JD. Structure and adsorption properties of fibrinogen. In: Proteins at interaces II: Fundamentals and Applications. York, PA: Maple Press; 1995: 66-79.
- 38 Butt H-J. Measuring electrostatic, van der Waals, and hydration forces in electrolyte solutions with an atomic force microscopy. Biophys J 1991; 60: 1438-44.
- 39 Müller DJ, Engel A. The height of biomolecules measured with the atomic force microscope depends on electrostatic interactions. Biophys J 1997; 73: 1633-44.
- 40 Tanaka Y, Nakaya S, Yoshioka Y, Yoshida Y, Hanaoka H, Kawamura R, Yasuda N. Hydration of fibrinogen, fibrin, and fibrin degradation product (FDP) as estimated by nuclear magnetic resonance (NMR) spectroscopy. Blood Coagula Fibrinolysis 1991; 2: 243-9.
- 41 Hantgan RR. Steady-state fluorescence polarization of dansylcadaverine-fibrinogen: evidence for flexibility. Biochemistry 1982; 21: 1821-9.
- 42 Serrallach E, Hofmann VE, Zulauf M, Binkert T, Hofmann R, Känzig W, Straub W, Schwyzer R. Fibrinogen: Agreement of experimental and calculated hydrodynamic data with electron-microscopic models. Thromb Haemost 1979; 41: 648-54.
- 43 Acuña AU, González-Rodriguez J, Lillo MP, Naqvi KR. Protein structure probed by polarization spectroscopy I. Evidence for fibrinogen rigidity from stationary fluorescence. Biophys Chem 1987; 26: 55-61.
- 44 Acuña AU, González-Rodriguez J, Lillo MP, Naqvi KR. Protein structure probed by polarization spectroscopy II. A time resolved fluorescence study of human fibrinogen. Biophys Chem 1987; 26: 63-70.
- 45 Larsson U, Blombäck B, Rigler R. Fibrinogen and the early stages of polymerization to fibrin as studies by dynamic laser light scattering. Biochim Biophys Acta 1987; 915: 172-9.
- 46 Roth CM, Neal BL, Lenhoff AM. van der Waals interactions involving proteins. Biophys J 1996; 70: 977-87.
- 47 Asthagiri D, Lenhoff AM. Influence of structural details in modeling electrostatically driven protein adsorption. Langmuir 1997; 13: 6761-8.
- 48 Marchant RE, Wang I-W. Physical and chemical aspects of biomaterials used in humans. In: Implantation biology: the host response and biomedical devices. Boca Raton, FL: CRC Press; 1994: 13-38.