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DOI: 10.1160/TH10-03-0179
A novel missense mutation in the FGB g. 3354 T>A (p. Y41N), Fibrinogen Caracas VIII
Financial support: This work was partially supported by NIH Grant HL 30954 and a fellowship to Oscar Castillo from the Oficina de Planificación del Sector Universitario (OPSU). Received: March 16, 2010 Accepted after major revision: January 16, 2011 Prepublished online: February 8, 2011
Publikationsverlauf
Received:
16. März 2010
Accepted after major revision:
16. Januar 2011
Publikationsdatum:
28. November 2017 (online)
Summary
A novel dysfibrinogenaemia with a replacement of Tyr by Asn at Bβ41 has been discovered (fibrinogen Caracas VIII). An asymptomatic 39-year-old male was diagnosed as having dysfibrinogenaemia due to a mildly prolonged thrombin time (+ 5.8 seconds); his fibrinogen concentration was in the low normal range, both by Clauss and gravimetric determination, 1.9 g/l and 2.1 g/l, respectively. The plasma polymerization process was slightly impaired, characterised by a mildly prolonged lag time and a slightly increased final turbidity. Permeation through the patients´ clots was dramatically increased, with the Darcy constant around four times greater than that of the control (22 ± 2 x10–9 cm2 compared to 6 ± 0.5 x10–9 cm2 in controls). The plasma fibrin structure of the patient, by scanning electron microscopy, featured a mesh composed of thick fibres (148 ± 50 nm vs. 120 ± 31 nm in controls, p<0.05) and larger pores than those of the control fibrin clot. The viscoelastic properties of the clot from the patient were also altered, as the storage modulus (G‘, 310 ± 30) was much lower than in the control (831 ± 111) (p ≤0.005). The interaction of the fibrin clot with a monolayer of human microvascular endothelial cells, by confocal laser microscopy, revealed that the patients´ fibrin network had less interaction with the cells. These results demonstrate the significance of the amino terminal end of the β chain of fibrin in the polymerisation process and its consequences on the clot organisation on the surface of endothelial cells.
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References
- 1 Mackie IJ, Kitchen S, Machin SJ. et al. Haemostasis and Thrombosis Task Force of the British Committee for Standards in Haematology. Br J Haematol 2003; 121: 396-404.
- 2 Scheraga HA, Laskowski M. Jr. The fibrinogen-fibrin conversion. Adv Protein Chem 1957; 12: 1-19.
- 3 Blombäck B, Hessel B, Hogg D. et al. A two-step fibrinogen-fibrin transition in blood coagulation. Nature 1978; 275: 501-505.
- 4 Weisel JW. Fibrinogen and fibrin. Adv Protein Chem 2005; 70: 247-299.
- 5 Laudano AP, Doolittle RF. Synthetic peptide derivatives that bind to fibrinogen and prevent the polymerization of fibrin monomers. Proc Natl Acad Sci USA 1978; 75: 3085-3089.
- 6 Laudano AP, Doolittle RF. Influence of calcium ion on the binding of fibrin amino terminal peptides to fibrinogen. Science 1981; 212: 457-459.
- 7 Siebenlist KR, Mosesson MW. Evidence for cross-linked Aα.γ chain heterodimers in plasma fibrinogen. Biochemistry 1996; 35: 5817-5821.
- 8 Van Hinsbergh VW, Koolwijk P, Hanemaaijer R. Role of fibrin and plasminogen activators in repair-associated angiogenesis: in vitro studies with human endothelial cells. EXS 1997; 79: 391-411.
- 9 Laurens N, Koolwijk P, de Maat MP. Fibrin structure and wound healing. J Thromb Haemost 2006; 4: 932-939.
- 10 Belkin AM, Tsurupa G, Zemskov E. et al. Transglutaminase-mediated oligomerization of the fibrin(ogen) αC domains promotes integrin-dependent cell adhesion and signaling. Blood 2005; 105: 3561-3568.
- 11 Cheresh DA, Berliner SA, Vicente V. et al. Recognition of distinct adhesive sites on fibrinogen by related integrins on platelets and endothelial cells. Cell 1989; 58: 945-953.
- 12 Charo IF, Nannizzi L, Smith JW. et al. The vitronectin receptor αvβ3 binds fibronectin and acts in concert with α5β1 in promoting cellular attachment and spreading on fibronectin. J Cell Biol 1990; 111: 2795-2800.
- 13 Yokoyama K, Zhang XP, Medved L. et al. Specific binding of integrin αvβ3 to fibrinogen γ αnd αE chain C-terminal domains. Biochemistry 1999; 38: 5872-5877.
- 14 Bach TL, Barsigian C, Yaen CH. et al. Endothelial cell VE-cadherin as a receptor for the beta15–42 sequence of fibrin. J Biol Chem 1998; 273: 30719-30728.
- 15 Languino LR, Plescia J, Duperray A. et al. Fibrinogen mediates leukocyte adhesion to vascular endothelium through an ICAM-1-dependent pathway. Cell 1993; 73: 1423-1434.
- 16 de Maat MP, Verschuur M. Fibrinogen heterogeneity: inherited and noninherited. Curr Opin Hematol 2005; 12: 377-383.
- 17 Hill M, Dolan G. Diagnosis, clinical features and molecular assessment of the dysfibrinogenaemias. Haemophilia 2008; 14: 889-897.
- 18 Mosseson MW. Hereditary fibrinogen abnormalities. In: Williams Hematology. 7th ed. McGraw-Hill Medical; 2006. pp. 1909-1927.
- 19 Ingram GIC. The determination of plasma fibrinogen by the clot weight method. Biochem J 1952; 51: 583-585.
- 20 Kierulf P, Jakobsen E. A modified beta-alanine precipitation procedure to prepare fibrinogen free of antithrombin-III and plasminogen. Thromb Res 1973; 3: 145-149.
- 21 Marchi R, Meyer M, de Bosch N. et al. Biophysical characterization of fibrinogen Caracas I with an Aα-chain truncation at Aα 466 Ser. Identification of the mutation and biophysical characterization of properties of clots from plasma and purified fibrinogen. Blood Coagul Fibrinolysis 2004; 15: 285-293.
- 22 Blombäck B, Okada M. Fibrin gel structure and clotting time. Thromb Res 1982; 25: 51-70.
- 23 Langer BG, Weisel JW, Dinauer PA. et al. Deglycosylation of fibrinogen accelerates polymerization and increases lateral aggregation of fibrin fibers. J Biol Chem 1988; 263: 15056-15063.
- 24 Janmey PA. A torsion pendulum for measurement of the viscoelasticity of bio-polymers and its application to actin networks. J Biochem Biophys Methods 1991; 22: 41-53.
- 25 Herrmann FH, Wulff K, Auerswald G. et al. Factor VII deficiency: clinical manifestation of 717 subjects from Europe and Latin America with mutations in the factor 7 gene. Haemophilia 2009; 15: 267-280.
- 26 Bouvier CA, Gruendlinger J. Study of the phenomena of coagulation and fibrinolysis by a simple method of continuous optical registration. Schweiz Med Wochenschr 1963; 93: 1451-1455.
- 27 Pandya BV, Gabriel JL, O’Brien J. et al. Polymerization site in the β chain of fibrin: mapping of the Bβ 1–55 sequence. Biochemistry 1991; 30: 162-168.
- 28 Bunce LA, Spom LA, Francis CW. Endothelial cell spreading on fibrin requires fibrinopeptide B cleavage and amino acid residues 15–42 of the β chain. J Clin Invest 1992; 89: 842-850.
- 29 Weisel JW. Which knobs fit into which holes in fibrin polymerization?. J Thromb Haemost 2007; 5: 2340-2343.
- 30 Siebenlist KR, DiOrio JP, Budzynski AZ. et al. The polymerization and thrombin-binding properties of des-(Bβ 1–42)-fibrin. J Biol Chem 1990; 265: 18650-18655.
- 31 Weisel JW, Nagaswami C. Computer modeling of fibrin polymerization kinetics correlated with electron microscope and turbidity observations: clot structure and assembly are kinetically controlled. Biophys J 1992; 63: 111-128.
- 32 Ryan EA, Mockros LF, Weisel JW. et al. Structural origins of fibrin clot rheology. Biophys J 1999; 77: 2813-2826.
- 33 Baradet TC, Haselgrove JC, Weisel J. Three-dimensional reconstruction of fibrin clot networks from stereoscopic intermediate voltage electron microscope images and analysis of branching. Biophys J 1995; 68: 1551-1560.
- 34 Ferry JD. Structure and rheology of fibrin networks. In: Biological and synthetic polymer networks. Kramer O.. ed. Elsevier; Amsterdam: 1988. pp. 41-55.
- 35 Abou-Saleh RH, Connell SD, Harrand R. et al. Nanoscale probing reveals that reduced stiffness of clots from fibrinogen lacking 42 N-terminal Bβ-chain residues is due to the formation of abnormal oligomers. Biophys J 2009; 96: 2415-2427.
- 36 De Caterina R, Massaro M, Libby P. Endothelial functions and dysfunctions. In: Endothelial dysfunctions and vascular disease. 1st ed. Blackwell Futura; 2007. pp. 3-25.
- 37 Vestweber D, Winderlich M, Cagna G. et al. Cell adhesion dynamics at endothelial junctions: VE-cadherin as a major player. Trends Cell Biol 2008; 19: 8-15.
- 38 Jerome WG, Handt S, Hantgan RR. Endothelial cells organize fibrin clots into structures that are more resistant to lysis. Microsc Microanal 2005; 11: 268-277.
- 39 Campbell RA, Overmyer KA, Bagnell CR. et al. Cellular procoagulant activity dictates clot structure and stability as a function of distance from the cell surface. Arterioscler Thromb Vasc Biol 2008; 28: 2247-2254.
- 40 Campbell RA, Overmyer KA, Selzman CH. et al. Contributions of extravascular and intravascular cells to fibrin network formation, structure, and stability. Blood 2009; 114: 4886-4896.