Studies of structural and functional changes of fibrinogen
Authors:
J. Štikarová; R. Kotlín; J. Suttnar; T. Riedel; J. E. Dyr
Authors place of work:
Oddělení biochemie Ústavu hematologie a krevní transfuze Praha, vedoucí oddělení biochemie prof. Ing. Jan E. Dyr, DrSc.
Published in the journal:
Vnitř Lék 2012; 58(Suppl 2): 70-83
Category:
Summary
At the Institute of Hematology and Blood Transfusion, we have been studying hereditary dysfibrinogenemia for more than ten years. During this period we have described more than 30 families in the Czech Republic with inherited mutations in fibrinogen. This paper provides an overview of 8 interesting cases of dysfibrinogenemia which we have characterized. Individual cases differ mainly in their clinical manifestations. The study of congenital fibrinogen disorders provides scientists and clinicians important information on structural and functional aspects of the fibrinogen molecule during various physiological processes, especially hemostasis. For roughly one third of the patients with thrombosis the causes of their thrombotic complications have not been found yet. It is therefore possible that at least some of them might be the result of mutations in fibrinogen molecule, especially if these changes do not have to affect basic coagulation tests. Mutations Bβ Arg237Ser, γ Tyr363Asn, and Aα Asn106Asp have thrombotic manifestation. The carriers of these mutations reported both deep vein thrombosis and pulmonary embolism. Mutations Aα Gly13Glu, Aα Arg16Cys, γ Tyr262Cys, and γ Arg275His have bleeding manifestation with varying intensity. A seven year old carrier of the Aα Arg16His mutation has been asymptomatic; however clinical manifestation of the mutation in the future cannot be excluded because the mutation is situated in the site of fibrinopeptide A release. Posttranslational modified fibrinogen is linked with various diseases. These diseases are associated with oxidative stress which leads to uncontrolled production of oxidants. The oxidants modify structure as well as affect function of fibrinogen. We used several oxidative reagents mimicking various (patho)physiological states. We characterized the structural changes with quantification of carbonyls groups and SDS-PAGE followed by immunodetection. Tyrosyl radicals were also detected by SDS-PAGE with immunodetection and by fluorescent determinations. To determine the extent of oxidative nature of the fibrinogen we used OFR (Oxidative Fibrinogen Reactivity). We also studied the influence of these structural changes on the fibrin network architecture (scanning electron microscopy), the interaction of fibrinogen with thrombin (fibrinopeptides release, turbidimetric monitoring of fibrin network formation) and platelets (static and dynamic adhesion of platelets). New carbonyl groups and tyrosyl radicals were formed in fibrinogen. Most modifications occured both to influence fibrin network as well as its interaction with platelets. The overall effect of the functional changes depended on the nature and intensity of the oxidizing agent and what is very important, ranged from protitrombogennic to significantly thrombogenic.
Key words:
fibrinogen – dysfibrinogenemia – oxidative stress
Zdroje
1. Weisel JW. Fibrinogen and fibrin. Adv Protein Chem 2005; 70: 247–299.
2. Brennan SO, Fellowes AP, George PM. Molecular mechanisms of hypo- and afibrinogenemia. Ann NY Acad Sci 2001; 936: 91–100.
3. Hanss M, Biot F. A Database For Human Fibrinogen Variants. Ann N Y Acad Sci 2001; 936: 89–90.
4. Sies H. Strategies of antioxidant defense. Eur J Biochem 1993; 215: 213–219.
5. Griendling KK, FitzGerald GA. Oxidative Stress and Cardiovascular Injury Part I: Basic Mechanisms and In Vivo Monitoring of ROS. Circulation 2003; 108: 1912–1916.
6. Ashi N, Hayes KC, Bao F. The peroxynitrite donor 3-morpholinosydnonimine induces reversible changes in electrophysiological properties of neurons of the gunea-pig spinal cord. Neuroscience 2008; 156: 107–117.
7. Paton LN, Mocatta TJ, Richards AM et al. Increased thrombin-induced polymerization of fibrinogen associated with high protein carbonyl levels in plasma from patients post myocardial infarction. Free Radic Biol Med 2010; 48: 223–229.
8. Upchurch GR, Ramdev N, Wash MT et al. Prothrombotic Consequences of the Oxidation of Fibrinogen and their Inhibition by Aspirin. J Thromb Thrombolysis 1998; 5: 9–14.
9. Mill JD, Ariëns RAS, Mansfield MW et al. Altered Fibrin clot Structure in the Healthy Relatives of Patients With Premature Coronary Artery Disease. Circulation 2002; 106: 1938–1942.
10. Scott EM, Ariëns RAS, Grant PJ. Genetic and Enviromental Determinants of Fibrin Structure and Function. Arterioscler Tromb Vasc Biol 2004; 24: 1558–1566.
11. Alexandru N, Constantin A, Popov D. Carbonylation of platelet proteins occurs as consequence of oxidative stress and thrombin activation, and is stimulated by ageing and type 2 diabetes. Clin Chem Lab Med 2008; 46: 528–536.
12. Undas A, Szułdrzynski K, Stepien E et al. Reduced clot permeability and susceptibility to lysis in patients with acute coronory syndrome: Effects of inflammation and oxidative stress. Atherosclerosis 2007; 196: 551–557.
13. Selmeci L, Seres L, Székely M et al. Assay of oxidized fibrinogen reactivity (OFR) as a biomarker of oxidative stress in human plasma: the role of lysina analogs. Clin Chem Lab Med 2010; 48: 379–382.
14. Schmidt D, Brennan SO. Modified form of the fibrinogen Bb chain (des-Gln Bb), potential long-lived marker of pancreatitis. Clin Chem 2007; 53: 2105–2111.
15. Shacter E, Williams JA, Levine RL. Oxidative modification of fibrinogen inhibits thrombin-catalyzed clot formation. Free Radic Biol Med 1995; 18: 815–821.
16. Nielsen F, Mikkelsen BB, Nielsen JB et al. Plasma malodiadehyde as biomarker for oxidative stress: reference interval and effects of life-style factors. Clin Chem 1997; 43: 1209–1214.
17. Hawkins CL, Davies MJ. Hypochlorite-induced damage to proteins: formation of nitrogen-centred radicals from lysine residues and their role in protein fragmentation. Biochem J 1998; 332: 617–625.
18. Hazell LJ, Stocker R. Oxidation of low-density lipoprotein with hypochlorite causes transformation of the lipoprotein into a high-uptake form for macrophages. Biochem J 1993; 290: 165–172.
19. Vadseth C, Souza JM, Thomson L et al. Pro--trombotic state induced by post-translational modification of fibrinogen by reactive nitrogen species. J Biol Chem 2004; 279: 8820–8826.
20. Nowak P, Wachowicz B. Peroxinitrite-mediated modification of fibrinogen affects platelet agregation and adhesion. Platelets 2002; 13: 293–299.
21. Nowak P, Zbikowska HM, Ponczek M et al. Different vulnerability of fibrinogen subunits to oxidative/nitrative modifications induced by peroxynitrite: functional consenqueces. Thromb Res 2002; 121: 163–174.
22. Akhter S, Vignini A, Wen Z et al. Evidence for S-nitrosothiol-dependent changes in fibrinogen that do not involve transnitrosation or thiolation. PNAS 2002; 99: 1972–1977.
23. Miller SA, Dykes PD, Polesky HF. A simple salting out procedure for extracting DNA from human nucleated cells. Nucl Acid Res 1988; 16: 1215.
24. Kotlín R, Sobotková A, Riedel T et al. Acquired Dysfibrinogenemia Secondary to Multiple Myeloma. Acta Haematol 2008; 120: 75–81.
25. Kotlín R, Chytilová M, Suttnar J et al. A novel fibrinogen variant – Praha I: hypofibrinogenemia associated with γ 351 Gly → Ser substitution. Eur J Haematol 2007; 78: 410–416.
26. Kotlín R, Suttnar J, Čápová I et al. Fibrinogen Šumperk II: dysfibrinogenemia in an individual with two coding mutations. Am J Hematol 2012; 87: 555–557.
27. Kotlín R, Reicheltová Z, Suttnar J et al. Two novel fibrinogen variants in the C-terminus of the Bβ-chain: Fibrinogen Rokycany and fibrinogen Znojmo. J Thromb Thrombolysis 2010; 30: 311–318.
28. Suttnar J, Dyr JE, Fořtová H et al. Determination of fibrinopeptides by high performance liquid chromatography. Biochem Clin Bohemoslov 1989; 18: 17–25.
29. Libondi T, Ragone R, Vincenti D et al. In vitro cross-linking of calf lens a-crystallin by malondialdehyde. Int J Pept Protein Res 1994; 44: 342–347.
30. Morris JS. The acid ionization constant of HOCl from 5 to 35. J Phys Chem 1966; 70: 3798–3805.
31. Levine RL, Garland D, Oliver CN et al. Determination of carbonyl content in oxidatively modified proteins. Meth Enzymol 1990; 186: 464–478.
32. Robinson CE, Keshavarzian A, Pasco DS et al. Determination of Protein Carbonyl Groups by Immunoblotting. Anal Biochem 1999; 266: 48–57.
33. Vlies DV, Wirtz KW, Pap EH. Detection of protein oxidation in rat-1 fibroblasts by fluorescently labeled tyramine. Biochemistry 2001; 40: 7783–7788.
34. Bekman EM, Baranova OA, Gubareva EV et al. Evaluation of the Resistance of Blood Plasma to Oxidative Stress by Oxidizability of Proteins and Lipids during Metal-Catalyzed Oxidation Bull. Exp Biol Med 2006; 142: 268–272.
35. Vaníčková M, Suttnar J, Dyr JE. The adhesion of blood platelets on fibrinogen surface: Comparison of two biochemical microplate assays. Platelets 2006; 17: 470–476.
36. Bellavite P, Andrioli G, Guzzo P et al. A colorimetric method for the measurement of platelet adhesion in microtiter platelets. Anal Biochem 1994; 216: 445–450.
37. Sobotková A, Mášová-Chrastinová L, Suttnar J et al. Antioxidant Change platelet responses to various stimulating events. Free Radic Biol Med 2009; 47: 1707–1714.
38. Kotlín R, Zichová K, Suttnar J et al. Congenital dysfibrinogenemia Aα Gly13Glu associated with bleeding during pregnancy. Thromb Res 2011; 127: 277–278.
39. Kotlín R, Chytilová M, Suttnar J et al. Fibrinogen Nový Jičín and Praha II: Cases of hereditary Aα 16 Arg→Cys and Aα 16 Arg→His dysfibrinogenemia. Thromb Res 2007; 121: 75–84.
40. Kotlín R, Blažek B, Suttnar J et al. Dysfibrinogenemia in childhood: two cases of congenital dysfibrinogens. Blood Coagul Fibrinolysis 2010; 21: 640–648.
41. Kotlín R, Sobotková A, Suttnar J et al. A novel fibrinogen variant – Liberec: dysfibrinogenaemia associated with γ Tyr262Cys substitution. Eur J Haematol 2008; 81: 123–129.
42. Kotlín R, Reicheltová Z, Suttnar J et al. Two novel fibrinogen variants in the C-terminus of the Bβ-chain: fibrinogen Rokycany and fibrinogen Znojmo. J Thromb Thrombolysis 2010; 30: 311–318.
43. Kotlín R, Reicheltová Z, Malý M et al. Two cases of congenital dysfibrinogenemia associated with thrombosis – Fibrinogen Praha III and Fibrinogen Plzeň. Thromb Haemost 2009; 102: 479–486.
44. Kotlín R, Reicheltová Z, Sobotková A et al. Three cases of abnormal fibrinogens: Šumperk (BβHis67Leu), Uničov (BβGly414Ser), and Brno (γ Arg275His). Thromb Haemost 2008; 100: 1199–1200.
45. Gaja A, Terasawa F, Okumuna N. Hereditární dysfibrinogenemie s Aa13Gly®Glu mutací. In: Malý M, Pecka J (eds). Trombóza a hemostáza. Hradec Králové: HK Credit 2001: 114.
46. Asselta R, Duga S, Spena S et al. Congenital afibrinogenemia: mutations leading to premature termination codons in fibrinogen Aα-chain gene are not associated with the decay of the mutant mRNAs. Blood 2001; 98: 3685–3692.
47. Ménaché D. Congenital fibrinogen abnormalities. Ann NY Acad Sci 1983; 408: 121–129.
48. Rose T, Di Cera E. Three-dimensional modeling of thrombin-fibrinogen interaction. J Biol Chem 2002; 277: 18875–18880.
49. Riedel T, Suttnar J, Brynda E et al. Fibrinopeptides A and B release in the process of surface fibrin formation. Blood 2011; 117: 1700–1706.
50. Lane DA, Ireland H, Thompson E et al. Two more fibrinogens (London III and Sydney) with impaired fibrinopeptide release. Thromb Res 1982; 28: 821–824.
51. Lee MH, Kaczmarek E, Chin DT et al. Fibrinogen Ledyard (AαArg16→Cys): Biochemical and physiologic characterization. Blood 1991; 78: 1744–1752.
52. Stucki B, Zenhäusern R, Biedermann B et al. Fibrinogens Bern IV, Bern V and Milano XI: three dysfunctional variants with amino acid substitutions in the thrombin cleavage site of the Aα – chain. Blood Coagul Fibrinolysis 1999; 10: 93–99.
53. Reber P, Furlan M, Beck EA et al. Fibrinogen Bergamo I (Aα16Arg→Cys): Susceptibility Towards Thrombin Following Aminoethylation, Methylation or Carboxyamidomethylation of Cysteine Residues. Thromb Haemost 1985; 54: 390–393.
54. Soria J, Soria C, Samama M et al. Fibrinogen Troyes – Fibrinogen Metz. Two cases of congenital dysfibrinogenemia. Thromb Diath Haemorrh 1972; 27: 619–633.
55. Spraggon G, Everse SJ, Doolittle RF. Crystal structures of fragment D from human fibrinogen and its crosslinked counterpart from fibrin. Nature 1997; 389: 455–462.
56. Doolittle RF, Goldbaum DM, Doolittle LR. Designation of sequence involved in the coiled-coil interdomainal connections in fibrinogen: construction of an atomic scale model. J Mol Biol 1978; 120: 311–325.
57. Voskuilen M, Vermond A, Veeneman GH et al. Fibrinogen lysine residue A alpha 157 plays a crucial role in the fibrin-induced acceleration of plasminogen activation, catalyzed by tissue-type plasminogen activator. J Biol Chem 1987; 262: 5944–5946.
58. Niwa K, Takebe M, Sugo T et al. A γ Gly-268 to Glu substitution is responsible for impaired fibrin assembly in a homozygous dysfibrinogen Kurashiki I. Blood 1996; 87: 4686–4694.
59. Castaman G, Ghiotto R, Duga S et al. A novel fibrinogen γ chain mutation (γ 239 Gln.His) is the cause of dysfibrinogenemia Vicenza. J Thromb Haemost 2005; 3: 600–601.
60. Imafuku Y, Tanaka K, Takahashi K et al. Identification of a dysfibrinogenemia of γR275C (Fibrinogen Fukushima). Clin Chim Acta 2002; 325: 151–156.
61. Borrell M, Garí M. Coll I et al. Abnormal polymerization and normal binding of plasminogen and t-PA in three new dysfibrinogenaemias: Barcelona III and IV (gamma Arg 275→His) and Villajoyosa (gamma Arg 275→Cys). Blood Coagul Fibrinolysis 1995; 6: 198–206.
62. Mimuro J, Kawata Y, Niwa K et al. A new type of Ser substitution for γ Arg-275 in fibrinogen Kamogawa I characterized by impaired fibrin assembly. Thromb Haemost 1999; 81: 940–944.
63. Medved L, Weisel JW. Recommendations for nomenclature on fibrinogen and fibrin. J Thromb Haemost 2009; 7: 355–359.
64. Banfi C, Brioschi M, Barcella S et al. Oxidazed proteins in plasma of patients with heart failure: Role in endothelial damage. Eur J Heart Fail 2008; 10: 244–251.
65. Lee JR, Kim JK, Lee SJ et al. Role of Protein Tyrosine Nitration in Neurodegenerative Diseases and Atherosclerosis. Arch Pharm Res 2009; 32: 1109–1118.
66. Heffron SP, Parastatidis I, Cuhel M et al. Inflammation induces fibrinogen nitration in experimental human endotoxemia. Free Radic Biol Med 2009; 47: 1140–1146.
67. Shacter E, Williams JA, Lim M et al. Differential susceptibility of plasma proteins to oxidative modification – examination by western blot immunoassay. Free Radic Biol Med 1994; 17: 429–437.
68. Lipinski B. Pathophysiology of oxidativestress in diabetes mellitus. J Diabetes Complications 2001; 5: 203–210.
69. Piryazev AP, Aseichev AV, Azizova OA. Effect of Oxidation-Modified Fibrinogen on the Formation and Lysis of Fibrin Clot in the Plasma. Bull Exp Biol Med 2009; 148: 881–883.
70. Tetik S, Kaya K, Demir M et al. Oxidative modification of fibrinogrn affects its binding activity to glycoprotein (GP) IIb/IIIa. Clin Appl Thromb Hemost 2010; 16: 51–59.
71. Tetik S, Kaya K, Yardimci TK. Effect of Oxidized Fibrinogen on Hemostatic System: In Vitro Study. Clin Appl Thromb Hemost 2011; 17: 259–263.
72. Barua RS, Sy F, Srikanth S et al. Effects of cigarette smoke exposure on clot dynamics and fibrin structure: an ex vivo investigation. Artherioscler Thromb Vasc Biol 2010; 30: 75–79.
73. Azizova OA, Aseychev AV, Piryazev AP et al. Effects of oxidized fibrinogen on the functions of blood cells, blood clotting, and rheology. Bull Exp Biol Med 2007; 144: 397–407.
74. Pieters M, Covic N, van der Westhuizen FH et al. Glycaemic control improves fibrin network characteristics in type 2 diabetes – A purified fibrinogen model. Thromb Haemost 2008; 99: 691–700.
Štítky
Diabetology Endocrinology Internal medicineČlánok vyšiel v časopise
Internal Medicine
2012 Číslo Suppl 2
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