Incorporation of fibrin molecules containing fibrinopeptide A alters clot ultrastructure and decreases permeability

Summary Previous studies have shown that a heterozygous mutation in the fibrinogen Aα chain gene, which results in an Aα R16C substitution, causes fibrinolytic resistance in the fibrin clot. This mutation prevents thrombin cleavage of fibrinopeptide A from mutant Aα R16C chains, but not from wild‐ty...

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Published in:British journal of haematology 2007-07, Vol.138 (1), p.117-124
Main Authors: Flood, Veronica H., Nagaswami, Chandrasekaran, Chernysh, Irina N., Al‐Mondhiry, Hamid A., Weisel, John W., Farrell, David H.
Format: Article
Language:English
Subjects:
biochemistry
Biological and medical sciences
Blood Coagulation - genetics
Blood Coagulation Tests
Blotting, Western
coagulation factors
Elasticity
Fibrin - metabolism
Fibrin Fibrinogen Degradation Products - physiology
Fibrinolysis
Fibrinopeptide A - analysis
Fibrinopeptide A - genetics
genetics of thrombosis and haemostasis
Hematologic and hematopoietic diseases
Medical sciences
Microscopy, Electron, Scanning
Mutation
Permeability
Sequence Analysis, Protein
thrombin
Viscosity
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Summary:Summary Previous studies have shown that a heterozygous mutation in the fibrinogen Aα chain gene, which results in an Aα R16C substitution, causes fibrinolytic resistance in the fibrin clot. This mutation prevents thrombin cleavage of fibrinopeptide A from mutant Aα R16C chains, but not from wild‐type Aα chains. However, the mechanism underlying the fibrinolytic resistance is unclear. Therefore, this study investigated the biophysical properties of the mutant fibrin that contribute to fibrinolytic resistance. Fibrin clots made from the mutant fibrinogen incorporated molecules containing fibrinopeptide A into the polymerised clot, which resulted in a ‘spiky’ clot ultrastructure with barbed fibrin strands. The clots were less stiff than normal fibrin and were cross‐linked slower by activated FXIII, but had an increased average fiber diameter, were more dense, had smaller pores and were less permeable. Protein sequencing showed that unclottable fibrinogen remaining in the supernatant consisted entirely of homodimeric Aα R16C fibrinogen, whereas both cleaved wild‐type α chains and uncleaved Aα R16C chains were in the fibrin clot. Therefore, fibrinolytic resistance of the mutant clots is probably a result of altered clot ultrastructure caused by the incorporation of fibrin molecules containing fibrinopeptide A, resulting in larger diameter fibers and decreased permeability to fibrinolytic enzymes.
ISSN:0007-1048
1365-2141
DOI:10.1111/j.1365-2141.2007.06630.x