Structural and Functional Characterization of Four Novel Fibrinogen Mutations in FGB Causing Congenital Fibrinogen Disorder.

ABSTRACT

Congenital fibrinogen disorders are caused by mutations in genes coding for fibrinogen and may lead to various clinical phenotypes. Here, we present a functional and structural analysis of 4 novel variants located in the FGB gene coding for fibrinogen Bß chain-heterozygous missense BßY416C and BßA68S, homozygous nonsense BßY345*, and heterozygous nonsense BßW403* mutations. The cases were identified by coagulation screening tests and further investigated by various methods. Fibrin polymerization had abnormal development with decreased maximal absorbance in all patients. Plasmin-induced fibrin degradation revealed different lytic phases of BßY416C and BßW403* than those of the control. Fibrinopeptide cleavage measured by reverse phase high pressure liquid chromatography of BßA68S showed impaired release of fibrinopeptide B. Morphological properties, studied through scanning electron microscopy, differed significantly in the fiber thickness of BßY416C, BßA68S, and BßW403*, and in the fiber density of BßY416C and BßW403*. Finally, homology modeling of BßA68S showed that mutation caused negligible alternations in the protein structure. In conclusion, all mutations altered the correct fibrinogen function or structure that led to congenital fibrinogen disorders.