Hypofibrinogenemia with preserved hemostasis and protection from thrombosis in mice with a Fga truncation mutation
Genetic variants within the fibrinogen Aa-chain encoding the aC-region commonly result in hypodysfibrinogenemia in patients. However, the (patho)physiological consequences and underlying mechanisms of such mutations remain undefined. Here, we generated Fga270 mice carrying a premature termination codon within the Fga gene at residue 271. The Fga270 mutation was compatible with Mendelian inheritance for offspring of heterozygous crosses. Adult Fga270/270 mice were hypofibrinogenemic with ~10% plasma fibrinogen levels relative to FgaWT/WTmice, linked to 90% reduction in hepatic Fga mRNA due to nonsense-mediated decay of the mutant mRNA. Fga270/270 mice had preserved hemostatic potential in vitro and in vivo in models of tail bleeding and laser-induced saphenous vein injury, while Fga-/- mice had continuous bleeding. Platelets from FgaWT/WTandFga270/270 mice displayed comparable initial aggregation following ADP stimulation, but Fga270/270 platelets quickly disaggregated. Despite ~10% plasma fibrinogen, the fibrinogen level in Fga270/270 platelets was ~30% of FgaWT/WT platelets with a compensatory increase in fibronectin. Notably, Fga270/270 mice showed complete protection from thrombosis in the inferior vena cava stasis model. In a model of Staphylococcus aureus peritonitis, Fga270/270 mice supported local, fibrinogen-mediated bacterial clearance and host survival comparable to FgaWT/WT, unlike Fga-/- mice. Decreasing the normal fibrinogen levels to ~10% with siRNA in mice also provided significant protection from venous thrombosis without compromising hemostatic potential and antimicrobial function. These findings both reveal novel molecular mechanisms underpinning fibrinogen aC-region truncation mutations and highlight the concept that selective fibrinogen reduction may be efficacious for limiting thrombosis while preserving hemostatic and immune protective functions.