Identification and characterization of novel mutations implicated in congenital fibrinogen disorders.

INTRODUCTION: Fibrinogen is a complex molecule comprised of two sets of Aα, Bß, and γ chains. Fibrinogen deficiencies can lead to the development of bleeding or thromboembolic events. The objective of this study was to perform DNA sequence analysis of patients with clinical fibrinogen abnormalities, and to perform genotype-phenotype correlations. MATERIALS AND METHODS: DNA from 31 patients was sequenced to evaluate disease-causing mutations in the three fibrinogen genes: FGA,FGB, and FGG. Clinical data were extracted from medical records or from consultation with referring hematologists. Fibrinogen antigen and functional (Clauss method) assays, as well as reptilase time (RT) and thrombin time (TT) were obtained for each patient. Molecular modeling was used to simulate the functional impact of specific missense variants on the overall protein structure. RESULTS: Seventeen mutations, including six novel mutations, were identified in the three fibrinogen genes. There was little correlation between genotype and phenotype. Molecular modeling predicted a substantial conformational change for a novel variant, FGG p.Ala289Asp, leading to a more rigid molecule in a region critical for polymerization and alignment of the fibrin monomers. This mutation is associated with both bleeding and clotting in the two affected individuals. CONCLUSIONS: Robust genotype-phenotype correlations are difficult to establish for fibrinogen disorders. Molecular modeling might represent a valuable tool for understanding the function of certain missense fibrinogen mutations but those should be followed by functional studies. It is likely that genetic and environmental modifiers account for the incomplete penetrance and variable expressivity that characterize fibrinogen disorders.

Congenital FX Deficiency Rio Tercero: A New Heterozygous Missense Mutation (Cys241Gly) with a Potentiating Effect by a Polymorphism (c. 503-57C>T).

OBJECTIVE: The aim was to report a new family with congenital FX deficiency. PATIENTS AND METHODS: The proposita is a 41 year old female with a moderate bleeding tendency (easy bruising, menorrhagia). Parents were not consanguineous. Family history was positive for a mild bleeding tendency. RESULTS: Coagulation and genetics studies revealed that the proposita and two of her siblings were heterozygotes for a new mutation Cys241Gly in exon 6 but had different FX level (2-3% of normal in the proposita and about 50% in the two siblings. The same was true for one of her three children. The mother and the other two children of the proposita had also slightly decreased FX levels but no mutation. On the suspicion that the proposita was carrying another defect which had escaped the Sanger method, we carried out a whole exome analysis and discovered that the proposita and one of her siblings were also homozygous for a mutation of a known polymorphism (c.503-57C>T). The daughter of the proposita was instead, besides being a carrier of the missense new mutation Cys241Gly, heterozygous for the same polymorphism. The mother and two other daughters were also heterozygous for the polymorphism. There were no deletions or duplications. CONCLUSION: The polymorphism present in the family seems to be capable of potentiating the defect induced by the new mutation. This, safe for epigenetics phenomena, is the only possible explanation for the discrepancy found in the FX level between mother and daughter despite the fact that both carried the same new mutation.

Combined deficiency of factor V and factor VIII is due to mutations in either LMAN1 or MCFD2.

Mutations in LMAN1 (ERGIC-53) or MCFD2 cause combined deficiency of factor V and factor VIII (F5F8D). LMAN1 and MCFD2 form a protein complex that functions as a cargo receptor ferrying FV and FVIII from the endoplasmic reticulum to the Golgi. In this study, we analyzed 10 previously reported and 10 new F5F8D families. Mutations in the LMAN1 or MCFD2 genes accounted for 15 of these families, including 3 alleles resulting in no LMAN1 mRNA accumulation. Combined with our previous reports, we have identified LMAN1 or MCFD2 mutations as the causes of F5F8D in 71 of 76 families. Among the 5 families in which no mutations were identified, 3 were due to misdiagnosis, with the remaining 2 likely carrying LMAN1 or MCFD2 mutations that were missed by direct sequencing. Our results suggest that mutations in LMAN1 and MCFD2 may account for all cases of F5F8D. Immunoprecipitation and Western blot analysis detected a low level of LMAN1-MCFD2 complex in lymphoblasts derived from patients with missense mutations in LMAN1 (C475R) or MCFD2 (I136T), suggesting that complete loss of the complex may not be required for clinically significant reduction in FV and FVIII.