Inherited antithrombin (AT) deficiency is one of the most clinically significant forms of congenital thrombophilia and follows an autosomal dominant mode of inheritance. We analyzed SERPINC1 in a patient who developed deep-vein thrombosis and low AT activity during pregnancy, and identified a novel missense mutation c.259A>G (p.Asn87Asp; N87D). Surprisingly, analysis of the parents' DNA showed that they did not possess this mutant, and thus, it may have been due to a de novo mutation. We also expressed this mutant AT protein in COS-1 cells and compared its intracellular localization and intracellular and extracellular antigen levels with that of wild-type AT. The expression experiment did not reveal a significant difference in the antigen levels of the mutant and wild-type AT in the cell lysate, but the mutant AT antigen level was markedly lower than that of its wild-type counterpart in the COS-1 cell supernatant. Immunofluorescence did not indicate any difference between the mutant and wild-type AT in terms of cytoplasmic localization of fluorescence signals. Our findings suggest that the patient's AT deficiency may have been caused by impaired extracellular secretion of mutant AT protein p.Asn87Asp.
Congenital factor X (FX) deficiency is a rare bleeding disorder that is inherited as an autosomal recessive trait. In this study, a genetic analysis of the FX gene was performed in five families with this disorder. Four heterozygous mutations [p.Gly154Arg, p.Val236Met, p.Gly263Val and p.Arg387Cys] and one pair of compound heterozygous FX gene mutations consisting of p.Gly406Ser and p.Val424Phe were identified. Mutant FX proteins containing the identified amino acid substitutions were also expressed in cultured cells. These proteins were analysed by enzyme-linked immunosorbent assay and pulse-chase experiments. The results demonstrated normal intracellular synthesis and extracellular secretion of mutant FX proteins carrying the p.Val236Met, p.Arg387Cys and p.Gly406Ser amino acid substitutions. However, the results also showed that the p.Gly154Arg, p.Gly263Val and p.Val424Phe proteins were secreted less efficiently than the wild-type protein, although they were synthesized normally in the cell. Collectively, these observations suggest that the amino acid substitutions p.Gly154Arg, p.Gly263Val and p.Val424Phe induce protein misfolding, leading to the intracellular degradation of many FX proteins containing any of these mutations, and ultimately to the development of FX deficiency. On the other hand, for the p.Val236Met, p.Arg387Cys and p.Gly406Ser mutant proteins, we hypothesize that secreted FX proteins have impaired coagulant activities due to functional defects caused by these amino acid substitutions.
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