A novel mutation (Leu60Pro) in a Chinese pedigree with hereditary factor XI deficiency.

To analyse F11 gene mutations in a Chinese pedigree with hereditary factor XI (FXI) deficiency and investigate the molecular mechanism. The plasma FXI activity and FXI antigen of the proband and the family members were detected by clotting assay and ELISA, respectively. The F11 gene was amplified by PCR and sequenced directly. Online bioinformatics software were needed to analyse the mutations. The proband showed a prolonged activated partial thromboplastin time (93.3 s), whose FXI activity and FXI antigen were low to 2, 4.5%, respectively. A novel mutation c.233T>C (p.Leu60Pro) in exon 4 and a previously described mutation c.1253G>T (Gly400Val) were found in the proband. Protein Leu60 is conserved highly among homologous species. Bioinformatics software indicated that Leu60Pro mutation might affect the protein function. Other coagulation abnormalities were not found. We preliminarily considered the mutations Leu60Pro and Gly400Val were responsible for the decrease FXI level in the family. Leu60Pro mutation in the F11 gene has not been described elsewhere.

[Identification of compound heterozygous variants of F12 gene in a pedigree affected with inherited coagulation factor XII deficiency].

OBJECTIVE: To explore the molecular pathogenesis for a pedigree affected with hereditary coagulation factor XII (FXII) deficiency. METHODS: Potential variant of the F12 gene was analyzed by PCR and Sanger sequencing. Expression plasmids were constructed by site-directed mutagenesis based on the wild-type and transiently transfected into 293T cells. FXII:C and FXII:Ag of the expression products were determined in the supernatant and cell lysate. Western blotting was used to verify the identify of the protein. RESULTS: Gene sequencing revealed that the proband has carried 46TT genetype and heterozygous p.Glu502Lys variants in exon 13, and a heterozygous p.Gly542Ser variant in exon 14 of the F12 gene. Transfection experiment suggested that the FXII:C and FXII:Ag of p.Glu502Lys variant in the supernatant were 28% and 24%, compared with the wild-type (100%) and FXII:Ag of cell lysates was 39% compared to the wild-type (100%). The FXII:C and FXII:Ag of p. Gly542Ser variant in the supernatant were 32% and 17% and the FXII:Ag of cell lysates was 59%. CONCLUSION: The 46TT genetype, p.Glu502Lys and p.Gly542Ser variants of the F12 gene probably underlie the low FXII level in the proband. As shown by in vitro experiment, the p.Glu502Lys and p.Gly542Ser variants can both inhibit the synthesis and secrection of the FXII protein.

Genetic analysis of a novel missense mutation (Gly542Ser) with factor XII deficiency in a Chinese patient of consanguineous marriage.

Coagulation factor XII deficiency is a rare autosomal recessive disorder, which could be found in a consanguineous family. We studied a Chinese family in which the activated partial thromboplastin time (APTT) of the proband had clearly prolonged up to 101.7 s, associated with low FXII activity of 3% and FXII antigen < 1%. To analyze the gene mutation in this FXII-deficient patient, we performed FXII mutation screening, and analyzed the DNA sequence of the F12 gene. A ClustalX-2.1-win and four online bioinformatics software services were used to study the conservatism and effects of the mutation. A transient in vitro expression study was performed to elucidate the possible pathological mechanism. Sequence analysis revealed a homozygous c.1681 G > A point mutation in exon 14, causing a novel Gly542Ser mutation in the catalytic domain. The results of the conservatism and bioinformatics analyses both indicated that the mutation likely affects the function of the protein. Additional expression studies in COS-7 cells showed that the antigen level of mutant FXII (FXII-Gly542Ser) was lower than wild type in culture medium, whereas the corresponding level of FXII antigen in cell lysates was equivalent. These results suggest that the Gly542Ser mutation causes FXII deficiency through intracellular degradation.