Identification of a novel large deletion in a patient with severe factor V deficiency using an in-house F5 MLPA assay.

Factor V (FV) deficiency is a rare autosomal recessive bleeding disorder caused by mutations in the F5 gene. FV-deficient patients in whom no mutation or only one mutation is found may harbour large gene rearrangements, which are not detected by conventional mutation screening strategies. The aim of this study was to develop and validate a multiplex ligation-dependent probe amplification (MLPA) assay for the detection of large deletions and duplications in the F5 gene. Twenty-two MLPA probes targeting 19 of the 25 exons and the upstream and downstream regions of the F5 gene were designed and tested in 10 normal controls, a patient with a known heterozygous deletion of F5 exons 1-7 (positive control) and 14 genetically unexplained FV-deficient patients. MLPA results were confirmed by digital PCR on a QuantStudio(™) 3D Digital PCR System. The F5-specific probes yielded a reproducible peak profile in normal controls, correctly detected the known deletion in the positive control and suggested the presence of a novel deletion of exons 9-10 in a patient with undetectable FV levels and only one identified mutation. Follow-up by chip-based digital PCR, long-range PCR and direct sequencing confirmed that this patient carried a heterozygous F5 deletion of 1823 bp extending from intron 8 to intron 10. Bioinformatics sequence analysis pinpointed repetitive elements that might have originated the deletion. In conclusion, we have developed and validated an MLPA assay for the detection of gross F5 gene rearrangements. This assay may represent a valuable tool for the molecular diagnosis of FV deficiency.

Genetic background and risk of postpartum haemorrhage: results from an Italian cohort of 3219 women.

Postpartum haemorrhage (PPH) is a leading cause of maternal mortality, particularly in the developing countries, and of severe maternal morbidity worldwide. To investigate the impact of genetic influences on postpartum haemorrhage, in association with maternal and intrapartum risk factors, using a candidate gene approach. All women (n = 6694) who underwent a vaginal delivery at the Obstetric Unit of a large University hospital in Milan (Italy) between July 2007 and September 2009 were enrolled. The first consecutive 3219 women entered the genetic study. Postpartum haemorrhage was defined as ≥500 mL blood loss. Eight functional polymorphisms in seven candidate genes were chosen because of their potential role in predisposing to or protecting from haemorrhagic conditions: tissue factor (F3), factor V (F5), tissue factor pathway inhibitor (TFPI), platelet glycoprotein Ia/IIa (ITGA2), prothrombin (F2), platelet glycoproteins Ibα (GP1BA) and angiotensin-converting enzyme (ACE). After correction for the already known PPH risk factors, only the promoter polymorphism of the tissue factor gene (F3 -603A>G) showed a significant association with PPH, the G allele exerting a protective effect (P = 0.00053; OR = 0.79, 95% CI = 0.69-0.90). The protective effect against PPH of the TF -603A>G polymorphism is biologically plausible since the G allele is associated with an increased protein expression and Tissue Factor is strongly represented in the placenta at term, particularly in decidual cells of maternal origin.

Functional characterization of a novel missense mutation identified in a Turkish patient affected by severe coagulation factor V deficiency.

Factor V (FV) deficiency is a rare coagulation disorder, characterized by a bleeding phenotype varying from mild to severe. To date, 115 mutations have been described along the gene encoding for FV (F5) but only few of them have been functionally characterized. Aim of this study was the identification and the molecular characterization of genetic defects underlying severe FV deficiency in a 7-month-old Turkish patient. Mutation detection was performed by sequencing the whole F5 coding region, exon-intron boundaries and about 300 bp of the promoter region. Functional analysis of the identified missense mutation was conducted by transient expression of wild-type and mutant FV recombinant molecules in COS-1 cells. Two novel mutations: a missense (Pro132Arg) and a 1-bp deletion (Ile1890TyrfsX19) were identified in the F5 gene. While the frameshift mutation is responsible for the introduction of a premature stop codon, likely triggering F5 mRNA to nonsense-mediated mRNA degradation, the demonstration of the pathogenic role of the Pro132Arg mutation required an experimental validation. Expression experiments showed that the missense mutation causes a significant reduction in FV secretion and in the specific activity of the residual secreted molecule (77% and 78% decrease, respectively). This paper reports the identification of two novel mutations responsible for FV deficiency, thus widening the mutational spectrum of the F5 gene. The Pro132Arg mutation adds to the only other two functionally characterized missense defects in the FV A1 domain.