Evaluation of factor V mRNA to define the residual factor V expression levels in severe factor V deficiency

We evaluated FV mRNA in severe factor V deficiency caused by the -12T/A IVS18 mutation, activating a cryptic splice site and leading to premature translation termination. Quantitative evaluation of factor V cDNA from homozygous and heterozygous subjects, and correction for nonsense mediated decay, suggested the presence of 0.1% of normal factor V mRNA.     

Homozygous factor V splice site mutation associated with severe factor V deficiency

We investigated a family whose proband has a severe bleeding disorder and factor V antigenic and functional levels of 8% and less than 1% of control values, respectively. Molecular analysis of the factor V gene revealed a novel homozygous mutation in the last nucleotide of exon 10. 1701G>T causes activation of a cryptic exonic splice site in exon 10, which encodes part of the factor V heavy chain (A2 domain). This leads to the deletion of 35 nucleotides and results in a frameshift with a premature stop codon at amino acid position 498. The G1701 and corresponding Gln509 are conserved in murine, bovine, and porcine factor V and in human factor VIII. Few factor V deficiency mutations have been identified as yet. Several are present in the heterozygous form in combination with factor V Leiden (Arg506Gln). This is the first reported homozygous splice site mutation in a patient with factor V deficiency.     

Arg2074Cys missense mutation in the C2 domain of factor V causing moderately severe factor V deficiency: molecular characterization by expression of the recombinant protein

Factor V (FV) deficiency is a rare bleeding disorder whose genetic basis has been described in a relatively small number of cases. Among a total of 12 genetic defects reported in severely or moderately severe deficient patients, 3 were missense mutations and in no case was the mechanism underlying the deficiency explored at the molecular level. In this study, a homozygous missense mutation at cDNA position 6394 in exon 23 of the FV gene was identified in a 22-year-old Italian patient. This mutation causes the replacement of arginine 2074 with a cysteine residue (Arg2074Cys) in the C2 domain of the protein. The effect of the Arg2074Cys mutation on FV secretion, stability, and activity was investigated. Site-directed mutagenesis of FV cDNA was used to introduce the identified mutation, and wild-type as well as mutant FV proteins were expressed by transient transfection in COS-1 cells. An enzyme immunoassay detected low FV antigen levels both in the conditioned media of cells expressing the mutant protein and in cell lysates. Metabolic labeling and pulse-chase experiments confirmed that the mutation caused an impaired secretion of FV associated with rapid intracellular degradation. In addition, evaluation of wild-type and mutant coagulant activity demonstrated that the FV molecules carrying the Arg2074Cys mutation have reduced activity. These findings, beside confirming the structural and functional importance of the arginine 2074 residue, demonstrate that its substitution with a cysteine impairs both FV secretion and activity.     

Severe coagulation factor V deficiency caused by 2 novel frameshift mutations: 2952delT in exon 13 and 5493insG in exon 16 of factor 5 gene.

A male infant with severe bleeding tendency had undetectable factor V activity. Sequence analysis of the proband's DNA revealed one base deletion in exon 13 (2952delT) and one base insertion in exon 16 (5493insG) in heterozygous form. Both mutations introduced a frameshift and a premature stop at codons 930 and 1776, respectively. The proband's father and mother were heterozygous for 2952delT and for 5493insG, respectively. Both mutations would result in the synthesis of truncated proteins lacking complete light chain or its C-terminal part. In the patient's plasma, no factor V light chain was detected by enzyme-linked immunosorbent assay. The N-terminal portion of factor V containing the heavy chain, and the connecting B domain was severely reduced but detectable (1.7%). A small amount of truncated factor V-specific protein with a molecular weight ratio of 236 kd could be immunoprecipitated from the plasma and detected by Western blotting. This protein, factor V(Debrecen), corresponds to the translated product of exon 16 mutant allele.     

Severe coagulation factor V deficiency caused by a 4 bp deletion in the factor V gene

Factor V (FV) deficiency (parahaemophilia) is an autosomal recessive bleeding disorder with an incidence of 1:10⁶. We have studied a young girl with very mild bleeding symptoms and undetectable levels of plasma factor V antigen and activity (<0.3% and <1.6% of normal, respectively). Both parents showed plasma levels of factor V activity of about 50% of normal. Sequence analysis of the 5'- and 3'-untranslated, coding and adjacent regions of the factor V gene revealed the presence of a 4 bp deletion in exon 13. Subsequent screening of members of the family for the mutation showed that both parents were heterozygous for the mutation, that one healthy sister carried only normal alleles, and that the patient was homozygous for the mutated allele. The mutation introduced a frameshift and a novel premature stop codon in codon 1303, and would predict the synthesis of a truncated factor V molecule that lacks part of the B domain and the complete light chain. However, no factor V heavy chain could be detected in the plasma of the patient. Furthermore, factor V activity could not be detected in the patients' platelets. This is the first reported mutation in the factor V gene that predicts a type I quantitative factor V deficiency. Surprisingly, the patient, who is homozygous for the mutation, so far has only a very mild bleeding tendency.     

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

Summary. 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.     

Asp361Val Mutant of alkaline phosphatase found in patients with dominantly inherited hypophosphatasia inhibits the activity of the wild-type enzyme

Hypophosphatasia is characterized by the hypomineralization of bone associated with the mutation of the tissue-nonspecific alkaline phosphatase (TNSALP) gene. Although the disease is usually autosomal recessive, an autosomal dominant form is also recognized. Approximately 50 mutations have been found in the TNSALP gene in patients with hypophosphatasia. However, the mutations identified to date do not seem to account for the dominantly inherited form of the disease. We have examined a German family in which the father and all 4 children were affected with hypophosphatasia, whereas the mother was healthy. The affected members of this family showed premature loss of deciduous teeth at or shortly before 2 yr of age and low levels of serum ALP with elevated levels of urinary phosphoethanolamine. DNA analysis by direct sequencing revealed a heterozygous missense mutation that caused the conversion of amino acid Asp to Val at position 361 (D361V) in the patients. Another substitution was detected in exon 12 (Val to Ala conversion at codon 505: V505A) in 1 allele of the mother and 3 children, indicating no association of the substitution with the disease. Reconstruction experiments demonstrated that the D361V mutant protein lost its enzymatic activity and that it inhibited the function of wild-type enzyme when coexpressed in COS-7 cells. On the other hand, the V505A mutant exhibited enzymatic activities equal to those of the wild-type ALP. It is likely that the mutant D361V protein forms dimers with the wild-type protein, and the protein-protein interaction contributes to the dominant effect of the mutant D361V. The mutation that causes D361V is the first one proven to be associated with the dominant form of hypophosphatasia.     

Phenotypic homozygous activated protein C resistance associated with compound heterozygosity for Arg506Gln (factor V Leiden) and His1299Arg substitutions in factor V

Two patients from two unrelated families with a history of thrombosis showed severe plasma activated protein C (APC) resistance. However, genotypic analysis demonstrated that the patients were heterozygous for factor V (FV) Leiden mutation. Coagulation studies revealed that FV clotting activity and antigen were similarly reduced at about 50% of normal in the patients. One brother of propositus A also showed the same abnormalities. Genetic analysis showed that, in addition to FV Leiden mutation in exon 10 of the FV gene (G1691A), these patients had a transition in exon 13 of the FV gene (A4070G; R2 allele) predicting His1299Arg substitution in the mature FV. Study by RT-PCR of platelet FV mRNA indicated that the mRNA produced by the FV gene, marked by the R2 allele, was reduced in amount in both pseudohomozygous patients of family A. The R2 allele has previously been demonstrated to be significantly associated with plasma FV deficiency in the Italian population. The presence of FV deficiency did not protect the propositi from thrombosis. These data confirm that genotypic analysis is mandatory in patients with phenotypic severe APC resistance before these patients are definitely classified as homozygotes for FV Leiden and that further genotypic analysis is advisable.     

Mild bleeding diathesis in a boy with combined severe haemophilia B (C10400→T) and heterozygous factor V Leiden

Haemophilia B patients with factor IX (FIX) activity < 1% are usually characterized by severe bleeding episodes early in life. We report a case of sporadic severe haemophilia B, clinically characterized by mild bleeding diathesis. The presence of anamnestic thrombophlebitis in the patient's mother prompted us to investigate a possible associated hypercoagulable condition. Resistance to activated protein C due to factor V R506Q mutation was present in the mother and in the propositus, in the homozygous and heterozygous form, respectively. Molecular analysis of the FIX gene led to the identification of a nonsense mutation resulting in a stop codon at position 50, previously described and usually responsible for a severe pattern of haemophilia B. The implications of this unusual association are discussed.     

Hyperhomocysteinaemia and factor V Leiden mutation are associated with Budd-Chiari syndrome

OBJECTIVES: Budd-Chiari syndrome (BCS) is characterized by hepatic venous outflow obstruction and may be caused by various prothrombotic disorders. We aimed to study the role of hyperhomocysteinaemia, factor V Leiden mutation and G20210A prothrombin gene mutation in the pathogenesis of the syndrome. METHODS: Thirty-two patients (16 male, 16 female, aged 19-45 years) with angiographically verified BCS and 33 age-matched and sex-matched voluntary healthy controls (15 male, 18 female, aged 19-45 years) were included into the study. Factor V Leiden and prothrombin gene mutations were determined in extracted DNA from peripheric mononuclear cells, using a light cycler amplification system. Plasma homocysteine levels were measured by fluorescence polarization immunoassay. RESULTS: The homozygote factor V Leiden mutation was diagnosed in four BCS patients and the heterozygote mutation was diagnosed in five. The frequency of the mutant allele was 20.3% in BCS patients and 7.6% in the controls (P < 0.05). There was no significant difference in prothrombin gene mutation frequency between the two groups. Serum homocysteine levels were significantly higher in the BCS group than in the controls (16.4 +/- 8.8 vs 11.0 +/- 2.7 micromol/l; P < 0.01). BCS patients with the mutant factor V Leiden allele have significantly higher levels of serum homocysteine (22.1 +/- 13.3 vs 14.4 +/- 5.9 mumol/l; P < 0.05). CONCLUSIONS: Hyperhomocysteinaemia, especially when associated with the factor V Leiden mutation, is an important risk factor for the development of BCS.     

Molecular basis of quantitative factor V deficiency associated with factor V R2 haplotype

To investigate the molecular mechanisms of the quantitative factor V (FV) deficiency associated with the FV R2 haplotype, 4 missense mutations, Met385Thr, His1299Arg, Met1736Val, and Asp2194Gly, identified in the R2 haplotype allele, were analyzed by in vitro expression studies. The FV variant carrying all 4 mutations showed a markedly lower steady-state expression level than wild-type FV because of low synthesis rate and impaired secretion of the mutant protein. The Asp2194Gly mutation was found to play a key role in the impaired secretion of the mutant FV by interfering with its transport from the endoplasmic reticulum to the Golgi complex. The deleterious effect of the Asp2194Gly mutation was shown to be dominant among the 4 mutations. The Met385Thr mutation and His1299Arg mutation had no effect on steady-state expression levels, but the secretion rates of the mutant proteins were moderately decreased by these mutations. The His1299Arg mutation partially impaired glycosylation in the C-terminal part of the B-domain of the mutant FV, which was supposed to affect the secretion rate, but not the steady-state expression level. It was also suggested that the Met385Thr mutation partially impairs posttranslational modification of the mutant FV without affecting the steady-state expression level. No deleterious effect of the Met1736Val mutation was observed in terms of expression and intracellular processing. Our in vitro data strongly suggest that the naturally existing R2 haplotype mutant FV, which carries all 4 mutations, has the potential to result in quantitative FV deficiency in vivo owing to impaired expression of the mutant protein when the Asp2194Gly mutation is present.     

Gene analysis and prenatal diagnosis for two families of congenital factor V deficiency

Summary. We studied two families in which the probands had severe bleeding tendency and showed low plasma levels of coagulation factor V (FV) antigen and activity. Sequence analysis of the FV gene on proband 1 demonstrated a novel G16088C homozygous missense mutation in exon 3 resulting in an Asp 68 to His substitution and on proband 2, a C69969T homozygous missense mutation in exon 23 leading to Gly2079Val. The parents of both families were each heterozygous for the corresponding FV gene defect. During their second pregnancy, the two families requested prenatal diagnosis. Chorionic villi were analysed at 12 weeks of gestation and cord blood samples were tested at 22 weeks. Microsatellite analysis performed in family 1 showed that the foetus sample was not contaminated by maternal tissue. The foetus 1 was found to be heterozygous for the familiar G16088C mutation with lower FV activity in the cord blood; the foetus 2 was a normal one. The diagnosis was confirmed after the birth. This is the first report of prenatal diagnosis for FV deficiency.     

Evidence for a single origin of factor V Leiden

Factor V Leiden is the most common hereditary blood clotting disorder so far identified, with an allele frequency of 4%. The low prevalence of the mutation outside of Europe suggests it occurred as a single event in the European founding population. In this study four polymorphisms have been identified defining different haplotypes in the exon 13 region of the factor V gene. One of these polymorphisms predicts a novel amino acid change, threonine to serine, in the B-domain of factor V. Statistical evidence for a single origin of factor V Leiden is provided through the association of the mutation with a single exon 13 haplotype.     

A novel ELISA-based primer extension assay for the detection of the factor V Leiden mutation

We describe an enzyme-linked immunosorbent assay (ELISA) based primer extension method for the detection of the factor V Leiden (FVL) mutation. The wild-type nucleotide at position 1691 or the mutant nucleotide at the complementary position on the antisense strand were detected by the incorporation of biotinylated complementary bases onto fluorescein isothiocyanate (FITC) labelled mini-sequence primers with specificity for the sense and antisense gene segments downstream from the bases adjacent to position 1691. The reactions took place in pairs of tubes containing the complementary bases to either the wild-type or mutant nucleotide respectively. Primer extension products from each reaction tube pair which have incorporated biotinylated bases were then captured in streptavidin-coated microtitre plate wells and detected colourimetrically using an ELISA procedure. 200 patient samples were tested to validate the assay and there was complete genotypic agreement between the ELISA method and restriction site analysis using Mnl I (137 wild type, 55 FVL heterozygotes and eight homozygotes). The method utilizes non-radioactive reagents and does not require electrophoretic techniques. It is therefore a safe, simple and rapid assay which lends itself to automation.     

Evidence for a single origin of factor V Leiden

Factor V Leiden is the most common hereditary blood clotting disorder so far identified, with an allele frequency of 4%. The low prevalence of the mutation outside of Europe suggests it occurred as a single event in the European founding population. In this study four polymorphisms have been identified defining different haplotypes in the exon 13 region of the factor V gene. One of these polymorphisms predicts a novel amino acid change, threonine to serine, in the B-domain of factor V. Statistical evidence for a single origin of factor V Leiden is provided through the association of the mutation with a single exon 13 haplotype.     

Identification of three F5 gene mutations associated with inherited coagulation factor V deficiency in two Chinese pedigrees

To investigate the molecular defects in two Chinese pedigrees with inherited factor V (FV) deficiency. A 37-year-old male (proband 1) and an 18-month-old boy (proband 2) were diagnosed as inherited coagulation FV deficiency by severely reduced plasma levels of FV activity and antigen. All 25 exons and their flanking sequence of F5 gene were amplified by polymerase chain reaction (PCR) for both probands and the PCR products were directly sequenced. Total RNA was extracted from the peripheral lymphocytes of proband 1 for detecting the changes at mRNA level. The homozygous deletion IVS8 -2A>G was identified in the F5 gene of proband 1 and complementary DNA (cDNA) analysis revealed the abolishment of the canonical splicing site by the mutation and the activation of the cryptic acceptor site 24 bp upstream instead. The insertion introduced eight additional amino acids (AA) into the FV protein. Two heterozygous mutations of F5 gene were discovered in proband 2. The 2238-9del AG in exon 13 introduced a premature termination code at 689 AA and the substitution of G6410 by T in exon 23 lead to the missense mutation Gly2079Val. Three F5 gene mutations, IVS8 -2A>G, 2238-9del AG and G6410T, have been identified in two Chinese pedigree with congenital FV deficiency, respectively.