Identification of a large deletion and three novel mutations in exon 13 of the factor V gene in a Spanish family with normal factor V coagulant and anticoagulant properties

Soria, José Manuel Nieto; Blangero, John; Souto, Joan Carles; Martínez-Sánchez, Elisabeth; Martínez-Marchán, Elisabeth; Coll, Immaculada; Tirado, Isabel; Cercós, A.; Almasy, Laura; Fontcuberta, Jordi

doi:10.1007/s00439-002-0746-y

Cited by 7 publications

(6 citation statements)

References 29 publications

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“…43 Our results are consistant with a naturally occurring mutation that also provided evidence for a nonfunctional role of the His1299Arg polymorphism in the phenotypic variability of APCR values. 44 In summary, these results represent the first direct evidence that APCR and FVIII levels, which are major risk factors underlying liability to thrombosis, are jointly influenced by a QTL on chromosome 18. Our results also support the conclusion that this QTL is an important modulator of an individual's susceptibility to thrombosis.…”

Section: Discussionmentioning

confidence: 61%

A new locus on chromosome 18 that influences normal variation in activated protein C resistance phenotype and factor VIII activity and its relation to thrombosis susceptibility

Soria

Almasy

Souto

et al. 2003

Blood

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Activated protein C resistance (APCR) is the most prevalent risk factor for thrombosis, accounting for 20% to 60% of familial thrombophilia. A mutation in the F5 gene, factor V Leiden (FVL), is a major determinant of pathological APCR in some populations. However, APCR predicts risk for thrombosis independently of FVL. This suggests that other genetic factors may influence risk of thrombosis through quantitative variation in APCR. To search for these unknown loci, we conducted a genome-wide linkage screen for genes affecting normal variation in APCR in the 21 Spanish families from the Genetic Analysis of Idiopathic Thrombophilia (GAIT) project. Conditional on FVL, the strongest linkage signal for APCR was found on chromosome 18 near D18S53. Bivariate linkage analyses with a genetically correlated trait, levels of clotting factor VIII, strengthened evidence for the chromosome 18 quantitative trait locus (QTL; logarithm of the odds [LOD], 4.5; P ‫؍‬ 3.08 ؋ 10 ؊5 ). However, the region on chromosome 1 that contains the F5 structural gene showed little evidence of linkage to APCR (LOD, < 1). This indicates that apart from the FVL, the F5 locus itself plays a relatively minor role in normal variation in APCR, including the HR2 IntroductionVenous and arterial thrombosis may be life-threatening events and are of great importance in public health. Very little is known about the relative importance of genetic factors in thrombosis risk in the general population. 1 Recently, as part of the GAIT (Genetic Analysis of Idiopathic Thrombophila) project, we have quantified the genetic contribution to susceptibility to thrombosis and related phenotypes in the Spanish population. 2,3 Of the quantitative risk factors studied, activated protein C resistance (APCR) had the highest heritability (0.71), and it was genetically correlated with thrombosis ( g ϭ Ϫ 0.65; P ϭ 1 ϫ 10 Ϫ6 ), 2,3 indicating that some of the genes that influence quantitative variation in this phenotype also influence susceptibility to thrombosis.APCR is the most prevalent risk factor for thrombosis, 4 accounting for 20% to 60% of familial thrombophilia. 5 A mutation in the F5 gene (factor V Leiden [FVL]) produces a coding change from Arg506 to Gln at the first cleavage site, where APC acts to inactivate FV. As a consequence, this mutation produces a protein that is intrinsically resistant to APC, causing the APCR pathological phenotype. 6 Prevalence of FVL in different European countries ranges between 2% and 6%. 7 Moreover, APCR is a genetic risk factor for thrombosis independent of FVL. 8,9 Therefore, because of its implication in thrombotic disease, there has been a growing interest in studying other genetic factors that are likely to affect thrombosis risk through quantitative variation in this important intermediate phenotype. The APCR phenotype could theoretically result from a variety of other mutations of critical sites in the F5 or F8 genes. However, no mutations of F8 have yet been identified in patients with the APCR phenotype, 10,11 whereas 2 point ...

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Section: Discussionmentioning

confidence: 61%

A new locus on chromosome 18 that influences normal variation in activated protein C resistance phenotype and factor VIII activity and its relation to thrombosis susceptibility

Soria

Almasy

Souto

et al. 2003

Blood

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“…This is due to the fact that amino acid changes in the B domain are unlikely to cause FV deficiency, because the B domain is subject to looser structural constraints than the A and C domains. In fact, even a naturally occurring 108‐bp deletion causing the in‐frame deletion of 36 amino acids within the B domain did not affect FV expression or activity (Soria et al , 2002).…”

Section: Congenital Fv Deficiency (Owren Parahaemophilia)mentioning

confidence: 99%

Advances in understanding the bleeding diathesis in factor V deficiency

et al. 2009

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SummaryCoagulation factor V (FV), present in plasma and platelets, is an indispensable clotting factor, as demonstrated by the uniform lethality of FV knock-out mice. Surprisingly, however, severe FV deficiency is rarely fatal in humans. In fact, although several cases of life-threatening intracranial haemorrhage have been reported in FV-deficient newborns, many patients with undetectable FV levels experience only mild to moderate bleeding and do not require routine prophylaxis. While the reasons for this variable phenotypic expression are largely unknown, several observations from different laboratories indicate platelets as crucial players in FV deficiency. Moreover, we have recently shown that plasma levels of tissue factor pathway inhibitor are considerably reduced in FV-deficient plasma, which results in enhanced thrombin generation especially at very low FV levels (<2%). The present review discusses and integrates these findings in the context of the biology of FV and the clinical features of FV deficiency.

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“…Other linkage studies restricted to candidate gene regions include those on a large Vermont pedigree [48,49] and an early linkage study of quantitative variation in histidine‐rich glycoprotein on a large Dutch kindred [50]. Family‐based association inferences related to thrombosis have been performed in nuclear families [35,37] and extended pedigrees [42–44,51–53].…”

Section: The Primacy Of Family Studies In Complex Disease Geneticsmentioning

confidence: 99%

Novel family-based approaches to genetic risk in thrombosis

Blangero

Williams

Almasy

2003

Journal of Thrombosis and Haemostasis

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Summary. The genetic basis of thrombosis is complex, involving multiple genes and environmental factors. The field of common complex disease genetics has progressed enormously over the past 10 years with the development of powerful new molecular and analytical strategies that enable localization and identification of the causative genetic variants. During the course of these advances, a major paradigmatic change has been taking place that focuses on the genetic analysis of measurable quantitative traits that are correlated with disease risk vs. the previous emphasis on the analysis of the much less informative dichotomous disease trait. Because of their closer proximity to direct gene action, disease‐related quantitative phenotypes represent our best chance to identify the underlying quantitative trait loci (QTLs) that influence disease susceptibility. This approach works best when data can be collected on extended families. Unfortunately, family‐based designs are still relatively rare in thrombosis/hemostasis studies. In this review, we detail the reasons why the field would benefit from a more vigorous pursuit of modern family‐based genetic studies.

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Identification of a large deletion and three novel mutations in exon 13 of the factor V gene in a Spanish family with normal factor V coagulant and anticoagulant properties

Cited by 7 publications

References 29 publications

A new locus on chromosome 18 that influences normal variation in activated protein C resistance phenotype and factor VIII activity and its relation to thrombosis susceptibility

A new locus on chromosome 18 that influences normal variation in activated protein C resistance phenotype and factor VIII activity and its relation to thrombosis susceptibility

Advances in understanding the bleeding diathesis in factor V deficiency

Novel family-based approaches to genetic risk in thrombosis

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