ABO blood group but not haemostasis genetic polymorphisms significantly influence thrombotic risk: a study of 180 homozygotes for the Factor V Leiden mutation

Limited data exist on the impact of additional genetic risk factors on the clinical manifestations of factor (F) V Leiden homozygotes. A retrospective multi-centre cohort study was performed to assess the role of the FII G20210A gene mutation, the protein C (PC) promoter CG haplotype, the combination of two PC polymorphisms (A-1641G, C-1654T), the FXIII Val34Leu polymorphism, two thrombin-activatable fibrinolysis inhibitor polymorphisms (Thr325Ile, Ala147Thr), two plasminogen activator inhibitor-1 polymorphisms (-675 4G/5G, A-844G), the methylene-tetrahydrofolate reductase (MTHFR) C677T polymorphism and the ABO blood group on the thrombotic phenotype in FV Leiden homozygotes. 127 subjects with venous thrombosis and 53 asymptomatic subjects were analysed. The T allele of MTHFR C677T was more frequent in symptomatic subjects than in asymptomatic ones (68% vs. 45%, P  = 0·02; odds ratio (OR) 2·8, 95% CI 1·3–5·8, after adjustment for potential confounders). For the other polymorphisms, no difference was observed between symptomatic and asymptomatic subjects. The non-O blood group was more frequent among symptomatic carriers (84% vs. 57%, P  = 0·0002; OR 4·1, 95% CI 1·7–9·7). In conclusion, except for the ABO blood group, none of the polymorphisms studied contribute strongly to the thrombotic risk in FV Leiden homozygotes.     

Activated protein C resistance as an additional risk factor for thrombosis in protein C-deficient families

Heterozygous protein C deficiency is associated with an increased risk for thrombosis. This association is restricted to a minority of protein C-deficient families, which have been defined as clinically dominant protein C-deficient. In contrast, in the clinically recessive protein C- deficient families, only the homozygous family members are (severely) affected. One possible explanation for this difference in thrombotic risk between families may be the presence of a second hereditary risk factor. A good candidate for this second risk factor is the recently identified resistance to activated protein C (APC). APC resistance, which is associated with a mutation in the FV gene (FV Leiden), is a common and strong risk factor for thrombosis. We show here that the prevalence of the FV Leiden mutation is high among symptomatic protein C-deficient probands (19%). In 6 clinically dominant protein C- deficient families, the segregation of the FV Leiden mutation and the protein C gene mutation was studied. A thrombotic episode had been experienced by 73% of the family members having both the protein C gene mutation and the FV Leiden mutation. In contrast, respectively, 31% and 13% of the family members having either the protein C gene mutation or the FV Leiden mutation had experienced a thrombotic episode. Moreover, the result of a two locus linkage analysis support the assumption that the FV gene and the protein C gene are the two trait loci responsible for the thrombophilia. These results indicate that carriers of both gene defects have an increased risk for thrombosis compared with related carriers of the single defect.     

A comparison between two activated protein C resistance methods as routine diagnostic tests for factor V Leiden mutation

The most common commercially available test measuring activated protein C (APC) resistance relies on the the anticoagulant response to added APC in an activated partial thromboplastin time (APTT) based method. Another method is a Russell Viper venom time (RVVT) based system. To improve the specificity for factor V Leiden of the APTT based method, pre-dilution of test plasma in FV-deficient plasma has recently been recommended. In this study we tested the relative suitabilities of the APTT-based system, the RVVT-based system and their corresponding assays modified by pre-dilution in FV-deficient plasma, for screening asymptomatic subjects, a group of thrombophilic patients (in particular those with low APC ratios), patients on oral anticoagulants, and patients with lupus anticoagulant (LAC). We found the RVVT-based assay to be superior to the APTT-based method in the separation of normals from those with FV Leiden mutation both in asymptomatic subjects and in the thrombophilic patient group. Both modified assays demonstrated a sensitivity and specificity of 100% for FV Leiden, as verified by genotyping in asymptomatic subjects, thrombophilic patients and patients on oral anticoagulants, with the modified RVVT-based assay giving better separation between normals and FV Leiden. Inhibition of phospholipid-dependent coagulation by LAC antibodies rendered the APTT-based system less suitable than the phospholipid-rich RVVT-based one, and as nine of the 20 LAC-positive patients were on warfarin, we showed only the modified RVVT assay to be a reliable predictor of factor V Leiden in this patient group.     

Pseudohomozygosity for activated protein C resistance is a risk factor for venous thrombosis

Pseudohomozygosity for activated protein C resistance (APC-r) is a rare condition due to the association of heterozygous FV Leiden mutation and partial type I FV deficiency. To assess the risk of venous thromboembolism in these subjects, seven families including 11 pseudohomozygotes and 45 relatives were examined. Among the relatives, 16 were heterozygous FV Leiden carriers, nine showed partial FV deficiency and 20 no abnormalities. Deep vein thrombosis occurred in 4/11 (36.3%) pseudohomozygous patients versus 6/16 (37. 4%) FV Leiden carriers and 1/20 (5%) normal relatives. Pseudohomozygotes and FV Leiden carriers had a significantly increased risk of venous thrombosis in comparison to normal relatives (RR 8.8 and 5.7, respectively). There was no difference between the thrombotic risk of pseudohomozygous subjects and of FV Leiden carriers (RR 1.6, 95% CI 0.43-5.7). Furthermore, there was no difference in thrombosis-free survival between pseudohomozygotes and 45 consecutive FV Leiden heterozygous outpatients, suggesting that a referral bias may explain the apparent younger age of thrombosis in the pseudohomozygotes in comparison to relatives with FV Leiden heterozygosity (27 years v 54 years; P = 0.01). Pseudohomozygosity for APC resistance carries a significantly higher risk for venous thromboembolism in comparison to normal subjects, but probably not in comparison to heterozygous FV Leiden carriers.     

Survival advantage associated with heterozygous factor V Leiden mutation in patients with severe sepsis and in mouse endotoxemia

Sepsis is associated with systemic inflammation, coagulopathy, and disrupted protein C (PC) pathway function. The effect of prothrombotic polymorphism, factor V Leiden (Arg506Gln; FV Leiden), was examined in a large clinical trial (PROWESS) of severe sepsis and a mouse endotoxemia model. In PROWESS, 4.1% (n = 65) of patients were heterozygous FV Leiden (VL+/-) carriers. The 28-day mortality was lower in VL+/- (13.9%) than in non-FV Leiden (VL-/-; 27.9%) patients (P =.013). The mortality benefit of recombinant human activated PC (rhAPC) treatment was similar in VL+/- (placebo, 15.6%; rhAPC,12.1%) and VL-/- patients (placebo, 31.0%; rhAPC, 24.7%; interaction P =.981). VL+/- status did not appear to influence baseline biomarkers of coagulopathy and inflammation or disease severity, with the exception that vasopressor usage was less in VL+/- patients (46.2% versus 63.0%; P =.009). In a median lethal dose (40 mg/kg) endotoxin mouse model, VL+/- mice had lower mortality than wild-type mice (19% versus 57%; P =.008), whereas the mortality of homozygous (VL+/+) mice was almost identical to that of wild-type mice (65% versus 57%; P =.76). The findings suggest that FV Leiden constitutes a rare example of a balanced gene polymorphism that maintains the FV Leiden mutation in the general gene pool due to a survival advantage of VL+/- in severe sepsis.     

The A20210 allele in the prothrombin gene enhances the risk of venous thrombosis in carriers of inherited protein S deficiency.

Sixteen families with inherited protein S deficiency and venous thromboembolism (VT) were screened for the presence of factor V (FV) Leiden mutation and for the G20210A allele in the prothrombin gene. While FV Leiden was not detected in any of the families, protein S deficiency and prothrombin mutation were present in five families. To assess the risk of VT in carriers of the combined defects, a total of 92 members of the 16 families, including propositi, were examined. Thirty subjects were normal, 40 showed protein S deficiency, 10 the prothrombin mutation and 12 showed both abnormalities. When index cases were excluded, thrombosis history were present in 40.7% of protein S-deficient patients, 75% of patients with combined abnormality, one out of the 10 (10%) with prothrombin mutation and only one (3.3%) of the normal subjects. Relatives with combined defects showed the highest incidence rate of VT in comparison with normal relatives (rate ratio = 32.4), those with protein S deficiency an intermediate degree (rate ratio = 15.7), and G20210A relatives the lowest (rate ratio = 3.4). Relatives with combined defects had an increased risk of VT in comparison with relatives with protein S deficiency (incidence rate ratio 2.1; 95% confidence interval, 0.7-5.41; P = 0.1). In conclusion, the presence of the prothrombin mutation seems to increase the risk of VT carriers of protein S deficiency, although additional families are required to fully estimate the magnitude of risk.     

The predictability of factor V Leiden (FV:Q(506)) gene mutation via clotting-based diagnosis of activated protein C resistance.

After the discovery of activated protein C resistance (APCR) due to factor V Leiden mutation and the causal relationship of the phenomenon with clinical thromboembolism, a wide variety of functional clotting-based assays were developed for testing of APCR in relation to the specific DNA-based analysis of FV:Q(506) Leiden. The aim of this study is to assess a clotting-based APCR assay using procoagulant crotalidae snake venom with respect to the sensitivity, specificity, and predictability for the presence of the factor V Leiden mutation. APCR testing and factor V DNA analyses have been performed concurrently on 319 patient specimens. APCR values of the patients with homozygous factor V Leiden mutation (70.4+/-13.5 s) were significantly lower (p<0.001) in comparison to the subjects with the heterozygous mutation (87.6+/-13.4 s). The assay is highly sensitive (98.7%) and specific (91.9%) for the screening of factor V Leiden mutation. The sensitivity and specificity of the APCR testing reached to 100% below the cut-off value of 120 s among the patients with homozygous factor V Leiden mutation. Therefore, this method could help the desired effective optimal screening strategy for the laboratory search of hereditary thrombophilia focusing on the diagnosis of APCR due to FV:Q(506).     

Additional genetic risk factors for venous thromboembolismin carriers of the factor V Leiden mutation

Only a minority of subjects with factor V (FV) Leiden mutation develop venous thromboembolism (VTE), suggesting that additional genetic risk factors may be present in symptomatic carriers. We screened 157 unrelated carriers of the FV Leiden mutation with a first episode of VTE and 291 unrelated asymptomatic FV carriers for the presence of two frequent mutations, i.e. G20210A of the prothrombin gene and C677T of the methylenetetrahydrofolate reductase gene. Carriers with other inherited or acquired thrombophilia-associated abnormalities were excluded from analysis. Heterozygotes for the G20210A mutation were more prevalent among symptomatic carriers than in asymptomatic carriers (10.8% v 2.7%, P  < 0.0001); homozygotes for the C677T mutation were also more prevalent in symptomatic carriers (21.6% v 14.4%, P  = 0.05). Factor V Leiden carriers who had had a VTE episode during oral contraceptive intake were more frequently carriers of the G20210A mutation (14.3%, P  = 0.03). These results further support the idea that VTE in carriers of FV Leiden results from interaction with additional genetic or circumstantial risk factors, and that an accurate search for such factors is required to identify carriers at risk.     

Factor V Leiden: the venous thrombotic risk in thrombophilic families

Factor V Leiden (FVL) leads to a sevenfold increased risk of venous thrombosis and is present in 50% of individuals from families referred because of unexplained familial thrombophilia. We assessed the association of FVL with venous thromboembolism (VTE) in 12 thrombophilic families of symptomatic probands with FVL in a retrospective follow-up study. We screened 182 first- and second-degree relatives of the 12 unrelated propositi for the FVL mutation and the occurrence of VTE. The incidence rate of VTE in carriers of FVL (0.56%/year) was about six times the incidence for the Dutch population (0.1%/year). The incidence rate in non-carriers also appeared to be higher (0.15% per year). At the age of 50 years, the probability of not being affected by VTE was reduced to 75% for carriers and to 93% for non-carriers (P = 0.009). Identification of carriers of FV Leiden may be worthwhile in young symptomatic individuals and their relatives with a strong positive family history of venous thromboembolism or a history of recurrent venous thrombosis who may be at risk (e.g. pregnancy, use of oral contraceptives). After adjustment for prothrombin G20210A (present in two families), even higher thrombotic incidence rates were found in carriers and non-carriers of FVL. This makes the presence of other unknown prothrombotic risk factors more probable in these families.     

Clinical and laboratory expression of associated thrombophilic conditions (homozygous/heterozygous factor V Leiden mutation and heterozygous prothrombin variant 20210A) in an Italian family.

Prothrombin variant 20210A is maintained to be a mild risk factor for venous thromboembolism (VTE). The association of this defect with other inherited thrombophilic conditions may result in an increased risk of developing VTE. In this article, a family is described in which prothrombin variant was associated with either homozygous or heterozygous factor V Leiden (FV Leiden) mutation. All family members except the proband were asymptomatic despite the presence and the severity of the underlying genetic defect(s). The proband, who carried homozygous FV Leiden mutation and heterozygous prothrombin variant, experienced recurrent VTE during pregnancies, whereas one brother, with the same defect, was asymptomatic. Mean prothrombin antigen and activity levels were higher in carriers of the prothrombin variant as compared with noncarriers. Thrombin generation was assessed in family members, in carriers of prothrombin variant or homozygous FV Leiden mutation and in a control group. Most of the family members presented with increased prothrombin fragment 1+2 levels possibly because of the presence of the FV Leiden mutation. Although it is conceivable that the co-inheritance of prothrombin variant and FV Leiden mutation may increase the risk of VTE, patients with these combined defects may remain asymptomatic. It is likely that acquired triggering conditions play a major role in determining VTE in carriers of a mild genetic predisposition. This has to be taken into account when recommendation for thromboprophylaxis is given.     

Contribution of the glycoprotein Ia 807TT, methylene tetrahydrofolate reductase 677TT and prothrombin 20210GA genotypes to prothrombotic risk among factor V 1691GA (Leiden) carriers

The cooperative effects of the GPIa 807TT, MTHFR 677TT and prothrombin 20210GA genotypes with the FV Leiden 1691GA (FVL) genotype were evaluated by comparing these genotype frequencies in 77 asymptomatic and 156 symptomatic heterozygous FVL carriers. The GPIa 807TT and MTHFR 677TT genotypes did not segregate within the symptomatic FVL carrier group and did not contribute to venous thrombotic risk in this patient cohort. There was no difference in the prothrombin 20210GA genotype frequency between asymptomatic FVL carriers and a random Caucasian control group; however, the prothrombin 20210GA genotype was nearly 5 times as prevalent (19/156 v 2/77; P < 0.02) in the symptomatic FVL carriers (odds ratio 5.21; 95% confidence interval 1.20-47.62), demonstrating that this important prothrombotic risk factor acts synergistically with FVL.     

The frequency of factor V Leiden and concomitance of factor V Leiden with prothrombin G20210A mutation and methylene tetrahydrofolate reductase C677T gene mutation in healthy population of Denizli, Aegean region of Turkey.

Factor V Leiden causing activated protein C resistance is the most common inherited form of thrombophilia leading to thrombosis. Its frequency shows great ethnic and geographic variations. The aim of this study was to determine the frequency of FV Leiden and coinheritance of FV Leiden with two other frequent hereditary thrombophilia causes, namely, prothrombin G20210A and methylene-tetrahydrofolate reductase (MTHFR) C677T mutation in the Aegean region of Turkey. The study population consisted of 1030 (500 men and 530 women) apparently healthy subjects. Functional resistance to activated protein C (APC) was measured by using the test kit STA staclot APC-R ((Diagnostica Stago, Asnieres, France, Cat. No. 00721). In subjects with APC resistance, molecular analyses of FV Leiden and of prothrombin G20210A and MTHFR C677T mutation were performed by using FV-PTH-MTHFR StripA (Vienna Lab, Labordiagnostika GmbH, Austria) kit, which was based on hybridization of polymerase chain reaction (PCR) amplified DNA products with mutation-specific oligonucleotide probes. Functional APC resistance was present in 93 subjects (9%). FV Leiden mutation was found in 87 of 93 subjects with APC resistance by PCR method. The FV Leiden carrier frequency was found to be 8.4% (87/1030). Seventy-six individuals were heterozygous (7.3%), and 11 were homozygous (1.06%). Among the 87 subjects with FV Leiden mutation, 45 subjects had MTHFR C677T gene mutation (7 homozygous, 38 heterozygous) and 4 subjects had heterozygote prothrombin G20210A gene mutation. A combination of FV Leiden and prothrombin G20210A and MTHFR C677T gene mutation was detected in 3 subjects. The results indicate that FV Leiden prevalence is quite high and coexistence of FV Leiden with other hereditary causes of thrombosis such as prothrombin G20210A mutation and MTHFR enzyme defect is not rare in healthy population of Aegean region of Turkey.     

The factor V (FV) gene ASP79HIS polymorphism modulates FV plasma levels and affects the activated protein C resistance phenotype in presence of the FV Leiden mutation

BACKGROUND AND OBJECTIVES: In carriers of the factor V (FV) Leiden mutation, different trans-acting gene variants (HR2 haplotype and FV Cambridge mutation) affect activated protein C (APC) sensitivity. Among a series of FV gene variants characterized, the Asp79His polymorphism appeared to be a good candidate for the modulation of FV activity. DESIGN AND METHODS: In a group of 150 apparently healthy subjects without the FV Leiden mutation and in 55 apparently healthy subjects with mutation, genotypes of the Asp79His polymorphism and of the HR haplotype were characterized and plasma levels of FV coagulant activity and APC ratios evaluated. RESULTS: In the group without the FV Leiden mutation, 16 subjects (10.7%) carried the His 79 allele and 15 subjects (10.0%) the HR2 haplotype. Two of them carried both gene variants. As compared to FV activity levels in non-carriers (106.4+18.5%), values were lower in subjects with the His79 allele (95.2+25.2%; p=0.025) and in those with the HR2 haplotype (93.7+16.2%; p =0.007). FV activity levels were further reduced in carriers of both FV gene variants (78.7+3.3%; p =0.009). APC values were similar among individuals carrying different FV genotypes. In the group with the FV Leiden mutation, APC ratios were lower in subjects carrying the His 79 allele (0.63; p =0.008) or the HR2 haplotype (0.63; p =0.026) than in subjects without (0.69) reflecting FV activity values. INTERPRETATION AND CONCLUSIONS: Present data suggest that carriership of the His79 allele modulate plasma levels of FV coagulant activity and, in subjects carrying the FV Leiden mutation, affects APC sensitivity.     

Risk of venous thromboembolism in carriers of factor V Leiden with a concomitant inherited thrombophilic defect: a retrospective analysis.

Factor V Leiden is the most common genetic defect associated with venous thromboembolism. Its clinical expression is limited and shows a wide intrafamilial and interfamilial variation, which might be explained by the influence of other genetic risk factors. We retrospectively studied 226 patients with factor V Leiden and documented venous thromboembolism (probands) and 400 first-degree carrier relatives to assess the contribution of concomitant genetic risk factors to the occurrence of venous thromboembolism. The prothrombin G20210A mutation was found in 8.3%, homozygosity of factor V Leiden in 7.2%, and inherited deficiencies of antithrombin, protein C or protein S in 4.7% of symptomatic carriers (probands and relatives), as compared with 6.0, 3.4 and 0.9% of asymptomatic carriers, respectively. The total follow-up time in relatives was 11 049 years. Prevalences of venous thromboembolism were 10.8% in single heterozygous factor V Leiden carrier relatives, 16.0% in double-heterozygotes for factor V Leiden and the prothrombin mutation, 36.8% in homozygotes for factor V Leiden, and 40.0% in double-heterozygotes for factor V Leiden and an inherited deficiency of protein C or protein S. Annual incidences in these groups were 0.39, 0.57, 1.41, and 4.76%, respectively. Multivariate analysis showed a small, non-significant additional effect of the prothrombin mutation on the risk of venous thromboembolism in heterozygotes for factor V Leiden [adjusted hazard ratio, 1.3; 95% confidence interval (CI), 0.5-3.8]. This effect was more pronounced for homozygosity of factor V Leiden (adjusted hazard ratio, 3.9; 95% CI, 1.7-9.0) and inherited protein C or protein S deficiencies (adjusted hazard ratio, 17.5; 95% CI, 3.8-81.2). Our data provide evidence of clustering of the evaluated genetic thrombophilic defects in symptomatic factor V Leiden carriers and support the assumption that the clinical expression of factor V Leiden depends on clustering in a part of carriers.     

Renal venous thrombosis in neonates: prothrombotic risk factors and long-term follow-up

The present study was designed to evaluate prothrombotic risk profiles in 59 consecutively recruited white neonates with renal venous thrombosis (RVT). The rates of prothrombotic risk factors (PRs)-for example, the factor V (FV) 1691G> A mutation, the factor II (FII) 20210G> A variant, antithrombin (AT), protein C (PC), protein S (PS), elevated lipoprotein(a) (Lp(a)), total fasting plasma homocysteine (tHcy) levels, and anticardiolipin antibodies (ACAs)-were compared with those of 118 healthy control children. At onset, 32 (54.2%) of the 59 neonates showed underlying clinical conditions; 40 (67.8%) of them and 23 (85.2%) of the 27 infants with idiopathic RVT showed at least one PR. Univariate analysis revealed significantly elevated odds ratios/95% confidence intervals (ORs/95% CIs) for FV and Lp(a). Additionally, PC/AT deficiency and ACAs were found significantly more often in the patient group (P =.04). Multivariate analysis calculated significant ORs/95% CIs only for FV (OR, 9.4; 95% CI, 3.3-26.6) and elevated Lp(a) (OR, 7.6; 95% CI, 2.4-23.8). Of the 59 neonates investigated, 53 revealed renal atrophy, and 13 children additionally suffered from severe arterial hypertension. In conclusion, the present study demonstrates the significance of genetic PR-especially the FV mutation and elevated Lp(a)-for the etiology of neonatal RVT.     

Determination of activated protein C resistance in anticoagulated and lupus positive patients.

Clotting-based activated protein C (APC) assays have limitations when testing patients on oral anticoagulant (OA) therapy or with a lupus anticoagulant (LA). Predilution in factor V (FV)-deficient plasma and testing with phospholipid-rich Russell Viper venom (RVV)-based methods have been shown to be the most suitable methods when testing these patient groups, respectively. We evaluated a modified RVV based clotting test (Gradileiden V test; Gradipore, Sydney, Australia) in a large patient cohort and determined its sensitivity to the FV Leiden mutation. We also examined whether normal plasma can be used to dilute plasma from warfarinized patients without compromising sensitivity to the FV Leiden mutation. A total of 1,956 plasmas were studied including congenital protein C (five plasmas), and protein S deficiency (five plasmas), LA (29 plasmas), FV Leiden heterozygote (102 plasmas), and homozygote (five plasmas), warfarin (54 plasmas), standard heparin therapy (37 plasmas) and normal healthy controls (21 plasmas). Molecular analysis was performed on all samples. The effect of FV Leiden concentration on the APC ratio was examined by determining the APC resistance of a homozygous plasma serially diluted in six sources of normal plasma (NP). The relationship was non-linear and dependent on the initial APC ratio of the chosen source of NP. APC resistance was demonstrated in the varying sources of NP in dilutions of 1/4 (25% FV Leiden) to 1/32 (3% FV Leiden). A 1/2 dilution in pooled NP is recommended for patients on OA therapy because the test remains sensitive at levels of 25% FV Leiden and this is the dilution routinely used for other applications in a coagulation laboratory. The effect of a LA on the APC ratio was similarly studied by determining the APC resistance of a homozygous plasma serially diluted in two sources of LA-positive plasma. This relationship was also non-linear and dependent on the initial APC ratio of the LA-positive plasma. APC resistance was demonstrated in dilutions of 1/16 (6% FV Leiden) to 1/64 (1.5% FV Leiden) demonstrating the sensitivity of the test to APC resistance in the presence of a LA. Our results show the modified RVV-based test clearly predicts the presence of factor V Leiden in a large cohort of patients. The method offers advantages when testing patients with a LA and patients receiving warfarin providing a 1/2 predilution step in pooled NP is performed. Pooled NP does not affect the sensitivity of the test to the mutation, is routinely used in coagulation laboratories, and is considerably less expensive than FV-deficient plasma.     

Coexistence of factor V G1691A and factor II G20210A gene mutations in a thrombotic family is associated with recurrence and early onset of venous thrombosis.

Two G-to-A mutations at positions 1691 of the factor V (FV) gene and 20210 of the prothrombin (FII) gene have been associated with an increased risk of venous thromboembolism. We report a thrombosis-prone family in which one subject--the propositus who exhibited combined heterozygous FV G1691A and FII G20210A mutations--showed spontaneous and early clinical onset (at 23 years), recurrences of deep-vein thrombosis and pulmonary embolism. His asymptomatic father carried the FII G20210A substitution and his mother, characterized by an isolated thrombotic episode on occasion of surgery (at 48 years), carried the FV G1691A substitution. In the maternal lineage, one of the propositus' uncles had thrombosis on occasion of a bone fracture (at 65 years) despite the absence of known prothrombotic defects. A sister of the propositus carried the FII G20210A and the brother the FV G1691A mutation. They have been asymptomatic until now. The propositus' two children, 20 and 16 years old, both carry the FV G1691A substitution and have been asymptomatic until now. The plasma levels of FII were higher in carriers of the FII G20210A allele if compared with noncarriers, and the activated protein C resistance phenotype, associated with the FV Leiden mutation, showed a complete correlation with the FV G1691A mutation. Despite the very limited number of thrombotic cases involved in this survey, which does not allow statistically sound conclusions, the data obtained from this family suggest that the synergy of inherited factors and transient risk conditions could play a key role in the occurrence of thrombotic accidents.     

Risk of venous thromboembolism and clinical manifestations in carriers of antithrombin, protein C, protein S deficiency, or activated protein C resistance: a multicenter collaborative family study

Deficiencies of antithrombin (AT), protein C (PC) or protein S (PS), and activated protein C resistance (APCR) are very well-established coagulation defects predisposing to venous thromboembolism (VTE). We performed a retrospective cohort family study to assess the risk for VTE in individuals with AT, PC, or PS deficiency, or APCR. Five hundred thirteen relatives from 9 Italian centers were selected from 233 families in which the proband had had at least 1 episode of VTE. We calculated the incidence of VTE in the whole cohort and in the subgroups after stratification by age, sex, and defect. The overall incidence of VTE (per 100 patient-years) in the group of relatives was 0.52. It was 1.07 for AT, 0.54 for PC, 0.50 for PS, 0.30 for APCR, and 0.67 in the group with a double defect. The incidence was associated with age, but not with sex. The mean age at onset was between 30 and 40 years for all the coagulation defects. Women had the peak of incidence in the age range of 21 to 40 years, earlier than men. The lifetime risk for VTE was 4.4 for AT versus APCR, 2.6 for AT versus PS, 2.2 for AT versus PC, 1.9 for PC versus APCR, and 1.6 for PS versus APCR. AT deficiency seems to have a higher risk for VTE than the other genetic defects. There is a relation between age and occurrence of thrombosis for both men and women. The latter had the peak of incidence earlier than the former.     

The factor V HR2 haplotype and the risk of venous thrombosis: a meta-analysis

Background and Objectives: A complex haplotype of factor V gene (FV HR2) has been recently reported. FVHR2 possesses decreased co-factor activity to APC in the degradation of FVIIIa, and an increased ratio of the more procoagulant isoform FV1 compared to FV2. Contrasting results on whether the haplotype induces a significant risk of venous thromboembolism (VTE) have been reported. Design and Methods: It has been surmised that FVHR2 enhances the risk of VTE carried by FV Leiden. We carried out a meta-analysis of the reported studies on the role of HR2 haplotype in inducing a risk of VTE and the influence of the polymorphism on the risk carried by patients with FV Leiden. Results: Eight studies were analyzed for the estimation of the risk of VTE. A total of 338 out of 2,696 cases (12.5%; range 7.8 to 18.5%) and 885 out of 7,710 controls (11.5%; range 8.1 to 12.1%) were HR2 positive. The odds ratio for VTE associated with HR2 haplotype was not statistically significant (OR 1.15; 95% C.I. 0.98-1.36). The OR for the association between FV Leiden and FV HR2 and the risk of VTE in cases and controls was largely heterogeneous as to OR and 95% C.I. and no statistical significant difference was observed. Interpretation and Conclusions: The data from the present meta-analysis suggests that FVHR2 could be a very mild prothrombotic factor. The association of FV Leiden and HR2 haplotype seems not to increase significantly the risk of VTE carried by isolated heterozygosity for FV Leiden. However, well-designed clinical studies are needed to clarify this issue definitely.     

Factor V Leiden: a disorder of factor V anticoagulant function

PURPOSE OF REVIEW: Activated protein C (APC) resistance, which is often associated with the factor V R506Q (FV Leiden) mutation, is a common risk factor for venous thrombosis. Study of the mechanism of APC resistance has revealed that coagulation FV stimulates the APC-catalysed inactivation of FVIIIa, and that this anticoagulant function of FV is impaired in FV Leiden. The present review covers the discovery, the physiological significance and the structural requirements of the APC-cofactor activity of FV. RECENT FINDINGS: Recent in vitro and in vivo experiments indicate that the anticoagulant activity of FV is physiologically relevant and that FV plays a major role in the maintenance of the haemostatic balance. Quantitative and functional defects of the APC-cofactor activity of FV lead to increased thrombin generation and are associated with a prothrombotic state. Although the structural requirements for the expression of the APC-cofactor activity of FV are now beginning to be unravelled, the underlying molecular mechanism remains elusive. SUMMARY: The APC-cofactor activity of FV and its impairment in FV Leiden can explain the different thrombosis risks associated with heterozygosity, homozygosity and pseudo-homozygosity for FV Leiden. Elucidation of the molecular mechanism of the anticoagulant function of factor V may provide novel targets for the design of antithrombotic drugs.