scholarly journals Activated Protein C has a Regulatory Role in Factor VIII Function

Blood ◽  
2021 ◽  
Author(s):  
Amelia R. Wilhelm ◽  
Nicole A. Parsons ◽  
Benjamin J Samelson-Jones ◽  
Robert J Davidson ◽  
Charles Esmon ◽  
...  
Keyword(s):  
Factor Viii ◽  
Protein C ◽  
Activated Protein C ◽  
Protein S ◽  
Inhibitory Antibody ◽  
Apc Resistance ◽  
Fv Leiden ◽  
A2 Domain ◽  
Tail Clip

Mechanisms thought to regulate activated factor VIII (FVIIIa) cofactor function include A2-domain dissociation and activated protein C (APC) cleavage. Unlike A2-domain dissociation, there is no known phenotype associated with altered APC cleavage of FVIII and biochemical studies suggest APC plays a marginal role in FVIIIa regulation. However, the in vivo contribution of FVIIIa inactivation by APC is unexplored. Here we compared wild-type B-domainless FVIII (FVIII-WT) recombinant protein to an APC resistant FVIII variant (FVIII-R336Q/R562Q; FVIII-QQ). FVIII-QQ demonstrated expected APC resistance without other changes in procoagulant function or A2-domain dissociation. In plasma-based studies, FVIII-WT/FVIIIa-WT demonstrated a dose-dependent sensitivity to APC with or without protein S, while FVIII-QQ/FVIIIa-QQ did not. Importantly, FVIII-QQ demonstrated approximately 5-fold increased procoagulant function relative to FVIII-WT in the tail clip and ferric chloride injury models in hemophilia A (HA) mice. To minimize the contribution of FV inactivation by APC in vivo, the tail clip assay was performed in homozygous HA/FV-Leiden mice infused with FVIII-QQ or FVIII-WT in the presence or absence of mAb1609, an antibody that blocks murine PC/APC hemostatic function. FVIII-QQ again demonstrated enhanced hemostatic function in HA/FV-Leiden mice; however, FVIII-QQ and FVIII-WT performed analogously in the presence of the PC/APC inhibitory antibody, supporting the increased hemostatic effect of FVIII-QQ was APC specific. Our data demonstrate APC contributes to the in vivo regulation of FVIIIa, which has the potential to be exploited to develop novel HA therapeutics.

scholarly journals In Vivo hemostatic Significance of Activated Protein C in Factor VIIIa Regulation

Blood ◽  
2019 ◽  
Vol 134 (Supplement_1) ◽  
pp. 93-93
Author(s):  
Amelia R. Wilhelm ◽  
Nicole A. Parsons ◽  
Charles T. Esmon ◽  
Rodney M. Camire ◽  
Lindsey A. George
Keyword(s):  
Blood Loss ◽  
Protein C ◽  
Activated Protein C ◽  
Enzyme Complex ◽  
Hemostatic Effect ◽  
Safety Considerations ◽  
A2 Domain ◽  
Tail Clip

Activated factor VIII (FVIIIa) is an essential cofactor in the intrinsic tenase (Xase) enzyme complex that generates factor Xa and propagates clot formation. The FVIIIa heterotrimer is comprised of a metal ion linked dimer (A1/A3-C1-C2 domains) that is associated with the A2 domain by weak non-covalent interactions. Regulation of FXa formation by the intrinsic Xase enzyme complex occurs by FIXa inhibition and mechanisms contributing to FVIIIa inactivation, including: 1) rapid A2 domain dissociation and 2) activated protein C (APC) cleavage of FVIIIa. While FVIIIa inactivation by APC is considered important, there are surprisingly no in vivo studies documenting the hemostatic role of APC in FVIIIa regulation. Further, published data demonstrate APC cleavage of FVIIIa at physiologic protein concentrations occurs over hours while A2 dissociation occurs rapidly over minutes. Thus, it is thought that the predominant mechanism of FVIIIa inactivation is A2 dissociation and APC likely plays a marginal role in FVIIIa regulation. Additionally, unlike described A2 mutations that enhance dissociation and cause hemophilia A (HA), there is no known disease state attributed to altered FVIIIa cleavage by APC. This is in contrast to FVIII's homologous protein, FVa, whereby resistance to APC cleavage is the most common inherited thrombophilia (FV-Leiden [FVL]). Understanding the physiologically relevant mechanisms of FVIIIa inactivation has immediate clinical applicability for understanding safety considerations in HA therapeutics that bypass FVIIIa regulation (FVIII mimetic antibodies, e.g. emicizumab). Further, as evidenced by successful hemophilia B gene therapy trials using a gain of function FIX variant (FIX-Padua), altering FVIIIa inactivation could be exploited for therapeutic benefit in the setting of gene transfer. We aimed to determine the in vivo hemostatic role of APC in FVIIIa regulation and pair these studies with purified system analysis. We introduced Arg to Gln mutations at FVIII APC cleavage sites (R336Q and R562Q, herein called FVIII-QQ) on a B-domain deleted FVIII (FVIII-WT) backbone and produced recombinant FVIII-QQ and FVIII-WT. Unlike FVIII-WT, western blot analysis of FVIII-QQ incubated with APC and phospholipids had no evidence of cleavage. Enzyme kinetic studies using purified components demonstrated no appreciable difference in the Km or Vmax for FX within the intrinsic Xase enzyme complex or A2 dissociation of FVIII-QQ relative to FVIII-WT. These data confirmed no unexpected differences in FVIII-QQ relative to FVIII-WT. To begin to evaluate the role of APC in FVIIIa regulation, we measured thrombin generation in murine and human HA plasma reconstituted with FVIII-QQ or FVIII-WT in the presence of increasing APC concentrations. The IC50 of APC was 2-3-fold higher for FVIII-QQ than FVIII-WT. To evaluate the in vivo hemostatic effect of APC in FVIIIa regulation, HA mice were infused with FVIII-QQ or FVIII-WT and evaluated by tail clip injury and 7.5% FeCl3 carotid artery occlusion models. Required doses of FVIII-QQ to normalize blood loss from a tail clip assay and time to vessel occlusion in a FeCl3 assay were 4-5 fold lower than necessary FVIII-WT doses; the superior hemostatic effect of FVIII-QQ supported the physiologic significance of APC in FVIIIa inactivation. To isolate the role of APC in FVIIIa regulation from APC inactivation of FVa, we backcrossed HA mice with FVL mice to create homozygous HA/FVL mice. HA/FVL mice were infused with FVIII-QQ or FVIII-WT and underwent tail clip assay analysis. Doses of FVIII-QQ required to normalize blood loss were again less than FVIII-WT. To further isolate the enhanced hemostatic effect of FVIII-QQ to APC resistance, we performed the tail clip assay in HA/FVL mice infused with FVIII-QQ or FVIII-WT in the presence or absence of MPC1609, an antibody that blocks murine APC function (Xu et al. J Thromb Haemost 2008). In the presence of MPC1609, the same dose of FVIII-WT and FVIII-QQ was required to normalize blood loss (Figure 1). Collectively, our in vitro and in vivo data support the physiologic significance of APC in FVIIIa regulation. To our knowledge these data are the first to demonstrate the in vivo hemostatic effect of APC in FVIIIa inactivation. Our data may be translated to rationally exploit APC regulation of FVIIIa to develop novel HA therapeutics or further delineate safety considerations in therapies that bypass FVIIIa regulation. Figure 1 Disclosures Camire: Pfizer: Research Funding. George:University of Pennyslvania: Employment; Pfizer: Consultancy; Avrobio: Membership on an entity's Board of Directors or advisory committees.

APC Resistance and other Haemostatic Variables during Pregnancy and Puerperium

1999 ◽  
Vol 81 (04) ◽  
pp. 527-531 ◽  
Author(s):  
U. Kjellberg ◽  
N.-E. Andersson ◽  
S. Rosén ◽  
L. Tengborn ◽  
M. Hellgren
Keyword(s):  
Factor Viii ◽  
Plasminogen Activator ◽  
Protein C ◽  
Activated Protein C ◽  
Plasminogen Activator Inhibitor ◽  
Protein S ◽  
Reference Level ◽  
Soluble Fibrin ◽  
Prothrombin Fragment ◽  
D Dimer

SummaryForty-eight healthy pregnant women were studied prospectively and longitudinally. Blood sampling was performed at 10-15, 23-25, 32-34 and 38-40 weeks of gestation, within one week and at eight weeks postpartum. Classic and modified activated protein C ratio decreased as pregnancy progressed. In the third trimester 92% of the ratios measured with the classic test were above the lower reference level whereas all modified test ratios were normal. Slight activation of blood coagulation was shown with increased levels of prothrombin fragment 1+2, soluble fibrin and D-dimer. Fibrinogen, factor VIII and plasminogen activator inhibitor type 1 and type 2 increased. Protein S and tissue plasminogen activator activity decreased. Protein C remained unchanged. No correlation was found between the decrease in classic APC ratio and changes in factor VIII, fibrinogen, protein S, prothrombin fragment 1+2 or soluble fibrin, nor between the increase in soluble fibrin and changes in prothrombin fragment 1+2, fibrinogen and D-dimer.

Molecular Characterization of a Type I Quantitative Factor V Deficiency in a Thrombosis Patient that Is “Pseudo Homozygous” for Activated Protein C Resistance

1997 ◽  
Vol 77 (02) ◽  
pp. 252-257 ◽  
Author(s):  
Joan F Guasch ◽  
Ruud P M Lensen ◽  
Rogier M Bertina
Keyword(s):  
Protein C ◽  
Dna Analysis ◽  
Activated Protein C ◽  
Type I ◽  
Factor V ◽  
Sequencing Analysis ◽  
Apc Resistance ◽  
Quantitative Factor ◽  
Factor V Deficiency ◽  
Fv Leiden

SummaryResistance to activated protein C (APC), which is associated with the FV Leiden mutation in the large majority of the cases, is the most common genetic risk factor for thrombosis. Several laboratory tests have been developed to detect the APC-resistance phenotype. The result of the APC-resistance test (APC-sensitivity ratio, APC-SR) usually correlates well with the FV Leiden genotype, but recently some discrepancies have been reported. Some thrombosis patients that are heterozygous for FV Leiden show an APC-SR usually found only in homozygotes for the defect. Some of those patients proved to be compound heterozygotes for the FV Leiden mutation and for a type I quantitative factor V deficiency. We have investigated a thrombosis patient characterized by an APC-SR that would predict homozygosity for FV Leiden. DNA analysis showed that he was heterozygous for the mutation. Sequencing analysis of genomic DNA revealed that the patient also is heterozygous for a G5509→A substitution in exon 16 of the factor V gene. This mutation interferes with the correct splicing of intron 16 and leads to the presence of a null allele, which corresponds to the “non-FV Leiden” allele. The conjunction of these two defects in the patient apparently leads to the same phenotype as observed in homozygotes for the FV Leiden mutation.

Platelet-mediated proteolytic down regulation of the anticoagulant activity of protein S in individuals with haematological malignancies

2012 ◽  
Vol 107 (03) ◽  
pp. 468-476 ◽  
Author(s):  
Ilze Dienava-Verdoold ◽  
Marina R. Marchetti ◽  
Liane C. J. te Boome ◽  
Laura Russo ◽  
Anna Falanga ◽  
...  
Keyword(s):  
Protein C ◽  
Normal Values ◽  
Anticoagulant Activity ◽  
Activated Protein C ◽  
Protein S ◽  
Intact Protein ◽  
The Impact ◽  
Independent Protein

SummaryThe natural anticoagulant protein S contains a so-called thrombin-sensitive region (TSR), which is susceptible to proteolytic cleavage. We have previously shown that a platelet-associated protease is able to cleave protein S under physiological plasma conditions in vitro. The aim of the present study was to investigate the relation between platelet-associated protein S cleaving activity and in vivo protein S cleavage, and to evaluate the impact of in vivo protein S cleavage on its anticoagulant activity. Protein S cleavage in healthy subjects and in thrombocytopenic and thrombocythaemic patients was evaluated by immunological techniques. Concentration of cleaved and intact protein S was correlated to levels of activated protein C (APC)-dependent and APC-independent protein S anticoagulant activity. In plasma from healthy volunteers 25% of protein S is cleaved in the TSR. While in plasma there was a clear positive correlation between levels of intact protein S and both APC-dependent and APC-independent protein S anticoagulant activities, these correlations were absent for cleaved protein S. Protein S cleavage was significantly increased in patients with essential thrombocythaemia (ET) and significantly reduced in patients with chemotherapy-induced thrombocytopenia. In ET patients on cytoreductive therapy, both platelet count and protein S cleavage returned to normal values. Accordingly, platelet transfusion restored cleavage of protein S to normal values in patients with chemotherapy-induced thrombocytopenia. In conclusion, proteases from platelets seem to contribute to the presence of cleaved protein S in the circulation and may enhance the coagulation response in vivo by down regulating the anticoagulant activity of protein S.

Cleavage of Factor V at Arg 506 by Activated Protein C and the Expression of Anticoagulant Activity of Factor V

Blood ◽  
1999 ◽  
Vol 93 (8) ◽  
pp. 2552-2558 ◽  
Author(s):  
Elisabeth Thorelli ◽  
Randal J. Kaufman ◽  
Björn Dahlbäck
Keyword(s):  
Protein C ◽  
Anticoagulant Activity ◽  
Activated Protein C ◽  
Protein S ◽  
Factor V ◽  
Wild Type ◽  
Apc Resistance ◽  
S 100 ◽  
Negative Effect ◽  
Cofactor Activity

Activated protein C (APC) inhibits coagulation by cleaving and inactivating procoagulant factor Va (FVa) and factor VIIIa (FVIIIa). FV, in addition to being the precursor of FVa, has anticoagulant properties; functioning in synergy with protein S as a cofactor of APC in the inhibition of the FVIIIa-factor IXa (FIXa) complex. FV:Q506 isolated from an individual homozygous for APC-resistance is less efficient as an APC-cofactor than normal FV (FV:R506). To investigate the importance of the three APC cleavage sites in FV (Arg-306, Arg-506, and Arg-679) for expression of its APC-cofactor activity, four recombinant FV mutants (FV:Q306, FV:Q306/Q506, FV:Q506, and FV:Q679) were tested. FV mutants with Gln (Q) at position 506 instead of Arg (R) were found to be poor APC-cofactors, whereas Arg to Gln mutations at positions 306 or 679 had no negative effect on the APC-cofactor activity of FV. The loss of APC-cofactor activity as a result of the Arg-506 to Gln mutation suggested that APC-cleavage at Arg-506 in FV is important for the ability of FV to function as an APC-cofactor. Using Western blotting, it was shown that both wild-type FV and mutant FV was cleaved by APC during the FVIIIa inhibition. At optimum concentrations of wild-type FV (11 nmol/L) and protein S (100 nmol/L), FVIIIa was found to be highly sensitive to APC with maximum inhibition occurring at less than 1 nmol/L APC. FV:Q506 was inactive as an APC-cofactor at APC-concentrations ≤ 1 nmol/L and only partially active at higher APC concentrations. Our results show that increased expression of FV anticoagulant activity correlates with APC-mediated cleavage at Arg-506 in FV, but not with cleavage at Arg-306 nor at Arg-679.

scholarly journals Inhibition of the intrinsic factor X activating complex by protein S: evidence for a specific binding of protein S to factor VIII

Blood ◽  
1995 ◽  
Vol 86 (3) ◽  
pp. 1062-1071 ◽  
Author(s):  
SJ Koppelman ◽  
TM Hackeng ◽  
JJ Sixma ◽  
BN Bouma
Keyword(s):  
Factor Viii ◽  
Protein C ◽  
Intrinsic Factor ◽  
Activated Protein C ◽  
Protein S ◽  
Inhibitory Effect ◽  
Factor X ◽  
Ic50 Values ◽  
Factor X Activation ◽  
Factor X Activating Complex

Protein S is a vitamin K-dependent nonenzymatic anticoagulant protein that acts as a cofactor to activated protein C. Recently it was shown that protein S inhibits the prothrombinase reaction independent of activated protein C. In this study, we show that protein S can also inhibit the intrinsic factor X activation via a specific interaction with factor VIII. In the presence of endothelial cells, the intrinsic activation of factor X was inhibited by protein S with an IC50 value of 0.28 +/- 0.04 mumol/L corresponding to the plasma concentration of protein S. This inhibitory effect was even more pronounced when the intrinsic factor X activation was studied in the presence of activated platelets (IC50 = 0.15 +/- 0.02 mumol/L). When a nonlimiting concentration of phospholipid vesicles was used, the plasma concentration of protein S (300 nmol/L) inhibited the intrinsic factor X activation by 40%. Thrombin-cleaved protein S inhibited the endothelial cell-mediated factor X activation with an IC50 similar to that of native protein S (0.26 +/- 0.02 mumol/L). Protein S in complex with C4b-binding protein inhibited the endothelial cell-mediated factor X activation more potently than protein S alone (IC50 = 0.19 +/- 0.03 mumol/L). Using thrombin activated factor VIII, IC50 values of 0.53 +/- 0.09 mumol/L and 0.46 +/- 0.10 mumol/L were found for native protein S and thrombin-cleaved protein S, respectively. The possible interactions of protein S with factor IXa, phospholipids, and factor VIII were investigated. The enzymatic activity of factor IXa was not affected by protein S, and interaction of protein S with the phospholipid surface could not fully explain the inhibitory effect of protein S on the factor X activation. Using a solid-phase binding assay, we showed a specific, saturable, and reversible binding of protein S to factor VIII with a high affinity. The concentration of protein S where half-maximal binding was reached (B1/2max) was 0.41 +/- 0.06 mumol/L. A similar affinity was found for the interaction of thrombin-cleaved protein S with factor VIII (B1/2max = 0.40 +/- 0.04 mumol/L). The affinity of the complex protein S with C4B-binding protein appeared to be five times higher (B1/2max = 0.07 +/- 0.03 mumol/L). Because the affinities of the interaction of the different forms of protein S with factor VIII correspond to the IC50 values observed for the intrinsic factor X activating complex, the interaction of protein S with factor VIII may explain the inhibitory effect of protein S on the intrinsic factor X activating complex.(ABSTRACT TRUNCATED AT 400 WORDS)

Mutation at either Arg336 or Arg562 in Factor VIII Is Insufficient for Complete Resistance to Activated Protein C (APC)-mediated Inactivation: Implications for the APC Resistance Test

1998 ◽  
Vol 79 (03) ◽  
pp. 557-563 ◽  
Author(s):  
Kagehiro Amano ◽  
Donna Michnick ◽  
Micheline Moussalli ◽  
Randal Kaufman
Keyword(s):  
Factor Viii ◽  
Cleavage Site ◽  
Protein C ◽  
Double Mutant ◽  
Chinese Hamster Ovary Cells ◽  
Activated Protein C ◽  
Chinese Hamster ◽  
Site Directed Mutagenesis ◽  
Apc Resistance ◽  
Specific Order

SummaryActivated protein C (APC)-mediated inactivation of factor VIII (FVIII) correlates with cleavage at either Arg336 and/or Arg562. To elucidate the APC cleavage requirements for inactivation of FVIII, APC cleavage site mutants in FVIII (R336I, R562K and R336I/R562K) were made by site-directed mutagenesis. Analysis of these FVIII mutants expressed in COS-1 monkey cells demonstrated the thrombin-cleaved mutant R562K was resistant to APC cleavage at residue 562 but not at Arg336 and the thrombin cleaved mutant R336I was mostly resistant to APC cleavage at residue 336, but was sensitive to APC cleavage at Arg562. The double mutant R336I/R562K was mostly resistant to cleavage at residue 336 and completely resistant to cleavage at residue 562. Thus, APC cleavage of FVIII does not require a specific order of cleavage at either residue. The functional inactivation by APC was studied using partially purified preparations of FVIII expressed in Chinese hamster ovary cells. Both single mutants were inactivated at similar rates but slower than wild-type FVIII, whereas the double mutant R336I/R562K was resistant to inactivation. The ability of a commercially available APC-resistance assay kit to detect APC resistant FVIII was tested by reconstituting FVIII deficient plasma with the APC resistant mutants. Only the R336I/R562K demonstrated a reduced APC-resistance ratio, indicating that this assay can not detect the single APC cleavage site mutant of FVIII. These results suggest that APC-mediated cleavage at either Arg336 or Arg562 partially inactivate FVIII.

Prevention of thrombosis following deep arterial injury in rats by bovine activated protein C requiring co-administration of bovine protein S

2003 ◽  
Vol 90 (08) ◽  
pp. 227-234 ◽  
Author(s):  
Björn Dahlbäck ◽  
Björn Arnljots ◽  
Karl Malm
Keyword(s):  
Protein C ◽  
Anticoagulant Activity ◽  
Activated Protein C ◽  
Protein S ◽  
Arterial Injury ◽  
Control Group ◽  
Clotting Time ◽  
Antithrombotic Effect

SummaryThe antithrombotic effect of bovine activated protein C (bAPC) given with or without bovine protein S (bPS) was investigated in a rat model of deep arterial injury. A segment of the left common carotid artery was isolated between vascular clamps and opened longitudinally. An endarterectomy was performed and the arteriotomy was closed with a running suture, whereafter the vessel was reperfused by removing the clamps. The antithrombotic effect (vascular patency rates 31 minutes after reperfusion) and the arteriotomy bleeding were measured. Ten treatment groups each containing 10 rats and a control group of 20 animals were in a blind random fashion given intravenous bolus injections of increasing doses of activated protein C, with or without co-administration of protein S. The groups received either bAPC alone (0.8, 0.4, 0.2 or 0.1 mg/kg), bAPC (0.8, 0.4, 0.2, 0.1 or 0.05 mg/kg) combined with bPS (0.6 mg/kg), or bPS alone (0.6 mg/kg) whereas the control group received vehicle only. Administered alone, bAPC or bPS had no antithrombotic effect, regardless of dosage. In contrast, all groups that were treated with bAPC in combination with bPS demonstrated a significant antithrombotic effect, as compared to controls. Neither bAPC, bPS, nor the combination of bAPC and bPS increased the arteriotomy bleeding significantly compared to controls. In vitro clotting assays using bAPC or bPS alone yielded only minor prolongation of clotting time, whereas bAPC combined with bPS prolonged the clotting time considerably, demonstrating the dependence on the APC-cofactor activity of bPS for expression of anticoagulant activity by bAPC. In conclusion, our study shows the in vivo significance of protein S as a cofactor to activated protein C, and that potent anti-thrombotic effect can be achieved by low doses of bAPC combined with bPS, without producing hemorrhagic side effects.

The VITA Project: Heritability of Resistance to Activated Protein C

2000 ◽  
Vol 84 (11) ◽  
pp. 811-814 ◽  
Author(s):  
Alberto Tosetto ◽  
Giancarlo Castaman ◽  
Antonio Cappellari ◽  
Francesco Rodeghiero
Keyword(s):  
Risk Factor ◽  
Protein C ◽  
Genetic Factors ◽  
Activated Protein C ◽  
Population Level ◽  
Phenotypic Resistance ◽  
Apc Resistance ◽  
Parental Response ◽  
High Heritability ◽  
Fv Leiden

SummaryResistance to activated protein C (APC) is a risk factor for venous thromboembolism also in absence of the FV Leiden mutation. To evaluate the influence of genetic factors on APC resistance, we evaluated the heritability of the APC resistance phenotype in 1,519 sib-parent pairs randomly selected from the VITA Project. After adjustment for known influencing factors, a high heritability coefficient (0.58) was observed and parental response to APC was the single most important factor in predicting the corresponding phenotype in sibs. In 32 parentsib pairs in which phenotypic resistance to APC unrelated to FV Leiden was present in both parents and sibs, no additional mutation on the 306-aminoacid residue of FV (FV Cambridge and FV Hong Kong) was found. In these 32 parent-sib pairs, FVIII:C and vWf:Ag levels were not significantly increased and there was no excess prevalence of the R2 allele of exon 13 of FV gene. This study suggests that the response to APC is significantly influenced by genetic factors also at a population level, but the responsible mechanisms are still undefined.

Prevalence of Activated Protein C Resistance Due To Factor V Leiden Mutation among South Asians (India and Pakistan) with Venous Thromboembolism.

Blood ◽  
2004 ◽  
Vol 104 (11) ◽  
pp. 4043-4043
Author(s):  
Sirisha Perumandla ◽  
Yelena Patsiornik ◽  
Neetha Mahajan ◽  
Anju Ohri
Keyword(s):  
Protein C ◽  
Chart Review ◽  
South Asians ◽  
Activated Protein C ◽  
Factor V Leiden ◽  
Factor V ◽  
Inherited Thrombophilia ◽  
Apc Resistance ◽  
Fv Leiden ◽  
Work Up

Abstract Objective: To study the prevalence of Activated Protein C (APC) resistance due to Factor V Leiden (FV Leiden) mutation among the first generation immigrants from India and Pakistan with venous thromboembolism (VTE). Introduction: APC resistance due to the substitution of Arginine 506 by Glutamine in coagulation Factor V is caused by G1691A mutation in exon 10 of Factor V gene. This is the commonest cause of inherited thrombophilia in Caucasians, but the frequency of this mutation is low in non-Caucasians. Among subjects in the Physician Health Study, the frequency of FV Leiden was found to be 5.27% in Caucasian Americans vs. 0.45% in Asian Americans. Another study found no mutation in 191 Asian Americans tested. In non-Caucasians with VTE, it is generally considered not cost effective to screen for this mutation. However Asians are a heterogeneous group and the Leiden gene frequency varies among different ethnic populations. While the frequency of FV Leiden gene has been documented to be low in China, Korea, Japan, Thailand, Indonesia etc, the frequency in India and Pakistan is not well studied. Two studies found a carrier frequency of 2% (Rees et al) and 4.2 % (Gou et al) among the general population from India and Pakistan. This is similar to the frequency found in Middle Eastern and European population. We did not come across any study of FV Leiden gene frequency in patients with VTE from India and Pakistan. Patients and Methods: A retrospective chart review of patients of Indian or Pakistani origin seen at Coney Island Hospital, from July 1996 to June 2003, who had a work up for inherited thrombophilia after an episode of VTE. During the chart review age, sex, first or recurrent episode and any predisposing factors such as immobilization, malignancy, hormonal therapy, surgery, pregnancy, and the presence of SLE or MPD were noted. Thrombophilia work up included functional assays for Protein C, S and Antithrombin III, Lupus anticoagulant, ACA and Homocysteine levels. APC resistance was measured by a clotting assay using Factor V depleted plasma and all patients who were borderline or resistant were tested for the presence of FV Leiden mutation by PCR. Results: A total of 18 patients were studied. All had an episode of VTE documented by a Doppler ultrasonography or a Ventilation Perfusion lung scan or a CT angiogram. 3 out of 18 patients (16.6%) had APC resistance. All the three patients were confirmed to be heterozygous for FV Leiden mutation. Two were male and one was a female with a median age of 36 yrs (27, 36 and 57 yrs). The female patient had a recurrent episode, first one occurred during pregnancy, but the second episode had no precipitating events. One male patient had trauma to the leg and was immobilized at the time of the VTE, another male patient was a cab driver by occupation. None of the patients had any other concurrent inherited thrombophilic state. Conclusions: The prevalence of the FV Leiden mutation is significantly high among South Asians with VTE in our study. If the findings are confirmed by a larger study, screening for this mutation for thrombophilia would be relevant in patients of South Asian origin and screening recommendations for family members would be identical to Caucasian population. The high prevalance as in Caucasians suggests a founder effect and possible spread of the mutation by the migration of Neolithic farmers from the Middle East towards Europe and India, ten thousand years ago. This has been confirmed by haplotype analysis.

Sign in / Sign up

Export Citation Format

Share Document