Factor VLeiden and thrombophilia

Inactivation of human plasma alters the structure and biomechanical properties of engineered tissues

Fibrin is widely used for tissue engineering applications. The use of blood derivatives, however, carries a high risk of transmission of infectious agents, necessitating the application of pathogen reduction technology (PRT). The impact of this process on the structural and biomechanical properties of the final products is unknown. We used normal plasma (PLc) and plasma inactivated by riboflavin and ultraviolet light exposure (PLi) to manufacture nanostructured cellularized fibrin-agarose hydrogels (NFAHs), and then compared their structural and biomechanical properties. We also measured functional protein C, prothrombin time (PT), activated partial thromboplastin time (APTT), thrombin time (TT) and coagulation factors [fibrinogen, Factor (F) V, FVIII, FX, FXI, FXIII] in plasma samples before and after inactivation. The use of PLi to manufacture cellularized NFAHs increased the interfibrillar spacing and modified their biomechanical properties as compared with cellularized NFAH manufactured with PLc. PLi was also associated with a significant reduction in functional protein C, FV, FX, and FXI, and an increase in the international normalized ratio (derived from the PT), APTT, and TT. Our findings demonstrate that the use of PRT for fibrin-agarose bioartificial tissue manufacturing does not adequately preserve the structural and biomechanical properties of the product. Further investigations into PRT-induced changes are warranted to determine the applications of NFAH manufactured with inactivated plasma as a medicinal product.

Inactivation of human plasma alters the structure and biomechanical properties of engineered tissues

Fibrin is widely used for tissue engineering applications. The use of blood derivatives, however, carries a high risk of transmission of infectious agents, necessitating the application of pathogen reduction technology (PRT). The impact of this process on the structural and biomechanical properties of the final products is unknown. We used normal plasma (PLc) and plasma inactivated by riboflavin and ultraviolet light exposure (PLi) to manufacture nanostructured cellularized fibrin-agarose hydrogels (NFAHs), and then compared their structural and biomechanical properties. We also measured functional protein C, prothrombin time (PT), activated partial thromboplastin time (APTT), thrombin time (TT) and coagulation factors [fibrinogen, Factor (F) V, FVIII, FX, FXI, FXIII] in plasma samples before and after inactivation. The use of PLi to manufacture cellularized NFAHs increased the interfibrillar spacing and modified their biomechanical properties as compared with cellularized NFAH manufactured with PLc. PLi was also associated with a significant reduction in functional protein C, FV, FX, and FXI, and an increase in the international normalized ratio (derived from the PT), APTT, and TT. Our findings demonstrate that the use of PRT for fibrin-agarose bioartificial tissue manufacturing does not adequately preserve the structural and biomechanical properties of the product. Further investigations into PRT-induced changes are warranted to determine the applications of NFAH manufactured with inactivated plasma as a medicinal product.

Osteonecrosis of the Femoral Head in Patients with Hypercoagulability-From Pathophysiology to Therapeutic Implications

Osteonecrosis of the femoral head (ONFH) is a debilitating disease with major social and economic impacts. It frequently affects relatively young adults and has a predilection for rapid progression to femoral head collapse and end-stage hip arthritis. If not diagnosed and treated properly in the early stages, ONFH has devastating consequences and leads to mandatory total hip arthroplasty. The pathophysiology of non-traumatic ONFH is very complex and not fully understood. While multiple risk factors have been associated with secondary ONFH, there are still many cases in which a clear etiology cannot be established. Recognition of the prothrombotic state as part of the etiopathogeny of primary ONFH provides an opportunity for early medical intervention, with implications for both prophylaxis and therapy aimed at slowing or stopping the progression of the disease. Hereditary thrombophilia and hypofibrinolysis are associated with thrombotic occlusion of bone vessels. Anticoagulant treatment can change the natural course of the disease and improve patients' quality of life. The present work focused on highlighting the association between hereditary thrombophilia/hypofibrinolysis states and ONFH, emphasizing the importance of identifying this condition. We have also provided strong arguments to support the efficiency and safety of anticoagulant treatment in the early stages of the disease, encouraging etiological diagnosis and prompt therapeutic intervention. In the era of direct oral anticoagulants, new therapeutic options have become available, enabling better long-term compliance.

Factor VIII and Factor V Membrane Bound Complexes

The formation of membrane-bound complexes between specific coagulation factors at different cell surfaces is required for effective blood clotting. The most important of these complexes, the intrinsic Tenase and Prothrombinase complexes, are formed on the activated platelet surface during the propagation phase of coagulation. These two complexes are highly specific in their assembly mechanism and function modulated by anionic membranes, thus offering desirable targets for pharmaceutical interventions. Factor V (FV) and factor VIII (FVIII) are highly homologous non-enzymatic proteins. In their active state, FVa and FVIIIa serve as cofactors for the respective serine proteases factor Xa (FXa) and factor IXa (FIXa), significantly increasing their catalytic activity. This is achieved by forming well organized membrane-bound complexes at the phosphatidylserine rich activated platelet membrane in the presence of Ca²⁺ ions. The tenase (FVIIIa/FIXa) complex, catalyzes the proteolytic conversion of FX to FXa. Subsequently the prothrombinase (FVa/FXa) complex catalyzes the conversion of prothrombin to thrombin, required for efficient blood clotting. Although significant knowledge of FV and FVIII biochemistry and regulation has been achieved, the molecular mechanisms of their function are yet to be defined. Understanding the geometric assembly of the tenase and prothrombinase complexes is paramount in defining the structural basis of bleeding and thrombotic disorders. Such knowledge will enable the design of efficient pro- and anticoagulant therapies critical for regulating abnormal hemostasis. In this chapter, we will summarize the findings to date, showing our achievement in the field and outlining the future findings required to grasp the complexity of these proteins.

Laboratory assessment of Activated Protein C Resistance/Factor V-Leiden and performance characteristics of a new quantitative assay

Activated Protein C Resistance is mainly associated to a factor V mutation (RQ506), which induces a deficient inactivation of activated factor V by activated protein C, and is associated to an increased risk of venous and arterial thrombosis in affected individuals, caused by the prolonged activated factor V survival. Its prevalence is mainly in Caucasians (about 5%), and this mutation is absent in Africans and Asians. Presence of Factor V-Leiden is usually evidenced with clotting methods, using a two-step APTT assay performed without or with APC: prolongation of blood coagulation time is decreased if this factor is present. The R506Q Factor V-Leiden mutation is now usually characterized using molecular biology, and this technique tends to become the first intention assay for characterization of patients. Both techniques are qualitative, and allow classifying tested individuals as heterozygotes or homozygotes for the mutation, when present. A new quantitative assay for Factor V-Leiden, using a one-step clotting method, has been developed, and designed with highly purified human coagulation proteins. Clotting is triggered with human Factor Xa, in presence of calcium and phospholipids (mixture which favours APC action over clotting process). Diluted tested plasma, is supplemented with a clotting mixture containing human fibrinogen, prothrombin, and protein S at a constant concentration. APC is added, and clotting is initiated with calcium. Calibration is performed with a pool of plasmas from patients carrying the R506Q Factor V mutation, and its mixtures with normal plasma. Homozygous patients have clotting times of about <40sec; heterozygous patients have clotting times of about 40-60sec and normal individuals yield clotting times >70sec. Factor V-Leiden concentration is usually >75% in homozygous patients, 30-60% in heterozygous patients and below 5% in normal. The assay is insensitive to clotting factor deficiencies (II, VII, VIII: C, IX, X), dicoumarol or heparin therapies, and has no interference with lupus anticoagulant (LA). This new assay for Factor V-Leiden can be easily used in any coagulation laboratory, is performed as a single test, and is quantitative. This assay has a high robustness, is accurate and presents a good intra- (<3%) and inter-assay (<5%) variability. It contributes solving most of the laboratory issues faced when testing factor V-Leiden. Quantitation of Factor V-L could contribute to a better assessment of thrombotic risk in affected patients, as this complication is first associated to and caused by the presence of a defined amount of FVa.

Removal of B-domain sequences from factor V rather than specific proteolysis underlies the mechanism by which cofactor function is realized

Factor V, the precursor of factor Va, circulates in plasma with little or no procoagulant activity. Activity is generated following limited proteolysis indicating that the conversion of factor V to factor Va results in appropriate structural changes, which impart cofactor function. We have produced recombinant partial B-domain-truncated derivatives of factor V (FV(des811-1491) and FV(des811-1491) with Arg(709) and Arg(1545) mutated to Gln) to investigate whether discrete proteolysis within the B-domain followed by a conformational transition is responsible for activation. Direct binding fluorescence measurements as well as steady-state kinetic assays were employed to assess the ability of these factor V derivatives to assemble and function in prothrombinase. In contrast to human factor V, single-chain B-domain-truncated factor V bound to FXa membranes with an affinity that was identical to factor Va. Additionally, it was found that, once this modified derivative was assembled in prothrombinase, it functioned in an equivalent manner to factor Va. Taken together these data support the hypothesis that proteolysis within the B-domain of factor V, although necessary, is incidental to the mechanism by which cofactor function is realized. Instead, our results are more consistent with the interpretation that proteolytic activation of factor V simply eliminates steric and/or conformational constraints contributed by the B-domain that otherwise interfere with discrete binding interactions that govern the eventual function of factor Va.

Isolation and characterization of an antifactor V antibody causing activated protein C resistance from a patient with severe thrombotic manifestations

A 44-year-old woman with a history of severe thrombotic manifestations presented with a markedly reduced activated protein C-sensitivity ratio (APC-SR). DNA sequencing of and around the regions encoding the APC cleavage sites in the factor Va molecule excluded the presence of the factor VLeiden mutation and of other known genetic mutations. No antiphospholipid antibodies were present in the patient's plasma and both prothrombin time and activated partial thromboplastin time were normal. The total immunoglobulin fraction was isolated from the patient's plasma and found to induce severe APC resistance when added to normal plasma and to factor V-deficient plasma supplemented with increasing concentrations of factor V. Immunoblotting and immunoprecipitation experiments with the total immunoglobulin fraction purified from the patient's plasma demonstrated that the antibody recognizes factor V, is polyclonal, and has conformational epitopes on the entire factor V molecule (heavy and light chains, and B region). Thus, the immunoglobulin fraction interferes with the anticoagulant pathway involving factor V. The inhibitor was isolated by sequential affinity chromatography on protein G-Sepharose and factor V-Sepharose. The isolated immunoglobulin fraction inhibited factor Va inactivation by APC because of impaired cleavage at Arg306 and Arg506 of the heavy chain of the cofactor. The isolated immunoglobulin fraction was also found to inhibit the cofactor effect of factor V for the inactivation of factor VIII by the APC/protein S complex. Our data provide for the first time the demonstration of an antifactor V antibody not related to the presence of antiphospholipid antibodies, which is responsible for thrombotic rather than hemorrhagic symptoms.

A matrix-assisted laser desorption/ionization time-of-flight based method for screening the 1691G --> A mutation in the factor V gene

A point mutation, 1691 G --> A in the coagulation factor V gene results in an Arg506 --> Gln amino acid substitution in the factor V molecule. This mutation, defined as factor VLEIDEN, results in activated protein C (APC) resistance and is the most common genetic risk factor for familial thrombophilia. A new mini-sequencing method using matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry was developed for the screening of the 1691G --> A substitution in factor V. In this method, a fragment of genomic DNA containing the 1691st base is first amplified, followed by mini-sequencing in the presence of dGTP and ddATP, ddCTP, and ddTTP. In this manner, the primer is extended by one base from one allele and two bases from the other allele. The extended products are analyzed using MALDI-TOF mass spectrometry. The base at position 1691 is identified based on the number of nucleotides added. We have used this method to genotype 16 APC-resistant patients previously identified by conventional methods and 11 normal control samples. The genotypes of all samples were correctly identified. This method is accurate, fast, and potentially allows for simultaneous multiplex genotyping of a number of mutation sites associated with thrombophilia and clot formation.

Prevalence of factor V Leiden and prothrombin 20210 A variant in Bulgarian patients with pulmonary thromboembolism and deep venous thrombosis

Factor V Leiden mutation and prothrombin variant 20210 A are well-known risk factors for venous thrombosis (DVT). Recent papers have reported a lower prevalence of factor V Leiden in patients with pulmonary thromboembolism (PTE) than in patients with deep venous thrombosis. The aim of the present study was to compare the prevalence of factor V Leiden and the prothrombin 20210 G <-- A mutation in patients with DVT and in patients with PTE. We studied 128 consecutive patients (45 with DVT, 40 with PTE, and 43 with DVT and PTE) for factor V Leiden and prothrombin 20210 A. One hundred healthy persons matched by age and sex were used as controls. Factor V Leiden was present in five of the patients with PTE [12.5%; 95% confidence interval (CI), 1.5-23.5%; not significant], 15 of the patients with DVT (33.3%; 95% CI, 9.6-38.7%; P < 0.001), and 12 of the patients with DVT and PTE (27.9%; 95% CI, 4.8-33%; P = 0.001). Results for the prothrombin 20210 A mutation were as follows: four of 40 patients with PTE (10%; 95% CI, 0-13.3%; P = 0.46), nine of 45 (20%) of the patients with DVT (95% CI, 0.5-25.5%; P < 0.05) and eight of 43 with DVT and PTE were heterozygous (18.6%; 95% CI, 0-23.9%; P = 0.02). In conclusion, there is a significantly higher frequency of factor V Leiden among patients with DVT than in patients with PTE. However, there is no significant difference of factor V Leiden or 20210 A prothrombin mutation in patients with DVT than in patients with combined DVT/PTE, therefore patients with DVT, carriers of the mutations, do not appear to be at lower risk for pulmonary embolism.

Plasminogen activator inhibitor-1 4G/5G polymorphism in Turkish children with cerebral infarct and effect on factor V 1691 A mutation

The thrombotic risk of carrying plasminogen activator inhibitor-1-675 4G allele was found to be controversial in previous studies. The aim of this study was to evaluate the possible effect of plasminogen activator inhibitor-1 4G/5G polymorphism in the pathogenesis of childhood stroke. The case-control study included 43 patients with cerebral infarct who were below the age of 18 years (range, 10 months to 18 years) and 113 healthy unrelated individuals without family histories of thrombosis. Plasminogen activator inhibitor-1 4G/5G polymorphism was analyzed according to a previously described method. There was no statistically significant difference in patient and control groups for the distribution of plasminogen activator inhibitor-1 4G/5G polymorphism (P = .75) (allele frequency 4G controls: 0.50; patients: 0.53). However, there was a significant difference for the factor V (FV) 1691 A mutation for both groups (P = .0007).

Combinations of 4 mutations (FV R506Q, FV H1299R, FV Y1702C, PT 20210G/A) affecting the prothrombinase complex in a thrombophilic family

The study of the molecular bases of thrombophilia in a large family with 4 symptomatic members is reported. Three thrombophilic genetic components (FV R506Q, FV H1299R, and PT 20210G/A), all affecting the activity of the prothrombinase complex, were detected alone and in combination in various family members. In addition, a newly identified missense mutation (factor V [FV] Y1702C), causing FV deficiency, was also present in the family and appeared to enhance activated protein C (APC) resistance in carriers of FV R506Q or FV H1299R by abolishing the expression of the counterpart FV allele. The relationships between complex genotypes, coagulation laboratory findings, and clinical phenotypes were analyzed in the family. All symptomatic family members were carriers of combined defects and showed APC resistance and elevated F1 + 2 values. Evidence for the causative role of the FV Y1702C mutation, which affects a residue absolutely conserved in all 3 A domains of FV, factor VIII, and ceruloplasmin, relies on (1) the absolute cosegregation between the mutation and FV deficiency, both in the family and in the general population; (2) FV antigen and immunoblot studies indicating the absence of Y1702C FV molecules in plasma of carriers of the mutation, despite normal levels of the FV Y1702C messenger RNA; and (3) molecular modeling data that support a crucial role of the mutated residue in the A domain structure. These findings help to interpret the variable penetrance of thrombosis in thrombophilic families and to define the molecular bases of FV deficiency.

Combinations of 4 mutations (FV R506Q, FV H1299R, FV Y1702C, PT 20210G/A) affecting the prothrombinase complex in a thrombophilic family

The study of the molecular bases of thrombophilia in a large family with 4 symptomatic members is reported. Three thrombophilic genetic components (FV R506Q, FV H1299R, and PT 20210G/A), all affecting the activity of the prothrombinase complex, were detected alone and in combination in various family members. In addition, a newly identified missense mutation (factor V [FV] Y1702C), causing FV deficiency, was also present in the family and appeared to enhance activated protein C (APC) resistance in carriers of FV R506Q or FV H1299R by abolishing the expression of the counterpart FV allele. The relationships between complex genotypes, coagulation laboratory findings, and clinical phenotypes were analyzed in the family. All symptomatic family members were carriers of combined defects and showed APC resistance and elevated F1 + 2 values. Evidence for the causative role of the FV Y1702C mutation, which affects a residue absolutely conserved in all 3 A domains of FV, factor VIII, and ceruloplasmin, relies on (1) the absolute cosegregation between the mutation and FV deficiency, both in the family and in the general population; (2) FV antigen and immunoblot studies indicating the absence of Y1702C FV molecules in plasma of carriers of the mutation, despite normal levels of the FV Y1702C messenger RNA; and (3) molecular modeling data that support a crucial role of the mutated residue in the A domain structure. These findings help to interpret the variable penetrance of thrombosis in thrombophilic families and to define the molecular bases of FV deficiency.

The autolysis loop of activated protein C interacts with factor Va and differentiates between the Arg506 and Arg306 cleavage sites

The anticoagulant human plasma serine protease, activated protein C (APC), inactivates blood coagulation factors Va (FVa) and VIIIa. The so-called autolysis loop of APC (residues 301-316, equivalent to chymotrypsin [CHT] residues 142-153) has been hypothesized to bind FVa. In this study, site-directed mutagenesis was used to probe the role of the charged residues in this loop in interactions between APC and FVa. Residues Arg306 (147 CHT), Glu307, Lys308, Glu309, Lys311, Arg312, and Arg314 were each individually, or in selected combinations, mutated to Ala. The purified recombinant protein C mutants were characterized using activated partial thromboplastin time (APTT) clotting assays and FVa inactivation assays. Mutants 306A, 308A, 311A, 312A, and 314A had mildly reduced anticoagulant activity. Based on FVa inactivation assays and APTT assays using purified Gln506-FVa and plasma containing Gln506-FV, it appeared that these mutants were primarily impaired for cleavage of FVa at Arg506. Studies of the quadruple APC mutant (306A, 311A, 312A, and 314A) suggested that the autolysis loop provides for up to 15-fold discrimination of the Arg506 cleavage site relative to the Arg306 cleavage site. This study shows that the loop on APC of residues 306 to 314 defines an FVa binding site and accounts for much of the difference in cleavage rates at the 2 major cleavage sites in FVa.

The autolysis loop of activated protein C interacts with factor Va and differentiates between the Arg506 and Arg306 cleavage sites

The anticoagulant human plasma serine protease, activated protein C (APC), inactivates blood coagulation factors Va (FVa) and VIIIa. The so-called autolysis loop of APC (residues 301-316, equivalent to chymotrypsin [CHT] residues 142-153) has been hypothesized to bind FVa. In this study, site-directed mutagenesis was used to probe the role of the charged residues in this loop in interactions between APC and FVa. Residues Arg306 (147 CHT), Glu307, Lys308, Glu309, Lys311, Arg312, and Arg314 were each individually, or in selected combinations, mutated to Ala. The purified recombinant protein C mutants were characterized using activated partial thromboplastin time (APTT) clotting assays and FVa inactivation assays. Mutants 306A, 308A, 311A, 312A, and 314A had mildly reduced anticoagulant activity. Based on FVa inactivation assays and APTT assays using purified Gln506-FVa and plasma containing Gln506-FV, it appeared that these mutants were primarily impaired for cleavage of FVa at Arg506. Studies of the quadruple APC mutant (306A, 311A, 312A, and 314A) suggested that the autolysis loop provides for up to 15-fold discrimination of the Arg506 cleavage site relative to the Arg306 cleavage site. This study shows that the loop on APC of residues 306 to 314 defines an FVa binding site and accounts for much of the difference in cleavage rates at the 2 major cleavage sites in FVa.

Association of the R485K polymorphism of the factor V gene with poor response to activated protein C and increased risk of coronary artery disease in the Chinese population

Inherited predisposition to thrombosis contributes to the initiation and progression of coronary artery disease (CAD). The present study was designed to explore the relationship between genetic variation of coagulation factor V and occurrence of CAD. A total of 141 unrelated patients with CAD and 175 healthy controls were analyzed by polymerase chain reaction-denaturing gradient gel electrophoresis (PCR-DGGE) for variation detection in all 25 exons of the factor V gene. Among the study subjects, 55 CAD patients and 73 controls were evaluated at random for response to activated protein C (APC) by Coatest APC resistance test. Polymorphisms in exon 4, 10, 13 and 16 of factor V gene were documented [642G-->T(S156), 1628--> A(R485K), 4070A-->G(H1299R) and 5380G A(V1736M), respectively]. The study also identified a novel polymorphism 327A G in exon 2 which did not alter the amino acid residue. Leiden mutation (R506Q) was not detected in any of our 316 subjects. Among the five polymorphisms, the allele frequency of 1628G--> A was significantly different between the CAD patients and the controls (0.36 vs. 0.21, p < 0.05). Subjects homozygous or heterozygous for the A allele of 1628G-->A polymorphism had lower normalized APC ratios than those with the GG genotype in the CAD group (1.16+/-0.13 and 1.18+/-0.23 vs. 1.36+/-0.33, p <0.05) and in the controls, indicating that A(1628) allele was associated with a poor response to APC. We conclude that the 1628G-->A (R485K) polymorphism of factor V is associated with a poor response to APC and increased risk for CAD.

Models of blood coagulation

We have used three models to study the process of tissue factor-initiated blood coagulation. These are: synthetic 'plasma' mixtures prepared with the proteins and membranes involved in the reaction and its regulation; mathematical models based on the reaction kinetics, binding constants and stoichiometries of individual procoagulant and inhibitor reactions, and contact pathway-inhibited coagulation of minimally altered whole blood in vitro. In all of these models, the procoagulant process may be divided into two phases: an initiation phase and a propagation phase. The initiation phase is characterized by the appearance of thrombin and other coagulation enzymes, and the activation of pro-cofactors V and VIII. The propagation phase is characterized by explosive and extensive prothrombin activation. During normal blood coagulation, the bulk of thrombin generation occurs after clot formation, while most release of fibrinopeptide A is observed just at the conclusion of the initiation phase. In the case of haemophilia A and B, the initiation phase is slightly extended, while thrombin generation during the propagation phase is significantly suppressed. The clot time, as well as fibrinopeptide release, is delayed in these patients. Data obtained in our laboratory, employing the above models, indicate that they are efficient tools for blood coagulation studies.

Effect of plasminogen activator inhibitor-1 4G/5G polymorphism in Turkish deep vein thrombotic patients with and without FV1691 G-A

A decreased fibrinolytic activity due to increased levels of plasminogen activator inhibitor-1 has been shown in deep vein thrombosis patients. Elevated plasma plasminogen activator inhibitor-1 levels are associated with the 4G allele of a 4G/5G polymorphism located in the promoter region of the plasminogen activator inhibitor-1 gene. Because there is no existing data in the Turkish population, we aimed to study these mutations in patients with deep vein thrombosis (n = 136) and normal controls (n = 113), consecutively selected among unrelated healthy subjects without personal and familial history of atherothrombosis from Ankara, Turkey. DNA was extracted by conventional methods, and polymerase chain reaction of the plasminogen activator inhibitor-1 4G/5G polymorphism was performed according to a previously described method. Genotype distributions of FV 1691G-A and plasminogen activator inhibitor-1 4G/5G are as follows: plasminogen activator inhibitor-1 4G (patients) 0.562, plasminogen activator inhibitor-1 4G (controls) 0.50 (p = 0.6); FV1691A (patients) 0.147, FV1691A (controls) 0.035 (p = 0.005). Our data indicated that plasminogen activator inhibitor-1 4G/5G does not have an effect on the thrombotic risk. Carrying the 4G allele either in heterozygous or homozygous state increases the risk in the presence of FV1691A (odds ratio: 9.8 and 6.9, confidence interval 95% 2.9-32.7 and 1.3-35.8). FV1691A is an independent risk factor for thrombosis (odds ratio: 5.5, confidence interval: 95% 2.5-12.1). We concluded that coexistence of FV1691A and plasminogen activator inhibitor-1 4G allele leads to an increased risk for thrombosis leading a further evidence to another prothrombotic factor that may be necessary for the development of a manifest thrombotic event.

A multilocus genotyping assay for candidate markers of cardiovascular disease risk

A number of chronic diseases, including cardiovascular disease, appear to have a multifactorial genetic risk component. Consequently, techniques are needed to facilitate evaluation of complex genetic risk factors in large cohorts. We have designed a prototype assay for genotyping a panel of 35 biallelic sites that represent variation within 15 genes from biochemical pathways implicated in the development and progression of cardiovascular disease. Each DNA sample is amplified using two multiplex polymerase chain reactions, and the alleles are genotyped simultaneously using an array of immobilized, sequence-specific oligonucleotide probes. This multilocus assay was applied to two types of cohorts. Population frequencies for the markers were estimated using 496 unrelated individuals from a family-based cohort, and the observed values were consistent with previous reports. Linkage disequilibrium between consecutive pairs of markers within the apoCIII, LPL, and ELAM genes was also estimated. A preliminary analysis of single and pairwise locus associations with severity of atherosclerosis was performed using a composite cohort of 142 individuals for whom quantitative angiography data were available; evaluation of the potentially interesting associations observed will require analysis of an independent and larger cohort. This assay format provides a research tool for studies of multilocus genetic risk factors in large cardiovascular disease cohorts, and for the subsequent development of diagnostic tests.

Secretable Human Platelet-Derived Factor V Originates From the Plasma Pool

Factor Va (FVa), derived from plasma or released from stimulated platelets, is the essential protein cofactor of the prothrombinase complex. Plasma-derived factor V (FV) is synthesized by the liver, whereas the source of the platelet-derived cofactor has not been unambiguously identified. Megakaryocytes, platelet precursors, are known to synthesize platelet proteins and to endocytose proteins from plasma (ie, fibrinogen) and then package these proteins into -granules. To determine which mechanism accounts for FV presence in platelets, two patients heterozygous for FVLeiden who underwent allogeneic transplantation from homozygous FV wild-type donors (bone marrow [BM] or liver) were studied. Patient JMW, whose skin biopsy specimen showed heterozygous FVLeiden, received a BM transplant from a wild-type homozygous FV donor as analyzed from posttransplant peripheral blood cells. Patient FW, whose native liver is heterozygous for FVLeiden, received a homozygous wild-type FV liver. Because each individual has two distinct genetic pools of factor V in liver and megakaryocytes, it was possible to determine whether secretable platelet-derived FV was normal or contained the FVLeiden mutation. Platelet-derived FVa released from thrombin-activated platelets from a normal individual, an individual heterozygous for the FVLeiden mutation, and the two patients was incubated with phospholipid vesicles and activated protein C (APC). Western blotting analyses using a monoclonal antibody that allows distinction between platelet-derived FVa and FVaLeiden subsequent to APC-catalyzed cleavage were then performed. Based on the accumulation of proteolytic fragments derived from APC-induced cleavage, analyses of platelet-derived FVa from JMW demonstrated both normal FVa and FVaLeiden consistent with a plasma-derived origin of the secretable platelet-derived FVa. Western blotting analyses of the APC-cleaved platelet-derived FVa from FW showed a wild-type phenotype, despite the presence of a FVLeiden allele in her megakaryocyte genome, also consistent with a plasma origin of her secretable platelet-derived FVa. Platelets do not appear to endocytose the plasma cofactor, because a 35-hour incubation of platelet-rich plasma with 125I-factor V showed no specific association/uptake of the radiolabeled ligand with the platelet pellet. Collectively, these results show for the first time that the majority of secretable platelet-derived factor V is endocytosed by megakaryocytes from plasma and is not exclusively synthesized by these cells, as previously believed.

© 1998 by The American Society of Hematology.

Secretable Human Platelet-Derived Factor V Originates From the Plasma Pool

Factor Va (FVa), derived from plasma or released from stimulated platelets, is the essential protein cofactor of the prothrombinase complex. Plasma-derived factor V (FV) is synthesized by the liver, whereas the source of the platelet-derived cofactor has not been unambiguously identified. Megakaryocytes, platelet precursors, are known to synthesize platelet proteins and to endocytose proteins from plasma (ie, fibrinogen) and then package these proteins into -granules. To determine which mechanism accounts for FV presence in platelets, two patients heterozygous for FVLeiden who underwent allogeneic transplantation from homozygous FV wild-type donors (bone marrow [BM] or liver) were studied. Patient JMW, whose skin biopsy specimen showed heterozygous FVLeiden, received a BM transplant from a wild-type homozygous FV donor as analyzed from posttransplant peripheral blood cells. Patient FW, whose native liver is heterozygous for FVLeiden, received a homozygous wild-type FV liver. Because each individual has two distinct genetic pools of factor V in liver and megakaryocytes, it was possible to determine whether secretable platelet-derived FV was normal or contained the FVLeiden mutation. Platelet-derived FVa released from thrombin-activated platelets from a normal individual, an individual heterozygous for the FVLeiden mutation, and the two patients was incubated with phospholipid vesicles and activated protein C (APC). Western blotting analyses using a monoclonal antibody that allows distinction between platelet-derived FVa and FVaLeiden subsequent to APC-catalyzed cleavage were then performed. Based on the accumulation of proteolytic fragments derived from APC-induced cleavage, analyses of platelet-derived FVa from JMW demonstrated both normal FVa and FVaLeiden consistent with a plasma-derived origin of the secretable platelet-derived FVa. Western blotting analyses of the APC-cleaved platelet-derived FVa from FW showed a wild-type phenotype, despite the presence of a FVLeiden allele in her megakaryocyte genome, also consistent with a plasma origin of her secretable platelet-derived FVa. Platelets do not appear to endocytose the plasma cofactor, because a 35-hour incubation of platelet-rich plasma with 125I-factor V showed no specific association/uptake of the radiolabeled ligand with the platelet pellet. Collectively, these results show for the first time that the majority of secretable platelet-derived factor V is endocytosed by megakaryocytes from plasma and is not exclusively synthesized by these cells, as previously believed.

© 1998 by The American Society of Hematology.

Platelet-Derived Factor Va/VaLeiden Cofactor Activities Are Sustained on the Surface of Activated Platelets Despite the Presence of Activated Protein C

We investigated the role of the thrombin-activated platelet in modulating the rate and extent of activated protein C (APC)-catalyzed inactivation of platelet-derived factor Va and factor VaLeiden. Platelet-derived factor Va and factor VaLeiden were inactivated by APC at near identical rates; however, complete inactivation of the cofactors was never achieved. Greater residual cofactor activity remained when using thrombin-activated platelets compared with that observed with synthetic phospholipid vesicles and platelet-derived microparticles, suggesting that thrombin-activated platelets protect the cofactors from APC-catalyzed inactivation. This apparent protection was not due to (1) an insufficient number of membrane binding sites for APC or factor Va; (2) the destruction of these sites; or (3) the presence of a platelet-associated APC inhibitor. Results from a plasma-based clotting assay (with or without APC) with platelets or PCPS vesicles added to induce clot formation indicated that, even in the presence of high concentrations of APC, platelets offered protection of the cofactor by delaying cleavage at Arg506. This resulted in incomplete proteolysis of the heavy chain, suggesting that platelets can also protect plasma-derived factor Va from APC-catalyzed inactivation. However, additional experiments indicated that the plasma-derived cofactor, bound to thrombin-activated platelets, was completely inactivated by APC, suggesting that the plasma and platelet-derived cofactor pools represent different substrates for APC. Collectively, these results indicate that platelets sustain procoagulant events by providing a membrane surface that delays cofactor inactivation and by releasing a cofactor molecule that displays an APC resistant phenotype. Thus, at sites of arterial injury, the factor VLeidenmutation may not as readily predict arterial thrombosis, because the normal and variant platelet-derived cofactors are equally resistant to APC at the activated platelet surface.

Activated protein C resistance: What have we learned now that the dust has settled?

Activated protein C resistance, most often caused by a single point mutation in the factor V gene, is the most common hereditary coagulation abnormality associated with venous thrombosis. Recent studies have established risk estimates of thrombosis in multiple clinical settings. The impact of activated protein C resistance on the absolute thrombotic risk of a given individual is significantly influenced by the presence or absence of other acquired or congenital risk factors. In this paper, the complex interplay between different risk factors for venous thrombosis is discussed. Additionally, the potential significance for arterial thrombosis of activated protein C resistance, that is not due to the genetic variant, Glutamine 506 factor V, is discussed.

The effect of Arg306-->Ala and Arg506-->Gln substitutions in the inactivation of recombinant human factor Va by activated protein C and protein S

Factor Va (fVa) is inactivated by activated protein C (APC) by cleavage of the heavy chain at Arg306, Arg506, and Arg679. Site-directed mutagenesis of human factor V cDNA was used to substitute Arg306-->Ala (rfVa306A) and Arg506-->Gln (rfVa506Q). Both the single and double mutants (rfVa306A/506Q) were constructed. The activation of these procofactors by alpha-thrombin and their inactivation by APC were assessed in coagulation assays using factor V-deficient plasma. All recombinant and wild-type proteins had similar initial cofactor activity and identical activation products (a factor Va molecule composed of light and heavy chains). Inactivation of factor Va purified from human plasma (fVaPLASMA) in HBS Ca2+ +0.5% BSA or in conditioned media by APC in the presence of phospholipid vesicles resulted in identical inactivation profiles and displayed identical cleavage patterns. Recombinant wild-type factor Va (rfVaWT) was inactivated by APC in the presence of phospholipid vesicles at an overall rate slower than fVaPLASMA. The rfVa306A and rfVa506Q mutants were each inactivated at rates slower than rfVaWT and fVaPLASMA. Following a 90-min incubation with APC, rfVa306A and rfVa506Q retain approximately 30-40% of the initial cofactor activity. The double mutant, rfVa306A/506Q, was completely resistant to cleavage and inactivation by APC retaining 100% of the initial cofactor activity following a 90-min incubation in the presence of APC. Recombinant fVaWT, rfVa306A, rfVa506Q, and rfVa306A/506Q were also used to evaluate the effect of protein S on the individual cleavage sites of the cofactor by APC. The initial rates of rfVaWT and rfVa306A inactivation in the presence of protein S were unchanged, indicating cleavage at Arg506 is not affected by protein S. The initial rate of rfVa506Q inactivation was increased, suggesting protein S slightly accelerates the cleavage at Arg306. Overall, the data demonstrate high specificity with respect to cleavage sites for APC on factor Va and demonstrate that cleavages of the cofactor at both Arg306 and Arg506 are required for efficient factor Va inactivation.