Multimodal measurement of glycocalyx degradation during coronary artery bypass grafting.

Background: Glycocalyx shedding and subsequent endothelial dysfunction occur in many conditions, such as in sepsis, in critical illness, and during major surgery such as in coronary artery bypass grafting (CABG) where it has been shown to associate with organ dysfunction. Hitherto, there is no consensus about the golden standard in measuring glycocalyx properties in humans. The objective of this study was to compare different indices of glycocalyx shedding and dysfunction. To this end, we studied patients undergoing elective CABG surgery, which is a known cause of glycocalyx shedding. Materials and methods: Sublingual glycocalyx thickness was measured in 23 patients by: 1) determining the perfused boundary region (PBR)-an inverse measure of glycocalyx thickness-by means of sidestream dark field imaging technique. This is stated double, 2) measuring plasma levels of the glycocalyx shedding products syndecan-1, hyaluronan, and heparan sulfate and 3) measuring plasma markers of impaired glycocalyx function and endothelial activation (Ang-2, Tie-2, E-selectin, and thrombomodulin). Measurements were performed directly after induction, directly after onset of cardiopulmonary bypass (CPB), and directly after cessation of CPB. We assessed changes over time as well as correlations between the various markers. Results: The PBR increased from 1.81 ± 0.21 µm after induction of anesthesia to 2.27 ± 0.25 µm (p < 0.0001) directly after CPB was initiated and did not change further during CPB. A similar pattern was seen for syndecan-1, hyaluronan, heparan sulfate, Ang-2, Tie-2, and thrombomodulin. E-selectin levels also increased between induction and the start of CPB and increased further during CPB. The PBR correlated moderately with heparan sulfate, E-selectin, and thrombomodulin and weakly with Syndecan-1, hyaluronan, and Tie-2. Shedding markers syndecan-1 and hyaluronan correlated with all functional markers. Shedding marker heparan sulfate only correlated with Tie-2, thrombomodulin, and E-selectin. Thrombomodulin correlated with all shedding markers. Conclusion: Our results show that glycocalyx thinning, illustrated by increased sublingual PBR and increased levels of shedding markers, is paralleled with impaired glycocalyx function and increased endothelial activation in CABG surgery with CPB. As correlations between different markers were limited, no single marker could be identified to represent the glycocalyx in its full complexity.

Two Novel Mutations in the SLC25A4 Gene in a Patient with Mitochondrial Myopathy.

In a 28-year-old male with a mild mitochondrial myopathy manifesting as exercise intolerance and early signs of cardiomyopathy without muscle weakness or ophthalmoplegia, we identified two novel mutations in the SLC25A4 gene: c.707G>C in exon 3 (p.(R236P)) and c.116_137del in exon 2 (p.(Q39Lfs*14)). Serum lactate levels at rest were elevated (12.7 mM). Both the patient's father and brother were heterozygous carriers of the c.707G>C mutation and were asymptomatic. The second mutation causes a 22 bp deletion leading to a frame shift likely giving rise to a premature stop codon and nonsense-mediated decay (NMD). The segregation of the mutations could not be tested directly as the mother had died before. However, indirect evidence from NMD experiments showed that the two mutations were situated on two different alleles in the patient. This case is unique compared to other previously reported patients with either progressive external ophthalmoplegia (PEO) or clear hypertrophic cardiomyopathy with exercise intolerance and/or muscle weakness carrying recessive mutations leading to a complete absence of the SLC25A4 protein. Most likely in our patient, although severely reduced, SLC25A4 is still partially present and functional.

Blocking CD40-TRAF6 interactions by small-molecule inhibitor 6860766 ameliorates the complications of diet-induced obesity in mice.

BACKGROUND: Immune processes contribute to the development of obesity and its complications, such as insulin resistance, type 2 diabetes mellitus and cardiovascular disease. Approaches that target the inflammatory response are promising therapeutic strategies for obesity. In this context, we recently demonstrated that the interaction between the costimulatory protein CD40 and its downstream adaptor protein tumor necrosis factor receptor-associated factor 6 (TRAF6) promotes adipose tissue inflammation, insulin resistance and hepatic steatosis in mice in the course of diet-induced obesity (DIO). METHODS: Here we evaluated the effects of a small-molecule inhibitor (SMI) of the CD40-TRAF6 interaction, SMI 6860766, on the development of obesity and its complications in mice that were subjected to DIO. RESULTS: Treatment with SMI 6860766 did not result in differences in weight gain, but improved glucose tolerance. Moreover, SMI 6860766 treatment reduced the amount of CD45(+) leucocytes in the epididymal adipose tissue by 69%. Especially, the number of adipose tissue CD4(+) and CD8(+) T cells, as well as macrophages, was significantly decreased. CONCLUSIONS: Our results indicate that small-molecule-mediated inhibition of the CD40-TRAF6 interaction is a promising therapeutic strategy for the treatment of metabolic complications of obesity by improving glucose tolerance, by reducing the accumulation of immune cells to the adipose tissue and by skewing of the immune response towards a more anti-inflammatory profile.

Factor Va alternative conformation reconstruction using atomic force microscopy.

Protein conformational variability (or dynamics) for large macromolecules and its implication for their biological function attracts more and more attention. Collective motions of domains increase the ability of a protein to bind to partner molecules. Using atomic force microscopy (AFM) topographic images, it is possible to take snapshots of large multi-component macromolecules at the single molecule level and to reconstruct complete molecular conformations. Here, we report the application of a reconstruction protocol, named AFM-assembly, to characterise the conformational variability of the two C domains of human coagulation factor Va (FVa). Using AFM topographic surfaces obtained in liquid environment, it is shown that the angle between C1 and C2 domains of FVa can vary between 40° and 166°. Such dynamical variation in C1 and C2 domain arrangement may have important implications regarding the binding of FVa to phospholipid membranes.

Factor IX mutants with enhanced catalytic activity.

BACKGROUND: Activated coagulation factor IX (FIXa) has low catalytic activity towards its physiologic substrate FX when activated FVIII (FVIIIa) is absent. One reason for this is that the FIX surface loop 99 stabilizes FIXa in a conformation that limits access of FX to the active site. OBJECTIVES: To investigate the effect of mutations in loop 99 and in the active site on FIXa activity with and without FVIIIa. METHODS: Five full-length FIX mutants with amino acid exchanges in the catalytic domain of FIX were constructed and characterized by measuring their activity in FX activation in model systems and in plasma. RESULTS AND CONCLUSIONS: The mutants showed no or marginally improved catalytic properties in FX activation by the intrinsic tenase complex (FIXa-FVIIIa-Ca(2+)-phospholipid). The combination of mutations Y94F and K98T hardly affected FX activation in the presence of FVIIIa, but yielded a FIX molecule that, in FIX-depleted plasma, had approximately 2.5-fold higher clotting activity and approximately 3.5-fold higher activity in a thrombin generation assay than plasma-derived FIX (pdFIX). Two FIXa mutants had considerably increased activities towards FX in the absence of FVIIIa. FIXa-Y94F/K98T/Y177F/I213V/E219G (FIXa-L) and FIXa-Y94F/A95aK/K98T/Y177F/I213V/E219G (FIXa-M) activated FX with catalytic efficiencies (k(cat)/K(m)) that, as compared with activated pdFIX, were increased 17-fold and six-fold, respectively. However, in plasma, their zymogen forms performed similarly to pdFIX. This indicates that the introduced mutations not only affected the activity of FIXa but may have also influenced the lifetime of the activated mutant molecules in plasma by modifying their activation and/or inhibition rates.

Defining the structure of membrane-bound human blood coagulation factor Va.

BACKGROUND: Blood coagulation factor (F) Va is the essential protein cofactor to the serine protease FXa. Factor Va stimulates the thrombin-to-prothrombin conversion by the prothrombinase complex, by at least five orders of magnitude. Factor Va binds with very high affinity to phosphatidylserine containing phospholipid membranes, which allows the visualization of its membrane-bound state by transmission electron microscopy (EM). METHODS: In this paper we present an averaged three-dimensional structure of FVa molecules attached to phosphatidylserine containing lipid tubes, as determined by EM and single particle analysis. The low-resolution FVa three-dimensional structure is compared with the available atomic models for FVa. RESULTS: The experimental data are combined with the most suitable atomic model and a membrane-bound FVaEM model is proposed that best fits the protein density defined by EM. In the FVaEM model, the C1 and C2 membrane-binding domains are juxtaposed onto the membrane surface and the model geometries indicate a deeper insertion of both C domains into the lipid bilayer than has been previously suggested. CONCLUSION: The present structure is a first step towards a higher-resolution experimental structure of a human FVa molecule in its membrane-bound conformation, allowing the visualization of individual domains within FVa and its association with the membrane.

Theoretical and experimental study of the D2194G mutation in the C2 domain of coagulation factor V.

Coagulation factor V (FV) is a large plasma glycoprotein with functions in both the pro- and anticoagulant pathways. In carriers of the so-called R2-FV haplotype, the FV D2194G mutation, in the C2 membrane-binding domain, is associated with low expression levels, suggesting a potential folding/stability problem. To analyze the molecular mechanisms potentially responsible for this in vitro phenotype, we used molecular dynamics (MD) and continuum electrostatic calculations. Implicit solvent simulations were performed on the x-ray structure of the wild-type C2 domain and on a model of the D2194G mutant. Because D2194 is located next to a disulfide bond (S-S bond), MD calculations were also performed on S-S bond depleted structures. D2194 is part of a salt-bridge network and investigations of the stabilizing/destabilizing role of these ionic interactions were carried out. Five mutant FV molecules were created and the expression levels measured with the aim of assessing the tolerance to amino acid changes in this region of molecule. Analysis of the MD trajectories indicated increased flexibility in some areas and energetic comparisons suggested overall destabilization of the structure due to the D2194G mutation. This substitution causes electrostatic destabilization of the domain by approximately 3 kcal/mol. Together these effects likely explain the lowered expression levels in R2-FV carriers.

Secondary substrate-binding exosite in the serine protease domain of activated protein C important for cleavage at Arg-506 but not at Arg-306 in factor Va.

Proteolytic inactivation of activated factor V (FVa) by activated protein C (APC) is a key reaction in the regulation of hemostasis. We now demonstrate the importance of a positive cluster in loop 37 of the serine protease (SP) domain of APC for the degradation of FVa. Lysine residues in APC at positions 37, 38, and 39 form a secondary binding site for FVa, which is important for cleavage of FVa at Arg-506 while having no effect on Arg-306 cleavage. In contrast, topological neighbors Lys-62, Lys-63, and Arg-74 in APC appear of minor importance in FVa degradation. This demonstrates that secondary binding exosites of APC specifically guide the proteolytic action of APC, resulting in a more favorable degradation of the 506-507 peptide bond as compared with the 306-307 bond.

The second laminin G-type domain of protein S is indispensable for expression of full cofactor activity in activated protein C-catalysed inactivation of factor Va and factor VIIIa.

Vitamin K-dependent protein S is a cofactor to the anticoagulant serine protease activated protein C (APC) in the proteolytic inactivation of the procoagulant, activated factor V (FVa) and factor VIII (FVIIIa). In the FVa degradation, protein S selectively accelerates the cleavage at Arg306, having no effect on the Arg506 cleavage. In the FVIIIa inactivation, the APC-cofactor activity of protein S is synergistically potentiated by FV, which thus has the capacity to function both as a pro- and an anticoagulant protein. The SHBG-like region of protein S, containing two laminin G-type domains, is required for the combined action of protein S and FV. To elucidate whether both G domains in protein S are needed for expression of APC-cofactor activities, chimeras of human protein S were created in which the individual G domains were replaced by the corresponding domain of the homologous Gas6, which in itself has no anticoagulant activity. In a plasma-based assay, chimera I (G1 from Gas6) was as efficient as wild-type recombinant protein S, whereas chimera II (G2 from Gas6) was less effective. The synergistic cofactor activity with FV in the inactivation of FVIIIa was lost by the replacement of the G2 domain in protein S (chimera II). However, chimera I did not exert full APC-cofactor activity in the FVIIa degradation, indicating involvement of both G domains or the entire SHBG-like region in this reaction. Chimera I was fully active in the degradation of FVa in contrast to chimera II, which exhibited reduced cofactor activity compared to protein S. In conclusion, by using protein S-Gas6 chimeric proteins, we have identified the G2 domain of protein S to be indispensable for an efficient inactivation of both FVIIa and FVa, whereas the G1 domain was found not to be of direct importance in the FVa-inactivation experiments.

Mutations in a potential phospholipid binding loop in the C2 domain of factor V affecting the assembly of the prothrombinase complex.

Activated factor V (FVa) serves as a cofactor to activated factor X in the prothrombinase complex. FVa is homologous to activated factor VIII (FVIIIa), the light chains of both proteins being formed by similar domains (A3-C1-C2). Interaction of FVa and FVIIIa with negatively charged phospholipid membranes is crucial for the function of both cofactors. In both proteins, the C2 domains are important for membrane binding but a detailed understanding of the binding mechanisms is missing. Recently, knowledge has been gained into the three-dimensional structures of the C domains facilitating studies of structure-function relationships. Structural analysis of the C2 domain in FVa predicted a surface-exposed loop (K2060, K2061, S2062, W2063, W2064) to be involved in membrane binding. Three double mutants were created, K2060Q-K2061Q, W2063Y-W2064Y and W2063A-W2064A, and expressed in a transient expression system. In addition, a FV variant in which all four residues were mutated, K2060Q-K2061Q-W2063A-W2064A, was produced. Mutagenesis of the two lysines showed no functional consequences, whereas mutagenesis of the two tryptophanes yielded FVa with impaired ability to interact with the phospholipid, as demonstrated by a poor functional activity at limiting phospholipid concentrations. A molecular model of FVa, anchored at the surface of a phospholipid membrane, was developed and used as a template for the interpretation of the mutagenesis experiments.

Partial glycosylation of Asn2181 in human factor V as a cause of molecular and functional heterogeneity. Modulation of glycosylation efficiency by mutagenesis of the consensus sequence for N-linked glycosylation.

Coagulation factor V (FV) circulates in two forms, FV1 and FV2, having slightly different molecular masses and phospholipid-binding properties. The aim was to determine whether this heterogeneity is due to the degree of glycosylation of Asn(2181). FVa1 and FVa2 were isolated and digested with endoglycosidase PNGase F. As judged by Western blotting, the FVa2 light chain contained two N-linked carbohydrates, whereas FVa1 contained three. Wild-type FV and three mutants, Asn(2181)Gln, Ser(2183)Thr, and Ser(2183)Ala, were expressed in COS1 cells, activated by thrombin, and analyzed by Western blotting. Wild-type FVa contained the 71 kDa-74 kDa doublet, whereas the Asn(2181)Gln and Ser(2183)Ala mutants contained only the 71 kDa light chain. In contrast, the Ser(2183)Thr mutant gave a 74 kDa light chain. This demonstrated that the third position in the Asn-X-Ser/Thr consensus affects glycosylation efficiency, Thr being associated with a higher degree of glycosylation than Ser. The Ser(2183)Thr mutant FVa was functionally indistinguishable from plasma-purified FVa1, whereas Asn(2181)Gln and Ser(2183)Ala mutants behaved like FVa2. Thus, the carbohydrate at Asn(2181) impaired the interaction between FVa and the phospholipid membrane, an interpretation consistent with a structural analysis of a three-dimensional model of the C2 domain and the position of a proposed phospholipid-binding site. In conclusion, we show that the FV1-FV2 heterogeneity is caused by differential glycosylation of Asn(2181) related to the presence of a Ser rather than a Thr at the third position in the consensus sequence of glycosylation.

Acquired APC resistance and oral contraceptives: differences between two functional tests.

Resistance to activated protein C (APC) is often associated with a mutation in factor V (factor VLeiden). Individuals without factor VLeiden who exhibit a response in functional APC-resistance tests similar to that of carriers of factor VLeiden are considered to be acquired APC resistant. This phenomenon is particularly observed in women using oral contraceptives (OC). In the present study we compared the response to APC in plasma from normal individuals, carriers of factor VLeiden and women who use OC using functional tests that either quantify the effect of APC on the endogenous thrombin potential (ETP) or on the activated partial thromboplastin time (aPTT). Both tests discriminated equally well between individuals with and without factor VLeiden who were not using OC. In contrast to the aPTT-based test, the ETP-based assay yielded significant differences in sensitivity to APC between non-OC users and OC users and between users of second and third generation OC. Since there was no correlation between APC-sensitivity determined with both assays in non-carriers of factor VLeiden and in women who use OC and a poor correlation in carriers of factor VLeiden, we propose that other plasma components differentially modulate the response to APC in the aPTT- and ETP-based APC-resistance tests and that OC change the level of plasma protein(s) that modulate the effect of APC on thrombin formation initiated via the extrinsic coagulation pathway.

Low-dose oral contraceptives and acquired resistance to activated protein C: a randomised cross-over study.

BACKGROUND: We have reported previously that, compared with use of second-generation oral contraceptives, the use of third-generation oral contraceptives is associated with increased resistance to the anticoagulant action of activated protein C (APC). Owing to the cross-sectional design of that study, these observations may have been subject to unknown bias or uncontrolled effects of the menstrual cycle. We aimed to overcome these sources of bias by doing a cycle-controlled randomised cross-over trial. METHODS: The response to APC in plasma was assessed in 33 women who received two consecutive cycles of a second-generation oral contraceptive (150 microg levonorgestrel and 30 microg ethinyloestradiol) or a third-generation oral contraceptive (150 microg desogestrel and 30 microg ethinyloestradiol), and who switched preparations after two pill-free cycles. Normalised APC sensitivity ratios were calculated by measurement of the effect of APC on thrombin generation in the plasma of these women and in pooled plasma from 90 controls. FINDINGS: Of the 33 women, five were excluded because not all required plasma samples were available. In the remaining 28 women, the normalised APC sensitivity ratio increased during treatment with both preparations. Compared with levonorgestrel, desogestrel-containing oral-contraceptive treatment caused a highly significant (p<0.0001) additional increase in normalised APC sensitivity ratio (0.51 [95% CI 0.37-0.66]). Normalised APC sensitivity ratios during oral-contraceptive treatment correlated with the values before oral-contraceptive use. INTERPRETATION: Oral-contraceptive treatment diminishes the efficacy with which APC down-regulates in-vitro thrombin formation. This phenomenon, designated as acquired APC resistance, is more pronounced in women using desogestrel-containing oral contraceptives than in women using levonorgestrel-containing preparations. Whether acquired APC resistance induced by oral contraceptives explains the increased risk of venous thromboembolism in oral-contraceptive users remains to be established.

PIP: This cycle-controlled randomized cross-over study examined the effects of a second-generation oral contraceptive (OC) containing levonorgestrel and a third-generation OC containing desogestrel on the anticoagulant action of activated protein C (APC) in the plasma. The response to APC in plasma was assessed in 28 women who received two consecutive cycles of a second-generation OC (150 mcg levonorgestrel and 30 mcg ethinyl estradiol) or a third-generation OC (150 mcg desogestrel and 30 mcg ethinyl estradiol), and who switched preparations after two pill-free cycles. Normalized APC sensitivity ratio was also taken from these women. Results showed that in the 28 women the normalized APC sensitivity ratio increased during treatment with both preparations. Compared with levonorgestrel, desogestrel-containing OC treatment caused a highly significant (p 0.0001) additional increase in normalized APC sensitivity ratio (0.51; 95% CI, 0.37-0.66). In conclusion, OC treatment diminishes the efficacy with which APC down-regulates in-vitro thrombin formation.

Regulation of thrombin formation by activated protein C: effect of the factor V Leiden mutation.

Activated Protein C (APC) resistance, one of the most common genetic risk factors for venous thrombosis, is caused by a single base mutation (G1691-->A) in the factor V (FV) gene resulting in the replacement of Arg506 by Gln at a predominant cleavage site for APC. Great progress in understanding the mechanism of downregulation of FVa activity via the protein C pathway has been achieved by studying APC-mediated inactivation of FVa purified from homozygous APC-resistant individuals. This review briefly summarizes the role of FVa in prothrombin activation and the structure-function relationship of FV and FVa. Subsequently, APC-dependent inactivation of FVa and FVa Leiden and its modulation by protein S and factor Xa in model systems containing purified proteins is discussed. FV also has a function in increasing the inactivation of FVIII/VIIIa by APC. This cofactor activity appears diminished in FV Leiden. Thus, an intricate mechanism of regulation of thrombin formation via the protein C pathway is starting to emerge. Extensive studies in plasma milieu will be needed to gain more insight into the relation between the presence of FV Leiden and impaired downregulation of thrombin formation in APC-resistant individuals.

Oral contraceptives and venous thrombosis: different sensitivities to activated protein C in women using second- and third-generation oral contraceptives.

Epidemiological studies have shown that women who use third-generation oral contraceptives (OC) containing desogestrel, gestodene or norgestimate have a higher risk of venous thrombosis than women who use second-generation OC containing levonorgestrel. It is also known that a mutation in factor V (factor V(Leiden)), which results in resistance to activated protein C (APC) and which is the most common cause of hereditary thrombophilia, potentiates the prothrombotic effect of OC. Effects of APC on thrombin generation in the plasma of women using OC were compared to the response to APC in non-OC users and in individuals that were heterozygous or homozygous for factor V(Leiden). The response towards APC was evaluated on basis of the ratio (APC-sr) of the time integrals of thrombin formation determined in the presence and absence of APC. Compared with women not using OC, women who used OC exhibited a significantly decreased sensitivity to APC (P<0.001), independent of the kind of OC used. Women who used third-generation monophasic OC were significantly less sensitive to APC than women using second-generation OC (P<0.001) and had APC-sr that did not significantly differ from heterozygous female carriers of factor V(Leiden) who did not use OC. Women who were heterozygous for factor V(Leiden) and used OC had APC-sr in the range of homozygous carriers of factor V(Leiden). Two women who started OC therapy had significantly elevated APC-sr within 3 d. Acquired APC resistance may explain the epidemiological observation of increased risk for venous thrombosis in OC users, especially in women using third-generation OC.

Human factor Va1 and factor Va2: properties in the procoagulant and anticoagulant pathways.

Human plasma factor V is heterogeneous and yields two forms of activated factor V that bind with low (factor Va1) and high affinity (factor Va2) to phospholipids. The properties of factor Va1 and factor Va2 in the anticoagulant and procoagulant pathways were evaluated by comparing their sensitivity for inactivation by APC and their ability to act as cofactor in prothrombin activation. At low phospholipid concentrations and on membranes containing low amounts of phosphatidylserine (PS), factor Va1 was inactivated by APC at 15-fold lower rates than factor Va2, both in the absence and in the presence of protein S. At high phospholipid concentrations and on membranes with more than 15 mol % PS, factor Va1 and factor Va2 were inactivated with equal efficiency. Differences between cofactor activities of factor Va1 and factor Va2 in prothrombin activation were only observed on membranes with less than 7.5 mol % PS. Due to the different phospholipid requirements of APC-catalyzed factor Va inactivation and of expression of factor Va cofactor activity in prothrombin activation, the thrombin-forming capacity of factor V1 was 7-fold higher than that of factor V2 in a reaction system containing factor Xa, prothrombin, APC, protein S, vesicles with a phospholipid composition resembling that of activated platelets, and traces of thrombin to initiate prothrombin activation. This shows that in the process of generation, expression, and down-regulation of factor Va cofactor activity on physiological membranes, the overall procoagulant activity of factor V1 can considerably exceed that of factor V2.

Effect of activated protein C on thrombin generation and on the thrombin potential in plasma of normal and APC-resistant individuals.

In this paper we describe the effect of activated protein C (APC) on thrombin generation initiated in platelet-poor plasma via the extrinsic or the intrinsic pathway. Thrombin was determined with a specific chromogenic substrate and quantitated by calculating the time integral of the thrombin generation curve, i.e. the endogenous thrombin potential (ETP). Addition of APC to normal plasma after both extrinsic and intrinsic initiation of coagulation resulted in a dose-dependent inhibition of thrombin generation as reflected by the decrease in ETP. Data obtained in intrinsically triggered plasma of normal individuals were subject to large variation. Therefore, the effect of APC on thrombin generation in APC-resistant plasmas was only studied in extrinsically stimulated reaction systems. APC had much less effect on the ETP of plasma from individuals that were heterozygous or homozygous for the mutation Arg506-->Gln506 in factor V (APC resistance). There appears to be a linear relationship between the ETP and the amount of alpha 2-macro-globulin-thrombin complex (alpha 2 M-IIa) that accumulates in plasma during thrombin formation. Since the alpha 2M-IIa complex possesses amidolytic activity, we measured the effect of APC on thrombin generation via the so-called normalized APC sensitivity ratio (APC-sr). The latter was defined as the ratio of the end levels of amidolytic activity of the alpha 2M-IIa complex determined in the presence and absence of 50 nM APC (alpha 2M-IIa + APC/(alpha 2M-IIa - APC) divided by the ratio of a normal plasma pool. Significant differences (P < 0.001) were observed between APC-sr of plasmas from normal individuals (APC-sr: 0.5-1.9, n = 25) and of plasmas from individuals that were heterozygous (APC-sr: 2.1-6.7, n = 17) or homozygous APC resistant (APC-sr: 3.9-5.9, n = 5). There was no overlap between APC-sr of normal plasmas and plasma from individuals, bearing the factor. V mutation. Abnormal APC-sr in certain plasmas (pregnancy, use of oral contraceptives, anticoagulant therapy, protein S deficiency or lupus anticoagulant) were corrected by performing the assay on a plasma sample that was diluted 10-fold in factor V-deficient plasma. Our data show that measurement of the effect of APC on the ETP yields valuable information about the (pro)thrombotic status of plasma (e.g. APC resistance, pregnancy, use of oral contraceptives).

A prothrombinase-based assay for detection of resistance to activated protein C.

In this paper we present a new method for the detection of resistance to activated protein C (APC) that is based on direct measurement of the effect of APC on the cofactor activity of plasma factor Va. The factor V present in a diluted plasma sample was activated with thrombin and its sensitivity towards APC was subsequently determined by incubation with phospholipids and APC. The loss of factor Va cofactor activity was quantified in a prothrombinase system containing purified prothrombin, factor Xa and phospholipid vesicles and using a chromogenic assay for quantitation of thrombin formation. The reaction conditions were optimized in order to distinguish normal, heterozygous and homozygous APC-resistant plasmas. Maximal differences in the response of these plasmas towards APC were observed when factor Va was inactivated by APC in the absence of protein S and when the cofactor activity of factor Va was determined at a low factor Xa concentration (0.3 nM). Addition of 0.2 nM APC and 20 microM phospholipid vesicles to a 1000-fold diluted sample of thrombin-activated normal plasma resulted in loss of more than 85% of the cofactor activity factor Va within 6 min. Under the same conditions, APC inactivated approximately 60% and approximately 20% of the factor Va present in plasma samples from APC-resistant individuals that were heterozygous or homozygous for the mutation Arg506-->Gln in factor V, respectively. Discrimination between the plasma samples from normal and heterozygous and homozygous APC-resistant individuals was facilitated by introduction of the so-called APC-sensitivity ratio (APC-sr). The APC-sr was defined as the ratio of the factor Va cofactor activities determined in thrombin-activated plasma samples after 6 min incubation with or without 0.2 nM APC and was multiplied by 100 to obtain integers (APC-sr = ¿factor Va+APC square root of factor Va-APC¿ x 100). Clear differences were observed between the APC-sr of plasmas from normal healthy volunteers (APC-sr: 8-20, n = 33) and from individuals that were heterozygous (APC-sr: 35-50, n = 17) or homozygous APC resistant (APC-sr: 82-88, n = 7). There was no mutual overlap between the APC-sr of normal plasmas and plasmas from heterozygous or homozygous APC resistant individuals (p < 0.0001). In all cases our test gave the same result at the DNA-based assay. Since the test is performed on a highly diluted plasma sample there is no interference by conditions that affect APC resistance tests that are based on clotting time determinations (e.g. coagulation factor deficiencies, oral anticoagulation, heparin treatment, the presence of lupus anticoagulants, pregnancy or the use of oral contraceptives). Furthermore, we show that part of the factor Va assay can be performed on an autoanalyzer which increases the number of plasma samples that can be handled simultaneously.

Effects of protein S and factor Xa on peptide bond cleavages during inactivation of factor Va and factor VaR506Q by activated protein C.

Inactivation of membrane-bound factor Va by activated protein C (APC) proceeds via a biphasic reaction that consists of a rapid and a slow phase, which are associated with cleavages at Arg506 and Arg306 of the heavy chain of factor Va, respectively. We have investigated the effects of protein S and factor Xa on APC-catalyzed factor Va inactivation. Protein S accelerates factor Va inactivation by selectively promoting the slow cleavage at Arg306 (20-fold). Factor Xa protects factor Va from inactivation by APC by selectively blocking cleavage at Arg506. Inactivation of factor VaR506Q, which was isolated from the plasma of a homozygous APC-resistant patient and which lacks the Arg506 cleavage site, was also stimulated by protein S but was not affected by factor Xa. This confirms that the target sites of protein S and factor Xa involve Arg306 and Arg506, respectively. Factor Xa completely blocked APC-catalyzed cleavage at Arg506 in normal factor Va (1 nM) with a half-maximal effect (K1/2Xa) at 1.9 nM factor Xa. Expression of cofactor activity of factor Va in prothrombin activation required much lower factor Xa concentrations (K1/2Xa = 0.08 nM). When the ability of factor Xa to protect factor Va from inactivation by APC was determined at low factor Va concentrations during prothrombin activation much lower amounts of factor Xa were required (K1/2Xa = 0.03 nM). This indicates 1) that factor Va is optimally protected from inactivation by APC by incorporation into the prothrombinase complex during ongoing prothrombin activation, and 2) that the formation of a catalytically active prothrombinase complex and protection of factor Va from inactivation by APC likely involves the same interaction of factor Xa with factor Va. In accordance with the proposed mechanisms of action of protein S and factor Xa, we observed that the large differences between the rates of APC-catalyzed inactivation of normal factor Va and factor VaR506Q were almost annihilated in the presence of factor Xa and protein S. This observation may explain why, in the absence of other risk factors, APC resistance only results in a weak prothrombotic condition.