Plasma Factor V Activation Is Prevented by Activated Protein C in the Presence of Phospholipid Vesicles, Not Platelets

1993 ◽  
Vol 69 (02) ◽  
pp. 124-129 ◽  
Author(s):  
Susan Solymoss ◽  
Kim Thi Phu Nguyen
Keyword(s):  
Western Blotting ◽  
Protein C ◽  
Thrombin Generation ◽  
Blood Platelets ◽  
Activated Protein C ◽  
Phospholipid Vesicles ◽  
Factor V ◽  
Two Stage ◽  
One Stage ◽  
Plasma Factor

SummaryActivated protein C (APC) is a vitamin K dependent anticoagulant which catalyzes the inactivation of factor Va and VIIIa, in a reaction modulated by phospholipid membrane surface, or blood platelets. APC prevents thrombin generation at a much lower concentration when added to recalcified plasma and phospholipid vesicles, than recalcified plasma and platelets. This observation was attributed to a platelet associated APC inhibitor. We have performed serial thrombin, factor V one stage and two stage assays and Western blotting of dilute recalcified plasma containing either phospholipid vesicles or platelets and APC. More thrombin was formed at a given APC concentration with platelets than phospholipid. One stage factor V values increased to higher levels with platelets and APC than phospholipid and APC. Two stage factor V values decreased substantially with platelets and 5 nM APC but remained unchanged with phospholipid and 5 nM APC. Western blotting of plasma factor V confirmed factor V activation in the presence of platelets and APC, but lack of factor V activation with phospholipid and APC. Inclusion of platelets or platelet membrane with phospholipid enhanced rather than inhibited APC catalyzed plasma factor V inactivation. Platelet activation further enhanced factor V activation and inactivation at any given APC concentration.Plasma thrombin generation in the presence of platelets and APC is related to ongoing factor V activation. No inhibition of APC inactivation of FVa occurs in the presence of platelets.

scholarly journals A Prothrombinase-based Assay for Detection of Resistance to Activated Protein C

1996 ◽  
Vol 76 (03) ◽  
pp. 404-410 ◽  
Author(s):  
Gerry A F Nicolaes ◽  
M Christella ◽  
L G D Thomassen ◽  
Rene van Oerle ◽  
Karly Hamulyak ◽  
...  
Keyword(s):  
Protein C ◽  
Plasma Sample ◽  
Activated Protein C ◽  
Factor Xa ◽  
Phospholipid Vesicles ◽  
Factor V ◽  
Plasma Samples ◽  
Factor Va ◽  
Plasma Factor ◽  
Cofactor Activity

SummaryIn 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 chromogen-ic 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 μM 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 rnin. Under the same conditions, APC inactivated ∼ 60% and ∼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/factor Va−APC} × 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 as 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.

Evidence that the Protein C Activation Pathway Amplifies the lnhibition of Thrombin Generation by Recombinant Human Thrombomodulin in Plasma

1993 ◽  
Vol 70 (03) ◽  
pp. 423-426 ◽  
Author(s):  
Rika ohishi ◽  
Naoko watanabe ◽  
Masaharu Aritomi ◽  
Komakazu Gomi ◽  
Takao Kiyota ◽  
...  
Keyword(s):  
Protein C ◽  
Inhibitory Action ◽  
Thrombin Generation ◽  
Anticoagulant Activity ◽  
Activated Protein C ◽  
Inhibitory Effect ◽  
Phospholipid Vesicles ◽  
Activation Pathway ◽  
Activated Platelets ◽  
Rapid Generation

SummaryThrombomodulin (TM) is a cofactor for the thrombin-catalyzed activation of anticoagulant protein C. However, we have no evidence that thrombomodulin actually activates protein C during blood coagulation processing, nor do we know whether this activated protein C acts as an anticoagulant. We studied the inhibitory action of recombinant human soluble TM (rhs-TM) on thrombin generation in whole plasma. Human plasma was activated with small amounts of tissue factor using phospholipid vesicles in place of activated platelets. Thrombin generation was observed. The addition of only 2 nM of rhs-TM prevented rapid generation of thrombin and reduced the total amount of thrombin generated. In order to study the influence of the protein C activation pathway on this inhibitory action of rhs-TM, protein C-depleted plasma was used. rhs-TM had little inhibitory effect on protein C-depleted plasma. However, the addition of protein C caused a delay in thrombin generation and a reduction of the maximum thrombin concentration. We concluded that the anticoagulant activity of rhs-TM was amplified by the protein C activation pathway.

Thrombin spatial distribution determines Protein C activation during hemostasis and thrombosis

Blood ◽  
2021 ◽  
Author(s):  
Tanya T. Marar ◽  
Chelsea N. Matzko ◽  
Jie Wu ◽  
Charles Esmon ◽  
Talid Sinno ◽  
...  
Keyword(s):  
Spatial Distribution ◽  
Protein C ◽  
Thrombin Generation ◽  
Jugular Vein ◽  
Activated Protein C ◽  
Factor V Leiden ◽  
Factor V ◽  
Factor V Leiden Mutation ◽  
Fibrin Formation

Rebalancing of the hemostatic system by targeting endogenous anticoagulant pathways, like the Protein C system, is being tested as a means of improving hemostasis in patients with hemophilia. Recent intravital studies of hemostasis demonstrated that, in some vascular contexts, thrombin activity is sequestered to the extravascular compartment. These findings raise important questions about the context-dependent contribution of activated Protein C (aPC) to the hemostatic response since Protein C activation occurs on the surface of endothelial cells. Here, we used a combination of pharmacologic, genetic, imaging, and computational approaches to examine the relationships among thrombin spatial distribution, Protein C activation, and aPC anticoagulant function. We found that inhibition of aPC activity, either in mice harboring the Factor V-Leiden mutation or infused with an aPC blocking antibody, significantly enhanced fibrin formation and platelet activation in a microvascular injury model, consistent with aPC's role as an anticoagulant. In contrast, inhibition of aPC activity had no effect on hemostasis following penetrating injury of the mouse jugular vein. Computational studies showed that differences in blood velocity, injury size, and vessel geometry determine the localization of thrombin generation and, consequently, the extent of Protein C activation. Computational predictions were tested in vivo and showed that when thrombin generation occurred intravascularly, without penetration of the vessel wall, inhibition of aPC significantly increased fibrin formation in the jugular vein. Together, these studies show the importance of thrombin spatial distribution in determining Protein C activation during hemostasis and thrombosis.

Thrombin generation and activated protein C resistance in patients with essential thrombocythemia and polycythemia vera

Blood ◽  
2008 ◽  
Vol 112 (10) ◽  
pp. 4061-4068 ◽  
Author(s):  
Marina Marchetti ◽  
Elisabetta Castoldi ◽  
Henri M. H. Spronk ◽  
René van Oerle ◽  
Donatella Balducci ◽  
...  
Keyword(s):  
Polycythemia Vera ◽  
Essential Thrombocythemia ◽  
Protein C ◽  
Thrombin Generation ◽  
Activated Protein C ◽  
Protein S ◽  
Factor V ◽  
Endogenous Thrombin Potential ◽  
Apc Resistance ◽  
Mutational Status

Abstract We used the thrombin generation assay to evaluate the hypercoagulable state according to JAK2V617F mutational status in essential thrombocythemia (ET) and polycythemia vera (PV) patients. Thrombin generation was determined in the presence and absence of activated protein C (APC), and APC resistance was expressed as normalized APC sensitivity ratio (nAPCsr). Tissue factor pathway inhibitor (TFPI), total and free protein S (PS), prothrombin (FII), factor V (FV), and neutrophil elastase were measured in plasma; CD11b was measured on neutrophils. Compared with normal controls, patients had a lower endogenous thrombin potential in the absence of APC but had a higher endogenous thrombin potential in the presence of APC, showing the occurrence of APC resistance. The nAPCsr increased in JAK2V617F carriers compared with noncarriers and was highest in JAK2V617F homozygous patients. FII, FV, free PS, and TFPI levels were reduced in patients, mainly in JAK2V617F carriers. Multiple regression analysis indicated the low free PS level as major determinant of the increased nAPCsr. Elastase was increased in patients and inversely correlated with free PS. In conclusion, these data indicate the occurrence of acquired APC resistance in ET and PV patients, probably because of a reduction in free PS levels. The APC-resistant phenotype is influenced by the JAK2V617F mutational load.

Thrombin generation and activated protein C resistance in the absence of factor V Leiden correlates with the risk of recurrent venous thromboembolism in women aged 18–65 years

2011 ◽  
Vol 106 (11) ◽  
pp. 901-907 ◽  
Author(s):  
Svetlana Tchaikovski ◽  
Margareta Holmström ◽  
Jan Rosing ◽  
Katarina Bremme ◽  
Gerd Lärfars ◽  
...  
Keyword(s):  
Risk Factor ◽  
Protein C ◽  
Thrombin Generation ◽  
Activated Protein C ◽  
Factor V Leiden ◽  
Peak Height ◽  
Factor V ◽  
Risk Of Recurrence ◽  
Apc Resistance ◽  
Increased Risk

SummaryIdentification of patients at high risk of recurrence after a first event of venous thromboembolism (VTE) remains difficult. Resistance to activated protein C (APC) is a known risk factor for VTE, but data on the risk of recurrence is controversial. We wanted to investigate whether APC resistance in the absence of factor V Leiden, determined with global coagulation test such as the thrombin generation assay, could be used as a marker for increased risk of recurrent VTE among women 18–65 years old after a first event of VTE. In a cohort of 243 women with a first event of VTE, plasma was collected after discontinuation of anticoagulant treatment and the patients were followed up for 46 months (median). Thrombin generation was measured via calibrated automated thrombography, at 1 pM and 10 pM of tissue factor (TF). In women without factor V Leiden (n=117), samples were analysed in the absence and in the presence of APC. Increase in ETP (endogenous thrombin potential) and peak height analysed in the presence of APC correlated significantly with higher risk of recurrence. At 1 pM, peak height correlated with increased risk of recurrence. In conclusion, high thrombin generation in the presence of APC, in women after a first event of VTE is indicative for an increased risk of a recurrence. We also found that thrombin generation at low TF (1 pM) is correlated with the risk of recurrence. Our data suggest that APC resistance in the absence of factor V Leiden is a risk factor for recurrent VTE.

Does activated protein C-resistant factor V contribute to thrombin generation in hemophilic plasma?

2005 ◽  
Vol 3 (3) ◽  
pp. 522-530 ◽  
Author(s):  
M. H. A. BOS ◽  
D. W. E. MEIJERMAN ◽  
C. VAN DER ZWAAN ◽  
K. MERTENS
Keyword(s):  
Protein C ◽  
Thrombin Generation ◽  
Activated Protein C ◽  
Factor V

scholarly journals Platelet protein S directly inhibits procoagulant activity on platelets and microparticles

2013 ◽  
Vol 109 (02) ◽  
pp. 229-237 ◽  
Author(s):  
Fabian Stavenuiter ◽  
Nicole Davis ◽  
Erning Duan ◽  
Andrew Gale ◽  
Mary Heeb
Keyword(s):  
Electrophoretic Mobility ◽  
Western Blotting ◽  
Plasma Protein ◽  
Protein C ◽  
Thrombin Generation ◽  
Activated Protein C ◽  
Protein S ◽  
Neutralising Antibodies ◽  
Platelet Protein ◽  
Cofactor Activity

SummaryAnticoagulant plasma protein S (PS) is essential for maintaining haemostatic balance. About 2.5% of PS is stored in platelets and released upon platelet stimulation. So far, little is known about the functionality and importance of platelet (plt)PS. A platelet-associated protease cleaves plasma-derived (pd)PS and pltPS in the “thrombin-sensitive region”, abolishing activated protein C (APC) cofactor activity. However, we showed that cleaved PS retains APC-independent anticoagulant activities (“PS-direct”). To investigate whether pltPS or pdPS exert PS-direct on platelets or platelet-shed microparticles, thrombin and factor (F)Xa generation on unstimulated or stimulated washed platelets and microparticles were measured. Western blotting revealed that pltPS and pdPS bound to washed, stimulated platelets and microparticles, and that pltPS had slower electrophoretic mobility than pdPS. Platelet stimulation in the presence of inhibitory anti-PS antibodies resulted in 2.6 ± 1.6-fold (p<0.0004, n=20) more thrombin generation upon addition of FXa and prothrombin. PltPS exerted PSdirect that was similar to or greater than that of Zn2+-containing pdPS and much greater than that of Zn2+-deficient pdPS. Findings were confirmed using purified pltPS. Platelet-bound pltPS and microparticlebound pltPS had similar PS-direct. Finally, platelet stimulation in the presence of inhibitory anti-PS antibodies resulted in 1.5 ± 0.2-fold (p<0.0001, n=11) more FXa generation upon addition of TF/FVIIa and FX. Thus, pltPS inhibits both prothrombinase and extrinsic FXase activities. Neutralising antibodies against APC and TFPI had no effect on the PS-direct of pltPS or pdPS on platelets. This study indicates that pltPS may be an essential pool of PS that counterbalances procoagulant activities on platelets.

Heightened Thrombin Generation in Individuals with Resistance to Activated Protein C

1996 ◽  
Vol 75 (05) ◽  
pp. 703-705 ◽  
Author(s):  
Ida Martinelli ◽  
Bianca Bottasso ◽  
Francesca Duca ◽  
Elena Faioni ◽  
Pier Mannuccio Mannucci
Keyword(s):  
Protein C ◽  
Thrombin Generation ◽  
Significant Positive Correlation ◽  
Activated Protein C ◽  
Protein S ◽  
Factor V ◽  
Factor V Gene ◽  
V Gene ◽  
Previous Occurrence ◽  
Thrombotic Tendency

SummaryWe chose to evaluate whether or not a state of biochemical hypercoagulability was present in 74 individuals (69 heterozygotes and 5 homozygotes) resistant to activated protein C (APC) due to the Arg506 -> Gin mutation in the factor V gene. To this end, plasma levels of two markers of thrombin formation, prothrombin fragment 1+2 (F1+2) and thrombin-antithrombin complexes (TAT), were measured. High levels of F1+2 and TAT were found in 32% and 23% of APC-resistant individuals vs 4% in controls. The levels of these markers tended to be particularly elevated in three homozygous subjects. A significant positive correlation between F1+2 and TAT was present in APC-resistant individuals. No relationship between marker values and the previous occurrence of thrombotic episodes was found. Therefore, by measuring F1+2 and TAT a state of biochemical hypercoagulability has been identified in about one-third of APC-resistant individuals. This frequency is similar to that previously observed in comparable individuals with inherited deficiencies of protein C and protein S, which are usually associated with a stronger thrombotic tendency than APC-resistant individuals.

scholarly journals Circulating Activated Protein C in Thrombophilia Carriers

Blood ◽  
2016 ◽  
Vol 128 (22) ◽  
pp. 4948-4948
Author(s):  
Thijs E van Mens ◽  
Joost C.M. Meijers ◽  
Saskia Middeldorp
Keyword(s):  
Venous Thrombosis ◽  
Lower Limit ◽  
Protein C ◽  
Thrombin Generation ◽  
Activated Protein C ◽  
Factor V Leiden ◽  
Prothrombin G20210a ◽  
Factor V ◽  
Limit Of Quantification ◽  
Inherited Thrombophilia

Abstract Background: Inherited thrombophilias are genetic disorders in which mutation carriers have an elevated risk of venous thromboembolism through abnormalities in the coagulation cascade. These abnormalities all lead to increased thrombin generation. The mutations, of which factor V Leiden and prothrombin G20210A are the most common, therefore likely increase thrombin mediated protein C activation in plasma. Previous findings have however been inconsistent. Increased activation of protein C in inherited thrombophilia would be interesting in light of various unexplained phenotypes described in thrombophilia carriers. Examples of such phenotypes include improved fertility, increased risk of miscarriage, protection from diabetic nephropathy, decreased susceptibility to and mortality from sepsis and decreased mortality in acute respiratory distress syndrome. These do not appear directly related to increased coagulation in carriers. Activated protein C (APC) possesses a wide range of signaling functions and interactions with multiple pathways. These result in anti-apoptotic, anti-inflammatory, gene-expression, regenerative and endothelial stabilizing effects. Such properties can easily be thought to play a role in the above described phenotypes. APC has indeed been shown to possess beneficial properties in numerous animal injury models. Due to its pleiotropic nature, APC might be a promising candidate for further research into the unexplained phenotypes observed in inherited thrombophilia. Aim: To investigate if plasma APC concentrations are higher in thrombophilia carriers as compared to non-carriers. Methods: We performed a cross-sectional observational study comparing the APC plasma levels of factor V Leiden and prothrombin G20210A mutation hetero- and homozygotes with non-carriers. Exclusion criteria comprised use of anticoagulant medication and recent venous thrombosis or risk factors for venous thrombosis. We measured APC using a recently developed highly sensitive oligonucleotide-based capture assay, with a limit of detection of 0.022 ng/ml and the ability to quantify APC upward of 0.116 ng/ml (lower limit of quantification) (Müller et al., 2012). In addition we determined APC-protein C inhibitor complex (APC-PCI) as a secondary measure of protein C activation, and prothrombin fragment 1+2 (F1+2) concentration as a measure of thrombin generation using immunoassays. Parametric and non-parametric descriptive and inferential statistics were applied as appropriate. Results: We included 19 thrombophilia carriers and 18 non-carriers (Table 1). APC was detectable in 47% of carriers and in 39% of non-carriers (p = 0.74). APC was above the lower limit of quantification in only 19% of all subjects, with no difference between the groups (Figure 1). The median APC-PCI concentration in carriers and non-carriers were 5 AU (IQR 3.5-10.5) vs. 5 AU (IQR 3.0-8.0) (p = 0.338); and mean F1+2 concentrations were 266 pmol/L and 194 pmol/L in carriers and non-carriers respectively (p = 0.075). Discussion: We did not find increased circulating APC concentrations in thrombophilia carriers. Given the low number of subjects with quantifiable APC in the study, elevated APC levels in carriers versus non-carriers cannot be fully excluded. Local elevation at the site of thrombin formation still seems plausible, and our data do show a trend towards increased thrombin generation in thrombophilia carriers. However, we also show that systemic concentrations are generally below 0.116 ng/ml, which is an order of magnitude lower than concentrations previously reported as physiological levels. A prominent role for APC in non-coagulation related thrombophilia phenotypes might therefore be questioned. References Müller, J. et al. (2012). Journal of Thrombosis and Haemostasis : JTH, 10(3), 390-8. Measured APC concentrations above the limit of quantification, according to thrombophilia carriership status. Measured APC concentrations above the limit of quantification, according to thrombophilia carriership status. Figure 1 Figure 1. Disclosures Middeldorp: Boehringer Ingelheim: Consultancy; GSK: Consultancy, Honoraria; Aspen: Consultancy, Honoraria; BMS/Pfizer: Consultancy, Honoraria; Bayer: Consultancy; Daiichi Sankyo: Consultancy, Honoraria; Sanquin: Consultancy.

Activated Protein C-Resistance Induced by a Low Molecular Weight Inhibitor.

Blood ◽  
2005 ◽  
Vol 106 (11) ◽  
pp. 2136-2136
Author(s):  
Michael Kalafatis ◽  
Rihard E. Chiott ◽  
Richard F. Branda ◽  
Kenneth G. Mann
Keyword(s):  
Molecular Weight ◽  
Protein C ◽  
Activated Protein C ◽  
Low Molecular Weight ◽  
Factor V ◽  
Prolonged Incubation ◽  
Apc Resistance ◽  
Factor Va ◽  
Normal Plasma ◽  
Plasma Factor

Abstract Activated protein C (APC) inactivates factor Va (fVa) following three cleavages in the heavy chain at R506, R306 and R679. Cleavage at R506 precedes cleavage at R306. Cleavage at Arg306 is strictly lipid-dependent and results in total inactivation of the factor Va molecule with dissociation of fragments from the A2 domain from the rest of the molecule. Factor VLeiden is associated with an R→Q substitution at position 506 and is present at approximately 8% of the Caucasian population. The heterozygous presentation of factor VLeiden results in delayed inactivation of factor Va and “APC-resistance” with attendant increased risk of venous thrombosis. However, not all cases of “APC-resistance” are explained by factor VLeiden. We observed “APC-resistance” in a patient displaying heterozygous factor VLeiden, Waldenstrom’s macroglobulinenemia, systemic lupus erythrematosus (anticoagulant) and a history of coronary artery disease. The patient’s plasma resistance to APC inactivation was not repaired by immunodepletion of his factor VLeiden and replacement by normal plasma factor V. Conversely when the patient’s fVa was returned to factor V immunodepleted normal plasma it did not display APC-resistance. Cleavage of the patient’s plasma fVa at R306 was not detected following prolonged incubation of his clotted plasma at 37°C even when 2 nM APC was added following clotting. These data suggested that the APC-resistance observed in the patient was not due to the presence of factor VLeiden, but due to some property which inhibited the lipid dependent cleavage at Arg306. The patient’s plasma was depleted of IgG/IgM and the purified immunoglobulin fraction assessed for inhibition of APC cleavage and inactivation of fVa in a system using purified reagents. The data were compared with the inhibition of fVa inactivation by APC by an IgG/IgM fraction obtained from normal plasma under similar experimental conditions. No inhibition of APC cleavage and inactivation of fVa by the IgM/IgG fraction obtained from either plasma were observed. In addition, the fVa molecule contained in the IgM/IgG-depleted patient plasma was still resistant to cleavage and inactivation by APC. Following dialysis the patient’s plasma lost its ability to inhibit fVa cleavage and inactivation by APC. Overall these studies indicate that inhibition of fVa cleavage and inactivation by APC in the patient’s plasma is caused by a hitherto undescribed metabolite of low molecular weight. The mechanism of action of this metabolite is not yet known, but the evidence suggests that the metabolite interferes with the lipid-dependent cleavage and inactivation of fVa by APC at R306. These data demonstrate the existence of an as yet unknown APC inhibitor of low molecular weight in the plasma of a patient with lupus anticoagulant and severe thrombotic symptoms.

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