scholarly journals Biochemical Characteristics of Emicizumab Activity with Factors IXa, X, and VIIa

Blood ◽  
2018 ◽  
Vol 132 (Supplement 1) ◽  
pp. 1167-1167
Author(s):  
Dougald Monroe ◽  
Maureane Hoffman
Keyword(s):  
Tissue Factor ◽  
Factor Viia ◽  
Binding Constants ◽  
Constant Factor ◽  
Factor Ix ◽  
Solution Phase ◽  
Factor X ◽  
Factor Ixa ◽  
Egf Domain ◽  
Factor X Activation

Abstract Introduction. Emicizumab (Hemlibra) is a bivalent antibody that binds to factor IXa and factor X; this binding can promote factor IXa activation of factor X. In patients on prophylaxis with emicizumab, breakthrough bleeding has been treated successfully with factor VIIa (eptacog alfa (activated) (NovoSeven)). Objective. Our goal was to study the biochemistry of the interaction of emicizumab with factor IXa and factor X. We further wanted to study how binding of emicizumab to factor X would impact factor X activation by factor VIIa. Background. Data from surface plasmon resonance binding studies has shown that solution phase interactions between emicizumab and factors IX, IXa, X, and Xa are in the micromolar range (supplement to Kitazawa et al Nature Med 2012; 18: 1570-1574). That same publication showed that a lipid surface is required for activity. Other studies have shown that emicizumab binds to EGF1 of factor IX and EGF2 of factor X (Kitazawa et al Thromb Haemost 2017; 117: 1348-1357). Methods. Lipids were large unilamellar vesicles with 14% phosphatidylserine. Factors IX and X were purified from plasma. The basic design of an assay is to vary one element while holding other elements constant. To determine the apparent Km for factor X, factor X was varied with constant factor IXa (0.1 nM), lipid (100 µM), and emicizumab (400 nM). To determine the apparent Kd for factor IXa, factor IXa was varied with constant factor X (135 nM), lipid (100 µM), and emicizumab (3, 10, or 30 nM). The binding of factor IXa was determined in the presence and the absence of plasma concentration (80 nM) factor IX. Factor VIIa/tissue factor activation of factor X was measured with 0.25 nM VIIa/TF complex with factor X (135 nM) and either no emicizumab, 400 nM, or 50 µM. Factor VIIa activation of factor X in the absence of tissue factor was measured with varied factor VIIa (25-100 nM), fixed factor X (135 nM) and lipid (100 µM) and either no emicizumab, 400 nM, or 50 µM. Results. In the presence of lipid, the apparent binding constants for formation of the IXa-emicizumab-X complex were tighter than the solution phase reactions. Under the conditions studied, the Km,app for factor X was about 25 nM. The Kd,app for factor IXa was about 5 nM. Surprisingly, when lipid and factor X were present, factor IX did not compete with factor IXa for activation of factor X. Factor VIIa/tissue factor activation of factor X was slowed considerably by emicizumab. By contrast, factor VIIa activation of factor X in the absence of tissue factor was not slowed. Conclusions. The binding of factor X to the factor VIIa/tissue factor complex involves multiple domains in factor X. Since emicizumab reduced factor X activation by the factor VIIa/tissue factor complex, it appears that binding of emicizumab to the second EGF domain of factor X interfered with formation of the activating complex. By contrast, activation of factor X by factor VIIa alone was not reduced by emicizumab suggesting that interactions between factor VIIa and the second EGF domain of factor X are not essential for formation of that lipid bound complex. We would predict from the solution phase binding constants that high concentrations of emicizumab would be required to form the complex with factors IXa and X. This is in contrast to the observation that relatively low concentrations of emicizumab give significant shortening of an aPTT assay. The tight binding constants in the presence of lipid may explain the results seen in clotting assays. Further, this significant effect of emicizumab in clotting assays is consistent with the surprising observation that factor IX does not compete with factor IXa in formation of the lipid bound complex of IXa-emicizumab-X. So even a small amount of factor IXa can form functional complexes that activate factor X. Disclosures Monroe: Novo Nordisk A/S: Honoraria, Research Funding. Hoffman:Novo Nordisk A/S: Consultancy, Honoraria, Research Funding.

Extrinsic Activation of Human Blood Coagulation Factors IX and X

1990 ◽  
Vol 63 (02) ◽  
pp. 224-230 ◽  
Author(s):  
V J J Bom ◽  
J H Reinalda-Poot ◽  
R Cupers ◽  
R M Bertina
Keyword(s):  
Tissue Factor ◽  
Kinetic Data ◽  
Factor Viia ◽  
Coagulation Factors ◽  
Factor Ix ◽  
Lag Phase ◽  
Factor X ◽  
Extrinsic Factor ◽  
Factor Ixa ◽  
Factor X Activation

SummaryWe studied activation of human coagulation factors IX and X by factor VIIa in the presence of calcium ions, phospholipid (phosphatidylserine/phosphatidylcholine, 50/50, mol/mol) and purified tissue factor apoprotein. Activation of factor IX and factor X was found to occur without a measurable lag-phase and hence initial rates of factor IXa and factor Xa formation could be determined. Like previously observed for the activation of factor X, the activation of factor IX was saturable with respect to factor VIIa, tissue factor apoprotein and phospholipid. The results suggested that in the presence of a Ca2+ ions the same ternary complex of factor VIIa-tissue factor apoprolein-phospholipid is responsible for the activation of factor IX and factor X. Roth the apparent Km of 22 nM-factor IX and the apparent Kcat of 28 min−1 were about 3-fold lower than the coiicsponding parameters of factor X activation by this complex. Hence, the catalytic efficiency (Kcat/Km) of factor IX and factor X activation was about equal. However, the two substrates inhibited the activation of each other by competition for the same catalytic sites. The apparent Kinh of factor IX for inhibition of extrinsic factor X activation is 30 nM. The apparent Kinh of factor X for inhibition of extrinsic factor IX activation is 116 nM. From these kinetic data it was calculated that at plasma concentration of factors IX and X, the rate of extrinsic factor IX activation would be half the rate of factor X activation. These relative rates of extrinsic factor IX and factor X activation in combination with previously reported kinetic data on the activation of factor X by factor IXa in the presence of factor VIIIa provide support for the concept that at low levels of tissue factor, factor IXa formation might play an important role in the extiinsic pathway of coagulation in vivo.

Factor VIII-Factor IX Interactions: Molecular Sites Involved in Enzyme-Cofactor Complex Assembly

1999 ◽  
Vol 82 (08) ◽  
pp. 209-217 ◽  
Author(s):  
Patrick Celie ◽  
Joost Kolkman ◽  
Peter Lenting ◽  
Koen Mertens
Keyword(s):  
Factor Viii ◽  
Tissue Factor ◽  
Factor Viia ◽  
Three Dimensional ◽  
Factor Ix ◽  
Coagulation Cascade ◽  
Factor X ◽  
Factor Ixa ◽  
Factor Viiia ◽  
Factor X Activation

IntroductionThe activation of factor X is one of the steps in the coagulation cascade that is driven by the assembly of an activated serine protease with a membrane-bound cofactor. In the initial phase of coagulation, factor X is activated by the complex of activated factor VII (factor VIIa) and tissue factor. Subsequently, during the so-called propagation phase, factor X activation is catalyzed by the complex of activated factor IX (factor IXa) and activated factor VIII (factor VIIIa). In these complexes, factor VIIa and factor IXa are the factor X-activating enzymes, whereas tissue factor and factor VIIIa serve as non-enzymatic cofactors.1 Factors VIIa and IXa are highly homologous to other cofactor-dependent enzymes, such as activated factor X (factor Xa) and activated protein C, both in amino acid sequence, domain organization, and three-dimensional structure.2 Factor VIIa and IXa further share low or negligible activity towards their natural substrate factor X, unless in complex with their physiological cofactors.Although tissue factor and factor VIIIa serve similar roles as biological amplifiers, they are structurally different. Tissue factor is a small, transmembrane protein with an extracellular part comprising 219 amino acids. Factor VIII is much larger (2,332 amino acids), circulates in plasma, and requires proteolytic processing to exert its biological activity.3 When cofactors are assembled with their respective enzymes, a dramatic increase in enzymatic activity occurs. The underlying molecular mechanism, however, remains poorly understood.During the past few years, remarkable progress has been made in understanding the molecular details of enzyme-cofactor assembly within the coagulation cascade. Crystallography has provided high-resolution structures of tissue factor4 and the various cofactor-dependent coagulation enzymes.2 Moreover, the crystal structure of the factor VIIa—tissue factor complex has been resolved and has allowed the identification of the molecular sites involved in enzyme-cofactor interaction.5,6 Such details are still lacking, however, for the factor IXa—factor VIIIa complex. Current views are derived from three-dimensional models generated by homology modeling based on structurally-related proteins, such as nitrite reductase,7 ceruloplasmin,8 and galactose oxidase.9 Despite their inherent limitations, these models greatly facilitate the interpretation of previous functional studies on factor X activation. As such, the availability of molecular models may be considered an important step toward resolving the structure of the factor IXa—factor VIIIa complex and understanding the role of complex assembly and defects thereof. This chapter provides an overview of the current developments in this field.

scholarly journals Factors IXa and Xa play distinct roles in tissue factor-dependent initiation of coagulation

Blood ◽  
1995 ◽  
Vol 86 (5) ◽  
pp. 1794-1801 ◽  
Author(s):  
M Hoffman ◽  
DM Monroe ◽  
JA Oliver ◽  
HR Roberts
Keyword(s):  
Tissue Factor ◽  
Platelet Activation ◽  
Thrombin Generation ◽  
Factor Viia ◽  
Factor Xa ◽  
Factor Ix ◽  
Main Role ◽  
Factor X ◽  
Platelet Surface ◽  
Factor Ixa

Tissue factor is the major initiator of coagulation. Both factor IX and factor X are activated by the complex of factor VIIa and tissue factor (VIIa/TF). The goal of this study was to determine the specific roles of factors IXa and Xa in initiating coagulation. We used a model system of in vitro coagulation initiated by VIIa/TF and that included unactivated platelets and plasma concentrations of factors II, V, VIII, IX, and X, tissue factor pathway inhibitor, and antithrombin III. In some cases, factor IX and/or factor X were activated by tissue factor- bearing monocytes, but in some experiments, picomolar concentrations of preactivated factor IX or factor X were used to initiate the reactions. Timed samples were assayed for both platelet activation and thrombin activity. Factor Xa was 10 times more potent than factor IXa in initiating platelet activation, but factor IXa was much more effective in promoting thrombin generation than was factor Xa. In the presence of VIIa/TF, factor X was required for both platelet activation and thrombin generation, while factor IX was only required for thrombin generation. We conclude that VIIa/TF-activated factors IXa and Xa have distinct physiologic roles. The main role of factor Xa that is initially activated by VIIa/TF is to activate platelets by generating an initial, small amount of thrombin in the vicinity of platelets. Factor IXa, on the other hand, enhances thrombin generation by providing factor Xa on the platelet surface, leading to prothrombinase formation. Only tiny amounts of factors IX and X need to be activated by VIIa/TF to perform these distinct functions. Our experiments show that initiation of coagulation is highly dependent on activation of small amounts of factors IXa and Xa in proximity to platelet surfaces and that these factors play distinct roles in subsequent events, leading to an explosion of thrombin generation. Furthermore, the specific roles of factors IXa and Xa generated by VIIa/TF are not necessarily reflected by the kinetics of factor IXa and Xa generation.

scholarly journals A soluble tissue factor-annexin V chimeric protein has both procoagulant and anticoagulant properties

Blood ◽  
2006 ◽  
Vol 107 (3) ◽  
pp. 980-986 ◽  
Author(s):  
Xin Huang ◽  
Wei-Qun Ding ◽  
Joshua L. Vaught ◽  
Roman F. Wolf ◽  
James H. Morrissey ◽  
...  
Keyword(s):  
Tissue Factor ◽  
Blood Coagulation ◽  
Vascular Injury ◽  
Factor Viia ◽  
Chimeric Protein ◽  
Annexin V ◽  
Factor X ◽  
Low Concentrations ◽  
Finite Period ◽  
Factor X Activation

AbstractTissue factor (TF) initiates blood coagulation, but its expression in the vascular space requires a finite period of time. We hypothesized that targeting exogenous tissue factor to sites of vascular injury could lead to accelerated hemostasis. Since phosphatidylserine (PS) is exposed on activated cells at sites of vascular injury, we cloned the cDNA for a chimeric protein consisting of the extracellular domain of TF (called soluble TF or sTF) and annexin V, a human PS-binding protein. Both the sTF and annexin V domains had ligand-binding activities consistent with their native counterparts, and the chimera accelerated factor X activation by factor VIIa. The chimera exhibited biphasic effects upon blood coagulation. At low concentrations it accelerated blood coagulation, while at higher concentrations it acted as an anticoagulant. The chimera accelerated coagulation in the presence of either unfractionated or low-molecular-weight heparins more potently than factor VIIa and shortened the bleeding time of mice treated with enoxaparin. The sTF-annexin V chimera is a targeted procoagulant protein that may be useful in accelerating thrombin generation where PS is exposed to the vasculature, such as may occur at sites of vascular injury or within the vasculature of tumors.

scholarly journals Inhibition of tissue factor/factor VIIa activity in plasma requires factor X and an additional plasma component

Blood ◽  
1985 ◽  
Vol 66 (1) ◽  
pp. 204-212
Author(s):  
NL Sanders ◽  
SP Bajaj ◽  
A Zivelin ◽  
SI Rapaport
Keyword(s):  
Tissue Factor ◽  
Factor Viia ◽  
Factor Ix ◽  
Factor Vii ◽  
Factor X ◽  
Additional Material ◽  
Plasma Reaction ◽  
Progress Curve ◽  
Peptide Release ◽  
Release Data

A study was carried out to explore requirements for the inhibition of tissue factor-factor VIIa enzymatic activity in plasma. Reaction mixtures contained plasma, 3H-factor IX or 3H-factor X, tissue factor (vol/vol 2.4% to 24%), and calcium. Tissue factor-factor VIIa activity was evaluated from progress curves of activation of factor IX or factor X, plotted from tritiated activation peptide release data. With normal plasma, progress curves exhibited initial limited activation followed by a plateau indicative of loss of tissue factor-factor VIIa activity. With hereditary factor X-deficient plasma treated with factor X antibodies, progress curves revealed full factor IX activation. Adding only 0.4 micrograms/mL factor X (final concentration) could restore inhibition. Inhibition was not observed in purified systems containing 6% to 24% tissue factor, factor VII, 0.5 micrograms/mL, factor IX, 13 micrograms/mL, and factor X up to 0.8 micrograms/mL, but could be induced by adding barium-absorbed plasma to the reaction mixture. Thus, both factor X and an additional material in plasma were required for inhibition. The amount of factor X needed appeared related to the concentration of tissue factor; adding more tissue factor at the plateau of a progress curve induced further activation. These results also indicate that inhibited reaction mixtures contained active free factor VII(a). Preliminary data suggest that inhibition may stem from loss of activity of the tissue factor component of the tissue factor- factor VII(a) complex.

scholarly journals In Hemophilia Α Plasma Treated with Emicizumab, Factor IX Activation By Factor VIIa Drives Thrombin Generation

Blood ◽  
2020 ◽  
Vol 136 (Supplement 1) ◽  
pp. 17-17
Author(s):  
Dougald Monroe ◽  
Mirella Ezban ◽  
Maureane Hoffman
Keyword(s):  
Factor Viii ◽  
Tissue Factor ◽  
Plasma Levels ◽  
Thrombin Generation ◽  
Hemophilia A ◽  
Factor Viia ◽  
Factor Ix ◽  
Factor X ◽  
Dose Dependent

Background.Recently a novel bifunctional antibody (emicizumab) that binds both factor IXa (FIXa) and factor X (FX) has been used to treat hemophilia A. Emicizumab has proven remarkably effective as a prophylactic treatment for hemophilia A; however there are patients that still experience bleeding. An approach to safely and effectively treating this bleeding in hemophilia A patients with inhibitors is recombinant factor VIIa (rFVIIa). When given at therapeutic levels, rFVIIa can enhance tissue factor (TF) dependent activation of FX as well as activating FX independently of TF. At therapeutic levels rFVIIa can also activate FIX. The goal of this study was to assess the role of the FIXa activated by rFVIIa when emicizumab is added to hemophilia A plasma. Methods. Thrombin generation assays were done in plasma using 100 µM lipid and 420 µM Z-Gly-Gly-Arg-AMC with or without emicizumab at 55 µg/mL which is the clinical steady state level. The reactions were initiated with low (1 pM) tissue factor (TF). rFVIIa was added at concentrations of 25-100 nM with 25 nM corresponding to the plasma levels achieved by a single clinical dose of 90 µg/mL. To study to the role of factor IX in the absence of factor VIII, it was necessary to create a double deficient plasma (factors VIII and IX deficient). This was done by taking antigen negative hemophilia B plasma and adding a neutralizing antibody to factor VIII (Haematologic Technologies, Essex Junction, VT, USA). Now varying concentrations of factor IX could be reconstituted into the plasma to give hemophilia A plasma. Results. As expected, in the double deficient plasma with low TF there was essentially no thrombin generation. Also as expected from previous studies, addition of rFVIIa to double deficient plasma gave a dose dependent increase in thrombin generation through activation of FX. Interestingly addition of plasma levels of FIX to the rFVIIa did not increase thrombin generation. Starting from double deficient plasma, as expected emicizumab did not increase thrombin generation since no factor IX was present. Also, in double deficient plasma with rFVIIa, emicizumab did not increase thrombin generation. But in double deficient plasma with FIX and rFVIIa, emicizumab significantly increased thrombin generation. The levels of thrombin generation increased in a dose dependent fashion with higher concentrations of rFVIIa giving higher levels of thrombin generation. Conclusion. Since addition of FIX to the double deficient plasma with rFVIIa did not increase thrombin generation, it suggests that rFVIIa activation of FX is the only source of the FXa needed for thrombin generation. So in the absence of factor VIII (or emicizumab) FIX activation does not contribute to thrombin generation. However, in the presence of emicizumab, while rFVIIa can still activate FX, FIXa formed by rFVIIa can complex with emicizumab to provide an additional source of FX activation. Thus rFVIIa activation of FIX explains the synergistic effect in thrombin generation observed when combining rFVIIa with emicizumab. The generation of FIXa at a site of injury is consistent with the safety profile observed in clinical use. Disclosures Monroe: Novo Nordisk:Research Funding.Ezban:Novo Nordisk:Current Employment.Hoffman:Novo Nordisk:Research Funding.

scholarly journals Inhibition of tissue factor/factor VIIa activity in plasma requires factor X and an additional plasma component

Blood ◽  
1985 ◽  
Vol 66 (1) ◽  
pp. 204-212 ◽  
Author(s):  
NL Sanders ◽  
SP Bajaj ◽  
A Zivelin ◽  
SI Rapaport
Keyword(s):  
Tissue Factor ◽  
Factor Viia ◽  
Factor Ix ◽  
Factor Vii ◽  
Factor X ◽  
Additional Material ◽  
Plasma Reaction ◽  
Progress Curve ◽  
Peptide Release ◽  
Release Data

Abstract A study was carried out to explore requirements for the inhibition of tissue factor-factor VIIa enzymatic activity in plasma. Reaction mixtures contained plasma, 3H-factor IX or 3H-factor X, tissue factor (vol/vol 2.4% to 24%), and calcium. Tissue factor-factor VIIa activity was evaluated from progress curves of activation of factor IX or factor X, plotted from tritiated activation peptide release data. With normal plasma, progress curves exhibited initial limited activation followed by a plateau indicative of loss of tissue factor-factor VIIa activity. With hereditary factor X-deficient plasma treated with factor X antibodies, progress curves revealed full factor IX activation. Adding only 0.4 micrograms/mL factor X (final concentration) could restore inhibition. Inhibition was not observed in purified systems containing 6% to 24% tissue factor, factor VII, 0.5 micrograms/mL, factor IX, 13 micrograms/mL, and factor X up to 0.8 micrograms/mL, but could be induced by adding barium-absorbed plasma to the reaction mixture. Thus, both factor X and an additional material in plasma were required for inhibition. The amount of factor X needed appeared related to the concentration of tissue factor; adding more tissue factor at the plateau of a progress curve induced further activation. These results also indicate that inhibited reaction mixtures contained active free factor VII(a). Preliminary data suggest that inhibition may stem from loss of activity of the tissue factor component of the tissue factor- factor VII(a) complex.

scholarly journals Studies of a mechanism inhibiting the initiation of the extrinsic pathway of coagulation

Blood ◽  
1987 ◽  
Vol 69 (2) ◽  
pp. 645-651 ◽  
Author(s):  
LV Rao ◽  
SI Rapaport
Keyword(s):  
Tissue Factor ◽  
Factor Viia ◽  
Factor Xa ◽  
Factor Ix ◽  
Factor Vii ◽  
Factor X ◽  
Extrinsic Pathway ◽  
Mechanism Of Inhibition ◽  
Peptide Release ◽  
Release Assay

Abstract We have extended earlier studies (Blood 66:204, 1985) of a mechanism of inhibition of factor VIIa/tissue factor activity that requires a plasma component (called herein extrinsic pathway inhibitor or EPI) and factor Xa. An activated peptide release assay using 3H-factor IX as a substrate was used to evaluate inhibition. Increasing the tissue factor concentration from 20% to 40% (vol/vol) overcame the inhibitory mechanism in normal plasma but not in factor VII-deficient plasma supplemented with a low concentration of factor VII. A second wave of factor IX activation obtained by a second addition of tissue factor to plasma with a normal factor VII concentration was almost abolished by supplementing the reaction mixture with additional EPI and factor X. Factor Xa's active site was necessary for factor Xa's contribution to inhibition, but preliminary incubation of factor Xa with EPI in the absence of factor VIIa/tissue factor complex or of factor VIIa/tissue factor complex in the absence of EPI did not replace the need for the simultaneous presence of factor Xa, factor VIIa/tissue factor, calcium, and EPI in an inhibitory reaction mixture. Inhibition of factor VIIa/tissue factor was reversible; both tissue factor and factor VIIa activity could be recovered from a dissociated, inhibited factor VIIa/tissue factor complex. EPI appeared to bind to a factor VIIa/tissue factor complex formed in the presence of factor Xa but not to a factor VIIa/tissue factor complex formed in the absence of factor Xa.

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