Your search keyword '"Villoutreix BO"' showing total 7 results

1. Gly197Arg mutation in protein C causes recurrent thrombosis in a heterozygous carrier.

Author

Lu Y, Giri H, Villoutreix BO, Ding Q, Wang X, and Rezaie AR

Subjects

Animals, Blood Coagulation Tests, Heterozygote, Humans, Mutation, Thrombin, Protein C genetics, Thrombosis genetics

Abstract

Background: Activated protein C (APC) downregulates thrombin generation by inactivating procoagulant cofactors Va and VIIIa by limited proteolysis. We identified two protein C-deficient patients both of whom carry a heterozygous Gly197 to Arg (G197R) mutation in PROC and experience venous thrombosis., Objective: The objective of this study was to determine the molecular basis of the clotting defect in patients carrying the G197R mutation., Methods: We expressed protein C-G197R in mammalian cells and characterized its properties in established coagulation and anti-inflammatory assay systems., Results: The activation of protein C-G197R by thrombin was improved ~10-fold; however, its activation by thrombin was not promoted by thrombomodulin (TM). In a tissue factor-mediated thrombin generation assay, the addition of soluble TM to protein C-deficient plasma, supplemented with protein C-G197R, did not have a significant inhibitory effect on thrombin generation parameters. APC-G197R did not exhibit a significant anticoagulant activity in either purified or plasma-based assay systems. APC-G197R was essentially inactive because it showed no activity in an aPTT assay. Anti-inflammatory activity of APC-G197R was also dramatically impaired as determined by an endothelial cell permeability assay. Structural modeling predicted that the side-chain of Arg cannot be accommodated at this site of APC without a major distortion of the local structure that appears to propagate and adversely affect the reactivity/folding of the catalytic pocket., Conclusion: The G197R mutation in patients appears to be functionally equivalent to a heterozygous protein C knockout with half of the protein having no significant activity and thus causing thrombosis., (© 2020 International Society on Thrombosis and Haemostasis.)

Published

2020

2. Expression and functional characterization of two natural heparin-binding site variants of antithrombin.

Author

Dinarvand P, Yang L, Villoutreix BO, and Rezaie AR

Subjects

Animals, Antithrombin III chemistry, Antithrombin III genetics, Binding Sites, Disease Models, Animal, Endothelial Cells metabolism, HEK293 Cells, Humans, Inflammation blood, Inflammation genetics, Inflammation prevention & control, Kinetics, Mice, Mutation, Protein Binding, Protein Conformation, Signal Transduction, Structure-Activity Relationship, Thrombosis blood, Thrombosis genetics, Antithrombin III metabolism, Heparin metabolism

Abstract

Essentials Heparin-binding site (HBS) variants of antithrombin (AT) are associated with thrombosis risk. HSB variants have, in general, normal progressive inhibitory activity but reduced heparin affinity. Thrombosis in HSB carriers has been primarily attributed to the loss of heparin cofactor activity. Results here demonstrate that HSB variants of AT also lack anti-inflammatory signaling functions., Summary: Background Several heparin-binding site (HBS) variants of antithrombin (AT) have been identified that predispose carriers to a higher incidence of thrombosis. Thrombosis in carriers of HBS variants has been primarily attributed to a loss in their heparin-dependent anticoagulant function. Objective The objective of this study was to determine whether HSB mutations affect the anti-inflammatory functions of variants. Methods Two HBS variants of AT (AT-I7N and AT-L99F), which are known to be associated with a higher incidence of thrombosis, were expressed in mammalian cells and purified to homogeneity. These variants were characterized by kinetic assays followed by analysis of their activities in established cellular and/or in vivo inflammatory models. The possible effects of mutations on AT structure were also evaluated by molecular modeling. Results The results indicated that, whereas progressive inhibitory activities of variants were minimally affected, their heparin affinity and inhibitory activity in the presence of heparin were markedly decreased. Unlike wild-type AT, neither AT variant was capable of inhibiting activation of nuclear factor-κB or downregulation of expression of cell adhesion molecules in response to lipopolysaccharide (LPS). Similarly, neither variant elicited barrier protective activity in response to LPS. Structural analysis suggested that the L99F substitution locally destabilizes AT structure. Conclusions It is concluded that the L99F mutation of AT is associated with destabilization of the serpin structure, and that the loss of anti-inflammatory signaling function of the HBS variants may also contribute to enhanced thrombosis in carriers of HBS mutations., (© 2017 International Society on Thrombosis and Haemostasis.)

Published

2018

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

Author

Stoilova-McPhie S, Parmenter CD, Segers K, Villoutreix BO, and Nicolaes GA

Subjects

Factor Va metabolism, Humans, Lipids, Membrane Proteins chemistry, Microscopy, Electron, Transmission, Phosphatidylserines metabolism, Protein Conformation, Factor Va chemistry, Phosphatidylserines chemistry

Abstract

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.

Published

2008

4. Molecular models of the procoagulant factor VIIIa-factor IXa complex.

Author

Autin L, Miteva MA, Lee WH, Mertens K, Radtke KP, and Villoutreix BO

Subjects

Algorithms, Cysteine Endopeptidases chemistry, Humans, Multiprotein Complexes chemistry, Neoplasm Proteins chemistry, Protein Binding, Protein Conformation, Structural Homology, Protein, Blood Coagulation, Factor IXa chemistry, Factor VIIIa chemistry, Models, Molecular

Abstract

Background: Formation of the intrinsic tenase complex is an essential event in the procoagulant reactions that lead to clot formation. The tenase complex is formed when the activated serine protease, Factor IXa (FIXa), and its cofactor Factor VIIIa (FVIIIa) assemble on a phospholipid surface to proteolytically convert the zymogen Factor X (FX) into its active form FXa. The physiological relevance of the tenase complex is evident in hemophilia A or B patients who present with bleeding disorders., Objectives: The purpose of this study was to establish three-dimensional (3D) models of the FVIIIa-FIXa complex., Methods: First, we built two new theoretical models of FVIIIa via homology modeling, inter-domain docking and loop simulation algorithms as well as a model for FIXa. This was followed by pseudo-Brownian protein-protein docking in internal coordinates with the ICM (Internal Coordinates Mechanics) program between the two FVIIIa and the FIXa structures., Results: Ten representative models of this complex are presented based on agreements with known experimental data and according to structural criteria., Conclusions: These novel 3D models will help guide future site directed mutagenesis aimed at improving the functionality of FVIIIa and/or FIXa and will contribute to a better understanding of the role of this macromolecular complex in the blood coagulation cascade.

Published

2005

5. A critical role for Gly25 in the B chain of human thrombin.

Author

Akhavan S, Miteva MA, Villoutreix BO, Venisse L, Peyvandi F, Mannucci PM, Guillin MC, and Bezeaud A

Subjects

Animals, Binding Sites, CHO Cells, COS Cells, Catalysis, Cricetinae, DNA Mutational Analysis, DNA, Complementary metabolism, Fibrin chemistry, Fibrinogen chemistry, Homozygote, Humans, Hydrolysis, Kinetics, Models, Molecular, Mutation, Protein Conformation, Protein Structure, Tertiary, Prothrombin chemistry, Prothrombin genetics, Recombinant Proteins chemistry, Snake Venoms, Snakes, Thrombin antagonists & inhibitors, Time Factors, Transfection, Glycine chemistry, Thrombin chemistry

Abstract

We have recently identified (Akhavan S et al., Thromb Haemost 2000; 84: 989-97) a patient with a mild bleeding diathesis associated to an homozygous mutation in the thrombin B chain (Gly25Ser, chymotrypsinogen numbering, i.e. position 330 in human prothrombin numbering). Transient transfection of wild-type prothrombin (FII-WT) and mutant prothrombin (designated FII-G25(330)S) cDNA in COS-7 cells showed a mild reduction (50%) in FII-G25(330)S production. Recombinant proteins, stably expressed in Chinese hamster ovary cells, were isolated and activated by Taipan snake or Echis carinatus venoms. We show that the G25(330)S mutation results in a decrease in the rate of prothrombin proteolytic activation. The mutation also significantly decreases (i) the catalytic activity of thrombin with a 9-fold reduction in catalytic efficiency of the mutant toward S-2238; (ii) the interaction with benzamidine; (iii) the rate of inhibition by TLCK and antithrombin; and (iv) the rate of hydrolysis of macromolecular substrates (fibrinogen, protein C). In contrast, exosite I does not appear to be affected by the molecular defect. These results, together with molecular modeling and dynamics, indicate that Gly25(330) is important for proper expression and probably proper folding of prothrombin, and also plays a critical role in both the alignment of the catalytic triad and the flexibility of one of the activation segments of prothrombin.

Published

2005

6. Molecular recognition in the protein C anticoagulant pathway.

Author

Dahlbäck B and Villoutreix BO

Subjects

Animals, Anticoagulants chemistry, Factor VIIIa chemistry, Factor Va chemistry, Factor X chemistry, Humans, Models, Molecular, Peptides chemistry, Prothrombin chemistry, Serine Endopeptidases metabolism, Anticoagulants metabolism, Protein C chemistry, Protein C genetics

Abstract

The protein C (PC) anticoagulant system provides specific and efficient control of blood coagulation. The system comprises circulating or membrane-bound protein components that take part in complicated multimolecular protein complexes being assembled on specific cellular phospholipid membranes. Each of the participating proteins is composed of multiple domains, many of which are known at the level of their three-dimensional structures. The key component of the PC system, the vitamin K-dependent PC, circulates in blood as zymogen to an anticoagulant serine protease. Activation is achieved on the surface of endothelial cells by thrombin bound to the membrane protein thrombomodulin. The endothelial PC receptor binds the Gla domain of PC and stimulates the activation. Activated PC (APC) modulates the activity of blood coagulation by specific proteolytic cleavages of a limited number of peptide bonds in factor (F)VIIIa and FVa, cofactors in the activation of FX and prothrombin, respectively. These reactions occur on the surface of negatively charged phospholipid membranes and are stimulated by the vitamin K-dependent protein S. Regulation of FVIIIa activity by APC is stimulated not only by protein S but also by FV, which, like thrombin, is a Janus-faced protein with both pro- and anticoagulant potential. However, whereas the properties of thrombin are modulated by protein-protein interactions, the specificity of FV function is governed by proteolysis by pro- or anti-coagulant enzymes. The molecular recognition of the PC system is beginning to be unravelled and provides insights into a fascinating and intricate molecular scenario.

Published

2003

7. Functional analysis of the EGF-like domain mutations Pro55Ser and Pro55Leu, which cause mild hemophilia B.

Author

Knobe KE, Persson KE, Sjörin E, Villoutreix BO, Stenflo J, and Ljung RC

Subjects

Calcium metabolism, DNA Mutational Analysis, Factor IX chemistry, Factor IX genetics, Factor IX metabolism, Factor IXa chemistry, Factor VIIa metabolism, Factor X metabolism, Humans, Male, Middle Aged, Protein Structure, Tertiary physiology, Thromboplastin metabolism, Epidermal Growth Factor chemistry, Factor IXa genetics, Hemophilia B genetics, Mutation, Missense

Abstract

We studied the functional role of two mutations, Pro55Ser and Pro55Leu, located in the N-terminal Epidermal Growth Factor-like domain (EGF1) of coagulation factor (F) IX. Both mutations cause mild hemophilia B with habitual FIX coagulant activities of 10-12% and FIX antigen levels of 50%. We found that activation by FVIIa/TF and FXIa was normal for FIXPro55Ser, but resulted in proteolysis of FIXPro55Leu at Arg318-Ser319 with a concomitant loss of amidolytic activity, suggesting intramolecular communication between EGF1 and the serine protease domain in FIX. This was further supported by experiments using an anti-EGF1 monoclonal antibody. Activation of FX by FIXaPro55Ser was impaired in both the presence and the absence of phospholipid or FVIIIa, indicating that Pro55 is not directly involved in binding to FVIIIa. We also studied the effect of the two Pro55 mutations on Ca2+ affinity and found only small changes. Thus, the Pro55Ser mutation causes hemophilia primarily through to an impaired ability to activate FX whereas at least in vitro the Pro55Leu defect interferes with the activation of FIX.

Published

2003