Mechanisms of autoantibody-induced monocyte tissue factor expression

Mechanisms of autoantibody-induced monocyte tissue factor expression

Thrombosis Research (2004) 114, 391--396 intl.elsevierhealth.com/journals/thre Mechanisms of autoantibody-induced monocyte tissue factor expression ...

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Thrombosis Research (2004) 114, 391--396

intl.elsevierhealth.com/journals/thre

Mechanisms of autoantibody-induced monocyte tissue factor expression Alisa S. Wolberg a, Robert A.S. Roubey b,* a

Department of Pathology and Laboratory Medicine, USA Department of Medicine, Division of Rheumatology and Immunology, The University of North Carolina at Chapel Hill, CB #7280, Rm. 3330 Thurston Building, Chapel Hill, NC 27599-7280, USA

b

Received 25 May 2004; accepted 9 June 2004 Available online 19 July 2004

KEYWORDS Tissue factor; Tissue factor pathway inhibitor; Monocytes; Endothelial cells

ABSTRACT The expression of tissue factor (TF) activity to flowing blood is the trigger for physiological coagulation as well as many types of thrombosis. A growing body of evidence suggests that increased tissue factor activity is a significant contributor towards the hypercoagulability associated with the antiphospholipid syndrome (APS). The increase in tissue factor activity appears to be due to increased transcription and translation of nascent tissue factor molecules but is not due to deencryption of existing tissue factor molecules on cells. Autoantibodies and/or immune complexes circulating in APS patients appear to enhance the expression of tissue factor activity on monocytes and endothelial cells. Anti-h2-glycoprotein I (h2GPI) autoantibodies have been specifically implicated in the antibody-mediated enhancement of tissue factor activity. The presence of antibodies against tissue factor pathway inhibitor (TFPI) in certain APS patients suggests that negative regulation of tissue factor activity might also be impaired in these patients. Given a mechanism involving increased tissue factor activity in APS-associated thrombosis, agents specifically targeting tissue factor activity may be a novel and efficacious therapy that is safer than current approaches to the management of APS. A 2004 Elsevier Ltd. All rights reserved.

Tissue factor and coagulation Tissue factor (TF) is the physiological initiator of normal coagulation as well as clotting observed in thrombotic disease. TF is a high-affinity receptor for * Corresponding author. Tel.: +1-919-966-0578; fax: +1-919966-1739. E-mail address: [email protected] (R.A.S. Roubey).

coagulation factor VII(a) and functions as an essential cofactor for factor VIIa to efficiently cleave factors IX and X to their active forms (factors IXa and Xa, respectively). The factors Xa/Va complex then cleaves prothrombin to thrombin (see Fig. 1). Cell-bound TF is a 47-kDa transmembrane glycoprotein that is constitutively expressed on the surfaces of various cell types outside the vasculature but is not expressed on endothelial cells or peripheral

0049-3848/$ - see front matter A 2004 Elsevier Ltd. All rights reserved. doi:10.1016/j.thromres.2004.06.012

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Figure 1 Regulation of the TF pathway. Functionally active TF expressed on a cell is a high-affinity receptor and cofactor for the enzyme, factor VIIa. Factor VIIa/TF cleaves factors X and IX to form factors Xa and IXa (factors IX and IXa not shown). Together with factor Va, factor Xa forms the prothrombinase complex and cleaves prothrombin (factor II) to yield thrombin (factor IIa). TFPI inhibits this pathway by binding to and inactivating factor Xa. The factor Xa/TFPI complex then inhibits factor VIIa/ TF, forming a quaternary complex.

blood cells (at least not in a functionally active form). A soluble form of TF also circulates in blood at approximately 60 pg/ml [1,2]. This circulating TF is likely in an inactive form, but can become procoagulant and is hypothesized to support thrombus propagation at sites of vascular injury [1]. Structurally, TF is a member of the cytokine receptor superfamily. Genetic deficiency of TF in mice is lethal at the embryonic stage [3].

Regulation of TF activity on cells in contact with blood Endothelial cells, blood monocytes, and other cells in contact with flowing blood do not constitutively express functional TF and do not have intracellular stores of TF [4]. However, in response to stimulation with certain agents, including lipopolysaccharide (LPS) [5], endothelial microparticles [6], chemokines [7], anti-platelet factor 4/heparin antibodies [8], homocysteine [9], P-selectin [10] and/or certain inflammatory cytokines, these cells express TF activity via transcription and synthesis of nascent TF molecules. Some cells may express a nonfunctional (encrypted) form of TF. These and other TF-expressing cells can regulate TF via a rapid mechanism (de-encryption) whereby the TF activity on a cell increases without a concomitant increase in TF antigen. De-encryption results from

A.S. Wolberg, R.A.S. Roubey the stimulation of TF-bearing cells with agents, such as calcium ionophore, cycloheximide, hydrogen peroxide or freeze/thaw cycles, and results in up to 11-fold increases in the measured TF activity of a cell [11--14]. De-encryption can be attributed to changes in morphology, membrane lipid expression (increased cell surface PS expression) and to changes in the TF molecule itself [13,15]. It has been shown that TF encryption is due in part to the dimerization of TF molecules on the cell surface. In this model, TF dimers are inactive and TF activity after stimulation is due to the rapid dissociation of dimers into active TF monomers [12].

Tissue factor pathway inhibitor Tissue factor pathway inhibitor (TFPI) is a trivalent Kunitz-type protease inhibitor that modulates the initiation of coagulation via factor Xa-dependent feedback inhibition of TF/VIIa. TFPI inhibits TF activity by forming a quaternary complex (TFPI, TF, VIIa, Xa) via an interaction that requires calcium ions and is enhanced by anionic phospholipid membrane (reviewed in Ref. [16]). TFPI can also inhibit VIIa/TF without factor Xa [17] and may inhibit factor Xa directly in a phospholipid-independent manner [18]. There are three intravascular pools of TFPI. About 10--50% of TFPI circulates in plasma at a concentration of 50--150 ng/ml, much of which is complexed to lipoproteins. Approximately 50--90% of TFPI is bound to vessel wall glycosaminoglycans and can be released into plasma by injection of heparin. A small amount of TFPI is stored in platelets and released upon platelet activation.

The TF pathway and thrombosis Increased TF activity has been implicated in a number of thrombotic conditions and hypercoagulable states. Increased expression of TF on vascular endothelial cells and monocytes has been reported in patients with cancer [19], gram-negative bacterial sepsis [20], atherosclerosis [21], and OKT3induced coagulopathy in renal transplant patients [22]. The physiological importance of TFPI is evidenced by the fact that ‘‘knockout’’ of the TFPI gene in mice is lethal at the embryonic stage [23]. Low levels of endogenous free TFPI have not been associated with thrombosis. A TFPI polymorphism

Mechanisms of autoantibody-induced monocyte tissue factor expression has been described [24]; however, the role of this polymorphism in thrombosis is controversial.

The TF pathway in APS Sera from certain patients with systemic lupus erythematosus enhance the procoagulant activity of cultured endothelial cells [25--28]. Most data support the hypothesis that the stimulating factor(s) are the patients’ autoantibodies, although the effects of the autoantibodies on cellular procoagulant activity may be enhanced by suboptimal concentrations of TNF-a [27,29]. There is growing evidence that increased TF activity on circulating blood monocytes is an important mechanism of hypercoagulability in antiphospholipid syndrome (APS) and that autoantibodies are directly responsible. In 1990, de Prost et al. [30] reported that monocyte procoagulant activity was increased in patients with systemic lupus erythematosus, about half of whom had lupus anticoagulants. Serum from these patients increased TF activity on normal monocytes, although the serum factor responsible did not appear to be immunoglobulins. In retrospect, the experiments with purified IgG were performed under serum-free conditions and the absence of h2-glycoprotein I (h2GPI) may have been a key factor. Subsequently, a number of groups have found that serum, plasma, purified total IgG, and anti-h2GPI antibodies from APS patients enhance TF expression and procoagulant activity on normal monocytes [31--37]. F(abV)2 antibody fragments retain these procoagulant effects, suggesting that Fc receptors are not required for the procoagulant activity of these antibodies [31,38]. Additionally, several of these studies demonstrated that monocytes isolated from APS patients exhibit increased expression of TF and TF mRNA [33,37,39,40]. Anti-h2GPI human monoclonal antibodies derived from peripheral B cells of APS patients enhance monocyte TF activity and levels of TF mRNA in a h2GPI-dependent fashion [33,35]. Using an anti-h2GPI monoclonal antibody [41], as well as affinity-purified anti-h2GPI autoantibodies from an APS patient, we have demonstrated that antih2GPI antibodies are at least one specificity involved in inducing monocyte TF. Time course experiments demonstrated that APS patient IgG increased both TF mRNA and activity, with peaks in expression at 2 and 6 h, respectively [38]. These same antibodies did not up-regulate TF activity by de-encryption, suggesting that de-encryption of existing TF on cells is not an APS thrombosis-related mechanism [42].

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We and others have also detected autoantibodies directed against TFPI in APS patients and found an association of these antibodies with arterial thrombosis and stroke [43,44]. Adams et al. [45] identified anti-TFPI activity in IgG from 5 of 33 APS patients examined. Another mechanism may be related to recent reports of cellular autoimmunity to h2GPI. Visvanathan and McNeil [46] reported that h2GPI-specific T cells are of the TH1 phenotype and produce interferon-g, a cytokine known to stimulate monocyte TF expression [47].

Pharmacological inhibition of TF as an APS therapy Given the relationship between increased TF activity, thrombosis, and APS, pharmacological agents that block monocyte TF activity may be a novel and attractive therapeutic approach in APS. Such targeted treatments would likely have less risk of bleeding complications than long-term anticoagulation with warfarin (the current treatment for prevention of recurrent thrombosis in APS). Several agents are known to decrease TF activity in vitro and in vivo. Dilazep, an antiplatelet agent, inhibits in vitro monocyte and endothelial cell TF expression induced by several stimuli including TNF-a, thrombin, and phorbol ester [48]. In vivo, dilazep decreases plasma levels of soluble TF, D-dimer, thrombin--antithrombin complexes, and fibrinogen in patients with a hypercoagulable state associated with malignancy [48]. Our data demonstrate that dilazep inhibited APS IgG-induced monocyte TF activity in a dose-dependent fashion. Because dilazep inhibits the uptake of adenosine by increasing the extracellular concentration of adenosine, and because adenosine inhibits TF expression [49,50], we have also examined the ability of theophylline, a nonspecific adenosine receptor antagonist, to block dilazep-mediated inhibition of TF expression. Theophylline partially blocked the inhibition of TF expression by dilazep, suggesting that dilazep mediates TF expression via its effect on adenosine transport. Future studies with specific adenosine receptor antagonists will better define dilazep’s mechanism of action. In addition to dilazep, several other drugs have been shown to inhibit increased expression of TF on monocytes and endothelial cells induced by LPS and other stimuli. The antiplatelet agent dipyridamole is an adenosine uptake inhibitor similar to dilazep and may have similar anti-TF properties. Pentoxifylline inhibits LPS-induced monocyte TF expression [51,52]. Several angiotensin-converting

394 enzyme inhibitors (captopril, imidapril, and fosinopril) significantly inhibit LPS-induced monocyte TF activity, antigen expression, and gene transcription [53,54]. Lastly, the 3-hydroxy-3-methylglutaryl coenzyme A (HMG--CoA) reductase inhibitors (‘‘statins’’), including simvastatin and fluvastatin, reduce TF activity, antigen expression, and gene transcription [55--57]. In particular, fluvastatin has recently been shown to inhibit thrombosis in a murine model of APS [58]. Direct inhibitors of TF activity could also prove excellent therapeutics in the treatment and management of APS. Active site-inactivated factor VIIa (FVIIai) is a modified form of recombinant factor VIIa in which the enzymatic active site has been blocked by a synthetic inhibitor. FVIIai has exhibited potent antithrombotic effects in two separate animal models (rat and rabbit) of arterial thrombosis [59,60].

Future directions Growing evidence supports the hypothesis that thrombosis in the antiphospholipid syndrome is caused by the increased expression of TF activity on monocytes and vascular endothelial cells. Recent work has identified increased transcription and translation of nascent TF as the mechanism of this increased expression of TF activity. Experiments examining the autoantibody-mediated regulation of TF activity will provide important information as to the mechanism of this activity. Therapies that specifically target the regulation of TF activity may provide an improved approach to the management of the antiphospholipid syndrome.

References [1] Giesen PLA, Rauch U, Bohrmann B, Kling D, Roque M, Fallon JT, et al. Blood-borne tissue factor: another view of thrombosis. Proc Natl Acad Sci U S A 1999;96:2311--5. [2] Bogdanov VY, Balasubramanian V, Hathcock J, Vele O, Lieb M, Nemerson Y. Alternatively spliced human tissue factor: a circulating, soluble, thrombogenic protein. Nat Med 2003;9:458--62. [3] Bugge TH, Xiao Q, Kombrinck KW, Flick MJ, Holmback K, Danton MJ, et al. Fatal embryonic bleeding events in mice lacking tissue factor, the cell-associated initiator of blood coagulation. Proc Natl Acad Sci U S A 1996;93:6258--63. [4] Drake TA, Ruf W, Morrissey JH, Edgington TS. Functional tissue factor is entirely cell surface expressed on lipopolysaccharide-stimulated human blood monocytes and a constitutively tissue factor-producing neoplastic cell line. J Cell Biol 1989;109:389--95. [5] Gregory SA, Morrissey JH, Edgington TS. Regulation of tissue factor gene expression in the monocyte procoagulant response to endotoxin. Mol Cell Biol 1989;9:2752--5.

A.S. Wolberg, R.A.S. Roubey [6] Sabatier F, Roux V, Anfosso F, Camoin L, Sampol J, DignatGeroge F. Interaction of endothelial microparticles with monocytic cells in vitro induces tissue factor-dependent procoagulant activity. Blood 2002;99:3962--70. [7] Lee WH, Kim SH, Jeong EM, Choi YH, Kim DI, Lee BB, et al. A novel chemokine, Leukotactin-1, induces chemotaxis, pro-atherogenic cytokines, and tissue factor expression in atherosclerosis. Atherosclerosis 2002;161:255--60. [8] Arepally GM, Mayer IM. Antibodies from patients with heparin-induced thrombocytopenia stimulate monocytic cells to express tissue factor and secrete interleukin-8. Blood 2001;98:1252--4. [9] Khajuria A, Houston DS. Induction of monocyte tissue factor expression by homocysteine: a possible mechanism for thrombosis. Blood 2000;96:966--72. [10] Celi A, Pellegrini G, Lorenzet R, DeBlasi A, Ready N, Furie BC, et al. P-selectin induces the expression of tissue factor on monocytes. Proc Natl Acad Sci U S A 1994;91:8767--71. [11] Walsh JD, Geczy CL. Discordant expression of tissue factor antigen and procoagulant activity on human monocytes activated with LPS and low dose cycloheximide. Thromb Haemost 1991;66:552--8. [12] Bach RR, Moldow CF. Mechanism of tissue factor activation on HL-60 cells. Blood 1997;89:3270--6. [13] Wolberg AS, Monroe DM, Roberts HR, Hoffman MR. Tissue factor de-encryption: Ionophore treatment induces changes in tissue factor activity by phosphatidylserine-dependent and -independent mechanisms. Blood Coagul Fibrinolysis 1999;10:201--10. [14] Penn MS, Patel CV, Cui M.-Z., DiCorleto PE, Chisolm GM. LDL increases inactive tissue factor on vascular smooth muscle cell surfaces. Circulation 1999;99:1753--9. [15] Bach R, Rifkin DB. Expression of tissue factor procoagulant activity: regulation by cytosolic calcium. Proc Natl Acad Sci U S A 1990;87:6995--9. [16] Broze Jr GJ. Tissue factor pathway inhibitor. Thromb Haemost 1995;74:90--3. [17] Callander NS, Rao LV, Nordfang O, Sandset PM, WarnCramer B, Rapaport SI. Mechanisms of binding of recombinant extrinsic pathway inhibitor (rEPI) to cultured cell surfaces. Evidence that rEPI can bind to and inhibit factor VIIa-tissue factor complexes in the absence of factor Xa. J Biol Chem 1992;267:876--82. [18] Jesty J, Wun TC, Lorenz A. Kinetics of the inhibition of factor Xa and the tissue factor-factor VIIa complex by the tissue factor pathway inhibitor in the presence and absence of heparin. Biochemistry 1994;33:12686--94. [19] Edwards RL, Rickles FR, Cronlund M. Abnormalities of blood coagulation in patients with cancer. Mononuclear cell tissue factor generation. J Lab Clin Med 1981;98:917--28. [20] Osterud B, Flaegstad T. Increased tissue thromboplastin activity in monocytes of patients with meningococcal infection: related to an unfavourable prognosis. Thromb Haemost 1983;49:5--7. [21] Weis JR, Pitas RE, Wilson BD, Rodgers GM. Oxidized lowdensity lipoprotein increases cultured human endothelial cell tissue factor activity and reduces protein C activation. FASEB J 1991;5:2459--65. [22] Pradier O, Surquin M, Stordeur P, de Pauw L, Kinnaert P, Vereerstraeten P, et al. Monocyte procoagulant activity induced by in vivo administration of the OKT3 monoclonal antibody. Blood 1996;87:3768--74. [23] Broze Jr GJ. Tissue factor pathway inhibitor gene disruption. Blood Coagul Fibrinolysis 1998;9:S89--92. [24] Kleesiek K, Schmidt M, Gotting C, Schwenz B, Lange S, Muller-Berghaus G, et al. The 536C ! T transition in the human tissue factor pathway inhibitor (TFPI) gene is stat-

Mechanisms of autoantibody-induced monocyte tissue factor expression

[25]

[26]

[27]

[28]

[29]

[30]

[31]

[32]

[33]

[34]

[35]

[36]

[37]

[38]

[39]

[40]

istically associated with a higher risk for venous thrombosis. Thromb Haemost 1999;82:1--5. Tannenbaum SH, Finko R, Cines DB. Antibody and immune complexes induce tissue factor production by human endothelial cells. J Immunol 1986;137:1532--7. Rustin MH, Bull HA, Machin SJ, Isenberg DA, Snaith ML, Dowd PM. Effects of the lupus anticoagulant in patients with systemic lupus erythematosus on endothelial cell prostacyclin release and procoagulant activity. J Invest Dermatol 1988;90:744--8. Hasselaar P, Derksen RH, Oosting JD, Blokzijl L, de Groot PG. Synergistic effect of low doses of tumor necrosis factor and sera from patients with systemic lupus erythematosus on the expression of procoagulant activity by cultured endothelial cells. Thromb Haemost 1989;62:654--60. Branch DW, Rodgers GM. Induction of endothelial cell tissue factor activity by sera from patients with antiphospholipid syndrome: a possible mechanism of thrombosis. J Am Obstet Gynecol 1993;168:206--10. Quadros NP, Roberts-Thomson PJ, Gallus AS. Sera from patients with systemic lupus erythematosus demonstrate enhanced IgG binding to endothelial cells pretreated with tumour necrosis factor alpha. Rheumatol Int 1995;15:99--105. de Prost D, Ollivier V, Ternisien C, Chollet-Martin S. Increased monocyte procoagulant activity independent of the lupus anticoagulant in patients with systemic lupus erythematosus. Thromb Haemost 1990;64:216--21. Schved JF, Gris JC, Ollivier V, Wautier JL, Tobelem G, Caen J. Procoagulant activity of endotoxin or tumor necrosis factor activated monocytes is enhanced by IgG from patients with lupus anticoagulant. J Am Hematol 1992;41:92--6. Kornberg A, Blank M, Kaufman S, Shoenfeld Y. Induction of tissue factor-like activity in monocytes by anti-cardiolipin antibodies. J Immunol 1994;153:1328--32. Amengual O, Atsumi T, Khamashta MA, Hughes GR. The role of the tissue factor pathway in the hypercoagulable state in patients with the antiphospholipid syndrome. Thromb Haemost 1998;79:276--81. Reverter JC, Tassies D, Font J, Monteagudo J, Escolar G, Ingelmo M, et al. Hypercoagulable state in patients with antiphospholipid syndrome is related to high induced tissue factor expression on monocytes and to low free protein S. Arterioscler Thromb Vasc Biol 1996;16:1319--26. Reverter JC, Tassies D, Font J, Khamashta MA, Ichikawa K, Cervera R, et al. Effects of human monoclonal anticardiolipin antibodies on platelet function and on tissue factor expression on monocytes. Arthritis Rheum 1998;41:1420--7. Lackner KJ, von Lerberg C, Barlage S, Schmitz G. Analysis of prothrombotic effects of two human monoclonal IgG antiphospholipid antibodies of apparently similar specificity. Thromb Haemost 2000;83:583--8. Ferro D, Saliola M, Meroni PL, Valesini G, Caroselli C, Pratico D, et al. Enhanced monocyte expression of tissue factor by oxidative stress in patients with antiphospholipid antibodies: effect of antioxidant treatment. J Thromb Haemost 2003;1:523--31. Zhou H, Wolberg AS, Roubey RAS. Characterization of monocyte tissue factor activity induced by IgG antiphospholipid antibodies and inhibition by dilazep. Blood 2004; in press. Cuadrado MJ, Lopez-Pedrera C, Khamashta MA, Camps MT, Tinahones F, Torres A, et al. Thrombosis in primary antiphospholipid syndrome: a pivotal role for monocyte tissue factor expression. Arthritis Rheum 1997;40:834--41. Dobado-Berrios PM, Lopez-Pedrera C, Velasco F, Aguirre

[41]

[42]

[43]

[44]

[45]

[46]

[47]

[48]

[49]

[50]

[51]

[52]

[53]

[54]

[55]

[56]

[57]

395

MJ, Torres A, Cuadrado MJ. Increased levels of tissue factor mRNA in mononuclear blood cells of patients with primary antiphospholipid syndrome. Thromb Haemost 1999;82: 1578--82. Roubey RA, Pratt CW, Buyon JP, Winfield JB. Lupus anticoagulant activity of autoimmune antiphospholipid antibodies is dependent upon beta 2-glycoprotein I. J Clin Invest 1992;90:1100--4. Wolberg AS, Roubey RAS. Anti-beta-2 glycoprotein I antibodies do not increase TF activity by de-encryption. Thromb Res 2004; in press. Cakir B, Arnett FC, Roubey RAS. Autoantibodies to tissue factor pathway inhibitor in the antiphospholipid syndrome. Arthritis Rheum [Abstr.] 1999;42:S281--2. Forastiero RR, Martinuzzo ME, Broze GJ. High titers of autoantibodies to tissue factor pathway inhibitor are associated with the antiphospholipid syndrome. J Thromb Haemost 2003;1:718--24. Adams MJ, Donohoe S, Mackie IJ, Machin SJ. Anti-tissue factor pathway inhibitor activity in patients with primary antiphospholipid syndrome. J Br Hematol 2001;114:375--9. Visvanathan S, McNeil HP. Cellular immunity to beta 2-glycoprotein-1 in patients with the antiphospholipid syndrome. J Immunol 1999;162:6919--25. del Prete G, de Carli M, Lammel RM, d’Elios MM, Daniel KC, Giusti B, et al. Th1 and Th2 T-helper cells exert opposite regulatory effects on procoagulant activity and tissue factor production by human monocytes. Blood 1995;86: 250--7. Deguchi H, Takeya H, Wada H, Gabazza EC, Hayashi N, Urano H, et al. Dilazep, an antiplatelet agent, inhibits tissue factor expression in endothelial cells and monocytes. Blood 1997;90:2345--56. Deguchi H, Takeya H, Urano H, Gabazza EC, Zhou H, Suzuki K. Adenosine regulates tissue factor expression on endothelial cells. Thromb Res 1998;91:57--64. Broussas M, Cornillet-Lefebvre P, Potron G, Nguyen P. Adenosine inhibits tissue factor expression by LPS-stimulated human monocytes: involvement of the A3 adenosine receptor. Thromb Haemost 2002;88:123--30. de Prost D. Pentoxifylline: a potential treatment for thrombosis associated with abnormal tissue factor expression by monocytes and endothelial cells. J Cardiovasc Pharmacol 1995;25:S114--8. Ollivier V, Ternisien C, Vu T, Hakim J, de Prost D. Pentoxifylline inhibits the expression of tissue factor mRNA in endotoxin-activated human monocytes. FEBS Lett 1993;322: 231--4. Soejima H, Ogawa H, Yasue H, Kaikita K, Takazoe K, Nishiyma K, et al. Angiotensin-converting enzyme inhibition reduces monocyte chemoattractant protein-1 and tissue factor levels in patients with myocardial infarction. J Am Coll Cardiol 1999;34:983--8. Napoleone E, De Santo A, Camera M, Tremoli E, Lorenzet R. Angiotensin-converting enzyme inhibitors downregulate tissue factor synthesis in monocytes. Circ Res 2000;86: 139--43. Ferro D, Basili S, Alessandri C, Cara D, Violi F. Inhibition of tissue-factor-mediated thrombin generation by simvastatin. Atherosclerosis 2000;149:111--6. Holschermann H, Hilgendorf A, Kemkes-Matthes B, Schonburg M, Bauer EP, Tillmanns H, et al. Simvastatin attenuates vascular hypercoagulability in cardiac transplant recipients. Transplantation 2000;69:1830--6. Rosenson RS, Tangney CC. Antiatherothrombotic properties of statins: implications for cardiovascular event reduction. JAMA 1998;279:1643--50.

396 [58] Ferrara DE, Liu X, Espinola RG, Meroni PL, Abukhalaf I, Harris EN, et al. Inhibition of the thrombogenic and inflammatory properties of antiphospholipid antibodies by fluvastatin in an in vivo animal model. Arthritis Rheum 2003;48: 3272--9. [59] Soderstrom T, Hedner U, Arnljots B. Active site-inactivated factor VIIa prevents thrombosis without increased surgical

A.S. Wolberg, R.A.S. Roubey bleeding: topical and intravenous administration in a rat model of deep arterial injury. J Vasc Surg 2001;33:1072--9. [60] Golino P, Ragni M, Cirillo P, D’Andrea D, Scognamiglio A, Ravera A, et al. Antithrombotic effects of recombinant human, active site-blocked factor VIIa in a rabbit model of recurrent arterial thrombosis. Circ Res 1998;82:39--46.