- Email: [email protected]
Antiphospholipid antibodies: Lessons from the bench
Journal of Autoimmunity 28 (2007) 129e133 www.elsevier.com/locate/jautimm
Review
Antiphospholipid antibodies: Lessons from the bench Takao Koike*, Miyuki Bohgaki, Olga Amengual, Tatsuya Atsumi Department of Medicine II, Hokkaido University Graduate School of Medicine, N15 W7, Kita-ku, Sapporo 060-8638, Japan
Abstract Antiphospholipid antibodies (aPL) are an heterogeneous group of circulating immunoglobulins arising in a wide range of infectious and autoimmune diseases. Since the early 80 s, the interest on anticardiolipin antibodies (aCL) has exponentially increased due to their association with thrombosis. The antiphospholipid syndrome (APS) was defined as a clinical disorder characterized by thrombosis and pregnancy morbidity associated to the persistent presence of aCL and/or lupus anticoagulant (LA). Thrombosis is the major manifestation in patients with aPL, but the spectrum of symptoms and signs associated with aPL has considerably broadened, and other manifestations such as thrombocytopenia, nonthrombotic neurological syndromes, psychiatric manifestations, livedo reticularis, skin ulcers, haemolytic anemia, pulmonary hypertension, cardiac valve abnormality and atherosclerosis have also been related to the presence of those antibodies. Numerous mechanisms have been proposed to explain the thrombotic tendency of patients with aPL, but the pathogenesis seems to be multifactorial. Ó 2007 Elsevier Ltd. All rights reserved. Keywords: Thrombosis; Antiphospholipid antibodies; Inflammation; Autoantibodies; Phospholipid antibody syndrome
1. Anticardiolipin and anti-b2-Glycoprotein I antibodies
2. Anti-b2-Glycoprotein I antibodies
The mechanisms involved in defining the thrombosis of patients with antiphospholipid antibody have been extensively studied by numerous investigators [1e9] (Table 1). Anticardiolipin antibodies (aCL) were detected using immunoassays with solid phase cardiolipin as a putative antigen [10,11]. However, antibodies directed to phospholipid-binding plasma or serum proteins, in particular b2-Glycoprotein I (b2GPI), are present in serum samples and can be components of the sample diluent and blocking buffer in various types of immunoassay systems. b2GPI-dependent aCL represent a predictor of future stroke and myocardial infarction in men, and are predictors of arterial thrombosis in patients with APS [12e14]. And also, antib2GPI antibodies have been often associated with venous thrombosis [15]. In contrast, aPL associated with infectious diseases bind directly to these negatively charged phospholipids, showing little association with thrombosis [16e19].
The mechanisms by which anti-b2GPI antibodies bind to b2GPI is unclear. It has been proposed that one antibody must bind two b2GPI molecules to obtain considerable avidity, the ‘‘dimerization theory’’ [20,21]. Another theory is based on the recognition of a cryptic epitope on b2GPI by aPL antib2GPI antibodies. This cryptic epitope is only exposed when b2GPI interacts with a lipid membrane composed of negatively charged phospholipids or when adsorbed on a polyoxygenated polystyrene plate treated with g-irradiation or electrons [22]. Consistent with this story, some reports showed the binding of aPL to b2GPI adsorbed on various commercially available oxidatively modified polystyrene plates, on a nitrocellulose membrane or on an experimentally g-ray/ UV-irradiated polystyrene plates [23,24]. Moreover, an epitope for aPL is exposed on the b2GPI molecule modified with glutaryldialdehyde [25]. The location of the epitope(s) on b2GPI for anti-b2GPI antibodies from APS patients has been largely discussed. Anti-b2GPI antibodies recognize different epitopes located in all five domains. In 1996, Igarashi et al. [26] firstly reported that domain IV or I are candidates for epitopic location on the
* Corresponding author. Tel.: þ81 11 706 5913; fax: þ81 11 706 7710. E-mail address: [email protected] (T. Koike). 0896-8411/$ - see front matter Ó 2007 Elsevier Ltd. All rights reserved. doi:10.1016/j.jaut.2007.02.009
130
T. Koike et al. / Journal of Autoimmunity 28 (2007) 129e133
Table 1 Proposed mechanism of antiphospholipid antibody-mediated thrombosis 1 2 3 4 5
Inhibition of endothelial cell prostacyclin production Procoagulant effects on platelets Impairment of fibrinolysis Interference with the thrombomodulin-protein S-protein C pathway Induction of procoagulant activity on cells (endothelial cells or monocytes)
b2GPI molecule by using a series of deletion mutant proteins of b2GPI. Wang et al. [27] showed the presence of antib2GPI antibodies directed to domain V. George et al. [28] demonstrated that domain IV of b2GPI is one of the major epitopic location for aCL raised in APS patients. In contrast, Iverson et al. [29] reported that anti-b2GPI antibodies, in the major population of APS patients, recognized a particular structure in domain I of b2GPI, and antibody binding was diminished by replacement of a related amino acid locates in the domain. However, it was also shown that some particular mutations made in domain IV also affected to antibody binding to b2GPI in anti-b2GPI antibody ELISA [30]. Recently, it has been showed that pathogenic aPL bind a cryptic epitope on domain I of b2GPI (G40eR43). This epitope is accessible for aPL only after conformational change which is induced by the binding of b2GPI to a negatively charged surface via a positive-charge patch in domain V of b2GPI [31,32]. Our group revealed that epitopic structures recognized by anti b2GPI antibodies are cryptic and that electrostatic interaction between domain IV and V are involved in their exposure [33]. 3. Cellular interaction and anti-b2GPI antibodies Intensive research works, performed in the last decade, have greatly advanced our knowledge of the mechanisms that explain why these antibodies may play a direct role in clot formation. Procoagulant cell activation, accompanied with TF expression, and TF pathway up-regulation is one of the key events considered to explain the pathophysiology of thrombosis in patients with APS. TF is the major initiator of the extrinsic coagulation system, functioning in coagulation by serving as the protein cofactor for the activated factor VII (FVIIa) [34]. Induced TF forms a complex with FVIIa that triggers blood clotting cascade by activating factors IX and X, leading to thrombin generation. In normal conditions, TF is not expressed on intravascular cells but it can be induced under some stimuli such as lipopolysaccharide, tumor necrosis factor a (TNFa), interleukin-1 (IL-1) and shear stress [35]. We showed elevated plasma levels of soluble TF in APS patients [36,37], and Cuadrado et al. [38] reported that monocytes prepared from APS patients had high TF expression. Tissue factor pathway inhibitor (TFPI), a physiological inhibitor of the extrinsic coagulation system, was also increased in plasma from patients with APS [36], suggesting up-regulation of TF and TFPI in affected patients. In in vitro experiments, there are numerous reports shown that IgG fraction from
patients with aPL induced procoagulant activity on cells [39e43]. Our previous observation that human monoclonal aCL/b2GPI induced TF mRNA and TF activity on PBMC or endothelium, was confirmed by Reverter et al. [44] using the same monoclonal antibodies. Apart from the TF molecule, other procoagulant substances induced by aPL were extensively investigated. Del Papa, Meroni et al. [45e48] have reported a series of molecules associated with endothelium activation by aPL in vitro, and other groups [49,50] have shown adhesion molecules expression induced by IgG with aPL activity in vitro and in vivo models. Thus, it is widely accepted that aPL can induce the expression of TF or other procoagulant substances on cells in some conditions. Vega-Ostertag et al. [51] reported that phosphorylation of p38 MAPK is involved in aPL-mediated production of thromboxane by platelets. Pretreatment of platelets with SB203580, a p38 MAPK specific inhibitor, completely abrogated aPLmediated platelet aggregation. We demonstrated that the p38 MAPK-dependent signaling pathway participates in aPLmediated TF expression. The multi-screening by cDNA array system combined with real time PCR analysis indicated that the MAPK pathway was related to TF expression when cells were treated with monoclonal aCL/b2GPI. We performed western blotting studies to confirm the result of cDNA array in protein level that p38 MAPK protein was phosphorylated. The specific p38 MAPK inhibitor decreased TF mRNA expression by aCL/b2GPI stimulation, suggesting a crucial role of the p38 MAPK pathway in this system [52]. The involvement of p38MAPK activation on endothelial cells has been preliminarily reported to be required in aPL-mediated prothrombotic status [53]. The association between aPL and the occurrence of thrombosis is widely recognized. The effect of aCL in the inhibition of natural anticoagulant systems, the impairment of fibrinolytic activity and the direct effect of these antibodies on cell functions or injury are some of the proposed mechanisms to explain the thrombotic tendency of patients with APS. Endothelial cells, monocytes and activated platelets may be a predominant target of aCL/b2GPI associated with the procoagulant state in characteristic of APS. Recently, the signal transduction mechanism has been explored and associated with the increased expression of procoagulant substances in response to aPL. Dunoyer-Geindre et al. [54] presented an indirect but essential role of NF-kB in endothelial cell activation by aPL. IgG purified from APS patients induced the nuclear translocation of NF-kB leading to the transcription of a large numbers of genes that have a NF-kB responsive element in their promoter. This nuclear translocation of NF-kB mediates, at least in part, can explain the increased expression of TF by endothelial cell. Activation of p38 MAPK increases activities of proinflammatory cytokines, such as TNF-a and IL-1b. Up-regulation of TNF-a, IL-1b and MIP3b was also found in our previous study [52]. Downstream of activated p38 MAPK, MAPK-activated protein kinase 2/3 (MAPKAPK-2/3) is a substrate for p38 that undergoes post-transcriptional regulation of TNF-a. P38 also activates transcriptional factors such as activating
T. Koike et al. / Journal of Autoimmunity 28 (2007) 129e133
transcriptional factor-2 (ATF2), which forms a herterodimer with Jun family transcriptional factors and associates with the activator protein-1 (AP-1) binding site. After LPS stimulation of dendritic cells, NH2-termini of histone H3 undergoes structural alteration in a p38-dependent pathway, which results in enhancement of accessibility of the cryptic NF-kB binding sites [55]. The promoter region of the TF gene contains two AP-1 binding sites and one NF-kB binding site, and these transcription factors are proven required for maximal induction of TF gene transcription. Moreover, p38 MAPK pathway has been implicated in the regulation of TF expression in monocytes, endothelial cells, and smooth muscle cells [56e60]. Very recently, Lopez-Pedrera et al suggested that aPL induced TF in monocytes from APS patients by activating, simultaneously and independently, the phosphorylation of MEK-1/ ERK proteins, and the p38 MAP kinase-dependent nuclear translocation and activation of NF-kappa B/Rel proteins [61]. Antib2GPI antibodies activate endothelial cell in a b2GPIdependent manner, and this cell activation might require an interaction between b2GPI and a specific endothelial cell receptor. It has been shown that annexin II, an endothelial cell receptor for tissue plasminogen activator and plasminogen, behaved as a receptor for b2GPI [62]. However it is still unclear whether such a putative receptor is actually involved in cell activation because annexin II does not span the cell membrane and the presence of an unknown ‘‘adaptor’’ was suggested to be necessary to induce activation. Raschi et al. [63] suggested a possible association between b2GPI and members of the Toll-like receptors (TLRs) family. They speculated that antib2GPI antibodies might cross-link b2GPI molecules likely together with TLRs, eventually favoring the receptor polymerization and the signaling cascade activation. Furthermore, Lutters et al. [64] showed that dimeric b2GPI can interact with apolipoprotein E receptor 2 (apoER2), a member of the low density lipoprotein receptor family present in platelets and that dimeric b2GPI induces increased platelet adhesion and thrombus formation, which depend on the activation of apoER2. 4. Conclusion The recognition of the crucial role of p38 MAPK in the intracellular activation mediated by aPL is a novel finding that represents a great advance in the understanding of the mechanisms involved in the production of the hypercoagulable state in patients with APS [51e53,61]. Those researches may open new insights in the therapeutic approach of patients with APS and give a clue to establish a more specific target therapy by down-regulating the specific pathway of signal transduction. Further studies are needed to clarify how aPL-phospholipid-binding complexes affect to cell surface molecule and how signal transduction events occur upstream of p38 MAPK. References [1] Khamashta MA. Hughes syndrome: history. In: Khamashta MA, editor. Hughes Syndrome: antiphospholipid syndrome. London: Springer-Verlag; 2006. p. 3e8.
131
[2] Schorer AE, Wickham NW, Watson KV. Lupus anticoagulant induces a selective defect in thrombin-mediated endothelial prostacyclin release and platelet aggregation. Br J Haematol 1989;71:399e407. [3] 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;41:1420e7. [4] Ames PR, Tommasino C, Iannaccone L, Brillante M, Cimino R, Brancaccio V. Coagulation activation and fibrinolytic imbalance in subjects with idopathic antiphospholipid antibodies e a crucial role for acquired free protein S deficiency. Thromb Haemost 1996;76:190e4. [5] Oosting JD, Derksen RHWM, Bobbink IWG, Hackeng TM, Bouma BN, de Groot PG. Antiphospholipid antibodies directed against a combination of phospholipids with prothrombin, protein C, or protein S: an explanation for their pathogenic mechanism? Blood 1993;81:2618e25. [6] Kornberg A, Blank M, Kaufman S, Shoenfeld Y. Induction of tissue factor-like activity in monocytes by anti-cardiolipin antibodies. J Immunol 1994;153:1328e32. [7] Amengual O, Atsumi T, Khamashta MA, Hughes GRV. The role of the tissue factor pathway in the hypercoagulable state in patients with the antiphospholipid syndrome. Thromb Haemost 1998;79:276e81. [8] Tannenbaum SH, Finko R, Cines DB. Antibody and immune complexes induce tissue factor production by human endothelial cells. J Immunol 1986;137:1532e7. [9] Branch DW, Rodgers GM. Induction of endothelial cell tissue factor activity by sera from patients with antiphospholipid syndrome: a possible mechanism of thrombosis. Am J Obstet Gynecol 1993;168:206e10. [10] Harris EN, Gharavi AE, Boey ML, Patel BM, Mackworth-Young CG, Loizou S, et al. Anti-cardiolipin antibodies: detection by radioimmunoassay and association with thrombosis in systemic lupus erythematosus. Lancet 1983;ii:1211e4. [11] Koike T, Sueishi M, Funaki H, Tomioka H, Yoshida S. Antiphospholipid antibodies and biological false positive serological test for syphilis in patients with systemic lupus erythematosus. Clin Exp Immunol 1984;56:193e9. [12] Brey RL, Abbott RD, Curb JD, et al. Beta(2)-Glycoprotein 1-dependent anticardiolipin antibodies and risk of ischemic stroke and myocardial infarction: the Honolulu heart program. Stroke 2001;32:1701e6. [13] Nojima J, Kuratsune H, Suehisa E, Kitani T, Iwatani Y, Kanakura Y. Strong correlation between the prevalence of cerebral infarction and the presence of anti-cardiolipin/beta2-glycoprotein I and anti-phosphatidylserine/prothrombin antibodies e co-existence of these antibodies enhances ADP-induced platelet activation in vitro. Thromb Haemost 2004;91:967e76. [14] Lopez LR, Dier KJ, Lopez D, Merrill JT, Fink CA. Anti-beta 2-glycoprotein I and antiphosphatidylserine antibodies are predictors of arterial thrombosis in patients with antiphospholipid syndrome. Am J Clin Pathol 2004;121:142e9. [15] Galli M, Luciani D, Bertolini G, Barbui T. Anti-beta 2-glycoprotein I, antiprothrombin antibodies, and the risk of thrombosis in the antiphospholipid syndrome. Blood 2003;102:2717e23. [16] Galli M, Comfurius P, Maassen C, Hemker HC, de Baets MH, van BredaVriesman PJ, et al. Anticardiolipin antibodies (ACA) directed not to cardiolipin but to a plasma protein cofactor. Lancet 1990;335:952e3. [17] McNeil HP, Simpson RJ, Chesterman CN, Krilis SA. Anti-phospholipid antibodies are directed against a complex antigen that induces a lipidbinding inhibitor of coagulation: b2-glycoprotein I (apolipoprotein H). Proc Natl Acad Sci USA 1990;87:4120e4. [18] Matsuura E, Igarashi Y, Fujimoto M, Ichikawa K, Koike T. Anticardiolipin cofactor(s) and differential diagnosis of autoimmune disease. Lancet 1990;336:177e8. [19] Koike T, Matsuura E. What is the ‘‘true’’ antigen for anticardiolipin antibodies? Lancet 1991;337:671e2. [20] Roubey RAS. Immunology of the antiphospholipid antibody syndrome. Arthritis Rheum 1996;39:1444e54. [21] Sheng Y, Kandiah DA, Krilis SA. Anti-b2-glycoprotein I autoantibodies from patients with the ‘‘antiphospholipid’’ syndrome bind to b2-glycoprotein I with low affinity: dimerization of b2-glycoprotein I induces
132
[22]
[23]
[24]
[25]
[26]
[27]
[28]
[29]
[30] [31]
[32]
[33]
[34] [35] [36]
[37]
[38]
[39]
[40]
[41]
[42]
T. Koike et al. / Journal of Autoimmunity 28 (2007) 129e133 a significant increase in anti-b2-glycoprotein I antibody affinity. J Immunol 1998;161:2038e43. Matsuura E, Igarashi Y, Yasuda T, Triplett DA, Koike T. Anticardiolipin antibodies recognize b2-glycoprotein I structure altered by interacting with an oxygen modified solid phase surface. J Exp Med 1994;179: 457e62. Tsutsumi A, Ichikawa K, Matsuura E, Sawada K, Koike T. Heterogeneous behavior of anti-b2-glycoprotein I antibodies on various commercially available enzyme immunoassay plates coated with b2-glycoprotein I. J Rheumatol 2000;27:391e6. Chamley LW, Duncalf AM, Konarkowska B, Mitchell MD, Johnson PM. Conformationally altered b2-glycoprotein I is the antigen for anticardiolipin autoantibodies. Clin Exp Immunol 1999;115:571e6. Galazka M, Tang M, DeBari VA, et al. Modification of b2glycoprotein I by glutardialdehyde. Conformational changes and aggregation accompany exposure of the cryptic autoepitope. Appl Biochem Biotechnol 1999;76:1e13. Igarashi M, Matsuura E, Igarashi Y, et al. Human b2-glycoprotein I as an anticardiolipin cofactor determined using deleted mutants expressed by a Baculovirus system. Blood 1996;87:3262e70. Wang MX, Kandiah DA, Ichikawa K, et al. Epitope specificity of monoclonal anti b2-glycoprotien I antibodies derived from patients with the antiphospholipid syndrome. J Immunol 1995;155:1629e36. George J, Gilburd B, Hojnik M, Levy Y, Langevitz P, Matsuura E, et al. Target recognition of b2-glycoprotein I (b2GPI)-dependent anticardiolipin antibodies: evidence for involvement of the fourth domain of b2GPI in antibody binding. J Immunol 1998;150:3917e23. Iverson GM, Victoria EJ, Marquis DM. Anti-b2 glycoprotein I (b2GPI) autoantibodies recognize an epitope on the first domain of b2GPI. Proc Natl Acad Sci USA 1998;95:15542e6. Koike T, Ichikawa K, Atsumi T, Kasahara H, Matsuura E. b2-glycoprotein I-anti-b2-glycoprotein I interaction. J Autoimmun 2000;15:97e100. de Laat B, Derksen RH, Urbanus RT, de Groot PG. IgG antibodies that recognize epitope Gly40eArg43 in domain I of beta 2-glycoprotein I cause LAC, and their presence correlates strongly with thrombosis. Blood 2005;105:1540e5. de Laat B, Derksen RH, van Lummel M, Pennings MT, de Groot PG. Pathogenic anti-beta2-glycoprotein I antibodies recognize domain I of beta2-glycoprotein I only after a conformational change. Blood 2006; 107:1916e24. Kasahara H, Matsuura E, Kaihara K, Yamamoto D, Kobayashi K, Inagaki J, et al. Antigenic structures recognized by anti-beta2-glycoprotein I auto-antibodies. Int Immunol 2005;17:1533e42. Mann K. Biochemistry and physiology of blood coagulation. Thromb Haemost 1999;82:165e74. Mackman N. Regulation of the tissue factor gene. Faseb J 1995;9:883e9. 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;79:276e81. Atsumi T, Khamashta MA, Amengual O, Hughes GR. Up-regulated tissue factor expression in antiphospholipid syndrome. Thromb Haemost 1997;77:222e3. 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;40:834e41. Oosting J, Derksen R, Blokzijl L, Sixma J, de Groot PG. Antiphospholipid antibody positive sera enhance endothelial cell procoagulant activity: studies in a thrombosis model. Thromb Haemost 1992;68:278e84. Branch D, Rodgers G. Induction of endothelial cell tissue factor activity by sera from patients with antiphospholipid syndrome: a possible mechanism of thrombosis. Am J Obstet Gynecol 1993;168:206e10. Schved J, Gris J, Ollivier V, Wautier J, Tobelem G, Caen J. Procoagulant activity of endotoxin or tumor necrosis factor activated monocytes is enhanced by IgG from patients with lupus anticoagulant. Am J Hematol 1992;41:92e6. Martini F, Farsi A, Gori AM, Boddi M, Fedi S, Domeneghetti MP, et al. Antiphospholipid antibodies (aPL) increase the potential monocyte
[43]
[44]
[45]
[46]
[47]
[48]
[49]
[50]
[51]
[52]
[53]
[54]
[55]
[56]
[57]
[58]
[59]
procoagulant activity in patients with systemic lupus erythematosus. Lupus 1996;5:206e11. Zhou H, Wolberg AS, Roubey RA. Characterization of monocyte tissue factor activity induced by IgG antiphospholipid antibodies and inhibition by dilazep. Blood 2004;104:2353e8. 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;41:1420e7. Del Papa N, Guidali L, Spatola L, Bonara P, Borghi MO, Tincani A, et al. Relationship between anti-phospholipid and anti-endothelial cell antibodies III: beta 2 glycoprotein I mediates the antibody binding to endothelial membranes and induces the expression of adhesion molecules. Clin Exp Rheumatol 1995;13:179e85. Del Papa N, Guidali L, Sala A, Buccellati C, Khamashta MA, Ichikawa K, et al. Endothelial cells as target for antiphospholipid antibodies. Human polyclonal and monoclonal anti-beta 2-glycoprotein I antibodies react in vitro with endothelial cells through adherent beta 2glycoprotein I and induce endothelial activation. Arthritis Rheum 1997; 40:551e61. Del Papa N, Sheng YH, Raschi E, Kandiah DA, Tincani A, Khamashta MA, et al. Human beta 2-glycoprotein I binds to endothelial cells through a cluster of lysine residues that are critical for anionic phospholipid binding and offers epitopes for anti-beta 2-glycoprotein I antibodies. J Immunol 1998;160:5572e8. Del Papa N, Meroni PL, Barcellini W, Sinico A, Radice A, Tincani A, et al. Antibodies to endothelial cells in primary vasculitides mediate in vitro endothelial cytotoxicity in the presence of normal peripheral blood mononuclear cells. Clin Immunol Immunopathol 1992;63:267e74. Simantov R, LaSala JM, Lo SK, Gharavi AE, Sammaritano LR, Salmon JE, et al. Activation of cultured vascular endothelial cells by antiphospholipid antibodies. J Clin Invest 1995;96:2211e9. Pierangeli SS, Colden-Stanfield M, Liu X, Barker JH, Anderson GL, Harris EN. Antiphospholipid antibodies from antiphospholipid syndrome patients activate endothelial cells in vitro and in vivo. Circulation 1999; 99:1997e2002. Vega-Ostertag M, Harris EN, Pierangeli SS. Intracellular events in platelet activation induced by antiphospholipid antibodies in the presence of low doses of thrombin. Arthritis Rheum 2004;50:2911e9. Bohgaki M, Atsumi T, Yamashita Y, Yasuda S, Sakai Y, Furusaki A, et al. The p38 mitogen-activated protein kinase (MAPK) pathway mediates induction of the tissue factor gene in monocytes stimulated with human monoclonal anti-beta2Glycoprotein I antibodies. Int Immunol 2004;16: 1633e41. Pierangeli SS, Vega-Ostertag M, Harris EN. Intracellular signaling triggered by antiphospholipid antibodies in platelets and endothelial cells: a pathway to targeted therapies. Thromb Res 2004;114:467e76. Dunoyer-Geindre S, de Moerloose P, Galve-de Rochemonteix B, Reber G, Kruithof EK. NFkappaB is an essential intermediate in the activation of endothelial cells by anti-beta(2)-glycoprotein 1 antibodies. Thromb Haemost 2002;88:851e7. Saccani S, Pantano S, Natoli G. p38-Dependent marking of inflammatory genes for increased NF-kappa B recruitment. Nat Immunol 2002;3: 69e75. McGilvray ID, Tsai V, Marshall JC, Dackiw AP, Rotstein OD. Monocyte adhesion and transmigration induce tissue factor expression: role of the mitogen-activated protein kinases. Shock 2002;18:51e7. Ohsawa M, Koyama T, Nara N, Hirosawa S. Induction of tissue factor expression in human monocytic cells by protease inhibitors through activating activator protein-1 (AP-1) with phosphorylation of Jun-Nterminal kinase and p38. Thromb Res 2003;112:313e20. Blum S, Issbrucker K, Willuweit A, Hehlgans S, Lucerna M, Mechtcheriakova D, et al. An inhibitory role of the phosphatidylinositol 3-kinase-signaling pathway in vascular endothelial growth factor-induced tissue factor expression. J Biol Chem 2001;276:33428e34. Eto M, Kozai T, Cosentino F, Joch H, Luscher TF. Statin prevents tissue factor expression in human endothelial cells: role of Rho/Rho-kinase and Akt pathways. Circulation 2002;105:1756e9.
T. Koike et al. / Journal of Autoimmunity 28 (2007) 129e133 [60] Herkert O, Diebold I, Brandes RP, Hess J, Busse R, Gorlach A. NADPH oxidase mediates tissue factor-dependent surface procoagulant activity by thrombin in human vascular smooth muscle cells. Circulation 2002; 105:2030e6. [61] Lopez-Pedrera C, Buendia P, Cuadrado MJ, Siendones E, Aguirre MA, Barbarroja N, et al. Antiphospholipid antibodies from patients with the antiphospholipid syndrome induce monocytes tissue factor expression through the simultaneous activation of NF-kappaB/Rel proteins via the p38 mitogen-activated protein kinase pathway, and of the MEK1/ERK pathway. Arthritis Rheum 2006;54:301e11.
133
[62] Ma K, Simantov R, Zhang JC, Silverstein R, Hajjar KA, McCrae KR. High affinity binding of beta 2-glycoprotein I to human endothelial cells is mediated by annexin II. J Biol Chem 2000;275:15541e8. [63] Raschi E, Testoni C, Bosisio D, Borghi MO, Koike T, Mantovani A, et al. Role of the MyD88 transduction signaling pathway in endothelial activation by antiphospholipid antibodies. Blood 2003;101:3495e500. [64] Lutters BC, Derksen RH, Tekelenburg WL, Lenting PJ, Arnout J, de Groot PG. Dimers of beta 2-glycoprotein I increase platelet deposition to collagen via interaction with phospholipids and the apolipoprotein E receptor 20 . J Biol Chem 2003;278:33831e8.
Review
Antiphospholipid antibodies: Lessons from the bench Takao Koike*, Miyuki Bohgaki, Olga Amengual, Tatsuya Atsumi Department of Medicine II, Hokkaido University Graduate School of Medicine, N15 W7, Kita-ku, Sapporo 060-8638, Japan
Abstract Antiphospholipid antibodies (aPL) are an heterogeneous group of circulating immunoglobulins arising in a wide range of infectious and autoimmune diseases. Since the early 80 s, the interest on anticardiolipin antibodies (aCL) has exponentially increased due to their association with thrombosis. The antiphospholipid syndrome (APS) was defined as a clinical disorder characterized by thrombosis and pregnancy morbidity associated to the persistent presence of aCL and/or lupus anticoagulant (LA). Thrombosis is the major manifestation in patients with aPL, but the spectrum of symptoms and signs associated with aPL has considerably broadened, and other manifestations such as thrombocytopenia, nonthrombotic neurological syndromes, psychiatric manifestations, livedo reticularis, skin ulcers, haemolytic anemia, pulmonary hypertension, cardiac valve abnormality and atherosclerosis have also been related to the presence of those antibodies. Numerous mechanisms have been proposed to explain the thrombotic tendency of patients with aPL, but the pathogenesis seems to be multifactorial. Ó 2007 Elsevier Ltd. All rights reserved. Keywords: Thrombosis; Antiphospholipid antibodies; Inflammation; Autoantibodies; Phospholipid antibody syndrome
1. Anticardiolipin and anti-b2-Glycoprotein I antibodies
2. Anti-b2-Glycoprotein I antibodies
The mechanisms involved in defining the thrombosis of patients with antiphospholipid antibody have been extensively studied by numerous investigators [1e9] (Table 1). Anticardiolipin antibodies (aCL) were detected using immunoassays with solid phase cardiolipin as a putative antigen [10,11]. However, antibodies directed to phospholipid-binding plasma or serum proteins, in particular b2-Glycoprotein I (b2GPI), are present in serum samples and can be components of the sample diluent and blocking buffer in various types of immunoassay systems. b2GPI-dependent aCL represent a predictor of future stroke and myocardial infarction in men, and are predictors of arterial thrombosis in patients with APS [12e14]. And also, antib2GPI antibodies have been often associated with venous thrombosis [15]. In contrast, aPL associated with infectious diseases bind directly to these negatively charged phospholipids, showing little association with thrombosis [16e19].
The mechanisms by which anti-b2GPI antibodies bind to b2GPI is unclear. It has been proposed that one antibody must bind two b2GPI molecules to obtain considerable avidity, the ‘‘dimerization theory’’ [20,21]. Another theory is based on the recognition of a cryptic epitope on b2GPI by aPL antib2GPI antibodies. This cryptic epitope is only exposed when b2GPI interacts with a lipid membrane composed of negatively charged phospholipids or when adsorbed on a polyoxygenated polystyrene plate treated with g-irradiation or electrons [22]. Consistent with this story, some reports showed the binding of aPL to b2GPI adsorbed on various commercially available oxidatively modified polystyrene plates, on a nitrocellulose membrane or on an experimentally g-ray/ UV-irradiated polystyrene plates [23,24]. Moreover, an epitope for aPL is exposed on the b2GPI molecule modified with glutaryldialdehyde [25]. The location of the epitope(s) on b2GPI for anti-b2GPI antibodies from APS patients has been largely discussed. Anti-b2GPI antibodies recognize different epitopes located in all five domains. In 1996, Igarashi et al. [26] firstly reported that domain IV or I are candidates for epitopic location on the
* Corresponding author. Tel.: þ81 11 706 5913; fax: þ81 11 706 7710. E-mail address: [email protected] (T. Koike). 0896-8411/$ - see front matter Ó 2007 Elsevier Ltd. All rights reserved. doi:10.1016/j.jaut.2007.02.009
130
T. Koike et al. / Journal of Autoimmunity 28 (2007) 129e133
Table 1 Proposed mechanism of antiphospholipid antibody-mediated thrombosis 1 2 3 4 5
Inhibition of endothelial cell prostacyclin production Procoagulant effects on platelets Impairment of fibrinolysis Interference with the thrombomodulin-protein S-protein C pathway Induction of procoagulant activity on cells (endothelial cells or monocytes)
b2GPI molecule by using a series of deletion mutant proteins of b2GPI. Wang et al. [27] showed the presence of antib2GPI antibodies directed to domain V. George et al. [28] demonstrated that domain IV of b2GPI is one of the major epitopic location for aCL raised in APS patients. In contrast, Iverson et al. [29] reported that anti-b2GPI antibodies, in the major population of APS patients, recognized a particular structure in domain I of b2GPI, and antibody binding was diminished by replacement of a related amino acid locates in the domain. However, it was also shown that some particular mutations made in domain IV also affected to antibody binding to b2GPI in anti-b2GPI antibody ELISA [30]. Recently, it has been showed that pathogenic aPL bind a cryptic epitope on domain I of b2GPI (G40eR43). This epitope is accessible for aPL only after conformational change which is induced by the binding of b2GPI to a negatively charged surface via a positive-charge patch in domain V of b2GPI [31,32]. Our group revealed that epitopic structures recognized by anti b2GPI antibodies are cryptic and that electrostatic interaction between domain IV and V are involved in their exposure [33]. 3. Cellular interaction and anti-b2GPI antibodies Intensive research works, performed in the last decade, have greatly advanced our knowledge of the mechanisms that explain why these antibodies may play a direct role in clot formation. Procoagulant cell activation, accompanied with TF expression, and TF pathway up-regulation is one of the key events considered to explain the pathophysiology of thrombosis in patients with APS. TF is the major initiator of the extrinsic coagulation system, functioning in coagulation by serving as the protein cofactor for the activated factor VII (FVIIa) [34]. Induced TF forms a complex with FVIIa that triggers blood clotting cascade by activating factors IX and X, leading to thrombin generation. In normal conditions, TF is not expressed on intravascular cells but it can be induced under some stimuli such as lipopolysaccharide, tumor necrosis factor a (TNFa), interleukin-1 (IL-1) and shear stress [35]. We showed elevated plasma levels of soluble TF in APS patients [36,37], and Cuadrado et al. [38] reported that monocytes prepared from APS patients had high TF expression. Tissue factor pathway inhibitor (TFPI), a physiological inhibitor of the extrinsic coagulation system, was also increased in plasma from patients with APS [36], suggesting up-regulation of TF and TFPI in affected patients. In in vitro experiments, there are numerous reports shown that IgG fraction from
patients with aPL induced procoagulant activity on cells [39e43]. Our previous observation that human monoclonal aCL/b2GPI induced TF mRNA and TF activity on PBMC or endothelium, was confirmed by Reverter et al. [44] using the same monoclonal antibodies. Apart from the TF molecule, other procoagulant substances induced by aPL were extensively investigated. Del Papa, Meroni et al. [45e48] have reported a series of molecules associated with endothelium activation by aPL in vitro, and other groups [49,50] have shown adhesion molecules expression induced by IgG with aPL activity in vitro and in vivo models. Thus, it is widely accepted that aPL can induce the expression of TF or other procoagulant substances on cells in some conditions. Vega-Ostertag et al. [51] reported that phosphorylation of p38 MAPK is involved in aPL-mediated production of thromboxane by platelets. Pretreatment of platelets with SB203580, a p38 MAPK specific inhibitor, completely abrogated aPLmediated platelet aggregation. We demonstrated that the p38 MAPK-dependent signaling pathway participates in aPLmediated TF expression. The multi-screening by cDNA array system combined with real time PCR analysis indicated that the MAPK pathway was related to TF expression when cells were treated with monoclonal aCL/b2GPI. We performed western blotting studies to confirm the result of cDNA array in protein level that p38 MAPK protein was phosphorylated. The specific p38 MAPK inhibitor decreased TF mRNA expression by aCL/b2GPI stimulation, suggesting a crucial role of the p38 MAPK pathway in this system [52]. The involvement of p38MAPK activation on endothelial cells has been preliminarily reported to be required in aPL-mediated prothrombotic status [53]. The association between aPL and the occurrence of thrombosis is widely recognized. The effect of aCL in the inhibition of natural anticoagulant systems, the impairment of fibrinolytic activity and the direct effect of these antibodies on cell functions or injury are some of the proposed mechanisms to explain the thrombotic tendency of patients with APS. Endothelial cells, monocytes and activated platelets may be a predominant target of aCL/b2GPI associated with the procoagulant state in characteristic of APS. Recently, the signal transduction mechanism has been explored and associated with the increased expression of procoagulant substances in response to aPL. Dunoyer-Geindre et al. [54] presented an indirect but essential role of NF-kB in endothelial cell activation by aPL. IgG purified from APS patients induced the nuclear translocation of NF-kB leading to the transcription of a large numbers of genes that have a NF-kB responsive element in their promoter. This nuclear translocation of NF-kB mediates, at least in part, can explain the increased expression of TF by endothelial cell. Activation of p38 MAPK increases activities of proinflammatory cytokines, such as TNF-a and IL-1b. Up-regulation of TNF-a, IL-1b and MIP3b was also found in our previous study [52]. Downstream of activated p38 MAPK, MAPK-activated protein kinase 2/3 (MAPKAPK-2/3) is a substrate for p38 that undergoes post-transcriptional regulation of TNF-a. P38 also activates transcriptional factors such as activating
T. Koike et al. / Journal of Autoimmunity 28 (2007) 129e133
transcriptional factor-2 (ATF2), which forms a herterodimer with Jun family transcriptional factors and associates with the activator protein-1 (AP-1) binding site. After LPS stimulation of dendritic cells, NH2-termini of histone H3 undergoes structural alteration in a p38-dependent pathway, which results in enhancement of accessibility of the cryptic NF-kB binding sites [55]. The promoter region of the TF gene contains two AP-1 binding sites and one NF-kB binding site, and these transcription factors are proven required for maximal induction of TF gene transcription. Moreover, p38 MAPK pathway has been implicated in the regulation of TF expression in monocytes, endothelial cells, and smooth muscle cells [56e60]. Very recently, Lopez-Pedrera et al suggested that aPL induced TF in monocytes from APS patients by activating, simultaneously and independently, the phosphorylation of MEK-1/ ERK proteins, and the p38 MAP kinase-dependent nuclear translocation and activation of NF-kappa B/Rel proteins [61]. Antib2GPI antibodies activate endothelial cell in a b2GPIdependent manner, and this cell activation might require an interaction between b2GPI and a specific endothelial cell receptor. It has been shown that annexin II, an endothelial cell receptor for tissue plasminogen activator and plasminogen, behaved as a receptor for b2GPI [62]. However it is still unclear whether such a putative receptor is actually involved in cell activation because annexin II does not span the cell membrane and the presence of an unknown ‘‘adaptor’’ was suggested to be necessary to induce activation. Raschi et al. [63] suggested a possible association between b2GPI and members of the Toll-like receptors (TLRs) family. They speculated that antib2GPI antibodies might cross-link b2GPI molecules likely together with TLRs, eventually favoring the receptor polymerization and the signaling cascade activation. Furthermore, Lutters et al. [64] showed that dimeric b2GPI can interact with apolipoprotein E receptor 2 (apoER2), a member of the low density lipoprotein receptor family present in platelets and that dimeric b2GPI induces increased platelet adhesion and thrombus formation, which depend on the activation of apoER2. 4. Conclusion The recognition of the crucial role of p38 MAPK in the intracellular activation mediated by aPL is a novel finding that represents a great advance in the understanding of the mechanisms involved in the production of the hypercoagulable state in patients with APS [51e53,61]. Those researches may open new insights in the therapeutic approach of patients with APS and give a clue to establish a more specific target therapy by down-regulating the specific pathway of signal transduction. Further studies are needed to clarify how aPL-phospholipid-binding complexes affect to cell surface molecule and how signal transduction events occur upstream of p38 MAPK. References [1] Khamashta MA. Hughes syndrome: history. In: Khamashta MA, editor. Hughes Syndrome: antiphospholipid syndrome. London: Springer-Verlag; 2006. p. 3e8.
131
[2] Schorer AE, Wickham NW, Watson KV. Lupus anticoagulant induces a selective defect in thrombin-mediated endothelial prostacyclin release and platelet aggregation. Br J Haematol 1989;71:399e407. [3] 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;41:1420e7. [4] Ames PR, Tommasino C, Iannaccone L, Brillante M, Cimino R, Brancaccio V. Coagulation activation and fibrinolytic imbalance in subjects with idopathic antiphospholipid antibodies e a crucial role for acquired free protein S deficiency. Thromb Haemost 1996;76:190e4. [5] Oosting JD, Derksen RHWM, Bobbink IWG, Hackeng TM, Bouma BN, de Groot PG. Antiphospholipid antibodies directed against a combination of phospholipids with prothrombin, protein C, or protein S: an explanation for their pathogenic mechanism? Blood 1993;81:2618e25. [6] Kornberg A, Blank M, Kaufman S, Shoenfeld Y. Induction of tissue factor-like activity in monocytes by anti-cardiolipin antibodies. J Immunol 1994;153:1328e32. [7] Amengual O, Atsumi T, Khamashta MA, Hughes GRV. The role of the tissue factor pathway in the hypercoagulable state in patients with the antiphospholipid syndrome. Thromb Haemost 1998;79:276e81. [8] Tannenbaum SH, Finko R, Cines DB. Antibody and immune complexes induce tissue factor production by human endothelial cells. J Immunol 1986;137:1532e7. [9] Branch DW, Rodgers GM. Induction of endothelial cell tissue factor activity by sera from patients with antiphospholipid syndrome: a possible mechanism of thrombosis. Am J Obstet Gynecol 1993;168:206e10. [10] Harris EN, Gharavi AE, Boey ML, Patel BM, Mackworth-Young CG, Loizou S, et al. Anti-cardiolipin antibodies: detection by radioimmunoassay and association with thrombosis in systemic lupus erythematosus. Lancet 1983;ii:1211e4. [11] Koike T, Sueishi M, Funaki H, Tomioka H, Yoshida S. Antiphospholipid antibodies and biological false positive serological test for syphilis in patients with systemic lupus erythematosus. Clin Exp Immunol 1984;56:193e9. [12] Brey RL, Abbott RD, Curb JD, et al. Beta(2)-Glycoprotein 1-dependent anticardiolipin antibodies and risk of ischemic stroke and myocardial infarction: the Honolulu heart program. Stroke 2001;32:1701e6. [13] Nojima J, Kuratsune H, Suehisa E, Kitani T, Iwatani Y, Kanakura Y. Strong correlation between the prevalence of cerebral infarction and the presence of anti-cardiolipin/beta2-glycoprotein I and anti-phosphatidylserine/prothrombin antibodies e co-existence of these antibodies enhances ADP-induced platelet activation in vitro. Thromb Haemost 2004;91:967e76. [14] Lopez LR, Dier KJ, Lopez D, Merrill JT, Fink CA. Anti-beta 2-glycoprotein I and antiphosphatidylserine antibodies are predictors of arterial thrombosis in patients with antiphospholipid syndrome. Am J Clin Pathol 2004;121:142e9. [15] Galli M, Luciani D, Bertolini G, Barbui T. Anti-beta 2-glycoprotein I, antiprothrombin antibodies, and the risk of thrombosis in the antiphospholipid syndrome. Blood 2003;102:2717e23. [16] Galli M, Comfurius P, Maassen C, Hemker HC, de Baets MH, van BredaVriesman PJ, et al. Anticardiolipin antibodies (ACA) directed not to cardiolipin but to a plasma protein cofactor. Lancet 1990;335:952e3. [17] McNeil HP, Simpson RJ, Chesterman CN, Krilis SA. Anti-phospholipid antibodies are directed against a complex antigen that induces a lipidbinding inhibitor of coagulation: b2-glycoprotein I (apolipoprotein H). Proc Natl Acad Sci USA 1990;87:4120e4. [18] Matsuura E, Igarashi Y, Fujimoto M, Ichikawa K, Koike T. Anticardiolipin cofactor(s) and differential diagnosis of autoimmune disease. Lancet 1990;336:177e8. [19] Koike T, Matsuura E. What is the ‘‘true’’ antigen for anticardiolipin antibodies? Lancet 1991;337:671e2. [20] Roubey RAS. Immunology of the antiphospholipid antibody syndrome. Arthritis Rheum 1996;39:1444e54. [21] Sheng Y, Kandiah DA, Krilis SA. Anti-b2-glycoprotein I autoantibodies from patients with the ‘‘antiphospholipid’’ syndrome bind to b2-glycoprotein I with low affinity: dimerization of b2-glycoprotein I induces
132
[22]
[23]
[24]
[25]
[26]
[27]
[28]
[29]
[30] [31]
[32]
[33]
[34] [35] [36]
[37]
[38]
[39]
[40]
[41]
[42]
T. Koike et al. / Journal of Autoimmunity 28 (2007) 129e133 a significant increase in anti-b2-glycoprotein I antibody affinity. J Immunol 1998;161:2038e43. Matsuura E, Igarashi Y, Yasuda T, Triplett DA, Koike T. Anticardiolipin antibodies recognize b2-glycoprotein I structure altered by interacting with an oxygen modified solid phase surface. J Exp Med 1994;179: 457e62. Tsutsumi A, Ichikawa K, Matsuura E, Sawada K, Koike T. Heterogeneous behavior of anti-b2-glycoprotein I antibodies on various commercially available enzyme immunoassay plates coated with b2-glycoprotein I. J Rheumatol 2000;27:391e6. Chamley LW, Duncalf AM, Konarkowska B, Mitchell MD, Johnson PM. Conformationally altered b2-glycoprotein I is the antigen for anticardiolipin autoantibodies. Clin Exp Immunol 1999;115:571e6. Galazka M, Tang M, DeBari VA, et al. Modification of b2glycoprotein I by glutardialdehyde. Conformational changes and aggregation accompany exposure of the cryptic autoepitope. Appl Biochem Biotechnol 1999;76:1e13. Igarashi M, Matsuura E, Igarashi Y, et al. Human b2-glycoprotein I as an anticardiolipin cofactor determined using deleted mutants expressed by a Baculovirus system. Blood 1996;87:3262e70. Wang MX, Kandiah DA, Ichikawa K, et al. Epitope specificity of monoclonal anti b2-glycoprotien I antibodies derived from patients with the antiphospholipid syndrome. J Immunol 1995;155:1629e36. George J, Gilburd B, Hojnik M, Levy Y, Langevitz P, Matsuura E, et al. Target recognition of b2-glycoprotein I (b2GPI)-dependent anticardiolipin antibodies: evidence for involvement of the fourth domain of b2GPI in antibody binding. J Immunol 1998;150:3917e23. Iverson GM, Victoria EJ, Marquis DM. Anti-b2 glycoprotein I (b2GPI) autoantibodies recognize an epitope on the first domain of b2GPI. Proc Natl Acad Sci USA 1998;95:15542e6. Koike T, Ichikawa K, Atsumi T, Kasahara H, Matsuura E. b2-glycoprotein I-anti-b2-glycoprotein I interaction. J Autoimmun 2000;15:97e100. de Laat B, Derksen RH, Urbanus RT, de Groot PG. IgG antibodies that recognize epitope Gly40eArg43 in domain I of beta 2-glycoprotein I cause LAC, and their presence correlates strongly with thrombosis. Blood 2005;105:1540e5. de Laat B, Derksen RH, van Lummel M, Pennings MT, de Groot PG. Pathogenic anti-beta2-glycoprotein I antibodies recognize domain I of beta2-glycoprotein I only after a conformational change. Blood 2006; 107:1916e24. Kasahara H, Matsuura E, Kaihara K, Yamamoto D, Kobayashi K, Inagaki J, et al. Antigenic structures recognized by anti-beta2-glycoprotein I auto-antibodies. Int Immunol 2005;17:1533e42. Mann K. Biochemistry and physiology of blood coagulation. Thromb Haemost 1999;82:165e74. Mackman N. Regulation of the tissue factor gene. Faseb J 1995;9:883e9. 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;79:276e81. Atsumi T, Khamashta MA, Amengual O, Hughes GR. Up-regulated tissue factor expression in antiphospholipid syndrome. Thromb Haemost 1997;77:222e3. 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;40:834e41. Oosting J, Derksen R, Blokzijl L, Sixma J, de Groot PG. Antiphospholipid antibody positive sera enhance endothelial cell procoagulant activity: studies in a thrombosis model. Thromb Haemost 1992;68:278e84. Branch D, Rodgers G. Induction of endothelial cell tissue factor activity by sera from patients with antiphospholipid syndrome: a possible mechanism of thrombosis. Am J Obstet Gynecol 1993;168:206e10. Schved J, Gris J, Ollivier V, Wautier J, Tobelem G, Caen J. Procoagulant activity of endotoxin or tumor necrosis factor activated monocytes is enhanced by IgG from patients with lupus anticoagulant. Am J Hematol 1992;41:92e6. Martini F, Farsi A, Gori AM, Boddi M, Fedi S, Domeneghetti MP, et al. Antiphospholipid antibodies (aPL) increase the potential monocyte
[43]
[44]
[45]
[46]
[47]
[48]
[49]
[50]
[51]
[52]
[53]
[54]
[55]
[56]
[57]
[58]
[59]
procoagulant activity in patients with systemic lupus erythematosus. Lupus 1996;5:206e11. Zhou H, Wolberg AS, Roubey RA. Characterization of monocyte tissue factor activity induced by IgG antiphospholipid antibodies and inhibition by dilazep. Blood 2004;104:2353e8. 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;41:1420e7. Del Papa N, Guidali L, Spatola L, Bonara P, Borghi MO, Tincani A, et al. Relationship between anti-phospholipid and anti-endothelial cell antibodies III: beta 2 glycoprotein I mediates the antibody binding to endothelial membranes and induces the expression of adhesion molecules. Clin Exp Rheumatol 1995;13:179e85. Del Papa N, Guidali L, Sala A, Buccellati C, Khamashta MA, Ichikawa K, et al. Endothelial cells as target for antiphospholipid antibodies. Human polyclonal and monoclonal anti-beta 2-glycoprotein I antibodies react in vitro with endothelial cells through adherent beta 2glycoprotein I and induce endothelial activation. Arthritis Rheum 1997; 40:551e61. Del Papa N, Sheng YH, Raschi E, Kandiah DA, Tincani A, Khamashta MA, et al. Human beta 2-glycoprotein I binds to endothelial cells through a cluster of lysine residues that are critical for anionic phospholipid binding and offers epitopes for anti-beta 2-glycoprotein I antibodies. J Immunol 1998;160:5572e8. Del Papa N, Meroni PL, Barcellini W, Sinico A, Radice A, Tincani A, et al. Antibodies to endothelial cells in primary vasculitides mediate in vitro endothelial cytotoxicity in the presence of normal peripheral blood mononuclear cells. Clin Immunol Immunopathol 1992;63:267e74. Simantov R, LaSala JM, Lo SK, Gharavi AE, Sammaritano LR, Salmon JE, et al. Activation of cultured vascular endothelial cells by antiphospholipid antibodies. J Clin Invest 1995;96:2211e9. Pierangeli SS, Colden-Stanfield M, Liu X, Barker JH, Anderson GL, Harris EN. Antiphospholipid antibodies from antiphospholipid syndrome patients activate endothelial cells in vitro and in vivo. Circulation 1999; 99:1997e2002. Vega-Ostertag M, Harris EN, Pierangeli SS. Intracellular events in platelet activation induced by antiphospholipid antibodies in the presence of low doses of thrombin. Arthritis Rheum 2004;50:2911e9. Bohgaki M, Atsumi T, Yamashita Y, Yasuda S, Sakai Y, Furusaki A, et al. The p38 mitogen-activated protein kinase (MAPK) pathway mediates induction of the tissue factor gene in monocytes stimulated with human monoclonal anti-beta2Glycoprotein I antibodies. Int Immunol 2004;16: 1633e41. Pierangeli SS, Vega-Ostertag M, Harris EN. Intracellular signaling triggered by antiphospholipid antibodies in platelets and endothelial cells: a pathway to targeted therapies. Thromb Res 2004;114:467e76. Dunoyer-Geindre S, de Moerloose P, Galve-de Rochemonteix B, Reber G, Kruithof EK. NFkappaB is an essential intermediate in the activation of endothelial cells by anti-beta(2)-glycoprotein 1 antibodies. Thromb Haemost 2002;88:851e7. Saccani S, Pantano S, Natoli G. p38-Dependent marking of inflammatory genes for increased NF-kappa B recruitment. Nat Immunol 2002;3: 69e75. McGilvray ID, Tsai V, Marshall JC, Dackiw AP, Rotstein OD. Monocyte adhesion and transmigration induce tissue factor expression: role of the mitogen-activated protein kinases. Shock 2002;18:51e7. Ohsawa M, Koyama T, Nara N, Hirosawa S. Induction of tissue factor expression in human monocytic cells by protease inhibitors through activating activator protein-1 (AP-1) with phosphorylation of Jun-Nterminal kinase and p38. Thromb Res 2003;112:313e20. Blum S, Issbrucker K, Willuweit A, Hehlgans S, Lucerna M, Mechtcheriakova D, et al. An inhibitory role of the phosphatidylinositol 3-kinase-signaling pathway in vascular endothelial growth factor-induced tissue factor expression. J Biol Chem 2001;276:33428e34. Eto M, Kozai T, Cosentino F, Joch H, Luscher TF. Statin prevents tissue factor expression in human endothelial cells: role of Rho/Rho-kinase and Akt pathways. Circulation 2002;105:1756e9.
T. Koike et al. / Journal of Autoimmunity 28 (2007) 129e133 [60] Herkert O, Diebold I, Brandes RP, Hess J, Busse R, Gorlach A. NADPH oxidase mediates tissue factor-dependent surface procoagulant activity by thrombin in human vascular smooth muscle cells. Circulation 2002; 105:2030e6. [61] Lopez-Pedrera C, Buendia P, Cuadrado MJ, Siendones E, Aguirre MA, Barbarroja N, et al. Antiphospholipid antibodies from patients with the antiphospholipid syndrome induce monocytes tissue factor expression through the simultaneous activation of NF-kappaB/Rel proteins via the p38 mitogen-activated protein kinase pathway, and of the MEK1/ERK pathway. Arthritis Rheum 2006;54:301e11.
133
[62] Ma K, Simantov R, Zhang JC, Silverstein R, Hajjar KA, McCrae KR. High affinity binding of beta 2-glycoprotein I to human endothelial cells is mediated by annexin II. J Biol Chem 2000;275:15541e8. [63] Raschi E, Testoni C, Bosisio D, Borghi MO, Koike T, Mantovani A, et al. Role of the MyD88 transduction signaling pathway in endothelial activation by antiphospholipid antibodies. Blood 2003;101:3495e500. [64] Lutters BC, Derksen RH, Tekelenburg WL, Lenting PJ, Arnout J, de Groot PG. Dimers of beta 2-glycoprotein I increase platelet deposition to collagen via interaction with phospholipids and the apolipoprotein E receptor 20 . J Biol Chem 2003;278:33831e8.