点击显示 收起
From Basic Research to Clinical Disease
From the Department of Rheumatology and Clinical Immunology (H.U.) and the Department of Hematology and Oncology (T.O), Clinical Science for Pathological Organs, Kyoto University Graduate School of Medicine, Kyoto, Japan; the Division of Cellular and Gene Therapies (HFM-518), Center for Biologics Evaluation and Research (E.T.B.), Food and Drug Administration, Bethesda, Md; the Department of Medicine, Osaka Dental University (Y.N.), Osaka, Japan; the Department of Microbiology, Kinki University School of Medicine (O.Y.), Osaka, Japan; and the Kan Research Institute (T.I.), Kyoto, Japan.
Correspondence to Hisanori Umehara, MD, PhD, Department of Rheumatology and Clinical Immunology, Kyoto University Graduate School of Medicine, 54 Shogoin-Kawahara-cho, Sakyo-ku, Kyoto 606-8507, Japan. E-mail umehara@kuhp.kyoto-u.ac.jp
Abstract
Fractalkine (now also called CX3CL1) is a unique chemokine that functions not only as a chemoattractant but also as an adhesion molecule and is expressed on endothelial cells activated by proinflammatory cytokines, such as interferon- and tumor necrosis factor-. The fractalkine receptor, CX3CR1, is expressed on cytotoxic effector lymphocytes, including natural killer (NK) cells and cytotoxic T lymphocytes, which contain high levels of intracellular perforin and granzyme B, and on macrophages. Soluble fractalkine causes migration of NK cells, cytotoxic T lymphocytes, and macrophages, whereas the membrane-bound form captures and enhances the subsequent migration of these cells in response to secondary stimulation with other chemokines. Furthermore, stimulation through membrane-bound fractalkine activates NK cells, leading to increased cytotoxicity and interferon- production. Recently, accumulating evidence has shown that fractalkine is involved in the pathogenesis of various clinical disease states or processes, such as atherosclerosis, glomerulonephritis, cardiac allograft rejection, and rheumatoid arthritis. In addition, polymorphisms in CX3CR1, which reduce its binding activity to fractalkine, have been reported to increase the risk of HIV disease and to reduce the risk of coronary artery disease. This review will examine new concepts underlying fractalkine-mediated leukocyte migration and tissue damage, focusing primarily on the pathophysiological roles of fractalkine in various clinical conditions, especially in atherosclerosis and vascular injury.
Key Words: fractalkine ? endothelial cells ? vascular biology ? atherosclerosis ? inflammation
From Basic Research
The migration of leukocytes into extravascular tissues involves a cascade of molecular events, including the elaboration of chemotactic factors and chemokines, the response to these factors, the interaction of leukocytes with endothelial cells (ECs), and leukocyte transmigration through the blood vessel wall.1–4 Chemokines can be divided broadly into 2 categories: (1) inflammatory chemokines, which recruit leukocytes in response to physiological stress, and (2) homeostatic chemokines, which are responsible for basal leukocyte trafficking and the forming of the architecture of secondary lymphoid organs.3,5,6 Expression of inflammatory chemokines can be elicited by almost any stimulus that alters cellular homeostasis, such as infections and immune disorders.7 However, inappropriately elevated expression of inflammatory chemokines may result in extensive tissue damage caused by activated leukocytes.6,8 Inasmuch as fractalkine is expressed on ECs activated by proinflammatory cytokines9 and has both chemoattractive and adhesive functions,10,11 it is likely that fractalkine is involved in the extravasation of leukocytes into inflamed tissues.12
Structure of Fractalkine
Chemokines were first described as chemoattractant cytokines synthesized at sites of inflammation and are now known to be major regulatory proteins for leukocyte recruitment and trafficking. More than 40 chemokines have been identified to date, and they are subdivided into 4 subfamilies, C-, CC-, CXC-, and CX3C-chemokines, according to the number and spacing of the first 2 cysteines in a conserved cysteine structural motif.5 Different chemokine classes tend to exhibit different ranges of leukocyte specificity, and a particular set of chemokines produced during an inflammatory process determines the extent, quality, and duration of the cellular infiltrate.1,13–15
Fractalkine is the only CX3C-chemokine to have been described.9,16 Fractalkine and CXCL16 (Bonzo ligand) contain multiple domains and are structurally distinct from other chemokines (Figure 1). The first 76 amino acids of the extracellular domain of fractalkine constitute a chemokine domain with a novel arrangement of cysteines (CXXXC: 2 cysteines separated by 3 other amino acids). The extracellular domain connects to an extended mucin-like stalk, followed by a transmembrane domain and an intracellular domain of 37 amino acids. The expression of membrane-bound fractalkine can be markedly induced on primary ECs by inflammatory cytokines, such as tumor necrosis factor (TNF)-, interleukin (IL)-1, and interferon (IFN)-.9 Soluble fractalkine can also be released, presumably by proteolysis at a membrane-proximal region by TNF-–converting enzyme (TACE [ADAM17]) and ADAM10,17,18 and this soluble form exhibits efficient chemotactic activity for monocytes, natural killer (NK) cells, and T cells.9 Because the endothelium is the first obstacle to leukocyte transmigration, the properties and functions of fractalkine on ECs support its role as a gateway controlling leukocyte extravasation at sites of inflammation.12,19
Figure 1. Schematic structure of fractalkine. Fractalkine, a CX3C-chemokine, is a large protein of 373 amino acids containing multiple domains and is structurally distinct from other chemokines, ie, CXCLs, CCLs, and XCLs. Beginning with the predicted signal peptide, it contains an N-terminal chemokine domain (residues 1 to 76) with the unique 3-residue insertion between cysteines (CX3C), mucin-like stalk (residues 77 to 317) with predicted O-glycosylated serine, and threonine (?), transmembrane domain (residues 318 to 336), and intracellular domain (residues 337 to 373). RR indicates a membrane-proximal dibasic motif similar to a dibasic cleavage site in syndecans. CXCL16 (Bonzo ligand) has a structure similar to that of fractalkine.
Adhesive Function of Fractalkine
Chemokines together with adhesion molecules regulate the appropriate "addressing and delivery" of each leukocyte subtype to healthy or diseased body compartments.15 The first step in the classical pathway of leukocyte migration involves transient, selectin-mediated interactions between rolling leukocytes and the endothelium. Next, integrins on leukocytes are activated by chemokines that have been produced locally; they are presented on glycosaminoglycans (triggering), resulting in firm adhesion between leukocytes and ECs (firm adhesion). Leukocytes then extravasate through the vascular wall and into the surrounding tissue (transmigration, Figure 2a).1–4 Before the identification and description of fractalkine, it had been assumed that all chemokines are secreted as soluble molecules that must associate with cell surface proteoglycans and tissue matrix components, such as glycosaminoglycan, to retain the local chemokine gradient.20 After this association, the interaction between chemokines and their specific receptors on leukocytes triggers the activation of members of the integrin family of adhesion molecules through a G-protein–dependent mechanism.3,6
Figure 2. Schematic model of classical and fractalkine-mediated pathways in the adhesion cascade. Leukocyte migration from the circulation into the peripheral tissue is a stepwise process. a, The classical pathway. The first step involves transient, weak, selectin-mediated binding (tethering). Next, integrins on leukocytes are activated by chemokines that have been presented on glycosaminoglycans (triggering), resulting in firm adhesion between leukocytes and ECs (adhesion). Finally, leukocytes migrate through the endothelial layer in response to a chemokine gradient (transmigration). b, Fractalkine-mediated pathway. Fractalkine is expressed on ECs as the membrane-bound form and captures leukocytes in a selectin- and integrin-independent manner. Interaction between fractalkine and CX3CR1 can also increase integrin avidity, resulting in firmer adhesion. Leukocytes then extravasate through the vascular wall and into the tissue to a chemokine gradient. Fractalkine may facilitate extravasation of circulating leukocytes by mediating cell adhesion through the initial tethering and final transmigration steps.
In the case of fractalkine, the chemokine domain is presented at the top of a cell-bound extended mucin-like stalk,9,16 and fractalkine itself functions as an adhesion molecule,10 thereby obviating the need for both the association with proteoglycans and other adhesion molecules. Indeed, CX3CR1-expressing cells bind rapidly and with high affinity to immobilized fractalkine or fractalkine-expressing cells in both static and physiological flow conditions.10,11,21 Using video microscopy, Haskell et al22 have found that CX3CR1-expressing cells adhere more rapidly to immobilized fractalkine than to vascular cell adhesion molecule (VCAM)-1 without cell tethering and dislodging in flow conditions.22 Thus, fractalkine may facilitate the extravasation of circulating leukocytes by mediating cell adhesion through the initial tethering and the final transmigration steps (Figure 2b).12
In addition to the intrinsic adhesion function of fractalkine, CX3CR1 can also transduce signals through G proteins that enhance the avidity of integrin binding to its ligands.11 Therefore, the engagement of both CX3CR1 and integrins through the coexpression of fractalkine and integrin ligands, such as intercellular adhesion molecule (ICAM)-1 and VCAM-1, results in greatly enhanced cell adhesion compared with each system alone.12,23 This cooperative adhesive function of fractalkine and integrin has been confirmed to occur under conditions of physiological flow.24
CX3CR1 and Leukocyte Subsets
CD4+ helper T cells (Th) as well as CD8+ cytotoxic T cells (Tc) are subdivided into 2 distinct populations based on the profile of cytokine production. Th1 and Tc1 cells secrete IFN-, TNF-?, and IL-2, mediate immune responses against intracellular pathogens, and are associated with pathological process, such as organ-specific autoimmune diseases. Conversely, Th2 and Tc2 cells produce IL-4, IL-5, IL-6, and IL-13, mediate immune responses against extracellular pathogens, and are associated with allergic immune responses.25,26 Recent studies have shown that various lymphocyte subsets with differential tissue tropism, in accordance with their particular developmental stages and/or functional properties, express specific chemokine receptors.14,27 Although this conclusion is still controversial, a number of groups have reported that Th1 cells preferentially express CCR5 and CXCR3 (Th1-associated chemokine receptors), whereas Th2 cells preferentially express CCR4 and possibly CCR3 and CCR8 (Th2-assocaited chemokine receptors). Kim et al28 have reported that overlapping patterns of expression of chemokine receptors effectively distinguish Th1 from Th2 cells, ie, CCR4-CXCR3+ and CCR4+CXCR3- for Th1 and Th2 cells, respectively.
Helper T cells are further subdivided into 2 distinct subsets according to the expression of CCR7, the homing chemokine receptor to secondary lymphoid organs. A linear differentiation from CCR7+ na?ve cells to CCR7+ lymph node–homing memory cells and, finally, to CCR7- tissue-homing effector memory cells has been reported.29 Thus, memory T cells lacking CCR7 produce the effector cytokine IFN- with rapid kinetics (effector memory T cells), whereas, T cells expressing CCR7 represent a pool of central memory T cells.27 On the other hand, it has been reported that the majority of polarized effector T cells are CCR7+ and that CCR7 ligands are able to attract na?ve as well as the vast majority of activated and effector/memory T cell stages.28,30
CD8+ cytotoxic T cells start to express lytic mediators, perforin and granzymes, during differentiation to memory/effector stages after antigenic stimulation.31 Terminally differentiated effector CD8+ T cells do not express CD27, CD28 (costimulatory molecules), or CD62L (L-selectin), and they possess high cytolytic activity that produces IFN- and TNF-.32,33 We have previously identified CX3CR1 and have demonstrated that it is expressed on most CD16+ NK cells, the majority of CD14+ monocytes, and a substantial fraction of CD3+ T cells.10 Recently, Nishimura et al34 characterized the phenotypes of lymphoid cells expressing CX3CR1. The majority of CX3CR1-expressing CD4+ and CD8+ T cells coexpress CCR5, but not CXCR3, suggesting that CX3CR1-expressing T cells partly overlap Th1 and Tc1 cells, respectively.34 This is consistent with a previous study of Fraticelli et al,35 who reported that CX3CR1 is preferentially expressed in Th1 compared with Th2 cells and that Th1, but not Th2, cells respond to fractalkine. In addition, CX3CR1-expressing cells, including CD4+ T cells, CD8+ T cells, T cells, and NK cells, also express CD57 and CD11b (good markers for cytotoxic lymphocytes) but rarely express CD27, CD28, or CD62L.34 Most CX3CR1-expressing cells possess cytoplasmic granules containing perforin and granzyme B.34 Collectively, these data suggest that CX3CR1 is a highly selective chemokine receptor and surface marker for cytotoxic effector lymphocytes, including NK cells, cytotoxic T lymphocytes (CTLs), and T cells, which express high levels of perforin and granzyme B, regardless of their lineage and mode of target cell recognition.
Fractalkine is also known to exert an effect on monocytes. Bazan et al9 have reported that fractalkine induces the migration of monocytes, and Imai et al10 have demonstrated that CD14+ monocytes express CX3CR1. Furthermore, fractalkine induces migration and enhances integrin-dependent cell adhesion in the monocytic cell line, THP-1 cells, as well as in fresh monocytes.11,23,36 Very recently, it has been reported that CD14lowCD16+ monocytes preferentially express CX3CR1 and undergo efficient binding to fractalkine-expressing cells and transendothelial migration in response to fractalkine.37,38 Thus, the fractalkine/CX3CR1 system may contribute to the pathogenesis of vascular and tissue injury by enhancing cell adhesion and facilitating transmigration of CX3CR1-expressing monocytes as well as lymphocytes.12
Fractalkine and Cytotoxicity
Almost all CD16+ NK cells express CX3CR1, suggesting that they are important targets of the biological effects of fractalkine (ie, chemotaxis, adhesion, and activation) while also having cytoplasmic granules containing perforin and granzyme B. Indeed, soluble fractalkine can induce the transmigration of NK cells9,10 and granule exocytosis by NK cells in a dose-dependent and pertussis toxin–sensitive manner, in association with enhanced cytolytic function against NK-sensitive target cells.39
Similar to NK cells, CX3CR1-expressing CD8+ and CD4+ T cells, but not those without surface CX3CR1, showed terminally differentiated effector phenotypes with cytotoxic granules. CD8+ T cells sorted into the CX3CR1-positive population indeed possess much greater cytotoxic activity than do presorted or CX3CR1-negative CD8+ T cells by CD3 monoclonal antibody–mediated redirected cytotoxicity assay.34 Because excessive activation of cytotoxic lymphocytes causes incidental vascular and tissue damage, the expression of fractalkine on ECs may be involved in vascular injury. This hypothesis is supported by experiments using ECV304 cells or human umbilical vein ECs transfected with fractalkine cDNA, resulting in the de novo expression of fractalkine on the cell surface membrane while not changing the expression of ICAM-1 or VCAM-1.10,39 The transfected cells showed increased interaction with NK cells and enhanced susceptibility to NK cell–mediated cytolysis compared with mock-transfected control cells.39 These findings suggest that the expression of fractalkine at the site of inflammation can attract and activate NK cells through CX3CR1 and that NK cells, once activated under such conditions, can lyse neighboring ECs despite MHC class I expression, which inhibits NK cell activation signals through interaction with inhibitory receptors that recognize MHC class I, such as certain killer cell immunoglobulin-like receptors (Figure 3).12,39
Figure 3. Biological functions of fractalkine: Engagement of CX3CR1 and integrins through coexpression of fractalkine and integrin ligands results in firm adhesion. CX3CR1-expressing cytotoxic effector cells including NK cells, CD8+ T cells, and T cells contain cytoplasmic granules. When these cells are activated by membrane-bound fractalkine or activating receptors, they may damage neighboring ECs. Membrane-bound fractalkine enhanced the effect of other chemokines on migration of CX3CR1-expressing cells into tissue. Transmigrated CX3CR1-expressing cells, activated by fractalkine, produce IFN-, leading to Th1 response. IFN- also enhances expression of fractalkine on ECs, indicating paracrine-feedback loop system.
Fractalkine and Inflammation
Nishimura et al34 observed that in addition to the original chemotactic function of soluble fractalkine, membrane-bound fractalkine enhanced the effect of other chemokines on the migration of CX3CR1-expressing lymphocytes in a transmigration assay using fractalkine-expressing ECV304 cells. The transmigration of CD8+ T cells (CX3CR1+/CCR5+) and NK cells (CX3CR1+/CXCR1+) to secondary chemokines (MIP-1?, a ligand for CCR5, and IL-8, a ligand for CXCR1, respectively) was significantly increased in the presence of membrane-bound fractalkine. Thus, fractalkine expressed on inflamed endothelium may play a role as a vascular gateway for cytotoxic effector cells (CX3CR1-expressing cells) by rapidly capturing them from the blood and by promoting their migration into tissue, where Th1 polarization may occur through IFN- production (Figure 3).
NK cells are important in innate immunity through the production of cytokines, including IFN-, TNF-, granulocyte-macrophage colony–stimulating factor, IL-3, IL-5, IL-10, and IL-15.40 IFN-, produced by NK cells and T cells as well as Th1 cells, has also been shown to be related to Th1 cell polarization.41,42 Recently, Yoneda et al43 have reported that stimulation of NK cells with immobilized fractalkine, but not with soluble fractalkine, or coculture of NK cells with fractalkine-expressing cells markedly induces IFN- production, suggesting a role for fractalkine expressed on ECs in developing Th1 responses. IFN- also enhances the expression of fractalkine on ECs,9,10 indicating the existence of a paracrine-feedback loop system in which ECs may be activated to produce more fractalkine (Figure 3).
To Clinical Disease
Cytotoxic lymphocytes, including NK cells, T cells, and CD8+ T cells, function in the immune defense against infections and tumors. However, in a variety of pathological conditions, excessive activity by such cells may damage tissues, including the endothelium.1,6,12,44 Although the possible involvement of fractalkine in such damage has not been thoroughly examined, accumulating evidence regarding the physiological effects of fractalkine might provide an insight into the pathogenesis of various diseases.
Atherosclerosis and Cardiovascular Disease
Atherosclerotic lesions contain large numbers of immune cells, particularly macrophages and T cells, which orchestrate inflammatory responses.45 There is growing evidence to suggest that fractalkine may be involved in atherosclerosis and cardiovascular pathophysiology. High levels of fractalkine mRNA expression, as well as mRNA encoding other 16q13-chromosome–linked chemokines, CCL17 (thymus- and activation-regulated chemokine ), and CCL22 (macrophage-derived chemokine ), have been observed in some, but not all, human arteries with advanced atherosclerotic lesions.46 Similar to atherosclerotic coronary artery disease, vessels from diabetic patients have been reported to express fractalkine in the deep intima.47 Circulating monocytes are the precursors of foam cells in the atherosclerotic lesion, and chemokines are important in directing monocyte migration from the blood to the vessel wall.48 Lesnik et al49 and Combadiere et al50 have reported that fractalkine expression is upregulated in atherosclerotic lesions of apolipoprotein E–deficient (apoE-/-) mice and that crossing CX3CR1-/- into the apoE-/- background results in decreased atherosclerotic lesion formation with reduced macrophage accumulation.49,50 Gene polymorphisms at amino acids 249 and 280 of human CX3CR1 have been reported to be a genetic risk factor for coronary artery disease.51,52 CX3CR1-V249I/T280M heterozygosity is associated with a markedly reduced risk of acute coronary events. This protective effect could be explained by the decreased ability of monocytes to adhere to vascular endothelium.
Although atherosclerosis is a multifactorial disease, often occurring as a complication of hypertension, obesity, and diabetes, it is also likely that infectious agents contribute to the development of atherosclerosis and to plaque instability and rupture.53,54 Two chronic human infections, the intracellular parasitic bacterium Chlamydia pneumoniae and human cytomegalovirus, are considered candidates. Interestingly, several studies have suggested that C pneumoniae infection may contribute to atherosclerotic plaque progression and rupture, at least in part, by accumulation of CD8+ T cells.55,56 In addition, the viral chemokine receptor US28, encoded by human cytomegalovirus, binds a broad spectrum of chemokines, including fractalkine, with high affinity and also recognizes membrane-associated fractalkine.57,58 A possible role for cytomegalovirus infection in exacerbating vascular pathology after angioplasty or organ transplantation has been also reported.59 Both of these infections induce the production of inflammatory chemokines and proinflammatory cytokines, such as TNF-, IL-1, and IFN-, which probably activate ECs. Despite the apparent lack of impact of polymorphisms in CX3CR1 on peripheral arterial disease,60 these findings suggest that it is likely that the fractalkine/CX3CR1 system may nevertheless be important in the pathogenesis of atherosclerotic and coronary vascular diseases.12,61,62
Allograft Rejection
Acute allograft rejection is characterized by an intense cellular immune response marked by the influx of circulating leukocytes into the transplant.44 Robinson et al63 have reported that fractalkine expression is significantly enhanced in rejecting cardiac allografts and is particularly prominent on vascular tissues and endothelium. Moreover, the treatment of recipients with anti-CX3CR1–blocking antibodies significantly prolonged allograft survival.63 Haskell et al64 have demonstrated that the survival time of allogeneic cardiac transplants is significantly increased in the presence of subtherapeutic levels of cyclosporin A in CX3CR1-knockout mice and that this prolongation is associated with a reduction in the infiltration of macrophages, NK cells, and other leukocytes. These findings suggest that the NK cells act in concert with cyclosporin A–sensitive T cells to effect graft rejection. Together, these results indicate an important role of the fractalkine/CX3CR1 system in graft rejection.
Renal Disease
There are a number of reports suggesting a role for fractalkine in human renal diseases (glomerulonephritis, renal tumors, and renal transplants) and in kidney disease in animal models. For example, a viral chemokine similar to macrophage inflammatory protein II, with antagonistic activity for CC-, CXC-, and CX3C-chemokine receptors, reduced the infiltration of leukocytes significantly and attenuated proteinuria in the rat crescent glomerulonephritis model.65 The expression of fractalkine and the presence of CX3CR1-expressing cells, such as CD16+ NK cells, have been demonstrated in patients with various types of nephropathies.66–70 Feng et al71 have reported that anti-CX3CR1 antibody treatment dramatically blocked leukocyte infiltration into the glomeruli, prevented crescent formation, and improved renal function, suggesting a role for fractalkine and CX3CR1-expressing cells in the pathogenesis of human glomerulonephritis.
HIV Infections
Increased expression of fractalkine has been detected in lymph nodes and brain tissue from patients with HIV. The increased expression of fractalkine protects neurons from 2 HIV-1 neurotoxins (Tat and platelet-activating factor, which play key roles in neural apoptosis in the brain)72 but induces the depletion of CX3CR1-positive Th cells by contact with dendritic cells.73 It has also been reported that CX3CR1 polymorphism may influence the pathogenesis of HIV infection. HIV-infected patients homozygous for CX3CR1-I249M280 progress to AIDS more rapidly than do those with other haplotypes. Functional CX3CR1 analysis showed that fractalkine binding is reduced among patients homozygous for this particular haplotype. Thus, it has been concluded that the specific polymorphism, CX3CR1-I249M280, is a recessive genetic risk factor in HIV.74
Other Inflammatory Diseases
The involvement of fractalkine as an inflammatory mediator has also been reported in the immunopathogenesis of various Th1-dominated inflammatory diseases. Synovial tissue macrophages, fibroblasts, ECs, and dendritic cells express fractalkine and CX3CR1 in patients with rheumatoid arthritis as well as in an adjuvant-induced arthritis model in rats.75–77 Furthermore, fractalkine in synovial fluid from patients with rheumatoid arthritis promotes angiogenic activity in vitro.78 It has been reported that EC dermal dendrocytes and keratinocytes from patients with lichen planus or psoriasis express high levels of fractalkine.35,79,80 The involvement of fractalkine/CX3CR1 has been also reported in pulmonary arterial hypertension,81 lung cancer,82 and acute hepatitis83 in humans and in prediabetic NOD mice.84 Taken together, these reports indicate that fractalkine may be expressed in many tissues and may be involved in the accumulation of CX3CR1-positive T cells at inflammation sites in Th1-dominated diseases.
Conclusions
Fractalkine, a unique chemokine, can fulfill the dual functions of an adhesion molecule and a chemoattractant. Fractalkine is expressed on activated ECs and functions as a vascular gateway by attracting CX3CR1-expressing NK cells, CTLs, and macrophages with immediate cytolytic function. Inappropriate expression or function of fractalkine might well be involved in inflammatory conditions leading to vascular and tissue damage. We now appreciate that the fractalkine/CX3CR1 system is important in various clinical diseases, such as atherosclerosis, cardiovascular disease, graft rejection, HIV infection, and inflammatory diseases. Efforts to elucidate the precise physiological role of fractalkine will provide conceptual, diagnostic, and therapeutic intervention for fractalkine-mediated pathophysiological conditions.
Acknowledgments
This work was supported by grants 13877075, 13226124, and 13557160 from the Japanese Ministry of Education, Science, and Culture (to H.U.). We acknowledge the help of numerous colleagues who have provided us with insightful discussion on the fractalkine and CX3CR1 system, in particular, Drs O. Yoneda, S. Goda, H. Inoue, and M. Nishimura.
References
Cines DB, Pollak ES, Buck CA, Loscalzo J, Zimmerman GA, McEver RP, Pober JS, Wick TM, Konkle BA, Schwarts BS, Marnathan ES, McCrae KR, Hug BA, Schmidt A-M, Stern DM. Endothelial cells in physiology and in the pathophysiology of vascular disorders. Blood. 1998; 91: 3527–3561.
Middleton J, Patterson AM, Gardner L, Schmutz C, Ashton BA. Leukocyte extravasation: chemokine transport and presentation by the endothelium. Blood. 2002; 100: 3853–3860.
Moser B, Loetscher P. Lymphocyte traffic control by chemokines. Nat Immunol. 2001; 2: 123–128.
Worthylake RA, Burridge K. Leukocyte transendothelial migration: orchestrating the underlying molecular machinery. Curr Opin Cell Biol. 2001; 13: 569–577.
Zlotnik A, Yoshie O. Chemokines: a new classification system and their role in immunity. Immunity. 2000; 12: 121–127.
Gerard C, Rollins BJ. Chemokine and disease. Nat Immunol. 2001; 2: 108–115.
Murdoch C, Finn A. Chemokine receptors and their role in inflammation and infectious diseases. Blood. 2000; 95: 3032–3043.
Proudfoot AEI. Chemokine receptors: multifaceted therapeutic targets. Nat Rev Immunol. 2002; 2: 106–115.
Bazan JF, Bacon KB, Hardiman G, Wang W, Soo K, Ross D, Greaves DR, Zlotnik A, Schall TJ. A new class of membrane-bound chemokine with a CX3C motif. Nature. 1997; 385: 640–644.
Imai T, Hieshima K, Haskell C, Baba M, Nagira M, Nishimura M, Kakizaki M, Takagi S, Nomiyama H, Schall TJ, Yoshie O. Identification and molecular characterization of fractalkine receptor CX3CR1, which mediates both leukocyte migration and adhesion. Cell. 1997; 91: 521–530.
Goda S, Imai T, Yoshie O, Yoneda O, Inoue H, Nagano Y, Okazaki T, Imai H, Bloom ET, Domae N, Umehara H. CX3C-chemokine, fractalkine enhanced adhesion of THP-1 cells to endothelial cells through integrin-dependent and independent mechanisms. J Immunol. 2000; 164: 4313–4320.
Umehara H, Bloom ET, Okazaki T, Domae N, Imai T. Fractalkine and vascular injury. Trends Immunol. 2001; 22: 602–607.
Baggiolini M. Chemokines and leukocyte traffic. Nature. 1998; 392: 565–568.
Yoshie O, Imai T, Nomiyama H. Related article chemokines in immunity. Adv Immunol. 2001; 78: 57–110.
Kunkel EJ, Butcher E. Chemokines and the tissue-specific migration of lymphocytes. Immunity. 2002; 16: 1–4.
Pan Y, Lioyd C, Zhou H, Dolich S, Deeds J, Gonzalo J-A, Vath J, Gosselin M, Ma J, Dussault B, Woolf E, Alperin G, Culpepper J, Gutierrez-Ramos JC, Gearing D. Neurotactin, a membrane-anchored chemokine upregulated in brain inflammation. Nature. 1997; 387: 611–617.
Garton KJ, Gough PJ, Blobel CP, Murphy G, Greaves DR, Dempsey PJ, Raines EW. Tumor necrosis factor--converting enzyme (ADAM17) mediates the cleavage and shedding of fractalkine (CX3CL1). J Biol Chem. 2001; 276: 37993–38001.
Tsou C-L, Haskell CA, Charo IF. Timor necrosis factor--converting enzyme mediates the inducible cleavage of fractalkine. J Biol Chem. 2001; 276: 44622–44626.
Umehara H, Imai T. The role of fractalkine in leukocyte adhesion and migration, and vascular injury. Drug News Perspect. 2001; 14: 460–464.
Tanaka Y, Adams DH, Hubscher S, Hirano H, Siebenlist U, Shaw S. T-cell adhesion induced by proteoglycan-immobilized cytokine MIP-1?. Nature. 1993; 361: 79–82.
Fong AM, Robinson LA, Steeber DA, Tedder TF, Yoshie O, Imai T, Patel D. Fractalkine and CX3CR1 mediate a novel mechanism of leukocyte capture, firm adhesion, and activation under physiologic flow. J Exp Med. 1998; 188: 1413–1419.
Haskell CA, Cleary MD, Charo IF. Molecular uncoupling of fractalkine-mediated cell adhesion and signal transduction: rapid flow arrest of CX3CR1-expressing cells is independent of G-protein activation. J Biol Chem. 1999; 274: 10053–10058.
Umehara H, Goda S, Imai T, Nagano Y, Minami Y, Tanaka Y, Okazaki T, Bloom ET, Domae N. Fractalkine, a CX3C-chemokine, functions predominantly as an adhesion molecule in monocytic cell line THP-1. Immunol Cell Biol. 2001; 79: 298–302.
Kerfoot SM, Lord SE, Bell RB, Gill V, Robbins SM, Kubes P. Human fractalkine mediates leukocyte adhesion but not capture under physiological shear conditions: a mechanism for selective monocyte recruitment. Eur J Immunol. 2003; 33: 729–739.
Kourilsky P, Truffa-Bachi P. Cytokine fields and the polarization of the immune response. Trends Immunol. 2001; 22: 502–509.
Rhodes SG, Graham SP. Is "timing" important for cytokine polarization? Trends Immunol. 2002; 23: 246–249.
Sallusto F, Mackay CR, Lanzavecchia A. The role of chemokine receptors in primary, effector, and memory immune responses. Annu Rev Immunol. 2000; 18: 593–620.
Kim CH, Rott L, Kunkel EJ, Genovese MC, Andrew DP, Wu L, Butcher E. Roles of chemokine receptor association with T cell polarization in vivo. J Clin Invest. 2001; 108: 1331–1339.
Sallusto F, Lenig D, Forster R, Lipp M, Lanzavecchia A. Two subsets of memory T lymphocytes with distinct homing potentials and effector functions. Nature. 1999; 401: 708–712.
Debes GF, Hopken UE, Hamann A. In vivo differentiated cytokine-producing CD4+ T cells express functional CCR7. J Immunol. 2002; 168: 5441–5447.
Shresta S, Pham CT, Thomas DA, Grauber TA, Ley TJ. How do cytotoxic lymphocytes kill their targets? Curr Opin Immunol. 1998; 10: 581–587.
Hamann D, Roos MTL, van Lier RAW. Face and phases of human CD8+ T-cell development. Immunol Today. 1999; 20: 177–180.
Tomiyama H, Matsuda T, Takiguchi M. Differentiation of human CD8+ T cells from a memory to memory/effector phenotype. J Immunol. 2002; 168: 5538–5550.
Nishimura M, Umehara H, Nakayama T, Yoneda O, Hieshima K, Kakizaki M, Domae N, Yoshie O, Imai T. Dual functions of fractalkine/CX3CR1 in trafficking of circulating cytotoxic effector lymphocytes that are defined by CX3CR1 expression. J Immunol. 2002; 168: 6173–6180.
Fraticelli P, Sironi M, Bianchi G, D’Ambrosio D, Albanesi C, Stoppacciaro A, Chieppa M, Allavena P, Ruco L, Girolomoni G, Sinigaglia F, Vecci A, Mantovani A. Fractalkine (CX3CL1) as an amplification circuit of polarized Th1 responses. J Clin Invest. 2001; 107: 1173–1181.
Chapman GA, Moores KE, Gohil J, Berkhout TA, Patel L, Green P, Macphee CH, Stewart BR. The role of fractalkine in the recruitment of monocytes to the endothelium. Eur J Pharmacol. 2000; 392: 189–195.
Ancuta P, Rao R, Moses A, Mehle A, Shaw SK, Luscinskas FW, Gabuzda D. Fractalkine preferentially mediates arrest and migration of CD16+ monocytes. J Exp Med. 2003; 197: 1701–1707.
Geissmann F, Jung S, Littman DR. Blood monocytes consist of two principal subsets with distinct migration properties. Immunity. 2003; 19: 71–82.
Yoneda O, Imai T, Gouda S, Inoue H, Yamauchi A, Okazaki T, Yoshie O, Domae N, Umehara H. NK cell-mediated vascular injury. J Immunol. 2000; 164: 4055–4062.
Seaman WE. Natural killer cells and natural killer T cells. Arthritis Rheum. 2000; 43: 1204–1217.
Rengarajan J, Szabo SJ, Glimcher LH. Transcriptional regulation of Th1/Th2 polarization. Immunol Today. 2000; 21: 479–483.
Murphy KM, Reiner SL. The lineage decisions of helper T cells. Nat Rev Immunol. 2002; 2: 933–944.
Yoneda O, Imai T, Inoue H, Nishimura M, Minami Y, Bloom ET, Mimori T, Domae N, Umehara H. Membrane bound form of fractalkine induces IFN- production by NK cells: a role for Th1 response. Eur J Immunol. 2003; 33: 53–58.
Nelson PJ, Krensky AM. Chemokines, chemokine receptors, and allograft rejection. Immunity. 2001; 14: 377–386.
Hansson GK. Immune mechanisms in atherosclerosis. Arterioscler Thromb Vasc Biol. 2001; 21: 1876–1890.
Greaves DR, Hakkeinen T, Lucas AD, Liddiard H, Jones E, Quinn CM, Senaratne J, Green FR, Tyson K, Hoyle J, Shanahan C, Weissberg PL, Gordon S, Yla-Hertulla S. Linked chromosome 16q13 chemokines, macrophage-derived chemokine, fractalkine, and thymus- and activation-regulated chemokine, are expressed in human atherosclerotic lesions. Arterioscler Thromb Vasc Biol. 2001; 21: 923–929.
Wong BWC, Wong D, McManus BM. Characterization of fractalkine (CX3CL1) and CX3CR1 in human coronary arteries with native atherosclerosis, diabetes mellitus, and transplant vascular disease. Cardiovasc Pathol. 2002; 11: 332–338.
Glass CK, Witztum JL. Atherosclerosis: the road ahead. Cell. 2001; 104: 503–516.
Lesnik P, Haskell CA, Charo IF. Decreased atherosclerosis in CX3CR1-/- mice reveals a role for fractalkine in atherogenesis. J Clin Invest. 2003; 111: 333–340.
Combadiere C, Potteaux S, Gao J-L, Esposito B, Casanova S, Lee EJ, Debre P, Tedgui A, Murphy PM, Mallat Z. Decreased atherosclerotic lesion formation in CX3CR1/apolipoprotein E double knockout mice. Circulation. 2003; 107: 1009–1016.
Moatti D, Faure S, Fumeron F, Amara MEW, Seknadji P, McDermott DH, Debre P, Aumont MC, Murphy PM, de Prost D, Combadiere C. Polymorphism in the fractalkine receptor CX3CR1 as a genetic risk factor for coronary artery disease. Blood. 2001; 97: 1925–1928.
MacDermott DH, Halcox JPJ, Schenke WH, Waclawiw MA, Merrell MN, Epstein N, Quyyumi AA, Murphy PM. Association between polymorphism in the chemokine receptor CX3CR1 and coronary vascular endothelial dysfunction and atherosclerosis. Circ Res. 2001; 89: 401–407.
Epstein SE, Zhou YF, Zhu J. Infection and atherosclerosis: emerging mechanistic paradigms. Circulation. 1999; 100: 1–9.
Greaves DR, Channon KM. Inflammation and immune responses in atherosclerosis. Trends Immunol. 2002; 23: 535–541.
Muhlestein J, Anderson J, Hammond Z, Zhao L, Trehan S, Schwobe E, Carlquist J. Infection with Chlamydia pneumoniae accelerates the development of atherosclerosis and treatment with azithromycin prevents it in a rabbit model. Circulation. 1998; 97: 633–636.
Nadareishvili ZG, Koziol DE, Szekely B, Ruetzler C, LaBiche R, McCarron R, DeGraba TJ. Increased CD8+ T cells associated with Chlamydia pneumoniae in symptomatic carotid plaque. Stroke. 2001; 32: 1966–1972.
Kledal TN, Rosenkilde MM, Schwartz TW. Selective recognition of the membrane-bound CX3C chemokine, fractalkine, by the human cytomegalovirus-encoded broad-spectrum receptor US28. FEBS Lett. 1998; 441: 209–214.
Casarosa P, Bakker RA, Verzijl D, Navis M, Timmerman H, Leurs R, Smit MJ. Constitutive signaling of the human cytomegalovirus-encoded chemokine receptor US28. J Biol Chem. 2001; 276: 1133–1137.
Streblow DN, Kreklywich C, Yin Q, Melena VTDL, Corless CL, Smith PA, Brakebill C, Cook CL, Vink C, Bruggeman CA, Nelson JA, Orloff SL. Cytomegalovirus-mediated upregulation of chemokine expression correlates with the acceleration of chronic rejection in rat heart transplants. J Virol. 2003; 77: 2182–2194.
Gugl A, Renner W, Seinost G, Brodmann M, Pabst E, Wascher TC, Paulweber B, Iglseder B, Pilger E. Two polymorphisms in the fractalkine receptor CX3CR1 are not associated with peripheral arterial disease. Atherosclerosis. 2003; 166: 339–343.
Alexander WR. Cytokine receptor CX3CR-1 and fractalkine: new factors in the atherosclerosis drama? Circ Res. 2001; 89: 376–377.
Cybulsky MI, Hegele RA. The fractalkine receptor CX3CR1 is a key mediator of atherogenesis. J Clin Invest. 2003; 111: 1118–1120.
Robinson LA, Nataraj C, Thomas DW, Howell DN, Griffiths R, Bautch V, Patel DD, Feng L, Coffman TM. A role for fractalkine and its receptor (CX3CR1) in cardiac allograft rejection. J Immunol. 2000; 165: 6067–6072.
Haskell C, Hancock WW, Salant DJ, Gao W, Csizmadia V, Peters W, Faia K, Fituri O, Rottman JB, Charo IF. Targeted deletion of CX3CR1 reveals a role for fractalkine in cardiac allograft rejection. J Clin Invest. 2001; 108: 679–688.
Chen S, Bacon KB, Li L, Garcia GE, Xia Y, Lo D, Thompson DA, Siani MA, Yamamoto T, Harrison JK, Feng L. In vivo inhibition of CC and CX3C chemokine-induced leukocyte infiltration and attenuation of glomerulonephritis in Wistar-Kyoto (WKY) rats by vMIP-II. J Exp Med. 1998; 188: 193–198.
Furuichi K, Wada T, Iwata Y, Sakai N, Yoshimoto K, Shimizu M, Kobayashi K, Takasawa K, Kida H, Takeda S, Matsushima K, Yokoyama H. Upregulation of fractalkine in human crescentic glomerulonephritis. Nephron. 2000; 87: 314–320.
Ito Y, Kawachi H, Morioka Y, Nakatsue T, koike H, Ikezuni Y, Oyanagi A, Natori Y, Natori Y, Nakamura T, Gejyo F, Shimizu F. Fractalkine expression and the recruitment of CX3CR1+ cells in the prolonged mesangial proliferative glomerulonephritis. Kidney Int. 2002; 61: 2044–2057.
Segerer S, Hughes E, Hudkins KL, Mack M, Goodpaster T, Alpers CE. Expression of the fractalkine receptor (CX3CR1) in human kidney disease. Kidney Int. 2002; 62: 488–495.
Cockwell P, Chakravorty SJ, Girdlestone J, Savage COS. Fractalkine expression in human renal inflammation. J Pathol. 2002; 196: 85–90.
Chakravorty SJ, Cockwell P, Girdlestone J, Brooks CJ, Savage COS. Fractalkine expression on human renal tubular epithelial cells: potential role in mononuclear cell adhesion. Clin Exp Immunol. 2002; 129: 150–159.
Feng L, Chen S, Garcia GE, Xia Y, Siani MA, Botti P, Wilson CB, Harrison JK, Bacon KB. Prevention of crescent glomerulonephritis by immunoneutralization of the fractalkine receptor CX3CR1. Kidney Int. 1999; 56: 612–620.
Faussat A, Bouchet-Delbos L, Berrebi D, Durand-Gasselin I, Coulomb-L’Hermine A, Krzysiek R, Galanaud P, Levy Y, Emilie D. Deregulation of the expression of the fractalkine/fractalkine receptor complex in HIV-infected patients. Blood. 2001; 98: 1678–1686.
Tong N, Perry SW, Zhang Q, James HJ, Guo H, Brooks A, Bal H, Kinnear SA, Fine S, Epstein LG, Dairaghi D, Schall TJ, Gendelman HE, Dewhurst S, Scharer LR, Gelbard HA. Neuronal fractalkine expression in HIV-1 encephalitis: roles for macrophage recruitment and neuroprotection in the central nervous system. J Immunol. 2000; 164: 1333–1339.
Faure S, Meyer L, Costagliola D, Vaneensberghe C, Genin E, Autran B, Delfraissy JF, McDermott DH, Murphy PM, Debre P, Theodorou I, Combadiere C. Rapid progression to AIDS in HIV+ individuals with a structural variant of the chemokine receptor CX3CR1. Science. 2000; 287: 2274–2277.
Ruth JH, Rottman JB, Katschke KJ Jr, Qin S, Wu L, LaRosa G, Ponath P, Rope RM, Koch AE. Selective lymphocytes chemokine receptor expression in the rheumatoid joint. Arthritis Rheum. 2001; 44: 2750–2760.
Ruth JH, Volin MV, Haines GK III, Woodruff DC, Katschke KJ Jr, Woods JM, Park CC, Morel JCM, Koch AE. Fractalkine, a novel chemokine in rheumatoid arthritis and in rat adjuvant-induced arthritis. Arthritis Rheum. 2001; 44: 1568–1581.
Nanki T, Imai T, Nagasaka K, Urasaki Y, Nonomura Y, Taniguchi K, Hayashida K, Hasegawa J, Yoshie O, Miyasaka N. Migration of CX3CR1-positive T cells producing type 1 cytokines and cytotoxic molecules into synovium of patients with rheumatoid arthritis. Arthritis Rheum. 2002; 46: 2878–2883.
Volin MV, Woods JM, Amin MA, Connors MA, Harlow LA, Koch AE. Fractalkine: a novel angiogenic chemokine in rheumatoid arthritis. Am J Pathol. 2001; 159: 1521–1530.
Raychaudhuri SP, Jiang W-Y, Farber EM. Cellular localization of fractalkine at sites of inflammation: antigen-presenting cells in psoriasis express high levels of fractalkine. Br J Dermatol. 2001; 144: 1105–1113.
Sugaya M, Nakamura K, Mitsui H, Takekoshi T, Saeki H, Tamaki K. Human keratinocytes express fractalkine/CX3CL1. J Dermatol Sci. 2003; 31: 179–187.
Balabanian K, Foussat A, Dormuller P, Durand-Gasselin I, Capel F, Bouchet-Delbos L, Portier A, Marfaing-Koka A, Krzysiek R, Rimaniol A-C, Simonneau G, Emilie D, Humbert M. CX3C chemokine fractalkine in pulmonary arterial hypertension. Am J Respir Crit Care Med. 2002; 165: 1419–1425.
Fujimoto K, Imaizumi T, Yoshida H, Takanashi S, Okumura K, Satoh K. Interferon- stimulates fractalkine expression in human bronchial epithelial cells and regulates mononuclear cell adherence. Am J Respir Cell Mol Biol. 2001; 25: 233–238.
Efsen E, Grappone C, DeFranco RMS, Milani S, Romanelli RG, Bonacchi A, Caligiuri A, Failli P, Annunziato F, Paglial G, Pinzani M, Laffi G, Gentilini P, Marra F. Up-regulated expression of fractalkine and its receptor CX3CR1 during liver injury in humans. J Hepatol. 2002; 37: 39–47.
Cardozo AK, Proost P, Gysemans C, Chen M-C, Mathieu C, Eizirik DL. IL-1? and IFN- induce the expression of diverse chemokines and IL-15 in human and rat pancreatic islet cells, and in islets from pre-diabetic NOD mice. Diabetologia. 2003; 46: 255–266.