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Vascular Endothelium: Checkpoint for Inflammation and Immunity Barbara C. Biedermann

Physiology 16:84-88, 2001. ; You might find this additional info useful... This article cites 18 articles, 9 of which you can access for free at: http://physiologyonline.physiology.org/content/16/2/84.full#ref-list-1 This article has been cited by 7 other HighWire-hosted articles: http://physiologyonline.physiology.org/content/16/2/84#cited-by Updated information and services including high resolution figures, can be found at: http://physiologyonline.physiology.org/content/16/2/84.full

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of gene variants (or single nucleotide polymorphisms) of the RAS in an in vivo model system.

References

Vascular Endothelium: Checkpoint for Inflammation and Immunity Barbara C. Biedermann Vascular endothelial cells play a threefold role in the interaction with leukocytes. First, they are gatekeepers in leukocyte recruitment to inflammatory foci and lymphocyte homing to secondary lymphoid organs. Second, they modulate leukocyte activation. Finally, they are targets of leukocyte-derived molecules, resulting either in endothelial cell activation or death.

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here are three major classes of leukocytes, which differ in their physiological roles as well as in their fates after trafficking through vascular endothelium (Fig. 1). Granulocytes are important representatives of the innate immune system. They evade the blood stream to phagocytose invading microbes or dead tissue. They are not capable of recirculating and die within days of performing their task. Monocytes migrate into tissues, in which they settle and become resident macrophages. Macrophages process internalized microbes and present major histocompatability complex (MHC) class

B. C. Biedermann is in the Department of Internal Medicine, University Hospital, Kantonsspital Bruderholz, CH-4101 Bruderholz, Switzerland. 84

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II-bound antigen to lymphocytes. Under certain circumstances, macrophages differentiate into dendritic cells, the body’s most efficient and versatile antigen-presenting cells. Lymphocytes represent the antigen-specific immune system. Lymphocytes survey the body for the presence of antigens. Naive lymphocytes home in to secondary lymphoid organs to meet antigen-presenting cells and to become antigenspecific effector lymphocytes. Plasma cells and effector T lymphocytes leave the lymph node to reach the blood stream, from where they are recruited into peripheral tissue. Cytotoxic T lymphocytes (CTL) eliminate antigen-bearing cells through the perforin/ granzyme, fas/fas ligand, or cytokine pathway. In peripheral tissues, helper T lymphocytes amplify macrophage function by release of activating cytokines. Anti0886-1714/99 5.00 © 2001 Int. Union Physiol. Sci./Am.Physiol. Soc.

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1. Cervenka L, Mitchell KD, Oliverio MI, Coffman TM, and Navar LG. Renal function in the AT1A receptor knockout mouse during normal and volumeexpanded conditions. Kidney Int 56: 1855–1862, 1999. 2. Davisson RL, Ding Y, Stec DE, Catterall JF, and Sigmund CD. Novel mechanism of hypertension revealed by cell-specific targeting of human angiotensinogen in transgenic mice. Physiol Genomics 1: 3–9, 1999. 3. Davisson RL, Kim HS, Krege JH, Lager DJ, Smithies O, and Sigmund CD. Complementation of reduced survival, hypotension and renal abnormalities in angiotensinogen deficient mice by the human renin and human angiotensinogen genes. J Clin Invest 99: 1258–1264, 1997. 4. Davisson RL, Oliverio MI, Coffman TM, and Sigmund CD. Divergent functions of angiotensin II receptor isoforms in brain. J Clin Invest 106: 103–106, 2000. 5. Gross V, Schunck WH, Honeck H, Milia AF, Kargel E, Walther T, Bader M, Inagami T, Schneider W, and Luft FC. Inhibition of pressure natriuresis in mice lacking the AT2 receptor. Kidney Int 57: 191–202, 2000. 6. Kim HS, Krege JH, Kluckman KD, Hagaman JR, Hodgin JB, Best CF, Jennette JC, Coffman TM, Maeda N, and Smithies O. Genetic control of blood pressure and the angiotensinogen locus. Proc Natl Acad Sci USA 92: 2735–2739, 1995. 7. Krege JH, John SWM, Langenbach LL, Hodgin JB, Hagaman JR, Bachman ES, Jennette JC, O’Brien DA, and Smithies O. Male-female differences in fertility and blood pressure in ACE-deficient mice. Nature 375: 146–148, 1995. 8. Okubo S, Niimura F, Matsusaka T, Fogo A, Hogan BL, and Ichikawa I. Angiotensinogen gene null-mutant mice lack homeostatic regulation

of glomerular filtration and tubular reabsorption. Kidney Int 53: 617–625, 1998. 9. Oliverio MI, Best CF, Kim H-S, Arendshorst WJ, Smithies O, and Coffman TM. Angiotensin II responses in AT1A-receptor deficient mice: a role for AT1B receptors in blood pressure regulation. Am J Physiol Renal Fluid Electrolyte Physiol 272: F515–F520, 1997. 10. Oliverio MI, Kim HS, Ito M, Le T, Audoly L, Best CF, Hiller S, Kluckman K, Maeda N, Smithies O, and Coffman TM. Reduced growth, abnormal kidney structure, and type 2 (AT2) angiotensin receptor-mediated blood pressure regulation in mice lacking both AT1A and AT1B receptors for angiotensin II. Proc Natl Acad Sci USA 95: 15496–15501, 1998. 11. Schnermann JB, Traynor T, Yang T, Huang YG, Oliverio MI, Coffman T, and Briggs JP. Absence of tubuloglomerular feedback responses in AT1A receptor-deficient mice. Am J Physiol Renal Physiol 273: F315–F320, 1997. 12. Siragy HM, Inagami T, Ichiki T, and Carey RM. Sustained hypersensitivity to angiotensin II and its mechanism in mice lacking the subtype-2 (AT2) angiotensin receptor. Proc Natl Acad Sci USA 96: 6506–6510, 1999. 13. Stec DE, Davisson RL, Haskell RE, Davidson BL, and Sigmund CD. Efficient liver-specific deletion of a floxed human angiotensinogen transgene by adenoviral delivery of cre-recombinase in vivo. J Biol Chem 274: 21285–21290, 1999. 14. Tsutsumi Y, Matsubara H, Masaki H, Kurihara H, Murasawa S, Takai S, Miyazaki M, Nozawa Y, Ozono R, Nakagawa K, Miwa T, Kawada N, Mori Y, Shibasaki Y, Tanaka Y, Fujiyama S, Koyama Y, Fujiyama A, Takahashi H, and Iwasaka T. Angiotensin II type 2 receptor overexpression activates the vascular kinin system and causes vasodilation. J Clin Invest 104: 925–935, 1999. 15. Yanai K, Saito T, Kakinuma Y, Kon Y, Hirota K, Taniguchi-Yanai K, Nishijo N, Shigematsu Y, Horiguchi H, Kasuya Y, Sugiyama F, Yagami K, Murakami K, and Fukamizu A. Renin-dependent cardiovascular functions and reninindependent blood-brain barrier functions revealed by renin-deficient mice. J Biol Chem 275: 5–8, 2000.

bodies secreted by B cells greatly amplify the phagocytosis of foreign material through a process called opsonization. On their way to sites of antigen challenge (microbial invasion, transplanted tissue, vaccine deposit) leukocytes have to cross vascular endothelial cells. Adhesion molecules in concert with chemokines play an essential role in leukocyte recruitment to secondary lymphoid organs as well as to peripheral tissue. Transmigration through the endothelium brings leukocytes into close contact with vascular cells. After this intimate interaction, leukocytes may further emigrate into parenchymal tissue. However, under certain circumstances the subendothelial space itself becomes a site of inflammation, such as in vasculitis, alloimmune vasculopathy, or arteriosclerosis. Endothelial cells are activated by proinflammatory cytokines to express adhesion molecules as well as high levels of antigen-presenting molecules (MHC class I and II). Adhesion molecules facilitate leukocyte recruitment. When endothelial cells express an antigen, they may become a direct target of leukocyte-derived effector molecules and finally succumb.

Adhesion molecules are involved in rolling, firm adhesion, and transmigration of leukocytes The physiological role of leukocyte adhesion molecules has been elucidated by the study of a particular human disease: leukocyte adhesion deficiency (LAD). Patients with inherited LAD disorders suffer from recurrent, severe bacterial infections due to a failure to recruit granulocytes to the site of microbial

invasion. CD18, the common β-chain of three intracellular adhesion molecule (ICAM)-1 ligands [lymphocyte functionassociated antigen-1 (LFA)-1, Mac-1, and p150,95] is mutated in patients suffering from LAD-1 (15). As a consequence of this defect, ICAM-1 ligands are virtually absent on the surface of leukocytes, and firm adhesion to vascular endothelium (a prerequisite for granulocyte evasion into tissues) is impossible. Patients with LAD have recurrent bacterial infections, suggestive of granulocyte dysfunction, but no obvious deficiency in antigen-specific immune responses. The recruitment of antigen-specific effector T cells to peripheral tissues is an important step in transplant rejection and graft vs. host disease, infection with intracellular pathogens (e.g., viruses), hypersensitivity reactions, and certain autoimmune disorders. Whereas the LFA-1/ICAM-1 interaction and CD15-E/P-selectin interaction are critical in neutrophil recruitment, lymphocyte recruitment to sites of antigen exposure involves additional or even redundant steps. This view is supported by the analysis of murine CD11a knockout lymphocyte (deficient in LFA-1) recruitment to secondary lymphoid organs (2). This study reveals a dominant role of LFA-1 in the recruitment to peripheral lymph nodes but not to the spleen. In addition, α4-integrins can compensate for the lack of LFA-1. Vascular endothelial cell adhesion molecule (VCAM)-1 is the preferred α4-integrin ligand in peripheral lymph nodes, whereas mucosa addressin cell adhesion molecule-1 is involved in recruitment to mesenteric lymph nodes and Peyer’s patches. VCAM-1 and ICAM-1, but not the selectins, have been shown to represent the dominant News Physiol. Sci. • Volume 16 • April 2001

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FIGURE 1. Fates of the 3 major classes of leukocytes after transmigration through vascular endothelium. Polymorphonuclear cells (PMN) transmigrate and die. Monocytes (Mo) transmigrate and become sessile macrophages (MQ). Lymphocytes (Ly) transmigrate, accumulate, and recirculate.

molecules involved in CD8 T cell recruitment to peripheral sites of viral infection (1).

Chemokines govern leukocyte recruitment by activation of integrins

“…leukocytes normally leave the perivascular area immediately to reach foci of antigen exposure.…” human immunodeficiencies. This suggests that in humans the chemokine system is organized in a redundant way. This view is also confirmed by the promiscuous nature of most chemokine receptors. Granulocytes are activated by a variety of chemokines such as interleukin-8, platelet activating factor, complement component 5a, leukotriene B4, and so forth. Under flow conditions, monocytes are activated by macrophage chemoattractant protein (MCP)-1 and interleukin-8 and lymphocytes are activated by stromal cell-derived factor 1α, 6Ckine, and macrophage inflammatory protein (MIP)-3β to firmly adhere to cytokine-activated endothelial cells or purified ICAM-1. In a murine model of listeria infection, MIP-1α was shown to be critical in mediating protection against a lethal infection by sensitized CD8 T lymphocytes (7). The precise cellular source of chemokines is often unknown. However, activated vascular endothelial cells have been shown to synthesize and secrete interleukin-8, MCP-3, MCP-1, and others.

Chronic vascular inflammation: a rare disorder or a common disease? After extravasation, leukocytes normally leave the perivascular area immediately to reach foci of antigen exposure or inflammation. In certain immune complex diseases, neutrophil granulocytes are recruited preferentially to the subendothelial and perivascular area, leading to so-called leukocytoclastic vasculitis. In solid organ transplantation and after allogeneic bone marrow/stem cell transplantation, vascular endothelial cells are antigen-bearing cells and therefore potential targets of alloantigen-specific lymphocytes. Under these circumstances, subendothelial lymphocytic infiltrates, called intimal arteritis or endothelialitis, are observed. It is not known which adhesion molecules and chemokines are involved in the accumulation of these predominantly CD8 lymphocytes in the intimal or peri86

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Leukocyte recruitment to peripheral tissues involves rolling, firm adhesion, and transmigration. Chemokines, synthesized at sites of inflammation or in secondary lymphoid organs, mediate rapid integrin activation through receptor-mediated activation of a pertussis toxin-sensitive α-subunit of Gi (for review, see Refs. 5 and 10). This G protein-dependent step supports firm adhesion of leukocytes to endothelial adhesion molecules VCAM-1 and ICAM-1. Complementary to site-specific adhesion molecule expression, they play an important role in directing leukocyte subsets to sites of inflammation or antigen exposure. In contrast to adhesion molecule deficiencies, which lead to increased susceptibility for bacterial infections, chemokine deficiencies are not known to cause congenital

capillary space. In solid organ transplantation, acute endothelialitis is recognized to be the harbinger of severe transplant rejection (6). Generally, antigen-specific immune attack leads to the rapid antibody- or cell-mediated elimination of antigenbearing cells. In the case of vascular endothelial cells, this would precipitate fibrinoid vessel wall necrosis and thrombus formation and would severely compromise organ perfusion. Under immunosuppressive treatment, this fatal course can be slowed. However, persistent vascular lymphocytic inflammation is thought to sustain the development of transplant-associated arteriosclerosis or chronic graft vs. host disease. A series of recently published experiments focus on interferon-γ as an important mediator of this chronic fibrotic vasculopathy in solid organ transplantation. When allogeneic hearts were transplanted into interferon-γ-deficient murine recipients, the development of graft vasculopathy was profoundly suppressed (13). Furthermore, the arteries showed virtually absent CD8 T cells and markedly reduced expression of VCAM-1 and ICAM-1. In a huSCID mouse model of transplant vasculopathy, a human artery is interposed in the murine abdominal aorta. Human interferon-γ was shown to be sufficient to induce intimal hyperplasia (16) indistinguishable from transplant-associated arteriosclerosis. This effect is presumably mediated through local expression of platelet-derived growth factor and its receptor. To characterize the molecular events that are involved in lymphocyte-endothelial cell interactions during a perivascular immune reaction, we cultured purified CD8 T lymphocytes with allogeneic vascular endothelial cells in the presence of exogenous interleukin-2 (3). In this in vitro system we observed the differentiation of CD8 T lymphocytes into allospecific, MHC class I-restricted CTL. Furthermore, vascular endothelial cells supported the emergence of endothelial cell-selective CTL lines. By cloning these lines we were able to demonstrate that cell type selectivity is a stable property of endothelial-stimulated CTL and not a transient regulatory effect of the coculture (4). We further showed at the clonal level that these endothelial cell-stimulated cells persistently express certain early activation markers, such as interleukin-2 receptor (CD25), and an important costimulatory molecule, CD40L, a member of the tumor necrosis factor (TNF) family. This early activation phenotype has been confirmed in the polyclonal endothelial cell-stimulated CD8 T cells as well. Endothelial cell-stimulated CTL are poor secretors of cytokine, TNF, and interferon-γ, and therefore intact endothelial cells may suppress the profibrotic activity of proinflammatory cytokines in the subendothelial microenvironment. Endothelial cells also profoundly suppress CD8 T cell activation by professional antigen-presenting cells. The physiological significance of endothelial cells as guardians of an anti-inflammatory vascular state adds a fascinating novel aspect to the manifold roles of these cells in maintaining tissue homeostasis. It is intriguing to speculate that immunoregulatory events are also involved in a much more common vascular disorder: arteriosclerosis (Fig. 2). In the western world, ~50% of people die from arteriosclerosis-related disease. An important role for activated inflammatory cells, T lymphocytes and macrophages in particular, has been proposed at all stages of the

disease (14). It is remarkable that inflammatory genes and leukocyte adhesion molecules are upregulated in the fibrous cap of atherosclerotic plaques compared with the tunica media of the artery (12). Of a series of transcription factors, early growth response gene-1 (egr-1) was elevated in these lesions. Its binding sites can be found in the promoter regions of a series of injury response genes, and it induces transcription of growth factors [PDGF-A and -B, transforming growth factor-β1], cytokines (TNF, interleukin-2), cell cycle regulators (e.g., p53), and adhesion molecules (e.g., ICAM-1) in reporter assays in vitro. It is hypothesized that a deregulated inflammatory response is involved in arteriosclerosis and drives lesion progression or destabilization. This hypothesis is supported by the fact that CD40L can be detected in atherosclerotic lesions. CD40L is an important activator molecule of dendritic cells and B cells, initiating antigen-specific immune responses and isotype switch of immunoglobulins involved in affinity maturation. CD40L deficiency causes a rare form of immunodeficiency, the X-linked hyper-IgM syndrome. Patients with this disease suffer from recurrent bacterial and fungal infections, suggesting a combined B and T lymphocyte defect. In atherosclerotic lesions, CD40L is not only detected in leukocytes but also in endothelial and smooth muscle cells (11). Inhibition of CD40-CD40L interaction stops lesion progression in murine models of arteriosclerosis. CD40 signaling in endothelial cells mediates expression of procoagulant tissue factor and therefore challenges one of the tissue-protecting qualities of vascular endothelium: to provide an anticoagulant endovascular surface. The presence of proinflammatory signaling molecules in lesions of chronic vascular diseases such

as transplant-associated vasculopathy and arteriosclerosis still does not prove that they are initiating the disease. These molecules might just be coincidentally present in lesions of arteriosclerosis and not even actively involved in the pathological process of lipid accumulation, vessel wall degeneration, and remodeling. Unless drugs can selectively target these proinflammatory mediators, and unless clinical trials will prove the efficacy of these drugs in reducing morbidity and mortality, their significance in sustaining human disease remains a fascinating hypothesis. I wish to thank Beat Oertli for critical comments and Reto Krapf for helpful discussions. This work is supported by a research grant from the Swiss National Science Foundation and the Department of Research/Biozentrum, University of Basel.

References 1. Bartholdy C, Marker O, and Thomsen AR. Migration of activated CD8(+) T lymphocytes to sites of viral infection does not require endothelial selectins. Blood 95: 1362–1369, 2000. 2. Berlin-Rufenach C, Otto F, Mathies M, Westermann J, Owen MJ, Hamann A, and Hogg N. Lymphocyte migration in lymphocyte function-associated antigen (LFA)-1-deficient mice. J Exp Med 189: 1467–1478, 1999. 3. Biedermann BC and Pober JS. Human endothelial cells induce and regulate cytolytic T cell differentiation. J Immunol 161: 4679–4687, 1998. 4. Biedermann BC and Pober JS. Human vascular endothelial cells favor clonal expansion of unusual alloreactive CTL. J Immunol 162: 7022–7030, 1999. 5. Campbell JJ and Butcher EC. Chemokines in tissue-specific and microenvironment-specific lymphocyte homing. Curr Opin Immunol 12: 336–341, 2000. 6. Colvin RB, Cohen AH, Saiontz C, Bonsib S, Buick M, Burke B, Carter S, Cavallo T, Haas M, Lindblad A, Manivel JC, Nast CC, Salomon D, Weaver News Physiol. Sci. • Volume 16 • April 2001

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FIGURE 2. Immunoregulatory events in the vessel wall sustain chronic vascular inflammation, e.g., in arteriosclerosis.

Egr-1 and Egr-1-inducible genes in mouse and human atherosclerosis. J Clin Invest 105: 653–662, 2000. 13. Nagano H, Mitchell RN, Taylor MK, Hasegawa S, Tilney NL, and Libby P. Interferon-γ deficiency prevents coronary arteriosclerosis but not myocardial rejection in transplanted mouse hearts. J Clin Invest 100: 550–557, 1997. 14. Ross R. Atherosclerosis is an inflammatory disease. Am Heart J 138: S419–S420, 1999. 15. Springer TA, Thompson WS, Miller LJ, Schmalstieg FC, and Anderson DC. Inherited deficiency of the Mac-1, LFA-1, p150,95 glycoprotein family and its molecular basis. J Exp Med 160: 1901–1918, 1984. 16. Tellides G, Tereb DA, Kirkiles-Smith NC, Kim RW, Wilson JH, Schechner JS, Lorber MI, and Pober JS. Interferon-γ elicits arteriosclerosis in the absence of leukocytes. Nature 403: 207–211, 2000. 17. Walzog B, Scharffetter-Kochanek K, and Gaehtgens P. Impairment of neutrophil emigration in CD18-null mice. Am J Physiol Gastrointest Liver Physiol 276: G1125–G1130, 1999. 18. Weninger W, Ulfman LH, Cheng G, Souchkova N, Quackenbush EJ, Lowe JB, and von Andrian UH. Specialized contributions by α(1,3)-fucosyltransferase-IV and FucT-VII during leukocyte rolling in dermal microvessels. Immunity 12: 665–676, 2000.

An Autocrine/Paracrine Mechanism Triggered by Myocardial Stretch Induces Changes in Contractility Horacio E. Cingolani, Néstor G. Pérez, and María C. Camilión de Hurtado An autocrine/paracrine mechanism is triggered by stretching the myocardium. This mechanism involves release of angiotensin II, release/increased formation of endothelin, activation of the Na+/H+ exchanger, increase in intracellular Na+, and the increase in the Ca2+ transient that underlies the slow force response to stretch. The autocrine/paracrine mechanism could explain how changes in afterload alter cardiac contractility.

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lthough the contractile performance of the heart is under continuous nervous, hormonal, and electrophysiological influence, the heart has intrinsic mechanisms by which it can adapt cardiac output to changing hemodynamic conditions. An increase in ventricular end diastolic volume (EDV), induced either by increasing aortic resistance to ejection or venous return, immediately leads to a more powerful contraction. This is the well known Frank-Starling mechanism that allows the heart to increase its output after the increase in venous return or to eject the same stroke volume against a greater afterload when an increase in arterial pressure takes place. However, over the next 10 or 15 min after the sudden stretch, there is a further increase in myocardial performance and EDV returns toward its original value (Fig. 1). The time constant of the phenomenon will depend on several factors, such as species differences, temperature, coronary blood flow, and so forth. Von Anrep (15) showed in 1912 that a heart dilatation induced by clamping the heart outflow was

H. E. Cingolani, N. G. Pérez, and M. C. Camilión de Hurtado are at the Centro de Investigaciones Cardiovasculares, Facultad de Ciencias Médicas, Universidad Nacional de La Plata, 1900 La Plata, Argentina. 88

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followed by a decline in heart volume toward the initial volume. His interpretation was that, perhaps, the decrease in the flow to the adrenal glands induced the release of catecholamines and a positive inotropic effect. In 1959, Rosenblueth et al. (11) called attention to the fact that both an increase in heart rate (Bowditch effect) and an increase in afterload triggered increases in contractility of the isolated canine right ventricle. They coined the expression “the twostaircase phenomenon.” Sarnoff et al. (13), in 1960, coined the term “homeometric autoregulation” to define the decrease in left ventricular EDV that occurs after the increase in diastolic volume induced by an increase in afterload. Since both reports (11, 13) were based on experiments performed in isolated hearts, the possibility of a positive inotropic effect due to the release of catecholamines by the adrenal glands was ruled out. In 1973, Parmley and Chuck (10) reproduced this phenomenon in isolated strips of ventricular myocardium. They showed that if the length of the muscle was increased, there were corresponding rapid and slow increases in developed force (1). The rapid change in force is thought to be the basis of the FrankStarling mechanism and is induced by an increase in the myofilament Ca2+ sensitivity. The slow force response (SFR) to 0886-1714/99 5.00 © 2001 Int. Union Physiol. Sci./Am.Physiol. Soc.

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C, and Weiss M. Evaluation of pathologic criteria for acute renal allograft rejection: reproducibility, sensitivity, and clinical correlation. J Am Soc Nephrol 8: 1930–1941, 1997. 7. Cook DN, Smithies O, Strieter RM, Frelinger JA, and Serody JS. CD8+ T cells are a biologically relevant source of macrophage inflammatory protein-1 alpha in vivo. J Immunol 162: 5423–5428, 1999. 8. Hu Y, Kiely JM, Szente BE, Rosenzweig A, and Gimbrone MA Jr. E-selectindependent signaling via the mitogen-activated protein kinase pathway in vascular endothelial cells. J Immunol 165: 2142–2148, 2000. 9. Karsan A, Cornejo CJ, Winn RK, Schwartz BR, Way W, Lannir N, GershoniBaruch R, Etzioni A, Ochs HD, and Harlan JM. Leukocyte adhesion deficiency type II is a generalized defect of de novo GDP-fucose biosynthesis. Endothelial cell fucosylation is not required for neutrophil rolling on human nonlymphoid endothelium. J Clin Invest 101: 2438–2445, 1998. 10. Loetscher P, Moser B, and Baggiolini M. Chemokines and their receptors in lymphocyte traffic and HIV infection. Adv Immunol 74: 127-180, 2000. 11. Mach F, Schonbeck U, Sukhova GK, Atkinson E, and Libby P. Reduction of atherosclerosis in mice by inhibition of CD40 signalling. Nature 394: 200–203, 1998. 12. McCaffrey TA, Fu C, Du B, Eksinar S, Kent KC, Bush H Jr, Kreiger K, Rosengart T, Cybulsky MI, Silverman ES, and Collins T. High-level expression of