Rapid leukocyte integrin activation by chemokines

Summary: Chemokines control selective targeting of circulating leukocytes to the microvasculature by triggering inside-out signal transduction pathways leading to integrin-dependent adhesion. Integrin activation by chemokines is very rapid, is downmodulated within minutes and appears to involve both enhanced heterodimer lateral mobility on the plasma membrane, facilitating encounters with dispersed ligand, as well as induction of a high-affinity state. These two modalities of integrin activation by chemokines involve distinct signaling pathways in the cell, yet complement each other functionally, allowing binding of rolling cells under conditions of low as well as high ligand density. Recent data show that chemokines generate both pro- and anti-adhesive intracellular signaling events, whose equilibrium is likely to be relevant to the kinetics of adhesion and de-adhesion, and to cell movement during diapedesis and chemotaxis. Importantly, chemokines utilize different signaling mechanisms to modulate the activity of distinct integrin subtypes. These recent advances suggest that chemokines may regulate adhesive responses of immune cells based not only on patterns of chemokine receptor expression, but also on variable signaling pathways that can modulate the pro-adhesive responses of leukocytes as a function of their differentiated state, and of the local microenvironment.     

Regulation of integrin function by T cell activation

Lymphocyte adhesiveness is dynamically regulated in response to conditions in the extracellular environment. One mechanism of regulation of integrin adhesion receptors involves a rapid, but transient, increase in integrin function upon T lymphocyte activation. These integrin activating signals can be initiated either via ligation of Ig superfamily members that are coupled to tyrosine kinase cascades, such as the CD3/T cell receptor, CD2, and CD28, or by G proteincoupled receptors for chemokines. Analysis of integrin activation induced by CD3/TCR, CD2 and CD28 suggests a critical role for phosphoinositide 3-OH kinase (PI 3-K). This review summarizes recent insights into PI 3-K-dependent regulation of integrin function in leukocytes, including the mechanisms by which these receptors are coupled to PI 3-K, and potential downstream effectors of PI 3-K that regulate integrin-mediated adhesion in leukocytes.     

P-selectin primes leukocyte integrin activation during inflammation

Selectins mediate leukocyte rolling and prime leukocytes for integrin-mediated leukocyte adhesion. However, neither the in vivo importance of nor the signaling pathway by which selectin-mediated integrin activation occurs has been determined. We report here that P-selectin-deficient mice manifested impaired leukocyte adhesion, which was 'rescued' by soluble P-selectin. Mechanistically, the cytoplasmic domain of P-selectin glycoprotein ligand 1 formed a constitutive complex with Nef-associated factor 1. After binding of P-selectin, Src kinases phosphorylated Nef-associated factor 1, which recruited the phosphoinositide-3-OH kinase p85-p110delta heterodimer and resulted in activation of leukocyte integrins. Inhibition of this signal-transduction pathway diminished the adhesion of leukocytes to capillary venules and suppressed peritoneal infiltration of leukocytes. Our data demonstrate the functional importance of this newly identified signaling pathway mediated by P-selectin glycoprotein ligand 1.     

Regulation of integrin function by T cell activation: points of convergence and divergence

Lymphocyte adhesiveness is dynamically regulated in response to conditions in the extracellular environment. One mechanism of regulation of integrin adhesion receptors involves a rapid, but transient, increase in integrin function upon T lymphocyte activation. These integrin activating signals can be initiated either via ligation of Ig superfamily members that are coupled to tyrosine kinase cascades, such as the CD3/T cell receptor, CD2, and CD28, or by G protein-coupled receptors for chemokines. Analysis of integrin activation induced by CD3/TCR, CD2 and CD28 suggests a critical role for phosphoinositide 3-OH kinase (PI 3-K). This review summarizes recent insights into PI 3-K-dependent regulation of integrin function in leukocytes, including the mechanisms by which these receptors are coupled to PI 3-K, and potential downstream effectors of PI 3-K that regulate integrin-mediated adhesion in leukocytes.     

Genetic analysis of integrin activation in T lymphocytes

Summary: Among the myriad receptors expressed by T cells, the sine qua non is the CD3/T cell receptor (CD3/TCR) complex, because it is uniquely capable of translating the presence of a specific antigen into intracellular signals necessary to trigger an immune response against a pathogen or tumor. Much work over the past 2 decades has attempted to define the signaling pathways leading from the CD3/TCR complex that culminate ultimately in the functions necessary for effective T cell immune responses, such as cytokine production. Here, we summarize recent advances in our understanding of the mechanisms by which the CD3/TCR complex controls integrin-mediated T cell adhesion, and discuss new information that suggests that there may be unexpected facets to this pathway that distinguish it from those previously defined.     

Selective human endothelial cell activation by chemokines as a guide to cell homing

An original model of organo-specific, immortalized and stabilized endothelial cell lines was used to delineate the part played by some chemokines (CCL21, CX3CL1, CCL5 and CXCL12) and their receptors in endothelium organo-specificity. Chemokine receptor expression and chemokine presentation were investigated on organo-specific human endothelial cell lines. Although the chemokines showed distinct binding patterns for the various endothelial cell lines, these were not correlated with the expression of the corresponding receptors (CX3CR1, CXCR4, CCR5 and CCR7). Experiments with CCL21 on peripheral lymph node endothelial cells demonstrated that the chemokine did not co-localize with its receptor but was associated with extracellular matrix components. The specific activity of chemokines was clearly shown to be related to the endothelial cell origin. Indeed, CX3CL1 and CCL21 promoted lymphocyte recruitment by endothelial cells from the appendix and peripheral lymph nodes, respectively, while CX3CL1 pro-angiogenic activity was restricted to endothelial cells from the appendix and skin. The high specificity of the chemokine/endothelium interaction allowed the design of a direct in vitro endothelial cell targeting assay. This unique cellular model demonstrated a fundamental role for chemokines in conferring on the endothelium its organo-specificity and its potential for tissue targeting through the selective binding, presentation and activation properties of chemokines.     

Regulation of T cell integrin function by adapter proteins

Integrins are cell surface heterodimers that bind adhesion molecules expressed on other cells or in the extracellular matrix. Integrin-mediated interactions are critical for T cell development in the thymus, migration of T cells in the periphery, and induction of T cell effector functions. In resting T cells, integrins are maintained in a low affinity state. Engagement of the T cell receptor or chemokine receptors increases integrin affinity, enabling integrins to bind their ligands and initiate a signaling cascade resulting in altered cell morphology and motility. Our laboratory is interested how adapter proteins, mediators of intracellular signal transduction, regulate both signals from the T cell receptor to integrins (inside-out signaling) and (outside-in) signals from integrins into the cell.     

CC chemokines in allergic inflammation

CC chemokines are small inducible proteins that are related to interleukin 8. Recent studies have shown that several CC chemokines, MCP-1, MCP-3, RANTES and MIP-1 α, act on basophils and/or eosinophils via GTP-binding protein-coupled receptors. Marco Baggiolini and Clemens Dahinden discuss the involvement of CC chemokines in the recruitment and activation of the main effector cells of allergic inflammation.     

Leukocyte integrin activation and deactivation: novel mechanisms of balancing inflammation

Leukocyte recruitment into tissue forms the basis of immune surveillance and direct immune defense. It proceeds in a cascade-like fashion. The first contact of leukocytes with the endothelium is mediated by selectins and their counter receptors, followed by rolling and integrin-mediated arrest. While rolling, neutrophils collect different inflammatory signals which can activate several signaling pathways leading to leukocyte adhesion to the endothelium and transmigration through the blood vessel wall into the inflamed tissue. Whereas inflammatory reactions are beneficial and necessary for host defense, they need to be balanced and controlled to prevent harmful consequences and tissue destruction. In this article, we discuss the different signaling pathways that ensure rapid and efficient integrin activation on leukocytes. In addition, we report on a recently identified novel endogenous mechanism that counteracts and balances integrin activation, thereby limiting leukocyte recruitment and the extent of inflammation. Further investigation of this new mechanism may allow providing new approaches for the development of the next generation of anti-inflammatory drugs.     

Roles of integrin activation in eosinophil function and the eosinophilic inflammation of asthma

Eosinophilic inflammation is a characteristic feature of asthma. Integrins are highly versatile cellular receptors that regulate extravasation of eosinophils from the postcapillary segment of the bronchial circulation to the airway wall and airspace. Such movement into the asthmatic lung is described as a sequential, multistep paradigm, whereby integrins on circulating eosinophils become activated, eosinophils tether in flow and roll on bronchial endothelial cells, integrins on rolling eosinophils become further activated as a result of exposure to cytokines, eosinophils arrest firmly to adhesive ligands on activated endothelium, and eosinophils transmigrate to the airway in response to chemoattractants. Eosinophils express seven integrin heterodimeric adhesion molecules: alpha 4 beta 1 (CD49d/29), alpha 6 beta 1 (CD49f/29), alpha M beta 2 (CD11b/18), alpha L beta 2 (CD11a/18), alpha X beta 2 (CD11c/18), alpha D beta2 (CD11d/18), and alpha 4 beta 7 (CD49d/beta 7). The role of these integrins in eosinophil recruitment has been elucidated by major advances in the understanding of integrin structure, integrin function, and modulators of integrins. Such findings have been facilitated by cellular experiments of eosinophils in vitro, studies of allergic asthma in humans and animal models in vivo, and crystal structures of integrins. Here, we elaborate on how integrins cooperate to mediate eosinophil movement to the asthmatic airway. Antagonists that target integrins represent potentially promising therapies in the treatment of asthma.     

Regulation of TCR-mediated T cell activation by TNF-RII

In the present study, we investigated the role of tumor necrosis factor receptor II (TNF-RII) in human T cell activation induced via the T cell receptor (TCR) in an antigen-presenting cell-independent system. Our results confirm that interaction of TNF-alpha with TNF-RII but not TNF-RI is directly costimulatory to TCR-mediated T cell activation, thereby augmenting T cell proliferation, expression of T cell activation markers (CD25, human leukocyte antigen-DR, TNF-RII), and secretion of cytokines such as interferon-gamma and TNF-alpha. In contrast to the well-defined costimulatory molecule CD28, costimulation via TNF-RII showed significant differences in kinetics, requirement for cross-linking, redundancy of intracellular signaling pathways involved, and the capacity to induce interleukin (IL)-2, IL-10, and IL-13 secretion. In addition, cross-linking TNF-RII had the capacity to down-regulate TCR/CD28-induced Ca++ mobilization, IL-2 mRNA expression, and IL-2 and IL-10 secretion. Taken together, our findings demonstrate that TNF-RII plays a unique role among the T cell costimulatory molecules, as TNF-RII ligation can have positive and negative effects on TCR-dependent signaling. TNF-RII cross-linking has an inhibitory effect on early TCR signaling events proximal to induction of Ca++ flux, which ultimately leads to modulation of the T cell cytokine pattern expressed.     

Role of chemokines in inflammation and immunoregulation

Chemokines are first noted for their ability to attract and activate leukocytes, as well as their potential role as mediators of inflammation. However, emerging data have shown that various chemokines may exert, other biologic effects both inside and outside the immune system. Inducible chemokines participate primarily in inflammatory responses and comprise the bulk of the chemokine family. Constitutive chemokines are expressed primarily in secondary lymphoid organs and some nonlymphoid organs, where they play amajor role in lymphocyte homing. Studies expanding to areas beyond inflammatory leukocyte recruitment, will likely give us a more complete picture of chemokine function, its regulation in lymphoid and nonlymphoid tissues and ways of utilizing endogenous chemokines to intervene with immune and inflammatory reactions.     

Orchestrating the orchestrators: chemokines in control of T cell traffic

The understanding of how chemokines orchestrate the trafficking and activity of immune cells has increased considerably. So far, over 50 chemokines and 20 chemokine receptors have been identified. Detailed analyses have demonstrated the function of chemokine receptors on T cell subsets, the temporal and spatial expression patterns of chemokines in vivo and the phenotypes of animals genetically deficient in one component or several components of the chemokine-chemokine receptor system. New microscopy modalities for studying the influence of chemokines on the migratory activity of T cells in the lymph node have also brought new insights. Here we review such advances with particular emphasis on control of the migration of T cell subsets in lymph nodes and in peripheral tissues in homeostasis and inflammation.     

Virus-induced polyclonal T cell activation is followed by apoptosis: partitioning of CD8+ T cells based on {alpha}4 integrin expression

Systemic infection with lymphocytic choriomeningitis virus (LCMV)is accompanied by marked splenomegaly, primarily reflectingthe accumulation of CD8⁺ T cells with an activated phenotypee.g. VLA-4^hi). Analysis of DNA content using 7-aminoactinomycin-Drevealed that as many as 30% of CD8⁺ T cells are cycling aroundday 6 post-infection and that virtually all cycling cells expressa high level of VLA-4. In accord with the relatively stableCD4⁺ cell number, only few cycling CD4⁺ cells were observed.Following virus control, splenic lymphocyte numbers decreasedgradually and during this period many apoptotic cells were detectedin the white pulp using terminal deoxynucleotidyl transferase-mediateddUTP-biotin nick end labeling. Flow cytometric analysis of DNAcontent revealed a high frequency of cells with subnormal levelsof DNA in the CD8⁺VLA-4^hi subset, whereas the frequency waslow for other lymphocyte subsets studied (CD4⁺, CD8⁺VLA-4¹⁰and B cells). In addition, numbers of CD8⁺VLA-4^hi cells constitute{small tilde}30% of splenocytes at the peak of the responseand undergo preferential decrease during normalization of splenocytenumbers. Together these findings indicate that LCMV-inducedactivation of T cells is followed by apoptosis of many of theactivated cells. Those CD8⁺VLA-4^hi cells which do persist inLCMV Immune mice are more sensitive to treatment with the cell-cycle-specificdrug hydroxyurea than are phenotypically naive T cells. Ourresults therefore indicate that LCMV infection induces polyclonalactivation of CD8 ⁺ cells which is followed by apoptosis ofmost of the triggered cells while a smaller subset persistsas a primed population which include cycling cells.