Expression Of Leukocyte Adhesion Molecule-1 Research Articles

Differential effects of neutrophil-activating peptide 1/IL-8 and its homologues on leukocyte adhesion and phagocytosis.

Several structural homologues of the chemotactic peptide neutrophil-activating peptide 1/IL-8 (NAP-1/IL-8) were tested for their ability to influence the expression and function of adhesion-promoting receptors on human polymorphonuclear leukocytes (PMN). NAP-2, melanoma growth stimulatory activity, and two forms of NAP-1/IL-8 (ser-NAP-1/IL-8 and ala-NAP-1/IL-8, consisting of 72 and 77 amino acids, respectively), each caused an increase in the expression of CD11b/CD18 (CR3) and CR1, which was accompanied by a decrease in the expression of leukocyte adhesion molecule-1 (LAM-1, LECAM-1). The binding activity of CD11b/CD18 was also enhanced 3- to 10-fold by these peptides, but enhanced function was transient: binding of erythrocytes coated with C3bi reached a maximum by 30 min and declined thereafter. Ser-NAP-1/IL-8, ala-NAP-1/IL-8, NAP-2, and melanoma growth stimulatory activity also caused a two- to threefold enhancement of the phagocytosis of IgG-coated erythrocytes (EIgG) by PMN without causing a large increase in the expression of Fc gamma receptors. Enhanced phagocytosis of EIgG appeared to be mediated through CD11b/CD18, because F(ab')2 fragments of an antibody directed against CD18 inhibited NAP-1/IL-8-stimulated ingestion of EIgG. The four active peptides caused a rapid, transient increase in the amount of F-actin within PMN, indicating that they are capable of influencing the structure of the microfilamentous cytoskeleton, which participates in phagocytosis. Two other NAP-1/IL-8-related peptides, platelet factor 4 and connective tissue-activating peptide III, were without effect on expression of CD11b/CD18, CR1, and LAM-1, binding activity of CD11b/CD18, or Fc-mediated phagocytosis, and increased actin polymerization only slightly. Our observations indicate that several members of the NAP-1/IL-8 family of peptides were capable of promoting integrin-mediated adhesion and Fc-mediated phagocytosis, processes important in the recruitment of PMN to sites of inflammation and antimicrobial responses of PMN.

An activated CD8+ lymphocyte appears in lymph nodes of rhesus monkeys early after infection with simian immunodeficiency virus.

Although alterations in T lymphocyte subset distribution and function in the peripheral blood of HIV-infected humans are well defined, the extent to which these reflect changes in other lymphoid compartments is unclear. We have characterized the coincident changes in PBL and lymph nodes (LN)1 after simian immunodeficiency virus of macaques (SIVmac) infection of rhesus monkeys. Whereas no consistent change in CD8+ PBL was noted during the first 60 d after infection, CD8+ lymphocytes increased significantly in number in LN. These CD8+ LN lymphocytes exhibited an increased expression of MHC class II and a decreased expression of leukocyte adhesion molecule-1, suggesting that they were activated, but interestingly did not express CD25 (IL-2 receptor). Moreover, there was no evidence that these CD8+ LN cells were proliferating, suggesting that they had migrated to the LN. These changes in the LN CD8+ lymphocyte population preceded any detectable change in the light microscopic appearance of the LN. When SIVmac-specific effector T cell responses were assessed, the magnitude of virus-specific effector activity was nearly identical in the PBL and LN of each monkey studied. However, the presence of SIVmac-specific effector cells in the LN did not correlate with the presence of CD8+, MHC class II+ cells. These findings suggest that this numerically important CD8+ lymphocyte subpopulation may serve a regulatory function.

In vitro and in vivo activation of endothelial cells by colony-stimulating factors.

This study was designed to identify the set of functions activated in cultured endothelial cells by the hematopoietic growth factors, granulocyte colony-stimulating factor (G-CSF) and granulocyte macrophage-colony-stimulating factor (GM-CSF), and to compare them with those elicited by prototypic cytokines active on these cells. Moreover, indications as to the in vivo relevance of in vitro effects were obtained. G-CSF and GM-CSF induced endothelial cells to proliferate and migrate. In contrast, unlike appropriate reference cytokines (IL-1 and tumor necrosis factor, IFN-gamma), G-CSF and GM-CSF did not modulate endothelial cell functions related to hemostasis-thrombosis (production of procoagulant activity and of platelet activating factor), inflammation (expression of leukocyte adhesion molecule-1 and production of platelet activating factor), and accessory function (expression of class II antigens of MHC). Other colony-stimulating factors (IL-3 and macrophage-colony-stimulating factor) were inactive on all functions tested. In comparison to basic fibroblast growth factor (bFGF), G-CSF and GM-CSF induced lower maximal proliferation of endothelial cells, whereas migration was of the same order of magnitude. G-CSF and GM-CSF stimulated repair of mechanically wounded endothelial monolayers. Exposure to both cytokines induced shape changes and cytoskeletal reorganization consistent with a migratory phenotype. To explore the in vivo relevance of the in vitro effects of these cytokines on endothelium, we studied the angiogenic activity of human G-CSF in the rabbit cornea. G-CSF, but not the heat-inactivated molecule, had definite angiogenic activity, without any sign of inflammatory reactions. G-CSF was less active than bFGF. However, the combination of a nonangiogenic dose of bFGF with G-CSF resulted in an angiogenic response higher than that elicited by either individual cytokines. Thus, G-CSF and GM-CSF induce endothelial cells to express an activation/differentiation program (including proliferation and migration) related to angiogenesis.

Granulocyte-macrophage colony-stimulating factor and other cytokines regulate surface expression of the leukocyte adhesion molecule-1 on human neutrophils, monocytes, and their precursors.

There is increasing evidence that cytokines such as granulocyte-macrophage (GM)-CSF can profoundly affect the adhesion, aggregation, and mobility of neutrophils both in vitro and in vivo. However, the mechanisms whereby these factors might alter the adhesive properties of neutrophils are incompletely understood. A new family of cellular adhesion molecules has recently been identified by cDNA cloning. The members of this family include human leukocyte adhesion molecule-1 (LAM-1), the human endothelial-leukocyte adhesion molecule, and the mouse leukocyte homing receptor for high endothelial venules, MEL-14. LAM-1 is the human homologue of murine MEL-14, and is believed to mediate binding of leukocytes to human high endothelial venules. LAM-1 can be identified by mAb TQ-1, Leu 8, or anti-LAM1.1. The expression and regulation of LAM-1 on granulocytes, monocytes, and their precursors was investigated using flow cytometry and the anti-LAM-1.1 mAb. Neutrophils, eosinophils, monocytes, marrow myeloid cells, granulocyte/macrophage colony-forming unit, and burst-forming unit for erythroid cells were LAM-1+ by flow microfluorimetry. The regulation of LAM-1 expression was tested by treating various cell populations with cytokines or other stimuli for 0-90 min. Exposure of neutrophils, monocytes, and marrow myeloid cells to GM-CSF induced rapid and complete loss of LAM-1 from the cell surface, but had no effect on LAM-1 expression by lymphocytes. The loss of LAM-1 was temporally correlated with up-regulation of CD11b (Mo1), an adhesion molecule involved in neutrophil aggregation. Several other factors known to activate neutrophils also caused down-regulation of LAM-1 and up-regulation of CD11b, including TNF, FMLP, and leukotriene B4. Interestingly, granulocyte-CSF and IFN-gamma had minimal effects on neutrophil LAM-1 expression. Similar results were observed on monocytes and myeloid precursor cells. Thus, exposure of neutrophils to GM-CSF results in a profound change in surface expression of adhesion molecules, with coordinated up-regulation of CD11b and down-regulation of LAM-1. These changes in adhesion proteins are likely to alter aggregation and mobility of both mature myeloid cells and their precursors in patients receiving certain types of cytokine therapy.

Expression of the human leukocyte adhesion molecule, LAM1. Identity with the TQ1 and Leu-8 differentiation antigens.

The LAM1 molecule is a member of the new family of cellular adhesion/homing molecules that contain a lectin-like domain at their amino-terminal end followed by an epidermal growth factor-like domain and short consensus repeat units like those found in C3/C4 binding proteins. Two mAb that react with the leukocyte adhesion molecule 1 (LAM1) were produced and used to examine the cell-surface expression of LAM1. The anti-LAM1 antibodies were reactive with the majority of blood lymphocytes, NK cells, neutrophils, and monocytes. LAM1 was also expressed by subpopulations of phenotypically immature and mature thymocytes. Blood lymphocytes rapidly modulated LAM1 from the cell surface during PMA exposure for 60 min. Coordinate with the loss of LAM1 from the cell surface, PMA-treated lymphocytes lost the ability to bind to lymph node high endothelial venules, indicating that expression of LAM1 may play a role in lymphocyte homing. Mitogen stimulation of blood T and B lymphocytes also resulted in decreased LAM1 expression, but at a slower rate. LAM1 was only weakly expressed by a minority of spleen lymphocytes. However, culturing spleen lymphocytes in media alone resulted in increased expression of LAM1 by a subpopulation of the cells (40 to 60%). Concomitant mitogen stimulation of spleen lymphocytes resulted initially in down-regulation of LAM1 expression followed by increased expression of LAM1 and then subsequent loss of LAM1 from the cell surface. The pattern of anti-LAM1 antibody reactivity was identical to that reported for the TQ1 and Leu-8 antibodies, and all of these antibodies reacted with cells transfected with the LAM1 cDNA. Thus, LAM1 is broadly expressed by leukocytes, and binding of LAM1 may participate in the process of leukocyte extravasation into lymphoid organs or sites of acute inflammation with subsequent loss of LAM1 from the cell surface.