Role of p150,95 in adhesion, migration, chemotaxis and phagocytosis of human monocytes

The leukocyte function-associated antigen-1 (LFA-1), the C3bi receptor (CR3) and the p150,95 antigen belong to a family of leukocyte surface molecules consisting of bimolecular complexes with alpha chains of 170 kDa, 165 kDa and 150 kDa, respectively, and a common beta subunit with a mol. mass of 95 kDa. In order to determine the function of the p150,95 antigen on human monocytes and U937 cells, and to study the functional relationship between this antigen and LFA-1 or CR3, we investigated the influence of monoclonal antibodies (mAb) directed against these cell surface molecules on the adhesive properties of these cells. The observation that anti-beta chain mAb strongly inhibited migration, chemotaxis, adhesion and phagocytosis of monocytic cells indicates a major role for LFA-1 family antigens in monocyte functions. Detailed analysis with a panel of anti-alpha chain antibodies demonstrated that both p150,95 and LFA-1 mediate random migration whereas in contrast, p150,95 and CR3 were shown to be involved in the directed migration of monocytes to f-Met-Leu-Phe. Furthermore, adhesion of monocytes to plastic surfaces or monolayers of endothelial cells as well as phagocytosis of latex particles was mediated by p150,95. The results demonstrate that, in spite of its relative low expression, the p150,95 glycoprotein is a major adhesion-associated molecule expressed by human monocytic cells.     

Ligand binding by the p150,95 antigen of U937 monocytic cells: properties in common with complement receptor type 3 (CR3)

U937 cells (a monocytic cell line) grown in the presence of phorbol myristate acetate were surface labeled with 125I and the iC3b-binding proteins isolated by affinity chromatography on iC3b-Sepharose in the presence of divalent cations. Three polypeptides of 170, 150 and 95 kDa were found to bind specifically to iC3b-Sepharose. The polypeptides of 170 and 95 kDa were identified as the alpha and the beta subunits of CR3 by immunoprecipitation with OKM1 monoclonal antibody. The 150-kDa polypeptide was not immunoprecipitated by antibodies to the alpha subunit of CR3 or LFA-1. However, the 150-kDa polypeptide, together with the 95-kDa polypeptide, was immunoprecipitated with an anti-beta subunit-specific antibody IB4, which immunoprecipitates LFA-1, CR3 and p150,95. These results indicated that the 150-kDa polypeptide is the alpha subunit of the p150,95 antigen. The binding of p150,95 and CR3 to iC3b-Sepharose is specific as neither binds to C3u-Sepharose. A monoclonal antibody, 3.9, which immunoprecipitated the 150 and a 95-kDa polypeptide from U937 cells was characterized as being directed against the alpha-subunit of the p150,95 antigen. Phorbol myristate acetate-stimulated U937 cells from rosettes with EAC3b and EAiC3b but not with EAC3d cells. Monoclonal antibody 3.9 does not inhibit either type of rosetting, but we were unable to exclude a role for p150,95 in adherence of iC3b-coated particles. Since there is no rosetting with C3d-bearing particles it is unlikely that p150,95 is a receptor for C3d, a role for p150,95 which has been suggested by others (Wright, S.D., Licht, M.R. and Silverstein, S.C., Fed. Proc. 1984. 43: 413).     

Biochemical and functional characteristics of the human leukocyte membrane antigen family LFA-1, Mo-1 and p150,95

The human leukocyte function-associated (LFA-1) antigen, the monocyte differentiation antigen Mo-1 which is characterized as the C3bi receptor and the glycoprotein p150,95 are characterized biochemically. Immunoprecipitations carried out with 6 different monoclonal antibodies (mAb) against LFA-1 indicated that four mAb (SPV-L1, SPV-L5, SPV-L7 and SPV-L11) were directed against the alpha chain, whereas mAb CLB54 and MHM-23 were found to react with the common beta chain of LFA-1, Mo-1 and p150,95. LFA-1 and Mo-1 expressed on KG-1 cells or lymphocytes, monocytes and granulocytes from one donor were homogeneous. Interestingly the alpha chain of p150,95 showed heterogeneity. The molecular weight of the alpha chain expressed on monocytes was consistently higher than that of the alpha chain on granulocytes. The beta subunits of LFA-1 and Mo-1 (as detected by mAb Bear-1) are not only similar in molecular weight and isoelectric focusing patterns, but it is demonstrated here that they are also identically glycosylated and have similar protein backbones as judged by tryptic peptide mapping. In spite of their structural similarities. LFA-1 and Mo-1 differ completely in some of their biological functions. Anti-LFA-1 mAb strongly inhibited monocyte-dependent T cell proliferation induced by tetanus toxoid or Helix pomatia hemocyanin and pokeweed mitogen-driven specific antibody production in vitro, whereas the anti-Mo-1 antibody Bear-1 was ineffective. These results suggest that the differences in these biological functions of LFA-1 and Mo-1 may be related to their different alpha subunits, which may recognize specific counter structures.     

Human T cell antigens involved in cytotoxicity against allogeneic or autologous chemically modified targets. Association of the Leu 2a/T8 antigen with effector-target cell binding and of the T3/Leu 4 antigen with triggering

Monoclonal antibodies (mAb) recognizing human T cell differentiation antigens were employed to analyze the role of these antigens on T cell-mediated cytotoxicity against autologous 2,4,6-trinitrophenyl (TNP)-modified targets. The OKT3/anti-Leu 4 and anti-Leu 2a/OKT8^* mAb inhibited T cell-mediated cytotoxicity against autologous or unrelated TNP-modified targets, in the absence of complement and at the effector cell level. These cytotoxic effector cells were T3⁺, T8⁺, T11⁺, T4^?. To analyze the role of the T3/Leu 4 and Leu 2a/T8 T cell differentiation antigens in the cytolytic process, we investigated the stages of this process that were inhibited by the OKT3/anti-Leu 4 and anti-Leu 2a/OKT8^* mAb. Using: (a) visual adhesions, and (b) a single cell cytotoxicity assay in agarose, we observed that the OKT3 and anti-Leu 4 mAb did not inhibit binding of effector cells to allogeneic targets or to autologous E rosette-negative TNP-modified targets, although they significantly inhibited both the proportions of target cells in conjugates that were lysed, and the ⁵¹Cr release. In contrast, the anti-Leu 2a and OKT8^* mAb blocked cytotoxicity by inhibiting binding of effector cells to the allogeneic or to autologous chemically modified targets. To further analyze the stages of the cytolytic process (adhesion; programming for lysis or lethal hit; and cytotoxic cell-independent lysis) that were inhibited by these mAb, we employed the detachment and dispersion method. This method is based on the differential temperature requirements of adhesion (which occurred both at 37 °C or 20 °C) and of programming for lysis (which occurred at 37 °C but not at 20 °C). Operational adhesions were determined by the ⁵¹Cr-release assay after dispersion of effector and target cells in a 10% solution of dextran (mol. wt. 500000). Programming for lysis was determined by the ⁵¹Cr-release assay after detachment of effector-target cell conjugates with 10 mM EDTA and dispersion in 10% dextran solution. Using this method we determined that mAb recognizing the Leu 2a/T8 antigen blocked cytotoxicity by inhibiting adhesion and binding of effector cells to target cells. These antibodies do not affect post-adhesion stages of the cytolytic process. In contrast, the OKT3 and anti-Leu 4 mAb inhibit a post-adhesion step of the cytolytic process, that occurs before irreversible events of the programming for lysis stage have taken place. These results and other properties (lymphokine production, mitogenic properties) of the OKT3/anti-Leu 4 mAb suggest that the T3/Leu 4 antigen may be associated with triggering of lethal hit (and triggering of T cell functions in general) and signal transfer or transduction. In contrast, the Leu 2a/T8 antigen appears to be involved in binding of effector to target cells and may contribute to the affinity of the effector cells for the target.     

Defective membrane expression of the LFA-1 complex may be secondary to the absence of the beta chain in a child with recurrent bacterial infection

Membrane and intracellular processing of the LFA-1 macromolecular complex, known to be involved in cytolytic function of T lymphocytes, was investigated in a child with recurrent bacterial infections, impaired natural killer activity, T cell-mediated lymphocytolysis and absent adhesion and migration of phagocytic cells. Monoclonal antibodies to the LFA-1 alpha and beta subunits, able to precipitate the LFA-1 alpha, 180-kDa chain, the p151 chain and beta 94-kDa chain (shared by both alpha chains), were used in immunoprecipitation studies of patient and control phytohemagglutinin-blasts. Neither of the alpha chains nor the beta chain were found in precipitates obtained from 125I-surface-labeled patient cells in contrast to controls. However, the precursor of the LFA-1 alpha chain, a 170-kDa polypeptide, was identified in lysates of biosynthetically labeled patients' cells. These results suggest that the defective membrane expression of the LFA-1 complex may be secondary to the absence of the mature beta chain.     

C5a-stimulated human neutrophils use a subset of beta2 integrins to support the adhesion-dependent phase of superoxide production

Isolated human polymorphonuclear neutrophils (PMN) responded to human C5a with an immediate, transient release of superoxide lasting from 0.5 to 5 min. This was followed by a second release of superoxide, which began at 10 min after addition of C5a, was sustained for more than 30 min, and required ICAM-1 immobilized in the wells. F(ab')2 monoclonal antibody (mAb) preparations were used to dissect the role of individual beta2 integrins and to avoid the confounding effects of ligating Fc receptors. Anti-CD18 mAb treatment of the PMN had no effect on the immediate first phase but completely inhibited the second, adhesion-dependent phase of superoxide production. Anti-CR3 mAb only inhibited the adhesion phase of superoxide production partially, implying that other beta2 integrins were involved. A mixture of anti-CD11a, anti-CD11b, and anti-CD11c was not able to block superoxide production completely, suggesting a role for alphad/beta2. Surprisingly, blocking anti-LFA-1 mAb had no effect on superoxide production. Consistent with this observation, immobilized, purified ICAM-2, a specific counter-receptor for LFA-1, did not support the adhesion-dependent phase of-superoxide production. Thus, PMN treated with C5a used signals via CR3, P150/95, and alphad/beta2, but not LFA-1, to support superoxide production. LFA-1 has been shown by others to mediate most of the adhesion necessary for transendothelial migration in vivo. The inability of LFA-1 ligation to stimulate superoxide production may be an important means of preventing blood-vessel damage when PMN migrate across the endothelium.     

The human intraepithelial lymphocyte marker HML-1 is an integrin consisting of a beta 7 subunit associated with a distinctive alpha chain.

The membrane antigen defined by the monoclonal antibody (mAb) HML-1 is abundantly expressed on, and largely restricted to, the T cells which populate the intestinal epithelium. We show that the mature form of the antigen is a heterodimer comprising a 150-kDa alpha chain and a 120-kDa beta chain. Direct sequencing of tryptic peptides cleaved from the purified beta chain identified this polypeptide with the integrin beta 7 isotype. cDNA clones coding for the beta 7 chain have recently been isolated from T cell cDNA libraries, but the beta 7 chain had not been identified at the protein level. No information is available concerning the primary structure of the HML-1 alpha chain. We show that this subunit is synthesized as a precursor form that undergoes, like several other integrin alpha subunits, a post-translational cleavage of a peptide bond. Among the 11 human integrin alpha chains previously identified, 10 have biochemical features and/or a distribution different from those of HML-1 alpha. One, VLA alpha 4 (CD49d), has a molecular mass of 150 kDa and is expressed on HML-1+ cells but is not recognized by HML-1 mAb. We conclude that HML-1 is a novel member of the integrin family made of the beta 7 chain and of an as-yet-undescribed human alpha chain characterized by the post-translational cleavage of a 10-kDa peptide. HML-1 is, thus, probably the human counterpart of the mouse antigen M290.     

LFA-1 beta-chain synthesis and degradation in patients with leukocyte-adhesive proteins deficiency

The defective membrane expression of the adhesive protein family (LFA-1, Mo1 and p150,93) on leukocytes from certain patients with recurrent bacterial infections was shown to be secondary to the absence of synthesis of mature beta chain that is common to all three antigens (Springer et al., 1984, Lisowska-Grospierre et al., 1986). In all patients, studies of beta-chain biosynthesis that lead to this conclusion were performed using the monoclonal anti-beta chain antibody to isolate the beta subunit. Since this antibody detects the mature form of beta chain only, the potential presence of a precursor or of an abnormal beta chain in the patient's cells could not be tested. The availability of the polyclonal antibody to the purified beta subunit allowed us to re-examine the biosynthesis of the LFA-1 subunits in 3 affected children. In all 3 patients, the absence of membrane expression of the LFA-1, CR3 and p150,95 proteins was confirmed. The LFA-1 alpha-chain precursor of 170 kDa was detected in the lysates of PHA blasts of two children, but was not detected in the third. The beta-chain precursor of 85 kDa was isolated by the polyclonal anti-beta chain antiserum from the cytoplasm of phytohemagglutinin and Epstein-Barr virus-induced blasts of one patient. The same antibody precipitated some peptides of smaller mol. wt. from the cell lysates of 2 other patients. These results suggest that in this disorder the membrane nonexpression of the adhesive proteins is probably due to the structural abnormality of beta chain which, although synthesized, is rapidly degradated.     

Monoclonal antibodies to leucosialin (CD43) induce homotypic aggregation of the human mast cell line HMC-1: characterization of leucosialin on HMC-1 cells.

CD43 (leucosialin, sialophorin) is the major sialoprotein of nearly all circulating leucocytes and has important biological activities in cellular differentiation and activation. Recently, the expression of CD43 has also been demonstrated on mast cells and basophils by flow cytometry. In order to further characterize mast cell/basophil leucosialin we have investigated CD43 on the human mast cell line HMC-1, the human basophilic precursor cell line KU-812, and the human promonocytic cell line U-937. The apparent molecular weights (MW) were 123,000 (HMC-1 and KU-812) and 144,000 (U-937) by Western blot analysis. Expression of CD43 on HMC-1 was down-regulated after stimulation with phorbol myristate acetate (PMA). Three monoclonal antibodies (mAb) specific for human CD43 induced homotypic mast cell line (HMC-1) aggregation in a semi-quantitative assay, a phenomenon that has not been described before with mast cells. Monoclonal antibodies specific for seven other surface antigens and an irrelevant mAb of the same isotype had no effect. The level of aggregation was dependent on anti-CD43 mAb concentration, time and temperature. Anti-leucosialin-induced aggregation of HMC-1 cells was completely inhibited by mAb against CD11a (LFA-1) and CD18 (beta 2-chain). Monoclonal antibody to CD54 (ICAM-1) partially inhibited anti-CD43-induced homotypic aggregation, while anti-CD11b (CR3), anti-CD11c (p 150, 95) and a control mAb had no inhibitory effect. We conclude that mast cell line CD43 antigen expression is differentially regulated during cell activation, and speculate that anti-CD43-induced homotypic aggregation of HMC-1 cells is closely associated with modulation of beta 2-integrins.     

Evidence for cell surface association of CD2 and LFA-1 (CD11a/CD18) on T lymphocytes

Previous studies have reported an association of the cell surface adhesion molecule CD2 with the T cell receptor and with CD45 on mouse and human T lymphocytes. In this study the association of CD2 with cell surface molecules was investigated using cell surface biotinylation of T lymphocytes, coupled with immunoprecipitation using two CD2-specific monoclonal antibodies (mAb) (RM2–5 and 12–15) and analysis by SDS-PAGE. Although both CD2 mAb immunoprecipitated CD2 from lysates of murine lymphocytes, it was found that mAb 12–15, but not RM2–5, co-precipitated two other molecules of 95 and 180 kDa. Subsequent studies revealed that the 95- and 180-kDa molecules were associated with a subspecies of CD2 (? 5%) on thymocytes, the antigen-specific T cell line D10, and splenic T cells but not B cells. Two lines of evidence were obtained consistent with the 95- and 180-kDa molecules being the β and α chains of LFA-1. Firstly, an analysis of 12–15 mAb immunoprecipitates on 4–12% gels under reducing and nonreducing conditions shows that the 95- and 180-kDa molecules have a molecular weight and migration pattern identical to LFA-1. Secondly, depletion of LFA-1 from lysates with LFA-1 mAb abolished the ability of CD2 mAb 12–15 to co-precipitate the 95- and 180-kDa molecules, thereby identifying these as the β and α chains of mouse LFA-1, respectively. These results provide evidence for the first time for an association of LFA-1 and CD2 on mouse T lymphocytes, and suggest that the association occurs with an immunologically distinct subspecies of CD2 molecules.     

Differential function of LFA-1 family molecules (CD11 and CD18) in adhesion of human monocytes to melanoma and endothelial cells.

Human peripheral blood monocytes from normal, healthy donors express the leucocyte function-associated antigen (LFA)-1, CR3 and p150,95. These heterodimeric antigens are members of a glycoprotein family sharing a common beta subunit but endowed with distinct alpha chains. They have been shown to play an important role in cell-cell interactions. In the present study we have investigated the role of these molecules in the interaction of monocytes with endothelial cells and melanoma (tumour) cells. Heterotypic cell-cell interactions were studied in single cell conjugate assays and by adhesion of monocytes to monolayers of cells. The results demonstrate that monoclonal antibodies directed against LFA-1 alpha, CR3 alpha, p150,95 alpha and the common beta chain strongly reduce the number of conjugates (71, 50, 60 and 89% inhibition, respectively), formed between monocytes and melanoma or endothelial cells in a single cell assay. In contrast, adhesion of monocytes to monolayers of the same cells seems only to depend on p150,95, since only antibodies directed to the alpha chain of this molecule and to the common beta chain inhibited adhesion. Interestingly, the number of conjugates formed with melanoma cells in single cell assays was at least twice the number of conjugates formed between monocytes and endothelial cells, whereas no differences were observed in the adhesion of monocytes to monolayers of these cells. However, the basis for this phenomenon is not yet clear. These results indicate that not only LFA-1 but also CR3 and p150,95 can mediate adhesion to target cells in suspension, but that monocyte adhesion to monolayers is caused by a different mechanism in which the p150,95 molecule seems to play a prominent role.     

Mac-1 (CD11b/CD18) is the predominant beta 2 (CD18) integrin mediating human neutrophil migration through synovial and dermal fibroblast barriers.

Recently we reported that polymorphonuclear leucocyte (PMNL) migration in vitro through a barrier of human synovial fibroblasts (HSF) involves both beta 2 (CD18) and beta 1 (CD29) integrins on the PMNL. Here we investigated the role of the beta 2 integrin family members, lymphocyte function-associated (LFA)-1 (alpha L beta 2 or CD11a/CD18) and Mac-1 ( alpha M beta 2 or CD11b/CD18), in PMNL migration through HSF and human dermal fibroblast (HDF) monolayers. Treatment of PMNL with monoclonal antibody (mAb) to LFA-1 (anti-alpha L) did not inhibit PMNL migration through either monolayer in response to C5a. In contrast, mAb to Mac-1 (Cd11b) inhibited (by 30-40%) PMNL migration, and by virtually the same extent as mAb to the beta 1 integrin chain (CD18) (40% inhibition). Addition of mAb to LFA-1 to mAb to Mac-1 did not result in greater inhibition. This was in contrast to PMNL migration through human umbilical vein endothelium (HUVE) monolayers, where mAb to LFA-1 or to Mac-1 each partially inhibited PMNL transendothelial migration, and when these mAbs were combined, synergistic inhibition of migration was observed, reaching 90-95% inhibition. Intercellular adhesion molecule 1 (ICAM-1) was not required for Mac-1 mediated migration through HSF or HDF, because treatment of the fibroblasts with mAb R6.5 (F(ab)2) to ICAM-1, which blocks the Mac-1 binding site on ICAM-1, did not inhibit PMNL migration. An LFA-1-ICAM-1 mechanism of PMNL migration through HSF and HDF monolayers could be detected after treatment (4 hr) of the monolayers with TNF-alpha plus IFN-gamma, which upregulated ICAM-1 on the fibroblasts. The results demonstrate the beta 2 integrin dependent PMNL migration in connective tissue may involve primarily Mac-1, with little involvement of LFA-1 or ICAM-1, a situation in marked contrast to PMNL migration across endothelium. However, in inflammatory conditions in which TNF-alpha and/or IFN-gamma may be generated, a role for LFA-1-ICAM-1 may be induced.     

Functional and biochemical characterizations of avian T lymphocyte antigens identified by monoclonal antibodies

Seven monoclonal antibodies (mAb) were used to characterize antigens present on chicken T lymphocytes and on natural killer cells by flow cytometry, radioimmunoprecipitation and by effects on cell-mediated cytotoxicity and mitogen-induced proliferation. mAb CTLA8 and 5 stained 73% of thymus, 44% of spleen and 51% of peripheral blood lymphocytes (PBL), respectively, and immunoprecipitated 65- and 45-kDa proteins from detergent extracts of ¹²⁵I surface-labeled thymocytes. Pretreatment of splenic lymphocytes with mAb CTLA5 and 8 in the presence of rabbit complement (C) eliminated the concanavalin A (Con A)-induced T cell proliferative responses. mAb CTLA3, 4 and 9 stained 43% of thymus, 36% of spleen and 18% of PBL, and immunoprecipitated 33–35-kDa proteins. Pretreatment of spleen cells with mAb 4 or 9 plus C reduced, but did not eliminate, the Con A-induced proliferative response and significantly reduced both major histocompatibility complex (MHC)-restricted and non-MHC-restricted cellular cytotoxicity. mAb CTLA1 and 6 stained 58% of thymus, 13% of spleen and 19% of PBL. mAb CTLA 1 and 6 immunoprecipitated a 65-kDa protein. mAb CTLA l and 6 had no effect on the Con A-induced blastogenesis and CTLA 6 caused no decrease in virus-specific cytotoxic T lymphocyte and natural killer activity. These results indicate that (a) mAb CTLA 5 and 8 identify antigens on mature T lymphocytes that are similar in tissue distribution, molecular mass and function to the mammalian CD5 antigen; (b) mAb CTLA 3, 4 and 9 detect the avian homologue of CD8 antigen; and (c) mAb CTLA l and 6 identify the avian homologue of CD4 antigen.     

Cytokine-induced generation of multinucleated giant cells in vitro requires interferon-gamma and expression of LFA-1

Multinucleated giant cells (MGC), which are a common feature of various pathologic states, were generated in vitro by cytokine-stimulation of human peripheral blood monocytes. As expected, conditioned medium, i.e. the supernatant of concanavalin A-stimulated peripheral blood mononuclear cells, readily caused generation of MGC. Addition of a monoclonal antibody (mAb) against interferon-gamma (IFN-gamma) completely abrogated this effect. IFN-gamma alone, however, had a much smaller effect than the conditioned medium. All other cytokines tested [including interleukin (IL)2, IL4 and tumor necrosis factor-alpha, which are known to activate monocytes] did not induce MGC nor did they enhance the effect of IFN-gamma. Formation of MGC could almost entirely be inhibited by mAb to the alpha or beta chain of LFA-1 and to a lesser extent by relatively high concentrations of a mAb against ICAM-1, one of the ligands of LFA-1. In contrast to the anti-IFN-gamma mAb that had no significant effect on the formation of monocyte clusters, mAb against LFA-1 inhibited clustering very efficiently. Antibodies directed to a number of different antigens present on the surface of monocytes (alpha chains of CR3 and CR4, HLA class I and II molecules, CD14 and CD16 antigens) had little or no effect on the generation of MGC. IFN-gamma, but not the concanavalin A-induced supernatant clearly enhanced expression of LFA-1 and ICAM-1 on monocytes. The results indicate that cytokine-induced generation of MGC is not possible without IFN-gamma, but most probably additional factor(s) enhance this effect. The mechanism(s) by which IFN-gamma promotes monocyte fusion apparently includes, among others, up-regulation of LFA-1 whose expression seems to be necessary but not sufficient for fusion.     

Induction of cell-associated interleukin 1 through stimulation of the adhesion-promoting proteins LFA-1 (CD11a/CD18) and CR3 (CD11b/CD18) of human monocytes.

Serum-free culture of human monocytes in the presence of monoclonal antibodies to the LFA-1 alpha chain (CD11a), CR3 alpha chain (CD11b) or beta chain (CD18) bound to Sepharose induced the dose-dependent production of cell-associated interleukin (IL) 1 activity and of IL 1 alpha and IL 1 beta antigens, but no release of extracellular IL 1 activity or antigen in the culture medium. Triggering of IL 1 production was also observed with insolubilized anti-CD11/CD18 F(ab')2 antibodies. Two cross-linked antibodies recognizing distinct epitopes on the CD11b molecule induced cell-associated IL 1. Soluble antibodies did not induce IL 1 production. The kinetics of induction of IL 1 by stimulation of adhesion-promoting proteins differed from those of IL 1 induction by adhesion to plastic. The lack of induction of IL 1 release by stimulation of the CD11/CD18 molecules resembled the intracellular accumulation of IL 1 induced by lipid A. Induction of IL 1 by adhesive processes may be a mechanism by which T cells trigger IL 1 production by monocytes during antigen presentation.     

Effects of monoclonal antibodies to the alpha and beta chains of the human lymphocyte function-associated (H-LFA-1) antigen on T lymphocyte functions

The ability of two antibodies, one specific for the alpha chain, p180, and the other for the beta chain, p95, of the human lymphocyte function-associated (LFA-1) antigens, to inhibit T cell function was measured. Both antibodies inhibited T cell-mediated lysis of virus-infected target cells and of K562 cells. Only the anti-beta chain antibody inhibited natural killer cell lysis of K562. The antibodies inhibited cytotoxic T lymphocyte cell (CTL) lysis of HLA-mismatched target cells in the presence of concanavalin A at 6.25-12.5 micrograms/ml, but at higher doses of Con A no inhibition was seen. When the lytic process was divided into calcium-independent (adherence) and -dependent (lysis) steps the antibodies were found to block at the initial step of conjugate formation. The effects of these antibodies on T cell proliferative responses showed that responses to antigens, alloantigens, mitogens and anti-CD3 (UCHT1) antibody were greatly inhibited. All of these responses are adherent cell dependent and proliferation of adherent cell-depleted mononuclear cells to Sepharose-coupled UCHT1 was not inhibited by anti-LFA-1 antibodies. Proliferation to paired anti-CD2 (T11) antibodies was also only weakly inhibited. Release of interferon-gamma by CTL on contact with target cells was also inhibited by anti-LFA antibody. These results are evidence that the LFA antigen is necessary for a nonspecific interaction with antigen-presenting cells that is essential for activation of T cells through the CD3-T cell receptor complex.     

Characterization of the rat leukocyte integrin, CD11/CD18, by the use of LFA-1 subunit-specific monoclonal antibodies.

We have attempted to characterize the rat leukocyte integrin, CD11/CD18, by the use of newly generated monoclonal antibodies (mAb) WT.1 (anti-CD11a) and WT.3 (anti-CD18) in conjunction with an mAb, OX42, reactive with a rat integrin-like molecule, with respect to the biochemistry, cellular distribution and function. The conclusion that the mAb WT.1 and WT.3 specifically recognize the rat CD11a and CD18, respectively, was based on: (a) their ability to inhibit homotypic aggregation of splenic concanavalin A (Con A) blasts; (b) sodium dodecyl sulfate-polyacrylamide gel electrophoretic analysis of the antigens recognized; (c) their ability to inhibit binding of Con A blasts to the purified ligand, namely the ICAM-1 antigen and (d) their blocking abilities in mixed leukocyte reaction. In the rat, CD18 has an apparent molecular mass of 95-100 kDa and can associate with at least three distinct alpha subunits of 160-170 kDa (CD11a), 140-150 kDa and 120-130 kDa. The latter two are precipitated by OX42 from M phi but not from unstimulated lymphocytes. They presumably represent the rat CD11b and CD11c, respectively. Rat thymocytes, PBL, thoracic duct lymphocytes, monocytes and neutrophils expressed differential levels of CD11a and CD18. Peritoneal M phi showed virtually no CD11a expression, although CD18 was expressed at levels similar to those seen on blood monocytes, showing an interesting pattern of LFA-1 expression regulation in this cell lineage. Both WT.1 (anti-CD11a) and WT.3 (anti-CD18) apparently recognize a "low-affinity" as well as a "high-affinity" form of LFA-1 and do not discriminate between the two.     

The p150,95 molecule is a marker of human mononuclear phagocytes: comparison with expression of class II molecules

A new monoclonal antibody (mAb), named 3.9, is described that is specific for the p150,95 molecule, a member of the LFA-1, CR3, p150,95 family of human leukocyte differentiation antigens. The LFA-1 molecule participates in a variety of T cell interactions and the CR3 molecule is the receptor for the complement component iC3b, but little is known about the p150,95 molecule. Here we show that the expression of p150,95 is confined to myeloid cells. mAb 3.9 reacts variably with neutrophils, more strongly with monocytes and is most strongly expressed on tissue macrophages. Using this mAb and others, we have examined the heterogeneity of tissue macrophages. Cells such as Langerhans' cells, dendritic reticulum cells and osteoclasts failed to react with these mAb and thus, probably do not belong to the mononuclear phagocyte lineage. Using a new double-labeling technique, we investigated lymphoid tissue for dendritic cells bearing class II molecules which might function in interactions with T cells. In T cell areas macrophages expressing class II markers were seen but there was no evidence for other types of dendritic or interdigitating cells which expressed class II molecules but not macrophage epitopes. The conclusion from this survey was that the most prominent cell with dendritic morphology found in the T cell areas of lymphoid tissue was a macrophage.     

Induction of homotypic T cell adhesion by triggering of leukocyte function-associated antigen-1 alpha (CD11a): differential effects on resting and activated T cells.

The leukocyte integrin LFA-1 (CD11a/CD18) plays a key role in many adhesive interactions involving cells of the immune system. Recently, it has been shown that LFA-1 is not only involved in cell adhesion, but that stimulation of LFA-1 can also contribute to cell activation. We now demonstrate that triggering of LFA-1 on T lymphocytes by monoclonal antibodies (mAb) against the LFA-1 alpha chain, but not against the LFA-1 beta chain, promotes cell adhesion. Induction of homotypic adhesion was only observed in T cells that had been pre-activated with anti-CD3 and not in resting peripheral blood T lymphocytes. The induced homotypic adhesion is mediated by LFA-itself, because it was inhibited by anti-LFA-1 beta mAb. This notion is supported by the temperature and divalent cation dependence which is characteristic of LFA-1-mediated adhesion. mAb against ICAM-1 (CD54) did not block LFA-1 alpha-induced adhesion. The sensitivity of LFA-1 alpha-induced adhesion to H7, which prevents the activation of protein kinase C and protein kinase A, and to cytochalasin B, which inhibits microfilament formation, suggests that the activation of the LFA-1 pathway through the LFA-1 alpha chain involves cell activation and requires an intact cytoskeleton.     

CD4 binding to major histocompatibility complex class II antigens induces LFA-1-dependent and -independent homotypic adhesion of B lymphocytes.

T helper cells recognize processed antigen (Ag) in the context of major histocompatibility complex (MHC) class II antigens present on the surface of B cells and other Ag-presenting cells. This interaction is mediated through the T cell receptor complex with associate recognition of class II molecules by the CD4 molecule. In this study, the binding of a soluble recombinant CD4/Ig heavy chain fusion protein (CD4-gamma 3) or monoclonal antibody (mAb) to class II antigens on human B cells was shown to induce rapid and specific homotypic adhesion of B cells and most B lymphoblastoid cell lines. mAb reactive with CD4 inhibited CD4-gamma 3-induced adhesion and a mutant B lymphoblastoid cell line deficient in class II antigens failed to respond. Induction of homotypic adhesion was dependent on energy metabolism and a functional cytoskeleton, and class II+ pre-B cells did not exhibit adhesion in response to these stimuli, suggesting that cross-linking of class II molecules generated a transmembrane signal and did not simply aggregate cells. In addition, MHC class II-induced adhesion was Fc receptor independent, as 15 mAb of different Ig isotypes reactive with HLA-D or HLA-DQ gene products induced adhesion. Anti-class II mAb and CD4-gamma 3 were able to induce adhesion at concentrations as low as 10 ng/ml and 100 ng/ml, respectively. Suboptimal stimulation of B cell lines through HLA-D antigens induced homotypic adhesion that was dependent on the activation of LFA-1 (CD11a/CD18), and which could be blocked by specific mAb. However, at greater signal strengths, adhesion was not blocked by mAb against the known adhesion receptors, suggesting the induction of a novel adhesion pathway. Consistent with this, homotypic adhesion induced by engagement of MHC class II antigens was observed with LFA-1-deficient B cell lines, and was independent of CD49d or CD18 expression. Thus, the direct engagement of B cell class II antigens by CD4 is likely to generate transmembrane signals which trigger both LFA-1-dependent and LFA-1-independent adhesion pathways.