Analysis of two-dimensional dissociation constant of laterally mobile cell adhesion molecules

We formulate a general analysis to determine the two-dimensional dissociation constant (2D Kd), and use this method to study the interaction of CD2-expressing T cells with glass-supported planar bilayers containing fluorescently labeled CD58, a CD2 counter-receptor. Both CD2 and CD58 are laterally mobile in their respective membranes. Adhesion is indicated by accumulation of CD2 and CD58 in the cell-bilayer contact area; adhesion molecule density and contact area size attain equilibrium within 40 min. The standard (Scatchard) analysis of solution-phase binding is not applicable to the case of laterally mobile adhesion molecules due to the dynamic nature of the interaction. We derive a new binding equation, B/F=[(Ntxf)/(KdxScell)]-[(Bxp)/Kd], where B and F are bound and free CD58 density in the contact area, respectively; Nt is CD2 molecule number per cell; f is CD2 fractional mobility; Scell is cell surface area; and p is the ratio of contact area at equilibrium to Scell. We use this analysis to determine that the 2D Kd for CD2-CD58 is 5.4-7.6 molecules/microm2. 2D Kd analysis provides a general and quantitative measure of the mechanisms regulating cell-cell adhesion.     

Influence of receptor lateral mobility on adhesion strengthening between membranes containing LFA-3 and CD2

We have used an in vitro model system of glass-supported planar membranes to study the effects of lateral mobility of membrane-bound receptors on cell adhesion. Egg phosphatidylcholine (PC) bilayers were reconstituted with two anchorage isoforms of the adhesion molecule lymphocyte function-associated antigen 3 (LFA-3). The diffusion coefficient of glycosyl phosphatidylinositol (GPI)-anchored LFA-3 approached that of phospholipids in the bilayers, whereas the transmembrane (TM)-anchored isoform of LFA-3 was immobile. Both static and laminar flow assays were used to quantify the strength of adherence to the lipid bilayers of the T lymphoma cell line Jurkat that expresses the counter-receptor CD2. Cell adhesion was dependent on LFA-3 density and was more efficient on membranes containing the GPI isoform than the TM isoform. Kinetic measurements demonstrated an influence of contact time on the strength of adhesion to the GPI isoform at lower site densities (25-50 sites/microns2), showing that the mobility of LFA-3 is important in adhesion strengthening. At higher site densities (1,500 sites/microns2) and longer contact times (20 min), Jurkat cell binding to the TM and GPI isoforms of LFA-3 showed equivalent adhesion strengths, although adhesion strength of the GPI isoform developed twofold more rapidly than the TM isoform. Reduction of CD2 mobility on Jurkat cells at 5 degrees C greatly decreased the rate of adhesion strengthening with the TM isoform of LFA-3, resulting in a 30-fold difference between the two LFA-3 isoforms. Our results demonstrate that the ability of a membrane receptor and its membrane-bound counter-receptor to diffuse laterally enhances cell adhesion both by allowing accumulation of ligands in the cell contact area and by increasing the rate of receptor-ligand bond formation.     

Motility and ultrastructure of large granular lymphocytes on lipid bilayers reconstituted with adhesion receptors LFA-1, ICAM-1, and two isoforms of LFA-3

Large granular lymphocytes, mediators of NK activity, bind to other cells using both the LFA (lymphocyte function-associated)-1-ICAM and the CD2-LFA-3 adhesion pathways. Here we have studied the motility and ultrastructure of large granule lymphocyte (LGL) on lipid bilayers containing purified LFA-1, ICAM-1, and the transmembrane and glycophosphatidylinositol isoforms of LFA-3. LGLs moved at 8 microns/min on ICAM-1 but poorly (less than 1 microns/min) on its receptor pair LFA-1. TM-LFA-3 promoted locomotion at a rate close to ICAM-1, whereas the cells were less motile on GPI-LFA-3. The difference in the rates of locomotion on the two isoforms of LFA-3 is presumably attributable to their difference in anchoring and lateral mobility in the bilayer. In spite of the variation in motility the ultrastructure of the adhering cells was similar on all four ligands. LGLs contacted the membrane variably, i.e., cells adhering only in a few small areas or in larger areas were detected on each ligand. The relative percentage of the plasma membrane facing the lipid bilayer was greatest on ICAM-1 and least on the transmembrane isoform of LFA-3, demonstrating no correlation with motility. The ratio of adjacent plasma membrane to lipid bilayer was virtually constant for all four ligands. Activation of the LGLs with a combination of CD2 mAb T11(2) and T11(3) (T11(2/3) mAb) reduced the movement on ICAM-1 and virtually immobilized the cells on the other bilayers. In the presence of T11(2/3) mAb, the area of cell membrane attaching to bilayers containing ICAM-1 and GPI-LFA-3 was decreased and the percentage of plasma membrane facing other cells was increased. No preferential orientation of the Golgi apparatus or degranulation was detected in the absence or presence of T11(2/3) mAb, but a significantly lower percentage of LGLs on ICAM-1 contained a profile of the Golgi apparatus after exposure to T11(2/3) mAb. The results demonstrate that the motility of LGLs depends on the type of receptor in the opposing bilayer, the receptor mobility in the bilayer, and the activation of the cells. The ultrastructure of LGLs binding to any of the adhesion molecules does not have the characteristics of LGLs in cytolytic contact with target cells, suggesting that the mediation of an attack on a target requires more complex stimulus than any one of the single adhesion proteins tested here.     

Costimulation of T cell receptor/CD3-mediated activation of resting human CD4+ T cells by leukocyte function-associated antigen-1 ligand intercellular cell adhesion molecule-1 involves prolonged inositol phospholipid hydrolysis and sustained increase of intracellular Ca2+ levels.

Activation of resting human CD4+ T cells mediated by mAb ligation of the TCR/CD3 complex requires costimulatory signals to result in proliferation; these can be provided by intercellular cell adhesion molecule-1 (ICAM-1, CD54) a natural ligand of leukocyte function-associated Ag-1 (LFA-1, CD11a/CD18). We analyzed early signaling events involved in T cell activation to determine the contribution by the LFA-1/ICAM-1 interaction. We studied in detail the hydrolysis of phosphatidylinositol(4,5)bisphosphate and intracellular levels of free Ca2+ during stimulation with beads coated with the CD3 mAb OKT3 alone or in combination with purified ICAM-1 protein. Our investigations show no response to LFA-1/ICAM-1 alone, but that costimulation by LFA-1/CAM-1 interaction induces prolonged inositol phospholipid hydrolysis (up to 4 h), resulting in generation of both inositol(1,4,5)phosphate3 and inositol(1,3,4,5)phosphate4 and their derivatives. Based on studies with cycloheximide, this costimulatory effect of prolonged inositol phospholipid hydrolysis appears dependent in part on de novo protein synthesis. A sustained increase in intracellular levels of free Ca2+ level is also observed after LFA-1/ICAM-1 costimulation, which is at least partly dependent on extracellular sources of Ca2+. Kinetic studies indicate that costimulation requires a minimal period of 4 h of LFA-1/ICAM-1 interaction to provide maximal costimulation for OKT3-mediated T cell proliferation. Thus, the necessary costimulation required for OKT3-mediated proliferation in this model system may be provided by an extended LFA-1/ICAM-1 interaction that in combination with OKT3 mAb leads to signal-transducing events, resulting in prolonged phospholipase C activation and phosphatidylinositol(4,5)bisphosphate hydrolysis, and a sustained increase in intracellular levels of free Ca2+.     

Interaction of CD2 with its ligand, LFA-3, in human T cell proliferation

Recently, it has been demonstrated that lymphocyte function-associated Ag (LFA-3) is a natural ligand for CD2 and that this receptor-ligand interaction functions in cell-cell adhesion. In this report, we demonstrate that LFA-3 plays a role in T cell activation. L cells were transfected with human genomic DNA and sorted for expression of LFA-3. We demonstrate that LFA-3+ L cells, together with anti-CD3 mAb or with suboptimal doses of PHA, stimulate proliferation of human peripheral blood T cells. Furthermore, thymocyte proliferation was induced by LFA-3+ L cells and suboptimal doses of PHA. Proliferation was inhibited by mAb directed against either CD2 or LFA-3. Stimulation of thymocytes by the combination of PHA and LFA-3+ L cells resulted in the increased expression of the IL-2R, as well as of the surface Ag 4F2, transferrin receptor, and HLA-DR. These data support the conclusion that LFA-3 plays a role in CD2-dependent T cell activation. LFA-3 is widely distributed and is expressed on all APC and target cells. Thus, the ability of the CD2/LFA-3 interaction to costimulate with an anti-CD3 mAb suggests that the CD2/LFA-3 interaction may be involved not only in an Ag-independent alternate pathway of T cell activation but also in Ag-specific T cell activation.     

Quantification and modeling of tripartite CD2-, CD58FC chimera (alefacept)-, and CD16-mediated cell adhesion

Alefacept is a chimeric protein combining CD58 immunoglobulin-like domain 1 with human IgG1 Fc. Alefacept mediates adhesion by bridging CD2 on T cells to activating Fc receptors on effector cells, but the equilibrium binding parameters have not been determined. Alefacept mediated T cell killing by NK cells and adhesion between CD2- and CD16-expressing cells at an optimum concentration of 100 nM. We introduce novel measurements with supported planer bilayers, from which key two-dimensional and three-dimensional parameters can be determined by data fitting. Alefacept competitively inhibited cell bilayer adhesion mediated by the CD2-CD58 interaction. Alefacept mediated maximal adhesion of CD2(+) T cells to CD16B, an Fc receptor, in planar bilayers at 500 nM. A mechanistic model for alefacept-mediated cell-bilayer adhesion allowed fitting of the data and determination of two-dimensional binding parameters. These included the density of bonds in the adhesion area, which grew to maintain a consistent average bond density of 200 molecules/microm(2) and two-dimensional association constants of 3.1 and 630 microm(2) for bivalently and monovalently bound forms of alefacept, respectively. The maximum number of CD16 bound and the fit value of 4,350 CD2 per cell are much lower than the 40,000 CD2 per cell measured with anti-CD2 Fab. These results suggest that additional information is needed to correctly predict Alefacept-mediated bridge formation.     

Regulation of locomotion and cell-cell contact area by the LFA-1 and ICAM-1 adhesion receptors.

We demonstrate complementary differences in the behavior of B lymphoblastoid cells adhering to LFA-1 or its counter-receptor ICAM-1. The interaction of B lymphoblastoid cells with glass-supported planar bilayers bearing LFA-1 or ICAM-1 was observed by time-lapse video microscopy, and the distribution of adhesion receptors on cells interacting with the planar bilayers was studied by immunofluorescence microscopy. B lymphoblasts formed a large contact area and crawled rapidly (up to 25 microns/min) on planar bilayers bearing ICAM-1. In contrast, these cells attached to planar bilayers bearing LFA-1 through a fixed point about which the cells actively pivoted, using a single stalk-like projection. Phorbol ester-stimulated lymphoblasts, which adhere more strongly to ICAM-1-bearing substrates than unstimulated lymphoblasts, were still capable of locomotion on ICAM-1. Phorbol ester stimulation of B lymphoblasts on planar bilayers bearing LFA-1 promoted a rapid conversion from "stalk" attachment to symmetrical spreading of the cell on the substrate. Cellular LFA-1 remained uniformly distributed on the cell surface during interaction with bilayers bearing purified ICAM-1 as determined by immunofluorescence. In contrast, ICAM-1 was concentrated in the stalk-like structure through which the unstimulated B lymphoblasts adhered to LFA-1 in planar bilayers, but ICAM-1 immunofluorescence became more uniformly distributed over the cell surface within minutes of phorbol ester addition. Neither LFA-1 or ICAM-1 colocalized with the prominent staining of filamentous actin in the ruffling membrane regions. Interaction through cell surface LFA-1 and ICAM-1, 2, or 3 promotes different cellular morphologies and behaviors, the correlation of which with previously observed patterns of lymphocyte interaction with different cell types is discussed.     

Human memory T lymphocytes express increased levels of three cell adhesion molecules (LFA-3, CD2, and LFA-1) and three other molecules (UCHL1, CDw29, and Pgp-1) and have enhanced IFN-gamma production

Studies of cell-surface molecules involved in human T cell interaction reveal that differential expression of each of three adhesion molecules (LFA-3, CD2, and LFA-1) subdivides human peripheral blood T cells into major subpopulations. Systematic analysis of the relationship between expression of these and other markers of T cell subsets demonstrates a single major subset of human peripheral blood T lymphocytes distinguished by enhanced expression of LFA-3, CD2, LFA-1, and three other markers (CDw29 [4B4], UCHL1, and Pgp-1). Large differences in relative expression are observed for UCHL1 (29-fold) and LFA-3 (greater than 8-fold), and smaller differences (2- to 4-fold) are seen for CDw29, CD2, LFA-1, and Pgp-1. Bimodal distribution of LFA-3 is found on both CD4+ cells and on CD8+ cells as well as on B lymphocytes (CD19+). Neonatal T cells (CD3+) are comprised almost exclusively of the subset expressing low LFA-3, CD2, LFA-1, CDw29, and UCHL1. Activation of cord peripheral blood mononuclear leukocytes with PHA leads to uniform enhanced expression of each of these molecules on CD3+ cells. Functional analyses of these T cell subsets were performed after sorting of adult T cells based on differential LFA-3 expression. Only the LFA-3+ subset proliferated in response to the Ag tetanus toxoid, even though the LFA-3- subset proliferated more strongly to PHA. Furthermore, the LFA-3+ subset made greater than fivefold more IFN-gamma than the LFA-3- subset in response to PHA, despite the fact that both subsets made equivalent amounts of IL-2. This phenotypic and functional analysis of resting and activated newborn and adult T cells indicates that human memory T cells express enhanced levels of LFA-3, CD2, LFA-1, UCHL1, CDw29, and Pgp-1; we speculate that the increase in expression of T cell adhesion molecules LFA-3, CD2, and LFA-1 on memory cells is functionally important in their enhanced responsiveness.     

Purified lymphocyte function-associated antigen-3 (LFA-3) activates human thymocytes via the CD2 pathway

Defining the cellular and molecular mechanisms of interaction of developing thymocytes with nonlymphoid cells of the thymic microenvironment is critical for understanding normal thymus function. We have previously shown that the CD2/LFA-3 adhesion pathway is important in the interaction of thymocytes with a variety of LFA-3+ nonlymphoid thymic microenvironment cell types. Moreover, T cell activation via the CD2 (alternative, Ag independent) pathway is considered an important mechanism for intrathymic T cell proliferation. To study the relevance of CD2/LFA-3 interactions to human thymocyte activation, we have used purified LFA-3 Ag in several in vitro assays of thymocyte proliferation. Whereas LFA-3 Ag alone did not induce thymocyte proliferation, LFA-3 Ag in combination with the anti-CD2 antibody, CD2.1, and rIL-2 induced marked thymocyte proliferation. Additionally, the anti-CD28 antibody, Kolt2, could substitute for rIL-2, resulting in thymocyte activation induced by LFA-3 Ag in combination with antibodies CD2.1 and Kolt2. In both triggering systems, LFA-3 induced thymocyte activation was dependent upon the concentration of LFA-3 Ag. LFA-3 Ag-dependent thymocyte activation was directed primarily toward CD1-, mature thymocytes. Finally, intact SRBC that express the sheep homolog of LFA-3, T11TS, in combination with antibody CD2.1 and rIL-2 could also induce thymocyte activation. These data suggest that interaction of LFA-3 molecules with thymocyte CD2 molecules may provide a component of the stimulus for normal intrathymic thymocyte activation leading to thymocyte proliferation.     

Interaction of CD2 with its ligand lymphocyte function-associated antigen-3 induces adenosine 3',5'-cyclic monophosphate production in T lymphocytes.

CD2 (T11, the T cell E receptor), a nonpolymorphic 47- to 55-kDa glycoprotein, is a T cell-specific surface protein that plays an important role in T lymphocyte adhesion, signal transduction, and differentiation. A natural ligand of CD2 is lymphocyte function associated Ag-3 (LFA-3 (CD58)), a widely expressed glycoprotein of 50 to 70 kDa. The physiologic interaction of CD2 with LFA-3 functions to increase intercellular adhesion and plays a role in T cell activation. This interaction, however, in the absence of other stimuli, has not previously been shown to induce intracellular signals such as Ca2+ mobilization or IL-2 production. To investigate whether cAMP may play a role in ligand-triggered CD2-mediated signal transduction, we have studied the ability of purified LFA-3 and anti-CD2 mAb to induce changes in intracellular cAMP content in murine Ag-specific T cell hybridomas that stably express wild-type and mutated human CD2 molecules. By using a RIA sensitive to the femtomolar range and specific for cAMP, we demonstrate that purified LFA-3, like anti-CD2 mAb, is capable of inducing marked, transient increases in the intracellular concentration of cAMP. Presentation of purified LFA-3, like anti-CD2 mAb, is capable of inducing marked, transient increases in the intracellular concentration of cAMP. Presentation of purified LFA-3 alone to CD2-expressing hybridoma cells, however, did not stimulate phosphatidylinositol turnover nor IL-2 production. The cytoplasmic domain of CD2 is necessary for these ligand-induced cAMP changes, demonstrating that LFA-3 binding to CD2 transduces a signal to the cell. Experiments using the phosphodiesterase inhibitor 3-isobutyl-1-methyl-xanthine showed that CD2-mediated regulation of cAMP levels occurs primarily by the stimulation of cAMP production rather than by the inhibition of cAMP degradation. These results demonstrate that the interaction of LFA-3 with CD2, in the absence of other stimuli, is capable of initiating intracellular biochemical changes and suggest that CD2/LFA-3 interactions may regulate T cell function at least in part through the generation of intracellular cAMP.     

Induction of tyrosine phosphorylation during ICAM-3 and LFA-1-mediated intercellular adhesion, and its regulation by the CD45 tyrosine phosphatase

Intercellular adhesion molecule (ICAM)-3, a recently described counter- receptor for the lymphocyte function-associated antigen (LFA)-1 integrin, appears to play an important role in the initial phase of immune response. We have previously described the involvement of ICAM-3 in the regulation of LFA-1/ICAM-1-dependent cell-cell interaction of T lymphoblasts. In this study, we further investigated the functional role of ICAM-3 in other leukocyte cell-cell interactions as well as the molecular mechanisms regulating these processes. We have found that ICAM-3 is also able to mediate LFA-1/ICAM-1-independent cell aggregation of the leukemic JM T cell line and the LFA-1/CD18-deficient HAFSA B cell line. The ICAM-3-induced cell aggregation of JM and HAFSA cells was not affected by the addition of blocking mAb specific for a number of cell adhesion molecules such as CD1 1a/CD18, ICAM-1 (CD54), CD2, LFA-3 (CD58), very late antigen alpha 4 (CD49d), and very late antigen beta 1 (CD29). Interestingly, some mAb against the leukocyte tyrosine phosphatase CD45 were able to inhibit this interaction. Moreover, they also prevented the aggregation induced on JM T cells by the proaggregatory anti-LFA-1 alpha NKI-L16 mAb. In addition, inhibitors of tyrosine kinase activity also abolished ICAM-3 and LFA-1- mediated cell aggregation. The induction of tyrosine phosphorylation through ICAM-3 and LFA-1 antigens was studied by immunofluorescence, and it was found that tyrosine-phosphorylated proteins were preferentially located at intercellular boundaries upon the induction of cell aggregation by either anti-ICAM-3 or anti-LFA-1 alpha mAb. Western blot analysis revealed that the engagement of ICAM-3 or LFA-1 with activating mAb enhanced tyrosine phosphorylation of polypeptides of 125, 70, and 38 kD on JM cells. This phenomenon was inhibited by preincubation of JM cells with those anti-CD45 mAb that prevented cell aggregation. Altogether these results indicate that CD45 tyrosine phosphatase plays a relevant role in the regulation of both intracellular signaling and cell adhesion induced through ICAM-3 and beta 2 integrins.     

Comparative analysis of CD4-mediated down-regulation of T cell adhesion to B cells by flow cytometry and fluorescence microscopy

We have previously shown by means of fluorescence microscopy that antigen-independent adhesion of resting CD4 T cells to EBV-transformed B cells can be down-regulated by ligand interaction with CD4. In this study we used flow cytometry analysis of conjugate formation to confirm these findings. No conjugates between resting CD4 + T cells and B cells were initially detected in the latter method, because flow velocity in the flow chamber induces hydrodynamic elongation forces which disrupt low-affinity conjugates. After forcing cell conjugation by low-speed centrifugation of T and B cells, conjugates became detectable although in smaller numbers than in fluorescence microscopy. "Forced" cell conjugates had similar characteristics to their unforced counterparts, i.e., 37 degrees C temperature dependency, mediation by LFA-1/ICAM-1 and CD2/LFA-3 pathways, and transiency. The latter characteristic was at least partly mediated by CD4/HLA class II interaction, since adhesion of CD4 + T cells to HLA class II-B cells was more stable. In addition, adhesion was inhibited by anti-CD4 antibodies but not by an HLA DR-derived peptide known to inhibit unforced CD4 + T cell adhesion to B cells. This blocking effect was partially reproduced by reducing the centrifugation time prior to the adhesion assay. These results show that a) CD4-mediated down-regulation of T cell adhesion can be observed by means of two different techniques, and b) analysis of cell-cell adhesion after increasing centrifugation times (and possibly speeds) is a simple way of measuring adhesion forces semiquantitatively.     

Intracellular mediators regulate CD2 lateral diffusion and cytoplasmic Ca2+ mobilization upon CD2-mediated T cell activation.

CD2 is a T cell surface glycoprotein that participates in T cell adhesion and activation. These processes are dynamically interrelated, in that T cell activation regulates the strength of CD2-mediated T cell adhesion. The lateral redistribution of CD2 and its ligand CD58 (LFA-3) in T cell and target membranes, respectively, has also been shown to affect cellular adhesion strength. We have used the fluorescence photobleaching recovery technique to measure the lateral mobility of CD2 in plasma membranes of resting and activated Jurkat T leukemia cells. CD2-mediated T cell activation caused lateral immobilization of 90% of cell surface CD2 molecules. Depleting cells of cytoplasmic Ca2+, loading cells with dibutyric cAMP, and disrupting cellular microfilaments each partially reversed the effect of CD2-mediated activation on the lateral mobility of CD2. These intracellular mediators apparently influence the same signal transduction pathways, because the effects of the mediators on CD2 lateral mobility were not additive. In separate experiments, activation-associated cytoplasmic Ca2+ mobilization was found to require microfilament integrity and to be negatively regulated by cAMP. By directly or indirectly controlling CD2 lateral diffusion and cell surface distribution, cytoplasmic Ca2+ mobilization may have an important regulatory role in CD2 mediated T cell adhesion.     

ICAM-3 interacts with LFA-1 and regulates the LFA-1/ICAM-1 cell adhesion pathway

The interaction of lymphocyte function-associated antigen-1 (LFA-1) with its ligands mediates multiple cell adhesion processes of capital importance during immune responses. We have obtained three anti-ICAM-3 mAbs which recognize two different epitopes (A and B) on the intercellular adhesion molecule-3 (ICAM-3) as demonstrated by sequential immunoprecipitation and cross-competitive mAb-binding experiments. Immunoaffinity purified ICAM-3-coated surfaces were able to support T lymphoblast attachment upon cell stimulation with both phorbol esters and cross-linked CD3, as well as by mAb engagement of the LFA-1 molecule with the activating anti-LFA-1 NKI-L16 mAb. T cell adhesion to purified ICAM-3 was completely inhibited by cell pretreatment with mAbs to the LFA-1 alpha (CD11a) or the LFA-beta (CD18) integrin chains. Anti-ICAM-3 mAbs specific for epitope A, but not those specific for epitope B, were able to trigger T lymphoblast homotypic aggregation. ICAM-3-mediated cell aggregation was dependent on the LFA-1/ICAM-1 pathway as demonstrated by blocking experiments with mAbs specific for the LFA-1 and ICAM-1 molecules. Furthermore, immunofluorescence studies on ICAM-3-induced cell aggregates revealed that both LFA-1 and ICAM-1 were mainly located at intercellular boundaries. ICAM-3 was located at cellular uropods, which in small aggregates appeared to be implicated in cell-cell contacts, whereas in large aggregates it appeared to be excluded from cell-cell contact areas. Experiments of T cell adhesion to a chimeric ICAM-1-Fc molecule revealed that the proaggregatory anti-ICAM-3 HP2/19 mAb was able to increase T lymphoblast attachment to ICAM-1, suggesting that T cell aggregation induced by this mAb could be mediated by increasing the avidity of LFA-1 for ICAM-1. Moreover, the HP2/19 mAb was costimulatory with anti-CD3 mAb for T lymphocyte proliferation, indicating that enhancement of T cell activation could be involved in ICAM-3-mediated adhesive phenomena. Altogether, our results indicate that ICAM-3 has a regulatory role on the LFA-1/ICAM-1 pathway of intercellular adhesion.     

Stimulation of IFN-gamma, TNF-alpha, and TNF-beta secretion in IL-2-activated T cells: costimulatory roles for LFA-1, LFA-2, CD44, and CD45 molecules.

Lymphokine-activated killer (LAK) cells are peripheral blood lymphocytes (PBLs) that possess the ability to kill target cells in a non-major histocompatibility complex (MHC)-restricted manner. Both NK and T cells can be stimulated with interleukin-2 (IL-2) to become LAK cells. We previously reported that the interaction of LAK cells with tumor cells also induces the secretion of interferon-gamma (IFN-gamma). The NK subset of LAK (LAK-NK) cells is stimulated by tumor cells to secrete IFN-gamma in a non-MHC-restricted manner while the T cell subset of LAK (LAK-T) cells is stimulated to secrete IFN-gamma upon cross-linking of the T cell receptor (TCR)-CD3 complex. We here report that LAK-T cells stimulated with anti-CD3 mAbs and tumor cells secrete two additional cytokines, tumor necrosis factor-alpha (TNF-alpha) and TNF-beta/lymphotoxin (TNF-beta). In addition, we demonstrate that at least four other structurally unrelated molecules, in addition to the TCR-CD3 complex, on LAK-T cells participate in the stimulation of IFN-gamma, TNF-alpha, and TNF-beta production. These molecules are the lymphocyte function associated antigen-1 (LFA-1), lymphocyte function associated antigen-2 (LFA-2), CD44, and CD45. LFA-1 is an integrin, LFA-2 is a member of the immunoglobulin supergene family, CD44 is homologous to the cartilage link proteins, and CD45 is a tyrosine phosphatase. Ligands to three of these molecules have been identified; ICAM-1, LFA-3, and hyaluronic acid binding to LFA-1, LFA-2, and CD44, respectively. LFA-1, LFA-2, and CD44 are reported to function both as adhesion molecules and as costimulators in resting T cells. Our data suggest that these three molecules enhance IFN-gamma, TNF-alpha, and TNF-beta production by augmenting LAK-T cell to tumor cell adhesion and also by functioning as costimulators.     

Low affinity binding of an LFA-3/IgG1 fusion protein to CD2+ T cells is independent of cell activation

Quantitative analysis of binding of the bivalent recombinant soluble fusion protein, LFA-3/IgG1, shows that the fusion protein binds to human CD2+ PBLs primarily through low affinity (KD approximately 140 microM) but also through high avidity (90 nM) interactions. The concentration dependence for LFA-3/IgG1 PBL binding took the form of two overlapping bell-shaped curves separated by a clear and reproducible minimum. This was accounted for in part by minor heterogeneity in the LFA-3/IgG1 preparations, and potentially by the ability of the ligand to bind to both CD2 and Fc receptors (FcR), best evidenced by the distinct binding properties of the fusion protein to NK and T cells. The low affinity LFA-3/ IgG1 binding to T cells is consistent with binding to CD2 only, and is in agreement with the low affinity reported for interactions between soluble forms of LFA-3 and CD2 by surface plasmon resonance technology. Moreover, as the low affinity determinations are similar for CD2 on resting and activated T cells, although the CD2 molecule has been reported to be altered to reveal new epitopes upon T cell activation, the binding data argue against multiple cell activation-dependent affinity states of CD2 for LFA-3 binding. This is distinct from that observed with other adhesion partners, and suggests that the different adhesion pathways utilize distinct mechanisms to mediate cell adhesion.     

CD18 is required for optimal development and function of CD4+CD25+ T regulatory cells

CD4+CD25+ T regulatory (Treg) cells inhibit immunopathology and autoimmune disease in vivo. CD4+CD25+ Treg cells' capacity to inhibit conventional T cells in vitro is dependent upon cell-cell contact; however, the cell surface molecules mediating this cell:cell contact have not yet been identified. LFA-1 (CD11a/CD18) is an adhesion molecule that plays an established role in T cell-mediated cell contact and in T cell activation. Although expressed at high levels on murine CD4+CD25+ Treg cells, the role of LFA-1 in these cells has not been defined previously. We hypothesized that LFA-1 may play a role in murine CD4+CD25+ Treg function. To evaluate this, we analyzed LFA-1-deficient (CD18-/-) CD4+CD25+ T cells. We show that CD18-/- mice demonstrate a propensity to autoimmunity. Absence of CD18 led to diminished CD4+CD25+ T cell numbers and affected both thymic and peripheral development of these cells. LFA-1-deficient CD4+CD25+ T cells were deficient in mediating suppression in vitro and in mediating protection from colitis induced by the transfer of CD4+CD25- T cells into lymphopenic hosts. Therefore, we define a crucial role for CD18 in optimal CD4+CD25+ Treg development and function.     

Low affinity binding of an LFA-3/IgG1 fusion protein to CD2+ T cells is independent of cell activation

Quantitative analysis of binding of the bivalent recombinant soluble fusion protein, LFA-3/IgG1, shows that the fusion protein binds to human CD2⁺ PBLs primarily through low affinity (K_D ～ 140 μM) but also through high avidity (90 nM) interactions. The concentration dependence for LFA-3/IgGl PBL binding took the form of two overlapping bell-shaped curves separated by a clear and reproducible minimum. This was accounted for in part by minor heterogeneity in the LFA-3/IgG 1 preparations, and potentially by the ability of the ligand to bind to both CD2 and Fc receptors (FcR), best evidenced by the distinct binding properties of the fusion protein to NK and T cells. The low affinity LFA-3/ IgG 1 binding to T cells is consistent with binding to CD2 only, and is in agreement with the low affinity reported for interactions between soluble forms of LFA-3 and CD2 by surface plasmon resonance technology. Moreover, as the low affinity determinations are similar for CD2 on resting and activated T cells, although the CD2 molecule has been reported to be altered to reveal new epitopes upon T cell activation, the binding data argue against multiple cell activation-dependent affinity states of CD2 for LFA-3 binding. This is distinct from that observed with other adhesion partners, and suggests that the different adhesion pathways utilize distinct mechanisms to mediate cell adhesion.     

Role of LFA-1 and VLA-4 in the adhesion of cloned normal and LFA-1 (CD11/CD18)-deficient T cells to cultured endothelial cells. Indication for a new adhesion pathway.

Patients with the leukocyte adhesion deficiency (LAD) syndrome have a genetic defect in the common beta 2-chain (CD18) of the leukocyte integrins. This defect can result in the absence of cell surface expression of all three members of the leukocyte integrins. We investigated the capacity of T cell clones obtained from the blood of an LAD patient and of normal T cell clones to adhere to human umbilical vein endothelial cells (EC). Adhesion of the number of LAD T cells to unstimulated EC was approximately half of that of leukocyte function-associated antigen (LFA)-1+ T cells. Stimulation of EC with human rTNF-alpha resulted in an average 2- and 2.5-fold increase in adhesion of LFA-1+ and LFA-1- cells, respectively. This effect was maximal after 24 h and lasted for 48 to 72 h. The involvement of surface structures known to participate in cell adhesion (integrins, CD44) was tested by blocking studies with mAb directed against these structures. Adhesion of LFA-1+ T cells to unstimulated EC was inhibited (average inhibition of 58%) with mAb to CD11a or CD18. Considerably less inhibition of adhesion occurred with mAb to CD11a or CD18 (average inhibition, 20%) when LFA-1+ T cells were incubated with rTNF-alpha-stimulated EC. The adhesion of LFA-1- T cells to EC stimulated with rTNF-alpha, but not to unstimulated EC, was inhibited (average inhibition, 56%) by incubation with a mAb directed to very late antigen (VLA)-4 (CDw49d). In contrast to LAD T cell clones and the LFA-1+ T cell line Jurkat, mAb to VLA-4 did not inhibit adhesion of normal LFA-1+ T cell clones to EC, whether or not the EC had been stimulated with rTNF-alpha. We conclude that the adhesion molecule pair LFA-1/intercellular adhesion molecule (ICAM)-1 plays a major role in the adhesion of LFA-1+ T cell clones derived from normal individuals to unstimulated EC. Adhesion of LFA-1-T cells to TNF-alpha-stimulated EC is mediated by VLA-4/vascular cell adhesion molecule (VCAM)-1 interactions. Since we were unable to reduce significantly the adhesion of cultured normal LFA-1+ T cells to 24 h with TNF-alpha-stimulated endothelium with antibodies that block LFA-1/ICAM-1 or VLA-4/VCAM-1 interactions, and lectin adhesion molecule-1 and endothelial leukocyte adhesion molecule-1 appeared not to be implicated, other as yet undefined cell surface structures are likely to participate in T cell/EC interactions.     

Nanoscale increases in CD2-CD48-mediated intermembrane spacing decrease adhesion and reorganize the immunological synapse

The relationship between intermembrane spacing, adhesion efficiency, and lateral organization of adhesion receptors has not been established for any adhesion system. We have utilized the CD2 ligand CD48 with two (wild type CD48 (CD48-WT)), four (CD48-CD2), or five (CD48-CD22) Ig-like domains. CD48-WT was 10-fold more efficient in mediating adhesion than CD48-CD2 or CD48-CD22. Electron tomography of contact areas with planar bilayers demonstrated average intermembrane spacing of 12.8 nm with CD48-WT, 14.7 nm with CD48-CD2, and 15.6 nm with CD48-CD22. Both CD48-CD2 and CD48-CD22 chimeras segregated completely from CD48-WT in mixed contact areas. In contrast, CD48-CD2 and CD48-CD22 co-localized when mixed contacts were formed. Confocal imaging of immunological synapses formed between primary T lymphocytes and Chinese hamster ovary cells presenting major histocompatibility complex-peptide complexes, and different forms of CD48 demonstrated that CD48-CD2 and CD48-CD22 induce an eccentric CD2/T cell antigen receptor cluster. We propose that this reorganization of the immunological synapse sequesters the T cell antigen receptor in a location where it cannot interact with its ligand and dramatically reduces T cell sensitivity.