Activation of LFA-1 through a Ca2(+)-dependent epitope stimulates lymphocyte adhesion

The leukocyte function-associated molecule-1 (LFA-1) plays a key role in cell adhesion processes between cells of the immune system. We investigated the mechanism that may regulate LFA-1-ligand interactions, which result in cell-cell adhesion. To this end we employed an intriguing anti-LFA-1 alpha mAb (NKI-L16), capable of inducing rather than inhibiting cell adhesion. Aggregation induced by NKI-L16 or Fab fragments thereof is not the result of signals transmitted through LFA-1. The antibody was found to recognize a unique Ca2(+)-dependent activation epitope of LFA-1, which is essentially absent on resting lymphocytes, but becomes induced upon in vitro culture. Expression of this epitope correlates well with the capacity of cells to rapidly aggregate upon stimulation by PMA or through the TCR/CD3 complex, indicating that expression of the NKI-L16 epitope is essential for LFA-1 to mediate adhesion. However, expression of the NKI-L16 epitope in itself is not sufficient for cell binding since cloned T lymphocytes express the NKI-L16 epitope constitutively at high levels, but do not aggregate spontaneously. Based on these observations we propose the existence of three distinct forms of LFA-1: (a) an inactive form, which does not, or only partially exposes the NKI-L16 epitope, found on resting cells; (b) an intermediate, NKI-L16+ form, expressed by mature or previously activated cells; and (c) an active (NKI-L16+) form of LFA-1, capable of high affinity ligand binding, obtained after specific triggering of a lymphocyte through the TCR/CD3 complex, by PMA, or by binding of NKI-L16 antibodies.     

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.     

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.     

Interferon-gamma induction of LFA-1-mediated homotypic adhesion of human monocytes

Cell-cell adhesion plays an important role in monocyte function. To investigate the molecular basis for monocyte adhesion, we used recombinant interferon-gamma to induce the formation of homotypic monocyte adhesions. The induction of homotypic adhesions correlated with the increased expression of the LFA-1 membrane molecule. LFA-1 surface expression was increased twofold, whereas expression levels of other monocyte surface molecules including CR3 and p150,95 were unchanged. The direct involvement of LFA-1 in monocyte adhesion was addressed by anti-LFA-1 monoclonal antibody inhibition of homotypic adhesions. Two monoclonal antibodies to distinct epitopes on the LFA-1 alpha-chain completely inhibited homotypic adhesions. Antibodies to a variety of other monocyte surface molecules, often present at higher cell surface density than LFA-1, did not inhibit homotypic adhesion. A panel of monoclonal antibodies that recognized different functional epitopes on the LFA-1 alpha-chain inhibited homotypic monocyte in a hierarchy identical to that observed in previous studies of cell-mediated cytotoxicity. These findings suggest that LFA-1 serves an adhesive function for human mononuclear phagocytes. In addition to providing a molecular basis for homotypic monocyte adhesions, the results suggest a more general role for LFA-1 in monocyte adhesion reactions.     

T lymphocyte adhesion to endothelial cells: mechanisms demonstrated by anti-LFA-1 monoclonal antibodies

Adhesion of lymphocytes to vascular endothelium is the first event in the passage of lymphocytes into a chronic inflammatory reaction. To investigate molecular mechanisms of T-EC adhesion, monoclonal antibodies (Mab) against T cell surface antigens have been tested for inhibition of binding. Baseline and phorbol ester-stimulated adhesion were strongly inhibited by either Mab 60.3 (reactive with the beta-chain of the LFA-1, OKM1, and p150,95 molecules) or by Mab TS 1/22 (specific for the alpha-chain of LFA-1). Although the increased binding of phorbol ester-stimulated lymphocytes was inhibited by anti-LFA-1 antibody, there was no increased expression of LFA-1 on phorbol ester-stimulated T cells, as determined by FACS analysis. Maximal inhibition of unstimulated and phorbol ester-stimulated T-EC adhesion was seen at Mab concentrations of 1 microgram/ml. In contrast, LPS- and IL 1-enhanced T-EC adhesion were only weakly inhibited by these antibodies. Mab 60.3 and TS 1/22 did not stain either unstimulated EC or LPS- or IL 1-stimulated EC, as measured by FACS analysis; moreover, preincubation of EC alone with these antibodies did not lead to inhibition of T-EC binding. Adhesion was not affected by Mab against the sheep erythrocyte receptor (LFA-2), a nonpolymorphic HLA class 1 framework antigen, or against LFA-3, the alpha-chain of OKM1, or the alpha-chain of p150,95. These results suggest that the mechanism of binding of lymphocytes to unstimulated endothelium differs from that to stimulated endothelium. LFA-1 appears to be an important adhesion-related molecule for binding to unstimulated endothelium. However, the increased lymphocyte adhesion to IL 1- or LPS-stimulated EC observed in these experiments appears to be relatively independent of LFA-1. The increased adhesion to stimulated EC could be due either to an increase in the avidity or the density of the EC receptor molecules ordinarily involved in unstimulated T-EC binding or to the formation of alternative receptors on the stimulated EC that are not present on unstimulated cells.     

A novel LFA-1 activation epitope maps to the I domain

A panel of 21 alpha-subunit (CD11a) and 10 beta-subunit (CD18) anti-LFA- 1 mAbs was screened for ability to activate LFA-1. A single anti-CD11a mAb, MEM-83, was identified which was able to directly induce the binding of T cells to purified ICAM-1 immobilized on plastic. This ICAM- 1 binding could be achieved by monovalent Fab fragments of mAb MEM-83 at concentrations equivalent to whole antibody, was associated with appearance of the "activation reporter" epitope detected by mAb 24, and was completely inhibited by anti-ICAM-1 and LFA-1 blocking mAbs. The epitope recognized by mAb MEM-83 was distinct from that recognized by mAb NKI-L16, an anti-CD11a mAb previously reported to induce LFA-1 activation, in that it was constitutively present on freshly isolated peripheral blood mononuclear cells and was not divalent cation dependent for expression. The ICAM-1 binding activity induced by mAb MEM-83 was, however, dependent on the presence of Mg2+ divalent cations. Using an in vitro-translated CD11a cDNA deletion series, we have mapped the MEM-83 activation epitope to the "I" domain of the LFA- 1 alpha subunit. These studies have therefore identified a novel LFA-1 activation epitope mapping to the I domain of LFA-1, thereby implicating this domain in the regulation of LFA-1 binding to ICAM-1.     

Evidence for involvement of lymphocyte function-associated antigen 1 in T cell migration to epidermis.

Although it is well known that in various T cell-mediated skin diseases T cells migrate preferentially to epidermis, no direct evidence has been presented in which molecules on T cells are important in directing T cell traffic to epidermis. We have previously established CD4+ autoreactive cloned T cells with a special tropism for epidermis in vitro as well as in vivo. Antibody inhibition studies demonstrated that only anti-lymphocyte function associated Ag 1 (anti-LFA-1) mAb completely inhibited the in vitro migration of the T cells toward the epidermis, whereas mAb against other T cell surface molecules had little or no effect. Monovalent F(ab) fragment of the anti-LFA-1 mAb, although less efficient, also inhibited the T cell migration. The apparent dependency of the inhibition on the anti-alpha-chain mAb suggested a major role for the alpha-chain of LFA-1 in T cell migration to epidermis. The relevance of an LFA-1-dependent mechanism to the epidermotropic migration of T cells was further strengthened by the findings that the T cell migration to epidermis was inhibited by divalent cation depletion, cytochalasin B, and low temperature. These findings indicate that the LFA-1 molecule, which is thought to be primarily involved in cell-to-cell adhesions, also plays an important role in directing T cell migration to epidermis.     

Level of ICAM-1 Surface Expression on Virus Producer Cells Influences both the Amount of Virion-Bound Host ICAM-1 and Human Immunodeficiency Virus Type 1 Infectivity

Using virions harvested from 293T cells stably expressing either low or high levels of surface ICAM-1, we determined that the number of virus-embedded host ICAM-1 proteins is positively influenced by the expression level of ICAM-1 on virus producer cells. Moreover, the increase in virion-bound host cell membrane ICAM-1 led to a concomitant enhancement of virus infectivity when a T-cell-tropic strain of human immunodeficiency virus type 1 (HIV-1) was used. The phenomenon was also seen when primary human cells were infected with virions pseudotyped with the envelope protein from a macrophage-tropic HIV-1 isolate, thus ruling out any envelope-specific effect. We also observed that target cells treated with NKI-L16, an anti-LFA-1 antibody known to increase the affinity of LFA-1 for ICAM-1, were markedly more susceptible to infection with HIV-1 particles bearing on their surfaces large numbers of host-derived ICAM-1 proteins. Given that cellular activation of leukocytes is known to modify the conformational state of LFA-1 and induce ICAM-1 surface expression, it is tempting to speculate that activation of virus-infected cells will lead to the production of HIV-1 particles bearing more host ICAM-1 on their surfaces and that such progeny virions will preferentially infect and replicate more efficiently in activated cells which are prevalent in lymphoid organs.     

Human lymphocyte function associated antigen-1 (LFA-1): identification of multiple antigenic epitopes and their relationship to CTL-mediated cytotoxicity

Human lymphocyte function-associated antigen (LFA)-1, a heterodimeric lymphocyte surface glycoprotein of 177,000 and 95,000 relative molecular weight has been implicated to function in the cytotoxic T lymphocyte (CTL) effector mechanism. Seven mouse hybridoma lines producing monoclonal antibodies (MAb) reactive with this structure were studied. Three unique and 3 partially over-lapping epitopes on human LFA-1 were defined by competitive cross inhibition binding assays using biosynthetically labeled anti-LFA-1 MAb. In contrast, of five rat antimouse LFA-1 MAb, all five recognized a common or shared epitope. An HLA-B7 specific human CTL line expressed 1.1 X 10(5) LFA-1 sites per cell with a direct saturation binding assay. Human CTL expressed two to four times more LFA-1 than peripheral blood lymphocytes or B and T lymphoblastoid cell lines. Titration of each of the anti-LFA-1 MAb in a 51chromium release cytolytic assay revealed quantitative differences in the ability of the different anti-LFA-1 MAb to block cytolysis indicating distinct functional and antigenic epitopes exist on the human LFA-1 molecule. Anti-LFA-1 MAb reversibly inhibited the CTL reaction by slowing the initial rate of cytolysis. These results suggest anti-LFA-1 MAb inhibit CTL function by specific blockade of a functionally relevant molecule.     

Functional distinctions between the LFA-1, LFA-2, and LFA-3 membrane proteins on human CTL are revealed with trypsin-pretreated target cells

We asked whether we could distinguish the roles of the human lymphocyte membrane proteins LFA-1, LFA-2, and LFA-3 in the function of CTL-mediated killing. Little is known about the functions of these molecularly distinct proteins beyond the facts that i) binding of a monoclonal antibody (MAb) to any one of them is sufficient to inhibit killing, ii) that in each case inhibition involves prevention of CTL-target cell conjugate formation, and iii) that MAb to LFA-1 and LFA-2 inhibit best when bound to the CTL, whereas anti-LFA-3 inhibits only when bound to the target cell. This latter is despite the fact that (in our test system) LFA-1 and LFA-3 are expressed both on the CTL and on the target. When the target cells were pretreated with trypsin, the sensitivity of CTL-mediated killing was affected in a different way for each site. Inhibition of anti-LFA-1 was increased by approximately 20-fold. Inhibition by anti-LFA-2 was unaffected. Inhibition by anti-LFA-3 was abolished. Trypsin did not remove the specific antigens recognized by the various CTL, HLA-A,B,C or HLA-DR. Nor did it remove LFA-1 from the target cell. It did, however, selectively remove LFA-3 from the target cell. These results indicate, for the first time, that LFA-1 and LFA-2 have functionally distinct roles. They suggest that an unidentified trypsin-sensitive target cell molecule, operationally designated the "trypsin-sensitive counter blocker" (TSCB), plays an important role in the function of LFA-1, possibly by providing a target cell binding site for LFA-1 on the CTL. The hypothesis that this TSCB is identical to LFA-3 (and the related possibility that LFA-1 and LFA-3 are mutual ligands) is not favored by our data, but is not excluded. Finally, the data indicate that the mechanisms by which MAb inhibit killing differ at the LFA-1 and LFA-3 sites. They are consistent with LFA-1 providing adhesion strengthening by binding to another site (the TSCB?) and with LFA-3 delivering an inhibitory signal when provoked with MAb.     

Extracellular Ca2+ modulates leukocyte function-associated antigen-1 cell surface distribution on T lymphocytes and consequently affects cell adhesion

Transition of leukocyte function-associated antigen-1 (LFA-1), from an inactive into an activate state depends on the presence of extracellular Mg2+ and/or Ca2+ ions. Although Mg2+ is directly involved in ligand binding, the role of Ca2+ in LFA-1 mediated adhesion remained obscure. We now demonstrate that binding of Ca2+, but not Mg2+, directly correlates with clustering of LFA-1 molecules at the cell surface of T cells, thereby facilitating LFA-1-ligand interaction. Using a reporter antibody (NKI-L16) that recognizes a Ca(2+)-dependent epitope on LFA-1, we found that Ca2+ can be bound by LFA-1 with different strength. We noticed that weak binding of Ca2+ is associated with a dispersed LFA-1 surface distribution on T cells and with non- responsiveness of these cells to stimuli known to activate LFA-1. In contrast, stable binding of Ca2+ by LFA-1 correlates with a patch-like surface distribution and vivid ligand binding after activation of LFA- 1. Mg(2+)-dependent ligand binding does not affect binding of Ca2+ by LFA-1 as measured by NKI-L16 expression, suggesting that Mg2+ binds to a distinct site, and that both cations are important to mediate adhesion. Only Sr2+ ions can replace Ca2+ to express the L16 epitope, and to induce clustering of LFA-1 at the cell surface. We conclude that Ca2+ is involved in avidity regulation of LFA-1 by clustering of LFA-1 molecules at the cell surface, whereas Mg2+ is important in regulation of the affinity of LFA-1 for its ligands.     

A 19-kDa human erythrocyte molecule H19 is involved in rosettes, present on nucleated cells, and required for T cell activation. Comparison of the roles of H19 and LFA-3 molecules in T cell activation

We have previously described a molecule on the SRBC surface which, in addition to the sheep equivalent of LFA-3, is involved in the process of rosette formation. It is made of a single, 14- to 19-kDa, polypeptide chain, and we termed this molecule S14. We have now identified, on the human E a molecule with a similar Mr albeit somewhat higher (19 kDa). The mAb against H19 efficiently block autologous or homologous rosettes by binding to human E. In addition, purified H19 molecules block rosettes made with human E and SRBC in a dose-dependent manner. The H19 molecule, like LFA-3, is not limited to the E surface, but is also present on many nucleated cells, including T cells and monocytes. Moreover H19, like LFA-3, is required for T cell activation: when we stimulated whole PBMC anti-H19 blocked [H3]TdR incorporation triggered via CD3, but not via CD2, in contrast to anti-LFA-3 that inhibited activation via both pathways. When a mixture of highly purified T-PBL and autologous paraformaldehyde fixed accessory cells (AC) was cultivated, anti-H19 or anti-LFA-3 mAb bound to AC blocked T cell proliferation. When high amounts of rIL-1 (100 U/ml) were added to purified T-PBL, no AC were required to sustain their proliferation upon stimulation via CD2, contrary to stimulation via CD3. When lower amounts of rIL-1 (10 U/ml) were used, fixed AC were still necessary to sustain proliferation via CD2. In this latter situation, anti-H19 mAb bound to AC could no longer inhibit T cell proliferation, whereas the anti-LFA-3 mAb was still inhibitory. When T-PBL were stimulated via CD2 in the presence of 100 U/ml of rIL-1, anti-LFA-3 did not induce any inhibition. Thus the inhibitory effect of anti-H19 and anti-LFA-3 mAb can both be accounted for by an effect on the AC molecules only, and not on the T cell molecules. F(ab')2 fragments of anti-H19 mAb produced the same pattern of inhibition as the whole Ig molecule, excluding an effect via the FcR. Moreover, purified preparations of the H19 molecules also produced inhibition.(ABSTRACT TRUNCATED AT 400 WORDS)     

Thymocyte binding to human thymic epithelial cells is inhibited by monoclonal antibodies to CD-2 and LFA-3 antigens

With the use of cultured human thymic epithelial (TE) cells, we have previously shown that thymocytes bind to TE cells in suspension in a rosette-forming assay. To identify cell surface molecules involved in human TE-thymocyte rosette formation, we assayed a large panel of monoclonal antibodies for their ability to inhibit rosette formation. We found anti-CD-2 (LFA-2, T11), and anti-LFA-3 antibodies all inhibited binding of TE cells to thymocytes. By using indirect immunofluorescence assays, we determined that cultured TE cells were 90% LFA-3 positive and CD-2 negative, whereas thymocytes were 10% LFA-3 positive and 98% CD-2 positive. Pretreatment of TE cells with anti-LFA-3 but not anti-LFA-2 inhibited TE-thymocyte binding. In contrast, pretreatment of thymocytes with anti-CD-2 but not anti-LFA-3 antibodies inhibited TE-thymocyte binding. Thus TE cell-thymocyte binding is blocked by antibodies to the CD-2 (T11) antigen on thymocytes and by an antibody to the LFA-3 antigen on TE cells. Because the CD-2 antigen has been implicated in T cell activation, these data suggest that a natural ligand for T cell activation via the CD-2 molecule is present on human thymic epithelial cells.     

Serologic cross-reactivity of T11 target structure and lymphocyte function-associated antigen 3. Evidence for structural homology of the sheep and human ligands of CD2

T11 target structure (T11TS) and lymphocyte function-associated antigen (LFA) 3 are the cell-surface glycoproteins on sheep and human erythrocytes (E) binding to cluster differentiation 2 (the E-receptor) on T cells in E rosette formation. Here we show that this functional cross-reactivity is most likely due to a structural homology of these molecules. A rabbit antiserum to sheep T11TS is shown to cross-react with LFA-3 in several independent assays: (a) rabbit anti-T11TS antiserum blocks the formation of E rosettes by human T cells with both autologous and xenogeneic (sheep) E by binding to the respective E; (b) the antiserum blocks the binding of anti-LFA-3 monoclonal antibody to human E; and (c) it reacts with purified LFA-3 in Western blotting. Together, these findings demonstrate that T11TS on sheep E and LFA-3 on human E are serologically related, providing further support for the notion that T11TS and LFA-3 are the sheep and human forms of the same cell interaction molecule.     

Lymphocyte function-associated antigen 1 (LFA-1) contains sulfated N-linked oligosaccharides

The murine lymphocyte function-associated antigen 1 (LFA-1) is a glycoprotein heterodimer consisting of an Mr 180,000 alpha-chain and an Mr 95,000 beta-chain. Although LFA-1 has been studied extensively in the past few years due to its involvement in various antigen-specific T lymphocyte responses, virtually nothing is known about its glycosylation. In this report, we have analyzed the oligosaccharide moieties of the murine LFA-1 molecule. Utilizing a T lymphoma cell line, EL-4, it was found that [35S] sulfate, [3H]glucosamine, [3H]mannose, and [3H]fucose were incorporated into both the alpha- and beta-chains of LFA-1. Isolated alpha- and beta-chains from anti-LFA-1 immunoprecipitates of [3H]glucosamine-labeled NP-40 lysates were subjected to tryptic-chymotryptic digestion, and the resulting glycopeptides were fractionated by reverse-phase high performance liquid chromatography. Five major [3H]glucosamine-labeled glycopeptides were generated by this procedure from each of the two polypeptide chains. Treatment of the individual glycopeptides with almond emulsin peptide:N-glycosidase or Endo F demonstrated that the [3H]glucosamine label existed almost entirely in N-linked oligosaccharide structures (Mr 5000 to 10,000). By using similar techniques, the majority of the [35S]sulfate moieties were also found covalently bound to N-linked oligosaccharides. In addition, both [35S]sulfate-labeled alpha- and beta-chains were susceptible to Keratanase and endo-beta-galactosidase digestions, indicating the presence of sulfated N-acetyllactosamine sequences. The expression of [35S]sulfate-labeled LFA-1 on various cell types was also examined. LFA-1 was found to be sulfated only on thymocytes and splenic T cells, but not on macrophages, splenic B, or bone marrow cells.     

LFA-1 fine-tuning by cathepsin X

The adhesion molecule lymphocyte function-associated antigen (LFA)-1 plays a key role in immune surveillance and response. Its conformation is spatially and temporally regulated, enabling adhesion and deadhesion during T-cell migration. LFA-1 adhesion to its major ligand intercellular adhesion molecule 1 is controlled by adaptor proteins which bind the cytoplasmic tail of the β (2) subunit. Cathepsin X, a cysteine carboxypeptidase, promotes T-cell migration and morphological changes by cleaving the β (2) cytoplasmic tail of LFA-1. In this way, it modulates the affinity of LFA-1 for structural adaptors talin-1 and α-actinin-1 and enables the stepwise transition between intermediate and high-affinity conformations of LFA-1, an event that is necessary for effective T-cell function. Cathepsin X regulation that would allow precise modulation of LFA-1 affinity has a great potential for anti-LFA-1 therapy.     

Identification of 5 topographic domains of the mouse LFA-1 molecule: subunit assignment and functional involvement in lymphoid cell interactions

We have evaluated the serologic and T cell function inhibiting properties of 10 rat mAb reactive with the mouse LFA-1 molecule. Binding inhibition studies revealed that these mAb identified five topographic domains on LFA-1, including an immunodominant epitope region (A) defined by 6 mAb (H35-89, H68-96, H85-326, H129-37, H154-595, and H155-141) and four other spatially separate epitopes each defined by a single mAb (i.e., B, H154-266; C, H129-296; D, H154-163; and E, H155-78). Immunoprecipitation studies carried out with T cell hybridoma detergent lysate containing native or dissociated alpha and beta LFA-1 subunits permitted assignment of the epitopes A, C, and D to the alpha-chain, while expression of the epitopes B and E required homologous pairing of the alpha and beta LFA-1 subunits. These anti-LFA-1 mAb did not bind to the Mac-1 positive P388D1 cells. All the six mAb directed at epitope A inhibited, in the range of 50 to 95%, the proliferative responses of alloantigen- or soluble-antigen GAT-specific T cell clones and the cytolytic activity of I-Ak-specific CTL clones. MAb reactive with the epitopes C and D also blocked these T cell responses, although to a lesser extent. No inhibition was observed with mAb specific to epitope B, whereas the epitope E-specific mAb H155-78 potentiated control T cell responses by 20 to 40%. Suboptimal amounts of anti-L3T4 mAb H129-19 were found to synergistically enhance the T cell function inhibiting properties of mAb to LFA-1 epitopes A, C, and D. These studies reveal an unexpected diversification of LFA-1 between mouse and rat species and further the functional dissection of this molecule.     

Rap1 is a potent activation signal for leukocyte function-associated antigen 1 distinct from protein kinase C and phosphatidylinositol-3-OH kinase

To identify the intracellular signals which increase the adhesiveness of leukocyte function-associated antigen 1 (LFA-1), we established an assay system for activation-dependent adhesion through LFA-1/intercellular adhesion molecule 1 ICAM-1 using mouse lymphoid cells reconstituted with human LFA-1 and then introduced constitutively active forms of signaling molecules. We found that the phorbol myristate acetate (PMA)-responsive protein kinase C (PKC) isotypes (alpha, betaI, betaII, and delta) or phosphatidylinositol-3-OH kinase (PI 3-kinase) itself activated LFA-1 to bind ICAM-1. H-Ras and Rac activated LFA-1 in a PI 3-kinase-dependent manner, whereas Rho and R-Ras had little effect. Unexpectedly, Rap1 was demonstrated to function as the most potent activator of LFA-1. Distinct from H-Ras and Rac, Rap1 increased the adhesiveness independently of PI 3-kinase, indicating that Rap1 is a novel activation signal for the integrins. Rap1 induced changes in the conformation and affinity of LFA-1 and, interestingly, caused marked LFA-1/ICAM-1-mediated cell aggregation. Furthermore, a dominant negative form of Rap1 (Rap1N17) inhibited T-cell receptor-mediated LFA-1 activation in Jurkat T cells and LFA-1/ICAM-1-dependent cell aggregation upon differentiation of HL-60 cells into macrophages, suggesting that Rap1 is critically involved in physiological processes. These unique functions of Rap1 in controlling cellular adhesion through LFA-1 suggest a pivotal role as an immunological regulator.