Antibodies against the CD44 p80, lymphocyte homing receptor molecule augment human peripheral blood T cell activation

The CD44 inhibitor Lutheran [In(Lu)]-related p80 molecule has recently been shown to be identical to the Hermes-1 lymphocyte homing receptor and to the human Pgp-1 molecule. We have determined the effect of addition of CD44 antibodies to in vitro activation assays of PBMC. CD44 antibodies did not induce PBMC proliferation alone, but markedly enhanced PBMC proliferation induced by a mitogenic CD2 antibody pair or by CD3 antibody. CD44 antibody addition had no effect upon PBMC activation induced by PHA or tetanus toxoid. CD44 antibody enhancement of CD2 antibody-induced T cell activation was specific for mature T cells as thymocytes could not be activated in the presence of combinations of CD2 and CD44 antibodies. CD44 antibody enhancement of CD2-mediated T cell triggering occurred if CD44 antibody was placed either on monocytes or on T cells. In experiments with purified monocyte and T cell suspensions, CD44 antibodies A3D8 and A1G3 augmented CD2-mediated T cell activation by three mechanisms. First, CD44 antibody binding to monocytes induced monocyte IL-1 release, second, CD44 antibodies enhanced the adhesion of T cells and monocytes in CD2 antibody-stimulated cultures, and third, CD44 antibodies augmented T cell IL-2 production in response to CD2 antibodies. Thus, ligand binding to CD44 molecules on T cells and monocytes may regulate numerous events on both cell types that are important for T cell activation. Given that recent data suggest that the CD44 molecule may bind to specific ligands on endothelial cells (vascular addressin) and within the extracellular matrix (collagen, fibronectin), these data raise the possibility that binding of T cells to endothelial cells or extracellular matrix proteins may induce or up-regulate T cell activation in inflammatory sites.     

Activation of cord T lymphocytes. I. Evidence for a defective T cell mitogenesis induced through the CD2 molecule

A study was carried out on cord blood T cell activation via the CD2-mediated pathway. Despite similar percentages of circulating CD3+ and CD2+ cells in adult and cord blood, the proliferation of cord PBMC to the anti-CD3 mAb and cord T cells to anti-CD2 mAb were defective. The T cell CD3-surface structure was normally able to control CD2-mediated activation, as its modulation by a non-mitogenic anti-CD3 mAb blocked cord PBMC proliferation induced by anti-CD2 mAb. CD2-stimulated cord T cells did not proliferate and did not produce a significant amount of IL-2 in culture, although they expressed the IL-2R. This observation was confirmed by the optimal proliferation of CD2-induced cord T cells when rIL-2 was added. Despite the alternative T cell activation pathway is monocyte-independent in adults, the defective cord T cell activation via the CD2 molecule could also be bypassed by the addition of PMA, small amounts of either autologous or allogeneic adult and cord AC or simply rIL-1 alone. Our findings provide evidence for an intrinsic functional defect in cord CD2-mediated T cell activation, which is linked to an impaired increase of free cytoplasmic calcium, as confirmed by the effectiveness of calcium ionophore A23187 in restoring a good CD2-induced cord T cell proliferation and by measurement of cellular calcium uptake after activation via the CD2 molecule. The characteristics of cord T cells revealed by this study recall the thymocyte functional pattern and may represent functional expression of the previously described phenotypic immaturity of cord T cells.     

Cytofluorometric analyses of human T cell CD2/CD4 inter-molecular interactions

Incubation of human T lymphocytes with saturating concentrations of combinations of certain anti-CD2 and -CD4 mAb results in reciprocal down-regulation of the cell surface density expression of the respective CD molecules. Such reciprocal down-regulation occurs at 0 degrees C in the presence of sodium azide and appears selective for CD2 and CD4 molecules because mAb identifying various other CD T cell surface molecules (anti-Leu2a, -OK-CLL, -W6/32, -beta 2-microglobulin, -4B4) do not modulate CD2 or CD4 R density, and because anti-CD2 mAb (anti-OKT11 and -D66 clone-1) do not alter CD8 R density (anti-OKT8, -Leu2a) and vice versa. Down-regulation of CD2 by mAb specific to CD4 is epitope-specific but does not vary on the basis of the antibody isotype used. The anti-CD4 mAb, Leu3a, was the strongest CD2 down-regulator examined followed by OKT4F. mAb specific to other CD4 epitopes (B, C, D, and E) caused only slight down-regulation of CD2 expression whereas anti-OKT4 and -OKT4A mAb had no significant regulatory effect. Also, mAb specific to the 9.6 (anti-OKT11) and D66 (anti-D66 clone 1) epitopes of the CD2 molecule down-regulated CD4 density detectable with Leu3a, OKT4, and OKT4A anti-CD4 mAb. Down-regulation of CD2 by anti-CD4 mAb also occurred with the transformed T cell line, KE-37, which demonstrates that such effects can occur without mononuclear phagocytic accessory cells. From these data it can be concluded that important T cell immunoregulatory signals may be transmitted intramembranally between CD2 and CD4 glycoproteins.     

Mechanism of peripheral T cell activation by coengagement of CD44 and CD2.

A number of CD44 antibodies are known to augment peripheral T cell proliferation stimulated with suboptimal concentrations of activating pairs of CD2 mAb. These findings have implicated the CD44 adhesion receptor in the activation of peripheral T cells via CD2. We have investigated early events after CD44 and CD2 coengagement on peripheral T cells. CD44 and CD2 coengagement resulted in enhanced [Ca2+]i mobilization. However, the increase in [Ca2+]i mobilization did not occur until at least 3 min after CD2 and CD44 coengagement, suggesting that other events precede the elevation in [Ca2+]i. Using a T cell/fibroblast adhesion assay, we could demonstrate a dramatic increase in T cell adhesiveness after about 1 min after CD44 and CD2 coengagement. The increase in T cell adhesiveness was comparable to that induced by PMA. In the absence of antibodies or treatment with mAb directed to other T cell surface Ag, there was little if any adhesion between unstimulated peripheral T cells and fibroblasts. Enhancement of T cell adhesiveness through CD44 engagement was not mediated by a direct effect on lymphocyte-function associated Ag-3, the known ligand of CD2. However, cross-linking of CD44 resulted in epitopic modulation of CD2 as demonstrated by the increased expression of the T11(3) activation epitope. Furthermore, anti-CD44 could substitute for anti-T11(2) in the activation of peripheral T cells via CD2. These results suggest that CD44 ligation has profound effects on CD2-mediated events by inducing epitopic modulation of CD2.     

Dual role of the CD44 molecule in T cell adhesion and activation

Studies of T cell adhesion and activation reveal two new functions of the CD44 molecule, a molecule now recognized to be identical to three molecules of functional interest: Pgp-1, Hermes, and extracellular matrix receptor type III (ECMRIII). By screening for mAb which inhibit T cell adhesion to E, we have identified a functionally unique CD44-specific mAb, NIH44-1, which partially inhibits T cell rosetting by binding to CD44 on the E. NIH44-1, which immunoprecipitates a protein of 85 to 110 kDa with broad tissue distribution, was determined to be specific for CD44 based on comparison of its tissue distribution with multiple CD44-specific reference mAb and sequential immunoprecipitation with such mAb. Anticipating a role for many adhesion molecules in signal transduction, we studied the effect of CD44 mAb on T cell activation and observed that CD44 mAb dramatically augments T cell proliferation induced by CD3- and CD2-receptor-mediated activation. The augmentation of the response to immobilized CD3 mAb by exhaustively monocyte-depleted T cells indicates that augmentation can be mediated by binding to the T cell. Thus, our studies demonstrate specific new roles for CD44 in T cell adhesion and activation. Furthermore, we suggest that: 1) CD44 has a role in adhesion of cells of multiple lineages; and 2) CD44 may participate in adhesion not (only) by functioning as an adhesion receptor but rather by serving as an anchorage site for other adhesion molecules.     

Patterns of costimulation of T cell clones by cross-linking CD3, CD4/CD8, and class I MHC molecules

The ability of mAb to class I MHC molecules, CD3, or CD4/CD8 to stimulate human T cell clones alone or in combination was examined. Cross-linking each of these surface Ag with appropriate mAb and goat anti-mouse Ig (GaMIg) resulted in a unique pattern of increase in intracellular free calcium ([Ca2+]i) and different degrees of functional activation. Cross-linking class I MHC molecules provided the most effective stimulus of IL-2 production and proliferation. Cross-linking more than one surface Ag induced a compound calcium signal with characteristics of each individual response. Cross-linking CD3 + HLA-A,B,C caused a rapid and prolonged increase in [Ca2+]i and synergistically increased IL-2 production and proliferation of all clones. Cross-linking CD3 + CD4/CD8 also generated a compound calcium signal and increased IL-2 production and DNA synthesis. Purposeful inclusion of CD3 was not required for costimulation as cross-linking HLA-A,B,C + CD4/CD8 also increased [Ca2+]i, IL-2 production, and proliferation. Cross-linking three surface Ag, CD3 + HLA-A,B,C + CD4/CD8, resulted in the greatest initial and sustained [Ca2+]i, IL-2 production, and DNA synthesis. Although there was a tendency for the various stimuli to increase both [Ca2+]i and functional responsiveness, neither the magnitude nor duration of the increased [Ca2+]i correlated with the amount of IL-2 produced or the ultimate proliferative response. To determine whether costimulation required that the various surface molecules were cross-linked together, experiments were carried out using isotype specific secondary antibodies. Augmentation of [Ca2+]i and costimulation of functional responses were noted when class I MHC molecules were cross-linked and CD3 was bound, but not cross-linked. Similarly, costimulation through CD3 and CD4/CD8 was observed when CD4/CD8 was cross-linked and the CD3 complex was engaged by an anti-CD3 mAb which was not further cross-linked. In contrast, costimulation by class I MHC molecules and CD4/CD8 was only observed when these molecules were cross-linked together. These data demonstrate that cross-linking class I MHC determinants or CD4/CD8 provides a direct signal to T cell clones that can be enhanced when CD3 is independently engaged. The results also indicate that T cell clones can be stimulated without engaging CD3 by the combination of signals delivered via class I MHC molecules and CD4/CD8, but only when these determinants were cross-linked together. These studies have demonstrated that these cell surface molecules differ in their capacity to deliver activation signals to T cell clones and also exhibit unique patterns of positive cooperativity in signaling potential.     

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)     

Functional analysis of B and T lymphocyte attenuator engagement on CD4+ and CD8+ T cells

T cell activation can be profoundly altered by coinhibitory and costimulatory molecules. B and T lymphocyte attenuator (BTLA) is a recently identified inhibitory Ig superfamily cell surface protein found on lymphocytes and APC. In this study we analyze the effects of an agonistic anti-BTLA mAb, PK18, on TCR-mediated T cell activation. Unlike many other allele-specific anti-BTLA mAb we have generated, PK18 inhibits anti-CD3-mediated CD4+ T cell proliferation. This inhibition is not dependent on regulatory T cells, nor does the Ab induce apoptosis. Inhibition of T cell proliferation correlates with a profound reduction in IL-2 secretion, although this is not the sole cause of the block of cell proliferation. In contrast, PK18 has no effect on induction of the early activation marker CD69. PK18 also significantly inhibits, but does not ablate, IL-2 secretion in the presence of costimulation as well as reduces T cell proliferation under limiting conditions of activation in the presence of costimulation. Similarly, PK18 inhibits Ag-specific T cell responses in culture. Interestingly, PK18 is capable of delivering an inhibitory signal as late as 16 h after the initiation of T cell activation. CD8+ T cells are significantly less sensitive to the inhibitory effects of PK18. Overall, BTLA adds to the growing list of cell surface proteins that are potential targets to down-modulate T cell function.     

Induction of human T cell proliferation by a monoclonal antibody to CD5.

A mouse mAb, TS 43, which recognized the human CD5 molecule, was found to induce the proliferation of human peripheral blood T cells. TS 43 mAb precipitated from 125I-radiolabeled T cells a 67-kDa band, which comigrated with the 67-kDa band precipitated by the anti-CD5 mAb OKT1. Preclearing of cell lysates with OKT1 mAb abolished the capacity of TS 43 mAb to precipitate radiolabeled material from T cell lysates. Furthermore, a mouse T cell hybridoma transfected with human CD5 was stained by TS 43 mAb. T cell proliferation mediated by TS 43 mAb was monocyte dependent, and was accompanied by IL-2R expression and by IL-2 synthesis. T cell activation by TS 43 mAb involved a rise in intracellular calcium level (CA2+)i and was dependent on the expression of the TCR/CD3 complex because no rise in (Ca2+)i was observed in a TCR-beta-deficient Jurkat T cell mutant. This study indicates that CD5 should be added to the list of surface molecules that can signal T cells to proliferate.     

CD44 antibody against In(Lu)-related p80, lymphocyte-homing receptor molecule inhibits the binding of human erythrocytes to T cells

The cluster of differentiation 44 (CD44) Ag system, originally described in brain and mature T cells, has been subsequently shown to be identical with the human lymphocyte homing-receptor defined by the Hermes-1 antibody and to be involved in T cell/endothelial cell interactions in synovium, mucosa, and lymph node. CD44 is also present on human E. On E, CD44 has been shown to be regulated by the In(Lu) dominant inhibitor gene and to express the Ina and Inb blood group Ag. Because human E have been shown to interact with human T cells via CD2 on T cells and LFA-3 on human E, we have studied the ability of human E and T lymphocyte CD44 Ag to participate in CD2/LFA-3 interactions between human E and T cells. In this study, we demonstrate that a mAb (A3D8) against the CD44, In(Lu)-related p80, lymphocyte homing-receptor molecule inhibited the binding of human E to human T cells. Whereas whole CD44 antibody molecules inhibited human E binding to T cells, saturating amounts of CD44 Fab fragments did not inhibit human E to T cell binding. Our data demonstrated that anti-CD44 antibody A3D8 acted at the level of the E to inhibit CD2/LFA-3 interactions between human E and T cells.     

Intracellular events involved in CD5-induced human T cell activation and proliferation.

In this report we describe a novel pathway of human T cell activation and proliferation involving the CD5 surface Ag. The CD5-specific Cris1 mAb induces by itself monocyte-dependent proliferation of PBMC. Among a panel of CD5-specific mAb (Leu1, OKT1, LO-CD5a, F101-1C5, and F145GF3), only the F145GF3 mAb shared this property with Cris1. The analysis of the biochemical pathway involved in this activation showed the lack of detectable hydrolysis of inositol phosphates or early increments in the intracellular cytosolic calcium concentration, after triggering cells with the mitogenic CD5 mAb. However, stimulation with CD5 induces activation of protein kinase C, as measured by phosphorylation of a specific peptide substrate (peptide GS), which can be inhibited by a pseudosubstrate peptide inhibitor. Stimulation with CD5 mAb induces also tyrosine kinase activity, with a substrate pattern that differs from that induced after triggering lymphocytes through the TCR-CD3 complex. On the other hand the IL-2/IL-2R pathway seems involved in the CD5-mediated proliferation of PBMC because anti-IL-2R-specific mAb inhibits CD5-induced proliferation, and stimulation with mitogenic CD5 mAb induces production of IL-2 and expression of IL-2R alpha and beta chains. Therefore, the triggering of the CD5 Ag can induce IL-2- and monocyte-dependent human T cell proliferation by a biochemical pathway that differs, at least in the first stages, from the one that mediates TCR-CD3 complex-induced T cell activation.     

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.     

Interactions between CD3 and Thy1 T cell activation pathways: blockade of CD3-mediated T lymphocyte activation induced by immobilized anti-Thy1 antibodies.

Resting murine T cell activation induced by either CD3 complexes or Thy1 molecules was investigated in vitro, using surface-bound anti-CD3 mAb as the stimulus. One mitogenic anti-Thy 1 mAb (G7) lost mitogenicity when presented to T cells immobilized on a plastic surface, even in the presence of phorbol ester. Moreover, T cell activation induced by immobilized anti-CD3 was potently blocked by coimmobilized anti-Thy 1 mAb. Nonmitogenic anti-Thy 1 mAb also blocked CD3-induced activation when coimmobilized with anti-CD3. Control experiments showed that anti-Thy 1 specifically blocked T cell activation, even in the presence of measurable and functional concentrations of plastic-bound anti-CD3. Coimmobilized anti-Thy 1 potently blocked IL2 secretion stimulated by anti-CD3. Addition of exogenous rIL2 completely prevented anti-Thy 1-mediated blockade. On the other hand, while completely blocking T cell proliferation, immobilized anti-Thy 1 only partially blocked secretion of IL3-like activity by the T cells. One IgM anti-Thy 1 mAb (2A3) induced secretion of IL3-like activity by T cells when immobilized in the absence of bound anti-CD3. These results indicate that extensive aggregation of Thy 1 molecules delivers a potent negative signal which antagonizes CD3-mediated T cell activation and growth.     

Activation of human CD8-positive T cells via the CD8/HLA class I complex

Cross-linking of CD8 and HLA class I molecules with appropriate monoclonal antibodies (mAb) and goat anti-mouse Ig (GaMIg) antibody resulted in a marked proliferation of resting human CD8 cells in the presence of interleukin-2 (IL-2). These cells also expressed IL-2 receptor (IL-2R), transferrin receptor, HLA-DR and -DQ antigens. Activation of the cross-linked CD8 cells is apparently independent of accessory monocytes. Various anti-CD8 and anti-HLA class I mAb recognizing nonpolymorphic antigenic determinants were examined for the efficacy of activating CD8 cells. Among mAb specific for HLA class I molecules, PA2.6, MB40.5, BB7.7, A1.4, and W6/32 mAb markedly stimulated the proliferation of cross-linked CD8 cells, whereas BBM.1, Q1/28, and HC10 mAb were found inactive. Footprinting analysis of HLA class I molecules suggested that the activity of these anti-HLA class I mAb appeared to be related to the corresponding peptides they protect from enzymatic digestion. In contrast to the anti-HLA class I mAb, all anti-CD8 mAb examined (C8, OKT8A, and anti-Leu-2a) induced the proliferation of CD8-HLA class I cross-linked cells with similar efficacy. These results suggest that physical interaction between CD8 and at least one specific region of HLA class I molecules can trigger the activation of resting human CD8 cells.     

Physical associations between CD45 and CD4 or CD8 occur as late activation events in antigen receptor-stimulated human T cells.

Activation of human PBL T cells with solid phase anti-CD3 mAb or during the course of an MLR response gives rise to the association of CD4 or CD8 molecules with the protein tyrosine phosphatase, CD45, on the cell surface. This paired association of cell-surface molecules occurs late in the activation cycle and appears to be dependent upon Ti-CD3-mediated signaling because mitogen-driven activation does not induce formation of the complex. Maximal association occurred 72 to 96 h after exposure to anti-CD3 mAb on both CD4+ and CD8+ T cells. In contrast, association between CD8 and CD45 during an MLR response did not occur until day 6 of a MLR whereas CD4-CD45 association was detected by 72 h of culture. The kinetics of association between CD4 or CD8 and CD45 was measured by fluorescence resonance energy transfer and confirmed by immunoprecipitation of dithiobis succinimidylpropionate or disuccinimidyl suberate cross-linked 125I-labeled resting or activated T cells. The molecules that co-precipitated with either CD4 or CD8 and had an apparent kDa of 180 to 205 could be immunodepleted with anti-CD45 mAb. Furthermore, CD4 or CD8 immunoprecipitates from 96-h activated T cells contained significant levels of protein tyrosine phosphatase activity whereas corresponding immunoprecipitates from resting or recently activated T cells showed little protein tyrosine phosphatase activity. This association may allow CD45 to engage and dephosphorylate lck or another CD4- or CD8-associated substrate in order to reset the receptor complex to receive a new set of stimuli. Our observations suggest that synergistic signaling provided as a consequence of CD4 or CD8 association with the TCR after antigenic stimulation may develop on a different temporal scale than that observed after soluble anti-CD4+ anti-CD3 heteroconjugate antibody cross-linking.     

Human peripheral blood T helper cell-induced B cell activation results in B cell surface expression of the CD23 (BLAST-2) antigen

We have developed an in vitro system to assess the early stages of B cell activation induced by peripheral blood T helper cells. Peripheral blood mononuclear cells are cultured for 16 hr with anti-CD3 monoclonal antibody (mAb), T lymphocytes are then removed by sheep red blood cell rosette depletion, and expression of the B cell surface activation antigen CD23 (BLAST-2) is assessed by indirect immunofluorescence. Anti-CD3 mAb, but not a control anti-CD5 mAb, stimulates the expression of CD23 on 20-50% of peripheral blood B cells cultured with autologous T cells. T cell subset depletion studies show that the CD4+ T cell subset is responsible for anti-CD3-mediated induction of CD23 on autologous B cells. Anti-CD3-induced, T helper cell-dependent CD23 expression is not MHC-restricted, as allogeneic combinations of T and non-T cells, cultured in the presence of anti-CD3 antibody, also result in the expression of B cell CD23. Individuals whose monocyte Fc receptors bind murine IgG1 mAb poorly fail to trigger T cell proliferation in response to murine IgG1 anti-CD3 mAb and also fail to express B cell CD23 following culture of PBMC with IgG1 anti-CD3 mAb, while the usual expression of CD23 is seen after culture with IgG2a anti-CD3 mAb. The mechanism of anti-CD3-induced B cell activation was addressed in experiments using a two-chamber culture system. While little IL-4 activity was detected in anti-CD3-stimulated culture supernatants, optimal induction of CD23 was observed when T and B cells were cultured together in a single chamber. This suggests that under physiologic conditions, in which quantities of lymphokine may be limiting, close physical contact between the anti-CD3-activated Th cell and B cell may be required for CD23 expression. The anti-CD3-induced BLAST-2 assay will facilitate the analysis of Th cell-mediated B cell activation in any individual and should permit us to separately evaluate the roles of Th cells and B cells in the impaired immunoregulation characteristic of autoimmune disorders.     

Comparison of phosphorylation and internalization of the antigen receptor/CD3 complex, CD8, and class I MHC-encoded proteins on T cells. Role of intracytoplasmic domains analyzed with hybrid CD8/class I molecules

We analyzed the phosphorylation and the dynamics of TCR/CD3, CD8 and MHC class I molecules during the activation of a CD8+ cytotoxic T lymphocyte clone and of CD8- T helper hybridomas transfected with the gene coding for the native (J. Gabert, C. Langlet, R. Zamoyska, J.R. Parnes, A.M. Schmitt-Verhulst, and B. Malissen. 1987. Reconstitution of MHC class I specificity by transfer of the T cell receptor and Lyt-2 genes. Cell 50:545) or truncated CD8 alpha molecule. The CD3 components gamma and epsilon and the CD8 alpha subunit were phosphorylated after activation of the CTL clone with the protein kinase C activator PMA. Class I MHC molecules were phosphorylated irrespective of PMA activation. Constitutive phosphorylation of the MHC class I products was found to be intrinsic to the transmembrane/cytoplasmic portion of the molecules because it was transferred to the CD8 alpha hybrid molecules composed of extracellular CD8 and MHC class I transmembrane and intracytoplasmic domains (CD8-e/MHC-t-i). Measurements of the dynamics of these cell surface molecules by using radiolabeled mAb revealed distinct behaviors: TCR/CD3 complex ligand internalization was increased (around 50% after 40 to 60 min) after PMA activation, whereas the ligand of class I MHC molecules was internalized at constant rate irrespective of PMA activation. Ligand bound to native CD8 molecules was poorly internalized, irrespective of the activation of the T cells with PMA. The same ligand bound to the CD8-e/MHC-t-i hybrid molecule was internalized at the same rate as a class I MHC molecule ligand, indicating that the behavior of the hybrid molecule was characteristic of the transmembrane/cytoplasmic portion of MHC class I molecules.     

Association of human lymph node homing receptor (Leu 8) with the TCR/CD3 complex.

Cross-linking of the human homologue of the murine MEL-14 lymph node homing receptor (Selectin-1, LECAM-1, Leu 8) on both T and B cells results in modification of cell function. To investigate this phenomenon, we performed studies to determine if the Leu 8 molecule influences T cell activation via the TCR/CD3 complex. In initial studies, we treated T cells with immobilized anti-CD3 (OKT3 mAb) in the presence or absence of immobilized Leu 8 mAb. We found that although Leu 8 mAb alone had no effect on T cell proliferation, this antibody markedly augmented immobilized OKT3 mAb-induced proliferation. In further studies, we immunoprecipitated surface radioiodinated T cell lysates with OKT3 and Leu 8 mAb to determine if molecules in the TCR/CD3 complex associate with Leu 8 molecules. Although Leu 8 mAb immunoprecipitated only a single protein of approximately 80 kDa from T cell lysates treated with Nonidet P-40 under reducing condition, it coimmunoprecipitated additional proteins of 48, 42, 28, 24, and 22 kDa from T cell lysates treated with 3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulfonate. These additional proteins were identified as the alpha-, beta-, gamma-, delta-, and epsilon-chains of the TCR/CD3 complex by one-dimensional and two-dimensional diagonal SDS-PAGE. Densitometric scanning showed that, on average, 18% of the TCR/CD3 complex associates with Leu 8. In a final study, we showed by immunoblotting analysis using anti-zeta peptide antibody that Leu 8 mAb coimmunoprecipitates the zeta-chain of CD3. These results indicate that the human lymph node homing receptor homologue (Leu 8) participates in the activation of T cells, probably via its association with the TCR/CD3 complex.     

Stimulation through the TCR/CD3 complex up-regulates the CD2 surface expression on human T lymphocytes.

Despite the well known interrelationship between the CD2- and CD3-mediated signal transduction pathways, it is not well established whether the CD2 surface expression can be regulated by triggering of TCR/CD3 complex. In this study we show that the stimulation of human PBMC with the Cris-7 (CD3) mAb, both in soluble and particulate form, results in hyperexpression of the CD2 surface Ag, as assessed by immunofluorescence and semi-quantitative immunoprecipitation assays. Similar effects on CD2 surface expression were obtained when different CD3 mAb (OKT3, RW2-8C8 and Leu-4) were tested. The CD3-mediated CD2 up-regulation was suppressed by cycloheximide and actinomycin D, indicating that it requires de novo protein and RNA synthesis. In agreement with this, increased CD2 RNA levels were observed after 3 h of stimulation, reaching a plateau at 24 h that was maintained for 72 h. The CD2 up-regulation was concomitant to other CD3-induced activation-related events such as induction of surface CD25 and CD71 and high RNA levels for c-myc, IL-2R alpha- and beta-chains, CD71, and IFN-gamma. CD2 up-regulation appeared to be elicited by a protein kinase C-dependent mechanism because it was abrogated by staurosporine, a potent protein kinase C inhibitor. Moreover, IL-2-dependent events may also help in enhancing CD2 hyper-expression because it was only partially inhibitable by cyclosporine, dexamethasone, or Mar-108 (CD25) mAb. In conclusion, our data suggest that CD2 up-regulation can be a relevant event in T cell activation triggered by the physiologic engagement of the TCR/CD3 complex.     

Constitutive expression of a chimeric receptor that delivers IL-2/IL-15 signals allows antigen-independent proliferation of CD8+CD44high but not other T cells

We have prepared transgenic mice whose T cells constitutively express a chimeric receptor combining extracellular human IL-4R and intracellular IL-2Rbeta segments. This receptor can transmit IL-2/IL-15-like signals in response to human, but not mouse, IL-4. We used these animals to explore to what extent functional IL-2R/IL-15R expression controls the capacity of T cells to proliferate in response to IL-2/IL-15-like signals. After activation with Con A, naive transgenic CD8+ and CD4+ T cells respond to human IL-4 as well as to IL-2. Without prior activation, they failed to proliferate in response to human IL-4, although human IL-4 did prolong their survival. Thus, IL-2-induced proliferation of activated T cells requires at least one other Ag-induced change apart from the induction of a functional IL-2R. However, a fraction of CD8+CD44high T cells proliferate in human IL-4 without antigenic stimulation or syngeneic feeder cells. In contrast, CD4+CD44high T cells are not constitutively responsive to human IL-4. We conclude that although all transgenic T cells express a functional chimeric receptor, only some CD8+CD44high T cells contain all molecules required for entry into the cell cycle in response to human IL-4 or IL-15.