Ligation of TAPA-1 (CD81) or major histocompatibility complex class II in co-cultures of human B and T lymphocytes enhances interleukin-4 synthesis by antigen-specific CD4+ T cells

We have previously shown that CD4⁺ T cells from allergic individuals are predisposed to producing interleukin (IL)-4 in response to allergens. IL-4 production could be modulated by antigen concentration as well as by the type of antigen-presenting cells (APC), with B lymphocytes inducing greater quantities of IL-4 than monocytes. Using this system we examined IL-4 synthesis after culture of CD4⁺ T cells with B cells, monocytes, or both, as APC in the presence of allergen and a monoclonal antibody against CD81 (TAPA-1), a member of the TM4 superfamily of proteins that regulates activation, proliferation and trafficking of B cells. Addition of anti-CD81 mAb during culture enhanced IL-4 synthesis by 2- to 70-fold over that using an isotype-matched control mAb. Furthermore, anti-CD81 mAb enhanced IL-4 synthesis in CD4⁺ T cells only when CD4⁺ T cells were cultured with B cells but not monocytes as APC, indicating that anti-CD81 mAb affected IL-4 synthesis in T cells via interactions with B cells. However, pretreatment of either population separately with anti-CD81 mAb prior to culture had no effect on subsequent IL-4 synthesis, suggesting a requirement for temporal or cooperative interactions between T and B lymphocytes. In addition, anti-CD81 mAb enhanced IL-4 production but reduced CD4⁺ T cell antigen-specific proliferation, demonstrating that IL-4 production and proliferation by CD4⁺ T cells were inversely related. Finally, mAb to major histocompatibility complex class II but not to anti-CD19 also enhanced IL-4 synthesis when B lymphocytes were used as APC. In all instances, enhancement of CD4⁺ IL-4 synthesis correlated with the presence of large cell aggregates in T-B lymphocyte cocultures. These results indicate that the capacity of B cells to induce IL-4 can be significantly enhanced by ligation of particular molecules on their surface and should aid in the design of treatments for diseases in which modulation of the cytokine profile would be beneficial.     

Positive signal transduction via surface CD4 molecules does not need coexpression of the CD3/TcR complex.

We previously reported that the human CD4 molecule is capable of transducing a positive signal when activated by an anti-CD4 mAb B66. This antibody, in contrast to many other anti-CD4 mAb, induced IL2 production and proliferation of resting CD4+ peripheral blood T lymphocytes in the absence of any other signal. We further reported that anti-CD4 mAb B66 was able to induce IL2 production in murine T-cell hybridoma cells transfected with full-length human CD4 cDNA. In the present study, we extend these findings by demonstrating that anti-CD4 mAb B66 was able to induce Ca2+ mobilization and IL2 production in a CD3/TcR- variant 31-13, of the CD3/TcR+ Jurkat cell line. We further showed that anti-CD4 mAb B66 was able to activate CD4+ cells from the promonocytic cell line U937. In these cells, mAb B66 induced Ca2+ mobilization when cross-linked with a second antibody and, in addition, the production of large quantities of IL1 beta was measured. In essence, our findings provide direct evidence that cross-linking of CD4 may cause T-cell activation in the absence of the coexpression of the CD3/TcR molecular complex and that, in addition, CD4 might transduce a positive signal in CD4+ cells of the myeloid lineage.     

T cell clones expressing the natural killer cell-related p58 receptor molecule display heterogeneity in phenotypic properties and p58 function

A new anti-p58 monoclonal antibody (mAb), termed CH-L, has been used to characterize a minor subset of T lymphocytes co-expressing p58 and CD3 molecules. In two-color immunofluorescence analysis, CH-L⁺CD3⁺ cells represented 0.5 to 6% of the peripheral blood lymphocytes (in 20 healthy donors). Clonal analysis showed that most CD3⁺CH-L⁺ T cell clones expressed the CD8⁺4^? T cell receptor (TcR) α/β⁺ phenotype, while only a few were CD8^?4⁺ TcR α/β⁺, CD8^?4^? TcR α/β⁺ or CD8^?4^? TcR γ/δ⁺. Western blot analysis indicated that the CH-L mAb identifies the same 56-58-kDa diffuse band in both T and natural killer cell (NK) clones. A minority of T cell clones also expressed other NK-related markers such as CD16, CD56 and CD94 and two clones also reacted with the anti-p58 mAb EB6. Interestingly, most clones displayed cytolytic activity in an anti-CD3 mAb-triggered redirected killing assay against the Fcδ receptor⁺ P815 target cells and NK-like activity against K562 and Raji cells. In contrast, the IGROV-1 ovarian carcinoma cell line was resistant to cytolysis by all of these clones. Since p58 molecules have previously been shown to exert regulatory functions on NK-mediated lysis, we investigated whether anti-p58 mAb could also influence cytotoxicity mediated by CD3⁺p58⁺ T lymphocytes. Lysis of P815 target cells, triggered by anti-CD3 mAb, could be inhibited by anti-p58 mAb in 8 out of 12 cytolytic clones tested, while 4 clones were not inhibited. In addition, anti-p58 mAb enhanced the cytolytic activity of 3 clones against IGROV-1 and of 4 other clones against Raji target cells. Taken together, these data indicate that p58⁺ T cells express heterogeneous phenotypes and different forms of TcR and, in most instances, display cytolytic functions. Perhaps more importantly, the p58 molecule appears to modulate the cytolytic activity triggered via the CD3/TcR complex.     

A positive signal is transduced via surface CD4 molecules

We have previously reported on the identification of a monoclonal antibody (mAb) directed against the human CD4 antigen which is capable of activating CD4+ peripheral blood T cells in the absence of other stimuli. In the present study, we extended these findings by demonstrating that the mAb, termed B66, was able to induce the production of interleukin-2 in murine T-cell hybridoma transfectants expressing the human CD4 glycoprotein. Moreover, we found that incubation of Jurkat cells with mAb B66 resulted in the nearly complete disappearance of both CD4 and CD3 from the cell surface, whereas modulation of CD4, but not CD3, was observed after incubation with a non-stimulatory anti-CD4 mAb. Similar results were obtained in modulation experiments using human CD4-expressing murine transfectants. It is thus conceivable that the stimulatory activity of anti-CD4 mAb B66 may be associated with an effect on the CD3 molecular complex. While the biochemical basis for the unique stimulatory activity of mAb B66 has yet to be defined, these findings provide direct evidence that cross-linking of CD4 alone may cause T-cell activation, thus supporting the notion that this glycoprotein can transduce independent positive signals upon binding to class II major histocompatibility complex molecules.     

Lymphocyte-activation gene 3/major histocompatibility complex class II interaction modulates the antigenic response of CD4+ T lymphocytes

The activation requirements for antigen-dependent proliferation of CD4⁺ T cells are well documented, while the events leading to the inactivation phase are poorly understood. Here, we tested the hypothesis that the lymphocyte-activation gene 3 (LAG-3), a second major histocompatibility complex (MHC) class II ligand, plays a regulatory role in CD4⁺ T lymphocyte activation. CD4⁺ class II-restricted T cell clones were stimulated by their relevant antigen (hemagglutinin peptide or diphteria toxoid) and antigen-presenting cells with or without anti-LAG-3 monoclonal antibody (mAb). Kinetic studies were performed to monitor different activation parameters, including the measurement of thymidine incorporation, expression of activation antigens and cytokine secretion. Results showed that the time course from the initial time points up to the peak time point was not modified in the presence of anti-LAG-3 mAb. However, addition of these antibodies, either as whole IgG or as Fab fragments, led to increased thymidine incorporation values for late time points and, hence, to a shift in the decreasing proliferation curve. We also showed that expression of activation antigens, such as CD25, was higher in the presence of anti-LAG-3 mAb, and that cytokine concentrations, i.e. of interferon-γ or interleukin-4, were higher in the corresponding culture supernatants. In addition, we tested whether the effects of anti-LAG-3 mAb were limited to antigen-dependent. MHC class II-restricted responses. The proliferative responses of CD4⁺ T cell clones following stimulation with either interleukin-2, mitogens, a combination of anti-CD2 mAb, immobilized anti-CD3 or anti-T cell receptor mAb were not altered by anti-LAG-3 mAb. The allogeneic proliferative response of a CD8⁺ T cell clone was also not affected. Overall, the present analysis reveals a modulating effect of anti-LAG-3 mAb, mediated specifically on antigen-dependent, MHC class II-restricted responses of CD4⁺ T cell lines. These results support the view that LAG-3/MHC class II interaction down-regulates antigen-dependent stimulation of CD4⁺ T lymphocytes.     

Antigen-independent adhesion of CD4 CD45RA T cells from cord blood

Antigen-independent adhesion of resting adult CD4⁺ CD45RO⁺ T cells to B lymphocytes has been shown to be transient and can be down-regulated by CD4 major histocompatibility complex (MHC) class II molecule interactions. Conversely, adhesion of adult CD4+ CD45RA+ subpopulation to B cells is not regulated by ligands of CD4. We have investigated the regulation of adhesion of cord blood CD45RA⁺ CD4⁺ T lymphocytes. In contrast to adult CD45RA⁺ CD4⁺ T cells, cord blood CD45RA⁺ CD4⁺ T cells were strongly sensitive to the down-regulation of adhesion mediated by the CD4-HLA class II interaction, since adhesion to MHC class II(⁺) B cells was transient and inhibited by an anti-CD4 antibody. In addition, human immunodeficiency virus gpl60, synthetic gpl06-derived peptides encompassing a CD4 binding site inhibited conjugate formation between cord blood CD45RA⁺ CD4+ T cells and B cells. Following activation of the cord blood CD4 T cells by an anti-CD3 antibody, a conversion from a transient to a stable adhesion pattern of cord blood CD4 T cells to B cells occurred in 2 days. The reversal to a transient adhesion occurred at day 8 following anti-CD3 activation in correlation with a complete shift to a CD45RO phenotype of the cord blood CD4 T cells. These data suggest that CD4 T cell adhesion can be developmentally regulated.     

CD23/CD21 interaction is required for presentation of soluble protein antigen by lymphoblastoid B cell lines to specific CD4+ T cell clones

Previous studies have documented a role for membrane-bound CD23 (the low affinity FcεRII) in presentation of alloantigens by B cells. The aim of the present study was to examine the involvement of cell surface CD23 in presentation of more conventional soluble protein antigens to T cells. We show that antibodies to CD23 and to its lymphocyte-associated second ligand, CD21, inhibit presentation of the cow's milk allergen casein, by autologous CD23⁺CD21⁺ B-EBV cell lines to casein-specific HLA-DP-restricted CD4⁺ T cell clones obtained from patients with either reaginic or enterophatic forms of cow's milk protein intolerance. Maximal inhibition was achieved when the antibodies were added at the initiation of the culture. The absence of specific inhibition by an anti-DRα monoclonal antibody (mAb) argues against a steric hindrance phenomenon impeding access of the T cell receptor to major histocompatibility complex class II molecules. Rather, anti-CD23 and anti-CD21 mAb-induced inhibition of antigen presentation seems to affect at least partly, heterotypic conjugate formation through CD23/CD21 interaction. Double immunofluorescence labeling of the T cell clones and antibody inhibition of T/B conjugate formation shows that functional CD23 and CD21 molecules are induced on T cells following contact with B-EBV cell lines. Taken together, these data indicate that CD23/CD21 interactions between T and B cells are required for presentation of soluble protein antigens by B-EBV cell lines to specific CD4⁺ T cells. The potential implications of these findings for allergen-specific T cell activation are discussed.     

Role of CD40 antigen and interleukin-2 in T cell-dependent human B lymphocyte growth

In the present study, we examined the participation of CD40 ligand (L)-CD40 interaction in T cell-dependent B cell responses. To this end, purified B lymphocytes were cultured over irradiated CD4⁺ cloned T cells activated with immobilized anti-CD3 antibody. The anti-CD40 mAb 89 strongly blocked, in a specific fashion, both proliferation and Ig secretion of tonsil B cells. Interestingly, proliferation of surface (s)IgD⁺ B cell was significantly less inhibited by anti-CD40 than that of sIgD^? cells. Preactivated T cells induced B cells to grow and secrete immunoglobulins preferentially in response to IL-2. This contrasts with the CD40 system where B cells are essentially responsive to IL-4 and IL-10 but not to IL-2 alone. Collectively, these data indicate that CD40L-CD40 interaction plays an important role in IL-2-mediated T cell-dependent B cell responses. However, the activation of a subset of sIgD⁺ cells may be independent of this interaction.     

CD40 ligand-positive CD8+ T cell clones allow B cell growth and differentiation

A fraction of activated CD8⁺ T cells expresses CD40 ligand (CD40L), a molecule that plays a key role in T cell-dependent B cell stimulation. CD8⁺ T cell clones were examined for CD40L expression and for their capacity to allow the growth and differentiation of B cells, upon activation with immobilized anti-CD3. According to CD40L expression, CD8⁺ clones could be grouped into three subsets. CD8⁺ T cell clones expressing high levels of CD40L (≥80% CD40L⁺ cells) were equivalent to CD4⁺ T cell clones with regard to induction of tonsil B cell proliferation and immunoglobulin (Ig) production, provided the combination of interleukin (IL)-2 and IL-10 was added to cultures. CD8⁺ T cell clones, with intermediate levels of CD40L expression (10 to 30% CD40L⁺ cells), also stimulated B cell proliferation and Ig secretion with IL-2 and IL-10. B cell responses induced by these CD8⁺ T cell clones were neutralized by blocking monoclonal antibodies specific for either CD40L or CD40. By contrast, CD40L^?? T cell clones (?5 % CD40L⁺ cells), only induced marginal B cell responses even with IL-2 and IL-10. All three clone types were able to activate B cells as shown by up-regulation of CD25, CD80 and CD86 expression. A neutralizing anti-CD40L antibody indicated that T cell-dependent B cell activation was only partly dependent on CD40-CD40L interaction. These CD40L^?? clones had no inhibitory effects on B cell proliferation induced by CD40L-expressing CD8⁺ T cell clones. Taken together, these results indicate that CD8⁺ T cells can induce B cell growth and differentiation in a CD40L-CD40-dependent fashion.     

Anti-CD5 extends the proliferative response of human CD5+ B cells activated with anti-IgM and interleukin-2

The CD5 T cell glycoprotein which is expressed by a subset of B cells has been shown to be involved in T cell activation and proliferation. No similar studies, to date, have addressed the role of CD5 on the B cell subset. CD5⁺ and CD5^? B cells were sorted and stimulated with anti-CD5 monoclonal antibody (mAb) in vitro. The activation and proliferative responses of these two populations, as measured by analysis of proliferation marker, did not differ following anti-μ and interleukin (IL)-2 stimulation. The addition of anti-CD5 did not change the responsiveness of such activated CD5⁺ B cells but resulted in a decrease in CD25 expression. Pre-activation of B cells with phorbol 12-myristate 13-acetate, which increased CD5 expression, failed to alter the proliferative response of CD5⁺ B cells to anti-μ and IL-2 with or without addition of anti-CD5 mAb. Anti-μ and IL-2 treatment of CD5⁺ cells resulted in optimal proliferation measured at day 3 which decreased by day 6. However, addition of anti-CD5 mAb at day 3 prevented this decline in proliferative response. This dose-dependent effect was observed only when the anti-CD5 mAb was presented to the B cells in cross-linked form. Co-stimulation of CD5 did not lower the threshold of antigen to which the B cells responded. Taken together, these data support a functional role for CD5 on B cells acting as an accessory signal, following their primary activation through the B cell receptor complex and highlight differences in the role of CD5 associated with the T cell receptor complex.     

Activation of human B lymphocytes through CD40 and interleukin 4

We have produced and characterized a new CD40 monoclonal antibody, mAb 89, which in the presence of anti-IgM antibodies co-stimulates to induce B cell proliferation. mAb 89 activates resting B cells as shown by an increase in cell volume and an enhanced subsequent proliferation of B cells in response to anti-IgM antibody. However, mAb 89 does not prepare B cells to respond to the growth-promoting activity of interleukin (IL) 2 or IL 4. Unlike IL 2 and IL 4, mAb 89 only weakly stimulates the proliferation of anti-IgM pre-activated B cells. Thus, the activating properties of anti-CD40 are likely to explain its co-stimulatory effect on B cells. Interestingly, the anti-CD40 mAb 89 was found to act in synergy with IL 4, but not with IL 2, in co-stimulation and restimulation assays. In this respect, anti-CD40 does not induce a significant increase of B cell surface IL 4 receptors while IL 4, but not IL 2, induces a twofold increase of the CD40 antigen expression. Thus the synergistic interaction between IL 4 and anti-CD40 may be related to the IL 4-dependent increase of CD40 antigen expression.     

Proliferative response of human CD4+ T lymphocytes stimulated by the lectin jacalin

The Galβ(1–3)GalNAc-binding lectin jacalin is known to specifically induce the proliferation of human CD4⁺ T lymphocytes in the presence of autologous monocytes and to interact with the CD4 molecule and block HIV-1 infection of CD4⁺ cells. We further show that jacalin-induced proliferation is characterized by an unusual pattern of T cell activation and cytokine production by human peripheral blood mononuclear cells (PBMC). A cognate interaction between T cells and monocytes was critical for jacalin-induced proliferation, and human recombinant interleukin (IL)-1 and IL-6 did not replace the co-stimulatory activity of monocytes. Blocking studies using monoclonal antibodies (mAb) point out the possible importance of two molecular pathways of interaction, the CD2/LFA-3 and LFA-1/ICAM-1 pathways. One out of two anti-CD4 mAb abolished jacalin responsiveness. Jacalin induced interferon-γ and high IL-6 secretion, mostly by monocytes, and no detectable IL-2 synthesis or secretion by PBMC. In contrast, jacalin-stimulated Jurkat T cells secreted IL-2. CD3^? Jurkat cell variants failed to secrete IL-2, suggesting the involvement of the T cell receptor/CD3 complex pathway in jacalin signaling. IL-2 secretion by CD4^? Jurkat variant cells was delayed and lowered. In addition to CD4, jacalin interacts with the CD5 molecule. Jacalin-CD4 interaction and the proliferation of PBMC, as well as IL-2 secretion by Jurkat cells were inhibited by specific jacalin-competitive sugars.     

Defective integration of activating signals derived from the T cell receptor (TCR) and costimulatory molecules in both CD4+ and CD8+ T lymphocytes of common variable immunodeficiency (CVID) patients

CVID is characterized by hypogammaglobulinaemia and impaired antibody production. Previous studies demonstrated defects at the T cell level. In the present study the response of purified CD4⁺ and CD8⁺ T lymphocytes to stimulation with anti-TCR monoclonal antibody (the first signal) in combination with anti-CD4 or anti-CD8, anti-CD2 and anti-CD28 MoAbs (the costimulatory signals) was investigated. Both CD4⁺ and CD8⁺ T cells from the patients showed significantly reduced IL-2 release following stimulation via TCR and costimulation via CD4 or CD8 and CD2, respectively. However, normal IL-2 production following TCR plus phorbol myristate acetate (PMA) costimulation and normal expression of an early activation marker, CD69, after TCR + CD28 stimulation indicated that TCR was able to transduce a signal. Furthermore, both IL-2 and IL-4 release were impaired in CD4⁺ lymphocytes following TCR + CD28 stimulation. In addition, stimulation via TCR + CD28 resulted in significantly decreased expression of CD40 ligand in the patients. These results suggest that the integration of activating signals derived from the TCR and costimulatory molecules is defective in CVID patients; the defect is not confined to costimulation via a single molecule, or restricted to cells producing Thl-type cytokines such as IL-2, and is expressed in both CD4⁺ and CD8⁺T cell subsets.     

A T cell activation antigen,Ly6C,induced on CD4+ Th1 cells mediates an inhibitory signal for secretion of IL-2 and proliferation in peripheral immune responses

A T cell activation antigen, Ly6C, is considered to be involved in the autoimmunity of some autoimmune-prone mice; however, the function of Ly6C remains largely unknown. We prepared a rat anti-mouse Ly6C monoclonal antibody (mAb) (S14) that inhibits the proliferation of peripheral T cells stimulated with anti-CD3 mAb in vitro. S14 mAb, the specificity of which is confirmed by a cDNA transfectant, recognizes Ly6C antigen preferentially expressed on a part of CD8⁺ T cells in peripheral lymphoid organs. The immunohistochemical analysis demonstrates that Ly6C appears on CD8⁺ T cells in the conventional T cell-associated area of BALB/c but not of nonobese diabetic (NOD) mice, confirming the absence of Ly6C⁺ T cells in NOD mice. Addition of soluble S14 mAb to the culture does not influence the proliferation of T cells in vitro; however, the S14 mAb coated on the plate clearly inhibits the proliferation and IL-2 production of anti-CD3-stimulated peripheral T cells. The T cells are arrested at the transitional stage from G₀/G₁ to S+G₂/M phases, but they are not induced to undergo apoptotic changes in vitro. This inhibitory signal provided through the Ly6C molecule inhibited IL-2 secretion in a subpopulation of the activated CD4⁺ T cells. Ly6C is expressed on T cell clones of both Th1 and Th2 cells, but the cytokine secretion from Th1 clones is preferentially inhibited. These results suggest that Ly6C mediates an inhibitory signal for secretion of cytokines from Th1 CD4⁺ T cells, potentially causing the inhibition of immune response in peripheral lymphoid tissues.     

Involvement of the CD4 molecule in a post-activation event on T cell proliferation

A monoclonal antibody (mAb) directed to a human leukocyte 55-kDa cell surface molecule with identical cellular distribution and biochemical properties to the CD4 was able to inhibit T cell proliferation induced either in a mixed lymphocyte culture or by activation with mAb anti-CD3, anti-CD2 or phytohemagglutinin. The inhibitory effect of anti-CD4 was observed in the absence of monocytes and was directly exerted on T4+ cells. This effect on cellular proliferation appears to be due to an inhibition of a postactivation event since the rise of cytoplasmic Ca2+ after activation with anti-CD3 mAb is not affected by the presence of anti-CD4 and the proliferation that occurs after an activation pulse of 3 h with ionophore and phorbol myristate acetate can be inhibited when the anti-CD4 is added after the pulse period. Kinetic studies demonstrated that the inhibition of cellular proliferation by anti-CD4 mAb was observed even if the antibody was added as late as 18-24 h after the initiation of the culture. The effect of this blocking anti-CD4 mAb on the interleukin (IL) 2/IL 2 receptor signalling pathways was also examined. The presence of anti-CD4 slightly affected the production of IL2. In fact, addition of exogenous recombinant IL2 at the initiation of the cultures did not restore the proliferative response. However, anti-CD4 had a strong inhibitory effect on the expression of IL2 receptors as analyzed by direct immunofluorescence cytometry. Taken together, these results indicate that the binding of the anti-CD4 mAb to T cells interferes with a late metabolic step being capable of abolishing the proliferative activity of fully activated cells.     

Cross-linking of the CAMPATH-1 antigen (CD52) triggers activation of normal human T lymphocytes

The CAMPATH-1 (CD52) antigen is a 21–28 kDa glycopeptidewhich is highly expressed on lymphocytes and macrophages andis coupled to the membrane by a glycosylphosphatidylinositol(GPI) anchoring structure. The function of this molecule isunknown. However, it is an extremely good target for complement-mediatedattack and antibody-mediated cellular cytotoxicity. The humanizedCAMPATH-1H antibody, which is directed against CD52, is veryefficient at mediating lymphocyte depletion in vivo, and iscurrently being used in clinical trials for lymphoid malignancyand rheumatoid arthritis. It is therefore important to examinethe functional effects of this antibody on different lymphocytesub-populations. Because several other GPI-linked moleculesexpressed on the surface of T lymphocytes are capable of signaltransductlon resulting in cell proliferation, we have investigatedwhether the CAMPATH-1 antigen can also mediate these effects.In the presence of phorbol esters and cross-linking anti-lgantibodies, mAbs specific for CD52 induced proliferation andlymphokine production in highly purified resting CD4⁺ and CD8⁺T lymphocytes. The ret lgG2c YTH 361.10 anti-CD52 antibody,however, was able to activate resting CD4⁺ and CD8⁺ T cellsdirectly without cross-linking or phorbol myristate acetatein the absence of Fc-bearlng cells. Anti-CD52 antibodies alsoaugmented the anti-CD3 mediated proliferatlve response of CD4⁺and CD8⁺ T cells when the two antibodies were co-immobilizedonto the same surface or cross-linked in solution by the samesecond antibody. Both CD4⁺CD45RA and CD4⁺CD45RO T cells werestimulated to proliferate by anti-CD52 antibodies in the presenceof appropriate co-stimulatory factors. Antl-CD52 mAbs did not,however, synerglze with anti-CD2 or CD28 mAb to induce CD4⁺T cell proliferation. The activation of CD4⁺ T cells by antl-CD52antibodies was inhibited by cyclosporin A, suggesting a rolefor the calcineurin-dependent signal transduction pathways.Although CD52 could transduce a signal In T cells, anti-CD52antibodies did not inhibit antigen-specific or polyclonal Tcell responses, suggesting this molecule does not play an essentialco-stimulatory role in normal T cell activation.     

Differential response of CD4+ V7+ and CD4+ V7− T cells to T cell receptor-dependent signals: CD4+ V7+ T cells are co-stimulation independent and anti-V7 antibody blocks the induction of anergy by bacterial superantigen

V7 is a novel cell surface glycoprotein that is expressed on 25% of circulating T lymphocytes. This molecule appears to play a critical role in T cell activation based on the observation that a monoclonal anti-V7 antibody inhibits T cell receptor (TCR)-dependent interleukin-2 (IL-2) production and proliferation of T cells. In the current study, CD4⁺ V7+ and CD4⁺ V7? T cells were separated from one another and their response to various stimuli analyzed. Although there were only minor differences between the two subsets in the expression of activation/differentiation markers, including CD45RA and R0 isotypes, when exposed to immobilized anti-CD3 or anti-TCR antibodies in the absence of APC, CD4⁺ V7+ T cells alone produced IL-2 and proliferated vigorously. By contrast, CD4⁺ V7? cells responded poorly to such stimuli, but they recovered their capacity to respond if antigen-presenting cells (APC) or anti-CD28 antibody were added to the cultures. The enhancement of the V7? T cell response by APC appears to be related to augmentation of TCR signals because the effect could be blocked by antibodies against molecules on APC [major histocompatibility (MHC) class II, CD86] that are known to up-regulate such signals through their interaction with counter-receptors on T cells. To assess the role of V7 in a system independent of co-stimulation, CD4⁺ T cells were stimulated with the bacterial superantigens, staphylococcal enterotoxins A and B. The cells responded by proliferating and then becoming anergic. Addition of anti-V7 antibody at the initiation of culture with superantigen did not inhibit cellular proliferation but prevented T cells from becoming anergic, while addition of anti-CD28 antibody had no effect on either proliferation or anergy induction. These results indicate that V7 and CD28 mediate distinct intracellular signals and suggest that V7 functions to preserve T cell reactivity whether the stimulus is mitogenic or anergizing.