Requirements for T cell activation by OKT3 monoclonal antibody: role of modulation of T3 molecules and interleukin 1

The requirements for activation of human peripheral blood T cells by the mitogenic monoclonal antibody OKT3 were examined. OKT3 binds to a T cell molecule, T3, associated with the T cell antigen receptor and involved in T cell activation. Activation of T cells by OKT3 requires signals provided by accessory cells and is IL 2 dependent. In the presence of accessory cells, OKT3 induces loss of T3 molecules from the cell surface, production of IL 2, expression of IL 2 receptors, and proliferation. Modulation of T3 molecules by OKT3 can be induced in the absence of accessory cells with anti-mouse IgG. These T cells, however, are not induced to express IL 2 receptors or secrete IL 2. The addition of IL 1 induces expression of IL 2 receptors, but does not induce IL 2 secretion or proliferation. Thus, peripheral blood T cells appear to have different requirements for activation compared with antigen-specific T cell clones that can be induced to produce IL 2 when stimulated with OKT3 and IL 1. Expression of IL 2 receptors does not require modulation of T3 molecules, because the binding of OKT3 to T cells in the presence of IL 1 alone is sufficient to induce IL 2 receptor expression. The results suggest that IL 2 secretion depends on cross-linking and modulation of T3 molecules, and additional, as yet undefined, accessory cell signals. The expression of IL 2 receptors and proliferation of T cells can be induced in the absence of these signals when exogenous IL 2 is provided.     

T cell unresponsiveness to the mitogenic activity of OKT3 antibody results from a deficiency of monocyte Fc gamma receptors for murine IgG2a and inability to cross-link the T3-Ti complex

We recently identified defective monocyte accessory function as the cause of T cell unresponsiveness to the mitogenic activity of OKT3 antibody in cultures of peripheral blood mononuclear cells (PBMC) from five healthy subjects, members of one family. We now report that the underlying abnormality in nonresponders is at the level of monocyte Fc gamma receptors for murine IgG2a. T cell unresponsiveness was not restricted to the signal provided by OKT3 but occurred also for two other anti-T3 antibodies of the IgG2a subclass, in contrast to a normal proliferative response to IgG1 anti-T3 antibodies in one of the OKT3 nonresponders. By using cytofluorography, we found that monocytes from responders but not from nonresponders bound OKT3-FITC to their membrane. The binding could be blocked by mouse IgG2a and by human IgG, but not by mouse IgG1 nor by serum albumin. The data suggest that, through specific Fc gamma receptors for murine IgG2a, monocytes bind the Fc portion of OKT3 during T cell activation. The function of this Fc gamma receptor binding was further studied by culturing PBMC from nonresponders on plates coated with affinity-purified goat anti-mouse IgG antibodies as a substitute for monocyte Fc gamma receptors. The addition of OKT3 to nonresponder PBMC, cultured on such plates, resulted in T cell activation, as evidenced by thymidine incorporation, IL 2 production, and expression of IL 2 receptors. Soluble anti-mouse IgG was not able to substitute for monocyte Fc gamma receptors. The results demonstrate the existence of polymorphism in monocyte Fc gamma receptors for murine IgG2a. They also substantiate that an essential helper function of monocytes in T cell activation by anti-T3 is to provide a matrix for multimeric binding of the Fc portion of the anti-T3 antibodies in order to cross-link T3 molecules.     

OKT8 antibody inhibits OKT3-induced IL 2 production and proliferation in OKT8+ cells

We studied IL 2 production and proliferation induced by OKT3 mitogenic monoclonal antibody in the OKT8+ T cell subset. OKT3 antibody induced IL 2 production and proliferation in OKT8+ cells in a typical time-dependent manner: maximal IL 2 levels were found in 24 hr culture supernatants; maximal proliferation was found on day 3. OKT3 antibody was mitogenic over a wide range of concentrations (0.125 to 500 ng/ml). The presence of OKT8 antibody (greater than or equal to 100 ng/ml) in these cultures resulted in almost complete inhibition of IL 2 production and proliferation. Kinetic studies demonstrate that OKT8 antibody suppresses both IL 2 production and response to exogenous IL 2 in OKT8+ cells when added within the first 2 hr of culture. After 14 to 20 hr of culture, addition of OKT8 only blocks IL 2 production but not the IL 2 response of activated OKT8+ cells. The specificity of inhibition by OKT8 antibody of OKT3 mitogenicity on OKT8+ cells was confirmed by the failure of Leu-I and OKT4 antibody to produce the same effect and by the lack of inhibition by OKT8 antibody of OKT3-induced IL 2 production and proliferation in OKT4+ cells.     

Monoclonal antibodies to the CD5 antigen can provide the necessary second signal for activation of isolated resting T cells by solid-phase-bound OKT3

Activation of human peripheral blood T cells by the anti-CD3 antibody OKT3 has been shown to require not only cross-linking of CD3 molecules with multimeric binding of the Fc part of OKT3 to a solid support, but also a second accessory cell-provided signal. Accordingly, measurement of T cell activation in cultures of highly enriched T cells with solid-phase-bound OKT3 can be used to investigate whether other agents can replace accessory cells. In this study we examined the capacity of anti-CD5 monoclonal antibodies to provide the additional activation signal. Resting T cells were prepared by isolating E rosette-positive cells, by removing OKM1(+) and HLA-DR(+) cells by panning, and by subsequent treatment of the cells with L-leucine methyl ester to kill remaining monocytes. These T cells were unresponsive to phytohemagglutinin (PHA) or to solid-phase-bound OKT3. However, when cultured in the presence of an anti-CD5 monoclonal antibody (anti-Leu-1, OKT1, or anti-T1), a proliferative response to solid-phase-bound OKT3 (but not to soluble OKT3 or to PHA) was observed. Anti-CD5 had no functional effect by itself, but in association with solid-phase-bound OKT3 it enhanced IL 2 receptor expression and IL 2 production and it initiated T cell proliferation. T cell proliferation under these conditions could be inhibited by an IL 2 receptor blocking antibody anti-Tac, thus confirming that anti-CD5 provides the second signal for an IL 2-dependent pathway of T cell proliferation. Preincubation of T cells with anti-Leu-1 or OKT1 resulted in complete loss of CD5 antigenicity, and such CD5 modulation was sufficient to induce a proliferative response to solid-phase-bound OKT3. It is concluded that in T cell activation by solid-phase-bound OKT3 the necessary additional signal can be provided by modulation of the CD5 antigen with an anti-CD5 antibody. CD5 therefore appears to be a positive signal receptor on the T cell membrane, whose physiologic ligand still has to be determined.     

Induction of phenotypic differentiation, interleukin 2 production, and PHA responsiveness of "immature" human thymocytes by interleukin 1 and phorbol ester

Small human thymocytes (ST) representing 70% of the thymocytes were isolated according to size by centrifugal elutriation. Although these ST contained approximately 30% PNA-cells, they failed to respond to lectins, indicating the existence of a PNA-ST subset that can be considered to belong to the "immature" thymocyte population. The ST were induced to proliferate if, in addition to PHA, IL 1-containing supernatants of highly purified monocyte cultures or 12-O-tetradecanoyl-phorbol-13-acetate (TPA) were present. The incubation of the ST for 90 hr with TPA or IL 1 in the absence of PHA resulted in a strong reduction in the percentage of cells reacting with the immature thymocyte markers TdT and PNA. In addition, the OKT6+ cells were partially reduced after incubation with IL 1. Concomitantly, an increase in the percentage of cells reacting with the mature T cell markers OKT1 and OKT3 was observed, whereas HLA antigens became strongly expressed on all ST. Although IL 1 or TPA were unable to induce proliferation of the ST, these substances induced IL 2 production by these cells. These shifts to cells with more "mature" phenotypes that are able to produce IL 2 were not observed if the ST were incubated with PHA or culture medium only. The responder capacity of the ST to PHA plus TPA was not significantly affected by the depletion of the more "mature" OKT3+ and OKT1+ cells. In addition, in this situation OKT1+, OKT3+, OKT6- cells were found to be generated from OKT1-, OKT3-, OKT6+ cells. Therefore, it could be excluded that the proliferative responses were due to a selective expansion of a preexisting mature T cell population. Our results indicate that TPA mimics IL 1 in the induction of differentiation of the ST to a stage in which subpopulations of these cells are able to produce IL 2 and to respond to PHA. Because only the proliferating ST were found to react with a monoclonal antibody, which is thought to be directed at the IL 2 receptor (anti-Tac), our data suggest that PHA is required for the induction of expression of receptors for IL 2 in those ST subpopulations that are able to proliferate in the presence of IL 2 generated in situ.     

Monoclonal antibodies against T cell differentiation antigens initiate stimulation of monocyte/macrophage oxidative metabolism

Within the first minute after incubation with the mouse anti-human T cell orthoclone monoclonal antibodies OKT3, OKT4, and OKT8, and in the absence of complement, human monocytes generate a burst of highly reactive oxygen metabolites as detected by a luminol-dependent photometric chemiluminescence (CL) assay. The kinetics of the CL responses to these antibodies are identical to that induced by OKM1, the monoclonal antibody to human monocytes and granulocytes. With regard to CL response intensities, OKM1 induces the maximal response and those of OKT3, OKT4, and OKT8 closely reflect the proportion of T cell subsets recognized by these antibodies in peripheral blood. This reaction is also observed when monoclonal antibodies against mouse Lyt surface determinants (Lyt-1 and Lyt-2) and Thy-1 antigen are tested against murine spleen cells. This murine model was further used to investigate the specificity and the mechanism of this reaction. It was demonstrated that the CL response is Lyt antigen specific, occurs upon addition of monoclonal IgG but not IgM antibodies, requires the concomitant presence of CL-producing cells (CLPC) (promonocytes, monocytes, macrophages, and/or granulocytes) and of fully differentiated T cells, and lastly, is mediated via a T cell opsonization process. Selective blockade of bone marrow cell Fc receptors (FcR II) with monoclonal anti-mouse FcR II antibody inhibits the CL response to IgG2b anti-T cell antibody-coated thymocytes and thus strongly suggests that the stimulation of CLPC oxidative metabolism in this model results from the binding of opsonized T cells to plasma membrane Fc receptors. These observations lend additional support to increasing evidence that the initiation of effector functions by monoclonal anti-T cell antibodies may be strictly dependent upon the presence of monocytes and/or macrophages.     

OKT3 monoclonal antibody induces production of colony-stimulating factor(s) for granulocytes and macrophages in cultures of human T lymphocytes and adherent cells

OKT3 monoclonal antibody (mab) recognizes a membrane antigen associated with the T cell antigen recognition receptor, and is known to be mitogenic and to induce lymphokine production. Our studies demonstrate the ability of OKT3 mab to induce from cultures of human T lymphocytes supplemented with adherent cells the production of colony-stimulating factor(s) for granulocytes and macrophages (GM-CSF) and interferon-gamma (IFN-gamma), an inhibitor of clonal growth of hematopoietic progenitor cells. As has been shown for the mitogenic and IFN-gamma-inducing activity of OKT3 mab, the induction of GM-CSF release in cultures of T cells is strictly dependent on the presence of adherent cells. However, the concentrations of OKT3 mab required for optimal GM-CSF production (50 ng/ml) were found to be 80-fold higher than those sufficient for maximal IFN-gamma production, proliferation, and interleukin 2 production. IFN-gamma activity induced by OKT3 mab partially inhibited colony and cluster formation from progenitor cells of granulocytes and macrophages in vitro. Therefore, neutralization of the IFN-gamma by monoclonal anti-human-IFN-gamma antibody before assay of conditioned medium in bone marrow cultures significantly enhanced the detection of GM-CSF. Kinetic studies demonstrated maximal cumulative GM-CSF production in response to optimal OKT3 mab concentrations on days 4 through 6 in cultures of T cells supplemented with 15% adherent cells. Highly enriched OKT4+ and OKT8+ T cell subsets co-cultured with adherent cells in the presence of OKT3 mab both produced GM-CSF and IFN-gamma and showed similar dose-response curves to OKT3 mab. The requirement for the presence of adherent cells could not be overcome by the addition of purified interleukin 1 or macrophage supernatants. Studies using irreversible inhibitors of DNA (mitomycin C) or protein biosynthesis (emetine-HCl) revealed the necessity of intact DNA synthesis and translation in mononuclear cells to produce GM-CSF in response to OKT3 mab. Loss of GM-CSF production was observed when either adherent cells or T lymphocytes were treated with emetine before co-culture with untreated cells of the other population in the presence of OKT3 mab. In contrast, mitomycin C reduced GM-CSF production significantly when T cells, but not adherent cells, were pretreated. These results suggest that T lymphocytes and adherent cells closely cooperate in the production of GM-CSF induced by OKT3 mab.     

Effect of T3 modulation on pokeweed mitogen-induced T cell activation: evidence for an alternative pathway of T cell activation

Modulation of the T3 molecule on human T cells with monoclonal anti-T3 antibodies has been shown to result in the disappearance of the T3-Ti complex from the membrane and to preclude subsequent T cell activation by various mitogenic and antigenic stimuli. We have examined the effect of T3 modulation on pokeweed mitogen (PWM)-induced T cell activation. T3 modulation was accomplished by incubating peripheral blood mononuclear cells (PBMC) or mixtures of T cells and non-T cells at 37 degrees C for 18 hr in the presence of UCHT-1, a mouse IgG1 anti-T3 monoclonal antibody. Only donors whose PBMC were unresponsive to the mitogenic activity of this antibody were selected. Although T3 modulation resulted in complete to substantial inhibition of T cell proliferation induced by low PWM concentrations of 5 or 50 ng/ml, it had no effect on T cell proliferation when PWM was added at a concentration of 0.5 and 5 micrograms/ml. The results demonstrate that the higher doses of PWM can induce T cell proliferation via an alternative pathway that does not involve participation of the T3-Ti complex. In contrast, irrespective of the PWM dose added, T3 modulation almost totally inhibited PWM-induced interleukin 2 (IL 2) production. The differential effect of T3 modulation on IL 2 production and on T cell proliferation induced by high doses of PWM suggests that this alternative pathway of T cell proliferation is IL 2 independent. This suggestion was additionally substantiated by the lack of effect of anti-Tac, and anti-IL 2 receptor antibody, on PWM-induced proliferation of T3-modulated T cells. In conclusion our data demonstrate that high doses of PWM can induce T cells to proliferate via an alternative pathway that does not involve perturbation of the T3-Ti complex.     

Failure of OKT3 monoclonal antibody to induce lymphocyte mitogenesis: a familial defect in monocyte helper function

Monoclonal antibodies to the T3 molecule on human T cells have mitogenic activity. Although anti-T3 antibodies of the IgG1 subclass (e.g., UCHT1) induce mitogenesis in lymphocyte cultures from only 60 to 70% of normal donors, antibodies of Ig2a subclass (e.g., OKT3) invariably have been found to be mitogenic in all subjects tested up to the present. This paper describes a family (a mother, six daughters, and one son) in which five members failed to respond mitogenically to OKT3 although the proportion of OKT3-reactive cells in their peripheral blood was normal. Mitogenic responses to PHA, Con A, and PWM were normal. Five members comprising four OKT3 nonresponders were also unresponsive to UCHT1. Unresponsiveness to OKT3 and unresponsiveness to UCHT1 were not absolutely linked to each other, nor were they linked to an HLA haplotype inherited from the mother. Upon stimulation by OKT3, lymphocyte preparations from OKT3-nonresponders failed to produce interleukin 2 (IL 2) and to display IL 2 receptors. OKT3 unresponsiveness was due to defective monocyte help: thus, responsiveness to OKT3 of T cells from an OKT3-nonresponder was restored by the addition of monocytes from an HLA-identical sister who had a normal response to OKT3. Inversely, T cells from the OKT3 responder had no reactivity to OKT3 when cultured in the presence of monocytes from an HLA-identical, OKT3-nonresponsive sister. Unresponsiveness to OKT3 could not be overcome by the addition of phorbol myristate acetate to the cultures. These data on a familial, non-HLA-linked deficiency of monocytes to exert their auxiliary function provide better insight into the mechanism of anti-T3-induced T cell activation.     

Concanavalin A triggers T lymphocytes by directly interacting with their receptors for activation

Anti-HLA-DR antibodies did not inhibit concanavalin A-(Con A) induced T cell proliferation or the generation of suppressor cells capable of inhibiting immunoglobulin synthesis in autologous mononuclear cells after pokeweed mitogen stimulation. Nylon-wool purified T cells (pretreated with anti-HLA-DR antibody and C) exposed to Con A acquired responsiveness to interleukin 2 (IL 2) and were able to absorb this growth factor, whereas nonlectin-treated cells did not respond to IL 2 and could not absorb it. In the presence of interleukin 1 (IL 1), Con A stimulated the synthesis of IL 2 in purified OKT4+ lymphocytes but not OKT8+ cells. However, in the absence of IL 1, neither resting OKT4+ nor Con A-treated OKT4+ cells produced IL 2. Con A by itself did not directly stimulate macrophages to synthesize IL 1, although it could do so in the presence of OKT4+ but not OKT8+ lymphocytes. In addition, Con A induced proliferation of purified T cells provided IL 1 was supplied to the cultures. Cyclosporin A rendered Con A-treated T cells unresponsive to IL 2, made lectin-stimulated OKT4+ lymphocytes unable to respond to IL 1, and inhibited the synthesis of IL 2. Furthermore, this drug abrogated the Con A-stimulated synthesis of IL 1 by acting on OKT4+ lymphocytes and not on macrophages. Finally, cyclosporin-A suppressed the proliferative response and the generation of suppressor T cells induced by Con A. The following are concluded: 1) HLA-DR antigens do not seem to play any role in the triggering of T cells by Con A, and macrophages participate in lectin-induced activation of T cells mainly by providing IL 1. 2) Cyclosporin-A inhibits activation of T cells by interfering with the mechanism by which Con A stimulates T lymphocytes. 3) Con A triggers T lymphocytes by directly interacting with their receptors for activation.     

Human monocytes and U937 cells bear two distinct Fc receptors for IgG

Several convergent lines of evidence have led us to propose that human monocytes and the related cell line U937 possess a second class of IgG Fc receptor (FcR) in addition to the 72-Kd high affinity FcR previously described. IgG affinity purification from detergent lysates of surface radiolabeled U937 cells has yielded both a 40-Kd IgG-binding membrane protein (p40) and the 72-Kd FcR protein. By the same procedure, only the p40 was isolated from the erythroblast cell line K562 and from the B cell lines, Daudi and Raji. Serologic cross-reactivity between the 40-Kd FcR on U937 and Daudi cells was demonstrated using a goat anti-FcR antiserum. A murine (m) monoclonal antibody, raised against the FcR of K562 cells, precipitated the 40-Kd FcR from lysates of U937 and K562 cells but not from Daudi or Raji cells. This antibody, referred to as anti-p40 (IV.3), selectively inhibited the binding of murine IgG1-coated erythrocytes to U937 cells, whereas monomeric human IgG selectively inhibited binding of human anti-Rh(D)-coated erythrocytes to U937 cells. Both Daudi and U937 cells mediated mIgG1 anti-T3 (Leu-4)-induced stimulation of T lymphocytes. In contrast, mIgG2a anti-T3 (OKT3)-induced stimulation was supported effectively by U937 cells but only modestly by Daudi cells. Intact IgG or Fab fragments of anti-p40 (IV.3) blocked mIgG1 anti-T3 (Leu-4) stimulation but not mIgG2a anti-T3 (OKT3) stimulation of T cells; monomeric human IgG blocked only OKT3-induced stimulation. The simplest interpretation of these results is that human monocytes and U937 cells bear two classes of IgG FcR, one of 72 Kd and the other, as described above, of 40 Kd. We propose that the 72-Kd FcR mediates rosette formation with red cells coated by human anti-Rh IgG as well as T cell stimulation by mIgG2a anti-T3 (OKT3) and that the 40-Kd FcR mediates rosette formation with erythrocytes bearing mIgG1 as well as T cell stimulation by mIgG1 anti-T3 (Leu-4). Furthermore, we suggest that these two FcR are the human homologues of the murine macrophage FcRI (binding mIgG2a) and FcRII (binding mIgG2b/1).     

Activation of resting T lymphocytes by anti-CD3 (T3) antibodies in the absence of monocytes

The antigen receptor molecules on human T lymphocytes are noncovalently associated on the cell surface with the CD3 (T3) molecular complex. Perturbation of this complex with anti-CD3 monoclonal antibodies induces T cell activation. Previous studies have demonstrated that this process requires the participation of monocytes. In the present report, we demonstrate that purified, resting (G0 phase) T cells incubated with monoclonal anti-CD3 antibodies proliferate in response to purified interleukin 2 (IL 2), in a lymphokine dose-dependent fashion. Anti-CD3 antibody or IL 2 alone did not trigger cell division. The effect was specific for anti-CD3 antibodies because monoclonal antibodies reactive with other surface molecules (OKT4, OKT8, L368) were inactive. Furthermore, the same phenomenon was observed when anti-CD3 antibody Leu-4 (IgG1) was incubated with cells of individuals whose monocytes cannot process antibodies of the IgG1 subclass (Leu-4 nonresponders). In addition, both F(ab')2 and Fab fragments of anti-CD3 antibody OKT3 were also capable of rendering T cells receptive to the IL 2 growth signal. These data indicate that neither monocytes nor CD3 receptor cross-linking are required absolutely for resting T cell activation, provided that IL 2 is supplied exogenously. T lymphocytes treated with anti-CD3 antibodies proliferated in response to both purified mitogen-induced and recombinant IL 2. Antibodies to the IL 2 receptor (anti-Tac) inhibited the proliferation. Thus, the most likely mechanism for anti-CD3 antibody-mediated triggering is induction of IL 2 receptors.     

Regulation of influenza virus-specific cytotoxic T cell responses by monoclonal antibody to a human T cell differentiation antigen

The results in this report indicate that the OKT3 monoclonal antibody, which is specific for a human T cell differentiation antigen present on 90 to 95% of peripheral T cells, can exert several effects that regulate the generation and expression of human influenza virus-immune cytotoxic T lymphocytes (CTL). The OKT3 antibody, but not OKT1 or OKT11 (which bind to all peripheral T cells), is able to inhibit anti-influenza CTL effector cell activity. An F(ab')2 preparation of OKT3 IgG were as effective as whole IgG for the inhibition of CTL effectors, indicating that the inhibitory activity of the antibody was not a function of the Fc portion of the molecule. OKT3 IgG and OKT3 F(ab')2 fragments (but not OKT4, OKT8, or OKI were able to inhibit the generation of anti-influenza CTL. The culture of human lymphoid cells with OKT3 in the presence or absence of influenza virus induced radioresistant cells that could suppress the CTL response of fresh autologous lymphocytes to influenza. These results suggest that T cell functions can be regulated by signals that are initiated by the binding of antibody to cell surface molecules that may not be related to the T cell antigen-specific receptor(s).     

Different effects of IL-2 addition or antibody crosslinking on T-cell subset stimulation by CD3 antibodies

The effect of exogenous recombinant interleukin-2 (IL-2) or of antibody crosslinking on the activation of human T-cell subsets by IgG2a (OKT3/BMA030), IgG1 (Leu4 and UCHT1), or IgG2b (BMA031) anti-T3 antibodies (CD3) was investigated. In so-called nonresponder cultures as well as in monocyte-depleted cell cultures addition of IL-2 increased the CD3-induced activation and proliferation of T4 and T8 cell subsets. Relatively more T8 than T4 cells were stimulated by antibody binding and IL-2. Crosslinking the cell-bound CD3 antibodies by plastic bound goat anti-mouse antibodies activated both T-cell subsets optimally and increased the IL-2 production of the IgG1-CD3 stimulated cultures. The data show that T cells (T8 greater than T4) can be stimulated by CD3 antibody binding and IL-2, but that crosslinking the cell-bound CD3 antibodies is crucial for optimal T4 cell stimulation and IL-2 production.     

IgG anti-lymphocyte antibodies in systemic lupus erythematosus react with surface molecules shared by peripheral T cells and a primitive T cell line

IgG anti-T cell autoantibodies are common in SLE serum, react preferentially with activated lymphocytes, and exert early-phase inhibitory effects on antigen-induced T cell proliferation. Little is known about the target molecules in this system, however, because the low titer and low avidity of the most interesting antibodies limit their utility in conventional immunoprecipitation analyses. Therefore, Western blotting was used to demonstrate binding of IgG in anti-T cell antibody-positive SLE sera to four surface membrane molecules shared by peripheral T cells and HSB-2 cells. Molecules of Mr 90,000 and 55,000 were particularly reactive: each target was stained by IgG anti-lymphocyte antibodies in 11 patient sera (approximately 85%) in the panel. Targets of Mr 37,000 and 105,000 were encountered less frequently (six of 13 and one of 13 patients, respectively). It is unlikely that alloantibodies contributed to the staining patterns observed because reactivity with the four targets was consistently present when cell preparations from multiple unrelated donors were examined. The target molecules were localized to the plasma membrane by whole cell absorption/elution experiments, by the failure of chromatin (DNA/histone) to absorb antibodies to these antigens, and through the use of purified membranes as substrate for Western blotting. With the possible exception of the 105,000 Mr molecule, which is a major target in the IgM anti-T cell antibody system, evidence for the existence of neoantigens as a basis for increased reactivity of SLE IgG with activated T cells was not obtained. The identity of the IgG antibody-reactive molecules with respect to known T cell antigens was not determined, although evidence against the existence of antibodies to Tac (IL 2 receptor) and the transferrin receptor was obtained in monoclonal antibody pre-clearing experiments. Nonetheless, the observation that a limited number of major IgG autoantibody target antigens on activated peripheral T cells are shared by HSB-2 cells, a primitive T cell line expressing few of the differentiation antigens characteristic of mature T cells, should provide a basis for more definitive characterization of antigens in this system in the future.     

Suppression of interleukin 2 receptor acquisition by monoclonal antibodies recognizing the 50 KD protein associated with the sheep erythrocyte receptor on human T lymphocytes

Monoclonal antibodies OKT11A, 9.6, and 35.1 recognize epitopes on a 50000 dalton surface molecule (p50) identical to or closely associated with the sheep erythrocyte receptor (E receptor) on human T lymphocytes. These three antibodies were investigated for ability to inhibit T cell proliferation and interleukin 2 (IL 2) receptor acquisition (determined with anti-Tac antibody in an immunofluorescence assay) induced by the lectin mitogen phytohemagglutinin (PHA) or by the phorbol ester 12-O-tetradecanoyl-phorbol-13 acetate (TPA). OKT11A, 9.6, and 35.1 were found to suppress [3H]thymidine incorporation and IL 2 receptor acquisition stimulated by PHA but not by TPA. This inhibition was not attributable to a lag in kinetics, but was sustained throughout 4 to 5 days of culture. Because OKT11A and 9.6 have been reported to suppress lectin mitogen-induced IL 2 production, we attempted to overcome inhibition of proliferation with exogenous IL 2 (MLA144 supernatants or immunoaffinity-purified human IL 2). Adding IL 2 at the initiation of culture abrogated the suppressive effect of all three anti-p50 antibodies on proliferation and on the acquisition of IL 2 receptors, raising the possibility that IL 2 may up-regulate expression of its cellular receptor on human T lymphocytes. These data, together with previous reports, indicate that OKT11A, 9.6, and 35.1 suppress lectin mitogen-induced T cell proliferation by impairing both IL 2 elaboration and IL 2 receptor acquisition, and suggest that IL 2 may be capable, at least under some conditions, of increasing expression of IL 2 receptors on human T lymphocytes.     

Regulation of the alternative pathway of T cell activation by anti-T3 monoclonal antibody

T cell activation may be triggered either through the T3-Ti antigen receptor complex or via an alternative macrophage-independent pathway involving the 50KD T11 sheep erythrocyte-binding glycoprotein. Monoclonal antibodies anti-T11(2) and anti-T11(3), directed at distinct epitopes of the T11 molecule, trigger mature T cells to proliferate and express their functional programs, and induce expression of IL 2 receptors on both T3+ and T3- thymocytes. We now show that a non-mitogenic anti-T3 antibody blocks activation via the T11 pathway of not only peripheral blood T cells, but also T3+ thymocytes. Anti-T3 does not affect surface expression of T11 or the rapid augmentation of T11(3) expression after incubation of cells with anti-T11(2). However, anti-T3 inhibits generation of IL 2 receptors and production of IL 2 by T lineage cells cultured with anti-T11(2) plus anti-T11(3). In contrast, modulation of the T11 molecule by a non-mitogenic anti-T11 antibody does not inhibit activation of T cells by a mitogenic anti-T3 antibody. The ability of anti-T3 to block expression of IL 2 receptors on both thymocytes and mature T cells activated by the T11 pathway suggests that a regulatory interaction may be important during T cell ontogeny to provide a mechanism for inhibiting expansion of autoreactive clones.     

The recognition specificity of a murine helper T cell for hemagglutinin of influenza virus A/PR/8/34

Human large granular lymphocytes (LGL), which are known to be responsible for natural killer (NK) cell activity, also produced a variety of lymphokines including interleukin 2 (IL 2), colony stimulating factor (CSF), and interferon (IFN) in response to phytohemagglutinin (PHA) or concanavalin A (Con A). Human peripheral blood LGL, which were purified by removal of monocytes adhering to plastic flasks and nylon columns, followed by separation on a discontinuous Percoll gradient, and additional treatment with anti-OKT3 and Leu-M1 plus complement, were more potent producers of these lymphokines than unseparated mononuclear cells (MNC), nylon column-eluted cells, or purified T lymphocytes. Moreover, IL 2 production by LGL could be further distinguished in that it was not enhanced by the addition of macrophages or macrophage-derived factor, i.e., IL 1, whereas addition of macrophages did potentiate IL 2 production by T lymphocytes. Further analysis of cells in the LGL population using various monoclonal antibodies revealed that removal of cells with OKT11 or AF-10, a monoclonal antibody against human HLA-DR antigen, decreased IL 2 production, whereas removal of OKT8+, OKM1+, Leu-M1+, or Leu-7+ cells led to enhanced IL 2 production. The LGL population is therefore heterogeneous and includes at least three functionally and phenotypically distinct subsets. An atypical T cell subset (OKT3-, Leu-1-, OKT11+) rather than the myeloid subset of LGL (Leu-M1+ or OKMI+) was the source of LGL-derived IL 2, whereas the latter subset and/or another subset of OKT8+ cells appear to regulate this IL 2 production. In addition to performing NK activity, LGL on a per cell basis seem to be more effective than T lymphocytes in producing lymphokines, namely, IL2, CSF, and IFN.     

Functional properties of the 50 kd protein associated with the E-receptor on human T lymphocytes: suppression of IL 2 production by anti-p50 monoclonal antibodies

Monoclonal antibody 9.6 is specific for a 50 kd T cell surface protein (p50) associated with the sheep erythrocyte (E)-receptor on human T lymphocytes. This antibody interferes with many T cell functions. We have examined the effect of antibody 9.6 on lymphocyte proliferation and interleukin 2 (IL 2) production triggered by mitogens, soluble antigens, and alloantigens to elucidate the mechanism(s) of its immunosuppressive action. At concentrations as low as 50 ng/ml, 9.6 suppressed lymphocyte proliferation and the elaboration of IL 2 by T cells stimulated by PHA, alloantigens, or low concentrations of the phorbol ester TPA (less than or equal to ng/ml). Furthermore, in cultures stimulated by a combination of PHA plus TPA, 9.6 did not inhibit the acquisition of IL 2 receptors but inhibited proliferation and IL 2 production. Immunoaffinity-purified IL 2 completely restored lymphocyte proliferation in cultures inhibited by 9.6. Studies of kinetics of inhibition by 9.6 showed that this antibody inhibited lymphocyte proliferation induced by PHA, alloantigen, and PPD even when added at 24, 48, and 72 hr, respectively, after the initiation of these cultures, suggesting that 9.6 does not block lectin binding or antigen recognition by T cells and that it can inhibit lymphocyte proliferation even after cells have undergone one or more rounds of cell division. A dose-response analysis of lymphocyte proliferation induced by PHA or by TPA demonstrated that the degree of inhibition by 9.6 decreased with increasing concentrations of these mitogens. Antibody 9.6 did not inhibit lymphocyte response induced by optimal concentrations of PHA (50 to 100 micrograms/ml; PHA-M) but inhibited proliferation of maximally induced lymphocytes by using a synergistic combination of low concentrations of PHA (5 micrograms/ml, PHA-M) plus TPA (1 ng/ml). Taken together, these findings indicate that 1) 9.6 inhibits lymphocyte proliferation by affecting IL 2 production, 2) 9.6 does not inhibit the acquisition of 9.6 receptors induced by a synergistic combination of PHA plus TPA, and 3) p50 molecules may be involved in multiple pathways of T cell activation.     

Characterization of T lymphocyte subpopulations responsible for deficient interleukin 2 activity in patients with systemic lupus erythematosus

Normal immunoregulation depends on a complex set of cellular interactions in which interleukin 2 (IL 2) appears to play an important role. We have examined the IL 2 activity in patients with systemic lupus erythematosus (SLE). IL 2 production by phytohemagglutinin (PHA)-stimulated T cells for 48 hr was measured by the ability of their culture fluid to induce proliferation of normal human T cells that had been activated for more than 20 days by PHA plus IL 2. To measure IL 2 responsiveness, T cells were blasted by preincubation with concanavalin A for 96 hr and stimulated for another 72 hr with lectin-free standard IL 2. SLE T cells failed to produce normal levels of IL 2 in vitro compared with normal control T cells. This failure resided in both OKT4+ and OKT8+ cells. Furthermore, the abnormality was due neither to soluble inhibitory factors produced by SLE T cells nor to active suppressor cells that might be induced by PHA-stimulation. Responsiveness to IL 2 of T cells from some, but not all, SLE patients was decreased significantly from that of normal controls. Absorption studies as well as studies with anti-Tac antibody demonstrated that the impaired responsiveness of T cells in the specific patients with SLE was due to inadequate expression of IL 2 receptors on the T cells upon activation. This defect was exclusively ascribed to the dysfunction of OKT4+, but not OKT8+, cells. The above defects in production of and responsiveness to IL 2 observed in patients with SLE were present at all times regardless of the disease activity or of corticosteroid therapy. Thus, the deficient IL 2 activity may be intrinsic to SLE lymphocytes and may contribute to impaired immunoregulation and to the development of SLE.