Regulation of human T lymphocyte mitogenesis by antibodies to CD3

The inhibitory and mitogenic effects of anti-CD3 antibodies (anti-CD3) were examined in cultures of human peripheral blood T cells. Resting T cells required the presence of accessory cells (AC) or phorbol myristate acetate (PMA) to be stimulated by soluble anti-CD3 (OKT3 and 64.1). Anti-CD3 was unable to induce activation of AC-depleted T cells as determined by IL 2 receptor expression, IL 2 production, cell cycle analysis, or detectable DNA synthesis. Although T cell responses to PHA also required AC, far fewer were necessary to generate responses. Anti-CD3 inhibited PHA-stimulated T cell IL 2 production, IL 2 receptor expression and proliferation in partially AC-depleted cultures. Moreover, anti-CD3 was able to inhibit PHA responses when added to culture as late as 24 to 42 hr after the initiation of a 96-hr incubation. Increasing concentrations of PHA reduced the inhibitory effect of anti-CD3 on PHA-stimulated T cell proliferation, whereas IL 2 production remained suppressed. Anti-CD3 linked to Sepharose beads effectively inhibited PHA-stimulated T cell DNA synthesis, indicating that internalization of the CD3 molecule was not required for inhibition of PHA responses. Although inhibition of IL 2 production was a major effect of anti-CD3 in PHA-stimulated cultures, it was not the only apparent inhibitory effect because the addition of exogenous IL 2 could not prevent inhibition completely. Intact AC but not IL 1 also reduced anti-CD3-mediated inhibition of PHA responsiveness, whereas the addition of both IL 2 and AC largely prevented inhibition. Thus, anti-CD3 in the absence of adequate AC signals exerted a number of distinct inhibitory effects on mitogen-induced T cell activation. These results suggest that the CD3 molecular complex may play a role in regulating T cell responsiveness after engagement of the T cell receptor by a number of mechanisms, some of which involve inhibition of IL 2 production.     

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.     

The role of IL 1 in the antigen-specific activation of murine class II-restricted T lymphocyte clones

The role of IL 1 in the antigen-specific activation of class II-restricted T lymphocytes was examined by using a model system consisting of cloned WEHI 5 B lymphoma accessory cells and class II-restricted, soluble antigen- or alloantigen-reactive T cell clones. The addition of exogenous recombinant IL 1 to the T cell cultures resulted in a significant enhancement of the antigen-specific T cell proliferation response, but at best, only small increases in IL 2 release. Goat IgG anti-IL 1 antibodies were added to the T cell cultures to assess their effect on T cell activation. The IL 1 enhancement of the T cell proliferation response was inhibited by the anti-IL 1 antibodies in a dose-dependent manner. In contrast, only modest levels (10 to 25%) of proliferation inhibition were observed in T cell cultures containing either WEHI 5 or splenocyte accessory cells but no exogenous IL 1. When the anti-IL 1 antibodies were added to primary mixed lymphocyte cultures stimulated by WEHI 5 cells in the absence of exogenous IL 1, no significant inhibition of proliferation was observed. A small but statistically significant proliferation inhibition was observed when anti-IL 1 antibodies were added to mixed lymphocyte reaction cultures stimulated by splenocytes. Two-color cytofluorometric analysis of the effects of IL 1 on antigen-activated T cell clones demonstrated that under suboptimal stimulation conditions, IL 1 stimulated a small but significant increase in the number of T cells bearing IL 2 receptors. In the presence of optimal numbers of WEHI 5 accessory cells, IL 1 enhanced T cell proliferation in the absence of a detectable increase in the number of T cells bearing IL 2 receptors, the number of IL 2 receptors per T cell, or the levels of IL 2 released. Finally, exogenous IL 1 can be added as late as 18 to 24 hr after culture initiation without significantly reducing its ability to enhance the T cell proliferation response. These data indicate that IL 1 has pleiotropic effects on murine T lymphocytes and can function to enhance T cell activation at multiple points during the activation sequence.     

Inhibitory effects of anti-CD2 monoclonal antibodies on interleukin 2 production and interleukin 2 receptor expression in anti-CD3-induced T cell activation

The effects of anti-CD2 monoclonal antibodies (mAb) on anti-CD3-driven interleukin 2 (IL2) production and IL2 receptor (IL2R) expression were investigated. Two anti-CD2 mAb, which had previously been shown to inhibit in vitro anti-CD3-induced T cell proliferation, also inhibited anti-CD3-induced IL2 production. However, it seemed unlikely that this was the crucial mechanism in the inhibition of anti-CD3-driven proliferation, since anti-CD2 mAb also partially inhibited T cell proliferation induced by the anti-CD3 mAb 446 which does not induce detectable IL2 levels. Anti-CD2 mAb also inhibited anti-CD3-induced surface IL2R expression as measured by immunofluorescence staining with an anti-IL2R mAb against the p55 chain. Inhibition of IL2R expression paralleled inhibition of proliferation. This anti-CD2-mediated inhibition involved a block in the generation of normal numbers of IL2R+ cells rather than a direct inhibitory effect on the IL2R+ cells themselves, since IL2R+ cells isolated from anti-CD2-containing cultures responded normally to IL2. Exogenous IL2 and IL4, singly or in combination, could reverse neither the anti-CD2-mediated inhibition of anti-CD3-induced proliferation nor the anti-CD2-mediated inhibition of anti-CD3-induced IL2R expression. Taken together, these observations suggest that anti-CD2 mAb inhibit anti-CD3-driven proliferation by inhibiting the generation of IL2R+ cells at a maturational stage proximal to their expression of surface IL2R. This inhibition cannot be overcome by exogenous IL2 or IL4, suggesting that the underlying biochemical mechanism involves an IL2- and IL4-independent pathway.     

Interleukin 3 is a major negative regulator of the generation of natural killer cells from bone marrow precursors

We have established a bone marrow culture system in which mature natural killer (NK) cells can be generated from inactive precursors by interleukin 2. Recombinant interleukin 3 (IL 3) almost completely blocked the induction of NK cells in this culture system as judged by cytotoxic activity, as well as appearance of cells with NK phenotype. The dose-response curve for inhibition of the generation of NK activity with IL 3 parallelled the growth promoting activity on the strictly IL 3-dependent cell line L/B. The effect of IL 3 was selective for the precursor stage of the NK cell, because mature NK cells were not affected by culture with IL 3 for the same period of time. Moreover, the effect of IL 3 was confined to the first 24 hr of culture, indicating an effect on an early stage of NK cell differentiation. IL 3 did not increase the small normally occurring NK-sensitive population in bone marrow, and did not affect the activity of a variant cytotoxic cell with specificity for adherent target cells, the natural cytotoxic cell. Concomitantly with downregulation of NK cell generation, IL 3 induced strong proliferation in the bone marrow cultures and an increase in the percentage of cells expressing the T cell marker Thy-1. A model for regulation of NK cells based on competition of growth factors for target cells with a common progenitor is discussed.     

Glioblastoma cells release interleukin 1 and factors inhibiting interleukin 2-mediated effects

Studies were designed to investigate whether the cellular immunodeficiency state observed in human glioblastoma patients could be due to inhibitory factors released by the tumor cells. Cultured human glioblastoma cells were found to secrete an interleukin 1-like factor (m.w. 22,000) and a factor (m.w. 97,000) that inhibits interleukin 2 (IL 2)-dependent T cell mechanisms. This is demonstrated by its inhibitory effect on the IL 2-induced proliferation of T cell clones and on the induction of alloreactive cytotoxic T cells in mixed lymphocyte cultures. Additionally the glioblastoma cell-derived 97,000-m.w. factor inhibited growth of neuroblasts but not of fibroblasts and thus shares the characteristics of the neuroblast growth inhibition factor (NGIF) previously detected in the supernatant of fetal rat glia cell cultures. If released by glioblastoma cells in vivo, the factor may contribute to impaired immunosurveillance and to the cellular immunodeficiency state detected in the patients.     

Differential effect of anti-beta 2-microglobulin on IL 2 production and IL 2 receptor expression in the primary mixed lymphocyte culture reaction

The mechanism of inhibition of the proliferative response in primary mixed lymphocyte culture (1 degree MLC) by antibodies to beta 2-microglobulin (beta 2m) was investigated. It is demonstrated that anti-beta 2m antibodies inhibit the production of interleukin 2 (IL 2). In contrast, the expression of IL 2 receptor is not affected by anti-beta 2m. The addition of purified exogenous IL 2 to the antibody-treated 1 degree MLC can completely restore the proliferative response, indicating that anti-beta 2m does not interfere with IL 2 binding to its receptor. Similarly, anti-beta 2m does not interfere with the capacity of IL 2-dependent T cell lines or T cell clones to respond to exogenous IL 2. The inhibition of cell proliferation and IL 2 production by anti-beta 2m is maximal when the antibody is added at the beginning of 1 degree MLC culture, and no effect of anti-beta 2m is seen when added after 3 days of culture. Anti-beta 2m has no effect on mitogen-induced cell proliferation and IL 2 production. Anti-beta 2m acts on the responder cell population, as demonstrated in experiments in which responder cells or stimulator cells are treated separately with the antibody. The expression of HLA-class II antigens (i.e., HLA-DR and DQ (DC) on the T cells activated on 1 degree MLC is not affected by anti-beta 2m. These studies indicate that the HLA-beta 2m class I antigen complex plays a role in T lymphocyte activation via release of IL 2, and suggest the existence of different mechanisms for activation of IL 2 producers and IL 2 responders in 1 degree MLC.     

Autoreactivity accelerates the development of autoimmunity and lymphoproliferation in MRL/Mp-lpr/lpr mice

Lymph node T cells from autoimmune MRL/Mp-lpr/lpr mice, but not from congeneic MRL/Mp-+/+ mice, spontaneously proliferate and produce IL 2 when cultured in vitro for 5 to 7 days. This autologous activation depends critically on the length of in vitro culture and the initial culture density, indicating that cell to cell interaction may be essential. Phenotypic characterization of cultured cells suggests that both L3T4+ and Lyt-2+ T cells proliferate. However, only L3T4+ T cells produce IL 2. Mixing experiments reveal that the inability of freshly isolated lymph node cells from MRL/Mp-lpr/lpr mice to proliferate is not due to the presence of suppressor cells. Supernatant from 7-day cultures failed to induce freshly isolated cells to proliferate. Thus, the failure of freshly isolated cells to spontaneously proliferate and secrete IL 2 is not due to the inability of the cells to produce soluble mediators. Similar to the inactivation of normal T lymphocytes, in vitro addition of monoclonal anti-L3T4 or anti-IL 2 receptor antibody significantly inhibits the activation of these cultured lymphocytes. Spontaneous proliferation and IL 2 production can be blocked by the addition of monoclonal anti-I-Ak but not by monoclonal anti-I-Ad. Spontaneous proliferation and IL 2 production can be detected in young (4-wk-old) MRL/Mp-lpr/lpr mice at a time when their lymphocyte composition and physiology appear to be normal. More interestingly, spontaneous proliferation and IL 2 production cannot be detected in C57BL/6J mice bearing the lpr/lpr gene. These experiments support the notion that aberrant syngeneic autoreactivity may act as an accelerating factor in the pathogenesis of lymphoproliferation and autoimmunity in MRL/Mp-lpr/lpr mice.     

Autoimmune effector cells. IX. Inhibition of adoptive transfer of autoimmune encephalomyelitis with a monoclonal antibody specific for interleukin 2 receptors

This study was conducted to determine whether a monoclonal antibody (MAb) specific for rat interleukin 2 receptors (IL 2R) inhibits the activation of effector T cells that adoptively transfer experimental allergic encephalomyelitis (EAE). MAb OX 39 appears to be specific for IL 2R because it binds to concanavalin A-activated, but not resting, rat lymphocytes and inhibits mitogen- and IL 2-induced proliferation of rat spleen cells. Moreover, this MAb inhibits the in vitro activation of effector cells of EAE by myelin basic protein when added to immune donor spleen cell at the start of 72-hr culture or after 24 hr, but not when added after 48 hr of culture. Other studies employed MAb W3/25, which reacts with the rat helper T cell subset and appears to define the rat homolog of the human CD4 marker present on T4-positive cells. MAb W3/25 also blocks in vitro activation of EAE effector cells, and this blocking effect can be abrogated by adding rat T cell growth factor or partially purified IL 2 to the donor spleen cell cultures. T cell growth factor alone is incapable of activating EAE effector cells. These findings are discussed with respect to the role of lymphokines in the generation of autoreactive T cells.     

Modulation of interleukin 2 internalization and interleukin 2-dependent cell growth by antireceptor antibodies

The growth factor interleukin 2 (IL2) binds to and is internalized together with high-affinity surface receptors present on lymphoid cells. This endocytosis thus results in down-regulation of the receptors. However, it is not known if the internalization is relevant to the induction of cell growth. In the present study a rat monoclonal antibody to the P55 chain of the IL2 receptor was used to examine the role of receptor internalization in the IL2-dependent autocrine human tumor T cell line IARC 301. When given alone, this antibody did not inhibit IL2 binding, internalization, or IL2-dependent cell proliferation. However, crosslinking by anti-rat immunoglobulins, which did not affect binding of the growth factor, inhibited both IL2 internalization and cell proliferation. Besides offering a novel means for the specific inhibition of the uptake of IL2 bound to IL2 high-affinity receptors, the results are compatible with the association of this receptor-ligand uptake to the growth stimulation by IL2.     

Immunologic and molecular characterizations of T cell-derived T cell activating factor

Culture supernatants from several subclones of a human T hybrid line (24A) stimulated with PMA showed co-stimulatory activity in the proliferation of Con A-stimulated murine thymocytes, but did not show any IL 2 activity. Some subclones did not show co-stimulatory activity even when stimulated with PMA, excluding the possibility of a carry-over effect. The factor found in the culture supernatants increased IL 2 production in normal T cells stimulated with a suboptimal concentration of PHA. The factor also induced IL 2 production in a T hybrid clone, T-394.1, when the latter was stimulated with a suboptimal concentration of mitogens, indicating a direct effect by this T cell-derived factor on mitogen-stimulated T cells inducing IL 2 production. This factor also induced the generation of other lymphokines such as BCDF and IFN-gamma. Northern blot analysis showed that the factor induced an increase in mRNA for IL 2 as well as IL 2 receptor. These results indicated that T cells could secrete a factor with IL 1-like activity. However, Northern blot analysis showed that mRNA from a T hybrid clone does not cross-react with cDNA for IL 1 (beta) derived from human monocytes.     

Retrovirus-mediated immunosuppression. I. FeLV-UV and specific FeLV proteins alter T lymphocyte behavior by inducing hyporesponsiveness to lymphokines

Murine splenocytes were used to study the in vitro immunosuppressive effects of UV-inactivated feline leukemia virus (FeLV-UV). FeLV-UV blocks both alloantigen (DBA/2)-induced and Con A-induced proliferation of C57BL/6 splenocytes in a dose-dependent manner. Furthermore, C57BL/6 anti-DBA/2 mixed lymphocyte cultures containing FeLV-UV fail to develop detectable DBA/2-specific cytolytic activity, although FeLV-UV has no effect on the cytolytic activity of preformed C57BL/6 anti-DBA/2 cytolytic T cells (CTL). Disruption of lymphocyte proliferation and CTL generation by FeLV-UV could not be overcome by the addition of exogenous lymphokines. These data suggest that FeLV-UV can interfere with the lymphokine reactivity of alloactivated lymphocytes. In fact, FeLV-UV blocks the lymphokine-induced proliferation of the murine IL 2-dependent cell line CTLL-20. The CTLL-20 cells were subsequently used to study the mechanism(s) by which retroviruses alter T lymphocyte function. Normally, CTLL-20 cells undergo significant proliferation when cultured in EL4 SN, an IL 2-containing culture supernatant from PMA-stimulated EL4 cells. This lymphokine-induced CTLL-20 proliferation is abrogated in a dose-dependent manner by UV-inactivated murine leukemia virus (MuLV-UV), FeLV-UV, and a purified 15,000 dalton viral protein, p15, derived from FeLV. Suppression of CTLL-20 proliferation requires only brief contact (6 hr) with FeLV-UV or with p15, but is most efficient after prolonged (24 hr) contact with these agents. Furthermore, suppression of CTLL-20 proliferation by FeLV-UV and p15 is reversible, because CTLL-20 cells which have been pretreated for 24 hr with FeLV-UV or p15 are equally as efficient at responding to EL4 SN as untreated CTLL-20. Additional studies indicate that CTLL-20 cells continue to remove IL 2 activity from EL4 SN in the presence of suppressive concentrations of FeLV-UV, and that suppressive concentrations of FeLV-UV do not remove IL 2 activity from EL4 SN. This suggests that FeLV does not block CTLL-20 proliferation by absorbing or inactivating IL 2, or by occluding IL 2 receptors, and that T lymphocytes develop an insensitivity to lymphokines after contact with FeLV-UV, which may be caused by a metabolic, rather than an immunologic, defect. Because lymphokines are requisite signals for T cell function, considerable immunosuppression would be associated with acquired lymphokine insensitivity.     

Antibodies to the common leukocyte antigen (T200) inhibit an early phase in the activation of resting human B cells

T191, a monoclonal antibody reactive with the T200 common leukocyte antigen, profoundly inhibits an early event(s) associated with alpha-immunoglobulin M (alpha IgM)/T cell replacing factor (TRF) or alpha IgM/recombinant interleukin 1 and 2 (rIL 1 and rIL 2)-induced tonsillar B cell proliferation. Kinetic analysis of T191-mediated inhibition indicated that the antibody exerts its effect within 12 to 24 hr of the initiation of cultures and rapidly loses its activity thereafter. Small resting B cells are most sensitive to T191 inhibition, whereas B cells with increasing buoyant density (presumably reflecting stages of increased activation) become progressively T191 insensitive. Analysis of RNA synthesis subsequent to alpha IgM crosslinking of surface immunoglobulin demonstrated that T191 reduced [3H]uridine incorporation by up to 38% during the first 20 hr of culture. In contrast to the effects seen with alpha IgM stimulated B cells, T191 had no inhibitory effect upon phorbol myristate acetate-induced B cell proliferation. The inhibitory effect upon B cell proliferation observed with T191 is not unique among other alpha-T200 antibodies. Four of five previously described alpha-T200 monoclonal antibodies had similar inhibitory effects (82 to 57% maximum inhibition of [3H]thymidine incorporation). However, 13.3, an alpha-T200 monoclonal antibody previously shown to block natural killer (NK) cell-mediated killing was without effect. Likewise, those antibodies capable of inhibiting B cell proliferation failed to block NK-mediated cytolysis. Antibody binding experiments together with proliferation inhibition studies suggest that all of the monoclonal antibodies tested recognized distinct epitopes on the T200 antigen. Both observations are of significance because they demonstrate that the effects seen with anti-T200 antibodies represent an interference with highly specific functional regions on the T200 molecules.     

The role of interleukin 2 in inducing Ig production in a pokeweed mitogen-stimulated mononuclear cell system

Cyclosporin A (CsA) has been found previously to block mitogen-stimulated T cell proliferation and production of discrete T cell-derived lymphokines such as interleukin 2 (IL 2) and interferon (IFN)-gamma. In addition, CsA blocks pokeweed mitogen (PWM)-driven T cell-dependent differentiation of B cells into immunoglobulin (Ig)-secreting cells. Recently, we reported that CsA (1 microgram/ml) inhibited PWM-induced T cell production of IL 2 and IFN-gamma, but supernatants retained B cell differentiation factor (BCDF)-like activity. The present study demonstrates the ability of CsA to suppress T cell functions in PWM-driven Ig production in mononuclear cells (MNC), and the capacity of exogenous T cell lymphokines to reverse CsA-induced suppression. CsA profoundly suppressed PWM-driven PFC formation (greater than 95%). However, Ig production was substantially reconstituted by the addition of IL 2 at concentrations of 10 to 50 U/ml. In contrast, no effects were observed by the addition of IFN-gamma or BCGF. The kinetics of CsA inhibition of Ig production and IL 2 secretion were found to be closely related. In addition, to obtain effective reconstitution in the CsA-treated PWM-MNC system it was necessary to add IL 2 at the initiation of culture. T cells themselves were also required for B cell differentiation in this system. However, surface Ig+ cells obtained by cell sorting after 3 days of culture could differentiate in the absence of T cells but only in response to IL 2, not in response to IFN-gamma or BCDF. Thus, in PWM-driven B cell differentiation T cells are necessary early in culture, whereas IL 2 is essential from the initial stage of B cell activation through the final stage of B cell differentiation.     

Production of IL 2 and IFN-gamma by T cells from malaria patients in response to Plasmodium falciparum or erythrocyte antigens in vitro

T cells from patients acutely infected with malaria exhibit a disease-related stimulation of DNA synthesis in response to Plasmodium falciparum antigen in vitro. This response is weak and short-lived, suggestive of induction of suppressor mechanisms. Exogenous T cell growth factor (IL 2) that was added to antigen-stimulated T cell cultures enhanced proliferation in antigen-responsive cultures, indicating that the lymphocytes expressed IL 2 receptors. In contrast, the addition of IL 2 to cultures that did not respond to antigen had no effect. Antigen-responsive cultures contained endogenous IL 2 as well, and the antigen-induced lymphocyte proliferation was correlated with IL 2 production. However, the results suggested that IL 2 production by the patients' T cells was insufficient or actively shut off, and that this was responsible for the premature cessation of their DNA synthesis. Supernatants from 60% of the T cell cultures treated with malaria antigen and from 30% treated with RBC ghost antigen contained interferon-gamma (IFN-gamma), as determined by a cytopathic effect inhibition assay combined with acid treatment and antibody neutralization or by an IFN-gamma-specific ELISA. There was no obvious correlation between antigen-induced lymphocyte proliferation and the presence of IFN-gamma in the culture supernatants. A high IFN-gamma activity was also seen in antigen-treated cultures from P. falciparum-immune donors living in highly endemic malaria areas. In contrast, no IFN-gamma was found in supernatants of antigen-treated T cells from healthy donors or patients with Plasmodium vivax malaria. Thus, the IFN-gamma activity of these cultures appears to reflect the presence of antigen-reactive T cells and may be useful as a sensitive indicator of cellular immunity in P. falciparum malaria.     

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.     

Mechanisms of human T cell response to mitogens: IL 2 induces IL 2 receptor expression and proliferation but not IL 2 synthesis in PHA-stimulated T cells

Human peripheral blood T cells were purified by a four-step procedure which included depletion of plastic-adherent cells, rosetting with sheep red blood cells, nylon wool passage, and treatment with mouse monoclonal antibodies to human Ia antigens plus complement. The purified T cells completely failed to proliferate to phytohemagglutinin (PHA). Bacterially derived recombinant human interleukin 2 (IL 2) reconstituted the proliferative response of resting T cells to PHA. The optimal concentration of IL 2 required was 100 to 200 U/ml. IL 2 alone caused no T cell proliferation. Both PHA and IL 2 needed to be present together for the proliferation of T cells to occur. Incubation of T cells with either PHA or IL 2 alone for up to 18 hr, followed by washing, then by the addition of the reciprocal reagent, resulted in no T cell proliferation. Expression of IL 2 receptors and of Ia antigens, as assessed by indirect immunofluorescent staining, revealed that both PHA and IL 2 needed to be present for Tac and Ia antigen expression by T cells. T cells incubated with PHA and IL 2 for 18 to 42 hr acquired responsiveness to IL 2. These T cells remained absolutely dependent on IL 2 for proliferation to occur. In contrast to T cells stimulated with PHA in the presence of monocytes, T cells stimulated with PHA and IL 2 released no detectable IL 2. The failure of IL 2 secretion was not caused by down-regulation of IL 2 production by IL 2 itself, because the addition of IL 2 to cultures of T cells stimulated with PHA in the presence of monocytes did not interfere with IL 2 production. These results indicate that IL 2 is a sufficient signal to induce the expression of its receptor in PHA-stimulated T cells and subsequent proliferation but is not sufficient to cause endogenous IL 2 release.     

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.     

The tumor promoter teleocidin induces IL 2 receptor expression and IL 2-independent proliferation of human peripheral blood T cells

In testing the recently discovered tumor promoter teleocidin (TCD), we found that like phorbol esters, TCD was mitogenic to human peripheral blood lymphocytes (PBL) and preferentially stimulated sheep erythrocyte-rosetted (ER) T cell-enriched populations. Stimulation of PBL with TCD induced synthesis and expression of receptors for interleukin 2 (IL 2), as shown by dot-blot analysis with the use of a synthetic oligonucleotide probe, cell surface staining with anti-Tac antibody followed by fluorescence-activated cell sorter analysis, and a functional proliferation assay in which TCD-stimulated cells were washed free of TCD and were recultured with human recombinant IL 2 (rIL 2). Increased expression of cell surface markers after TCD stimulation of PBL is not general, because TCD did not affect the expression of Leu-2a antigen, and it also reduced the density of Leu-3a and Leu-4 antigens. Stimulation of cultured, IL 2 receptor-positive PBL with rIL 2, but not TCD, was blocked by anti-rIL 2 antibodies. Furthermore, IL 2-specific mRNA was not detected in TCD-stimulated PBL, demonstrating that IL 2 was not required for TCD-induced T cell proliferation. In addition, TCD replaced IL 2 in inducing short-term proliferation of IL 2-dependent murine cytotoxic T cell lines. The findings that TCD induced IL 2-independent proliferation of T cells, and TCD and IL 2 synergized in inducing T cell proliferation, suggest that they initiate T cell proliferation via different mechanisms. The IL 2-independent activation of T cells, and the induction of IL 2 receptor expression by TCD, may be related to its ability to activate protein kinase C in cell membrane.     

Separable helper factors support B cell proliferation and maturation to Ig secretion

The 24-hr culture supernatant of Con A-activated spleen cells (SN) contains helper factors that enable maturation to high-rate polyclonal Ig secretion and enhance proliferation in cultures of mouse B cells activated with the F(ab')2 fragment of class-specific rabbit antimouse IgM antibody (anti-Ig). When interleukin 2 (IL 2), also called T cell growth factor, is removed from SN by absorption with an IL 2-dependent cell line at either 4 degrees C or 37 degrees C, all the helper activity for anti-Ig-activated B cells is also removed. Partial removal of IL 2 results in partial removal of helper activity for B cells. However, the IL 2-depleted SN appears to contain another helper factor, TRF, that enables anti-Ig-activated B cell cultures to mature to high-rate Ig secretion. This TRF activity is revealed by adding purified human IL 2 or an IL 2-containing supernatant of a cloned, lectin-activated T cell hybridoma line (FS6-14.13) to Il 2-depleted SN, which restores the polyclonal antibody response to anti-Ig. The hybridoma supernatant by itself supports proliferation of anti-Ig-activated B cell cultures, as measured by an increase in cell number, but not maturation to Ig secretion. This proliferative response is likewise IL 2 dependent, although purified IL 2 with anti-Ig is not sufficient. These experiments define separable combinations of factors acting on anti-Ig-activated B cell cultures, one of which (SN) results in both proliferation and maturation to high-rate Ig secretion, whereas the other (hybridoma supernatant) results in proliferation only. IL 2 appears to be an essential component of both combinations, although the target cell for IL 2 action in this system remains to be determined.