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.     

Distinct signals are required for proliferation and lymphokine gene expression in murine T cell clones

Experiments were performed to assess the capacity of lectin (Con A), ionomycin, phorbol ester (PMA), and recombinant IL 2 to mediate proliferation as well as the expression of cell surface IL 2 receptors, two lymphokine genes, IL 2 and IFN-gamma, and the c-myc proto-oncogene in cloned T cell populations. Stimulation of T cell clones with recombinant IL 2 resulted in proliferation and sustained expression of the c-myc cellular proto-oncogene, but did not induce the expression of mRNA for the lymphokines IFN-gamma and IL 2. In contrast, stimulation of cloned T cells with lectin alone induced significant IFN-gamma and IL 2 mRNA expression, up-regulation of the number of cell surface IL 2 receptors, and transient c-myc expression. Ionomycin alone was not a sufficient signal for lymphokine mRNA induction. The phorbol ester PMA alone induced neither proliferation nor lymphokine gene expression but potentiated lectin and ionomycin-mediated signals. We also performed experiments to examine whether the T cell response to extracellular stimuli was a function of the activation state of the cell. Reexposure of 48-hr antigen-activated cloned cells to identical stimuli revealed several differences. Low but significant levels of IFN-gamma mRNA were now also reinduced in activated clones cells in response to IL 2 or PMA alone. Activated cells were refractory to reinduction of IL 2 mRNA by any stimulus, which may reflect a physiologic mechanism to limit clonal expansion after antigenic stimulation. This could be partially reversed by restimulation with lectin in the presence of cycloheximide, suggesting a role for a labile protein repressor in the down-regulation of IL 2 mRNA expression. PMA alone induced an IL 2-independent proliferative response. We demonstrate that distinct signals are required for lymphokine gene expression vs cellular proliferation in cloned T lymphocyte populations, and that the capacity of extracellular stimuli to reinduce expression of lymphokine genes or to mediate cell proliferation is altered by prior activation.     

T cell growth without serum

Most in vitro T cell proliferation experiments are performed by using serum-supplemented medium, yet the actual contributions of serum components to cell cycle progression remain ill-defined, thus complicating attempts to fully define requirements for cell division. By utilizing a functional separation between T cell receptor-triggered "competence" and IL 2-promoted "progression" to independently assess serum requirements during each cell cycle stage, it was shown that serum serves an essential, active role only during the early events of the competence phase (G0-G1 transition) of T cell activation. Serum is required for optimal IL 2 production and the cell surface expression of IL 2 receptors after the stimulation of the T3/Ti antigen receptor complex. In contrast, serum does not function actively during IL 2-mediated progression through the G1 phase of the cycle. Serum proteins serve only a passive role at this stage, preventing the adsorption of IL 2. This same effect can be provided by any number of proteins including IL 2 itself, or even a high cell concentration. Supplementation of serum-free T cell cultures solely with IL 2 and transferrin is sufficient for maximal T cell proliferation, although the time of the peak response is delayed owing to a suboptimal rate of IL 2 receptor expression. Accordingly, the realization that serum is only necessary for the earliest stage of T cell activation will now enable studies designed to identify the critical individual serum components and to define their mechanism of action.     

Role of membrane potential in the response of human T lymphocytes to phytohemagglutinin

We have analyzed the role of membrane potential on T cell activation and cell proliferation. Depolarization of T lymphocytes, by increasing the extracellular concentration of K+ during a 1-hr exposure to PHA, results in a marked inhibition of cell proliferation. In parallel, depolarization of T cells prevented the normal increase in [Ca2+]i seen after PHA binding. In depolarized cells, PHA failed to induce IL 2 secretion, but, in contrast, IL 2 receptor expression was triggered normally and the cells were subsequently responsive to exogenous IL 2. Increasing [Ca2+]i in depolarized cells with the ionophore ionomycin, or bypassing the requirement for an increase in [Ca2+]i with TPA, restored the PHA-induced proliferative response in depolarized cells. These data confirm that a membrane potential-sensitive step, namely, Ca2+ influx and the resulting change in [Ca2+]i, is triggered by PHA. The inhibitory effects of depolarization are mediated through the impairment of IL 2 secretion, but not IL 2 receptor expression. T cell proliferation can therefore be regulated by altering membrane potential, which in turn modulates the extent of the change in [Ca2+]i. This study suggests a role for transmembrane potential in the regulation of the T cell proliferative response.     

Induction of proliferation and Ig production in human B leukemic cells by anti-immunoglobulins and T cell factors

The proliferation and differentiation of human leukemic B cells (B-CLL cells) with anti-Ig and T cell-derived helper factors are described. Stimulation of B-CLL cells with anti-Ig and T helper factors could induce proliferation as well as differentiation into IgM- and IgG-producing cells. Neither anti-Ig nor T helper factors alone could induce any proliferation and/or differentiation of B-CLL cells. Not only whole molecules of anti-Ig but also F(ab')2 fragments could induce proliferation and differentiation of B-CLL cells in the presence of T helper factors, but monovalent Fab' fragments were not effective. Induction of both IgM and IgG with the same idiotype was confirmed by immunofluorescent and SDS-PAGE analysis. By employing an IL 2-dependent cytotoxic T cell line and a TRF-responsive B cell line, T cell factors were separated into a fraction with IL2 activity but no TRF activity and a fraction with TRF activity but no IL 2 activity by chromatofocusing. Anti-Ig and IL 2 fraction could induce proliferation of B-CLL cells, but TRF fraction was not effective for the induction of proliferation in anti-IG-stimulated cells. For IgM and IgG production, anti-Ig and both IL 2 and TRF fractions were required. Depletion of IL 2 fraction in the first 2 days' culture inhibited Ig production, whereas the absence of TRF fraction in the first 2 days did not show any inhibitory effect on Ig production.     

PMA alone induces proliferation of some murine T cell clones but not others

The responses of cloned murine T cell lines to the phorbol ester, phorbol myristate acetate (PMA), were investigated. PMA alone was able to stimulate proliferation of some clones but not others. Two Lyt-2+, cloned cytolytic T lymphocyte (CTL) lines proliferated in response to stimulation by PMA alone, but several L3T4+, cloned helper T lymphocyte (HTL) lines did not. In contrast, all clones tested released lymphokines in response to stimulation by the combination of PMA and the calcium ionophore A23187. Moreover, all clones proliferated in response to stimulation by the combination of PMA and A23187. The proliferation of HTL in response to PMA + A23187 could be completely inhibited either by cyclosporine A (CsA) or by PC61.5, a monoclonal antibody directed against the murine IL 2 receptor; however, the proliferation of CTL in response to PMA alone was not affected either by CsA or by PC61.5. These results suggest that of the murine T cell clones tested, HTL proliferate in response to stimulation via an IL 2-dependent, autocrine pathway; in contrast, CTL, in addition to an IL 2-dependent pathway, may possess an additional IL 2-independent pathway of proliferation. CTL that proliferate in response to stimulation by PMA alone may be useful models in the study of T cell proliferation.     

Antigen-specific and -nonspecific mitogenic signals in the activation of human T cell clones

We have directly compared the signals required for: induction of the [Ca+2]i response, expression of Tac antigen, and proliferation in antigen-specific human T cell clones. We have previously shown that antigen-specific activation of cloned T cells under conditions leading to proliferation is accompanied by a rapid increase in [Ca+2]i. Cloned T cells showed increased [Ca+2]i, enhanced Tac expression, and proliferated in response to specific antigen in the presence of viable, genetically appropriate antigen-presenting cells. Paraformaldehyde fixation of antigen-presenting cells after "pulsing" with antigen prevented proliferation, but did not affect MHC-restricted [Ca+2]i or Tac responses. Treatment of cloned T cells with monoclonal anti-T3 antibody also increased [Ca+2]i and Tac expression but did not induce proliferation. Proliferation was restored by viable autologous or allogenic APC or exogenous IL 2, but not by IL 1. In contrast to resting T cells, T cell clones were insensitive to the mitogenic effects of lectins or of ionophores and phorbol esters. These results suggest that activation of antigen-specific T cells requires the sequential action of at least two signals. The first is MHC restricted and is mediated by interaction of antigen + MHC class II products with the T cell receptor (T3-Ti) complex. This leads to Tac expression and increased [Ca+2]i, but is not sufficient for proliferation. This signal can be bypassed by anti-T3 monoclonal antibodies. Proliferation requires a second, nonantigen-specific, non-MHC-restricted antigen-presenting cell signal, which cannot be replaced by IL 1 in our system. This signal can be bypassed, however, by the addition of exogenous IL 2 to cells that have received the first signal and express Tac, suggesting that it is required for IL 2 synthesis and secretion. T cell clones therefore provide a useful model for studying antigen-dependent and -independent events in cell activation.     

Induction of proliferation in vitro of resting human natural killer cells: IL 2 induces into cell cycle most peripheral blood NK cells, but only a minor subset of low density T cells

We report that resting human peripheral blood natural killer (NK) cells proliferate in response to recombinant interleukin 2 (rIL 2), and addition of irradiated lymphoblastoid B cells significantly increase their proliferative response. Interaction of IL 2 with the Tac IL 2 receptor expressed on activated NK cells is necessary to maintain continued growth of these cells. Experiments in which NK cell mitosis is prevented by colchicine show that the majority of peripheral blood NK cells are induced into the first cell cycle over a 6-day culture period in the presence of rIL 2. The addition of the irradiated lymphoblastoid B cell line, Daudi, to colchicine blocked cultures does not increase the proportion of cells entering cell cycle in response to rIL 2 alone. In limiting dilution analysis, only 1/1700 B73.1+ cells grow clonally in response to rIL 2. The frequency of clonal growth of NK cells in response to irradiated Daudi cells alone is minimal, whereas the addition of irradiated Daudi cells to rIL 2 stimulated cultures resulted in a 10-fold increase in clonal frequency compared with the cultures in rIL 2 alone. Therefore, Daudi cells may act by maintaining continuous proliferation of the NK cells originally responsive to IL 2. Unlike NK cells, only a minimal proportion of peripheral blood T cells proliferate in response to IL 2. These IL 2 responsive T cells are characterized by a lower bouyant density than the majority of peripheral blood T cells. These results indicate physiologic differences between peripheral blood resting NK and T cells in their ability to be induced to cycle. IL 2 is a growth factor for both cell types, but although the presence of the growth factor is sufficient for quiescent NK cells to be induced into cycle, T cells require antigenic or other mitogenic stimuli to respond to IL 2. The small proportion of light density IL 2 responsive T cells might represent in vivo activated T cells.     

Direct activation of human resting T cells by IL 2: the role of an IL 2 receptor distinct from the Tac protein

High concentrations of interleukin 2 (IL 2) were shown to produce a delayed but pronounced proliferation of purified resting T cells in the apparent absence of other activation signals. Because these stimulatory effects of IL 2 occurred in the absence of detectable Tac+ cells, the possibility that IL 2 might be initially interacting with an IL 2 binding protein distinct from the Tac protein was studied. Chemical cross-linking studies with 125I-IL 2 revealed the presence of an IL 2 binding protein distinct from the Tac protein on the surface of these unstimulated T cells. This second IL 2 receptor has an estimated molecular size of 70,000 daltons, lacks reactivity with the anti-Tac antibody, and appears to be identical to the p70 protein recently proposed as a component of the high affinity IL 2 receptor. Scatchard analysis of IL 2 binding assays performed with the unactivated T cells revealed approximately 600 to 700 p70 sites per cell and an apparent Kd of 340 pM. These data indicate that the p70 protein present on resting T cells binds IL 2 with an intermediate affinity compared with the previously recognized high and low affinity forms of the receptor and may account for the high concentration of IL 2 needed to induce resting T cell proliferation. To investigate the early biologic consequences of IL 2 binding to the p70 protein, potential changes in the expression of genes involved in T cell activation were examined. Northern blotting revealed the rapid induction of c-myc, c-myb, and Tac mRNA after stimulation of resting T cells with a high concentration of IL 2. The anti-Tac antibody did not inhibit IL 2 induced expression of these genes, suggesting that the p70 protein rather than the Tac antigen or the high affinity IL 2 receptor complex mediated this signal. However, in contrast to these early activation events, the anti-Tac antibody significantly inhibited IL 2 induced T cell proliferation. This finding implicates the high affinity form of the IL 2 receptor in the proliferative response of the IL 2 activated T cells. Thus these data support a two step model for the induction of resting T cell proliferation by high doses of IL 2 involving the initial generation of an activation or "competence" signal through the p70 protein and a subsequent proliferation or "progression" signal through the high affinity form of the receptor.     

Induction of human T lymphocyte motility by interleukin 2

Interleukin 2 (IL 2) is known to have multiple immunoenhancing activities that are related to its ability to promote the proliferation and the expression of effector functions of human T lymphocytes. We investigated the potential of IL 2 to induce human T lymphocyte migration. Unstimulated T cells did not respond to IL 2, but T cells exposed to dextran or phytohemagglutinin did respond to IL 2 concentrations from 0.01 to 10.0 U/ml, with significantly increased migration. This activity could be specifically blocked with anti-Tac antibody. Analysis of T lymphocyte subsets revealed that OKT4+ but not OKT8+ lymphocytes responded to IL 2 in the chemotaxis assay. Checkerboard analysis demonstrated that the IL 2-induced chemoattractant activity was predominantly chemotactic rather than chemokinetic in nature. The activity of IL 2 was compared with that of another chemoattractant lymphokine, lymphocyte chemoattractant factor, which was found to stimulate lymphocyte migration without prior exposure to mitogen, and which was not inhibited by anti-Tac. Our data suggest that the lymphocyte migratory response to IL 2 is under the control of the inducible receptor recognized by anti-Tac in a manner similar to the proliferative response to IL 2, but differs from proliferation in its OKT4+ cell specificity.     

Genetic regulation of the immune response to hepatitis B surface antigen (HBsAg). V. T cell proliferative response and cellular interactions

We previously demonstrated that in vivo antibody production to HBsAg in the mouse is regulated by at least two immune response (Ir) genes mapping in the I-A (HBs-Ir-1) and I-C (HBs-Ir-2) subregions of the H-2 locus. To confirm that H-2-linked Ir genes regulate the immune response to HBsAg at the T cell level and to determine if the same Ir genes function in T cell activation as in B cell activation, the HBsAg-specific T cell responses of H-2 congenic and intra-H-2 recombinant strains were analyzed. HBsAg-specific T cell proliferation, IL 2 production, and the surface marker phenotype of the proliferating T cells were evaluated. Additionally, T cell-antigen-presenting cell (APC) interactions were examined with respect to genetic restriction and the role of Ia molecules in HBsAg presentation. The HBsAg-specific T cell proliferative responses of H-2 congenic and intra-H-2 recombinant strains generally paralleled in vivo anti-HBs production in terms of the Ir genes involved, the hierarchy of responses status among H-2 haplotypes, antigen specificity, and kinetics. However, the correlation was not absolute in that several strains capable of producing group-specific anti-HBs in vivo did not demonstrate a group-specific T cell proliferative response to HBsAg. The proliferative responses to subtype- and group-specific determinants of HBsAg were mediated by Thy-1+, Lyt-1+2- T cells, and a possible suppressive role for Lyt-1-2+ T cells was observed. In addition to T cell proliferation, HBsAg-specific T cell activation could be measured in terms of IL 2 production, because anti-HBs responder but not nonresponder HBs-Ag-primed T cells quantitatively produced Il 2 in vitro. Finally, the T cell proliferative response to HBsAg was APC dependent and genetically restricted in that responder but not nonresponder parental APC could reconstitute the T cell response of (responder X nonresponder)F1 mice, and Ia molecules encoded in both the I-A and I-E subregion are involved in HBsAg-presenting cell function.     

Immunologic effects of interleukin 2 in primary immunodeficiency diseases

Five children with primary deficiencies of T cell function were studied to assess the effects of highly purified exogenous Interleukin 2 (IL 2) on their in vitro T cell responses. The lymphocytes from one child with Nezelof's T cell deficiency demonstrated absence of endogenous IL 2 production and improved proliferative responses to mitogen or alloantigen in the presence of exogenous IL 2. Moreover, during in vitro mixed lymphocyte culture in the presence of exogenous IL 2, his lymphocytes were able to develop into cytotoxic effector cells. A second child with Nezelof's syndrome demonstrated a different type of defect. The lymphocytes from this child had less impairment of endogenous IL 2 production. Although IL 2 increased the proliferation of his cells in response to PHA, similar augmentation was not seen after stimulation with OKT3 or alloantigen. In cell-mediated cytotoxicity assays, after mixed lymphocyte culture, natural killer-like activity was strongly boosted in the cultures that contained IL 2, but T cell-mediated cytotoxicity was not. The lymphocytes from three patients with severe combined immunodeficiency did not show improved proliferative responses in the presence of IL 2. Thus, only one of the five patients demonstrated the combination of defective endogenous IL 2 production, but preservation of the ability to respond appropriately to exogenous IL 2. This child may therefore have suffered from a T cell defect pathophysiologically similar to that seen in nude or aged mice.     

The relationship between immune interferon production and proliferation in antigen-specific, MHC-restricted T cell lines and clones

The release of immune or gamma interferon (IFN-gamma) by major histocompatibility complex (MHC)-restricted pigeon cytochrome c-specific Lyt 1+2-, interleukin 2 (IL 2)-producing proliferative T cell clones when cultured with antigen and antigen-presenting cells (APC) is a sensitive measure of the state of activation of the cell. In general, the fine specificity of T cell activation was similar when activation was measured either by IFN-gamma production or by proliferation. In response to antigen and the correct Ia molecule, the T cell clones produced both high titered IFN-gamma and a strong proliferative response. However, IFN-gamma production and the degree of proliferation of the T cell clones differed at high antigen concentrations. As antigen concentration increased, the magnitude of proliferation became submaximal whereas the IFN-gamma response became maximal suggesting that IFN-gamma produced by the cells might act as an autoregulatory molecule inhibiting the proliferative response. Stimulating the T cell to divide via its IL 2 receptor by adding exogenous IL 2 produced high levels of proliferation but only low titers of IFN-gamma activity. In addition, irradiation of the clone eliminated the IFN-gamma release induced by IL 2 but did not affect the IFN-gamma release induced by antigen and Ia. Thus proliferation is not essential for IFN-gamma production and unlike antigen and Ia, IL 2 functions predominantly as a proliferative signal and not as a signal for factor release. Two T cell clones showed a dissociation of IFN-gamma production and proliferation. In one case, a clone that proliferated in response to both allogeneic and antigenic stimuli released IFN-gamma in response to antigen but failed to produce IFN-gamma in response to the allogeneic stimulus. A second clone that showed a strong proliferative response to pigeon cytochrome c but no proliferative response to a species variant of cytochrome c, tobacco hornworm moth (THWM) cytochrome c, produced IFN-gamma when stimulated with either of these antigens. Thus, the sensitivity of detecting activation of T cell clones as measured by the release of an individual lymphokine varies from one clone to another.     

Sodium periodate-induced T cell mitogenesis: an analysis of the requirement for Ia and IL 1

T lymphocytes oxidized with the mitogen sodium periodate undergo a proliferative response when cultured in the presence of Ia+ accessory cells. However, the exact role(s) the accessory cells play in such a response has not been clearly defined. We have evaluated the role of Ia and the requirement for interleukin 1 (IL 1) in periodate mitogenicity by using the Ia+ cloned tumor cell lines P388AD (Ia+, IL 1 inducible) and P388NA (Ia+, IL 1 noninducible) as accessory cells. P388AD but not P388NA was able to supply accessory cell function to periodate-treated T cells, suggesting that Ia expression alone was not sufficient to reconstitute a response. Monoclonal anti-I-Ad and anti-I-Ed antibody blocked the accessory cell function of P388AD. In addition, monoclonal antibody GK 1.5, directed against the T cell determinant L3T4a, blocked the P388AD/periodate-treated T cell interaction, confirming that this interaction was restricted by class II molecules. Although Ia expression was required, the response was not major histocompatibility complex (MHC) restricted, because allogeneic as well as syngeneic macrophages were capable of supplying accessory cell function to periodate-treated T cells. Exogenous IL 1 alone was able to trigger periodate-treated T cells, suggesting that Ia was required for the induction of IL 1 synthesis by the accessory cells. Furthermore, purified IL 2, devoid of IL 1 activity, was able to fully reconstitute the proliferative response of accessory cell-depleted oxidized T cells to a level equal to that of whole spleen accessory cells or P388AD. These data suggest that periodate-treated T cells can proliferate with IL 1 alone and that Ia+ accessory cells in periodate-mediated T cell mitogenicity may function in the release of IL 1 and the induction of IL 2 synthesis by the T cells.     

Lymphokine regulation of activated (G1) lymphocytes. II. Glucocorticoid and anti-Tac-induced inhibition of human T lymphocyte proliferation

The regulation of the first cell cycle of human, activated (G1) PBL was analyzed by flow cytometry and [3H]thymidine incorporation. Endogenous IL 2 production was blocked in situ by pharmacologic concentration of DEX (100 to 1000 nM), resulting in an 80 to 90% reduction of thymidine uptake. Although T lymphocyte activation (G0-G1a transition) by PHA was unaltered, cells remained in the G1a phase of the cell cycle due to insufficient RNA synthesis for proliferation. The addition of IL 2-containing supernatants reversed this inhibitory effect of DEX by allowing the cells to synthesize more RNA (G1a-G1b transition). Such cells could enter the S phase and proliferate. Similar studies were performed on cells treated with a monoclonal antibody (anti-Tac) against the IL 2 receptor. In these studies, IL 2-induced RNA synthesis, and subsequent proliferation of DEX-treated and PHA-stimulated cells was inhibited by anti-Tac. Anti-Tac did not, however, inhibit the effect of endogenous IL 2 (PHA-stimulated PBL without DEX treatment), although it did bind equally well to such cells. Thus, IL 2 directly or indirectly regulates human T cell proliferation at the level of RNA synthesis. Furthermore, anti-Tac can inhibit the mitogenic signal given by endogenous IL 2, but not by in situ produced IL 2, an observation of importance to further investigations of the mechanisms by which IL 2 interacts with specific receptors to elicit proliferation.     

The role of interleukin 2 and T11 E rosette antigen in activation and proliferation of human NK clones

Although considerable data have recently been accumulated regarding the functional role of natural killer (NK) cells, relatively little is known about the factors that regulate NK cell activity. In these studies, we evaluated the role of interleukin 2 (IL 2) and the expression of the IL 2 receptor in the activation and proliferation of human NK cloned cell lines. By using a series of cloned cell lines, we were able to analyze homogeneous populations of NK cells that ordinarily comprise only a small fraction of peripheral blood lymphocytes and are extremely heterogeneous with respect to phenotypes and cytotoxic specificities. In comparison with several T cell clones, we found a much lower density of IL 2 receptors on NK clones, regardless of whether or not these cloned cells had a mature T cell phenotype. Correspondingly, NK clones needed a 10-fold higher concentration of recombinant IL 2 for maximal proliferation. Moreover, blocking studies with specific monoclonal IL 2 receptor antibodies indicated that IL 2 is both necessary and sufficient to induce the proliferation of NK clones. Because the majority of peripheral blood NK cells and NK clones express the T11 E rosette receptor antigen, which has been shown to be an antigen-independent activation pathway for T cells, we were able to study the role of monoclonal anti-T11 antibodies in the activation of various NK clones for which a specific target antigen is not known. In contrast to T cell clones, the induction of IL 2 receptor expression after T11 activation was possible only for some NK clones such as JT10 and JT3, but not for CNK5. Before activation, the IL 2 receptor expression of NK clones was confined to cells in the G2 - M phase, but after T11 activation the more pronounced IL 2 receptor expression became independent of the cell cycle. With respect to the direct proliferative effect of anti-T11 activation that has been noted with T cell clones, only the T3+ (JT10) and not the T3- NK clones could be directly stimulated. Nevertheless, IL 2 receptor expression could be triggered on some T3- clones such as JT3. Because T11-induced proliferation of T cells has been shown to be dependent on both the expression of the IL 2 receptor and on the interaction of this receptor with IL 2, it is proposed that the different responses of NK cells to T11 activation may reflect the ability of the individual clone to produce endogenous IL 2, as well as its ability to express the IL 2 receptor.     

Characterization of an antigen-specific suppressive factor derived from a cloned suppressor effector T cell line

A cloned effector-type suppressor T cell line, 3D10, which is known to suppress the antibody response against dinitrophenylated keyhole limpet hemocyanin (KLH), produced a soluble KLH-specific factor (TsF) that can replace the function of parental T cell clones. High activity of TsF was released spontaneously into the culture supernatant when cultured in interleukin 2 (IL 2)-containing medium, requiring no antigenic stimulation. The culture supernatant of 3D10 was also capable of inhibiting the KLH-induced proliferative response of primed T cells in an antigen-specific manner. The direct target of TsF was found to be Lyt-1+2- T cells undergoing an early stage of antigen-specific proliferation. TsF was antigen binding but lacked any other serologic markers such as I-J and immunoglobulin heavy chain-linked allotypic determinants on T cells. No genetic restriction was found in its action on allogeneic T cells. The production of IL 2 in proliferative T cells by antigenic stimulation was not inhibited by TsF. These results indicate that the TsF described here is the legitimate mediator produced by the effector-type suppressor T cell that suppresses the antigen-specific responses of Lyt-1+2- T cells. The m.w. of TsF was approximately 75,000.     

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.     

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.     

Interleukin 2 administered in vivo induces the growth of cultured T cells in vivo

The capacity of exogenous IL 2 to induce the growth of antigen-activated T lymphocytes in vivo was evaluated. The in vivo growth of adoptively transferred T lymphocytes that had been previously cultured long-term with IL 2 was initially examined, because in vitro such T cells are exquisitely dependent upon exogenous IL 2 for proliferation and survival. Daily administration of IL 2 in vivo, beginning on the day of cell transfer, induced these IL 2-dependent long-term cultured T lymphocytes to proliferate in vivo, and the magnitude of in vivo growth was proportional to the dose of IL 2 administered. The capacity of IL 2 to induce the in vivo growth of antigen-activated T cells not previously exposed in vitro to exogenous IL 2 was similarly studied. T lymphocytes from the spleens of immune mice, activated by 5-day culture with tumor antigen before transfer, survived poorly in vivo when injected with antigen alone, but demonstrated marked proliferation in vivo in response to antigen and exogenous IL 2. By contrast, immune spleen cells transferred with antigen, but without prior culture, proliferated without supplementary exogenous IL 2. Moreover, the growth of noncultured donor T cells was not augmented by the administration of exogenous IL 2, implying that noncultured spleen cells immune to tumor antigens can produce sufficient amounts of endogenous IL 2 in vivo to sustain maximal T cell growth over the time period examined. Importantly, the ability of exogenous IL 2 to induce donor T cell growth in vivo correlated with its ability to function in vivo to augment the anti-tumor efficacy of specifically immune donor T cells in models for the adoptive therapy of disseminated antigenic murine leukemia. Thus, the current studies highlight the potential of exogenous IL 2 to induce T cell growth in vivo and suggest that the administration of IL 2 in vivo may be useful for augmenting T cell responses that are relatively deficient in the production of endogenous IL 2.