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.     

Association of protein kinase C activation with IL 2 receptor expression

Tac antigen (as a measure of the IL 2 receptor) acquisition and regulation by IL 2, an antigen-receptor agonist (anti-T3), phorbol esters, and phytohemagglutinin (PHA) were studied. Phorbol esters stimulated de novo acquisition of Tac antigen, which was associated with the subcellular redistribution of protein kinase C (PK-C) from cytosol to particulate membranes of human T lymphocytes. PHA and anti-T3 (alpha-T3) antibody also stimulated a transient redistribution and activation of PK-C that reached a maximum within 20 min after stimulation. Both phorbol esters and alpha-T3 could increase Tac expression and stimulate PK-C translocation on 5 and 12 day activated T cells that were at the G0/G1 stage of the cell cycle due to IL 2 deprivation. Tac antigen-specific mRNA was seen in the nucleus within 2 hr after stimulation. In contrast, IL 2 alone could only increase Tac expression and stimulate PK-C translocation on day 5 but not day 12 activated T cells. IL 2 synergizes with alpha-T3 and phorbol ester for the regulation of Tac expression. Although IL 2 increased expression of Tac, the majority if not all of these receptors possessed low affinity for IL 2. These data suggest that the activation of PK-C is a common transmembrane signal shared by IL 2 and antigen stimulation. The results also imply that PK-C activation is necessary for the regulation of Tac antigen expression.     

Expression of functional IL 2 receptors by lipopolysaccharide and interferon-gamma stimulated human monocytes

Human peripheral blood monocytes were stimulated with lipopolysaccharide (LPS) and interferon-gamma (IFN-gamma) alone or in combination. Stimulated but not resting monocytes displayed the Tac peptide of the interleukin 2 (IL 2) receptor within 24 hr as measured by immunofluorescence staining and [3H] Tac binding. The total number of anti-Tac binding sites on co-stimulated monocytes was 13,700. By using scatchard analysis with radiolabeled IL 2, the activated cells were shown to express low numbers (below 100 sites/cell) of high affinity binding sites with a KD of approximately 15 pM. LPS and IFN-gamma were additive in augmenting the number of IL 2 and anti-Tac binding sites. By using an ELISA assay specific for the soluble released form of the Tac peptide we identified 112 U/ml of IL 2 receptors in the supernatant of monocytes stimulated for 24 hr with IFN-gamma, 233 U/ml after stimulation with LPS, and 519 U/ml after the addition of both stimulating agents. Both the membrane form (55,000 daltons), as well as the soluble form (45,000 to 50,000 daltons) of the Tac, IL 2 receptor, peptide from monocytes were shown by immunoprecipitation and gel electrophoresis to be similar size to the comparable forms of these receptors derived from activated T cells. In addition, monocytes stimulated for 8 hr contained mRNA specifically hybridizing to a cDNA probe coding for the Tac peptide. Finally, activated monocytes responded to the addition of recombinant IL 2 by an increase in H2O2 production that was measured by using fluorescent indicator 2,7-dichlorofluorescein. This response as well as the observed induction of monocytic IL 2 receptors by LPS may point to a functional role for this receptor during monocyte/macrophage responses to microbial infections.     

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.     

rIL 2-induced proliferation of human circulating NK cells and T lymphocytes: synergistic effects of IL 1 and IL 2

Cells participating in the rIL 2-induced proliferation of resting PBMC were identified by using different methods of cell purification. NK cells recovered in the light density fraction of Percoll gradients responded, as already known, directly to rIL 2 by strong proliferation. In contrast, large T lymphocytes co-purifying with NK cells, and small T cells sedimenting in the high density area of the Percoll gradients, were virtually unresponsive when cultivated in the sole presence of rIL 2. However, the addition of either irradiated autologous monocytes or highly purified IL 1 allowed both kinds of T cells to undergo cell division. Stringent elimination of possibly contaminating NK cells (NKH-1+) and/or activated T cells (TNKTAR, Tac+, HLA-DR+) from the high density T cells by complement lysis did not impair rIL 2-induced cell proliferation, indicating entire responsiveness of these cells to the synergistic action of IL 1 plus IL 2. Both high density CD4+ and CD8+ participated in this phenomenon, with an apparent advantage for CD4+ cells. All Tac+ cells emerging in a 6-day culture of these cells expressed the WT31 antigen, which indicates that T cells involved in rIL 2-induced proliferation are conventional mature T cells. The relative precursor frequencies of NK cells, large T lymphocytes, and small T lymphocytes that proliferated in response to rIL 2 were analyzed by limiting dilution analysis. The frequencies of clonal growth of NK cells and low density T lymphocytes were approximately the same (1/103 vs 1/185), whereas that of high density T cells was four times lower (1/458). Thus, we clearly demonstrate that resting T cells, defined as such by morphological, density, and phenotypic criteria, are able to proliferate in response to IL 2 in the presence of IL 1 without antigenic or mitogenic triggering.     

TCGF (IL 2)-receptor inducing factor(s). I. Regulation of IL 2 receptor on a natural killer-like cell line (YT cells)

A continuous cell line (YT cells) with inducible receptor for T cell growth factor (TCGF)/interleukin 2 (IL 2) was established from a 15-yr-old boy with acute lymphoblastic lymphoma and thymoma. YT cells were tetraploid, having 4q+ chromosomal markers, and proliferated continuously in vitro without conditioned medium (CM) or IL 2. They were weakly positive for OKT9, OKT11, and Tac antigen (Ag), a determinant closely associated with the receptor for IL 2 (IL 2-R), and were negative for OKT1, OKT3, OKT4, and OKT8 Ag. YT cells also expressed HNK-1 Ag and Fc receptors for IgG, which are expressed on natural killer (NK) cells. They retained a killing activity against human cell lines, including K562 (myeloid), T, and B cell lines. Unlike Tac Ag/IL 2-R(+) cell lines derived from adult T cell leukemia (ATL), YT cells were negative for HTLV, as proved by Southern blotting with cDNA for viral DNA. The expression of Tac Ag was markedly enhanced in 18 hr, when YT cells were incubated with CM from PHA-stimulated peripheral blood leukocytes (PBL) or spleen cells, as determined by immunofluorescence by using flow cytometry and binding assay with 125I-anti-Tac antibody (Ab). The binding study with 125I-labeled recombinant IL 2 showed 3.2 X 10(4) IL 2 receptor sites on YT cells precultured with CM. PHA-P and Con A neither agglutinate nor enhance the expression of IL 2-R/Tac antigen on these non-T cell line cells. Furthermore, neither recombinant IL 2 nor gamma-interferon could induce IL 2-R on YT cells, suggesting the presence of a unique IL 2-R inducing factor in PBL or spleen CM. Unlike Tac Ag on HTLV(+), ATL-derived cell lines (Hut-102, MT-1, ATL-2), the expression of Tac Ag on YT cells was down-regulated by anti-Tac Ab. The induction of Tac Ag/IL 2-R on YT cells seemed specific, because the enhancement of Tac Ag expression was not associated with that of Ia Ag and T9/transferrin receptor.     

Interleukin 2 (IL 2) up-regulates its own receptor on a subset of human unprimed peripheral blood lymphocytes and triggers their proliferation

Several reports indicate that human peripheral blood lymphocytes (PBL) seeded in culture with purified or recombinant interleukin 2 (IL 2) immediately after separation from the blood display a substantial level of proliferation at day 5 or 6, even in the absence of any activating signal. The spontaneously IL 2 proliferating cells are large lymphocytes, and they co-purify on a Percoll gradient in the large granular lymphocytes (third (LGL) fraction) together with the natural killer (NK) activity. When LGL were separated into NKH1 (an NK-specific surface marker)-positive and NKH1-negative cells by fluorescence-activated cell sorting (FACS), proliferating cells were mainly found in the NKH1-negative fraction. On the contrary, when cells from Percoll fraction 3 were separated into OKT3-negative and positive cells, the majority of the proliferating cell was found in the OKT3-positive cells. These results indicate that spontaneously IL 2 proliferating (SIP) cells most probably belong to the T cell lineage, but are distinct from NK cells. Surprisingly, cells from this Percoll fraction examined immediately after separation from the blood do not express detectable amounts of IL 2 receptors as assessed by three different techniques: binding of [3H]IL 2, binding of [125I]anti-Tac antibodies, and FACS analysis with the use of anti-Tac antibodies. However, after 18 hr of culture in IL 2-supplemented medium, 5 to 7% of these cells became Tac-positive by FACS analysis. Additional analysis of IL 2 receptor induced in culture with IL 2 was performed by [125I]anti-TAC binding and by [3H]IL 2 binding. Scatchard analysis of [3H]IL 2 binding, in the range of concentrations leading to the detection of high-affinity binding sites, showed an affinity constant similar to that of conventional phytohemagglutinin blasts. The role of IL 2/IL 2 receptor interaction in the proliferation process was confirmed by the fact that proliferation, in contrast with NK activation, was clearly inhibited by anti-Tac antibodies. When LGL activated with IL 2 for 60 hr were sorted into Tac+ and Tac- cells, equal levels of NK activity was found in the two fractions. Proliferation, however, was only observed in the Tac+ population. We interpret these results to indicate that SIP cells are preactivated cells circulating in the blood. They are large cells and represent a very small proportion of circulating lymphocytes (0.3%). They express a subliminal amount of IL 2 receptor. Cultivated in the presence of IL 2, IL 2 receptor expression is enhanced to a detectable level, and the SIP cells begin to proliferate. These SIP cells could be activated T cells present in every normal individual.     

Thy-1+ epidermal cells proliferate in response to concanavalin A and interleukin 2

Mouse epidermal cells (EC) are composed of at least two phenotypically discrete populations of cells that in epidermal sheets have a dendritic morphology: Ia+ Langerhans cells (LC) and dendritic, bone marrow-derived, Ia- cells that express Thy-1 antigen (Thy-1+ dEC). Thy-1+ dEC lack other typical T cell markers such as L3T4, Lyt-1, and Lyt-2; however they do express Ly-5 and asialo GM1 in common with NK cells and certain other leukocytes. To investigate the functional capabilities of Thy-1+ dEC in vitro, cell suspensions prepared from trypsin-disaggregated sheets of mouse body wall epidermis were first enriched to 8 to 20% Ia+ and 20 to 40% Thy-1+ cells by centrifugation over Isolymph and then were cultured for 2 to 10 days with Concanavalin A (Con A) and/or partially purified rat IL 2. Con A-induced proliferation of EC was readily seen, with the maximal response occurring at a Con A concentration of 2.5 micrograms/ml on day 5 of culture. Con A responses were significantly enhanced by the continuous presence of 1 microgram/ml indomethacin. Responses both in the presence and absence of Con A were significantly enhanced by the addition of 5 to 10 U/ml of partially purified rat IL 2; proliferation in cultures stimulated by both Con A and IL 2 continued to increase throughout the 10-day culture period. Culture of fluorescence-activated cell sorter (FACS)-separated EC suspensions revealed that Thy-1-depleted EC and irradiated Thy-1+ EC failed to proliferate in response to Con A and IL 2, whereas unirradiated purified Thy-1+ EC gave enhanced Con A- and IL 2-induced responses compared with the unseparated population. Finally, to distinguish between the proliferation of small numbers of mature peripheral T cells and that of Thy-1+ dEC, antibody and complement-depletion studies were conducted with an unusual monoclonal anti-Thy-1 reagent, 20-10-5S, and with the anti-T cell reagents, anti-L3T4 and anti-Lyt-2. Thy-1+ dEC, but not LC, express the 20-10-5S determinant; furthermore, in CBA (Thy-1.2) mice 20-10-5S reacts with Thy-1+ dEC, thymocytes, and peripheral T cells, whereas in AKR/J (Thy-1.1) mice, it reacts only with Thy-1+ dEC and thymocytes and not with peripheral T cells. Pretreatment of AKR/J EC with 20-10-5S and complement abolished the capacity of such cells to respond to Con A and to IL 2.(ABSTRACT TRUNCATED AT 400 WORDS)     

Crosslinking of the CD5 antigen on human T cells induces functional IL2 receptors.

CD5 is a 67-kDa antigen that is expressed on the membrane of the majority of human T cells, and on a subset of B cells. Previous studies have demonstrated that anti-CD5 monoclonal antibodies (mAb) can provide a helper signal for T cell activation through the TCR/CD3 complex. We now demonstrate that when CD5 is crosslinked by immobilized anti-CD5 mAb in the absence of other activating stimuli, the T cells proliferate in response to recombinant interleukin 2 (rIL2) (but not to rIL4). Four different anti-CD5 mAb (anti-Leu1, 10.2, anti-T1, and OKT1) had a similar effect. IL2 responsiveness could be induced with immobilized anti-CD5 mAb in cultures of purified T cells, but was enhanced by the addition of monocytes, by monocyte culture supernatant, or by the combination of IL1 and IL6. Staining with an anti-IL2 receptor (p55) mAb demonstrated expression of IL2 receptors on about 10% of the anti-CD5-stimulated T cells. Both virgin (CD45RA+) and memory (CD45RO+) T cells were responsive. Our data provide further evidence for the involvement of CD5 in T cell activation.     

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.     

The anti-T cell monoclonal antibody 9.3 (anti-CD28) provides a helper signal and bypasses the need for accessory cells in T cell activation with immobilized anti-CD3 and mitogens

CD28 is an antigen of 44 kDa which is expressed on the membrane of the majority of human T cells. The present study examines the functional effects of an anti-CD28 monoclonal antibody (mAb 9.3) on T cell activation induced with immobilized anti-CD3 mAb OKT3 or with mitogens, in the absence of accessory cells. To this end, we used blood resting T cells that were completely depleted of accessory cells (monocytes, B cells, and natural killer cells), and consequently did not respond to recombinant interleukin-2 (rIL-2), to immobilized OKT3, to PHA, or to Con A. Addition of mAb 9.3 to the cultures enhanced IL-2 receptor expression (Tac antigen) on PHA- or immobilized OKT3-stimulated T cells and induced IL-2 receptors on Con A-stimulated T cells. Moreover, addition of mAb 9.3 to cultures of T cells stimulated with PHA, Con A, or immobilized OKT3 resulted in IL-2 production. Soluble mAb 9.3 was a sufficient helper signal for T cell proliferation in response to PHA or immobilized OKT3. Crosslinking of mAb 9.3 by culture on anti-mouse IgG-coated plates enhanced the helper effect and was an essential requirement for the induction of T cell proliferation in response to Con A. No other anti-T cell mAb (anti-CD2, -CD4, -CD5, -CD7, -CD8) was found to provide a complete accessory signal for PHA or Con A stimulation of purified T cells. T cell proliferation induced by the combination of PHA and mAb 9.3 was strongly inhibited by the anti-IL-2 receptor mAb anti-Tac. In conclusion, mAb 9.3 can provide a signal bypassing monocyte requirement in T cell activation with immobilized OKT3, PHA, and Con A, resulting in an autocrine IL-2-dependent pathway of proliferation.     

Structural and functional characterization of IL 2 receptors on activated human B cells

After activation, B cells express the IL 2 receptor as determined by their reactivity with monoclonal anti-IL 2 receptor antibodies. In this report we show that anti-IL 2 receptor antibodies precipitated comparable 60,000 to 65,000 dalton proteins from highly purified B and T cells. Limited peptide mapping suggested that the receptors on B and T cells were identical. Moreover, activated B cells could be induced to proliferate by IL 2, but not to secrete Ig. Anti-IL 2R antibody blocked the effect of IL 2 but not the proliferative response induced by B cell growth factor (BCGF), suggesting independent growth factor receptors. Investigation of the kinetics of the B cell response to growth factor indicated that BCGF acts within 24 hr, whereas IL 2 was virtually devoid of activity for 48 hr. Nevertheless, after 72 to 96 hr, the effect of IL 2 was equal to or greater than that obtained with BCGF. These studies suggest that the initial stages of B cell proliferation involves a sequential interaction of BCGF and IL 2 with their respective receptors.     

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.     

In vitro maturation of B cells in chronic lymphocytic leukemia. I. Synergistic action of phorbol ester and interleukin 2 in the induction of Tac antigen expression and interleukin 2 responsiveness in leukemic B cells

Recent evidence indicates that interleukin 2 (IL 2), formerly thought to serve as growth factor exclusively for activated T cells, is directly involved in human B cell differentiation. We have investigated the role of IL 2 and IL 2 receptors (as defined by monoclonal anti-Tac antibody) in the phorbol ester-induced in vitro maturation of leukemic B cells from patients with chronic lymphocytic leukemia (CLL). Peripheral blood lymphocytes from B cells from CLL patients with high (greater than 10(5)/microliters) white blood cell counts were depleted of residual T lymphocytes and low-density cells (primarily macrophages) by consecutive steps of E rosetting, complement-mediated lysis of OKT3+ and OKT4+ cells, and Percoll density gradient centrifugation. No OKT3+ T cells were detectable in these cell populations before or after culture. When incubated for 3 days with phorbol ester plus recombinant human IL 2 (rIL 2), 12 to 57% of highly purified B cells from four of five tested patients expressed Tac antigen. Both phorbol ester and rIL 2 were required for maximal Tac antigen expression. Functional studies revealed that phorbol ester-activated (but not resting) CLL B cells responded to rIL 2 with [3H]thymidine incorporation and with enhanced secretion of IgM. Tac+ B cells were isolated in two cases on a fluorescence-activated cell sorter. In one patient, stimulation of Tac+ B cells with rIL 2 resulted in enhanced [3H]thymidine incorporation but no change in IgM secretion, as compared with Tac- B cells; in the second patient, stimulation of Tac+ B cells with rIL 2 did not result in [3H]thymidine uptake, but did result in significant IgM secretion. These findings indicate that certain leukemic B lymphocytes can be induced to express IL 2 receptors and respond to IL 2. The use of resting clonal B cell populations arrested at distinct stages of differentiation may help to better define the stage(s) at which IL 2 acts directly on B cells to induce proliferation and/or terminal differentiation.     

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.     

Both cloned interleukin 2 and purified interleukin 1 are required for optimal growth of purified L3T4+ and Lyt 2+ lymphocytes initiated by concanavalin A

Concanavalin A (Con A), cloned interleukin 2 (IL-2), purified interleukin 1 (IL-1) or two different crude preparations containing IL-1 activity alone, did not induce proliferation of rigorously accessory cell (AC)-depleted splenic L3T4+ or Lyt 2+ lymphocytes. Con A together with saturating concentrations of cloned IL-2 (100 U/ml) promoted less than 40% of the proliferative responses observed in AC-supplemented L3T4+ and Lyt 2+ T-cell cultures. The three preparations of IL-1 used supported minimal proliferation of Con A-treated purified L3T4+ or Lyt 2+ lymphocytes. However, all these IL-1 preparations promoted significant growth of the T-cell populations if AC (1%) were included in the cultures. Cloned IL-2 combined with purified IL-1 promoted proliferation of Con A-treated L3T4+ and Lyt 2+ lymphocytes achieving approximately 75% of the responses observed in AC-supplemented T-cell cultures. The additive effect of IL-1 was apparent in the presence of saturating concentrations of cloned IL-2. Finally, Con A alone induced a detectable number of both L3T4+ and Lyt 2+ lymphocytes to express IL-2 receptors as determined with the anti-mouse IL-2 receptor antibody 7D4 by immunofluorescence and FACS analysis. Purified IL-1 neither induced detectable number of L3T4+ or Lyt 2+ T cells to express IL-2 receptors nor increased the number of Con A-treated T cells bearing IL-2 receptors. We have interpreted these findings to indicate the following: Con A alone is sufficient to induce highly purified L3T4+ and Lyt 2+ lymphocytes to express IL-2 receptors. Cloned IL-2 and purified IL-1 are required for optimal growth of L3T4+ and Lyt 2+ lymphocytes and these cytokines together efficiently replace AC in growth of T cells initiated by Con A. IL-1 alone does not replace AC in Con A-induced activation of mouse T cells. IL-1 exerts potentiation on IL-2-driven growth of Con A-treated L3T4+ and Lyt 2+ lymphocytes. The additive activity of IL-1 on growth of normal T cells is not due to increased production of IL-2 in the cultures or induction of normal T cells to expression of IL-2 receptors by IL-1. We propose that IL-1 optimizes the action and/or interaction of IL-2 with its receptors on the T-cell membrane (by, i.e., increasing affinity of the IL-2 receptor for its ligand and/or stabilizing the IL-2 receptor).     

Production of lymphokines by circulating human T lymphocytes that express or lack receptors for interleukin 2

The capacity for circulating human T cells which have or lack receptors for interleukin 2 (IL 2) to produce IL 2, interleukin 3 (IL 3), and interferon-gamma (IFN-gamma) under the stimulus of phytohemagglutinin was studied. By using the monoclonal anti-Tac antibody which reacts against IL 2 receptors on human T cells, concanavalin A-treated T cells were separated into IL 2 receptor-positive (Tac+ T cells) and IL 2 receptor-negative (Tac- T cells) lymphocytes. The results show that Tac+ T cells secreted IL 2 and IFN-gamma but not IL 3. Tac- T cells produced IL 2 and IL 3 but not IFN-gamma. It is concluded that: 1) both T cells lacking and T cells having receptors for IL 2 produce IL 2, but only IL 2 receptor-negative T cells appear to secrete IL 3; and 2) virtually all of the T cells that produce IFN-gamma after PHA stimulation express receptors for IL 2.     

Proliferation of phenotypically immature human thymocytes with and without interleukin 2 receptors

Previous studies have indicated that the human thymus is composed of several discrete compartments. Cortical thymocytes are reactive with the monoclonal antibody anti-T6, whereas most medullary cells, unreactive with anti-T6, stain brightly with anti-T3, which defines mature T cell populations. Only a minor thymocyte population lacks both T3 and T6 but expresses T11 antigens. Within the thymus, several proliferating lymphoblasts are present. In addition a distinct subset shows the capacity to proliferate in response to mitogens. By continuous Percoll density gradient centrifugation, we have obtained a cell fraction comprising the vast majority of cells able to proliferate spontaneously or after PHA stimulation. By a panning procedure performed with anti-T3 and anti-T6 antibodies, three phenotypically distinct thymocyte subsets were separated from this fraction, and their functional capabilities were tested. The spontaneous proliferating activity was found to be mainly attributable to thymocytes unable to respond to mitogen, expressing the cortical T6 marker and lacking receptors for IL 2. T3-positive cells are able to respond to mitogen. However, these thymocytes are incapable of producing the adequate amount of IL 2 required to fully saturate their intrinsic proliferative capability. Surprisingly, the phenotypically least mature intrathymic T lymphocytes (T3 and T6 negative) respond to phytomitogen, at least in part, in an interleukin-dependent manner. It is noteworthy that a large proportion of these T3- and T6-negative thymocytes express IL 2 receptors and class II MHC antigens without in vitro activation. These novel findings have potential implications in the context of current models of differentiation pathways within the human thymus.     

Lyt-2+ cells. Requirements for concanavalin A-induced proliferation and interleukin 2 production

The requirements for inducing Lyt-2+ T cell proliferation in response to concanavalin A (Con A) were examined. Purified Lyt-2+ or L3T4+ spleen cells of C57BL/6 origin were stimulated with Con A and syngeneic macrophages (MO) in the presence of monoclonal antibodies to T cell markers or to polymorphic determinants on major histocompatibility complex molecules, and assessed for the ability to proliferate and to produce interleukin (IL) 2. alpha I-Ab failed to inhibit the Con A response of Lyt-2+ cells at dilutions that significantly inhibited the response of L3T4+ cells. In contrast, alphaKb/Db or alpha Lyt-2.2 specifically inhibited the response of Lyt-2+ cells, but not L3T4+ cells. The ability of alpha Kb/Db and of alpha Lyt-2.2 to inhibit the response of Lyt-2+ cells was dependent upon the concentration of Con A. These data demonstrate that optimal triggering of T cell subsets to proliferate and to produce IL-2 in response to Con A requires interactions with the appropriate restricting major histocompatibility complex molecule. The role of accessory cells in Lyt-2+ Con A-induced proliferation and IL-2 production was also investigated. Purified Lyt-2+ cells and purified L3T4+ cells failed to respond to Con A in the absence of MO. IL-1 reconstituted the response when MO were limiting, but failed to restore the response of either Lyt-2+ or L3T4+ cells when T cells were rigorously purified to remove all MO. These results demonstrate that triggering Lyt-2+ T cells, like L3T4+ T cells, requires accessory cells, and that this does not merely reflect a requirement for IL-1 production. Thus, Con A-induced proliferation and IL-2 production by Lyt-2+ T cells requires intimate contact with accessory cells and interactions dependent upon the class I-restricting element.     

Novel mechanism for Trypanosoma cruzi-induced suppression of human lymphocytes. Inhibition of IL-2 receptor expression

Co-culture of blood forms of Trypanosoma cruzi, the causative agent of Chagas' disease, with human PBMC impaired the capacity of T lymphocytes to express surface receptors for IL-2. This effect was evidenced by marked reductions in both the proportion of Tac+ cells and the density of Tac Ag on the surface of the positive cells, determined by flow cytometry. The extent of the inhibition increased with parasite concentration. Under optimal or suboptimal conditions of stimulation with either PHA or monoclonal anti-CD3, specific for an epitope of the T3-Ti human T cell Ag receptor complex, the presence of T. cruzi curtailed the capacity of T lymphocytes to proliferate and express Il-2R but did not affect IL-2 production. Furthermore, the addition of exogenous IL-2 did not restore the responsiveness of suppressed human lymphocytes but did when mouse lymphocytes were used instead. Therefore, unlike mouse lymphocytes, human lymphocyte suppression by T. cruzi did not involve deficient IL-2 production and was accompanied by impaired IL-2 utilization. Co-culture of human monocytes/macrophages with suppressive concentrations of T. cruzi increased IL-1 production, and the parasite did not decrease IL-1 secretion stimulated by a bacterial LPS. Therefore, the suppression of IL-2R expression and lymphoproliferation is not likely to have been an indirect consequence of insufficient IL-1 production due to infection of monocytes or macrophages. We have shown that suppression of human lymphocyte proliferation by T. cruzi is not caused by nutrient consumption, absorption of IL-2, lymphocyte killing, or mitogen removal by the parasite. Therefore, these results uncover a novel suppressive mechanism induced by T. cruzi, involving inhibited expression of IL-2R after lymphocyte activation and rendering T cells unable to receive the IL-2 signal required for continuation of their cell cycle and mounting effective immune responses.