Production of interleukin 2, interleukin 3, and interferon by mouse T lymphocyte clones of Lyt-2+ and -2- phenotype

T lymphocyte clones were derived by stimulation of positively selected Lyt-2+ and Lyt-2- lymphocytes with Con A in an Interleukin 2 (IL 2)-enriched medium under conditions of limiting dilution. Forty clones were expanded and tested, after activation by Con A, for the production of IL 2, IL 3, and interferon (IFN). Thirteen Lyt-2- clones were all co-producers of IL 2 and IL 3, and 10/13 were also producers of IFN. Twenty-seven Lyt-2+ clones were much more heterogeneous, 13 being IL 2 and IL 3 nonproducers, whereas 14 produced variable and poorly correlated amounts of IL 2 and IL 3. Three Lyt-2+ clones were observed to produce IL 2 or IL 3 alone. The majority of the Lyt-2- (10/13) and of the Lyt 2+ (21/27) clones were also producers of IFN. Exogenous IL 2 added during the activation of the Lyt-2+ by Con A did not enhance IL 3 production, whereas it did enhance IFN production by some but not all Lyt-2+ clones. Thus, among the T lymphocytes of the Lyt-2+ and -2- phenotypes there are cells capable of releasing IL 2, IL 3, and IFN. This supports the concept that these phenotypes are associated with antigen recognition rather than with cell functions, but it is apparent that the functional capacities of individual T cells, if accurately represented by their clonal progeny, are far from uniform.     

Independent regulation of granulocyte-macrophage colony-stimulating factor and multi-lineage colony-stimulating factor production in T lymphocyte clones

When murine T lymphocyte clones were cultured with purified recombinant IL 2, a dose-dependent increase in the production of granulocyte-macrophage colony-stimulating factor (GM-CSF) was observed. Whereas these clones produced both GM-CSF and multi-lineage CSF (multi-CSF) when cultured with concanavalin A, IL 2 induced the production of GM-CSF in the virtual absence of detectable multi-CSF. In addition, IL 2 synergistically enhanced the production of both GM-CSF and multi-CSF by some antigen- or Con-A-stimulated clones. Like Con-A-induced CSF production, GM-CSF production in the presence of IL 2 required protein synthesis but could occur in the absence of proliferation by the clone. Analysis of dose-response curves for stimulation of CSF production by Con A in the presence and absence of IL 2 suggested that Con A and IL 2 activated GM-CSF synthesis by different mechanisms. These results indicate that the coordinate production of two factors by a single T cell clone stimulated with Con A can be dissociated when the clone is stimulated with IL 2.     

Glucocorticoid inhibition of lymphokine secretion by alloreactive T lymphocyte clones

The effect of glucocorticoids on lymphokine production by T lymphocytes was examined by using long-term alloreactive T cell clones that secreted one or more of the lymphokines interleukin 2 (IL 2), interferon-gamma, macrophage-activating factor (MAF), and colony-stimulating factor when stimulated by an antigen or a mitogen. Production of all of these four lymphokines was inhibited when glucocorticoids were added at physiologic concentrations (10(-8) to 10(-6) M) to clones stimulated with concanavalin A (Con A). Clones were heterogeneous with respect to their sensitivity to glucocorticoid inhibition of MAF production; cytolytic clones were generally more resistant than noncytolytic clones. The glucocorticoid dexamethasone (Dex) and an IL 2-containing supernatant exerted opposing effects on clonal MAF production. Kinetics experiments showed that Dex inhibited MAF production by reducing the rate of secretion without causing a compensatory increase in the duration of secretion, whereas the IL 2 source increased the rate and the total amount of MAF secretion. Dex abrogated the effect of IL 2. Inhibition by Dex was apparent from the earliest time of detectable MAF production (about 4 hr after stimulation) and increased with longer exposure until production ceased (12 to 24 hr). Pre-exposure and removal of Dex before Con A stimulation also inhibited MAF release. Effects of Dex on lymphokine secretion by clones could be dissociated from effects on their growth in response to stimulator cells and IL 2. Factor production by the 16 clones tested was inhibited to some degree. Proliferation, however, by two of these clones (both cytolytic) was unaffected by Dex, whereas proliferation of two noncytolytic clones was strongly inhibited even in the presence of a saturating dose of IL 2.     

Characterization of a factor produced by human alloreactive T lymphocyte clones, active on the eosinophils and precursors of erythroid strains

Alloreactive T-cell clones obtained from cells infiltrating a human rejected kidney graft were shown to produce upon specific antigenic stimulation with interleukin 2, a factor triggering the proliferation of an interleukin 3 dependent murine cell line. The lymphokine responsible for this activity was a monomeric glycoprotein (MW = 41,000) exhibiting on one hand chemotactic as well as activating properties on murine and human eosinophils respectively, and on the other hand a burst promoting activity. Its biochemical and biological features strongly suggest that this factor cannot be likened to any known human lymphokine.     

Regulation of interleukin 2 receptor expression on murine cytotoxic T lymphocyte clones

We have previously reported that influenza virus-specific cytotoxic T lymphocyte (CTL) clones require antigen and exogenous growth factors for continued proliferation in culture. In this report we show that after stimulation with specific antigen, cloned CTL are capable of limited proliferation in response to interleukin 2 (IL 2) alone but with time these large blast-like cells revert to smaller, quiescent cells that are no longer responsive to IL 2. The IL 2-unresponsive CTL can not be driven to proliferate by supra-optimal concentrations of IL 2, and unresponsiveness correlates with decreased ability to absorb IL 2 from conditioned medium at 0 degrees C, suggesting that unresponsiveness is due to diminished IL 2 receptors. Stimulation of the unresponsive CTL with antigen leads to re-expression of the IL 2 receptor. Decreased absorbing capacity of the unresponsive cells could not be accounted for by their smaller surface area, and the IL 2-unresponsive cells seemed not to down-regulate all their immune functions, as they remained cytotoxic. These results provide a basis for the role of specific antigen in maintaining CTL clones in vitro. Furthermore, these results suggest that antigen-dependent CTL lines can be regulated and that antigen and IL 2 both play a role in their regulation.     

Detection of HLA-DR associated PLT determinants by alloreactive lymphocyte clones

This study deals with alloreactive T-cell clones which recognize cellular determinants associated with HLA-DR antigens. Two clones, CB55 and DS56, exhibited a PLT specificity that was perfectly associated with DR5. On the other hand, clones CB7, DS1 and HS1 showed PLT reactivity with approximately one-half of the DR5 positive cells and none of the DR5 negative cells, whereas clone MD4 largely reacted with the other half of DR5 positive cells. Another MLR culture generated two alloreactive clones DS6 and DS9 with PLT specificity for DR2. However, these clones did not respond to DR2 cells, which were also positive for the DR2-associated HLA-B7 and B18 antigens. Monoclonal antibody (mAb) inhibition studies showed heterogenous patterns, whereby monomorphic non-DR mAbs inhibited the DR2-associated PLT clones while the DR5-associated PLT clones were inhibited by different groups of anti-DR and non-DR mAbs. These observations suggest the existence of several lymphocyte-activating determinants associated with HLA-DR antigens. This diversity may be an important consideration in studies of the role of HLA-DR in immune mechanisms and transplant compatibility.     

T lymphocyte cloning from rejected human kidney allograft. Recognition repertoire of alloreactive T cell clones

We analyzed the recognition repertoire of 16 human alloreactive T cell clones (ATLC) derived from cells invading an irreversibly rejected kidney allograft. These clones, which specifically proliferated against the kidney donor B lymphoblastoid cell line, fell into two classes: CD4+ killers and CD8+ killers. Cytotoxic and proliferative activities of the ATLC were studied by using a panel of allogeneic cells sharing HLA specificities with kidney donor cells. Moreover, mAb recognizing monomorphic parts of HLA class I and class II molecules were used in blocking experiments of ATLC cytotoxicity. The results obtained from proliferative and cytotoxic assays were concordant. All ATLC investigated were directed against HLA molecules, and some clones were found to recognize HLA-B, -C, -DP, -DQ, or -DR products. All anti-HLA class I ATLC were CD8+, whereas both CD4+ and CD8+ ATLC were committed against HLA class II specificities. Nine of 16 ATLC were shown to react against serologically defined donor HLA determinants. These data indicate the recognition of HLA determinants in the course of an in vivo alloimmune response and particularly emphasize the role of HLA-C and DP loci products so far ignored in clinical transplantation.     

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.     

Secretion of colony-stimulating factors by T cell clones. Role in adoptive protection against Listeria monocytogenes

CSF have been postulated to be important mediators of host defenses. The current studies were undertaken to investigate the production of CSF by Listeria-specific, T cell clones and to assess the participation of CSF in anti-listerial host resistance. Listeria-specific L3T4+, Lyt-2- T cell clones were isolated and expanded by standard techniques. The clones themselves protected mice from listerial challenge when injected intravenously, and supernatants generated from Ag-stimulated clones were protective. In order to define factors important in the protection, supernatants from the clones were assayed for CSF by several in vitro assays. Total colony-stimulating activity was measured with a bone marrow colony-forming assay. T cell clones secreted 1000 to 2000 U/ml of colony-stimulating activity after 48 hours of stimulation with specific antigen. The relative amounts of the various CSF were determined by the capacity of supernatants to support proliferation of the factor-dependent cell lines FDCP-1 and 32D cl 3 in the presence and absence of specific anti-CSF antibodies. Results showed that most of the CSF activity was due to granulocyte-macrophage (GM)-CSF and IL-3. The role of GM-CSF in anti-listerial host resistance was assessed in two types of experiments. In one set of experiments GM-CSF activity was neutralized in the supernatants by addition of specific rabbit anti-GM-CSF antibodies. Treated and untreated supernatants were then tested for their capacity to protect nonimmune mice against listerial challenge. Neutralization of GM-CSF in the supernatants decreased the protective capacity of the supernatants by approximately 23%. In a second set of studies, the administration of recombinant murine GM-CSF was shown to protect mice from challenges of L. monocytogenes. Taken together, these experiments provide evidence that CSF are important mediators of immune T cell mediated host defenses.     

Growth of an interleukin 2/interleukin 4-dependent T cell line induced by granulocyte-macrophage colony-stimulating factor (GM-CSF)

Lymphokine activities in conditioned medium from activated helper T cell lines are most commonly defined by the proliferation of "specific" lymphokine-dependent cell lines. Various sublines of IL 2-dependent (and ostensibly specific) HT-2 and CTLL cells have now been shown to proliferate in response to BSF-1/IL 4 as well. After activation with antigen or mitogen, D10.G4.1, an antigen-specific cloned T helper cell that has recently been shown to produce IL 4 but not IL 2, secretes two distinct cytokines that induce the growth of HT-2 cells. These "T cell growth factors" (TCGF) can be separated by reversed phase high-performance liquid chromatography (RP-HPLC). The TCGF activity of one of these factors can be blocked by 11B11, an antibody specific for IL 4. The second TCGF activity is not affected by 11B11 or by antibodies specific for IL 2. This TCGF activity can be neutralized by a goat polyclonal antibody to granulocyte-macrophage colony-stimulating factor (GM-CSF), and has a RP-HPLC elution profile identical to that of recombinant GM-CSF. Recombinant GM-CSF induces both proliferation and long-term growth of HT-2 but not CTLL cells, and this activity can be neutralized by the same antibody to GM-CSF. GM-CSF is best known as a factor that induces the maturation and growth of granulocytes and macrophages from bone marrow-derived hematopoietic precursor cells. The ability of GM-CSF to induce the growth of certain T cell lines indicates that this molecule may play a role in T cell-mediated immune responses, either as an autocrine growth factor or a paracrine stimulus from both lymphoid and nonlymphoid tissues that produce this cytokine.     

Modulation of in vitro myelopoiesis by alloreactive T cell clones

Regulatory effects of mixed lymphocyte culture (MLC)-derived CD4+ human T cell clones on granulocyte-macrophage colony (CFU-GM) formation by normal bone marrow (BM) were studied in an initial attempt to establish an in vitro model for the negative feedback control of myelopoiesis by alloactivated T cells. This is likely to be of clinical significance in the aberrant control of haematopoiesis during some cases of graft-versus-host disease (GVHD) after allogeneic BM transplantation. Whilst 5 such alloproliferative clones generally failed to suppress CFU-GM, the majority of clones with natural killer (NK)-like activity, or those with suppressive activity in MLC, regularly and strongly suppressed in this system, reinforcing the view that certain T cells may have potent negative regulatory effects on haematopoiesis.     

The role of the T cell receptor, CD8, and LFA-1 in different stages of the cytolytic reaction mediated by alloreactive T lymphocyte clones

The cytotoxic reaction mediated by cytotoxic T lymphocytes (CTL) consists of three phases: first, the CTL binds to the target cell; next, the CTL is triggered to lyse the target cell; and in the third phase, the CTL detaches from the target cell which is lysed in the absence of the CTL. Recently, we obtained evidence that human alloreactive CTL clones initially adhere to target cells without the involvement of the interaction between the T cell receptor (Tcr) and its specific target antigen. In the present study, we investigated the effect of monoclonal antibodies specific for the Tcr on the cytotoxic reaction of three CD8+ HLA-A2-specific CTL clones, using a single cell assay in which the binding event can be distinguished from the post-binding (lytic) phase of the cytolytic reaction. It was found that monoclonal antibodies directed at a variable part of the Tcr do not affect the binding phase but strongly block the lytic phase of the cytotoxic reaction. An anti-constant region Tcr antibody and an anti-CD3 reagent had a similar effect on the two phases of the reaction as the anti-variable part Tcr antibodies. In contrast, antibodies specific for LFA-1 strongly blocked the adhesion phase but did not affect the lytic phase. Antibodies specific for CD-8 had intermediate effects. They could block both the adhesion as well as the lytic phase. The effect of anti-CD8 appeared to be dependent on the CTL clone tested. One clone was found to be inhibited in the adhesion phase, but not in the lytic phase, whereas anti-CD8 hardly blocked the adhesion phase of two other CTL clones, but affected the lytic step of those clones. Our data indicate that LFA-1 is a major adhesion molecule in the CTL reaction, whereas the Tcr/CD3 complex is implicated in a phase after the initial formation of conjugates. CD8 is associated with both steps in the cytolytic reaction. In addition to its minor role in the adhesion phase, our data suggest strongly that CD-8 is involved in the triggering phase of the cytolytic reaction.     

A soluble interleukin 2 receptor produced by a normal alloreactive human T cell clone binds interleukin 2 with low affinity

Several alloreactive human T cell clones derived from a rejected kidney graft were found to produce in their culture supernatants soluble interleukin 2 receptors (IL-2R) upon specific antigenic challenge (irradiated B cell line from the graft's donor). Among them, the 2B11, a high producer clone, was used to purify a soluble IL-2R preparation which was analyzed, in comparison with the high and low affinity cell-surface IL-2R expressed by 2B11 cells, for its parameters of interaction with a set of anti-IL-2R monoclonal antibodies (mAb) and IL-2. This soluble receptor purified by affinity chromatography (anti-IL-2R mAb column) and sodium dodecyl sulfate gel electrophoresis is composed of a single chain of 35,000 to 45,000 Da. Immunoradiometric assays (IRMA) at equilibrium were set up, using pairs of mAb directed against two separate epitopes on the Tac antigen of the human IL-2R, to measure the respective dissociation constant of these mAb for the soluble IL-2R. They were found to be identical to those found on the cell-surface IL-2R. A 1:1 stoichiometry between the two epitopes were found both on the membrane and soluble species. Competition experiments between membrane and soluble IL-2R for binding the mAb allowed the quantitative analysis of the concentration of soluble IL-2R without the need of amino acid analysis on purified material and set up a quantitative IRMA for the human soluble IL-2R (detection limit 5 pM). The affinity of the soluble IL-2R for IL-2 was determined by various techniques including an IRMA using an anti-IL-2R mAb and radiolabeled IL-2. The results obtained led us to conclude that the soluble IL-2R binds IL-2 with a dissociation constant (KD = 30 nM) identical to that found for the binding of IL-2 to low affinity cell-surface IL-2R (Tac antigen). Whereas 2.5% of cell-surface IL-2R expressed 2 days after antigenic stimulation of 2B11 cells were of high affinity for IL-2 (KD = 25 pM), no (less than 0.07%) high affinity binding sites could be detected on the purified soluble IL-2R. This soluble IL-2R therefore likely corresponds to a truncated, extracellular part of the membrane Tac antigen. The amounts of soluble Tac antigen produced by the 2B11 alloreactive human T cell clone did not exceed 1 nM and, as expected from the binding studies, did not affect IL-2-induced T cell proliferation. The physiologic and pathologic implications of our results are discussed.     

Association of PLT specificity of alloreactive lymphocyte clones with HLA-DR,MB and MT determinants

The HLA-D region encodes for several serologically defined systems, including DR, MB, and MT. The antigens of MB and MT are strongly associated with two or more DR specificities. The purpose of this study was to determine the role of MB and MT antigens in lymphocyte alloactivation. A soft agar colony assay was used to generate alloreactive lymphocyte clones primed in mixed leukocyte culture against a stimulator who typed as HLA-DR4,-;MB3,-; MT3,-. In secondary primed lymphocyte typing (PLT) assays, several clones were identified with PLT specificities strongly associated with DR4, MB3, or MT3. The data suggest that HLA-D controls different lymphocyte-activating determinants associated with the serologically defined DR, MB, or MT antigens.     

Suppression of alloimmune cytotoxic T lymphocyte (CTL) generation by depletion of NK cells and restoration by interferon and/or interleukin 2

By using rabbit antiserum to a glycolipid, ganglio-n-tetraosylceramide (ASGM1), the accessory effect of natural killer (NK) cells on the generation of alloimmune CTL in mice was investigated. When normal C3H/He mice were immunized with C57BL/6 or BALB/c spleen cells, they generated alloimmune CTL with a surface marker phenotype of Thy-1+ Lyt-1-2+ ASGM1-, preceded by early augmentation of cytotoxic activity of NK cells with a Thy-1-Lyt-1-2-ASGM1+ phenotype. Administration of anti-ASGM1 (10 microliters) in mice resulted in a complete depletion of NK activity and ASGM1+ cells in the spleen even 1 day after injection, but no changes in the proportions of T (Thy-1+) cells and their Lyt-1 and Lyt-2 subsets as revealed by an immunofluorescence analyzer (FACS) and phagocytic cells. When these anti-ASGM1-treated mice were immunized with allogeneic cells, they showed neither augmented NK activity nor generation of alloimmune CTL, and spleen cells isolated from these anti-ASGM1-treated mice produced no CTL response to alloimmunization in vitro. Normal spleen cells treated with the antiserum and complement in vitro also showed a complete NK depletion without any deterioration of T cells and their Lyt-1 and Lyt-2 subsets, and when stimulated with allogeneic cells they generated no CTL. Spleen NK (ASGM1+) cells were purified by Percoll-gradient centrifugations followed by complement-dependent killing of T cells with the use of anti-Thy-1 monoclonal antibody, and were further purified by panning methods with anti-ASGM1, giving a preparation consisting of greater than 90% ASGM1+, Ly-5+ cells, and less than 0.5% of Thy-1+, Lyt-1+, and Lyt-2+ cells. These purified ASGM1+ Thy-1- cells alone generated no alloimmune CTL in response to alloantigens, suggesting that ASGM1+ NK cells contained no precursors of alloimmune CTL. When added into NK-depleted spleen cells, they restored the normal alloimmune CTL response of the spleen cells, indicating that ASGM1+ fractions contained cells to provide an accessory function for CTL generation. Lyt-1+ cells purified by panning methods did not restore the CTL response of NK-depleted spleen cells. These results indicate that ASGM1+ NK cells, but not Lyt-1+ helper T cells contaminating ASGM1+ fractions at undetectable levels, are responsible for the accessory function. When these purified ASGM1+ Thy-1- cells were stimulated with allogeneic cells, they produced IL 2 and IFN.(ABSTRACT TRUNCATED AT 400 WORDS)     

Murine T helper cell clones secrete granulocyte-macrophage colony-stimulating factor (GmCSF) by both interleukin-2-dependent and interleukin-2-independent pathways

Granulocyte-macrophage colony-stimulating factor (GmCSF) is a lymphokine secreted by class II major histocompatibility complex (MHC)-restricted T cells after lectin or antigen stimulation. To investigate the relationship between interleukin-2 (IL-2) and GmCSF production, we utilized long-term cultures of porcine myelin basic protein (PMBP)-specific T helper cell clones that were maintained with IL-2 in the absence of antigen or irradiated antigen-presenting cells (APC). We have found that supernatants of these T cell clones contained GmCSF activity after IL-2 stimulation. Inhibition of cell proliferation by irradiation failed to stop GmCSF production. When these clones were stimulated with PMBP and irradiated APC in the presence of anti-IL-2 receptor antibody, the T cell supernatants still contained GmCSF activity. These results indicate that (1) GmCSF production by T helper clones after IL-2 stimulation is independent of cell proliferation and (2) antigen/MHC-stimulated GmCSF production by T cell clones can occur by an IL-2-independent pathway.     

Regulation of the production of immune interferon and cytotoxic T lymphocytes by interleukin 2

The activation of alloantigen-specific cytotoxic T lymphocyte precursors is dependent upon the presence of both macrophages and helper T cells or regulatory molecules derived from these facilitative cells. Three biochemically distinct helper factors have been identified: interleukin 1 (macrophage-derived), Interleukin 2 (T cell derived), and immune interferon. All 3 factors are found in supernatants of mixed lymphocyte cultures (MLC), however, the removal of macrophages from these cultures completely ablates the production of these factors as well as the induction of cytotoxic T lymphocytes (CTL). The addition of IL 2 to these macrophage-depleted MLC restores the ability of responder T cells to: 1) bypass the requirement for macrophage soluble function, 2) produce immune interferon, and 3) generate CTL. The kinetics and dose response of immune interferon production in response to IL 2 correlates with the generation of CTL. The production of immune interferon as well as the generation of CTL requires T cells, alloantigen, and IL2. Furthermore, the induction of CTL by IL2 was neutralized by the addition of anti-immune interferon. These data suggest that: 1) the regulation of immune interferon production is based on a T to T cell interaction mediated by IL 2, and 2) immune interferon production may be required for IL 2 induction of CTL. These findings are consistent with the hypothesis that the induction of CTL involves a linear cell-factor interaction in which IL 1 (macrophage-derived) stimulates T cells to produce IL 2, which in turn stimulates other T cells to produce immune interferon and become cytotoxic.     

Abnormal migration of T lymphocyte clones

Several in vitro T cell clones were markedly deficient in their ability to home to peripheral lymphoid tissue. This was found for an alloreactive noncytolytic clone, a soluble antigen- (KLH)specific line, and cytotoxic clones specific for allogeneic cells and for Abelson virus-induced lymphoma cells. This abnormal circulation pattern was probably caused by the lack of the receptors of the lymphocytes for high endothelial venules (HEV), as implied by the lack of binding of these T cells to HEV in frozen sections of mouse lymph node and Peyer's patches. The loss of surface receptors that are necessary for normal lymphocyte migration may thereby alter the in vivo function of adoptively transferred T cells.