Different antigen-presenting cells differ in their capacity to induce lymphokine production and proliferation of an apo-cytochrome c-specific T cell clone

The activation of an apo-cytochrome c-specific T cell clone was found to differ, depending on the antigen-presenting cell population. Whereas total syngeneic spleen cells and bone marrow macrophages could be shown to trigger proliferation, IL 2, and MAF production by the T cell clone, a B cell lymphoma only induced MAF secretion. Further studies demonstrated that this effect was not due to a different antigen processing by the B lymphoma or to limiting amounts of Ia and antigen molecules on the B lymphoma cell surface. The dissociation of induction of MAF production from IL-2 production/proliferation found with the different antigen-presenting cells indicates strongly that molecules other than Ia and antigen may be required for the complete functional activation of antigen-specific T cell clones.     

Cytolytic T lymphocyte clones that proliferate autonomously to specific alloantigenic stimulation. II. Relationship of the Lyt-2 molecular complex to cytolytic activity, proliferation, and lymphokine secretion

Previous analyses of the inhibitory effects of anti-Lyt-2 monoclonal antibodies (mAb) on cytolytic activity suggested that Lyt-2/3 antigens expressed on the surface of murine cytolytic T lymphocytes (CTL) are involved in antigen recognition. In the present study, we investigated the effects of anti-Lyt-2 mAb (in the absence of complement) on the functional activities of H-2K/D-specific Lyt-2+ CTL clones that proliferate to antigenic stimulation in the absence of helper T cells or added interleukin 2 (IL 2) and secrete lymphokines. For those clones that were inhibited in cytolysis by anti-Lyt-2 mAb, a parallel inhibition of antigen-dependent proliferation and lymphokine secretion (interferon, macrophage-activating factor) was observed. Inhibition of proliferation or lymphokine secretion could be overcome by the addition of IL 2 or lectin, respectively. Collectively, these results would strongly suggest that anti-Lyt-2 mAb were inhibiting CTL antigen recognition. Not all CTL clones, however, were inhibited in cytolysis by anti-Lyt-2 mAb, in which case proliferation and lymphokine secretion were similarly unaffected. This heterogeneity of Lyt-2+ CTL clones in their susceptibility to inhibition of cytolytic activity, proliferation, and lymphokine secretion by anti-Lyt-2 mAb is discussed in the context of a model proposing that Lyt-2/3 molecules function to stabilize the interaction between CTL receptors and the corresponding target/stimulating cell antigens. Such a stabilization may be required by CTL possessing few and/or low affinity receptors.     

Immunodeficiency in graft-versus-host disease (GVHD). II. Effects of GVHD-induced suppressor cells on CD4+ T cell clones

Lethally irradiated mice transplanted with H-2-matched, minor histocompatibility-disparate bone marrow develop graft-vs-host disease (GVHD) that is associated with severe immunodeficiency. Splenocytes from such mice contain radioresistant cells that profoundly suppress normal lymphocyte function. We now show that GVHD-induced suppressor cells also inhibit the proliferation of CD4+ T cell clones specific for different Ag and class II MHC determinants. These suppressors have a dominant anti-proliferative effect, because they inhibit DNA synthesis in response to receptor-mediated stimulation and growth-promoting lymphokines, without abolishing lymphokine secretion or lymphokine receptor expression by the cloned T cells. The implications of these findings, and the usefulness of T cell clones for studying immune suppression, are discussed.     

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.     

Monoclonal antibody recognizes a conformational epitope in a random coil protein

The antigenic determinants for two monoclonal antibodies directed against horse apo-cytochrome c, a protein of disordered structure, as judged by spectroscopic and hydrodynamic criteria, have been studied by a combination of methods: antigen competition in solution by radio immunoassay and enzyme-linked immunoassay, and differential acetylation of free and antibody-bound antigen. In the latter method the accessibility of lysine residues of the antigen in the antigen-antibody complex is compared to the accessibility in the free antigen. The two antibodies against the heme-free protein do not recognize intact native cytochrome c, but they crossreact with the heme-containing peptides 1-38 and 1-65 of cytochrome c. The antigenic determinant recognized by monoclonal antibody SJL 2-4 is conformational and discontiguous, it is composed of residues close to the N-terminus and around position 25. The other monoclonal antibody, Cyt-1-59, seems to recognize a contiguous epitope close to the N-terminus. The present results show that even a seemingly disordered protein which is conventionally classified as a random coil may feature subtle spatial regularities. The presence of ordered conformational elements in apocytochrome c may be important for the enzyme-catalyzed covalent attachment of the heme and the import of cytochrome c into mitochondria. A discontiguous determinant for SJL 2-4 is particularly interesting because this antibody inhibits the proliferation of a T-cell clone specific for apo-cytochrome c [Corradin & Engers (1984) Nature (Lond.) 308, 547-548].     

Effects of monoclonal antibodies directed against murine T lymphocyte cell surface antigens on lymphokine production by cloned T lymphocytes reactive with class I MHC or Mls alloantigens

Monoclonal antibodies recognizing murine T lymphocyte cell surface structures implicated in T lymphocyte-mediated cytolysis, including Lyt-2, L3T4, LFA-1, and a cytolytic T lymphocyte (CTL) clonotypic determinant, were used as probes to investigate the role of these structures in lymphokine production by T cell clones induced by antigen or lectin. The clone-specific antibody 384.5 bound to and inhibited antigen-induced lymphokine production by the L3 CTL clone, but did not affect lymphokine production by other T cell clones. Antibodies against the T cell surface structures Lyt-2 or L3T4, which are expressed by mutually exclusive T cell subsets, inhibited antigen-induced lymphokine production by class I major histocompatibility complex (MHC) antigen-reactive CTL clones or an M1s-reactive helper T lymphocyte (HTL) clone, respectively. Antibody against the broadly distributed LFA-1 molecule inhibited antigen-induced lymphokine production by all of the clones tested. Lectin-induced lymphokine production by cloned T cells was not inhibited by the clonotypic antibody, anti-Lyt-2, or anti-LFA-1; slight inhibition of the HTL clone was observed with the anti-L3T4 antibody. None of these structures appear to be uniquely involved with a particular functional response. Our results suggest that each of these structures is involved with the interactions between the effector cell and the stimulating cell leading to lymphokine production.     

Differential effects of poly (Glu60, Phe40) (GPhe) on murine TH1 and TH2 cells.

The random amino acid copolymer (Glu60, Phe40)n (GPhe) was previously shown to augment antigen-dependent proliferation of the murine TH2 cell lines DCL-2 and D10.G4.1. In the present study, the addition of GPhe to (Glu36, Lys24, Ala40)n (GLA)-primed BALB/c primary lymph node (1 degree LN) T cell cultures, the source of DCL-2, resulted in significant suppression of both the proliferative and lymphokine response to GLA. Suppression by GPhe of the 1 degree LN response was subsequently shown to be neither antigen- nor haplotype restricted, and was inhibitable by polyclonal anti-GPhe antibodies. Studies were extended to a GLA-reactive T cell hybridoma clone (DL.4G6.1). where significant suppression by GPhe of GLA-stimulated lymphokine production was observed as measured by markedly decreased HT-2 stimulatory activity of the collected supernatants. Subsequent antibody blocking experiments employing the monoclonal anti-murine IL-4 antibody 11B11 revealed that BALB/c GLA-reactive 1 degree LN T cells and DL.4G6.1 did not produce detectable levels of IL-4 in their culture fluids when stimulated by GLA, which suggested that these cells, unlike DCL-2, were TH1-like in nature. The addition of GPhe to the TH1 clones 5.2 and 5.9 resulted in significant suppression of proliferation to homologous antigen (ovalbumin), in contrast to the augmentation observed with the TH2 cell lines DCL-2 and D10.G4.1. It was concluded from these data, that the addition of GPhe to various T cell cultures lead to unusual suppressive and augmenting activities specific for TH1 and TH2 cells, respectively. Although the mechanism for these dichotomous effects of GPhe is as yet undetermined, several possibilities are considered.     

Antibodies to the L3T4 and Lyt-2 molecules interfere with antigen receptor-driven activation of cloned murine T cells

When L3T4+ cloned murine helper T lymphocytes (HTL) are stimulated with antigen or immobilized anti-T cell receptor (TCR) monoclonal antibodies (mAb) at concentrations which are optimal for proliferation, anti-L3T4 mAb inhibits activation as measured by proliferation and lymphokine production. Under similar conditions, IL 2-independent proliferation of Lyt-2+ cloned murine cytolytic T lymphocytes (CTL) stimulated by anti-TCR mAb is inhibited by anti-Lyt-2 antibodies. Proliferation of cloned HTL and CTL cells stimulated by IL 2 is not affected by the anti-L3T4 and anti-Lyt-2 mAb. The inhibition of TCR-induced activation of the T cell clones is not due to interference with the binding of the anti-TCR mAb. Stimulation of the TCR has been proposed to induce lymphokine secretion and proliferation by T cells through a pathway involving the activation of protein kinase C and the stimulation of an increase in the concentration of intracellular free calcium. However, proliferation of T cells stimulated by PMA (which activates protein kinase C) plus the calcium ionophore A23187 (which increases the concentration of intracellular free calcium) is not affected by mAb reactive with the Lyt-2 or L3T4 structures. If TCR stimulation does indeed activate T cells by activating protein kinase and increasing intracellular free calcium, then our data suggest that anti-L3T4 and anti-Lyt-2 mAb inhibit TCR-driven proliferation at some step before the activation of protein kinase C and the stimulation of a rise in intracellular free calcium concentration. Our results suggest that anti-L3T4 and anti-Lyt-2 mAb interfere with early biochemical processes induced by stimulation of the TCR. In HTL, which proliferate via an autocrine pathway, anti-L3T4 mAb appears to inhibit proliferation by interfering with signaling events involved in lymphokine production. Inhibition of IL 2-independent proliferation of Lyt-2+ cells by anti-Lyt-2 mAb appears to occur by a different mechanism. The precise molecular basis for the interference of each cell type has not yet been characterized.     

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.     

Selective activation of helper and cytolytic T-cell functions of L3T4+ clones with either antireceptor antibody or phorbol ester and ionophore

After activation with specific antigen and antigen presenting cells (APC) L3T4+ inducer T-cell clones can lyse Ia+ APC. The present study characterizes the mechanism of activation and specificity of L3T4+ inducer cell-mediated cytolytic function. Two methods that bypass the physiological stimulus of antigen presented on Ia+ APC were used to activate L3T4+ clones. The first method utilized an antireceptor monoclonal antibody (MAb), KJ16.133, to activate KJ16.133+ clones. The activated clones expressed nonspecific cytolytic activity, killing target cells irrespective of their H-2 haplotype or their ability to express cell surface Ia molecules. The crosslinking of bound KJ16.133 antibody greatly enhanced cytolytic activity. This activation is receptor specific because KJ16.133- clones were not activated under identical conditions. The second method of activation was provided by a synergistic action of phorbol-12-myristate-13-acetate (PMA) and ionophore A23187. These agents nonspecifically activated all L3T4+ clones tested. The simultaneous presence of the two agents is required for maximal activation. Again, the activated clones expressed potent nonspecific cytolytic activity. These observations demonstrated that L3T4+ inducer T-cell-mediated killing can be separated into two stages: an activation step, which can be specifically and nonspecifically triggered and an effector phase which causes nonspecific lysis of bystander targets. The induction of nonspecific cytolytic activity by antireceptor MAb was inhibited by anti-L3T4 MAb (GK1.5). In contrast, activation of nonspecific cytolytic activity by treatment with PMA plus A23187 was not inhibited by anti-L3T4 MAb. Under the above activation conditions, antireceptor MAb selectively induced the secretion of IL-3 and expression of nonspecific cytolytic activity. However, there was little or no concomitant proliferation and production of IL-2. In contrast, activation by PMA plus A23187 coordinately induces expression of nonspecific cytolytic activity, secretion of lymphokines (IL-3 and IL-2), and cell proliferation. Thus, the anticlonotypic activation preferentially induces certain functions whereas activation with PMA plus A23187 is not selective.     

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.     

Prostaglandin E2-dependent induction of granulocyte-macrophage colony-stimulating factor secretion by cloned murine helper T cells

PG are known to inhibit T cell proliferation, at least in part by suppressing IL-2 production, but effects of PG on the production of other lymphokines have not been well studied. We have found that PGE2 and PGE1, but not PGF2 alpha, inhibit both proliferation and production of granulocyte-macrophage (GM)-CSF by murine TH clones stimulated with Ag or anti-CD3 antibody. Thus, signals generated via the Ag receptor:CD3 complex were inhibited by PGE. Most interesting, however, was the finding that PGE2 and PGE1 could act synergistically with IL-2 for the induction of GM-CSF in some TH1 clones. Dependence on PGE2 for this response was not found in all clones, as some TH1 cells could produce GM-CSF after IL-2 alone, and some cells did not produce GM-CSF even in the presence of PGE2 and IL-2. These observations indicate that there is a subset of TH1 cells receptive to a stimulating activity of PGE2 in the presence of IL-2. PGE2 is known to elevate cAMP levels in T cells. Therefore, we tested whether other agents known to increase cAMP, such as forskolin and cholera toxin, could act in conjunction with IL-2 to induce GM-CSF secretion. As was found with PGE2, these compounds also induced GM-CSF activity in the presence of IL-2, suggesting a critical role for cAMP in this process. Overall these data indicate that the requirements for activation of GM-CSF secretion vary among individual T cells. Most importantly they provide the first evidence that E-series PG are positive signals for lymphokine induction in certain T cells, whereas simultaneously acting as negative signals limiting proliferation. This result also suggests that treatment with anti-inflammatory drugs that decrease PGE2 concentrations may inhibit lymphokine secretion normally stimulated by this pathway.     

In vitro T cell-mediated killing of Pseudomonas aeruginosa. IV. Nonresponsiveness in polysaccharide-immunized BALB/c mice is attributable to vinblastine-sensitive suppressor T cells

We reported previously that BALB/c mice immunized with a polysaccharide (PS) antigen isolated from immunotype 1 Pseudomonas aeruginosa and vinblastine sulfate develop T cell-mediated protective immunity, despite their failure to produce specific antibody. In vitro, Lyt-1-,2+, I-J+ T cells from vinblastine- and PS-immunized mice kill P. aeruginosa by secretion of a bactericidal lymphokine. BALB/c mice immunized with PS alone generate neither protective antibodies nor a protective T cell response. The current studies indicate that T cells from mice immunized with PS alone significantly suppress the bactericidal activity of T cells from mice immunized with vinblastine and PS. The suppressor T cells are of the same Lyt-1-,2+, I-J+ phenotype as the bactericidal T cells. Suppression is mediated by a soluble product of these suppressor T cells which both inhibits T cell proliferation and interferes with the production or release of the bactericidal lymphokine. Cyclophosphamide, used in other systems to remove suppressor T cells, fails to enhance bacterial killing and does not inhibit suppressor cell activity. These studies indicate that immunization with PS elicits responses in two functionally distinct subgroups of Lyt-1-,2+, I-J+ T cells, and that these cells are distinguishable by their sensitivity to vinblastine sulfate.     

Functional heterogeneity of CD4-positive T-cell subsets: the correlation between effector functions and lymphokine secretion is limited

Several effector functions and the lymphokine secretion pattern of 30 antigen-specific CD4+ T-cell clones have been investigated. The clones were generated directly by limiting dilution cloning of nylon wool-purified T-cells obtained from KLH immunized BALB/c mice and avoiding an initial bulk culture phase. Using this approach the CD4+ T-cell clones were grouped into helper and nonhelper subsets. Among the helper subset, clones which helped B-cells for specific antibody production by either cognate or noncognate recognition were identified. Some but not all of these helper clones fitted into the Th1 and Th2 scheme, if the lymphokine secretion pattern was evaluated. Among the nonhelper subset CD4+ clones which killed activated APC in a MHC class II-restricted and antigen-specific manner were identified. In addition, one clone which suppressed B-cell antibody production mediated by helper clones was found. However, neither the suppression of antibody responses nor the inability of the nonhelper clones to help B-cells is due to the killing of B-cells. Various attempts were made to convert nonhelper into helper clones and helper into killer clones, without success. Thus, the functional properties of these clones are stable traits and not convertible by varying the experimental conditions.     

Antigen-specific, MHC-restricted B cell activation by cell-free Th2 cell products. Synergy between antigen-specific helper factors and IL-4

Ag-specific and MHC-restricted Th clones of different Ag specificities and MHC haplotypes were tested for their ability to produce soluble factors capable of providing the signals required for B cell activation and IgG antibody production. Each of five Th clones tested generated significant helper activity in supernatants derived from coculture of the T cell clone with specific Ag and syngeneic APC. The same helper activity was detected in supernatants of clones stimulated with immobilized anti-CD3 antibody in the absence of Ag or APC. The secreted helper activity resembled the activity of the intact Th cells in that it was Ag-specific, carrier-hapten-linked and MHC-restricted. These T cell products functioned to activate only those B cells expressing MHC products which corresponded to the specificity of each Th clone. Thus, the specificity of the cell-free T cell product mimicked precisely that expressed by the intact Th cell and presumably mediated by the cell surface TcR. In addition to the apparent presence of specific helper factor in Th clone supernatants, a role for nonspecific lymphokines was also identified in these preparations. Although recombinant or purified IL-4 alone was not sufficient to stimulate hapten-primed B cells to secrete hapten-specific IgG antibodies, mAb specific for IL-4 blocked the induction of antibody secretion by Th cell supernatant. These results indicate that stimulation of B cells to produce hapten-specific IgG antibody requires at least two distinct signals: an Ag-specific T cell signal which is restricted by MHC products expressed on the B cells, and a nonspecific signal mediated at least in part by the lymphokine IL-4.     

Suppression of antibody synthesis by CD4+ T cell clones and normal T cells stimulated with monoclonal anti-CD3 antibody

CD4+ve Th1 clones, as well as normal splenic T cells, were found to suppress LPS-driven antibody secretion in a non-Ag-specific and non-MHC-restricted manner when the T cells were activated with the anti-CD3 mAb, 145-2C11. Suppression was observed with both primed and naive B cells, as well as with purified hapten-specific B cells, a result that suggests a direct effect of anti-CD3-activated T cells on B cell differentiation. Th1 clones activated by cognate Ag also suppressed LPS-driven antibody secretion. Furthermore, suppression of LPS-driven antibody secretion could be achieved across a cell-impermeable porous membrane when T cells were activated with anti-CD3. Suppression by Th1 clones and by normal T cells could not be attributed to a concomitant decrease in B cell proliferation or to a shift in the kinetics or isotype of the antibody response. These data demonstrate that CD4+ve Th1 clones, as well as normal T cells, can effect suppression of polyclonal antibody formation.     

Characterization of murine T cell activation signals produced by B lymphoma cells

The activation requirements of alloreactive and antigen reactive murine T cells were examined by stimulating class II restricted T cell clones with monoclonal B lymphoma cells. One B lymphoma cell line (T27A) was found to stimulate IL 2 release from some alloreactive T cell clones without stimulating any significant T cell proliferation response. The same B lymphoma cells are capable of stimulating IL 2 release and proliferative responses from other T cell clones. Evidence is presented suggesting that B lymphoma cell stimulation of these T cell clones is largely IL 1 independent and that at least some T cell clones may require activation signals other than Ia, antigen, and IL 1. The addition of exogenous, purified IL 1 to the T cell activation assays was found to have a wide range of stimulatory effects on the proliferative responses of different T cell clones. The absence of comparable IL 1-induced stimulation of IL 2 secretion suggests that IL 1 primarily enhances antigen specific T cell proliferation through mechanisms other than acting as a co-stimulant for IL 2 release.     

Inhibition of B lymphocyte activation by interferon-gamma

Helper/inducer T cell clones specific for protein antigens and class II MHC determinants consist of two nonoverlapping subsets. One (called Th1) secretes IL 2 and IFN-gamma and the other (Th2) produces BSF1 upon stimulation with antigen or polyclonal activators. By using hapten-binding normal B cells and the B lymphoma line WEHI-279 as assays for B cell helper (maturation) factors, we have shown that Th2 clone supernatants (SN) induce differentiation to antibody secretion, whereas Th1 SN do not. The failure of Th1 SN to activate B cells is due to inhibitory effects of IFN-gamma, because it can be reversed by a neutralizing monoclonal antibody specific for IFN-gamma. Thus, in the presence of this antibody, even Th1 SN stimulate B cell maturation maximally. Conversely, recombinant IFN-gamma inhibits proliferation and differentiation of B cells induced by active Th2 SN. These results demonstrate that IFN-gamma is a potent inhibitor of B lymphocyte activation and can be distinguished from growth and maturation-inducing helper factors that are produced by both subsets of helper T cells.     

IgM induction in murine B hybridomas with Ia-restricted T cell clones: a monoclonal model for T and B cell interactions in antibody response

The mechanism of MHC-restricted T and B cell interactions in antibody response was studied with IgM-inducible B hybridomas and antigen-specific helper T cell clones. B hybridomas were prepared by fusion between splenic B cells from (CBA/N (H-2k) X BALB/c (H-2d)) F1 (NBF1) male mice and a B lymphoma cell line, M12.4.5. A B hybridoma clone, 1M70, which expressed I-Ad but not I-Ak determinants was chosen in the present study. IgM secretion was induced in 1M70 when it was cocultured with a "resting" KLH-specific and H-2d restricted helper T cell clone in the presence of KLH. A "resting" KLH-specific and H-2k restricted T cell clone did not induce IgM secretion in 1M70 even in the presence of KLH. However, when these KLH-specific T cell clones were activated by KLH and appropriate antigen presenting cells, both H-2d and H-2k restricted T cell clones induced IgM secretion in 1M70 even in the absence of KLH. A monoclonal anti-I-Ad antibody inhibited IgM secretion induced by a "resting" H-2d restricted T cell clone, but not by an "activated" T cell clone. These results indicated that T cell clones recognized antigens in the context of Ia molecules on B hybridomas in a MHC-restricted manner and were activated to produce B cell stimulatory factors which in turn acted on B hybridomas in a non-MHC-restricted manner and induced differentiation of B hybridomas into IgM secreting cells.