Human suppressor T cells induced by concanavalin A: suppressor T cells belong to distinctive T cell subclasses.

Human peripheral blood lymphocytes were stimulated by concanavalin A (Con A) and then evaluated by their suppressive activity for thymus-derived (T) cell- and bone marrow-derived (B) cell-proliferative responses to mitogen and allogeneic cells. Con A-activated T cells markedly suppressed these responses, but Con A-activated B cells failed to demonstrate suppressor activity. Discontinuous bovine serum albumin (BSA) density gradient separation of T cells which had been activated by Con A demonstrated that a fraction containing blast cells as well as fractions containing unproliferated cells manifest the same degree of suppressor capabilities. However, when density gradient separation of T cells followed by subsequent incubation with Con A was performed, fractions of proliferating cells of low density exhibited no suppression; a fraction containing high density T cells produced marked suppression, but this fraction incorporated only little thymidine in response to Con A. Thus, these studies indicate that Con A-induced suppressor T cells belong to a distinctive subpopulation which has already been programmed to express this function before exposure to Con A and that cell proliferation may not be a prerequisite for the development of such suppressor T cells.     

The role of the 2H4 molecule in the generation of suppressor function in Con A-activated T cells

The molecular basis for the suppression generated in a concanavalin A (Con A)-activated T cell culture remains unknown. In this study, we have attempted to determine whether the 2H4 and 4B4 molecules on Con A-activated T cells play some role in the generation of suppression by such cells. We have shown that Con A-activated suppressor cells belong to the 2H4+ subset of T cells but not the 4B4+ (2H4-) subset. Con A-activated T cells exerted their optimal suppressor function on day 2 in culture, a time at which the expression of 2H4 on such cells was maximal and 4B4 was minimal. Furthermore, the stimulation of T cells with the higher concentration of Con A generated the stronger suppressor function. At the same time, both 2H4 expression and density were increased and 4B4 expression and density were decreased on such Con A-activated T cells. More importantly, the treatment of Con A-activated T cells with anti-2H4 antibody but not with anti-4B4, anti-TQ1, or anti-T4 antibodies can block the suppressor function of such cells. Taken together, the above results strongly suggest that the 2H4 molecule itself may be involved in the generation of suppressor function in Con A-activated T cells. The 2H4 antigen on such cells was shown to be comprised of 220,000 and 200,000 m.w. glycoproteins. Thus this study indicates that the 220,000 and 200,000 m.w. structure of the 2H4 molecule may itself play a crucial role in the generation of suppressor signals of Con A-activated cells.     

Deficiencies in suppressor T cell activity seen in patients with active systemic lupus erythematosus are due to the dilution of normally functioning suppressor T cells by nonsuppressor T cells

Concanavalin A (Con A)-activated T lymphocytes from patients with active, but not inactive, systemic lupus erythematosus (SLE) failed to express normal suppressor activity, regardless of the phenotype of CD4+ or CD8+. Con A-activated CD4+ or CD8+ T lymphocytes from the SLE patients and from normal controls were further separated into two populations, using the autologous erythrocyte rosette technique. One population very rich in cells capable of forming rosettes with autologous erythrocytes from the active patients showed the same degree of suppressor activity, as did that from normal controls; the CD4+ or CD8+ population poor in autorosetting cells derived from Con A-activated T lymphocytes from both the controls and patients did not express suppressor activity. Moreover, when autorosetting T cells from the active patients and nonrosetting cells from the same patients were mixed at a normal ratio (4:6), normal suppressor activity could be restored. It was notable that the frequency of autorosette-forming cells was markedly reduced in the Con A-activated T lymphocytes from the active, but not inactive, SLE patients, regardless of the phenotype of CD4+ or CD8+. These findings indicate the presence of a normally functioning suppressor T cell population in patients with active SLE. It seems that the lack of suppressor T cell function in patients with active SLE is due to the dilution of a few normal suppressor T cells by large numbers of nonsuppressor T lymphocytes.     

Developmental changes in humoral suppressor activity released from concanavalin A-stimulated human lymphocytes on B cell differentiation

Cell-free culture supernatants (Con A-activated supernatants) were obtained by incubating peripheral blood lymphocytes (PBL) from cord blood, healthy children of various ages, and healthy adults with mitogenic doses of concanavalin A (Con A) for 48 hr. It is well known that human T lymphocytes are activated by Con A to manifest suppressor function in vitro. One mechanism whereby these suppressor cells act has been shown to be by the secretion of a soluble suppressor factor. The present study has investigated the Con A-inducible suppressor cell function in cord blood, children of various ages, and adults by comparing the ability of each Con A-activated supernatant to inhibit the generation of immunoglobulin-producing cells (Ig-PC) in pokeweed mitogen- (PWM) stimulated cultures of adult PBL. Con A-activated supernatants from adults could markedly suppress the generation of Ig-PC by allogeneic as well as autologous PBL in response to PWM. Such suppression appeared to be equally effective on the generation of IG-PC of 3 major classes, IgG, IgM, and IgA. On the contrary, Con A-activated supernatants from cord blood and newborn infants showed only a negligible suppression on PWM-induced adult B cell differentiation. But the suppressor activity found in Con A-activated supernatants gradually increased with advancing age, and reached approximately to the adult level at 4 yr of age or later. The results suggest that human T lymphocytes may be relatively deficient in their Con A-induced suppressor cell function in the early period of life.     

Immunological unresponsiveness of self-recognizing B lymphocytes to the PBA property of a soluble T cell factor.

Spleen cells cultured in the presence of Con A became activated to polyclonal anti-body synthesis. This effect was found to be mediated by a polyclonal factor released by the activated T cells. Such a factor, contrary to any other polyclonal B cell activator, so far tested, failed to induce resting B cells to synthetize antibodies capable of lysing autologous albumin coupled SRBC. The Unresponsiveness was found to be specific since Con A activated spleen cells were capable of lysing heterologous albumin and HGG coupled SRBC. Moreover, neither active suppressor cells, nor soluble suppressor factors seem to be involved in the lack of response to autologous antigens. It is concluded that the clones of B cells carrying the polyclonal receptor for the T factor and Ig receptors for self are eliminated or functionally inactivated. The implication of these findings for the mechanism of self-non-self discrimination are discussed in relation to the mechanism of immunocyte triggering.     

Activation of human B lymphocytes. V. Kinetics and mechanisms of suppression of plaque-forming cell responses by concanavalin A-generated suppressor cells.

The kinetics and mechanisms of suppression of the PWM-induced PFC response of human PB lymphocytes by Con A-activated suppressor cells were investigated. It was necessary that Con A suppressor cells be present early in the process of activation of human B cells toward antibody syntheses, but maximal suppression of the PFC response occurred later in the culture period. In addition, Con A-activated cells, although suppressing the PFC response to PWM greater that 90% of control, did not significantly suppress the blastogenic response to PWM after 3 or 5 days in culture. On the contrary, after 3 days in culture, background tritiated thymidine incorporation as well as tritiated thymidine incorporation to PWM stimulation was increased when Con A suppressor cells are added to fresh autologous peripheral blood lymphocytes. This increased blastogenic response after three days most likely represented an autologous mixed lymphocyte reaction (MLR) or Con A suppressor cells against fresh autologous non-T cells. The induction of autoreactive cells may be one of several modes of suppression of PFC responses by Con A activated suppressor cells.     

Origin of autoreactive T helper cells. I. Characterization of Thy-1+, Lyt-, L3T4- precursors in the spleen of normal mice

A new population of dull Thy-1+, Ly-1-, Lyt-2-, L3T4- PNA- cells, resistant to a double cytotoxic treatment by monoclonal antibodies to these T cell markers plus complement, has been isolated from the spleen of normal adult BALB/c and DBA/2 mice (Tkr cells). These cells exhibit no spontaneous autoreactivity or alloreactivity but can be activated with concanavalin A (Con A). Once activated, they differentiate into bright Thy-1+, Ly-1+, Lyt-2-, L3T4+ PNA- T lymphocytes. Con A-activated Tkr cells also strongly proliferate in the presence of allogeneic or syngeneic dendritic cells in secondary cultures. Moreover, contrary to other Con A-stimulated T cell populations, they induce B lymphocytes to proliferate and to differentiate into Ig-secreting cells at a very high level. Con A-activated Tkr cells are therefore very potent polyclonal B cell activators. Restimulated of Tkr cells by syngeneic dendritic cells can be inhibited by anti-L3T4 or anti-class II monoclonal antibodies. The results suggest that Tkr cells are the precursors of class II-specific autoreactive T helper cells. Tkr cells are absent in the spleen of B6 animals. This indicates that their expression might be genetically controlled. It also suggests that Tkr cells may not be the unique splenic precursors of autoreactive T cells. Con A activation of Tkr cells in Click's medium is 2-mercaptoethanol dependent and highly sensitive to pCO2, like the response of thymocytes. Tkr cells are also absent in the spleen of nude mice. We conclude that Tkr cells represent splenic precursors of autoreactive T helper cells equivalent to Thy-1+, Ly-2-, L3T4- PNA- cortical thymocytes.     

Biological expressions of lymphocyte activation. IV. Concanavalin A-activated suppressor cells in mouse mixed lymphocyte reactions.

Thymus-derived lymphocytes (T cells) from mouse spleen, activated in vitro or in vivo with concanavalin A (Con A), suppress proliferative responses of syngenic lymphocytes in mixed lymphocyte reactions (MLR). Replication in vitro was not required for expression of suppressor activity by Con A-activated cells and was blocked in MLR by treating suppressor cells with mitomycin C or irradiation. Kinetics of MLR responses and viability of cultures were not altered by addition of activated suppressor cells. The data are consistent with a direct inhibitory effect of suppressor T cells on antigen-induced DNA replication. These observations extend a model previously described for regulation of antibody synthesis by Con A-activated T cells to control of cell-mediated immune responses. This model should be particularly useful in further definition of regulatory T cell subpopulations, and in investigation of interactions and relationships between such populations.     

5C6-F4, a novel 100,000-dalton rat lymphocyte activation antigen defined by monoclonal antibody

Con A-activated rat thymocytes were used to immunize mice, and immune spleen cells were fused with NS/1 myeloma cells. One clone, designated 5C6-F4, reacted strongly with Con A-activated rat thymocytes and some LPS-activated rat spleen cells but not with normal thymocytes, spleen cells, or bone marrow cells of rat origin. The 5C6-F4 did not react with Con A-activated thymocytes of mouse origin. Immunoprecipitation of 5C6-F4 antigen from surface-iodinated Con A-activated rat thymocytes or LPS-activated rat spleen cells revealed its m.w. to be approximately 100,000. The kinetic studies of the expression of 5C6-F4 antigen revealed that 5C6-F4 antigen was detectable at 6 hr after Con A stimulation of rat spleen cells, whereas IL 2 receptor (IL 2R) was detectable at 12 hr. The appearance of 5C6-F4 antigen and IL 2R precede the onset of DNA synthesis of Con A-activated spleen cells. Thus, 5C6-F4 antigen is classified as early activation antigen. The 5C6-F4 inhibits the lymphocyte proliferation induced by mitogen and the IL 2-driven rat T cell proliferation. Sequential immunoprecipitation study as well as binding inhibition study indicated that the 5C6-F4 antigen is distinct from IL 2R molecule. The 5C6-F4 antigen appears to be a novel rat lymphocyte activation antigen that exhibits immunoregulatory function and also may serve as a useful marker of T cell activation.     

Abnormal activation and loss of suppressor T cells in the spontaneously hypertensive rat.

Suppressor T cell function in the spontaneously hypertensive rat (SHR) and normotensive Wistar Kyoto (WKY) rats was analyzed using syngeneic mixed lymphocyte reaction (SMLR) and concanavalin A (Con A) activation. A depressed SMLR was found in adult SHR but not in adult WKY. IL-2 synthesized by SHR was 40-fold lower than that of WKY, and the suppressor T cells generated in the SMLR were incapable of suppressing IgG synthesis. Precursors of cells that can be activated by Con A to become functional suppressor cells are reduced in adult SHR. Supernatant fluids derived from Con A-activated spleen cells from adult SHR failed to significantly inhibit IgG synthesis by cultures of syngeneic spleen cells compared to supernatant fluids from young SHR or WKY Con A-activated spleen cells. However, spleen cells from both adult SHR and WKY proliferated strongly and released equivalent amounts of IL-2 in response to Con A. Addition of exogenous IL-2 to the SMLR cultures in vitro restored the ability of SHR T cells to respond in the SMLR, with generation of cells capable of suppressing IgG synthesis. Administration of SHR with IL-2 in vivo also restored the suppressor T cell function in the SMLR. These results suggest a defective suppressor T cell activation and loss of suppressor T cell activity as the SHR age.     

B lymphocyte regulation of the immune system. I. In vivo biologic activity of the novel lymphokine, B cell-derived enhancing factor (BEF)

B cell-derived enhancing factor (BEF) is a lymphokine of B cell origin which was originally identified and characterized by its ability to enhance in vitro antibody responses, an effect shown to be due to the ability of BEF to reduce the activation of suppressor T cells. The present study was undertaken to determine whether BEF could also be active in modulating antibody responses in vivo. The data presented here demonstrate that BEF is biologically active in vivo, as manifested by significantly enhanced primary IgM and IgG antibody responses in mice that were either injected with BEF prepared exogenously or implanted with growing BEF-secreting cells of a B cell line. Moreover, BEF was shown to enhance subsequent development of immunologic memory in mice pretreated with BEF at the time of primary immunization; these mice then displayed enhanced secondary responses when challenged with the same antigen some weeks later. The mechanism by which BEF exerts biologic activities to positively modulate in vivo antibody responses and immunologic memory reflects the ability of BEF to modulate one or more T cell functions, as evidenced by the following findings. 1) Transient in vitro exposure to BEF of T cells, but not of B cells, endowed such cells with the capacity to adoptively transfer enhanced primary antibody responses to irradiated recipients. 2) Utilizing adoptive in vivo antibody responses, in which fractionated B cell or T cell populations were obtained from BEF-pretreated mice, revealed that one effect of BEF which results in enhanced immunologic memory is related to its activity on T cells during the priming phase of the immune response. Finally, the existence of this B cell-derived lymphokine and the demonstration of its in vivo regulatory effects on the immune system provide yet another example of the emerging biologic importance of B lymphocytes in the overall regulation of the immune system.     

Regulatory function of Thy 1 negative cells. II. Spontaneous release of enhancing product by B cells cultured in vitro

The supernatant from non-antigen- and non-mitogen-stimulated spleen cells, cultured for 2 days, is effective in augmenting the IgM primary antibody response to TD antigens. The IgM and IgG secondary response to TD antigens, as well as the IgM response to TI antigens is not affected. Neither T cells nor accessory cells seem to be responsible for the release of the enhancing product. The soluble factor described in this paper (i) is not a polyclonal activator of B cells, (ii) does not substitute for thymus-derived cell functions in the in vitro response to heterologous erythrocytes, (iii) does not promote the response to optimal and suboptimal doses of Con A. It modulates the antibody production only in conjunction with T cells and in the presence of macrophages. Studies carried out with mouse myeloma cell lines confirmed present results obtained with normal spleen cells. A soluble product which exhibits the biological activities ascribed to the BEF and which prevents the activation of T suppressor cells was produced by a B-cell clone that does not express immunoglobulin heavy or light chains (P. del Guercio, S. Brugère, and M. F. Poirier, Cell. Immunol., in press).     

Site of action of a soluble immune response suppressor (SIRS) produced by concanavalin A-activated spleen cells.

The cellular site of action of SIRS, a soluble immune response suppressor released by Con A-activated spleen cells which suppresses antibody responses to heterologous erythrocytes by murine spleen cells in vitro, was investigated. Exposure of spleen cells to SIRS for 2 hr at 37 degrees C or 1 hr at 4 degrees C was sufficient to suppress 5-day antibody responses in vitro. Similar exposure of splenic or peritoneal exudate macrophages to SIRS also suppressed antibody responses by untreated splenic lymphoid cells; exposure of splenic lymphoid cells to SIRS was without effect. SIRS did not act via T cells which might have contaminated the macrophage preparations. SIRS-mediated suppression could be partially overcome by an excess of normal peritoneal exudate macrophages, but not by an excess of T or B cells. These data indicate that the target cell of SIRS activity is the macrophage. The results are discussed in the context of macrophage functions that could be affected by SIRS.     

Identification and characterization of a B cell growth inhibitory factor (BIF) on BCGF-dependent B cell proliferation

The culture supernatants of Con A-activated human peripheral blood mononuclear cells (PBM) contained at least two regulatory factors upon B cell proliferation. One was B cell growth factor (BCGF), which activated antigen-stimulated B cells to proliferation and clonal expansion, and the other was its inhibitory factor, arbitrarily named B cell growth inhibitory factor (BIF). This BIF inhibited the effect of BCGF on anti-mu-stimulated B cells or the monoclonal mature B cell line (CLL-T.H.) obtained from the peripheral blood lymphocytes of B cell-type chronic lymphocytic leukemia patients, which were activated only with BCGF and without adding other proliferating stimuli (e.g., anti-mu). BIF activity was detected in the 24 hr culture supernatants of Con A-activated human PBM in FCS containing medium and also in serum-free RPMI 1640 medium. This substance with BIF activity could not be derived from FCS. Con A-induced BIF (m.w. of 80,000 and an isoelectric point of pH 5.4) was analyzed by Sephadex G-200 gel filtration and chromatofocusing. BIF was stable at pH 2.0 and at 56 degrees C for 30 min. Partially purified BIF had no effect on cell viability and almost no interferon activity (less than 1 IU/ml). BIF with high titer had a slight but significant inhibition on TCGF-dependent T cell growth and on PHA or Con A responses, but the extent of these inhibitions was far less than that of BCGF-dependent B cell growth. Absorption of BIF with Con A blasts made its inhibition on T cell growth even less. On the other hand, BIF activity could not be absorbed with Con A blasts but was almost absorbed with large numbers of CLL-T.H. cells. BIF had almost no inhibitory effect on the proliferation of a mouse fibroblast cell line (NIH 3T3), a mouse myeloma cell line (NS-1), human lymphoid cell lines (MOLT-4, HSB-2, and Daudi), or a human myeloid cell line (K-562). BIF-producing cells were estimated to be T cells and were identified as T8+ T cells. On the other hand, Con A-induced BCGF was demonstrated to be produced predominantly by T4+ T cells. These results show that human B cell proliferation is regulated by interaction between T4+ and T8+ cells via soluble factors, namely BCGF and BIF, respectively.     

Reversal of Con A-induced suppression by a platelet-derived factor which binds to activated suppressor T cells

A platelet-derived factor found in serum as well as in platelet releasate prepared either with calcium ionophore or with thrombin was shown to reverse Con A-induced suppression of the plaque forming cell (PFC) response to sheep erythrocytes (SRBC) in vivo in (CB6)F1 mice. In addition, as shown previously, lymphoma cell-induced suppression in SJL mice was similarly reversed. The factor could be injected prior to Con A on the day before SRBC injection, or on the same day as antigen with comparable results. It also enhanced PFC responses in the absence of Con A. Suppressor cell induction by Con A in vivo, as demonstrated by assay on PFC responses of normal spleen cells in vitro, was abrogated by simultaneous injection of the platelet factor. Cells from mouse spleen and lymph node, but not from thymus could absorb the factor from human serum at 4 degrees C. The phenotype of the relevant spleen cells was L3T4-, Ly1-, Ly2+, Thy1+, Ly22+, Qa1+, Qa4+, Qa5+, and Ly6.IE+. These results suggest that this factor binds to activated peripheral T cells of the suppressor cell phenotype.     

B lymphocyte regulation of the immune system. II. Inhibition of Fc receptor expression of lymphocytes by BEF, a lymphokine of B cell origin

Recently, we described a new lymphokine of B cell origin, capable of selectively preventing the differentiation of T suppressor cells from the precursor into the effector stage. As a result, antibody production against various antigens is markedly increased. We termed this lymphokine B cell-derived enhancing factor (BEF). To discern the mechanism(s) by which BEF interferes with the activation of T suppressor cells, experiments were undertaken to explore the effect of BEF on the induction of Fc receptors (FcR). The induction of FcR on T cells has been implicated in the down-regulation of antibody synthesis, and it has been suggested that the expression of FcR for a given immunoglobulin precedes the release of factors with regulatory functions for the corresponding isotype. In the experiments reported here, murine spleen cells were incubated for 24 hr in the presence of IgG1 or IgA monoclonal antibodies, were washed, and the number of FcR gamma 1+ and FcR alpha+ cells were calculated by a rosette assay. The effect of BEF was studied either during the inductive phase or before, i.e., by pretreating the cells with BEF for 18 hr at 37 degrees C before the inductive phase. Our results show that BEF abolishes, in a dose-dependent manner, the expression of isotype-specific FcR in spleen cells when present during the inductive phase, as well as when cells are pretreated with it. In successive experiments, we tested the effect of BEF on the induction of FcR on T cell-enriched or B cell-enriched spleen cells. The results show that BEF is effective in selectively inhibiting FcR expression on T lymphocytes, but not on B lymphocytes, once isolated from the total spleen cell population. These findings provide further insight into the mechanism by which BEF modulates the immune response, and suggest that different mechanisms may be involved in the induction of FcR on T and B lymphocytes, respectively.     

Lymphocyte function in experimental African trypanosomiasis. VIII. Loss of suppressor T cell function in lymph nodes

The immunosuppression that occurs in mice experimentally infected with African trypanosomiasis has been examined further. In the present study we have examined lymph node cells from Trypanosoma rhodesiense-infected C57Bl/6J mice for the ability to produce mitogen induced antigen-nonspecific suppressor T cells (Ts). Inguinal, mesenteric, and brachial lymph node cells were harvested from uninfected control mice and from mice at different periods of infection. These cells were cultured with or without concanavalin A (Con A) for 48 hr to induce Ts activity. After stimulation, the control and infected lymph node cells were passed over Sephadex G-10 columns to remove suppressor macrophages that arise during the infection from Con A-induced Ts. The column passed cells were then added to normal mouse responder spleen cells in a primary in vitro antibody response culture system with sheep erythrocytes (SRBC) as antigen. The resultant plaque-forming cell responses to SRBC indicated that Ts function was not induced in infected lymph node cell populations. However, early in the infection, a stimulatory signal was provided by both the untreated and Con A-treated infected lymph node cells, which was lost in the terminal stage. Determinations of T cell subpopulations revealed that the infected Lyt 2.2-bearing subpopulation was not significantly altered from normal controls. We conclude that T. rhodesense infected mice fail to mount normal lymph node cell antigen nonspecific Ts responses and that this loss of activity may be due to an intrinsic dysfunction in the suppressor T cell population.     

Activated suppressor cell dysfunction in progressive multiple sclerosis

Concanavalin A (Con A)-induced suppressor activity has previously been shown to be reduced in multiple sclerosis (MS) patients with active clinical disease. In this study, we demonstrate that OKT3, as well as Con A induced suppressor activity mediated by unfractionated peripheral blood mononuclear cells is reduced in patients with the progressive form of MS. By performing reconstitution experiments involving E+, T4+, or T8+ cells derived from either MS patients or controls, and normal allogeneic macrophages or E- cells, we sought to define the cellular basis for this suppressor defect. In both MS and control groups, E+ cells were required to obtain measurable levels of suppression. Suppressor levels induced by Con A-activated cultures containing E+ cells from MS patients were lower than those induced by those containing control donor E+ cells. Suppression mediated by T8+ cells from MS patients was also lower than for controls. In the control group, suppression mediated by T8+ cells exceeded that mediated by T4+ cells; such differences were not apparent in the MS group. These results suggest that although Con A-induced suppression can be mediated by a number of T and non-T cell subsets, the functional suppressor defect measured in the MS population does involve the T8+ cell subset.     

The regulatory role of adenosine-activated T-lymphocyte subset on the immune response in humans: I. Mitogenic response and production of mediators

Human T lymphocytes, rerosetted with sheep erythrocytes in the presence of adenosine, yield two subpopulations: a major one (E_R), still capable of forming E rosettes; and a minor nonrosetting (E_S) one. The two subpopulations differed in their proliferative responses to various mitogens. E_R cells responded well to galactose oxidase (GO), soybean agglutinin (SBA), and phytohemagglutinin (PHA) but responded poorly to concanavalin A (Con A). The response of E_S cells was poor to GO and SBA, intermediate to PHA, and significantly high to Con A. The different response of E_R and E_S subsets to Con A was not greatly affected by adherent cells, but an enhancing effect on the proliferation of E_S cells to Con A was observed when prostaglandin synthesis was inhibited by indomethacin. Addition of E_S cells to E_R cells in a ratio of 1:5 resulted in an enhanced synergistic effect of Con A-induced proliferation. A soluble mitogenic factor released from Con A-activated T cells appeared involved in this enhanced proliferation. This factor (E_SF) was produced only by the minor T-cell subpopulation which is sensitive to adenosine (E_S). The induction of E_SF was not dependent on the addition of adherent cells and required 72 hr of incubation for its production. E_SF was mitogenic to nonactivated and Con A-activated PBL as well as to T, E_R, and E_S subpopulations. Following incubation of E_R cells with E_SF, a suppressor factor (E_RSF) was produced which abolished the mitogenic activity of E_SF. Differences between these factors and a known mediator like Interleukin-2 (IL-2) and suppressor factors are discussed.     

Cellular requirements for production and release of the lymphocyte costimulator

The lymphocyte costimulator (CoS) is a lymphokine required for the activation of T cell responses to H-2 alloantigens or mitogen, CoS activity is found in the supernatant medium of Concanavalin A (Con A) stimulated spleen cells, In this paper we investigate the cellular requirements for CoS production by Con A-activated mouse spleen cells. Maximal lymphokine production in response to Con A depends on a co-operative interaction between T cells and a nylon wool-adherent cell present in the spleen of nude mice. T cells appear to be the major producers of CoS activity, doing so only in response to an initial inductive stimulus supplied by nude spleen cells. The inductive stimulus is found as a soluble factor in the supernatant of Con A-activated spleen cells, and can also be provided by stimulatory (S+), but not by non-stimulatory (S-), tumour cells H-2 identical with the responding T cells. The activation of lymphokine-producing T cells is thus a two-signal process, requiring both mitogen and an additional inductive signal. Once activated, homogeneous populations of T cells will release lymphokine in response to mitogen alone.