Signals involved in T cell activation. I. Phorbol esters enhance responsiveness but cannot replace intact accessory cells in the induction of mitogen-stimulated T cell proliferation

The role of accessory cells (AC) in the initiation of mitogen-induced T cell proliferation was examined by comparing the effect of intact macrophages (M phi) with that of 4-beta-phorbol 12-myristate 13-acetate (PMA). In high-density cultures, purified guinea pig T cells failed to proliferate in response to stimulation with phytohemagglutinin (PHA), concanavalin A (Con A), or PMA alone. The addition of M phi to PHA or Con A but not PMA-stimulated cultures restored T cell proliferation. The addition of PMA to high-density T cell cultures stimulated with PHA or Con A also permitted [3H]thymidine incorporation, but was less effective than intact M phi in this regard. This action of PMA was dependent on the small number of AC contaminating the T cell cultures as evidenced by the finding that PMA could not support mitogen responsiveness of T cells that had been depleted of Ia-bearing cells by planning, even when these cells were cultured at high density. When PMA was added to T cell cultures supported by optimal numbers of M phi, catalase-reversible suppression of responses was noted. Even in cultures containing catalase, PMA failed to enhance responsiveness above that supported by optimal numbers of M phi. A low-density culture system was used to examine in greater detail the possibility that PMA could completely substitute for M phi in promoting T cells activation. In low-density cultures, mitogen-induced T cell proliferation required intact M phi. PMA could not support responses even in cultures supplemented with interleukin 1-containing M phi supernatants or purified interleukin 2 alone or in combination. Similar results were found in high-density cultures of T cells depleted of Ia-bearing cells. These results support a model of T cell activation in which AC play at least two distinct roles. The initiation of the response requires a signal conveyed by an intact M phi, which cannot be provided by either a M phi supernatant factor or PMA. The response can be amplified by additional M phi or M phi supernatant factors. PMA can substitute for M phi in this regard and can provide the signal necessary for amplification of T cell proliferation supported by small numbers of intact AC.     

The role of Ia molecules in the activation of T lymphocytes. I. The activation of an IL 1-dependent IL 2-producing T cell hybridoma by Con A requires an interaction, which is not H-2-restricted, with an Ia-bearing accessory cell

A model of accessory cell-dependent lectin-mediated T cell activation was investigated by utilizing a mitogen-inducible T cell hybridoma. A continuous MHC-restricted antigen-specific T cell line was fused with the azaguanine-resistant AKR thymoma BW5147. A hybrid, RF1.16B, was identified that is minimally inducible by Con A stimulation alone but is stimulated by Con A in the presence of T cell-depleted accessory cells to produce interleukin 2. The accessory cell function can be replaced by the monokine interleukin 1. Thus the lectin is a sufficient trigger for the hybrid in the absence of MHC restriction elements. The accessory cell function from splenocytes is provided by a non-B, non-T, predominantly Ia-bearing radioresistant cell. The interaction between the RF1.16B hybrid and the accessory cell population is not H-2-restricted. Control experiments, including the use of a cloned source of accessory cells, ruled out contaminating T cells or direct lectin effects as an explanation for the lack of H-2 restriction. The finding that an Ia-bearing cell is required for activation in an MHC-nonrestricted manner is discussed, and a hypothesis is raised that Ia antigens may play a role in addition to that of being a restriction element.     

Requirement for an Ia-bearing accessory cell in Con A-induced T cell proliferation.

Pretreatment of murine lymphoid cells with anti-Ia and C abrogated the proliferative response of these cells to Con A, but not to PHA. Reconstitution experiments demonstrated that T cell-enriched populations failed to restore Con A responsiveness and that T cell-depleted populations were more effective in restoring responsiveness to Con A. In particular, a population of 1000 R resistant, glass-adherent, non-T spleen cells was capable of completely restoring responsiveness to Con A when added in numbers as low as 4% of cultured cells. These splenic adherent cells were found to express Ia determinants encoded by at least two genes: one in I-A and the other in I-B, I-J, and/or I-E/C, and it was demonstrated that determinants encoded in these two regions were expressed on the same cell. These results demonstrate that non-T accessory cells may be the Ia+ cells entirely responsible for the anti-Ia and C-induced abrogation of T cell proliferative responses to Con A.     

Modulation of T-cell functions: I. Effect of 2-mercaptoethanol and macrophages on T-cell proliferation

The in vitro effects of 2-mercaptoethanol (2-ME), macrophages (MØ), and concanavalin A (Con A) on the proliferation of normal spleen cells (NSC), MØ-depleted spleen cells (DSC), T cells, T-cell subpopulations, and B cells were assessed by [³H]thymidine incorporation. 2-ME alone was consistently shown not to be mitogenic for purified T cells; however, 2-ME enhanced the early (Days 1 and 2) Con A (2 μg/ml)-induced response of NSC, DSC, and T-cell preparations, but depressed the late response (Days 4 and 5). 2-ME alone was mitogenic for purified B-cells, as reported previously; and the 2-ME-induced B-cell response was inhibited by Con A. Preincubation of T cells with 2-ME was sufficient for enhanced Con A responsiveness; however, if 2-ME was added 24 hr after the initiation of culture, no alteration of the Con A-induced response was observed. Ly-2,3⁺ T cells were unresponsive to Con A (0.3–20 μg/ml), but the addition of 2-ME or peritoneal cells enhanced the Con A responsiveness of Ly-2,3⁺ T cells over 200-fold. Ly-1⁺ T cells responded with a similar doseresponse and kinetic profile as unselected T cells. Although Ly-1⁺ T cells responded to Con A, unlike Ly-2, 3⁺ T cells, extensive removal of MØ significantly reduced the Con A-induced responsiveness of the Ly-1⁺ T cells. The reactivities of Ly-1⁺ and Ly-2,3⁺ DSC could be reconstituted by the addition of MØ or 2-ME; however, the kinetic response of Ly-1⁺ T cells peaked on Day 2–3, and Ly-2,3⁺ T cells had a delayed response which peaked on Day 4–5. The results indicated that (i) 2-ME and/or MØ accelerate the response kinetics of T-cells to Con A; (ii) T-cell subpopulations have differential requirements for MØ and/or 2-ME in the response to Con A; (iii) T-cell subpopulations exhibit differential dose responsiveness to Con A; and (iiii) 2-ME alters Con A responsiveness by a direct effect on T cells.     

Pleiotropic effects of the Bcg gene. II. Genetic restriction of responses to mitogens and allogeneic targets

The response of Bcgr and Bcgs spleen cells to allogeneic Ag, mitogens, and in a system of oxidative mitogenesis using neuraminidase and galactose oxidase was investigated in two Bcg congenic systems. The Bcgr macrophages supported the MLR across H-2 barrier much better than the Bcgs macrophages. At sub-optimal or optimal doses of mitogens Bcgr mice were higher responders than their Bcgs counterparts. The superior response of Bcgr spleen cells to Con A was further investigated with the aim of identifying the population expressing this phenotype. T cells of either Bcgr or Bcgs type showed equal ability to respond to Con A in the presence of macrophages. Purified splenic macrophages from Bcgr mice contained a significantly greater percentage of Ia+-bearing macrophages compared to Bcgs mice. Splenic macrophages of the Bcgr type were more efficient than their Bcgs counterparts at restoring the Con A response of accessory cell-depleted spleen cells. Resident peritoneal macrophages as well as splenic dendritic cells from Bcgr and Bcgs mice were equally efficient at restoring this response. Glutaraldehyde-fixed Bcgr splenic macrophages were shown to be more efficient than the Bcgs cells at replenishing the response of Con A-unresponsive spleen cells when supplemented with IL-1.     

Stimulated rat T cell-derived inhibitory factor for cellular DNA synthesis (STIF). III. Effect on cell proliferation and immune responses

Stimulated T cell-derived inhibitory factor for cellular DNA synthesis (STIF), a lymphokine produced from concanavalin A (Con A)-stimulated rat suppressor T cells, was examined for its inhibitory effect on various cultured cells and on in vitro immune reactions. STIF could inhibit the DNA synthesis of a variety of normal and neoplastic cells from rats, mice, and humans in a dose-dependent fashion. Kinetics studies revealed that STIF selectively inhibited cellular DNA synthesis after incubation for 12 hr, but after 36 hr, it also inhibited RNA and protein syntheses. The inhibited cellular DNA synthesis by 12-hr incubation with STIF was recovered after culturing the cells in STIF-free medium. The inhibitory effect of STIF on the DNA synthesis was not blocked by addition of a sugar (alpha-methyl-D-mannoside, N-acetyl-D-glucosamine, N-acetyl-D-galactosamine, L-fucose, or L-rhamnose) in culture, as determined by using rat bone marrow cells. STIF inhibited proliferative responses of rat lymphocytes to T cell mitogens, Con A and phytohemagglutinin, and a B cell mitogen, lipopolysaccharide, as well as IL 2-dependent growth of cloned T572 cells. It could also inhibit both blastogenesis and cytotoxic T cell generation in allogeneic mixed lymphocyte reaction. The release of IL 2 from Con A-stimulated T cells was also inhibited by the added STIF in culture, as demonstrated from the finding that IL 2 activity was not detected in the supernatants even after an anion-exchange column chromatography. These results indicate that STIF could inhibit cellular DNA synthesis in a species-unrestricted manner and thus inhibits the proliferation of various normal and neoplastic cells, and that it could also inhibit lectin- or IL 2-dependent T cell proliferation as well as IL 2 production from T cells in in vitro immune reactions.     

Ontogeny of proliferative and cytotoxic responses to interleukin 2 and concanavalin A in murine fetal thymus

The ontogeny of proliferative and cytotoxic responses to concanavalin A (Con A) and interleukin 2 (IL 2) in C57BL/6J (B6) fetal thymus (FT) was investigated. Embryonic thymocytes were either taken from embryos at different times of gestation or from 14 day B6 FT that were maintained as organ cultures for various times. It was found that the B6 FT could proliferate to Con A and EL4 SN (an IL 2 containing culture supernatant) in a synergistic fashion. This synergy between Con A and EL4 SN was first observed at the 16th to 17th day of gestation. A similar differentiation process took place in 14-day FT that had been maintained as organ cultures; the synergy between Con A and EL4 SN was first observed after 3 days in organ culture. This synergy increased with increasing time of organ culture, and was most evident after 10 days. The synergy between Con A and EL4 SN was also observed when the EL4 SN was replaced with IL 2 which had been purified from crude EL4 SN to apparent homogeneity. B6 FT could also form cytotoxic T lymphocytes (CTL) on stimulation with Con A and EL4 SN. Con A-activated CTL (polyspecific) were detected by including phytohemagglutinin in the assay medium. CTL response was first detected in the 17-day fetal thymus by using this assay. In organ cultures, CTL responses were first detected after 4 days in organ culture, and reached peak levels after 12 to 14 days. The CTL precursor (CTL-P) frequencies in the B6 FT after 2, 5, 10, and 14 days in organ culture were less than 1/10,000, 1/2232, 1/297, and 1/70, respectively; the corresponding CTL-P frequency in adult thymus was 1/60. After 6 days in organ culture, B6 FT could also form CTL in response to Con A and pure IL 2. This finding suggests that the ability to synthesize other differentiation factors that are required for CTL responses is acquired at an early time of thymic differentiation.     

B cell helper factors. II. Synergy among three helper factors in the response of T cell- and macrophage-depleted B cells

The concanavalin A- (Con A) stimulated supernatant of normal spleen cells (normal Con A SN) was shown to contain a set of helper factors sufficient to allow T cell- and macrophage- (M phi) depleted murine splenic B cells to produce a plaque-forming cell response to the antigen sheep red blood cells (SRBC). The activity of normal Con A SN could be reconstituted by a mixture of three helper factor preparations. The first was the interleukin 2- (IL 2) containing Con A SN of the T cell hybridoma, FS6-14.13. The second was a normal Con A SN depleted of IL 2 by extended culture with T cell blasts from which the 30,000 to 50,000 m.w. factors were isolated (interleukin X, IL X). The third was a SN either from the M phi tumor cell line P388D1 or from normal M phi taken from Corynebacterium parvum-immune mice. The combination of all three helper factor preparations was required to equal the activity of normal Con A SN; however, the M phi SN had the least overall effect. The M phi SN and IL 2 had to be added at the initiation of the culture period for a maximal effect, but the IL X preparation was most effective when added 24 hr after the initiation of culture. These results indicate that at least three nonspecific helper factors contribute to the helper activity in normal Con A SN.     

Mitogenic Activity of a Water-Soluble Adjuvant (Bu-WSA) Obtained from Bacterionema matruchotii

Butanol-extracted water-soluble adjuvant (Bu-WSA) obtained from Bacterionema matruchotii was cultured with peripheral blood mononuclear cells (PBM) in the presence of sub- and/or supra-optimal mitogenic concentrations of concanavalin A (Con A). The addition of Bu-WSA resulted in increased tritiated thymidine incorporation above that produced by Con A alone. Bu-WSA by itself is not mitogenic for PBM and in fact produced a decrease in thymidine uptake compared to the control. We investigated the response of subpopulation(s) of PBM to Bu-WSA, Con A and a mixture of Bu-WSA and Con A. Separation of PBM into purified T cells, B cells and macrophages showed that cell-cell cooperation of T cells with B cells or macrophages is necessary for the observed synergistic effect of Bu-WSA with Con A. A marked increase in thymidine incorporation by the mixture of T and B cell populations occurred, while only a small amount of thymidine was incorporated when the B cell population was absent. Mitomycin treatment revealed that the response could be ascribed to the T-cell response with a B-cell helper effect. Moreover, Con A and Bu-WSA appeared to act on the same T cell population. This model may provide unique information about the activation of human peripheral blood T cells compared with the activation of these cells by other mitogens.     

Differential requirement for accessory cells in polyclonal T-cell activation

Highly purified rat Ia-negative (OX-6-) and Ia-positive (OX-6+) T cells were employed to examine the requirement for accessory cells (AC) and/or soluble factors in the activation of resting T cells with Con A, PHA, sodium periodate, or antigen. A variety of cells were employed as AC, including Ia-positive and Ia-negative macrophages (M phi), gamma-irradiated (2000 rad) or non-irradiated OX-6+ T cells, and several Ia-negative adenovirus-transformed rat embryo fibroblast cell lines. Our results suggested that for the expression of IL-2 receptors (IL-2R) and proliferation of OX-6- T cells in response to Con A, PHA, or antigen, there was an obligatory requirement for the presence of AC which could not be overcome by the addition of IL-1 and/or IL-2. Activation of OX-6- T cells with antigen required the presence of Ia+ AC, while activation with mitogens could be initiated with Ia- AC. M phi were efficient in AC function in all responses tested, while the AC function of OX-6+ T cells (TAPC) proved discriminatory under different conditions. The optimal response to PHA required much higher concentrations of TAPC as AC than for the Con A response. TAPC failed to stimulate sodium periodate-treated T cells under any conditions tested. Furthermore, when TAPC were employed as AC, their antigen-presenting ability was radiosensitive, while their AC function for Con A and PHA was radioresistant. These results suggest that molecules involved in T cell-AC interactions may differ, depending on the source of AC and/or type of the proliferative stimulus provided to T cells. This data has been discussed in the context of T-cell activation.     

Concanavalin A inhibits oral regeneration in Stentor coeruleus through a mechanism involving binding to the cell surface

Concanavalin A (Con A) has been shown to induce delays in oral regeneration in the ciliate Stentor coeruleus. Associated with the delayed oral regeneration is a shedding of the cell's extracellular pellicle with the loss of some pigment granules. It is shown that the delays in oral regeneration are not the result of the pigment shedding. The delays are localized in the earliest stages of oral regeneration prior to stage 4. The delays caused by Con A are completely reversible by the addition of 2 mg/ml alpha-D-methyl mannoside either at the time of Con A exposure or 5 min later. Con A clearly binds to the cell surface as shown by the binding of FITC-Con A and its reversal by alpha-methyl mannoside. Crosslinking of Con A receptor molecules may be responsible for the effects of Con A since succinyl Con A, which does not crosslink these receptors, has no effect on oral regeneration even at double the Con A concentration. Calcium ions are also implicated in the action of Con A because an excess of extracellular calcium (10 mM) completely eliminates the Con A delays when added simultaneously with Con A. Examination of the minimum extracellular calcium concentration required for this effect showed that 2 mM calcium can reverse most of the delays but that 5 mM is necessary to completely reverse the delays caused by Con A. If the addition of calcium is delayed for various times after Con A addition, the extracellular calcium is progressively less effective in reversing the Con A delays.     

Separation of mitogen-induced suppressor cells of human antibody-producing cells

Human antibody-forming cells were demonstrated by a plaque in agar technique following in vitro stimulation with either pokeweed mitogen or Cowan I strain of protein A-positive Staphylococcus aureus bacteria. We evaluated the effects on this antibody formation caused by the addition of cells which had been stimulated with PH A or Con A. Both Con A and PHA cells harvested after 3 days showed strong inhibition of pokeweed-induced plaque formation. The majority of the suppression could be accounted for by a blast fraction separated on 1g sedimentation gradients from the Con A or PHA cultures. Small cells from such cultures showed inhibition of PFC when added at high ratios (1:2), but this suppressive activity diluted out much more rapidly than that of the blast cells. No helper activity was noted with either small cells or blasts. Our studies indicate a T-cell blast as the suppressive fraction in Con A- or PHA-stimulated human lymphoid cells. While this T-cell suppression applies to T-dependent responses such as antibody stimulation with pokeweed mitogen, it does not have a substantial effect on Cowan I-induced plaque-forming responses. The finding that Cowan I-induced plaques could not be inhibited by Con A or PHA blasts indicates the T independence of this response.     

Concanavalin A triggers T lymphocytes by directly interacting with their receptors for activation

Anti-HLA-DR antibodies did not inhibit concanavalin A-(Con A) induced T cell proliferation or the generation of suppressor cells capable of inhibiting immunoglobulin synthesis in autologous mononuclear cells after pokeweed mitogen stimulation. Nylon-wool purified T cells (pretreated with anti-HLA-DR antibody and C) exposed to Con A acquired responsiveness to interleukin 2 (IL 2) and were able to absorb this growth factor, whereas nonlectin-treated cells did not respond to IL 2 and could not absorb it. In the presence of interleukin 1 (IL 1), Con A stimulated the synthesis of IL 2 in purified OKT4+ lymphocytes but not OKT8+ cells. However, in the absence of IL 1, neither resting OKT4+ nor Con A-treated OKT4+ cells produced IL 2. Con A by itself did not directly stimulate macrophages to synthesize IL 1, although it could do so in the presence of OKT4+ but not OKT8+ lymphocytes. In addition, Con A induced proliferation of purified T cells provided IL 1 was supplied to the cultures. Cyclosporin A rendered Con A-treated T cells unresponsive to IL 2, made lectin-stimulated OKT4+ lymphocytes unable to respond to IL 1, and inhibited the synthesis of IL 2. Furthermore, this drug abrogated the Con A-stimulated synthesis of IL 1 by acting on OKT4+ lymphocytes and not on macrophages. Finally, cyclosporin-A suppressed the proliferative response and the generation of suppressor T cells induced by Con A. The following are concluded: 1) HLA-DR antigens do not seem to play any role in the triggering of T cells by Con A, and macrophages participate in lectin-induced activation of T cells mainly by providing IL 1. 2) Cyclosporin-A inhibits activation of T cells by interfering with the mechanism by which Con A stimulates T lymphocytes. 3) Con A triggers T lymphocytes by directly interacting with their receptors for activation.     

Concanavalin A is mitogenic for resident peritoneal macrophages

Con A, a known T-cell mitogen, is also mitogenic for resident peritoneal macrophages. The stimulated cells morphologically resemble macrophages and are actively phagocytic. The concentration of con A (30 micrograms/ml) required to stimulate 3H-TdR incorporation is ten times that required for T-cell activation. Con A must be present throughout the entire culture period to produce the maximum effect, and con A-depleted supernatant fluids from con A-stimulated cells cannot replace the con A requirement. Stimulation of 3H-TdR incorporation occurs after a 48-hour lag period and is maximal on the fifth to seventh day of culture. At the peak of the response, 20-30% of the macrophages can be stimulated to incorporate 3H-TdR, but little or no increase in the total number of cells present in the culture occurs. This and pulse-chase experiments indicate that only a single cycle of replication occurs in the stimulated cells. Con A-responsive peritoneal macrophages appear to be a distinct subpopulation and might play a different role in the interaction with T cells and B cells in the immune response than the con A-non-responsive cells.     

In vitro studies of the rabbit immune system. IV. Differential mitogen responses of isolated T and B cells.

The mitogenic responses of separated rabbit lymphocyte populations functionally analogous to mouse T and B cells have been tested in vitro. Purified T cells were prepared by passage over nylon wool (NW) and purified B cells prepared by treatment with antithymocyte serum and complement (ATS + C). ATS + C kills 70% of peripheral blood lymphocytes (PBL's) and 50% of the spleen cells while passage over NW yields 40% of the applied PBL's and 5–23% of the applied spleen cells. NW-purified T cells from the spleen or PBL's respond fully to concanavalin A (Con A) but have a reduced response to phytohemaglutinin (PHA) and little or no response to goat anti-rabbit immunoglobulin (anti-Ig). PBL's that survive ATS + C (B cells) are stimulated by anti-Ig but not by Con A or PHA. B cells purified from spleen do not respond to Con A or PHA but will respond to anti-Ig under appropriate conditions. A full spleen B-cell response to anti-Ig required removal of Ig produced by the cultures that blocked anti-Ig stimulation. It is concluded that, for rabbit lymphocytes, Con A and PHA are primarily T-cell mitogens and that anti-Ig is primarily a B-cell mitogen. However, the mitogen response of unfractionated PBL or spleen cell populations indicates an overlap in reactivity. This could be due to cells sharing T and B properties, alteration of cell populations by the fractionation procedures used, or recruitment of one population in the presence of a mitogenic response of the other population.     

Simultaneous suppression of allogeneic cytolytic activity and stimulation of lectin-dependent cytolytic activity by con A.

It is well known that when mouse lymphocytes are cultured with irradiated allogeneic stimulator lymphocytes, T cells capable of mediating specific cytolysis are generated. We noted that when the stimulator cells were pretreated with concanavalin A (Con A), the generation of T cell-mediated specific lysis (TSL) is largely abolished, but large amounts of T cell-mediated lectin-dependent lytic (LDL) activity are nevertheless produced. Data are presented indicating that generation of TSL is inhibited by suppressor cells which are generated by the Con A in the culture.One possible source of the LDL would be a specific clonal response to Con A-altered H-2 molecules. Evidence concerning this was equivocal since the amount of lectin required tor expression of the LDL is suffcient to cause non-specific T cell-mediated lysis of any target cell type, making inoperative the conventional tests for H-2 restricted recognition.Use of dead cell fragments for stimulation in MLC has previously been reported to produce LDL without TSL, but Con A-induced premature death of the stimulator cells was ruled out as a source of the LDL in our cultures.Another possible source of LDL would be suppressor-induced blockade of killer cell differentiation at a hypothetical stage expressing LDL but not TSL. However, delayed addition of Con A induced suppressor cells to M LC's never allowed generation of LDL when TSL was suppressed. Therefore, such a blocked differentiation mechanism did not contribute significantly to the LDL produced.The LDL activity results largely from Con A-induced polyclonal activation of cytolytic progenitor cells. It is shown that generation of LDL by Con A is able to be suppressed by Con A-induced suppressor cells added at the initiation of culture. However, in cultures in which Con A is simultaneously generating LDL and suppressor activities, the LDL is generated rapidly (in 2 days) and apparently passes the suppressable stage before the suppressor cells become active.     

Differential effects of concanavalin A and phytohemagglutinin on murine immunity. Suppression and enhancement of cell-mediated immunity.

To assess the effects of the selective T-cell mitogens concanavalin A (Con A) and phytohemagglutinin P (PHA) on cell-mediated immunity (CMI), the mitogens were injected before, with, or after intravenous (iv) challenge of mice with Listeria monocytogenes. Mitogenic treatment differentially influenced the CMI response to Listeria. Con A enhanced listericidal activity when given before or with Listeria challenge, but Con A suppressed the CMI response when given after infection with Listeria. In contrast, PHA enhanced listericidal activity at all intervals. Since Con A, but not PHA, affected the growth of Listeria in the spleens of mice 24 and 48 hr after infection, Con A was shown to have an immediate effect on the development of listericidal activity and PHA was shown to have a delayed effect. In addition, Con A induction of immediate nonspecific listericidal activity was short-lived, while PHA induced a longer-lasting effect on resistance to Listeria. The mitogen-induced effects in the CMI response to Listeria were shown to be dependent upon the activities of activated T cells. The enhancement and suppression of listericidal activity appears to result from the activation of different T-cell subpopulations, known to be stimulated preferentially by Con A or PHA.     

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.     

Accessory cell function in a Con A response: role of Ia and interleukin 1

Accessory cell (A-cell) function in a Con A response was analyzed. Irradiated P388D1 cells efficiently induced a proliferative response to Con A of T cells purified from spleen cells, whereas paraformaldehyde-fixed P388D1 cells failed to serve as A cells. Although IL-1 containing culture supernatant (SN) of a macrophage hybridoma induced the Con A response of the T-cell preparations, the depletion of Ia+ cells by the treatment with anti-Ia antibody and complement abrogated the response in the presence of IL-1. Fixed P388D1 cells and the hybridoma SN synergized in the reconstitution of the response. A 15,000-Da fraction of the hybridoma SN or human recombinant IL-1 alpha was able to substitute the hybridoma SN for the response. The reconstitution of the response by IL-1 and fixed P388D1 cells was inhibited by the addition of monoclonal anti-Ia antibody. These results indicate that IL-1 or fixed P388D1 cell does not exert a sufficient signal by itself and both of them are required for the reconstitution of a Con A response of highly purified T cells, and that Ia on fixed P388D1 cells play an important role.