A study of the mechanism of Con A-induced immunosuppression in vivo

The plaque-forming cell (PFC) response to sheep erythrocytes (SRBC) is suppressed in a dose-related manner when concanavalin A (Con A) is administered intravenously to mice prior to or after immunization with antigen. The magnitude of suppression as well as the duration of the Con A effect greatly depends on the concentration of antigen used for immunization. Although profound suppression of the anti-SRBC PFC response is observed in intact mice pretreated with Con A for 4-24 hr, spleen cells from these mice do not exhibit suppressive activity when transferred into normal recipients or when cotransferred with normal spleen cells into irradiated recipients. Moreover, the cells from Con A-treated mice respond as normal spleen cells to SRBC when transferred alone into irradiated hosts. Suppression of the anti-SRBC PFC is only observed when adoptive hosts of cells from Con A-treated mice are also injected with Con A within 48 hr (but not 72 hr) of cell transfer and immunization. This time course of responsiveness to the suppressive effects of Con A is similar to that observed in normal mice and in irradiated recipients of normal spleen cells. The immune response to SRBC is also suppressed in adoptive hosts of normal spleen cells that are pretreated with Con A 4-24 hr prior to irradiation and cell transfer. Although functionally inactive when transferred into adoptive hosts, spleen cells from mice pretreated with Con A for 4-24 hr can suppress a primary antibody response to SRBC in vitro. The suppressive activity, which cannot be detected in the spleens of mice when the interval between pretreatment and assay is longer than 24 hr, is present in a subpopulation that bears the Thy 1.2 and Lyt 2 phenotype. Taken together the results obtained in in vivo and in vitro functional assays suggest that a suppressor cell population is activated following in vivo treatment with Con A, but that the cells rapidly lose their state of activation when removed from a Con A environment. This phenomenon is in all probability responsible for the failure to demonstrate suppressive activity in the spleens of Con A-treated mice using in vivo functional assays.     

Characteristics and mechanisms of action of the concanavalin A-activated suppressor cell in man.

Human peripheral blood lymphocytes treated for 24 to 48 hr with optimally mitogenic doses of concanavalin A suppressed the proliferative response of autologous T cells to mitogens and antigens. Con A-treated cells also suppressed the proliferative response and the immunoglobulin synthetic response of autologous B cells stimulated in vitro by T cell helper factor. The human Con A suppressor cell was sensitive to treatment with mitomycin C and to exposure to radiation doses exceeding 1000 rads. The Con A suppressor cell was shown to reside in the nylon wool-nonadherent, sheep red cell rosette-forming, histamine receptor-bearing population of lymphocytes and to lack surface DRW antigens. One mechanism of action of Con A suppressor cells was shown to be the inactivation of nonspecific T cell helper factor.     

Stimulation of suppressor cells in the bone marrow and spleens of high dose cyclophosphamide-treated C57Bl/6 mice

Systemic administration of a single dose (300 mg/kg) of cyclophosphamide (Cy) induced the appearance of a population of suppressor cells in the bone marrow and spleens of mice. Suppressor cells were assayed by their capacity to inhibit the concanavalin A (Con A) blastogenesis or the mixed-lymphocyte response of normal C57Bl/6 spleen cells. Cy-induced bone marrow (Cy-BM) suppressor cells were present as early as 4 days following Cy therapy and their activity gradually decreased over the next 2 weeks. Cy-induced splenic (Cy-Sp) suppressor cells were maximally present on Days 6 through 10 following Cy therapy. Studies were performed to characterize the suppressor cells of bone marrow obtained 4 days after Cy treatment and of normal bone marrow (N-BM). Some suppressor activity was present in normal bone marrow. N-BM suppressor cells resembled cells of the monocyte/macrophage lineage in that they were slightly adherent to Sephadex G-10, sensitive to L-leucine methyl ester (LME), and insensitive to treatment either with anti-T-cell antibody and complement or with anti-immunoglobulin antibody and complement. Their suppressive activity was abrogated by incubation with either indomethacin or catalase. Cy-BM suppressor cells were also resistant to treatment with anti-T-cell and anti-immunoglobulin antibody and complement but were not adherent to Sephadex G-10 and not sensitive to LME. Their suppressive activity was partially eliminated by indomethacin alone or in combination with catalase. We conclude that Cy chemotherapy induces the appearance of a population of immune suppressive cells and that these cells appear first in the bone marrow and subsequently in the spleen.     

A soluble factor produced by bone marrow natural suppressor cells blocks interleukin 2 production and activity

We previously reported that a population of Fc gamma-receptor+ (Fc gamma R+) suppressor cells present in normal unstimulated rabbit bone marrow inhibited the growth of autologous rapidly proliferating bone marrow cells devoid of Fc gamma R. It is now reported that the Fc gamma R+ bone marrow cells produced a soluble, nondialyzable suppressor factor(s) (SF) which blocked the proliferation of Fc gamma R- bone marrow cells. In addition, the Fc gamma R+ cells and SF significantly inhibited spleen cell proliferation in response to concanavalin A (Con A), phytohemagglutinin, and pokeweed mitogen. The bone marrow SF exhibited a dose-dependent suppression of the growth of IL-2-dependent T lymphocytes in the presence of IL-2. SF also completely blocked the production or release of IL-2 by Con A-stimulated T cells. Thus, these bone marrow natural suppressor cells produced a soluble factor, which regulated the growth of rapidly proliferating bone marrow cells and also regulated T cell reactivity by modulating IL-2 production and activity.     

Suppression of Con A mitogen-induced proliferation of normal spleen cells by macrophages from chickens with hereditary muscular dystrophy

Spleen cells from chickens with hereditary muscular dystrophy (MD) give low blastogenic responses to the T cell mitogen concanavalin A (Con A) while exhibiting normal mitogen stimulated blastogenic responses to the T cell mitogen phytohemagglutinin (PHA). The addition of MD spleen cells to normal spleen cells caused a marked suppression of the Con A response of the normal cells while not affecting the PHA response of the normal cells. The suppressive activity by the MD spleen cells requires viable cells and is contact mediated. The suppressive activity is attributed to the presence in MD spleens of a population of suppressor cells with characteristics typical of macrophages. The suppressor cell activity was not removable by complement-mediated lysis using anti-T or anti-B sera, but it was reversible by treatment with carrageenan or carbonyl iron magnet, by passage through a Sephadex G-10 column, and by adherence to plastic petri dishes or glass beads. MD spleen cells depleted of the suppressor cell population remained unable to respond to Con A.     

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.     

In vitro growth of murine T cells. IV. Use of T-cell growth factor to clone lymphoid cells

Murine bone marrow cells can suppress the in vitro primary antibody response of normal spleen cells without apparent cytotoxicity. The bone marrow cells suppress the response to both T-dependent (SRBC) and T-independent (DNP-Ficoll) antigens. When bone marrow cells are fractionated on a sucrose density gradient, the suppressive activity is found in the residue rather than the lymphocyte fraction. The suppressive activity is either unaffected or enhanced by treatment with anti-T- and anti-B-cell serums. Pretreatment of mice with phenylhydrazine which reduces the number of pre-B cells did not reduce the suppressive activity of their bone marrow cells. Suppressive activity is abolished by irradiation of the marrow cells in vitro with 1000 R prior to assay. The activity is present in the marrow of thymus deficient (nude) mice, infant mice, and mice which have been made polycythemic by transfusion. Furthermore, the suppressor cell can phagocytize iron carbonyl particles, is slightly adherent to plastic and Sephadex G-10, and can bind to EA monolayers. We conclude that the suppressor cell is not a mature lymphocyte or granulocyte nor a member of the erythrocytic series, but is likely to be an immature cell possibly of the myeloid series. We speculate on the physiologic role of this cell.     

BCG-induced suppressor cells. I. Demonstration of a macrophage-like suppressor cell that inhibits cytotoxic T cell generation in vitro.

Spleen cells obtained from mice 5 to 40 days after infection with viable BCG organisms (BCG-spleens) were found to be unresponsive in vitro to both mitogenic and alloantigenic stimuli. Moreover, suppressor cells could be demonstrated in the spleens from these infected animals. When spleen cells from BCG-infected mice were added to either syngeneic or allogeneic normal spleen cells, the mixtures neither proliferated nor developed cytotoxic activity when cultured with alloantigen or with concanavalin A (Con A). The development of unresponsiveness post-infection paralleled the onset of suppressive activity. Spleen cells obtained from mice given heat-killed BCG were neither suppressive nor unresponsive. The suppressive activity of BCG-spleen cells was associated with an adherent, phagocytic cell that lacked membrane-associated Thy-1 antigen. Removal of this cell by passage through nylon wool columns resulted in a cell population that was no longer capable of suppression and that responded normally to alloantigen and to Con A. It would thus appear that BCG infection results in the development of a "suppressor" macrophage-like cell population within the spleen. The role of this cell type in regulation of the immune response in BCG-infected animals is as yet undefined.     

The immunoregulatory role of bone marrow. II. Characterization of a suppressor cell inhibiting the in vitro antibody response.

The addition of bone marrow cells (BMC) to spleen cell cultures suppressed the antibody response in a dose-dependent manner. This suppression required viable cells. Treatment of BMC with anti-thymocyte serum did not affect the suppressive activity and BMC, but not spleen cells, from nude mice inhibited the antibody response to the same degree as marrow from normal littermates. BMC which had been depleted of macrophages with antimacrophage serum or carbonyl iron showed increased suppressor activity. Furthermore, fractionation of BMC by velocity sedimentation and resetting revealed the suppressor cell to be a medium-to-large Fc receptor-positive lymphocyte. Absence of detectable B or T cell markers on the suppressor cell indicates this cell to be an Fc-positive null lymphocyte, possibly a precursor cell, which inhibits the response of mature lymphocytes     

Proliferative response of bone marrow cells to concanavalin A does not require Ia antigen-positive cells

The in vitro proliferative response of murine bone marrow cells to concanavalin A (Con A) and the effect of anti-Ia serum on the response were studied. The incorporation of [3H]thymidine into cells prepared from the bone marrow of C3H/He, ATL, ATH, and C57BL/6 mice increased in the presence of certain doses of Con A. The bone marrow cells of athymic nude mice were also capable of responding to Con A, but cells prepared from the spleens of such mice were not. The addition of anti-Ia serum to the cultures of bone marrow cells did not affect the responses of these cells to Con A, though their proliferative response to bacterial lipopolysaccharide was greatly reduced in the presence of the serum. Moreover, pretreatment of the bone marrow cells with anti-Ia serum or anti-Thy. 1.2 serum and rabbit complement did not abolish the ability of these cells to respond to Con A. These results indicate that there are some Ia negative and Thy. 1.2 negative cell populations in the marrow capable of responding to Con A. Furthermore, the effect of anti-Ia serum on the Con A-induced proliferative response of the spleen cells which had been obtained from gamma-irradiated and syngeneic bone marrow cell-reconstituted mice was examined. The ability of these cells to respond to Con A increased gradually week by week after the reconstitution. The suppressive effect of anti-Ia serum on the response of these cells gradually became much more pronounced after the reconstitution.     

Transfer of agammaglobulinemia in the chicken. I. Generation of suppressor activity by injection of bursa cells

Spleen cells from adult agammaglobulinemic (bursectomized) chickens taken 1 to 3 weeks after an injection of histocompatible bursa cells can inhibit the adoptive antibody response to B. abortus of normal spleen or bursa cells in irradiated recipients. Spleen cells from Aγ chickens not injected with bursa cells generally do not. Moreover, bursectomized chickens which have been reconstituted with spleen cells within the first week after hatching do not respond with suppressor cell formation upon bursa cell injection. This apparent “autoimmunization” with bursa cells induces suppressor T cells which are only minimally sensitive to treatment with mitomycin C or to 5000 R γ irradiation. The suppressor activity is neither induced nor potentiated by concanavalin A in vivo. It is much stronger in spleen than in thymus cells and appears to be macrophage independent and to require intact cells. The cell component which stimulates the suppressor activity is more pronounced on bursa than on spleen cells, and is at most present to a very limited extent on bone marrow, thymus, or peritoneal exudate cells. It is better represented in comparable cell numbers of Day 17 than of Day 14 embryonic bursa. The inducing cell component is present in the membrane fraction of disrupted bursa cells. Immunization with bursa cells from B locus histoincompatible chickens leads to suppressor activity against histocompatible bursa cells. Although the removal of Ig-bearing cells from bursa greatly diminishes its immunizing capacity, injection of serum IgM and IgG does not induce suppressor cells. It is suggested that tolerance to a B-cell antigen is lacking in adult Aγ chickens, resulting in an autoimmune response upon exposure to B cells. The B-cell antigen may be a cell surface-specific form of Ig, a complex of Ig and a membrane component, or a differentiation antigen which appears simultaneously with Ig during ontogeny.     

Lymphocyte function in human bone marrow. I. Characterization of two T cell populations regulating immunoglobulin secretion

We analyzed the regulation of immunoglobulin (Ig) production in short-term cultures of human (rib) bone marrow cells. In contrast to blood or tonsil cell cultures, large quantities of IgG and IgA, but not IgM, were secreted by unstimulated marrow cells. The addition of pokeweed mitogen or phytohemagglutinin resulted in the suppression of this Ig secretion. Both mitogens induced the production of high levels of interleukin 2 (IL 2) in marrow cultures, and the addition of IL 2 alone mimicked the suppressive effect of mitogens. Incubation of marrow cells with Epstein Barr virus resulted in enhanced Ig secretion, primarily of the IgM isotype. The addition of mitogen or IL 2 suppressed Ig production in these cultures as well. The mitogen-induced suppression of Ig secretion in stimulated or unstimulated marrow cultures was inhibited by the monoclonal anti-TAC (IL 2 receptor) antibody. Cell separation experiments indicated that the induction of suppressor activity in marrow cultures involved two distinct populations of marrow-resident T lineage cells. The first population responds to activation by mitogens with the production of IL 2. This population has a surface phenotype appropriate for helper T cells. The second T cell population expresses T8 and TAC determinants. These cells acquire suppressor cell activity after exposure to IL 2. The expression of suppressor function does not require additional (e.g., mitogenic) activation signals. The IL 2-dependent marrow suppressor T cells represent a newly recognized T lymphocyte subset. The regulatory pathway delineated may be important for the regulation of antibody formation in bone marrow, the major site of Ig production in man.     

Natural suppressor (NS) activity from murine neonatal spleen is responsive to IFN-gamma

Natural suppressor (NS) cell activity is the ability of apparently unprimed "null" cells to nonspecifically suppress immune responses. Previously we have shown that NS cell activity from the spleens of mice undergoing chronic graft-vs-host disease (GVHD) is enhanced in vitro by activated T cell signals (e.g., Con A supernatant [CAS]). Here we asked if the naturally occurring suppressor activity found in the neonatal mouse spleen is caused by NS cells, and if so whether this NS activity is also responsive to T cell signals. Finally, we wanted to identify the material in the CAS to which the NS cells respond. Spleen cells from (BALB/c X B10.D2)F1 neonates contain potent, genetically unrestricted suppressor activity toward normal mitogen responses. The cells responsible for this suppression are nonadherent, Thy-, Ig- and are thus by definition NS cells. Neonatal spleen NS cells suppress the indicator Con A response of all mouse strains tested, but their behavior with regard to LPS responses is different. They significantly inhibit the indicator LPS response of allogeneic strains, but are less inhibitory of LPS-stimulated syngeneic (BALB/c X B10.D2)F1 and parental strains. However, the addition of CAS to these latter cultures enhances the NS inhibition of the LPS response to the level of suppression seen with a Con A response. Two lymphokines were able to replace the CAS. Recombinant interferon-gamma (rIFN-gamma) closely mimics the activity found with whole CAS, with low concentrations (1 U/well) being capable of enhancing the neonatal NS activity to near-maximal levels. Recombinant interleukin 2 (rIL 2) is also capable of stimulating the neonatal NS activity to near maximum. However, the rIL 2 must be added at much higher concentrations, taking greater than 50 U/well to get maximum activation of NS suppression. The addition of anti-IFN-gamma antiserum to these LPS suppression assays removes the ability of CAS to activate the neonatal NS cells. Anti-IFN-gamma antiserum also removes the ability of rIL 2 as well as rIFN-gamma to activate the NS cells. It thus appears that the rIL 2 is working by its ability to stimulate IFN-gamma production. Anti-IFN-gamma also removes the ability of the neonatal NS cells to suppress a Con A response. Therefore, it appears that neonatal splenic NS cells respond to, and are activated by, IFN-gamma to carry out their suppressive activity.(ABSTRACT TRUNCATED AT 400 WORDS)     

The nature of immunodeficiency induced by injections of lectins and cyclophosphamide

Consecutive injections of T-cell mitogen (LcA, Con A) and cyclophosphamide (CY) produce an inhibition of T-cell, but not B-cell functions. This phenomenon was not a result of suppressor-cell activity of the action of some suppressor serum factors. Immunoreactivity of mice, treated with Con A CY is restored by thymocytes from intact donors, but not bone marrow cells. Using, monoclonal antibodies to Thy-1.2 antigen or anti-Ig serum it has been shown that pretreatment of mice with lectin and CY resulted in a decrease in T-cell, but not B-cell number in comparison with control mice. The above facts are indicative of CY-mediated elimination of T cells involved in proliferation and differentiation by lectin.     

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.     

Inhibition of ongoing myeloma IgE synthesis in vitro by activated human T cells

The ability of activated T cells to suppress ongoing IgE synthesis in vitro was assessed using U266--a human myeloma cell line spontaneously producing IgE. T cells were able to inhibit U266 IgE synthesis in the presence of 10 micrograms/ml of Con A by 41.8% (p less than 0.01). T cells preincubated with 10 or 50 micrograms/ml of Con A and washed extensively were still able to inhibit U266 IgE synthesis in the absence of Con A by 41 and 46% (p less than 0.05 and p less than 0.02, respectively). The decrease in IgE measured was due to inhibition of newly formed IgE by U266, as shown by control experiments with cycloheximide. The inhibition was not due to the simple depletion of nutrient growth factors by the activated T cells, as it did not occur with MOLT-4, T cells that are very active metabolically; nor could it be reversed with medium containing IL 2 and B cell growth factors. Culture supernatants of Con A-activated T cells were also able to suppress IgE synthesis by U266 (21%; p less than 0.01), which suggests that upon appropriate activation, T cells secrete material(s) with inhibitory properties for IgE synthesis. Activation of T cells by mixed lymphocyte culture using puromycin-treated lymphoblastoid cell lines as stimulators also generated T cells that had suppressive activity for IgE synthesis. T cells activated with Con A and subsequently incubated with IgE demonstrated a diminished ability to suppress IgE synthesis. This observation is in agreement with the finding that patients with high levels of IgE may lack isotype-specific suppressor T cells for spontaneous IgE secretion. However, T cells from such patients have so far shown variable loss of IgE suppressive function. These results suggest that human IgE synthesis is susceptible to inhibition at a very differentiated stage, and this may be important in expression of allergic diseases.     

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.     

The effects of lectins on the interaction between macrophages and bone in vitro

Summary Recent studies have demonstrated that the attachment of elicited rat macrophages to bone is mediated by specific saccharides located on the cell and/or bone surfaces. We have used a macrophage-bone culture system to study the effects of two lectins, concanavalin A (con A) and soybean agglutinin (SBA), on the morphology of macrophage attachment to a devitalized bone surface and subsequent functional activity. Macrophages were obtained from 3- to 4-week-old rats by peritoneal lavage and the adherent pool was used to prepare cell suspensions. Con A-treated, SBA-treated or control cell suspensions were aliquoted onto the endocranial surface of devitalized rat calvariae. The cells were allowed to attach for 1 h at 37° C, after which, the bone samples were removed from culture and prepared for scanning electron microscopy (SEM). The morphology of con A-treated macrophages attached to bone was markedly different from that of control or SBA-treated cells. Con A altered the attachment and subsequent spreading of macrophages on bone as visualized by SEM. Furthermore, the number of con A-treated cells that attached to bone and the average surface area of cell membrane apposed to the matrix was significantly different from that of control or SBA-treated cells. A ⁴⁵Ca bone-release assay was performed to evaluate the functional significance of the morphological findings. Lectin-treated or control cell suspensions were allowed to attach to the endocranial surface of ⁴⁵Ca pre-labeled calvariae for 1 h. Following attachment, the samples were cultured for 72 h. The con A-treated cultures demonstrated a significant decrease in the release of ⁴⁵Ca after 48 and 72 h in comparison to control cultures, while the ⁴⁵Ca released from SBA-treated cultures did not differ significantly from controls. These results suggest that certain sugar residues common to membrane-associated glycoconjugates and the organic component of the bone matrix regulate the attachment of macrophages to bone and their subsequent bone-resorbing activity.     

Spontaneously Induced Suppressor Cells In Vitro: Nonspecific Suppression of In Vitro Antibody Formation

Nonspecific suppressor cells were induced during in vitro culture of normal mouse spleen cells (SPC) using the Marbrook culture system. The suppressor cells inhibited both the primary and secondary antibody-formation responses antigen nonspecifically in vitro, and both IgM- and IgG-responses were inhibited. The supernatants from suppressive precultured cells were not suppressive. The suppressor cells also inhibited the response of allogeneic SPC beyond H-2 compatibility. The induction of the suppressor cells did not require the presence of antigen but required fetal calf serum (FCS) or both FCS and 2-mercaptoethanol (2-ME). The suppressor cells were generated from the nylon-wool adherent, radiation-sensitive T cell population. On the other hand, the suppressor cells were nylon-wool nonadherent, relatively radiation-sensitive T cells. Actively antibody-producing cells were not affected by the suppressor cells. The suppressor cells inhibited the mitogenic responses of normal SPC to phytohemagglutinin-P (PHA), bacterial lipopolysaccharide (LPS) and concanavalin A (Con A). The suppressor cells themselves inhibited the growth of EL4 cells (T-cell leukemia of C57BL/6 mouse origin) and MOPCll cells (B cells, plasmacytoma of BALB/c mouse origin) even at a low effector-to-target cell ratio (E:T ratio = 1:1), but did not kill these tumor cells. These results indicate that the target cells of the suppressor cells are both T and B cells, and that the mechanism of action of the suppression is either inhibition of proliferation or inhibition of early events in the course of the immune response.     

Role of prostaglandin E2 in the induction of nonspecific T lymphocyte suppressor activity

Activated human monocytes and concanavalin A (Con A)-activated T lymphocytes are known to suppress T and B lymphocyte proliferation and B cell maturation into immunoglobulin-producing cells. We have now shown that monocyte suppressive activity is predominantly mediated through release of prostaglandin E2 (PGE2), which is active only in the presence of a "short-lived," radiosensitive T lymphocyte subset. PGE2, at high concentration, can activate T suppressor lymphocytes (TS), which display the same characteristics as Con A-activated TS lymphocytes. Moreover, Con A activation of TS lymphocytes was obtained only in the presence of PGE2, as specific anti-PGE2 antiserum or indomethacin prevented TS activation; this suggested a double signal as a prerequisite for activation of the nonspecific TS cell subset. We propose that TS lymphocytes modified by Con A become sensitive to small amounts of PGE2 produced by monocytes that must be present during the Con A-stimulated activation phase of suppressive cells.