Suppressor cells function in healthy persons

The investigations were performed on lymphocytes isolated from peripheral blood of 26 healthy persons aged from 20 to 68 years. The following parameters were evaluated: T suppressor cell activity in two-step culture, concanavalin A (Con A) responsiveness in three-day culture and number of T lymphocytes carrying receptor for Fc portion of immunoglobulin G (TG cells). A slight increase in T suppressor activity and diminished responsiveness to Con A have been shown to be age-dependent. A correlation has been found between suppressor cells activity in vitro and the percentage of TG cells (r = 0.62, p less than 0.05). The level of suppressor activity of lymphocytes was independent of their Con A responsiveness.     

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.     

Concanavalin A-inducible suppressor cells in pleural effusions and peripheral blood of cancer patients

Summary Carcinomatous pleural effusions of 18 of 20 patients with lung cancer contained suppressor cell precursors that could be activated by concanavalin A (Con A) to suppress the proliferative responses of autologous and allogeneic lymphocytes to phytohemagglutinin and Con A. However, pleural effusion cells showed no suppressor function without prior activation by Con A. In contrast, the peripheral blood of the cancer patients exhibiting impaired mitogenic response contained nonspecific spontaneous suppressor cells capable of inhibiting the lymphoproliferative response to mitogens without prior activation by Con A, but these cells were not able to show further suppressor function even after activation by Con A. The maximum suppression was observed after 48-h treatment of lymphocytes with optimally mitogenic doses of Con A. The Con A-inducible suppressor cells of the pleural effusion and spontaneous suppressor cells of the peripheral blood of cancer patients had the same characteristics with regard to the capacity to suppress the mitogenic responses of autologous and allogeneic lymphocytes, belonging to the group of nylon wool-nonadherent T cells and being sensitive to in vitro culture and resistant to treatment with mitomycin C.     

Functional characterization of T lymphocytes grown in semisolid agar

T lymphocyte colony forming cells (TL-CFC) grown in agar in the presence of PHA were assayed for their capacity to induce or suppress polyclonal PWM dependent B lymphocyte differentiation into plasma cells. This was measured by identifying cells containing intracytoplasmatic immunoglobulins by direct immunofluorescence. To validate the helper and suppressor system used in this paper, the inductive capacity of unfractionated T lymphocytes and their subpopulations bearing Fc-receptors for IgM (TM) and for IgG (TG) was measured. The unfractionated T cells and the TM fraction showed helper activity, whereas the TG cells expressed suppressor activity. The TL-CFC grown in agar in the presence of PHA manifested helper activity at low cell concentration. However, increasing the TL-CFC concentration finally caused suppression of B cell differentiation. The suppressor effect could be abolished by prior irradiation of the TL-CFC before seeding them in agar. These results indicate that T cells grown in agar have the functional capacity of T helper and T suppressor cells to induce and suppress polyclonal PWM dependent B lymphocyte differentiation into plasma cells.     

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.     

Separation and characterization of human T G and T M lymphocyte populations

During the last few years a number of experimental evidences have shown the presence of Fc receptors for IgG or IgM on the membrane of human T cells. These two different receptors are detectable and mutually exclusive on distinct cell populations named respectively TG, TM and T "null" (which lack detectable receptors). Studies on the functional activities of these cells have shown that TM and TG lymphocytes play an antitetical role in regulating B cell response, TM exerting an "helper" activity on the differentiation of B lymphocytes while TG having a "suppressor" one. The aim of this study has been to determine the values of these two subpopulations in a group of twenty control subjects. Our results have shown that TG constitute 10%, whereas TM represent 40% of the total T cells. After EA-G rosetting, the purification of this subpopulation on a density gradient has shown an enrichment of more than 90% in TG cells, while TM contaminate this fraction for less than 4%. The purity of the fraction containing TM has been evaluated using the localization of alpha-naphthyl acetate esterase activity, which has shown that more than 88% of the cells in this fraction are positive for this enzyme.     

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.     

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.     

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.     

Interaction of reovirus with cell surface receptors. II. Generation of suppressor T cells by the hemagglutinin of reovirus type 3

In studying reovirus interactions with lymphocytes, we have found that reovirus type 3, but not type 1, inhibits the in vitro proliferative response of murine splenic lymphocytes to concanavalin A (Con A). By analyzing recombinant clones containing genes from both reovirus types 1 and 3, we found that the S1 gene, the gene that encodes the viral hemagglutinin, is responsible for the inhibitory effect. In addition we found that type 3, but not type 1, generates suppressor T cells in vitro capable of suppressing Con A proliferation. By analyzing recombinant clones, we also found that the viral hemagglutinin is responsible for the generation of suppressor T cells by reovirus type 3. These effects were observed whether UV-inactivated or live virus was used. Reovirus type 3 inhibition of the proliferative response of murine splenic lymphocytes to Con A was blocked by anti-reovirus type 3 antibody but not by anti-reovirus type 1 antibody. Antiviral antibody had no effect on the ability of reovirus type 3 induced suppressor cells to inhibit Con A proliferation. We have previously demonstrated a receptor on murine lymphocytes for the hemagglutinin of reovirus type 3, and our results suggest that the in vitro suppression of Con A proliferation of murine lymphocytes by reovirus type 3 is secondary to the interaction of the viral hemagglutinin with a receptor on the surface of murine lymphocytes, which results in the generation of functionally active suppressor T cells.     

The control of autoreactivity. I. Lack of autoreactivity in murine spleens is due to concomitant presence of suppressor and autocytotoxic lymphocytes.

To determine if autocytotoxic lymphocytes were naturally occurring in murine spleens, C57BL/6 spleen cells were fractionated on discontinuous BSA gradients. Autocytotoxicity was assessed in vitro (cytotoxicity of C57BL/6 fibroblasts) and in vivo (splenomegaly and popliteal node enlargement in C57BL/6 mice). A medium density subpopulation of lymphocytes was shown to be autocytotoxic and to be similar to autoreactive lymphocytes produced by the in vitro "sensitization" of splenic lymphocytes on syngeneic fibroblasts monolayers. The naturally occurring autocytotoxic lymphocytes express no detectable theta antigen, did not adhere to nylon, but did have an Fc receptor. In recombination experiments, BSA-fractionated lymphocytes were incubated with autocytotoxic and "sensitized" lymphocytes. A light density subpopulation was shown to suppress both autoreactive lymphocyte subpopulations at a 1:50 ratio. The suppressor cells were nylon nonadherent T lymphocytes. The lack of autoreactivity of unfractionated murine spleen cells is due to the concomitant presence of autocytotoxic and suppressor lymphocytes. If suppressor lymphocytes are selectively removed in vitro, the reactivity of autocytotoxic lymphocytes can be detected.     

The differentiation of suppressor cell populations as revealed by studies of the effects of mitogens on the mixed lymphocyte reaction and on the generation of cytotoxic lymphocytes.

The regulation by concanavalin A (Con A) and bacterial lipoloysaccharide (LPS) of the mixed lymphocyte reaction (MLR) and of the generation of cytotoxic lymphocytes (CL) was studied in congenic resistant mice using cortisone resistant thymocytes as the responding cells. LPS enhances the generation of CL selectively when suboptimal numbers of allogeneic cells are present in mixed lymphocyte cultures and also results in the augmentation of the MLR. Mitogenic concentrations of Con A on the other hand suppress the generation of CL regardless of alloantigen dose. The mechanism of suppression cannot be ascribed to the presence of suppressor T cells, since the addition to the cultures of syngeneic cortisone resistant thymocytes activated by Con A does not change the immune response. However, prospective suppressor cells that can be activated by Con A are located in secondary lymphoid organs such as spleen and lymph node. Suppressor activity by those cells is abolished by anti θ plus complement. Con A activated spleen cells suppress the MLR, whereas Con A activated thymocytes amplify the proliferation of responding cells.     

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.     

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.     

Morphologic and phenotypic features of the subpopulation of Leu-2+ cells that suppresses B cell differentiation

The Leu-2 antigen is expressed on a subpopulation of human T cells that perform suppressor and cytotoxic functions. In addition, this antigen is also present on a portion of cells with morphologic characteristics of granular lymphocytes. Although both Leu-2+ cells and granular lymphocytes have been shown to suppress B cell differentiation, the interrelationship of these two suppressor populations has not previously been fully characterized. We recently produced a monoclonal antibody, termed D12 (anti-Leu-15), which reacts with a variety of cell types, including a subpopulation of Leu-2+ cells. Previous studies have indicated that the Leu-2+ cells that suppress T cell proliferative responses express the Leu-2+15+ phenotype, whereas the precursor and effector cytotoxic T cells that recognize class I major histocompatibility antigens are Leu-2+15- lymphocytes. For this report, we used the anti-Leu-2 and anti-Leu-15 monoclonal antibodies and fluorescence-activated cell sorter techniques to characterize the E+ cells that suppress PWM-induced B cell differentiation. These studies indicate that the vast majority of Leu-2+ cells that suppress this T cell-dependent B cell response have the Leu-2+15+ phenotype. Furthermore, when the morphologic and cytochemical characteristics of these Leu-2+15+ cells were studied, virtually all of these cells were granular lymphocytes. Most of the Leu-2+15+ suppressor cells co-expressed the HNK-1 (Leu-7) antigen, which is detected only on granular lymphocytes. In contrast, virtually none of the Leu-2+15+ granular lymphocytes expressed Fc receptors for IgG molecules. These data indicate that the Leu-2+ cells that suppress PWM-induced B cell differentiation are Leu-2+15+ (and predominantly Leu-7+) granular lymphocytes that do not express Fc receptors. The implications of these observations concerning the relationship of human Leu-2+ suppressor cells to murine Ly-2+ cells and the lineage of granular lymphocytes are discussed.     

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.     

Functional properties of a lymphocyte subpopulation responding to low suboptimal doses of concanavalin A

Incubation of human peripheral blood lymphocytes with concanavalin A (Con A), in a low suboptimal dose (0.5 microgram/ml), results in formation of the cells that inhibit proliferation of autologous cells in cultures activated with optimal but not with suboptimal dose of the mitogen. Nevertheless, 50 micrograms/ml Con A-activated cells efficiently suppress proliferation everywhere. Cell preincubation during 18 h before Con A activation leads to a reduction of lymphocyte responses to the mitogen in cultures reactivated with 5 micrograms/ml Con A in a mixture with autologous lymphocytes, containing no mitogen. Activation of T-T helper cells providing suppressor T cells differentiation seems to take place in the presence of a low suboptimal dose of Con A. Besides, 0.5 microgram/ml Con A prevents the preincubation-induced elimination of some lymphocytes responding to an optimal dose of Con A and autologous lymphocytes.     

Fractionation of lymphocyte subpopulations which regulate mixed lymphocyte reactions.

Four days after injection of allogeneic lymphocytes BALB/c splenic T cells suppress proliferation of syngeneic cells in mixed lymphocyte reactions (MLR). Conversely, lymph node cells from the same mice amplify MLR responses. To further characterize these functional subpopulations, alloantigen-primed lymphocyte suspensions from both organs were fractionated by velocity sedimentation at unit-gravity. After fractionation MLR suppressor cells from spleens localized exclusively in rapidlly sedimenting fractions of large cells. MLR suppressor activity of cells from these fractions, as well as that of unfractionated spleen cell suspensions, was abolished by treatment with anti-Thy-1.2 serum and complement. Spleen cell fractions of similar sedimentation velocity also secreted a soluble MLR suppressor into culture supernatants. Although inhibitory of MLR, spleen cells of rapid sedimentation velocity did not suppress responses to T cell mitogens. In marked contrast with the effects of spleen cells, large 4-day-alloantigen-primed lymph node cells had no suppressive activity in MLR. MLR amplifier cells of uncertain derivation were found in fractions of medium sedimentation velocity from both spleens and lymph nodes. Fractionation of alloantigen-primed lymph node cell suspensions did reveal, however, a subpopulation of small cells with MLR suppressor acitivty which was unaffected by treatment with anti-Thy-1 serum and complement. The data thus indicate that large alloantigen-activated lymphocytes are not intrinsically suppressive nor are cells which suppress MLR necessarily large. We consequently conclude that regulation of MLR responses by alloantigen-primed lymphocytes involves a complex interaction between distinct functional subpopulations of cells which are separable both by physical and biologic properties.     

In vitro immune response of human peripheral lymphocytes. II. Properties and functions of concanavalin A-induced suppressor T cells.

Con A-stimulation of human peripheral T lymphocytes induced both suppressor and helper T cells. ConA-generated suppressor T cells inhibited PWM-induced IgG and IgM production in PBL. Lower concentrations of Con A (0.5 micrograms/ml) or shorter incubation periods (6 to 24 hr) induced mainly helper T cells, while higher concentrations of Con A (10 micrograms/ml) or longer incubation periods (at least 48 hr) induced suppressor T cells. Con A-generated suppressor T cells were sensitive to mitomycin treatment and exerted their suppressor function on the early phase of differentiation and/or proliferation of B cells but not on the final differentiation of B cells to Ig-producing cells. The identity of the MHC was not required for the expression of suppressor function. Suppressor T cells competed with helper T cells in PWM-induced Ig-production of PBL. This experimental system can be applied to estimate the regulatory function of T cells in several disease states.     

Characterization of thymus-derived lymphocyte subsets in acute Epstein-Barr virus-induced infectious mononucleosis.

Changes in thymus-derived (T) lymphocyte subpopulation numbers were studied in patients with acute and convalescent Epstein-Barr virus (EBV)-induced infectious mononucleosis (LM). T cell subsets were characterized by the presence of Fc receptors for IgG (TG), for IgM (TM) or by the absence of either receptor (Tnon-M, non-G). We found that in acute IM, total numbers of T and B lymphocytes were elevated (p less than 0.01). Of the T lymphocyte subsets, the total number of Tnon-M, non-G lymphocytes was increased six fold compared to normal subjects (p less than 0.001) and included the majority of the atypical T lymphocytes. The number of total TG and TM lymphocytes was moderately increased (p less than 0.05). In convalescent IM patients, the number of total T cells remained slightly elevated (p less than 0.02) whereas proportions and absolute numbers of B lymphocytes and T cell subsets returned to near normal levels. Thus, acute Epstein-Barr virus-induced IM is associated with a T lymphocytosis which is composed predominantly of atypical T cells which lack detectable Fc receptors for IgG or IgM.