A partial characterization of suppressor cells in rat fetal liver cells

Rat fetal liver cells (FLC) obtained at 18–20 days gestation suppressed mixed lymphocyte reactions(MLR) of adult lymph node cells. The suppression was not strain specific: both syngeneic and allogeneic FLC were capable of suppressing the MLR. The same suppressor activity was observed with fetal spleen cells but not with fetal thymus cells. Removal of phagocytic cells from FLC failed to inhibit the suppressor activity. The suppressor cells were separated into two different types by BSA density gradient: one is radiosensitive, the other radioresistant. A stronger suppressor activity was observed in radiosensitive cells. The suppressor cells belonged to the fraction agglutinated with peanut agglutinin. The data suggest that the suppressor cells in rat FLC may be a proliferating blastoid-type cell rather than mature lymphocytes or mature macrophages.     

Contact sensitivity to picryl chloride: the occurrence of B suppressor cells in the lymph nodes and spleen of immunized mice.

Mice were immunized for contact sensitivity and antibody production by painting the skin with picryl chloride. Lymph node and spleen cells taken 4 days later transferred contact sensitivity. However, cells taken at 7–8 days failed to transfer but were able to block the transfer by 4 day immune cells. These suppressor cells occurred in the regional lymph nodes, spleen and thymus. The suppressor activity of lymph node and spleen cells was due to B cells as shown by the effect of anti-θ serum and complement, nylon wool filtration and separation of EAC positive and negative cells by centrifugation on a discontinuous gradient. The transfer of fractions rich or poor in macrophages showed that the suppressor cell in the transferred population was not a macrophage. Separation using EAC rosettes suggested that B cells were responsible for the suppressor activity in the thymus.T cells isolated from the lymph nodes and spleen 7–8 days after immunization transferred contact sensitivity although the initial population was inactive. This indicates that passive transfer cells are present in the regional lymph nodes and spleen at later times after immunization but cannot be demonstrated because of the presence of suppressor B cells. However, no passive transfer cells were found in the thymus. The production of B suppressor cells required little or no T cell help and following immunization the spleens of reconstituted (B) mice were at least as active as control cells in causing suppression. There are several different suppressor cells which act in the picryl system and the B suppressor cells in immunized mice described here are distinct from the T suppressor cells in mice injected with picryl sulphonic acid.     

Failure of NZB spleen to respond to prethymic bone marrow suppressor cells.

Mouse bone marrow contains theta-negative lymphocytes that can suppress an in vitro plaque response by spleen cells primed in vivo with burro red blood cells (BRBC). These bone marrow cells are radiosensitive and can be induced with thymosin fraction 5 or alpha 1 thymic peptides to express the theta antigen. Enrichment for these suppressor pre-T lymphocytes can be achieved by a one-step density centrifugation, macrophage depletion, or a combination of both procedures. NZB mice, which spontaneously develop an autoimmune disorder, have a suppressor abnormality revealed by this assay system. Upon analysis, they have normal BM pre-T suppressor cells but their spleen cells are refractory to the BM suppressor signal. NZB BM suppressor cells inhibit the response by DBA/2 spleen cells, but DBA/2 BM suppressor cells do not inhibit NZB spleen. This resistance to suppression is a property of the B cell fraction recovered from NZB spleen.     

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 experimental African trypanosomiasis. III. Loss of lymph node cell responsiveness

The relationship between immunosuppression and suppressor cell activity in the lymphoid organs of animals with experimental African trypanosomiasis has been examined further. In the present study we measure the primary in vitro PFC response to SRBC by spleen and lymph node cells from Trypanosoma rhodesiense infected or drug-cured C57BL/6 mice. Passive transfer experiments with this culture system tested for the presence or absence of suppressor cells. We demonstrate that infected mice exhibit immunosuppression in the spleen cell population several weeks before becoming suppressed at the level of the lymph node cell populations. Although suppressor cells are present in immunosuppressed spleen cell populations, suppression of lymph node cell responsiveness was not attributable to suppressor cells detectable withi, lymph nodes. After Berenil treatment of terminally infected mice immunocompetence was restored gradually, first to the lymph node cells and subsequently to the spleen cell population. Recovery of spleen cell responsiveness was attributable to the loss of detectable suppressor cell activity within spleens. These results demonstrate that there is anatomical restriction of the suppressor cell population to trypanosome-infected mouse spleen and that loss of immunocompetence in the lymph nodes may be due to factors unrelated to suppressor cell effects.     

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.     

Induction of suppressor cells by a tumor-derived suppressor factor

Murine fibrosarcomas produce a factor that activates suppressor cells to inhibit expression of delayed-type hypersensitivity (DTH) responses to dinitrochlorobenzene (DNCB). This tumor-derived suppressor factor (TDSF) was partially purified by preparative isoelectric focusing of spent medium and 3 M KCl extracts of cultured methylcholanthrene-induced and spontaneous fibrosarcomas of C3H/He mice. Incubation of 1 micrograms/ml of a fraction, isoelectric pH less than 2.9, with normal syngeneic spleen cells for 1-6 hr at 37 degrees C induced suppressor cells that inhibited the primary DTH response to DNCB upon intraperitoneal transfer to normal C3H/HeJ mice. TDSF was not present in extracts of either syngeneic embryonic fibroblasts or normal spleen cells or in medium conditioned by normal peritoneal exudate cells but was present in 3 M KCl extracts of and the spent medium from four different cultured murine fibrosarcomas. TDSF activity was not restricted at the major histocompatibility complex. The suppressor cells inhibited the efferent limb of the DTH response because (1) hyporesponsive recipients of TDSF-treated spleen cells had splenic effector T cells capable of transferring DTH to DNCB into naive secondary recipients and (2) the ability of Lyt 1+,2- effector Tdth cells to transfer a secondary DTH response to DNCB was inhibited by co-incubation with macrophages or Lyt 1-,2+ T cells treated with TDSF. Preliminary biochemical analysis suggested that TDSF was an RNA- protein complex. Thus, several murine fibrosarcomas produced a soluble factor that activated splenic suppressor cells to depress the immune response to nonneoplastic antigens. These suppressor factors represent a novel group of regulatory molecules which may be ribonucleoprotein complexes.     

Suppression of mitogen-induced proliferation of normal spleen cells by macrophages from chickens inoculated with Marek's disease virus

Spleen cells from chickens 7 days after inoculation with Marek's disease virus (MDV) responded poorly to stimulation by phytohemagglutinin (PHA). Addition of these cells to syngeneic normal spleen cells caused of marked suppression of the PHA response of the normal cells. The MDV spleen cells also inhibited the DNA synthesis of MSB-1 lymphoblastoid cells in vitro. The suppressive activity is attributed to the presence in MDV spleen cells of a population of suppressor cells with characteristics typical of macrophages. The suppressor cell activity was not removable by treatment with anti-T or anti-B serum with C, but it was reversible by treatment with carrageenan or carbonyl iron/magnet, by passage through glass wool column, and by adherence to plastic Petri dishes. The adherent MDV spleen cells also showed strong suppressor cell activity against syngeneic normal spleen cells.     

Characterization of suppressor cells in mice bearing syngeneic mastocytoma.

Suppressor cells from syngeneic P815 mastocytoma-bearing DBA/2 mice that inhibit in vitro generation of specific anti-tumor cytotoxicity were characterized. Suppressive activity was almost completely eliminated by treating suppressive spleen cells with anti-theta serum and complement. Treatment with anti-mouse lg serum and complement or with carbonyl iron did not affect their suppressive activity. When suppressive thymocytes from P815 tumor-bearing DBA/2 mice were tested for their capacity to inhibit the generation of cytotoxicity against L1210 cells, a leukemia line in DBa/2 mice, they did not affect the activity, indicating that the supressor cells in the thymocytes of P815 tumor-bearing mice are specific to the tumor. When Ficoll-Hypaque density cell separation was carried out with cytotoxic spleen cells and suppressive spleen cells from 815 tumor-bearing mice, the dense fraction was enriched for kiler cells whereas the suppressive activitty was mainly recovered in the light fraction. Therefore, killer cells and suppressor cells in P815 tumor-bearing mice are thought to be distinct populations.     

In vitro generation of suppressor cell activity: suppression of in vitro induction if cell-mediated cytotoxicity.

It was observed that when normal mouse spleen cells were cultured alone in vitro (precultured) for 3 to 7 days, these cells lost the ability to generate cell-mediated cytotoxicity (CML) during subsequent in vitro sensitization with allogeneic spleen cells, trinitrophenyl (TNP)-modified syngeneic spleen cells, or syngeneic tumor cells. These precultured cells, which were themselves unable to generate CML, were also shown in mixing experiments to suppress, actively, the generation of CML by freshly explanted spleen cells. Suppression occurred at the sensitization phase of CML, and not at the effector level; supernatants from suppressive precultured cells were not suppressive. Suppression was totally abrogated by the treatment of spleen cells with a T cell-specific rabbit anti-mouse brain serum and complement (RalphaMB+C) either before or after preculturing, suggesting that a T cell eas essential both to the generation of suppressor activity and to its expression. Suppressor activity was entirely absent in precultured nylon wool column-nonadherent spleen cells, a T cell-enriched population containing most of the RalphaMB+C-sensitive cells in the spleen. Precultured nylon column-adherent cells (T cell-depleted) did have suppressive activity, and a mixture of nylon-adherent and nylon-non-adherent cells was a suppressive after preculture as the precultured unseparated spleen. Moreover, the ability of nylon-adherent spleen cells to generate suppressive activity during preculturing was abrogated by treatment with RalphaMB+C. Thus, the "spontaneous" generation of CML-suppressive activity was dependent upon a limited subpopulation of splenic T cells isolated in the nylon column-adherent fraction. The relationship of these data to a previously described synergy between subpopulations of normal spleen in the generation of CML is discussed, and the findings related to other suppressor systems described in the literature.     

Macrophage-mediated suppression of immune responses in Toxoplasma-infected mice. I. Inhibition of proliferation of lymphocytes in primary antibody responses

The suppressor cells induced by Toxoplasma infection were shown to be macrophages, since they adhered to plastic, and their suppressive activity in anti-sheep erythrocytes (SRBC) antibody responses was abrogated by treatment with silica or carrageenan, which are selectively cytotoxic for macrophages. The suppressor macrophages strongly inhibited the uptake of tritiated thymidine ( [3H]TdR) by normal mouse spleen cells in the responses to SRBC and Toxoplasma antigens. Supernatant fluids from the suppressor macrophages could not passively transfer the suppressive effect on anti-SRBC antibody responses. Furthermore, when the suppressor macrophages were isolated by a cell-impermeable membrane from normal mouse spleen cells, the antibody responses of normal spleen cells were not suppressed. These results indicate that suppression of antibody responses in Toxoplasma-infected mice is caused by an inhibitory effect of the suppressor macrophages upon proliferation of lymphocytes via direct contact with responder target cells. The suppressive effect of the macrophages was not counteracted by indomethacin, a potent inhibitor of prostaglandin synthesis, or catalase, a catabolic enzyme for hydrogen peroxide (H2O2).     

Reaginic antibody formation in the mouse. VII. Induction of suppressor T cells for IgE and IgG antibody responses.

Intravenous injections of urea-denatured ovalbumin (UD-OA) into OA-primed high responder mice suppressed the antibody response not only to the priming antigen but also to subsequent immunization with dinitrophenyl derivatives of OA (DNP-OA). The transfer of normal spleen cells or OA-primed spleen cells into UD-OA-treated animals did not restore the capacity of responding to DNP-OA to form anti-DNP IgE and IgG antibodies. The transfer of splenic T cell fraction from the UD-OA-treated animals into normal syngeneic mice diminished both IgE and IgG antibody responses of the recipients to DNP-OA. The B cell-rich fraction from the same donors failed to affect the anti-hapten antibody response and enhanced anti-cancer (OA) IgG antibody response of the recipients. It was also found that the transfer of T cell-rich fraction of OA-primed spleen cells failed to suppress antibody response of the recipients to DNP-OA. The results indicated that spleen cells of UD-OA-treated mice contained suppressor T cells which are distinct from helper cells. Suppressive activity of T cells in the UD-OA treated animals was specific for OA. The transfer of the T cell-rich fraction failed to suppress anti-DNP antibody response of the recipients to DNP-KLH.     

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.     

Characteristics of the splenic suppressor cell--target cell interaction in experimental African trypanosomiasis

We have examined further the relationship between immunosuppression and suppressor cell activity in experimental African trypanosomiasis. In the present study we describe the nature of the interaction between splenic suppressor macrophages from Trypanosoma rhodesiense-infected C57BL/6 mice and target effector cells in the primary in vitro PFC response to SRBC. Suppressor cell potential was expressed only when cell-cell contact of a noncytolytic nature was established between infected spleen cells and normal splenic responder cells. Isolation of suppressor cells from responder cells by a cell-impermeable membrane completely abrogated suppression. Similarly, supernatant fluids from infected spleen cell cultures could not passively transfer suppression. Suppressor cells did not act via prostaglandin synthesis in that indomethacin failed to restore responsiveness to infected spleen cells or to passively suppressed normal cultures. Inhibition of DNA synthesis by irradiation of mitomycin C treatment did not block suppressor cell function, but suppressor cell effects were inhibited by exposure of infected spleen cells to silica particles or to heat treatment. We conclude that suppressor cell effects in experimental African trypanosomiasis are consistent with a suppressor macrophage acting via a noncytolytic cell-cell interaction with responder target cells.     

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.     

Proliferation of natural suppressor cells in long-term cultures of spleen cells from normal adult mice.

Natural suppressor cells were induced by culturing spleen cells from normal adult mice for 2 to 3 wk. The suppressor cells were large in size, nonadherent and nonspecifically suppressed the plaque-forming cells response of fresh spleen cells to SRBC in vitro. The suppressive activity of the cells was not affected by treatment with indomethacin or anti-Thy-1, anti-Ig, anti-Ia, or anti-asialoGM1 plus complement. Phenotype analysis by FACS showed that Thy-1, L3T4, Ly-2, CD3-epsilon, TCR-alpha beta, Ig, B220, Ia, and asialoGM1 Ag were all absent in the suppressor cells, although they were wheat germ agglutinin receptor positive. The suppressor cells did not demonstrate cytotoxicity against either YAC-1 or P-815 cells. Enriched large cell populations from fresh normal spleens expressed the same phenotypes and also exhibited the suppressive activity. These findings suggest that a minor population of natural suppressor cells exist in the normal adult mouse spleen and they proliferate during the in vitro culture of spleen cells.     

A splenic requirement for the generation of suppressor T cells.

Tolerance to contact sensitization with DNFB may be induced by DNBSO3. This specific unresponsiveness may occur via one or both of two mechanisms--production of suppressor T cells or clone inhibition. We investigated the role of the spleen in this unresponsiveness. Splenectomized mice may be tolerized by i.v. injection of DNBSO3, but they are incapable of serving as donors of lymph node cells for transfer of tolerance to normal recipients. Kinetic studies indicated that the spleen must be present at least three days after tolerization in order to permit development of a significant number of suppressor cells in the peripheral lymph nodes. We interpret these results to indicate that 1) clone inhibition does not require the spleen, 2) the generation of suppressor T cells is dependent on the presence of the spleen, and 3) it is likely that tolerogens in this system induce suppressor cells in the spleen and some of these cells or their products leave the spleen to reach the peripheral lymph nodes.     

Macrophages suppress CTL generation in rat mixed leukocyte cultures.

The generation of CTL in rat MLC was actively suppressed by a cell population present in spleen cell preparations from normal rats. These suppressor cells were characterized by using a variety of cell fractionation techniques. Suppressor cells were removed by passage of spleen cells through nylon wool columns or by treatment with carbonyl iron. Suppressive activity was present in the mononuclear cell fraction of spleen cells obtained by Ficoll-Hypaque density gradient centrifugation. After velocity sedimentation at unit gravity, enrichment of suppressive activity was demonstrated in the fractions containing large cells as compared to the fractions containing small cells. Populations rich in macrophages were shown to have similar suppressive activity upon CTL induction in MLC. These studies suggest that macrophages present in normal rat spleen cell preparations account for the difficulty in generating CTL in MLC prepared with rat cells.     

Immunologic tolerance to HGG in mice. I. Suppression of the HGG response in normal mice with spleen cells or a spleen cell lysate from tolerant mice.

Adoptive transfer of spleen cells or spleen cell lysates from mice tolerant to human-gamma-globulin (HGG) specifically suppressed the response of normal syngeneic recipients to HGG. The suppressive activity could be transferred for over 100 days after tolerance induction. The suppression induced by both spleen cells and spleen cell lysate was found to be specific as evidenced by a normal response to a challenge with turkey-gamma-globulin or goat erythrocytes. The activity of the suppressive lysate could be removed by passing the material through an HGG immunoadsorbent column but not by passing it through an anti-HGG column or a BSA column. These results indicated that the factor had antigen specificity and was probably not antigen-antibody complexes. That this suppression was not due to a shifting of the kinetics of the antibody response has also been demonstrated. The antigen-specific suppressor factor in the tolerant spleen cell lysates was a protein with a m.w. of approximately 45,000 daltons. The kinetics of the appearance of both suppressor cells and suppressor factor were consistent with a mechanism of active suppression functioning in the maintenance of tolerance to HGG.     

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