Mouse fetal liver cells manifest antigen-specific suppressor activity

Liver cells obtained from C57B1/6J mice at different stages of development suppress the primary in vitro induced immune response. Fetal liver cells showed the strongest suppression of the PFC response, an effect which was gradually lost after birth. Thymic or splenic cells were ineffective in suppressing the PFC response under conditions where fetal liver cells from the same donors were highly active. Liver cells from newborn C57B1/6J athymic nude mice were equally suppressive as cells from their normal thymus-bearing littermates. Preculture of liver cells from 18-day-old fetuses with antigen homologous to that used in the indicator system increased suppressor activity severalfold compared with other experimental groups in which cells have been precultured in medium alone or with the addition of a heterologous antigen. The data suggest that antigen-specific suppressor activity is present in fetal liver cells. The possible relevance of these findings in relation to acquisition of self-tolerance is discussed.     

IgE-binding factors from mouse T lymphocytes. III. Role of antigen-specific suppressor T cells in the formation of IgE-suppressive factor

BDF1 mice were given three i.v. injections of ovalbumin (OA) to induce antigen-specific suppressor T cells. Incubation of spleen cells of OA-treated mice with homologous antigen resulted in the formation of IgE-suppressive factor. This factor was not derived from antigen-specific suppressor T cells, but suppressor T cells were essential for determining the nature of IgE-binding factors formed. In the spleen cells of OA-treated mice, antigenic stimulation of antigen-primed Lyt-1+ (helper) T cells resulted in the formation of inducers of IgE-binding factor, whereas Lyt-2+, I-J+ T cells released glycosylation-inhibiting factor (GIF), and these two factors, in combination, induced unprimed Lyt-1+ T cells to form IgE-suppressive factor. The role of GIF is to inhibit the assembly of N-linked oligosaccharides on IgE-binding factors during their biosynthesis, and thereby provide them with a biologic activity: suppression of the IgE response. Under the experimental conditions employed, GIF was released spontaneously from antigen-specific suppressor T cells. However, antigenic stimulation of the cells enhanced the release of the factor. GIF from antigen-specific suppressor T cells has a m.w. of 25,000 to 30,000, as estimated by using gel filtration, binds to anti-I-J alloantibodies and to a monoclonal antibody specific for lipomodulin, and has affinity for specific antigen. The possible relationship between antigen-specific GIF and antigen-specific suppressor factors is discussed.     

In vivo generation of suppressor T cells by thymosin in congenitally athymic nude mice

Treatment of nude mice with thymic factors such as thymosin has been mostly ineffective in generating effector T cells. This study examined the effects of treating nude mice with thymosin fraction 5 on the induction of cells that could participate in and/or regulate cytotoxic T lymphocyte (CTL) generation by normal spleen cells in vitro. Splenic lymphocytes from BALB/c nude mice injected with thymosin fraction 5 every other day for 2 wk were tested for their ability to generate CTL in vitro. Two days after the last subcutaneous injection of thymosin, nude spleens were removed, mixed with normal BALB/c spleen cells, and placed into a mixed lymphocyte tumor culture (MLTC) against allogeneic RBL 5 tumor cells. After a 5-day incubation, cultures were tested for the presence of CTL in a 4-hr 51Cr-release assay. Spleen cells from thymosin-treated nude mice did not generate CTL but suppressed the ability of normal spleen cells to generate CTL in vitro. Characterization of the thymosin-induced nude mouse suppressor cells showed them to be Thy 1 positive, nonadherent, cyclophosphamide-sensitive T cells. These data demonstrate that some T cell maturation occurs in vivo under thymosin influence. However, the activity of these cells is initially limited to a regulatory function. These studies suggest that maturation of functional suppressor T cells occurs before CTL. Further immunologic manipulation appears to be necessary in order to induce CTL effector cells in nude mice.     

Spleen cells from adult mice given total lymphoid irradiation (TLI) or from newborn mice have similar regulatory effects in the mixed leukocyte reaction (MLR). II. Generation of antigen-specific suppressor cells in the MLR after the addition of spleen cells from newborn mice

Spleen cells from newborn BALB/c mice were added to the mixed leukocyte reaction (MLR) between a variety of responder and stimulator cells. The newborn cells nonspecifically suppressed the uptake of (3H)-thymidine and the generation of cytolytic cells regardless of the responder-stimulator combination used. Suppressor cell activity fell rapidly during the first 4 days after birth, and could not be detected by day 20. Newborn spleen cells inhibited the generation of nonspecific suppressor cells during the MLR but did not inhibit the generation of antigen-specific suppressor cells. Thus, newborn spleen cells exhibit a pattern of regulation of the MLR similar to that reported previously for spleen cells from adult mice given total lymphoid irradiation (TLI). These regulatory interactions provide a model that explains the ease of induction of transplantation tolerance in vivo in newborn mice and in TLI-treated adult mice.     

Suppression and contrasuppression in athymic nude mice: nude mice produce the antigen-specific component of a T suppressor factor that inhibits the late 24-hr phase of DTH but do not generate suppression nor contrasuppression of the early initiating phase of DTH.

Previous studies demonstrated that the initiation of murine delayed-type hypersensitivity (DTH), as exemplified by contact sensitivity induced by picryl chloride (PCI) or oxazolone (OX), is due to antigen-specific, T cell-derived, DTH-initiating factors called, respectively, PCl-F and OX-F. These factors participate in the extravascular recruitment of CD4+, Th-1, DTH effector T cells in the elicitation of DTH. Related factors also participate, together with nonantigen binding factors derived from CD8+ T cells, to constitute an antigen-specific T cell-derived suppressor factor (TsF) that can down regulate the ability of Th-1 effector T cells to mediate DTH. Since it was shown recently that athymic nude mice can make antigen-specific, DTH-initiating T cell factors, the current study tested whether nude mice also could produce the antigen-specific component of the TsF that suppresses DTH effector T cells. We found that antigen-specific factors from nu/nu mice could complement the nonantigen-binding subfactor produced in normal mice to constitute the whole antigen-specific TsF. Additional studies showed that the successful adoptive cell transfer of DTH-initiating T cell activity from nude mice into normal mice required cyclophosphamide treatment of the recipient. In contrast, transfer of DTH-initiating cell activity from nu/+ mice did not require cyclophosphamide treatment of the recipients. We hypothesized that nude mice lacked contrasuppressor cells. Although nude mice were able to manifest the early, initiating phase of DTH, we found that there was no suppression of early DTH-initiating T cells in nude mice, compared to nu/+. Therefore the production of DTH-initiating T cell factor could be boosted in nude mice. The ability to boost DTH-initiating cells in nude mice should facilitate the development of cell lines and clones with the ability to initiate DTH.     

Suppression of delayed-type hypersensitivity to third party "bystander" alloantigens by antigen-specific suppressor T cells

Delayed-type hypersensitivity (DTH) against alloantigens can be induced by sc immunization with allogeneic cells. The induction of DTH can be suppressed by iv preimmunization of the mice with similar allogeneic spleen cells, provided the cells are irradiated before injection. This suppression is mediated by T cells. The suppressor activity can be induced not only by H-2-and non-H-2-coded antigens, but also by H-2 subregion-coded antigens. Suppression induced by K, I, or D subregion-coded antigens is specific for that particular subregion as well as for its haplotype. I-J-coded alloantigens were found to not be necessary for the induction of antigen-specific suppressor T cells. After restimulation of suppressor T cells by the "specific" alloantigens, the DTH to simultaneously administered third-party alloantigens becomes suppressed as well. This nonspecific suppression of DTH to third party "bystander" alloantigens also occurs when the specific and the third-party antigens are presented on separate cells, provided that both cell types are administered together at the same site. The simultaneous presentation of both sets of alloantigens during the induction phase of DTH only is sufficient to prevent the normal development of DTH to the third-party antigens.     

In vitro activation of suppressor cells from spleens of mice treated with radioactive strontium

Mice were treated with two 100-muCi injections of 89Sr to deplete marrow-dependent (M) cells. Mice so treated responded normally to immunization with sheep red blood cells (SRBC) in vivo; moreover, spleen cells from 89Sr-treated mice were able to respond to SRBC after infusion into irradiated recipient mice. However, spleen cells from mice treated with 89Sr did not respond to SRBC in vitro and mixtures of normal spleen cells with the latter were also not able to respond in vitro. The discrepancy between in vivo and in vitro responses was abolished by culturing spleen cells for 24 hr before testing their ability to respond to SRBC in the adoptive transfer in vivo. Pretreatment of spleen cells from 89Sr-treated mice with 1000 R of gamma-radiation lessened their suppressive activity. The suppressor cells were detected in spleens of athymic nude mice treated with 89Sr. The suppressive activity, after the 24-hr culture period, was not abolished by irradiation and was active in vivo as well as in vitro. Thus, depletion of M cells by 89Sr results in the appearance within the spleen of thymus-independent suppressor cells, which require a short period of in vitro cultivation before becoming functionally active.     

Simultaneous induction of antigen-specific IgA helper T cells and IgG suppressor T cells in the murine Peyer's patch after protein feeding

The effects of feeding the dietary protein antigen, ovalbumin (OVA), on OVA-specific IgG and IgA immune responses involving Peyer's patches (PP) and mesenteric lymph nodes (MLN) were examined. Mice were administered soluble OVA by gastric intubation. One to 3 days later, PP, MLN, or spleen cells from these donor mice were adoptively transferred into normal syngeneic recipients. After two subsequent immunizations, spleens from the recipient mice were assayed for IgA and IgG anti-OVA plaque-forming cell (PFC) responses. None of the tissues from normal (unfed) mice had the inherent ability to alter recipients' IgG or IgA PFC responses. Within 1 day of OVA feeding, however, cells were generated in the PP that could augment recipients' IgA anti-OVA PFC responses and suppress IgG PFC responses. Three days after OVA feeding, these cells were present in MLN as well, and whereas the IgG suppressor cell also appeared to migrate to spleen, the IgA helper cell did not. The cells mediating antigen-specific IgG suppression and IgA help were both T cells but could be distinguished by surface phenotype. We therefore conclude that protein feeding induces differential, isotype-specific immunoregulation in gut-associated lymphoid tissues, part of which is mediated by an antigen-specific IgA helper T cell.     

Nature of neonatal splenic suppressor cells in the mouse

Due to the controversy in the recent literature concerning the T-cell nature of the neonatal mouse splenic suppressor cell, we have reexamined the nature of these cells at different stages after birth. With the use of monoclonal anti-Thy antibody we can detect T-cell products on spleen suppressor cells from BDF₁ mice at 3, 4, 5, 6, and 7 days of age. The suppressor cells are assayed by their ability to inhibit mixed-lymphocyte reactivity, which is an in vitro example of cell-mediated immunity. The neonatal spleen suppressor cells also carry products of the Ly 1 and I-J locus. Neonatal thymectomy results in a premature decrease of suppressor cell activity. These data suggest that the mouse neonatal splenic suppressor cell is a short-lived Ly 1⁺, I-J⁺ T cell.     

Activation of suppressor T cells by low-molecular-weight factors secreted by spleen cells from tumor-bearing mice

The spleens of mice bearing large M-1 fibrosarcomas have been shown to contain several populations of cells which nonspecifically suppress antibody synthesis by cocultured normal spleen cells. It has now been shown that the spleens of tumor-bearing mice also contain inducer cells which secrete soluble factors capable of activating suppressor T cells from unprimed precursor cells. The activated suppressor cells are Thy 1+, Lyt 1+2+ and secrete a soluble suppressive factor. They inhibit the in vitro generation of antibody-forming cells by cocultured normal spleen cells stimulated by T-cell-dependent antigens. They do not, however, suppress the antibody response to T-cell-independent antigens and do not inhibit antibody synthesis by cocultured nude mouse spleen cells cultured with T-cell-dependent antigens and exogenous helper factors. In addition, suppression is blocked if conditioned medium containing T-cell growth factors is added to the suppressor cell assays. These data suggest that cells in the spleens of tumor-bearing mice secrete inducing factors which activate suppressor cells. These activated suppressor cells in turn secrete soluble suppressor factors which inhibit antibody synthesis, possibly by interfering with the synthesis or release of T-cell growth factors.     

Soluble suppressor activity of concanavalin A-activated spleen cells on B-lymphocyte colony formation in vitro.

Supernates from concanavalin A (Con A)-activated mouse spleen cell cultures suppress the formation of B-lymphocyte colonies (BLC) in soft agar culture by 30 to 95%. Con A-induced BLC suppressive culture supernates can be heated at 80 °C for 1 hr without losing activity. The BLC suppressive activity is eliminated totally by trypsin treatment and partly by treatment with β-galactosidase. Activity is unaffected by treatment with DNAse, RNAse, and α-glucosidase. By ultrafiltration the BLC suppressive factor(s) was shown to have a molecular weight greater than 300,000. These data suggest that BLC suppression is mediated by a protein-carbohydrate complex. BLC suppression was obtained when normal spleen cells were preincubated in Con A-activated supernates for only 1 hr at 37 °C. BLC suppressor activity was absent in the supernatant fluid of Con A exposed anti-θ-treated spleen cells, nonadherent spleen cells, extensively washed spleen cells, and spleen cells from nude (athymic) mice suggesting that cells responsible for Con A-induced BLC suppression are adherent, fragile cells of the T lineage. Con A-activated spleen cell supernates do not suppress colony formation in soft agar by normal mouse granulocyte-macrophage precursors, by plasmacytoma cells, T-lymphoma cells, or by carcinoma cells. However, colony formation by Abelson's murine leukemia virus transformed B-lymphoma cells was suppressed by 95% suggesting a relationship between this immature B-lymphoma line and B-lymphocyte colony-forming cells. Con A-activated spleen cell supernates do not suppress lymphocyte activation in liquid culture by phytohemagglutinin, Con A, or lipopolysaccharide. Heat-treated supernates—which inhibited BLC development by 90–95%—did not suppress the plaque formation by spleen cells immunized in vivo or in vitro by sheep red blood cells.     

Suppressor T cells in thymus-reconstituted nude mice: regulation of mitogen-induced transformation

A population of glass-wool-adherent splenic cells which could suppress the response of other spleen cell populations to T-cell mitogens was isolated from thymus-reconstituted nude mice. Such adherent cells were characterized as sensitive to anti-Thy 1.2 and complement treatment. Glass-wool-adherent cells from athymic mice do not have suppressor activity to self or normal littermate NAC; however, these mice possess precursor suppressor cells as demonstrated by isolation of glass-wool-adherent T regulatory cells in thymus-grafted nude mice. Such cells are generated in either freshly obtained or in vitro cultured thymus. Evidence for suppressor T cells of host genotype was supported by their sensitivity to host-specific anti-Thy serum treatment as well as their generation in alymphoid thymus grafts. Prior anti-Thy 1.2 treatment of GAC partially removed the suppressor activity: however, macrophages and B lymphocytes were shown not to be secondary regulatory cells or suppressor mediators, thus mature T lymphocytes with low amounts of Thy 1.2 antigen may be responsible for this residual suppression. Further characterization of GAC indicates that active cell growth is required for their regulatory function, as irradiation removed the suppressor activity. This report provides evidence for the presence of a T-lymphocyte subpopulation which has a regulatory function and requires a thymus in the generation of these cells.     

Suppressor cell regulation of encephalitogenic T cell lines: generation of suppressor macrophages with cyclosporin A and myelin basic protein.

Chronic relapsing experimental allergic encephalomyelitis (CR-EAE) can be adoptively transferred using myelin basic protein (BP)-specific helper T cell lines, and suppressor cells may be important in recovery from EAE. In order to generate suppressor cells, spleen cells obtained from BP-complete Freund's adjuvant (CFA) inoculated SJL/J mice and from normal mice were cultured for 7 days with medium, with cyclosporin A (CsA), or with CsA and antigen (BP or purified protein derivative of mycobacterium (PPD)). Cultured spleen cells were assayed for suppressor activity in vitro by coculture with BP-specific and PPD-specific helper T cell lines derived from SJL/J mice. Immunized donor spleen cells cultured with cyclosporin A (CsA) and BP were potent inhibitors of T cell line proliferation, and suppressor activity was increased 17-fold compared with control splenocytes. The number of suppressor cells required to suppress PPD-specific line proliferation by 50% (I50) was significantly higher than the number required to suppress BP-specific line proliferation, suggesting an antigen-specific component to the suppression. The major effector cell required for suppression was a large granular Mac-1+ cell with the functional characteristics of a macrophage. Suppressor activity persisted after depletion of Thy 1.2+ cells, but suppression was no longer antigen-specific, suggesting that culture of spleen cells with CsA and BP may generate suppressor macrophages which are antigen-nonspecific and Thy 1.2+ suppressor cells which are antigen-specific. These suppressor cells may be important in the regulation of CR-EAE and the techniques described for their generation may prove useful for treatment and prevention of disease.     

Direct evidence for the involvement of T suppressor cells in the expression of low-dose paralysis to type III pneumococcal polysaccharide

Prior treatment (priming) with a subimmunogenic dose of type III pneumococcal polysaccharide results in the development of an antigen-specific state of unresponsiveness termed low-dose paralysis. Such unresponsiveness can be transferred by spleen cells obtained from mice within 5 to 24 hr after priming; the suppressive activity of transferred cells is abolished by treatment with monoclonal anti-Thy-1.2 antibody and complement. These findings show clearly that low-dose paralysis is mediated by T suppressor cells.     

Specific unresponsiveness to skin allografts in anti-lymphocyte serum-treated, marrow-injected mice: participation of donor marrow-derived suppressor T cells

Sequential changes of cell-mediated immune reactivities were examined in anti-lymphocyte serum-(ALS) treated, C3H/He (C3H; H-2k) bone marrow-injected (C57BL/6 X A)F1 (B6AF1; H-2b/k.d) mice bearing enhanced C3H skin grafts. Spleen cells of these mice exhibited marked suppression of the proliferative response to phytohemagglutinin and concanavalin A. When the spleen cells were assayed for the direct lymphocyte-mediated cytotoxicity against H-2k targets, their lytic activity remained low until the time of graft rejection, in contrast to the increasingly high cytotoxic activity exhibited by spleen cells of control B6AF1 mice given only ALS and C3H skin grafts. When spleen cells of marrow-injected B6AF1 mice were cultured with mitomycin-C treated C3H spleen cells, the proliferative response was significantly suppressed the throughout the course, despite the early appearance of high "secondary-type" cytotoxic activity. Co-culture experiments demonstrated the presence of C3H antigen-specific suppressor cells in the ALS-treated, marrow-injected mice bearing intact allografts. Treatment of spleen cells with anti-H-2, anti-Thy 1 and anti-I-J sera and C revealed that the suppressor cells present late in the marrow-injected mice were T cells of donor C3H bone marrow cell origin.     

Age restriction in antigen-specific immunosuppression

Age-related alterations of antigen-specific T cell-mediated suppression have been examined in the 4-hydroxy-3-nitrophenyl acetyl (NP) system. Inducer suppressor T cells (Tsi) were activated in mice at the age of 3 mo (young) or 18 mo (old) by i.v. injection of NP-conjugated syngeneic spleen cells (SC). Spleen cells from the NP-SC-injected mice were subcultured in vitro with spleen cells from normal young or old mice to generate transducer suppressor T cells (Tst). Four days later subcultured cells were added to responder cell cultures 1 day before the PFC assays to trigger effector suppressor T cells (Tse). Responder cell cultures, containing NP-conjugated horse red blood cells (HRBC) and spleen cells from HRBC-primed young or old mice, were assayed on day 4 for anti-NP and anti-HRBC PFC. Suppression was found to be antigen specific and age restricted. NP-specific suppressor cells are easily induced in subculture if the Tsi and Tst cell populations are both derived from young or old mice. Conversely, if Tsi cells from young or old mice are subcultured with Tst cells from mice of a different age, suppression of the anti-NP PFC response is hardly observed. Age restriction was also found to operate in the interactions between subcultured and responder cell populations, indicating that age-matching is required for effective triggering of Tse cells by Tst cells. These results altogether suggest that aging may affect the recognition repertoire expressed in suppressor T cell subsets. Moreover, the finding that suppression is less efficient when exerted on responder spleen cells from old than from young mice provides an explanation for the increased frequency of autoimmune disorders in aging.     

Demonstration of active suppressor cells in spleens of young NZB mice

NZB mice, a strain prone to the development of autoimmune disease, have during the first 2 weeks of life suppressor cells in their spleens which can in coculture with adult spleen cells suppress the antibody response to sheep red blood cells (SRBC) generated in culture by the adult cells. The suppressive activity of spleen cells from NZB mice in the first week after birth is similar to that of spleen cells from 4-day-old C57BL/6 mice, a strain which does not spontaneously develop autoimmune disease. As in “normal” strains of mice, suppressor cell activity in NZB mice is diminished at 2 weeks and undetectable at 3 weeks of age. The data indicate that there is no defect inherent in the suppressor cells detected in the spleens of newborn and young NZB mice and suggest that the development of autoimmune responses does not result from a lack of suppressor cells in the young animals.     

Modulation of immune responses by suppressor T cells.

The activity of suppressor T cells has been demonstrated in almost every phase of the immune response. These regulatory cells modulate both humoral and cell-mediated immunity utilizing antigen-specific and nonspecific mechanisms. For comparative purposes two murine models are described, the nonspecific suppressor T cell stimulated by the mitogen concanavalin A and the antigen-specific suppressor T cell stimulated by injection of the synthetic terpolymer acid 60-L-alanine30-L-tyrosine10 (GAT) in nonresponder mice. These two T cells are similar to expression of Ly alloantigens, ability to inhibit antibody responses, and the mediation of suppression, at least in part, by soluble products. However, differences in radio-resistance and antigenic specificity of the suppressor T cells, as well as differences in molecular characteristics of the soluble factors and their targets suggest that these T cells regulate the immune response by different mechanisms. The relationship of these two suppressor T cells to other nonspecific and antigen-specific suppressor T cells is discussed.     

Trypanosoma cruzi-induced suppressor substance III. Activation of suppressor cells

Serum from mice infected with Trypanosoma cruzi (SSS) is known to interact with normal spleen cells to induce an immunosuppressed condition and activate splenic suppressor cells. The induction of immunosuppression by SSS was shown to be independent of, and precede the activation of, suppressor cells. Suppressor-cell activation, however, was demonstrable only after the induction of immunosuppression. Furthermore, mice that were given two aliquots of SSS at different intervals of time, exhibited suppression of humoral responses of similar duration and magnitude, regardless of the SSS transfer regimen, whereas both the length and degree of suppressor-cell activity was critically dependent on the interval of time between SSS transfers. SSS interacted with spleen cells via a trypsin-sensitive membrane site which was regenerable within a 4- to 5-hr period, yet the suppressive effects of SSS on spleen cells following interaction was resistant to treatment with trypsin. The interaction between SSS and spleen cells during brief adsorption protocols leads to immunosuppression only because extensive washing of SSS-treated spleen cells did not reverse the immunosuppression process, but did prevent the development of detectable suppressor cells. The phenomenon of suppressor-cell activation was further distinguished from immunosuppression in that supernates from culture of spleen cells derived from SSS-treated mice or T. cruzi-infected contained a factor that activated suppressor cells, but did not directly induce a state of suppression in the responding cell population.     

Bacterial lipopolysaccharides activate immune suppressor cells in newborn mice

Neonatal injection of C57B1/6 mice with bacterial LPS results in an impairment of the ability of splenic lymphocytes to respond to erythrocyte antigens in vitro 4 weeks later. This impairment is due either to a de novo activation of suppressor cells or to an enhancement of the longevity of “naturally occurring” suppressor cells found in the newborn spleen since cells from LPS-injected mice also inhibited normal control responses. The suppressor cells from LPS-injected mice are not macrophages and, by conventional criteria, appear to be T lymphocytes. Results of this study raise questions concerning the effects of suppressor cells on LPS-potentiated antibody formation and the multiplicity of pathways for activation of antibody-forming precursor cells.