Induction of suppression by a murine nonspecific suppressor-inducer cell line (M1-A5). II. The role of prostaglandins

A murine nonspecific suppressor-inducer cell line (M1-A5) was generated from the spleen cells of a mouse bearing an advanced methylcholanthrene-induced fibrosarcoma. We previously demonstrated the capability of M1-A5 cells to activate suppressor cells from the spleen cells of unprimed mice. We demonstrate here that induction of suppression by M1-A5 cells was blocked by acetylsalicylic acid (ASA) and ibuprofen at concentrations which block prostaglandin (PG) synthesis. Maximal blockade of the induction of suppression by M1-A5 cells was seen when ASA was added at the initiation of culture, and it required inhibition of PG synthesis at the level of the inducer (M1-A5 cells) population. However, ASA blockade of suppressor cell activation by M1-A5 cells was not due to ASA acetylating suppressor-inducing factor. Exogenously added PGE1, PGE2, and PGI2, but not PGF2 alpha or PGD2, were able to restore the inducing capability of M1-A5 cells, which had been blocked by ASA. However, PGE1, PGE2, or PGI2 did not reconstitute an inactive suppressor-inducing factor. These results suggest that PG act to modulate the release of suppressor-inducing factor from M1-A5 cells.     

Secretion of a suppressor cell inducing factor by an interleukin-3 dependent cell line with natural cytotoxic activity

This report describes the morphology, surface markers, growth requirements, and functional activity of the M1-A5 cell line, which was established by the limiting dilution of spleen cells from a mouse bearing a large methylcholanthrene-induced fibrosarcoma. The M1-A5 cells share many of the morphological features of large granular lymphocytes and, in addition, express asialo GM1 and Ly-5 surface markers which are commonly found on natural killer cells (NK) cells. There is no expression of T-cell differentiation antigens, surface immunoglobulin, or the granulocyte/macrophage marker, MAC-1. M1-A5 cells are dependent on exogenous growth factor(s) for survival and will proliferate if cultured in interleukin 3 (IL-3), but not in interleukin 1 (IL-1), interleukin 2 (IL-2), or granulocyte/macrophage colony stimulating factor (GM-CSF). In addition, the M1-A5 cells do not absorb IL-2. Despite their morphology and surface characteristics, the M1-A5 cells do not lyse NK targets such as YAC-1 and RLM1 in 4- or 18-hr cytotoxic assays but do lyse the natural cytotoxic (NC) susceptible target, WEHI-164, and to a very small extent, the M-1 fibrosarcoma cells, in an 18-hr assay. Thus they exhibit NC-like cytotoxic activity. In addition, the M1-A5 cells secrete a small molecular weight factor which activates suppressor cells capable of inhibiting antibody synthesis by cocultured syngeneic spleen 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.     

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.     

Prevention of granuloma development in the mouse by using T cell hybridoma products

The ability of an azobenzenearsonate (ABA)-specific suppressor T cell factor, a soluble extract from first order suppressor T cells (Ts1), and suppressor molecules produced by a long-term T cell hybridoma to regulate ABA-specific granuloma formation was studied. ABA-derivatized syngeneic spleen cells (ABA-SC) administered subcutaneously induced persistent delayed-type hypersensitivity (DTH) responses, detected by footpad swelling and hapten-specific granuloma formation by 72 and 96 hr after challenge with ABA-bovine serum albumin coupled to polyacrylamide beads (ABA-BSA-PAB). Soluble factors from ABA-specific Ts1 prevented DTH and granulomatous development after subcutaneous administration of ABA-SC. Moreover, the in vivo administration of a factor that is derived from a Ts1 functioning hybrid cell line induced a second set of suppressor cells (Ts2) that upon transfer to syngeneic ABA-primed mice were able to inhibit granuloma formation in the footpad, as well as in the gastrointestinal tract after challenge with ABA-BSA-PAB. These experiments demonstrate the dependence of the granulomatous reaction on T cell-mediated events, as well as the potential therapeutic efficacy of an antigen-specific suppressor T cell factor and a hybridoma T cell product in limiting antigen-specific granuloma formation in vivo.     

Peripheral tolerance induced in lymph nodes by syngeneic spleen cells inhibits generation of CTLs to hapten-altered self antigens but not to alloantigens.

The immunological tolerance that is induced in lymph nodes that have been exposed to syngeneic spleen cells has been examined. Development of cytotoxic T lymphocytes was used to assess the immunological status of the lymph node cells. The tolerance was studied from the viewpoint of its induction, its activation, and its specificity. We had already reported that injecting either T or B cells of splenic origin into a regional lymph node environment a week prior to immunization for CTL to hapten-altered self antigens prevents development of the CTL. Here, we confirm that syngeneic splenic cells but not lymph node cells will induce the suppression provided that spleen cells are not coupled with hapten. We now report that splenic cells that cannot replicate or synthesize and secrete protein are capable of inducing the suppression. The data suggest a preformed surface marker peculiar to spleen cells and perhaps on cells that traverse the thymus induces local tolerance that is mediated by suppressor cells. Triggering the induced suppressor T cells (previously identified as CD8-) was achieved by syngeneic spleen cells as well as by H-2-compatible, Mls-disparate spleen cells but not by syngeneic lymph node cells or apparently by allogeneic spleen cells. Furthermore, triggering suppression was achieved by hapten-coupled syngeneic spleen cells whereas such cells would not induce the suppression. Thus, activating the suppressor cells requires reexposure to splenic cells of the proper MHC haplotype, unaltered or coupled with either TNP or FITC. Once triggered, the suppression was manifested toward CTL generation against hapten-coupled syngeneic antigens on either spleen or lymph node cells but not against allogeneic antigens. Thus, the specificity of the tolerance was directed to altered self antigens despite its induction by unaltered spleen antigen. Furthermore, for suppression to be seen the spleen antigen was not required to be on the hapten-coupled syngeneic cells used for the CTL immunization. The relationship of the splenic cell "antigen" to hapten-altered self antigens and to other surface markers and its site of acquisition within the body and its significance for cell homing have become intriguing questions of importance. This information has been discussed from the viewpoint of its applicability to autoimmune diseases as well as to cessation of inflammatory reactions that may be mediated by lymph node cells.     

Induced suppression of the efferent phase of contact sensitivity in rats

A study of the immunosuppressive systems of rats has been conducted with special attention to whether suppressor cells can be induced to down-regulate the efferent limb of contact sensitivity. Contact sensitivity (CS)1 was induced in DA rats 5 days after immunization with trinitrochlorobenzene (TNCB). Intravenous pretreatment of naive rats with TNP-coupled syngeneic spleen cells 7 days before sensitization suppressed the induction of CS by 60%. Suppression of the inductive phase of CS could be transferred adoptively into syngeneic rats with spleen cells of such tolerized animals. Cell fractionation studies showed the OX8+ (CD8) T cell population (cytotoxic/suppressor) was responsible for the suppression in the afferent phase of CS. Such cells were incapable of suppressing preexisting CS. To investigate whether suppression could be induced for the efferent phase, spleen and peritoneal exudate cells (PEC) from rats tolerized by administering TNP-spleen cells iv plus epidermal paintings with TNCB were adoptively transferred into recipients sensitized 4 days earlier. Both spleen cells and PEC suppressed the efferent phase of CS but PEC did so more efficiently. Separation of splenic cells revealed the suppressors to be CD8+ T cells. Furthermore, separation of PEC into plastic adherent and nonadherent cells showed the nonadherent (T cell enriched) cells to be noneffective alone. The adherent subpopulation conveyed suppression but did so more effectively upon addition of the T cells. Thus, T cells and macrophages may operate in concert to achieve suppression of the efferent limb of CS. PEC from tolerized rats suppressed performed CS of any specificity but only after the suppressor cells were triggered with the same antigen that induced them. Since both the afferent and efferent phases of CS have now been shown to be suppressable, two separate suppressor mechanisms may be operable in rats.     

Feedback suppression of the immune response in vivo. III. Lyt-1+ B cells are suppressor-inducer cells

We previously demonstrated that injection of a high dose (4 X 10(9] of sheep erythrocytes (SRBC) into C57BL/6 mice results in the generation of splenic B cells (plastic nonadherent, Thy-1- and Ig+) which, when transferred to normal syngeneic recipients, subsequently induce antigen-specific suppressor T cells to suppress the recipient's plaque-forming cell (PFC) responses to SRBC. In the present study we characterized the suppressor-inducer B cells phenotypically. Cytotoxic treatment of the donor's immune spleen cells with anti-Lyt-1 antibody plus complement (C'), but not with anti-Lyt-2 antibody plus C', relieved the suppression of PFC responses in recipients. The FcRr+ population separated by EA-rosette formation showed enriched suppressor-inducing activity, whereas the FcRr- population showed no activity. Our findings, taken together with the previous ones, suggest that suppressor-inducer cells are Thy-1-, Lyt-1+, Lyt-2-, FcRr+, and Ig+.     

Immune suppression in vivo with antigen-modified syngeneic cells. II. T cell-mediated nonresponsiveness to fowl gamma-globulin.

Intravenous administration of syngeneic spleen cells coupled with the palmitoyl derivative of fowl gammma-globulin (p-F gamma G) results in a profound state of F gamma G-specific tolerance in C57BL/6 mice. Administration of p-F gamma G coupled syngeneic cells specifically reduces both the primary and secondary hapten and carrier-specific PFC responses to TNP-F gamma G. Since the haptenic response is affected, the tolerance functions at the level of the F gamma G-specific helper T cell. As few as 10(3) p-F gamma G spleen cells carrying only 1 ng of p-F gamma G can induce tolerance. At least a 2-day-induction period is required. This nonresponsiveness is long lived, lasting over 120 days. Spleen cells from tolerized mice can transfer suppression to normal syngeneic recipients. Treatment of tolerant spleens with anti-Thy 1.2 antiserum + C eliminates the suppressor cell activity. In addition, thymocytes and purified splenic T cells from tolerized mice can transfer suppression to normal recipients. Thus, at least a component of this nonresponsiveness is mediated by suppressor T cells. The requirement of antigen association with cell membrane components and the general applicability of this method of inducing T cell nonresponsiveness are discussed.     

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.     

Regulation of antibody secretion by hybridoma cells. I. Suppression of antibody secretion by coculture of hybridoma cells with idiotype-induced suppressor cells

In this study, we have demonstrated that antibody secretion by hybridoma cell lines can be down-regulated by idiotype-specific immune spleen cells or by nylon wool nonadherent spleen cells. This suppression of antibody secretion can be abolished by treating the idiotype-specific immune spleen cells with anti-Thy 1.2 plus complement. The hybridoma we used for most of our experiments secretes IgM specific for the cross-reacting haptens 2,4,6-trinitrophenyl (TNP) and 2,4-dinitrophenyl (DNP). Suppression was achieved by direct coculture of hybridoma cells with immune cells from animals which were injected with affinity-purified hybridoma antibody-coupled syngeneic spleen cells. The suppressed and control cultures contained similar numbers of viable hybridoma cells, suggesting that a simple cytotoxic effect is not responsible. Idiotype specificity was established in experiments showing that two idiotype immune animals immunized with antibody from two different IgM anti-TNP hybridomas could suppress the hybridoma to which they were immunized but could not affect the other hybridoma. Immune spleen cells required 3-4 days of coculture with hybridoma cells before maximum suppression was achieved. The kinetics of the response suggest that the final effector suppressor cell is generated during the coculture period and that a second signal, perhaps a product of the hybridoma cells, may be required.     

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.     

Antigen and receptor-driven regulatory mechanisms. VI. Demonstration of cross-reactive idiotypic determinants on azobenzenearsonate-specific antigen-binding suppressor T cells producing soluble suppressor factor(s)

The first detectable suppressor T cell (Ts) arising after i.v. administration of azobenzenearsonate- (ABA) conjugated syngeneic spleen cells to A/J mice has been studied for its receptor specificity and ability to produce soluble suppressor factor(s). This cell, termed Ts1, has a specific receptor for the eliciting antigen ABA, as demonstrated by selective binding to ABA protein- but not TNP protein-coated plastic dishes. The activity of ABA-Ts1 can be abrogated by treatment with anti-idiotypic antibodies made against anti-ABA antibodies of A/J mice (anti-CRI), indicating that these ABA-binding cells possess a surface receptor structure sharing idiotypic determinants with antibodies of the same specificity. Finally, soluble extracts from, antigen-adherent ABA-Ts1, but not nonadherent cells from the same spleen cell population, possess suppressive activity when assayed directly for afferent suppression or tested for their ability to trigger a second population of Ts (Ts2) in naive recipients. These findings demonstrate a close concordance between a T cell surface receptor, soluble T suppressor factors, and B cell derived antibody, all capable of direct recognition of the eliciting ABA antigen.     

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.     

Role of self carriers in the immune response and tolerance. IV. Active T cell suppression in the maintenance of B cell tolerance to a "T-independent" antigen.

Previous studies indicated that T cells are required for tolerance induction by hapten-modified syngeneic spleen cells (TNP-SC) in vivo. The role of T cells in the maintenance of this unresponsive state has been examined herein. By three criteria--limiting dilution precursor analysis, removal of T cells by anti-Thy-1 + C, and direct mixing experiments--we show that T cells are required for the continued suppression of the B cell response to the T-independent antigen, TNP-POL. Suppressor cells can also be induced by TNP-teratoma cells, which lack detectable H-2 antigens. Both anti-Ly-1 + C and anti-Ly-2 + C treatment reversed suppression induced by TNP-SC. These results demonstrate that normal B cell reactivity is present in the spleens of mice rendered tolerant by haptenated self, but that Ly-1,2,3 or Ly-1 + Ly-2,3 suppressor T cells prevent their responsiveness.     

Suppressor T cells induced by soluble immune complexes can adoptively transfer inhibition of cytophilic antibody receptors on macrophages.

Immune complexes (soluble antigens of L1210 and antibody to L1210) when given to allogeneic C3H mice generated suppressor cells that inhibited receptors for cytophilic antibody on macrophages. Thymocytes or nylon-nonadherent splenic T cells (4 × 10⁷) from immune-complex-treated mice transferred this suppressive activity when injected into normal syngeneic mice. Maximal suppression of macrophages occurred 4 to 6 days after transfer. In contrast, even 5 × 10⁷ nylon-adherent, non-T spleen cells from immune-complex-treated (“suppressed”) mice failed to induce macrophage suppression in the syngeneic recipients. When T-cell-depleted “B” mice were used as recipients, neither thymocytes nor splenic T cells from suppressed mice were able to transfer suppressive activity. However, the admixture of 2 × 10⁷ normal syngeneic thymocytes with 4 × 10⁷ thymocytes from suppressed mice restored the latter's ability to elicit suppression of macrophages in T-cell-deprived recipients. Peritoneal monocytes from recipients of suppressor thymocytes (to L1210) could not attach cytophilic antibody to L1210 but could attach cytophilic antibody to EL-4 and sheep erythrocytes. Thus, suppressor T cells induced by immune complexes can transfer immunologically specific macrophage suppression (inhibition of cytophilic antibody receptors) to syngeneic recipients. The suppressor cells required the cooperation of normal T cells, suggesting either recruitment of suppressor cells from, or a helper effect by, the normal T cells, in order to produce their effect.     

Suppression of the in vitro secondary response to syngeneic tumor and of in vivo tumor therapy with immune cells by culture-induced suppressor cells.

Mice with advanced disseminated syngeneic tumor can be successfully treated with a combination of chemotherapy and adoptively transferred syngeneic immune cells. We have previously demonstrated that in vivo primed cells secondarily sensitized in vitro became more effective in tumor therapy, whereas primed cells cultured for 5 days without tumor stimulation became less effective than an equal number of uncultured fresh primed cells. Therefore, we examined stimulated and unstimulated cultures of tumor-primed cells for the presence of culture-induced suppressor cells, and determined whether in vivo tumor therapy with immune cells could be inhibited by concurrent inoculation of immune effector cells and cultured normal spleen cells, which contain culture-induced suppressor cells but are devoid of additional effector cells. The in vitro primary allogeneic response was suppressed by cultured normal spleen cells, or tumor-primed spleen cells previously cultured for 5 days with or without tumor stimulation. In vitro secondary sensitization to syngeneic tumor was suppressed by normal or tumor-primed cells that had previously been cultured for 5 days without stimulation. The majority of this suppression was mediated by T cells in the cultured populations. The efficacy of fresh tumor-primed cells, as well as primed cells secondarily sensitized in vitro, in adoptive chemoimmunotherapy of advanced tumor was diminished by concurrent inoculation of cultured normal cells. The cells mediating suppression of in vivo therapy required previous in vitro culture for induction, and were radiation sensitive.     

Properties of syngeneic and allogeneic antisera raised to tumor-specific suppressor factor from DBA/2J mice

Summary Tumor-specific suppressor factor was prepared by injecting soluble membrane extracts of the syngeneic mastocytoma, P815, into DBA/2J mice 4 days prior to sacrifice. The suppressor factor was purified by passage of spleen extracts over an immunoadsorbent containing P815 membrane components. Antisera raised in syngeneic and allogeneic (C57Bl/6) mice by repeated injections of suppressor factor were tested. It was found that these antisera, but not their controls, were capable of absorbing out the suppressor factor. The antisera were also capable, in the presence of complement, of eliminating suppressor cells from suppressive spleen cell populations. However, the antisera were not capable of eliminating syngeneic tumor-specific in vitro-generated killer cells, indicating that the receptor molecules on suppressor and effector cells in this system are distinct from each other.     

Spontaneous proliferation in unfractionated spleen cell cultures: autologous mixed-lymphocyte reactions (AMLR) which can be differentially regulated by prostaglandins and lymphokines

The present studies were undertaken to define the contribution of the autologous or syngeneic mixed-leukocyte reactions (AMLR/SMLR) to the cellular proliferation observed in unfractionated spleen cell cultures. Proliferation was studied in whole, untreated 6-day murine spleen cell cultures supplemented with syngeneic serum. These cultures exhibited relatively low but significant levels of cellular proliferation as measured by uptake of radioactive thymidine ([3H]TdR). Treatment of spleen cells with monoclonal anti-Thy 1.2 antibody and complement before culture, the addition of specific anti-I-A monoclonal antibodies to the cultures or removal of Ia+ adherent cells before initiation of culture all inhibited the proliferative response significantly. Thus, the autologous proliferation of untreated and unfractionated spleen cells manifests the main characteristics of the AMLR/SMLR, namely, its dependence on T (responder) and Ia+ (stimulator) cells and specific inhibition by anti-I-A antibodies. A marked augmentation in cellular proliferation was observed in unfractionated spleen cell cultures treated for the initial 24 hr of culture with 5 X 10(-6) M indomethacin, an inhibitor of prostaglandin synthesis. Conversely, the addition of 7 X 10(-9) M prostaglandin E1 (PGE1) to these cultures depressed cellular proliferation. This suppression of autologous splenic cell proliferation induced by PGE1 could be partially reversed by the addition of concanavalin A-induced lymphokine (LK) preparations early in the culture. These findings indicate that (a) the proliferation of unfractionated spleen cell cultures occurring in the absence of exogenous stimulatory signals is due largely to an ongoing AMLR, and (b) biologically active mediators with opposing influences, namely, prostaglandins and immunostimulatory LK, participate in the regulation of the AMLR.     

Direct demonstration of specific suppressor T cells in the mice tolerant to type III pneumococcal polysaccharide: two-step requirement for development of detectable suppressor cells

Spleen cells from CAF1 mice made tolerant to type III pneumococcal polysaccharide (S3) with S3 coupled to syngeneic spleen cells (S3-SC) develop S3-specific suppressor T cells (Ts). These Ts could be demonstrated consistently only when spleen cells from tolerant mice were cultured in vitro with the specific antigen and the specific tolerogen. Spleen cells from normal mice cultured under the same conditions did not suppress the antibody response to S3. When different numbers of Ts were transferred to normal CAF1 mice, an unusual dose-effect pattern was observed. Maximal suppression of the S3 response occurred when relatively low numbers of Ts, 3 to 30 x 10(5) per recipient, were transferred, whereas larger numbers of cells, 150 x 10(5) per recipient, were not suppressive. These results indicate that a presumably T-independent antigen, S3, can activate antigen-specific Ts. These Ts exhibit unusual dose effects upon transfer and require both an in vivo induction period and in vitro activation for development of maximal activity. These latter observations suggest that S3 may activate a different population of T cells with suppressor function than do conventional T-dependent antigens. The loss of suppression observed when greater than optimal numbers of cells were transferred suggests that a second type of T cell, which has the ability to 'neutralize' the activity of S3-specific Ts, is also induced in the same spleen cell population.