Recombinant granulocyte-macrophage colony-stimulating factor restores deficient immune responses in mice with chronic Trypanosoma cruzi infections

Spleen cells from mice with chronic Trypanosoma cruzi infection generate a minimal plaque-forming response to SRBC in vitro. Addition of granulocyte-macrophage (GM)-CSF to cultures of spleen cells from chronically infected mice restored the plaque-forming cells (PFC) response to normal levels. Splenic adherent cells from chronically infected mice were deficient in their ability to reconstitute the PFC response of accessory cell-depleted normal spleen cells. Preincubation of splenic adherent cells from infected mice with GM-CSF restored their ability to reconstitute the PFC response of adherent cell depleted cultures. Ia Ag expression by splenic adherent cells from chronically infected mice was significantly lower compared to Ia Ag expression of cells from normal mice. Incubation of splenic adherent cells from chronically infected mice for 48 h with GM-CSF increased levels of Ia Ag expression to approximately those of uninfected mice. Peritoneal macrophages from infected mice produced IL-1 after incubation with GM-CSF at levels equivalent to those produced by similarly treated control macrophages. Spleen cells from chronically infected mice showed significant induction of IL-2 mRNA after GM-CSF treatment, and the addition of the anti-IL-2 mAb to GM-CSF supplemented cultures of spleen cells from infected mice blocked the restoration of the anti-SRBC PFC response. Thus, the ability of GM-CSF to restore the anti-PFC response to SRBC appears to involve the up-regulation of accessory cell function that includes increased Ia Ag expression and the induction of IL-1 production. These events also involve increased IL-2 production with resultant up-regulation of the response to SRBC by spleen cells from infected mice. Finally, it was shown that treatment of infected mice with rGM-CSF completely restored their depressed PFC production in vivo.     

Granulocyte-macrophage colony-stimulating factor augments the primary antibody response by enhancing the function of antigen-presenting cells

Purified, recombinant-derived murine granulocyte-monocyte colony-stimulating factor was found to enhance the primary in vitro immune response to SRBC by murine spleen cells. In determining the mechanism of this augmentation, it was found that only splenic adherent cells and neither resting nor activated T cells nor B cells expressed specific receptors for GM-CSF. When splenic adherent cells were pulsed briefly with GM-CSF before addition to macrophage-depleted cultures, they reconstituted the PFC response to a significantly greater degree than did control macrophages. Splenic adherent cells incubated overnight with SRBC plus GM-CSF were also more efficient antigen-presenting cells than splenic adherent cells incubated with antigen alone. The mechanism of this enhanced antigen presentation was found to be due to a GM-CSF-dependent increase in the level of IL 1 secretion and Ia antigen expression. Consistent with these data was the finding that GM-CSF augmented IL 2 production by splenic T cells in response to suboptimal concentrations of Con A. Finally, the day 5 in vivo antibody response (as measured by serum titers) of mice immunized with a low dose of SRBC was enhanced by two daily inoculations of GM-CSF. Thus, the role that GM-CSF plays in augmenting immune responses may not be solely accounted for by its ability to cause the proliferation or differentiation of macrophages, but more than likely includes its ability to enhance the function of antigen-presenting macrophages.     

Immune parameters of untrained or exercise-trained rats after exhaustive exercise

The effect of a single exhaustive swimming exercise bout on immune competence of untrained or exercise-trained female Wistar rats was compared with the competence of control sedentary rats. After the exhaustive exercise bout, the blastogenic response to concanavalin A by spleen cells of untrained rats was extensively suppressed, whereas the response of the trained rats was only marginally suppressed. The suppressed immune competence of the untrained rats after the exhaustive exercise was associated with an increase in immune-suppressive activity of splenic lymphocytes. The macrophages of the untrained rats and of the control sedentary rats were slightly immune suppressive to normal spleen cells through a prostaglandin-dependent mechanism. The addition of prostaglandin E2 (PGE2) to the blastogenesis cultures revealed that the spleen cells of untrained rats were unusually sensitive to the suppressive effects of PGE2. In contrast to the untrained rats, the marginal level of immune suppression in trained rats after the exhaustive exercise was associated with a lesser degree of lymphocyte-suppressive activity, an immune stimulatory activity by the splenic macrophages, and an insensitivity of the splenic lymphocytes to the suppressive effects of PGE2.     

Immunosuppression induced by attenuated Salmonella. Reversal by IL-4

We previously demonstrated that an aroA- strain of Salmonella typhimurium, which provides excellent protection against virulent Salmonella challenge, also rendered immunized mice unable to mount in vivo and in vitro antibody responses to heterologous Ag. Coculture studies using transwell plates indicated that suppression was mediated by soluble factors. The suppressive cells were identified as belonging to the monocytic linkage. Macrophage precursors as well as mature adherent macrophages mediated the observed suppression. In the present study, the mechanism of immunosuppression was investigated. Suppression was found to be genetically nonrestricted as spleen cells from immunized C3HeB/FeJ mice (H-2k) suppressed the anti-SRBC plaque-forming cell (PFC) responses of normal spleen cells from two MHC noncompatible mouse strains, BALB/c (H-2d) and C57BL/6 (H-2b). Time course experiments demonstrated that the addition of spleen cells from immunized mice to normal splenocytes as late as day 4 of a 5-day assay was still markedly suppressive. Furthermore, suppression of the PFC responses was accompanied by a profound inhibition of the capacity of immune splenocytes to produce IL-2 in response to in vitro stimulation by Con A. Coculture studies showed that immune spleen cells were able to suppress IL-2 production by normal splenocytes in a dose-dependent fashion. However, the suppressed PFC responses of immune spleen cells could not be reversed by the exogenous addition of up to 200 U/ml of IL-2, suggesting that immune splenocytes are also defective in their ability to respond to IL-2. In marked contrast, suppression of PFC responses was reduced by more than 50% by the addition of as little as 1 U/ml of IL-4 and was completely abrogated when 5 U/ml of IL-4 were added to in vitro cultures of spleen cells from immunized mice. The antisuppressive action of IL-4 appeared to be via its inhibitory effect on activated macrophages. The implications of the above findings are discussed.     

Suppression of antitumor immunity by macrophages in spleens of mice bearing a large MOPC-315 tumor

We had shown previously that progression of MOPC-315 plasmacytoma growth is associated with an increase in the percentage of macrophages in the spleen as well as a decrease in the ability of tumor-bearer spleen cells to mount an antitumor cytotoxic response upon in vitro immunization. Here we provide evidence that macrophages in the MOPC-315 tumor-bearer spleen are responsible at least in part for the suppression of the generation of antitumor cytotoxicity. Accordingly, removal of most macrophages by depletion of phagocytic cells or Sephadex G-10-adherent cells from spleens of mice bearing a large tumor resulted in augmented antitumor immune potential. Also, Sephadex G-10-adherent spleen cells from tumor-bearing (but not normal) mice drastically suppressed the in vitro generation of antitumor cytotoxicity by normal spleen cells. The suppressive activity of these adherent cells did not reside in contaminating suppressor T cells, since it was not reduced by treatment with monoclonal anti-Thy 1.2 antibody plus complement. The Sephadex G-10-adherent cell population from the tumor-bearer spleen suppressed the in vitro generation of antitumor cytotoxicity against autochthonous tumor cells but not against allogeneic EL4 tumor cells, and hence the suppression was apparently specific. The suppressive activity of the Sephadex G-10-adherent cell population from tumor-bearer spleens was overcome by treatment of the tumor-bearing mice with a low curative dose of cyclophosphamide. This immunomodulatory effect of a low dose of the drug in overcoming the suppression mediated by the Sephadex G-10-adherent cell population enables the effector arm of the immune system of tumor-bearing mice to cooperate effectively with the drug's tumoricidal activity in tumor eradication.     

Distinct role of neonatal and adult monocytes in the regulation of the in vitro antigen-induced plaque-forming cell response in man

Mononuclear cells from human cord blood (CBMC) are able to mount an antigen-specific IgM plaque-forming cell (PFC) response after primary in vitro stimulation with the T cell-dependent antigen ovalbumin (OA). The antigen dose-response relationship for the induction of PFC in cultures of CBMC is represented by a bell-shaped curve comparable to that found for mononuclear cells from adult peripheral blood (adult PBMC). The dose of OA optimal for the induction of a response in cultures of CBMC consistently, however, is 100-fold lower than the antigen dose optimal for adult PBMC (0.03 microgram OA/ml vs 3.0 micrograms OA/ml). Results obtained from co-culture experiments in which semiallogeneic combinations of parental/neonatal lymphocytes and monocytes were stimulated with a variable dose of OA indicate that the adherent cell (AC) plays a pivotal role in the establishment of the optimum antigen dose. From experiments using antigen-pulsed AC, it was concluded that neonatal and adult AC differ in their antigen handling capacity. In the presence of the prostaglandin synthetase inhibitor indomethacin the antigen dose-response relationship for the induction of PFC in cultures of CBMC shifts to an "adult type" of curve. From pulsing experiments it emerges that indomethacin affects the interaction between antigen and monocytes. Indomethacin causes an enhancement of the expression of HLA-DR at the surface of neonatal as well as adult AC; this can be down regulated by the addition of prostaglandin E2 (PGE2). The addition of PGE2 to cultures of adult PBMC leads to a shift of the optimal antigen dose for induction of PFC toward lower concentrations. Although higher levels of PGE2 were measured in the supernatant of cultured neonatal AC compared with adult AC, it seems unlikely that this observation can explain the distinct antigen dose-response relationship for the induction of a PFC response in cultures of CBMC.     

Suppression of antitumor immunity by macrophages in spleens of mice bearing a large MOPC-315 tumor

Summary We had shown previously that progression of MOPC-315 plasmacytoma growth is associated with an increase in the percentage of macrophages in the spleen as well as a decrease in the ability of tumor-bearer spleen cells to mount an antitumor cytotoxic response upon in vitro immunization. Here we provide evidence that macrophages in the MOPC-315 tumor-bearer spleen are responsible at least in part for the suppression of the generation of antitumor cytotoxicity. Accordingly, removal of most macrophages by depletion of phagocytic cells or Sephadex G-10-adherent cells from spleens of mice bearing a large tumor resulted in augmented antitumor immune potential. Also, Sephadex G-10-adherent spleen cells from tumor-bearing (but not normal) mice drastically suppressed the in vitro generation of antitumor cytotoxicity by normal spleen cells. The suppressive activity of these adherent cells did not reside in contaminating suppressor T cells, since it was not reduced by treatment with monoclonal anti-Thy 1.2 antibody plus complement. The Sephadex G-10-adherent cell population from the tumor-bearer spleen suppressed the in vitro generation of antitumor cytotoxicity against autochthonous tumor cells but not against allogeneic EL4 tumor cells, and hence the suppression was apparently specific. The suppressive activity of the Sephadex G-10-adherent cell population from tumor-bearer spleens was overcome by treatment of the tumor-bearing mice with a low curative dose of cyclophosphamide. This immunomodulatory effect of a low dose of the drug in overcoming the suppression mediated by the Sephadex G-10-adherent cell population enables the effector arm of the immune system of tumor-bearing mice to cooperate effectively with the drug's tumoricidal activity in tumor eradication.This paper was presented in part at the annual meeting of the American Association of Immunologists, Chicago, Illinois, 10–15 April 1983     

Immunoregulation in the rat: requirements for in vitro B cell responses to classical TI-1 and TI-2 antigens

The presence of suppressor cells and their mediators has made it difficult to induce B cell mitogenic or immune responses in rat spleen cell cultures. In the present study, we have defined culture conditions required for induction of in vitro thymic independent (TI) immune responses in the rat. Rat spleen cell cultures support low responses to various trinitrophenyl (TNP) haptenated antigens including TNP-Brucella abortus (TNP-BA), TNP-lipopolysaccharide [LPS; either phenol (Ph)- or butanol (Bu)-water extracted], TNP-Ficoll, and TNP-dextran. However, all of these antigens induced good splenic anti-TNP PFC responses when given at appropriate doses in vivo. When spleen cells were depleted of adherent cells and cultured with TI antigens in vitro, good anti-TNP PFC responses were seen with TNP-BA, whereas, lower responses were induced by TNP-LPS (Ph or Bu). No responses were observed in cultures incubated with either TNP-Ficoll or TNP-dextran. Purified splenic B cell cultures [prepared by panning on plates coated with anti-rat F (ab')2] supported good responses to TNP-LPS (Ph or Bu) and TNP-BA. The addition of irradiated splenic adherent cells (macrophages, M phi) to either M phi-depleted or purified B cell cultures completely abrogated in vitro responses to TNP-BA or TNP-LPS (Ph or Bu). Purified splenic B cell cultures generally responded poorly to TNP-Ficoll or TNP-dextran. Addition of indomethacin (IM) to spleen cell cultures abrogated suppression and allowed anti-TNP PFC responses to TNP-BA, TNP-LPS (Ph or Bu), TNP-Ficoll, and TNP-dextran. Furthermore, nude spleen cell cultures treated with IM, also allowed significant TNP-Ficoll and TNP-dextran immune responses; however, untreated cultures did not respond to these antigens. Our studies indicate that rat splenic B cell cultures are responsive to TI antigens, and highest responses occur with the murine TI-1 class, e.g., TNP-BA and TNP-LPS. Inhibition of suppression with IM restored splenic B cell responses to the murine TI-2 class, i.e., TNP-Ficoll and TNP-dextran.     

Lymphocyte activation by the Fc region of immunoglobulin. I. Role of prostaglandins in the down regulation of Fc fragment-induced polyclonal antibody production

Fc fragment-, subfragment-, and p23-induced polyclonal antibody production are regulated by endogenous and exogenous PGE. Addition of the PG synthetase inhibitor indomethacin (IM) to murine spleen cell cultures resulted in a significant increase in the amount of Ig secreted. Moreover, addition of exogenous PGE to culture resulted in a marked suppression of IgM and IgG secretion. Splenic adherent macrophages and P388D1 cells release PGE upon stimulation with Fc fragments, subfragments, and p23. The inclusion of IM or aspirin in culture was found to abrogate the ability of Fc fragments to induce PGE release from adherent cells. These results suggest a role for PG in immune complex mediated regulation of immune responses.     

Macrophage-mediated suppression of con A-induced IL-2 production in spleen cells from syphilitic rabbits

Blast transformation studies have indicated a diminished T cell response in spleen cell preparations from rabbits infected with Treponema pallidum. IL-2 synthesis by T lymphocytes is required for proliferation of these cells. Thus, Con A-induced IL-2 generation was measured in syphilitic animals infected for 9 to 14 days. IL-2 production in the infected rabbits was only one-half that observed for uninfected rabbits. This marked decrease in IL-2 was not caused by decreased IL-1 secretion by adherent cells from infected animals because similar levels were found in both infected and uninfected splenic cultures. This decrease was also not caused by an increase in infected spleen cell adsorption of IL-2; similar numbers of receptors for this IL were present in Con A-stimulated infected and uninfected splenic preparations. The inhibited IL-2 production in infected spleen cells was reversed upon removal of the adherent cells and also elevated upon addition of indomethacin to the cultures. PGE levels were also elevated in splenic cultures from infected animals. Finally, IL-2 synthesis, when evaluated at various days postinfection, showed that at 4 days, splenic cells generated twice as much IL-2 as uninfected cells. At 9 to 14 days, IL-2 levels were dramatically decreased (50% lower than that observed in uninfected cultures), and suppression of IL-2 by adherent cells was observed as late as 35 days post-infection. We propose that premature down regulation (suppression) of IL-2 secretion is mediated by adherent cells via a cyclo-oxygenase product, most likely PGE. These results may explain why most, but not all, treponemes are cleared during infection, and why the secondary manifestations of the disease occur.     

Selective immunomodulation by the antineoplastic agent mitoxantrone. I. Suppression of B lymphocyte function

Novantrone mitoxantrone, an antineoplastic agent with antiproliferative properties, is under investigation as an immunomodulating agent. The impact of mitoxantrone treatment on B lymphocyte reactivity is presented here. Administered i.p. in H2O at a dose of 0.5 mg/kg, daily for 14 days, mitoxantrone abrogated both the in vivo antibody response (to ovalbumin) and the in vitro plaque-forming cell (PFC) response (to SRC). In addition to the effects on thymus-dependent reactivity, PFC responses to the thymus-independent antigens TNP-LPS and TNP-Ficoll were also inhibited when tested in vivo or in vitro. B cells were identified as a target for the suppressive activity of mitoxantrone by using T cell-replacing factor to reconstitute the in vitro anti-SRC PFC response of a T lymphocyte-depleted spleen cell preparation. LPS-induced B cell mitogenesis was largely inhibited by mitoxantrone treatment. However, depletion of Sephadex G-10-adherent cells significantly restored the proliferative response. Flow cytometric analysis revealed a dramatic decrease in splenic B lymphocyte content. Therefore, mitoxantrone exerted a potent suppressive influence on the humoral immune system through a direct reduction in B cell number augmented by macrophage-mediated inhibition of B cell proliferation.     

Cell interactions in alveolar macrophage-mediated suppression of the immune response: an unusual suppressor pathway involving a population of T-cells that express Lyt-1, L3T4, and I-J

Studies from this laboratory have demonstrated that incubation of murine alveolar macrophages (AM) with SRBC-primed spleen cells (SC) results in suppression of the in vitro plaque-forming cell (PFC) response and that suppression is mediated by a soluble factor contained in supernatants obtained from cultures of AM and SC. In the present study, immunological techniques employing monoclonal antibody (MoAb) were used to isolate various T-cell subsets in order to determine the phenotype of the cells which interact with AM to produce suppression. Spleen cell populations depleted of Thy-1+-, Lyt-1+-, L3T4+-, or I-J+-bearing cells failed to generate suppressive supernatants when cultured with AM. Depletion of Lyt-2+ T-cells (the classical suppressor/effector subset) did not alter the ability of the remaining cell population to cooperate with AM for generation of suppressive supernatants. Direct suppression of the PFC response in cultures containing AM was abrogated after treatment of the spleen cells with anti-I-J, but not anti-Lyt-2 MoAbs. Reconstitution of the AM-mediated suppressive response with enriched populations of SC required the presence of T-cells which expressed Lyt-1, L3T4, and I-J. These results suggest the existence of an unusual suppressor pathway involving I-J restriction but which appears to be mediated by the interaction of AM with a population of T-cells that expresses surface markers characteristic of T-helper cells.     

The role of membrane gangliosides in murine alveolar macrophage-mediated suppression of the immune response

Generation of aldehydes on cell membranes of viable alveolar macrophages (AM) by mild oxidation with sodium periodate was previously shown to result in total abrogation of AM-mediated suppression of the plaque-forming cell (PFC) response of spleen cells previously primed with sheep erythrocytes (SRBC). These results suggested a possible role for macrophage sialoglycoconjugates, such as gangliosides and sialoglycoproteins, in suppression. In the present report, it is shown that a purified mixture of gangliosides suppressed the PFC response of SRBC-primed spleen cells in a dose-dependent manner. Addition of rabbit anti-mouse brain antiserum (RAMB), which reacts with the gangliosides, reversed both ganglioside- and AM-mediated suppression of the PFC response. Pretreatment of AM but not spleen cells with RAMB also resulted in the reversal of AM-mediated suppression. The expression of gangliosides on the membrane of AM was detected with RAMB in an enzyme-linked immunosorbent assay (ELISA). The results suggest that membrane gangliosides may play an important role in the AM-mediated suppression of the PFC response. Since paraformaldehyde-fixed AM were not suppressive, it is speculated that AM release the suppressive gangliosides into the culture medium and rabbit anti-mouse brain antibody either prevents their release and/or neutralizes the suppressive function of released gangliosides.     

Immunosuppression by spleen cells from Moloney leukemia. Comparison of the suppressive effect on antibody response and on mitogen-induced response.

The inhibitory effect of cells from leukemic spleens on the immune functions of normal lymphocytes was studied. Suppressor cells were obtained as the nonadherent fraction (NA) from splenic tumors of mice infected with MuLV-Moloney. This fraction (NA MuLV- M) contained less than 10% membrane Ig-positive (Ig+) cells, 45 to 60% theta-positive cells (theta+) and 40 to 50% naught cells (theta-, Ig-). Similarly prepared fractions from normal control spleens (NAc) containing 75 to 90% theta+cells and less than 10% Ig+ and naught cells were utilized in control cultures. Addition of the NA MuLV- M cells into cultures (Marbrook system) of normal spleen cells with sheep red blood cells suppressed the specific antibody response determined by the number of hemolytic plaque forming cells (PFC). The PFC response was significantly suppressed at a suppressor cell to responder cell ratio of 1:100, and was completely abolished at a ratio of 1:10 or higher. The control NAc fraction showed some inhibitory effect only at high suppressor to responder ratios (1:2 or 1:1). In contrast, the suppressive effect of NAMuLV-M on mitogen-induced 3H-thymidine incorporation in normal B and T cells was much weaker. Very little, if any, suppression occurred at the ratio of 1:100 or 1:10, however, about 50% decrease in DNA synthesis was observed at the ratio 1:2 or 1:1. On the basis of this differential suppressive effect, it is suggested that leukemic spleen cells can suppress the function of immunocompetent cells by more than one mechanism.     

Trypanosoma cruzi-induced suppression of IL-2 production. II. Evidence for a role for suppressor cells

Suppression of IL-2 production during experimental Chagas' disease accounts at least in part for the overall depressed state of the immune system in infected mice. The failure to produce IL-2 in response to mitogen stimulation is not the result of the lack of cells capable of producing IL-2, but appears to be due to regulation of IL-2 production by suppressor cells. This conclusion is supported by cell-mixing experiments where the ability of cells from infected mice to suppress normal spleen cell IL-2 production is evident. Although depletion of plastic and Sephadex G-10 adherent cells results in modest increases in IL-2 production by spleen cells from infected mice, even in the presence of normal adherent cells as a source of IL-1 producers, IL-2 production does not approach normal levels. Also, isolated macrophages are not by themselves suppressive for normal spleen cell IL-2 production, whereas plastic and G-10 nonadherent cells from infected mice are. Depletion of Thy-1+ and Ly-2+ cells not only completely abrogates the ability of spleen cells from infected mice to suppress normal IL-2 production, but results in a cell preparation which actually enhances IL-2 production. Anti-Ly-2 and C treatment of infected spleen cells also markedly enhances their ability to produce IL-2. These results indicate a major role for Ts cells in the regulation of IL-2 production, and a relatively minor role of macrophages as direct effector cells of suppression in this response. The ability to enhance IL-2 production in this system with PG synthesis inhibitors suggests a role for PG-producing cells such as macrophages in the suppressor mechanism, perhaps as inducers of the suppressor effector cells.     

Suppression of in vitro primary immune response by L1210 cells and their culture supernatant: Evidence for cytotoxic effects

L1210 cells and their culture supernatants were found to inhibit the generation of PFC in the in vitro primary immune response of spleen cells to SRBC. As few as 1% of L1210 cells and 1% of culture fluid were inhibitory. Inhibition of DNA or protein synthesis of L1210 cells did not abolish their immunosuppressive activity, excluding exhaustion of culture medium as a possible mechanism of inhibition of PFC. Heating of the supernatant completely abrogated the suppressive effect and resulted in a marked increase of PFC. Daily evaluation of cell viability in the cultures revealed that, in the presence of L1210 and supernatants, the fraction of surviving cells is markedly reduced. We conclude that a direct cytotoxic effect on splenic lymphocytes and macrophages is the predominant immunosuppressive mechanism of L1210 cells and their culture supernatants.     

C-Reactive protein (CRP)-mediated inhibition of the induction of in vitro antibody formation. I. T-cell dependence of the inhibition.

Purified human C-reactive protein (CRP) inhibited the in vitro anti-hapten antibody plaque-forming cells (PFC) response of both carrier keyhole limpet hemocyanin (KLH)-primed and unimmunized Balb/c spleen cells to TNP-KLH. The inhibitory effect was neutralized by the CRP-substrate, C-polysaccharide. The response to the T-independent antigens, TNP-T4 and DNP-lys-Ficoll, was not inhibited by CRP. A cell population that was suppressive for the in vitro PFC response was generated by incubating normal spleen cells with CRP. These cells suppressed the PFC response of syngeneic KLH-primed cells to TNP-KLH in proportion to the number of added lymphoid cells with bound CRP. Selective depletion of B cells, T cells or macrophages before incubation with CRP revealed that T cells were required for the induction of suppressive cells. Treatment of spleen cells after incubation with CRP, with T cell-specific antisera and C abolished suppressor-cell activity. Mitomycin-C treatment of the CRP-binding cells did not alter their suppressive activity. These results indicated that CRP mediates suppression of antibody induction to T-dependent antigens by interacting with T cells and generating a suppressive T-cell population.     

Immunoregulation in the rat: cellular and molecular requirements for B cell responses to types 1, 2, and T-dependent antigens

The requirements for primary in vitro plaque-forming cell (PFC) development in cultures of purified rat splenic B cells have been examined. Rat B cells were directly responsive to the type 1 antigen trinitrophenyl-Brucella abortus (TNP-BA), but both T cells and adherent accessory cells were required for B cell responses to the type 2 antigen TNP-Ficoll and the T cell-dependent (TD) antigen sheep erythrocytes (SRBC). However, the cellfree supernatants from concanavalin A-induced spleen cells of rat or mouse origin replaced the requirement for T cells and macrophages, and resulted in PFC development in response to TNP-Ficoll and SRBC and augmented PFC numbers in response to TNP-BA. Culture supernatants from induced murine T cell and macrophage cell lines were used to partially deduce the molecular requirements for the support of PFC development by rat B cells to these three antigens. Supernatants from the EL-4 (EL-4 sup) and B151 K12 (B15 sup) T cell lines augmented TNP-BA responses, suggesting that B cell growth factor II (BCGF-II) mediated this effect. An admixture of purified interleukin 2 (IL 2) and B15 sup supported PFC development to SRBC; indicating that IL 2, BCGF-II, and the T cell-replacing factor in B15 sup (B15-TRF) were sufficient to support this response. In addition, the IL 2 plus B15 sup-supported anti-SRBC PFC response was increased by the addition of an interleukin 1-containing fraction from the supernatant of the macrophage line P388D1. PFC development in response to TNP-Ficoll had the most stringent requirements and only occurred in the presence of EL-4 sup and B15 sup (IL 2, BCGF-I, BCGF-II, EL-TRF, B15-TRF). These data indicate that different cellular and molecular requirements exist for PFC development in response to types 1, 2, and TD antigens by rat B cells.     

Graft-versus-host induced immunosuppression: depressed T cell helper function in vitro.

The cause of graft-versus-host (GVH) induced suppression of the plaque forming cell (PFC) response to sheep erythrocytes (SRBC) was investigated by in vitro restoration experiments employing a double compartment culture vessel. The two culture compartments were separated by a cell impermeable membrane. Restoring cells were placed in one chamber and responding GVH spleen cells plus SRBC were placed in the other chamber. It was demonstrated that thymus, lymph node, and spleen cells restored the PFC response whereas bone marrow cells did not. Treatment of the restoring cells with anti-theta serum plus complement abrogated restoration. Supernatants obtained from antigen free cell cultures restored nearly as well as whole cell suspensions. The degree of restoration was not increased by allogeneic or xenogeneic antigenic stimulation of the restoring cells. Thymus and lymphoid cells obtained from animals experiencing a GVH reaction restored as well as normal cells, however spleen cells were unable to restore by day 5 post-GVH induction. The results suggest that GVH induced immunosuppression of the PFC response is due, at least in part, to a depressed T cell factor production by splenic T cells.     

Activation of lymphoid cells by BCG in vitro

Bacillus Calmette-Guerin (BCG) stimulated splenic and thymic lymphocytes in vitro as measured by uptake of ³H-thymidine. This activation of lymphocytes by BCG required the presence of a critical concentration of macrophages. Thymus cells containing no more than 0.25% macrophages were stimulated by BCG, but reduction of macrophages below this level by adherence to plastic abolished the response. Reconstitution with purified macrophages completely restored the response. A high concentration of adherent cells (“macrophages”) depressed the response of splenic lymphocytes, as judged by the improvement in DNA synthesis after reduction of the proportion of adherent cells in the spleen cell population.Bacillus Calmette-Guerin augmented the production of lymphocyte-activating factor (LAF) from purified splenic adherent cells, but the presence of lymphocytes made that augmentation considerably greater.These data reaffirm the bidirectional nature of the relationship between lymphocytes and macrophages. They further show that BCG can create highly activated populations of each type of cell, in part by enhancing their interaction.