Hapten-specific T cell responses to 4-hydroxy-3-nitrophenyl acetyl. XIII. Characterization of a third T cell population involved in suppression of in vitro PFC responses

The involvement of a third-order suppressor T cell population (Ts3) in the suppression of in vitro PFC responses was analyzed. It was shown that Ts2 effector-phase suppressor cells, induced by the i.v. injection of NP-coupled syngeneic spleen cells, require a third suppressor T cell population to effect NPb idiotype-specific suppression of an in vitro B cell response. This Ts3 population was shown to be present in NP-primed but not unprimed donors. The Ts3 population specifically binds NP and is Lyt-1-, Lyt-2+, I-J+ and bears NPb idiotypic determinants. The involvement of the Ts3 population in a suppressor pathway that requires recognition of idiotypic determinants is discussed.     

Regulation of IgG1 and IgG2 subclass expression by adjuvant-activated splenic suppressor T cells

Spleen cells from mice immunized with different adjuvants are able to suppress secondary in vitro IgG plaque-forming cell (PFC) responses. The suppressive effect is mediated by Lyt-2-positive T cells. IgG subclasses are affected differentially depending on the number of T suppressor (Ts) cells added in the assays. At low Ts cell concentration IgG2a and IgG2b PFC responses are selectively inhibited. At higher Ts cell concentration IgG1 responses could also be completely inhibited, but IgA and IgM responses are not affected. Suppressor cells responsible for IgG1, IgG2a, and IgG2b suppression are never found in the draining lymph nodes of adjuvant-immunized animals.     

Characterization of anti-idiotypic suppressor T cells (Tsid) induced after antigen priming

The induction and fine specificity of idiotype-specific suppressor T cells (Tsid) were studied. Spleen cells from C57BL/6 mice, immunized 4 wk previously with NP-KLH, failed to express NPb3 idiotype-bearing PFC when challenged in vitro with NP-Ficoll or NP-Brucella abortus. After treatment of NP-primed responder cultures with anti-Thy-1.2 anti-serum + C, NPb idiotype-bearing B cells could be detected. This B cell subset was preferentially suppressed by the addition of T cells from NP-primed mice. With this reconstitution protocol, it was determined that suppression of the NPb idiotype-bearing portion of the B cell response was mediated by a specifically induced T cell population (Tsid) that directly suppressed NPb-bearing B cells. As with a previously described suppressor population induced with hapten-modified syngeneic spleen cells (Ts2), the Tsid population bound and was lysed by NPb idiotype-bearing serum antibodies. However, the Tsid could be distinguished from the Ts2 population because it lacked I-J determinants and functioned as an effector T cell, not an intermediary suppressor cell. Furthermore, fine specificity studies with monoclonal NP-specific antibodies expressing various levels of serologically detectable NPb idiotypic determinants indicated that unlike the Ts2, the Tsid population reacts with conventional, serologically detected members of the NPb family. The combined idiotype binding studies for the Tsid and Ts2 populations demonstrate that the fine specificity of suppressor T cell populations reflects their independent mechanisms of regulation.     

Regulation of the secondary in vitro antibody response by endogenous natural killer cells: kinetics, isotype preference, and non-identity with T suppressor cells

Our previous studies had demonstrated that depletion of endogenous natural killer (NK) cells resulted in an augmented primary antibody response in vivo and in vitro. We have now examined the effect of NK cell depletion on the in vitro secondary response to antigen. Treatment of primed murine spleen cells with anti-NK-1.1 allo-antibody and complement before culture resulted in a significant increase in the magnitude of the antigen-specific plaque-forming cell (PFC) response. This treatment did not affect the proportions of Lyt-2+, L3T4+, or sIg+ cells in the population, however, indicating that the augmentation in PFC was not due to changes in the ratio of T to B cells. Removal of endogenous NK cells had a greater effect on the IgG (indirect) PFC response (100 to 200% increase) than on the IgM (direct) PFC response (25 to 50% increase). In contrast, removal of Lyt-2+ cells before culture affected the IgM and IgG responses similarly. Moreover, the kinetics of augmentation differed between cultures depleted of Lyt-2+ cells and those depleted of NK-1.1+ cells. NK cells appeared to act earlier in the response than did T suppressor cells. The NK-1.1+ cells involved in antibody regulation were not involved in the generation of the in vitro derived T suppressor cells. The conclusion that the regulation of the antibody response by NK-1.1+ cells is distinct from that involving T suppressor cells was confirmed in experiments in which removal of both regulatory cell populations resulted in an increase in PFC that was greater than in cultures depleted of either NK or T suppressor cells.     

Anti-idiotypic B cells are required for the induction of suppressor T cells

A nylon wool-adherent, B cell-enriched population is required during the in vitro induction of third order effector suppressor T cells (Ts3). This B cell population expresses IgM and IgD and is devoid of conventional T cell markers such as Thy-1, L3T4, and Lyt-1. Treatment of the B cell population with anti-NP antibodies expressing the NPb idiotype and complement specifically eliminated the ability to generate Ts cell activity, suggesting that the critical B cells expressed anti-idiotypic receptors. To independently verify the role of anti-idiotypic B cells in the generation of Ts cells, B cells were panned on antibody-coated plates. The results demonstrated that only NPb idiotype-binding B cells could induce effector suppressor cells from naive T cell populations. The combined data demonstrate the role of Ig network interactions in the generation of Ts cells.     

Metabolic activity is necessary for activation of T suppressor cells by B cells

Ag-primed B cells must express cell-surface IgM, but not IgD or Ia Ag, and must remain metabolically active, in order to activate suppressor T cells (Ts) specific for type III pneumococcal polysaccharide. Ag-primed B cells that were gamma-irradiated with 1000r, or less, retained the ability to activate Ts; however, Ag-primed B cells exposed to UV light were not able to do so. gamma-Irradiated and UV-treated Ag-primed B cells both expressed comparable levels of cell-surface IgM, and both localized to the spleen after in vivo transfer; neither could proliferate in vitro in response to mitogens. By contrast, gamma-irradiated primed B cells were still able to synthesize proteins, whereas UV-treated primed B cells could not. These findings suggest that in order for Ag-primed B cells to activate Ts, they must a) express cell-associated IgM (sIgM) antibody bearing the idiotypic determinants of antibody specific for type III pneumococcal polysaccharide, and b) be able to synthesize protein for either the continued expression of sIgM after cell transfer, or for the elaboration of another protein molecule that is also required for the activation of Ts; this molecule does not appear to be Ia Ag.     

Immunoregulatory pathways in adult responder mice. II. Regulation of delayed-type hypersensitivity responses by GAT-specific suppressor factors present in GAT-tolerant adult responder mice

We studied the effects of T cell extracts from adult responder BALB/c mice tolerized with poly(Glu60Ala30Tyr10) (GAT)-coupled syngeneic spleen cells (GAT-SP) on delayed-type hypersensitivity (DTH), T cell-proliferative (Tprlf), and plaque-forming cell (PFC) responses. Adult responder mice injected i.v. with GAT-SP develop Lyt-1-2+ suppressor T cells (Ts), which suppress the induction of GAT-specific DTH and PFC, but not Tprlf responses. Sonicates from these Ts contain an afferent-acting, soluble factor(s) (GAT-TsFdh) that specifically suppresses the same responses as the intact Ts (i.e., DTH and PFC, but not Tprlf). Immunosorbent chromatography studies were employed to determine the molecular nature of the suppressive material active on both cellular and humoral responses. In both assay systems, GAT-TsFdh was found to bear determinants encoded by the I subregion of the H-2 complex and a receptor(s) for GAT. BALB/c-derived GAT-TsFdh suppressed the induction of GAT DTH in syngeneic BALB/c and H-2-compatible B10.D2, but not in allogeneic C57BL/6 or CBA/Cum, suggesting a possible H-2 restriction in the suppression. It was also shown that one target of functional regulation by GAT-TsFdh is the T helper cell for DTH responses (DTH-Th). The results suggest that similar Ts and TsF regulate humoral and cell-mediated responses, perhaps by affecting a target common to both pathways (e.g., the T helper cell). The resistance of Tprlf responses to suppression by GAT-TsFdh indicates that the effector DTH-Th target is not a major component of the proliferative response. These data are discussed with respect to GAT-specific TsF-regulating PFC responses, which have been identified in nonresponders and in responders tolerized as neonates with GAT.     

Regulation of T15 idiotype dominance. II. Genes unlinked to the Igh locus regulate T15 dominance of the secondary adoptive transfer response to phosphocholine

We have studied the idiotype and fine specificity of the secondary immune response to phosphocholine (PC) in C57BL (B10, B10.D2, and B.C8) and BALB (BALB/c, BAB-14, and C.B20) congenic strains of mice. In vivo IgM responses of mice from these two genetic backgrounds differed in their T15 idiotypic representation. BALB strains expressed the T15 idiotype on greater than 90% of their IgM, PC-specific plaque-forming cells (PFC), whereas C57BL strains expressed the T15 idiotype on approximately 50% of their IgM PFC. All strains examined expressed greater than 75% PC-inhibitable, VHPC idiotype-positive, IgM PFC. The IgG3 and IgA memory responses were similar to the IgM memory response; BALB strains produced a higher proportion of T15+ PFC than C57BL strains; however, the majority of IgG3 and IgA PFC in all strains were VHPC+, and PC-inhibitable. In contrast, the IgG1 memory response was not dominated by T15+, VHPC+, PC-inhibitable PFC in any of the strains tested. The IgG1 PFC required nitrophenylphosphocholine (NPPC) for efficient inhibition. The IgG2 memory response generally mimicked the IgG1 response with respect to idiotype and specificity. These data demonstrate that the representation of the T15 idiotype in the anti-PC immune response is determined by genes outside both the MHC and Igh genetic loci. Control of T15 expression in secondary IgM, IgG3, and IgA anti-PC responses was examined by using a cell-mixing protocol with primed T and B cells from BALB/c and B10.D2 mice. T15 representation in these responses was determined by the genotype of the B cell, not by the genotype of the helper T cell. Similarly, the B cell genotype was responsible for the idiotypic profile of a primary, in vitro, T-dependent, anti-PC response.     

Regulation of B cell maturation and differentiation. I. Suppression of pokeweed mitogen-induced B cell differentiation by tumor necrosis factor (TNF)

Growth and differentiation of B cells into Ig-secreting plasma cells is regulated by both T cells and macrophages and/or their secreted factors. Although the regulatory role of various cell-derived factors has been examined, the involvement of the macrophage-derived factor, TNF, in human B cell growth and differentiation has not yet been investigated. In the present study we examine the role of rTNF in polyclonal B cell response of human PBL induced by PWM. The addition of rTNF at the initiation of the culture resulted in the dose-dependent inhibition of the generation of both IgG and IgM PFC. Inhibition of PFC development followed the same dose response as rTNF-mediated cytotoxicity against a TNF-sensitive tumor target. The mechanism of rTNF-mediated suppression was examined in different experimental systems. Recombinant TNF did not affect the viability or proliferation of either the T cell or B cell subpopulations, suggesting that TNF does not mediate its suppressive effect by cytotoxic mechanisms. Kinetic studies in which rTNF was added at different times after initiation of culture indicated that inhibition can be observed as late as 4 days of culture and suggested that TNF acts at a late phase of the growth and differentiation pathway of B cells. In further studies we examined the cellular level of TNF-mediated suppression. The addition of rTNF to supernatants containing helper factors and enriched B cells resulted in no inhibition, suggesting that TNF does not act at the B cell level. This was confirmed by demonstrating that rTNF does not inhibit spontaneous PFC development by the CESS B cell line. The effect of TNF on T cell subpopulations was examined by using normal or irradiated T cells, which inactivate suppressor cells. Addition of rTNF to B cells combined with either T cell population suppressed both IgG and IgM PFC development, indicating that the target cell for suppression is the T helper cell but not ruling out an effect on macrophages or the T suppressor cells. Combined, the observed results demonstrate that rTNF suppresses PWM-induced B cell differentiation without affecting B cell proliferation. TNF appears to mediate the suppression by acting directly on T helper cells or else by regulating the production of factors controlling T cell activation and lymphokine secretion.     

Hormonal regulation of soluble immune response suppressor (SIRS): a possible role of SIRS in the maintenance of pregnancy

This study was conducted to investigate the effects of sex hormones upon the nature of soluble immune response suppressor (SIRS) produced by concanavalin A-stimulated Lyt-2+ T cells. Conventional SIRS affected IgM PFC only. However, SIRS made with progesterone (20-400 ng/ml or Prog-SIRS) suppressed IgM PFC, one-way MLR, and generation CTL; and SIRS made with estrogen (0.2-50 ng/ml or Est-SIRS) enhanced these responses. The factor(s) (MW 40,000-55,000) to stimulate macrophages to produce the second soluble factor (M phi-SF) was isolated from all preparations by gel filtration. Furthermore, Est-SIRS contained a factor(s) (MW 10,000-30,000) to enhance IgM PFC, MLR, and mitogen-induced blastogenesis of both T and B cells; and Prog-SIRS possessed the suppressive factor(s) to IgM PFC, MLR, and mitogen-induced T-cell proliferation. These activities were not impaired by 2-mercaptoethanol. Moreover, the suppressive activity of Prog-SIRS was completely absorbed by T cells only, but the enhancing activity of Est-SIRS was not completely absorbed by a single-cell population. These data suggest that progesterone can contribute to the suppression of allograft rejection through soluble factors, and estrogen can enhance host responses which may be affected by several soluble factors during pregnancy.     

Activation of idiotype-specific suppressor T cells by injection of antibody carrying a recurrent idiotype

Intravenous injection of spleen cells (SC) coated with an antitrinitrophenyl (anti-TNP) IgM monoclonal antibody, Sp6 (Sp6-SC), which carries a recurrent idiotype, resulted in activation of a Lyt-2-positive population which did adhere to Sp6-coated plates. No effect of Sp6-SC injection could be observed in vivo on an anti-TNP B-cell response when mice were primed with an immunogenic dose of TNP-horse red blood cells (HRBC), but an anti-TNP response was observed when Sp6-SC-injected mice were primed with a subimmunogenic dose of TNP-HRBC. Furthermore, after intravenous (iv) injection of Sp6-SC, it was no longer possible to suppress a primary anti-TNP response by iv injection of TNP-haptenized thymocytes. In vitro analysis showed that the Sp6-induced suppressor T cell (Ts) population had no measurable influence on TNP-specific naive B cells, nor did it suppress TNP-specific helper T cells (THTNP), but it did lead to counterregulation of TNP-specific suppressor T cells (TsTNP). Hence, iv injection of antibody carrying a recurrent idiotype resulted in activation of a Ts population which functioned as inhibitor of suppression, thus displaying a helper effect.     

An in vitro system for the generation of suppressor cells and the requirement for B cells in their induction

An in vitro method for the generation of effector suppressor cells (Ts3) was developed. By utilizing this protocol, it was possible to investigate both the cellular and genetic requirements for suppressor cell induction. It was determined that populations containing Ts3 cells can be induced after a 4-day culture of spleen cells and antigen. These Ts3 cells are similar to Ts3 cells generated by in vivo immunization. Both populations are I-J+, bind NP hapten, bind NP hapten, bear receptors which share NPb idiotypic determinants with anti-NP antibodies, function during the effector phase of the immune response, and require activation with Ts2 cells. Generation of Ts3-containing populations required both nylon wool-nonadherent T cells and a nylon-adherent, B cell-enriched population from an Igh-identical donor. T cells cultured with antigen alone or with syngeneic macrophages and antigen did not develop suppressive activity. Lytic treatment of the nylon-adherent population with a B cell-specific monoclonal antibody (J11d) removed the ability to generate suppressor cells. These results imply that the induction of suppressor T cells requires B lymphocytes, and that this induction process is dependent on Igh-linked gene products.     

Differential regulation of activation, clonal expansion, and antibody secretion in human B cells

Limiting dilution analysis, hemolytic plaque assay, and ELISA procedures were used to study the recruitment, clonal expansion, and antibody secretion in human TNP-specific B cells activated in the presence of TNP-ovalbumin (TNP-OA), pokeweed mitogen (PWM), or regulatory T cells. TNP-OA-responsive, hapten-specific PFC precursor cells occupy approximately 0.5% of all sIgM+/sIgD+ B cells in cord blood, bone marrow, peripheral blood, and tonsil. The PWM-responsive, hapten-specific PFC precursor pool is 70 to 90% smaller and does not express sIgD. Antigen-reactive B cells go through a minimum of three divisions in culture (six to nine PFC per clone), and antibody secretory rates of about 10(4) molecules IgM/cell/hr are achieved. In contrast, PWM-induced clone sizes were at least 60 PFC per clone, with antibody secretory rates of approximately 6 to 7 X 10(4) molecules IgM/cell/hr. Addition of high-dose carrier-primed suppressor T cells to limit dilution cultures reduced PFC precursor cell recruitment by up to 99%. However, in the few clones escaping from suppression, both clonal expansion and antibody secretory rates were much higher than in suppressor cell-free cultures, generating 30 to 60% of the antibody secreted in controls but with consequently much more restricted clonal diversity. When limiting dilution cultures were compared with standard microcultures of 2 X 10(5) cells, both clonal expansion and antibody secretory rates were much lower than expected, with a culture efficiency calculated to be 10 to 20% of that in low-density cultures. Our data suggest that the B cell subsets activated by antigen and by mitogen differ in their abilities for clonal expansion and antibody secretion. The hapten-specific and -responsive B cell family is expressed early in ontogeny, and in adults it is distributed evenly throughout the body. These limiting dilution experiments revealed that the primary effect of regulatory T cells is a drastic reduction in clonal diversity, and much less a mere reduction in overall response magnitude.     

Coexistence of antigen-specific and idiotype-specific suppressor T cells in mice injected neonatally with a mixture of antigen and anti-idiotype antibody

Specific tolerance to phosphorylcholine (PC) can be induced in BALB/c mice by neonatal injection with either pneumococcal C-polysaccharide (PnC) containing PC or anti-TEPC-15 idiotype (T15id) antibody which recognizes the predominant idiotype of anti-PC antibody of BALB/c mice. Suppressor T cells (Ts) induced after treatment with anti-T15id antibody react with the T15id and PnC-induced Ts cells appear to recognize PC. A brief incubation of anti-id-induced, T15id-specific Ts with PnC-induced, PC-reactive Ts resulted in complete cancellation of their suppressor functions. However, both types of Ts were present in mice neonatally injected with mixtures of PnC and anti-T15id antibody. Neutralization experiments using either PnC-induced or anti-id-induced suppressor T cells strongly suggest that only one of the Ts cell types is functionally dominant in those mice: most frequently, T15id-specific Ts cells. The suppressor function of the other population is detectable only when the predominant Ts cell population is removed by anti-id or monoclonal IgM anti-PC (SP45) plus complement. However, both suppressor activities are completely eliminated when one of the Ts populations is removed by adherence to either antigen or T15id. These results suggest that mice neonatally injected with a mixture of antigen and anti-id antibody possess both types of suppressor T cells, yet only one type is functionally dominant.     

T cell regulation of B cell activation. An antigen-mediated tripartite interaction of Ts cells, Th cells, and B cells is required for suppression

To determine the requirements underlying the antigen specificity observed in T cell-mediated immune response suppression, cloned major histocompatibility complex (MHC)-restricted T suppressor (Ts) cells specific for keyhole limpet hemocyanin (KLH) and cloned MHC-restricted T helper (Th) cells specific for fowl gamma-globulin (FGG) were employed to study the regulation of trinitrophenyl (TNP)-specific B cell responses. Neither antigen bridging between Ts cells and Th cells (FGG=KLH) nor bridging between Ts cells and B cells (TNP-KLH) was sufficient to allow suppression; a mixture of FGG=KLH and TNP-KLH was also insufficient for suppression. In contrast, suppression was induced by KLH-specific Ts cells only when suppressor determinants (KLH), helper determinants (FGG), and B cell determinants (TNP) were covalently linked on the same molecule (TMP-FGG)=(TNP-KLH) or TNP-(FGG=KLH)). These findings imply that a tripartite antigen-mediated interaction of Ts cells, Th cells, and responding B cells is necessary for the mediation of this antigen-specific suppression.     

Keyhole limpet hemocyanin-propagated Peyer's patch T cell clones that help IgA responses

Four T cell clones, isolated from Peyer's patches of keyhole limpet hemocyanin (KLH)-primed BALB/c mice, were selected on the basis of their ability to help IgA responses by TNP-KLH-primed BALB/c mouse B cells. Two were KLH-dependent both in terms of their own proliferative response and in terms of their help for that of B cells. The other two were autoreactive and helped B cells proliferate independently of the presence of Ag. Both primed and unprimed B cells proliferated to some extent when helped by the KLH-reactive clones in the presence of high concentrations of either KLH or TNP-KLH. Much higher proliferation was, however, induced when primed, but not unprimed, B cells were exposed to the T cells in the presence of low concentrations of TNP-KLH but not KLH, i.e., under conditions favoring direct, cognate interaction between the T and B cells. Only modest IgM, and no IgG or IgA plaque-forming cell (PFC) responses were generated by TNP-primed B cells upon interaction with either autoreactive T cells in the absence of Ag or KLH-reactive T cells in the presence of high concentrations of KLH. For high IgM responses as well as for the appearance of IgG and IgA PFC responses, TNP-KLH was required whatever the source of the T cell help. The isotype ratios depended on the TNP-KLH concentration; IgA responses were highest and IgM responses lowest at the lowest TNP-KLH concentrations suggesting that the precursors of the IgA PFC have higher average affinity for TNP than the precursors of IgM PFC. Overall, the results are compatible with the idea that the precursors of IgA and IgG PFC and many of the precursors of IgM PFC in the long term primed B cell populations used in these experiments require engagement of their Ag-receptors before they express sufficient class II Ag and/or receptors for "switch" and differentiation factors for cognate interaction with T cells leading to PFC responses.     

Relationships between antigen-specific helper and inducer suppressor T cell hybridomas

Ts1, or inducer suppressor T cells, share many phenotypic and functional characteristics with helper/inducer subset of T cells. In order to evaluate the relationship between these cell types, we made a series of new Ts1 hybridomas by the fusion of Ts1 cells with the functionally TCR alpha/beta-negative BW thymoma (BW 1100). Three Ts1 hybridomas (CKB-Ts1-38, CKB-Ts1-53, and CKB-Ts1-81) were established that express TCR and produce Ag-specific suppressor factors constitutively, thus making it possible to study the nature and specificity of Ag receptors, MHC restriction, and lymphokine production by the Ts1 hybridomas. Results presented in this report demonstrate that all the Ts1 hybridomas described here express CD3-associated TCR-alpha beta. These three Ts1 hybridomas recognize Ag (NP-KLH) specifically in a growth inhibition assay and this recognition is restricted by IE molecules. Two of the hybridomas also produce IL-2 or IL-2 and IL-4 upon Ag-specific activation. Thus, by these three criteria the Ts1 hybridomas appear indistinguishable from Th cells. These three Ts1 hybridomas, however, release suppressor factors (TsF1) in the supernatant that suppress both in vivo DTH and in vitro PFC responses in an Ag-specific manner. Like the TsF1 factors characterized previously, the suppression mediated by these factors are Igh restricted and lack H-2 restriction. These factors mediate suppression when given in the induction phase but not during the effector phase of the immune response. The TsF1 factors are absorbed by Ag (NP-BSA), and anti-TCR affinity columns and the suppressor activity can be recovered by elution. The data are consistent with the interpretation that Ts1 inducer-suppressor T cells are related to Th cells; the feature that distinguishes these cells is the ability to produce Ag-binding factors that specifically suppress immune responses.     

A syngeneic splenic cell antigen induces a suppressor T cell in lymph nodes that controls cytotoxic T-cell and primary antibody responses

The nonspecific suppression of immunological responses that is generated within host popliteal lymph nodes upon exposure to syngeneic normal spleen cells has been examined. The suppression, which had previously been described as being capable of preventing initiation of cytotoxic T lymphocytes (CTLs) to hapten-altered self antigens, arises within 3 to 7 days after injecting the spleen cells. Suppression was shown to be attributable to an induced T cell that was functional when transferred intravenously. Although the cell surface marker(s) on both splenic B and T cells that stimulates appearance of Ts has not yet been identified, the cells possessing the marker were not required to be viable to cause the induction. We have shown here that the Ts is fully functional when it is put in the antigenic site used for CTL immunization. The induced Ts has been identified as bearing the Lyt 2.1 cell surface marker. Furthermore, it has been shown to be insensitive to cyclophosphamide (CY), thus differentiating it from the naturally occurring Ts cell (TS0) that is known to be CY sensitive. In addition to preventing induction of CTLs toward hapten-altered self antigens, exposing popliteal lymph nodes to syngeneic spleen cells induced Ts capable of suppressing the primary IgM antibody response to sheep red blood cells. The Ts cells that suppressed the primary antibody response possessed the same Lyt cell surface markers and CY insensitivity as the Ts that mediated suppression of the CTL response. Thus, evidence that two dissimilar immunological reactions may be down-regulated by the same suppressor mechanism has been provided. Results of a kinetic study showed that the Ts prevented development of both the humoral and the cell-mediated immune responses by affecting their inductive phases. Possible targets for suppression that more than likely would have to be common to the two widely different immune responses have been indicated.     

Monoclonal antibodies specific for single chain or two chain GAT-specific suppressor factors: production and analysis of in vitro modulating properties

Fusion of spleen cells from rats hyperimmunized with T cell hybridoma derived GAT-specific TsF1 or TsF2 suppressor T cell factors has resulted in the generation of hybridomas secreting monoclonal antibodies reactive with the appropriate GAT-TsF used for immunization, and in several cases, reactive with other GAT-TsF1 and TsF2. The monoclonal anti-TsF1 antibodies are capable of modulating in vitro GAT-specific PFC response in a GAT-specific manner; some suppress responses to GAT directly, whereas others reverse GAT-TsF1-mediated suppression of responses. The monoclonal anti-TsF2 antibodies all reverse suppression but are reactive with combinatorial determinants, I-J+ chains or antigen-binding chains of the GAT-TsF2. The data are discussed in terms of the nature of the determinants recognized by these antibodies as well as the potential uses of these reagents for studying the suppressor T cell pathway and potential relationships between Ts1, Ts2, and T helper cells.     

Factors determining the effects of chronic protein-deficiency on antibody responses to sheep red blood cells and Brucella abortus vaccine in mice.

Chronic protein-deficiency in weanling mice caused variable suppression of the humoral plaque-forming cell (PFC) responses to sheep erythrocytes. This was most prominent at high antigen doses and did not increase when mice were maintained on the diets for longer periods. Antibody responses produced by deficient mice were often short-lived and involved high levels of IgM. Total PFC counts were depressed slightly more than were circulating antibodies. Antibody responses to Brucella abortus were slightly decreased by protein-deficiency at high antigen doses but were normal or elevated at lower doses, the proportion of IgM produced was increased and the splenomegaly response to B. abortus was severely depressed. These results suggest that the depression of antibody production by protein-deficiency is not simply due to an impairment of helper T cell function, but a reduction in the availability or effectiveness of macrophage and regulatory or suppressor T cells may be important.