Suppressor T cell growth and differentiation: production of suppressor T cell differentiation factor by the murine thymoma BW5147

Previous studies have identified a lymphokine, termed Ts differentiation factor (TsDF), in primary MLR supernatants that induces effector function of alloantigen-primed MLR-Ts. The present report describes constitutive production of TsDF by the murine thymoma BW5147, and its use to analyze alloantigen and TsDF requirements for MLR-Ts activation to TsF production. Serum-free supernatants of BW5147 restored the capacity of MLR-TsF production to alloantigen-primed MLR-Ts cultured with glutaraldehyde-fixed allogeneic stimulator cells, and were not themselves directly suppressive in the MLR assay. BW5147 supernatant induced MLR-TsF production from primed L3T4-Ly2+ MLR-Ts in the absence of concomitant proliferation, suggesting that the function of BW5147 supernatant, like that of MLR-derived TsDF, is a differentiative rather than a proliferative one, and is required for the synthesis or release of TsF. The differentiative activity of BW5147 supernatant was associated with a molecular species of approximately 14,500 m.w. by HPLC fractionation and was expressed independently of detectable IL 2, IL 3, IFN-gamma, and IL 1. The functional activity of BW5147 supernatant has therefore been provisionally designated BW5147-derived Ts differentiative factor, or BW-TsDF. By using BW-TsDF, it was demonstrated that MLR-Ts fail to respond to TsDF in the absence of, or preceding, reexposure to priming alloantigen. Instead, alloantigen binding by primed MLR-Ts appears to create a transient state of TsDF responsiveness. Primed MLR-Ts were fully sensitive to delayed addition of TsDF for approximately 12 hr after reexposure to alloantigen, but became TsDF-unresponsive within 24 to 36 hr. MLR-Ts cultured alone for 36 hr were fully responsive to the combined addition of TsDF and alloantigen. Thus, MLR-Ts activation to TsF release requires the sequential events of specific alloantigen binding, which induces a TsDF-responsive state, followed by interaction with TsDF. The transience of induced TsDF responsiveness suggests a precise mechanism for control of antigen-initiated Ts activation to effector function.     

Interaction of idiotype-specific T suppressor factor with the hapten-specific third-order T suppressor subset results in antigen-nonspecific suppression

The interaction between the third-order T suppressor (Ts3) cell and the idiotype (Id)-specific second-order Ts factor (TsF2) was studied in the phenyltrimethylamino (TMA) hapten system. The experimental system which we used allowed the independent analysis of induction and activation requirements of Ts3. The procedure consisted of inducing the Ts3 in vivo and activating the enriched T-cell populations containing Ts3 in vitro with TsF2. The suppressive potential was then tested in mice previously primed for delayed-type hypersensitivity responses which were also treated with cyclophosphamide to deplete Ts3 and other drug-sensitive Ts cell types. Using this experimental system, it was found that the Id-specific TsF2 was required for the in vitro activation of Ts3. Furthermore, the TsF2 activated only the homologous and not heterologous antigen-primed Ts3-containing T cells and moreover, the target of TsF2 was found to be the Ts cells bearing hapten-specific receptors. Once the TMA hapten-specific Ts3 was activated with TsF2, the ensuing suppression was antigen nonspecific. The data demonstrate that the Ts3 represents a final effector Ts cell type in the TMA system.     

Idiotype-specific T suppressor factor alternatively interacts with a nonspecific T-acceptor-like cell to mediate immune suppression

The ability of the idiotype (Id)-specific second-order T suppressor factor (TsF2) to interact with a final effector Ts cell type other than the previously reported third-order Ts (Ts3) subset was studied in the phenyltrimethylamino (TMA) hapten system. Hence, mice were primed with unrelated heterologous haptens to induce the nonspecific T acceptor (Tacc) cells following published procedures. When enriched T cell populations containing these nonspecific Ts were briefly incubated in vitro with TMA-TsF2, they produced suppression upon adoptive transfer into cyclophosphamide-treated mice which had been previously immunized for TMA-specific delayed-type hypersensitivity. Despite the fact that the effector population studied in this report also required Id-binding TsF2 for its function, it differs markedly from the Ts3 subset studied previously in the TMA system. First, the cell type studied herein could be easily generated with noncrossreacting heterologous chemically reactive haptens when applied directly to the skin of mice. Furthermore, these Ts effector cells had no detectable intrinsic receptors for homologous haptens and most importantly, unlike Ts3, this population had no affinity for the TMA hapten. Nevertheless, the nonspecifically induced Ts once activated by TsF2 suppresses TMA-directed, but not similar immune responses specific for heterologous haptens. Thus the results indicate that TsF2 can functionally interact with a final effector Ts subset (very similar to the Tacc) other than the well described Ts3 population. The ramifications of these findings are discussed with reference to a generalized view of the cellular basis of terminal phases of immune suppression.     

A monoclonal antibody raised to tumor-specific T cell-derived suppressor factors also recognizes T suppressor inducer factors of the 4-hydroxy-3-nitrophenyl acetyl hapten suppressor network

A monoclonal antibody (mAb), B16G, was raised from BALB/c mice immunized with affinity-purified T suppressor factors (TsF) specific for the murine mastocytoma P815. This mAb was found to bind to polyclonal TsF isolated from the spleens of tumor-bearing animals, and to the TsF released from a P815-specific T cell hybridoma. In this study, B16G was tested for its reactivity with TsF produced in the 4-hydroxy-3-nitrophenyl acetyl hapten system. The factors from three types of suppressor T cell hybridomas, each representing the immortalized analogues of the inducer T suppressor cell (Ts1), transducer suppressor cell (Ts2), and effector suppressor cell (Ts3) network populations, were tested. B16G was found to be reactive with two sources of TsF1 as assayed by enzyme-linked immunosorbent assay and delayed-type hypersensitivity bioassay. By contrast, TsF2 and TsF3 were nonreactive with B16G. These results indicate that B16G recognizes class-specific suppressor factor determinants, and that the transducer/effector factors of the network are apparently serologically distinct. Because the B16G mAb fails to recognize 4-hydroxy-3-nitro-phenyl acetyl-specific TsF3 that share idiotype-related determinants with TsF1 yet binds to TsF1 molecules that have interacted with antigen, the binding is apparently independent of the site of antigen recognition. Additionally, the results show that the tumor-specific TsF1 raised in one suppressor system share serologic determinants with anti-hapten TsF1 raised in another.     

Age-related changes within a suppressor T cell circuit

The effects of aging on cellular and molecular components of the 4-hydroxy-3-nitrophenyl acetyl-specific suppressor T (Ts) cell circuit were analyzed in vitro using inducer (Ts1), transducer (Ts2), and effector (Ts3) cells and activating factors (TsF1 and TsF2) derived from young or old mice. The activation of Ts2 cells by TsF1 and of Ts3 cells by TsF2 was found age-restricted, suggesting a loss of Ts2 and Ts3 cell subsets in old mice. However, the activation of Ts3 cells by small amounts of TsF2 is more efficient when both are derived from old rather than from young mice while the same level of maximum suppression is attained. Higher affinity of the interactions involved in Ts cell activation may compensate for loss of Ts cell subsets in old mice. No age restriction was found for antigen presentation to Ts1 cells and for the interaction between Ts3 cells and target B cells. Thus, the effects of aging on immunosuppression result from changes within the Ts cell circuit.     

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.     

Requirements for suppressor T cell activation

Third-order (Ts3) suppressor cells are generated after conventional immunization. These cells, however, will not mediate suppressor cell function unless specifically triggered by an activating signal, termed TsF2. This report analyzes the mechanism of this TsF2-mediated triggering event. TsF2-mediated suppression is genetically restricted by genes in the I-J and Igh-V regions. The target of the I-J restrictions is a firmly adherent accessory cell, which appears to express I-J-related determinants. These accessory cells are sensitive to cyclophosphamide treatment and 500 R irradiation. In contrast, the target of the Igh-V restriction of TsF2 appears to be the Ts3 cell, which carries antigen-specific, idiotype-related receptors. The mechanism of suppressor cell activation appears to involve two stages. Presentation of I-J-restricted TsF2 by I-J-compatible presenting cells and a second step involving idiotype-anti-idiotype interactions between TsF2 and the Ts3 cell. I-J compatibility is not required with the accessory cell for Ts3 activation. Finally, we hypothesize that the anti-idiotypic determinants expressed on TsF2 can serve as an internal image of antigen, thereby permitting specific targeting of the factor.     

Immunoregulation in the rat: characteristics of a suppressor T cell that inhibits antigen-dependent cell proliferation

We have examined the characteristics of a rat suppressor T cell (Ts) that inhibited the antigen-dependent proliferative response of antigen-primed T cells. The kinetics of in vitro induction of Ts from lymph node T cells obtained from antigen-primed rats indicated that Ts were induced in the presence of the priming antigen within 48 hr of culturing. The Ts produced during the first 48 hr of in vitro cultures were radiosensitive (2000 rad) but became partially radioresistant within the next 48 hr of culturing. In the presence but not the absence of priming antigen, Ts inhibited the antigen-dependent proliferative response to the priming antigen as well as to heterologous antigens. Suppression appeared to be mediated via a nondialyzable suppressor factor (TsF). The induction of Ts in cultures required the presence of OX-6-/OX-8- T cells, antigen-presenting cells, and the antigen. Although a majority of cells recovered from the induced cultures were OX-8+, there was no evidence that OX-8+ antigen expression per se was related to Ts activity. Addition of highly purified IL 2 augmented the Ts-mediated suppression. The immunoregulatory implications of these findings are discussed.     

Characterization of an antigen-specific suppressive factor derived from a cloned suppressor effector T cell line

A cloned effector-type suppressor T cell line, 3D10, which is known to suppress the antibody response against dinitrophenylated keyhole limpet hemocyanin (KLH), produced a soluble KLH-specific factor (TsF) that can replace the function of parental T cell clones. High activity of TsF was released spontaneously into the culture supernatant when cultured in interleukin 2 (IL 2)-containing medium, requiring no antigenic stimulation. The culture supernatant of 3D10 was also capable of inhibiting the KLH-induced proliferative response of primed T cells in an antigen-specific manner. The direct target of TsF was found to be Lyt-1+2- T cells undergoing an early stage of antigen-specific proliferation. TsF was antigen binding but lacked any other serologic markers such as I-J and immunoglobulin heavy chain-linked allotypic determinants on T cells. No genetic restriction was found in its action on allogeneic T cells. The production of IL 2 in proliferative T cells by antigenic stimulation was not inhibited by TsF. These results indicate that the TsF described here is the legitimate mediator produced by the effector-type suppressor T cell that suppresses the antigen-specific responses of Lyt-1+2- T cells. The m.w. of TsF was approximately 75,000.     

Purification and analysis of an antigen-specific suppressor factor from a T cell hybridoma specific for phenyltrimethylamino hapten

The synthetic monovalent antigen L-tyrosine-p-azophenyltri-methylammonium (tyr (TMA)) induces in A/J mice, a cascade of regulatory T cells in the absence of any detectable effector function (e.g., CTL, delayed-type hypersensitivity, etc.). An important component of the activated T cells is a first order suppressor T cell or Ts1 that is Ly-1+2-, functions only at the afferent limb of the anti-TMA response, binds the TMA ligand and bears cross-reactive idiotypes associated with anti-TMA antibodies. This Ts1 produces a suppressor factor (TsF1) that binds the TMA ligand, bears the cross-reactive idiotypes and I-J determinants and functions to induce an idiotype-specific Ts2 population. To study the biochemistry of this TsF, use was made of T cell hybridomas that constitutively produce TMA-TsF1 (8A.1 and 8A.3). The TsF1 was purified from culture supernatant or cell extracts by (NH4)2SO4 precipitation, reverse phase HPLC and either affinity chromatography or by preparative IEF. The TsF1 has an isoelectric point of 6.5 and a m.w. of 26,000 or 62,000 as analyzed by SDS-PAGE or high performance molecular sieve chromatography. Its precipitation in 30 to 40% (NH4)2SO4; elution pattern from reverse phase high performance columns; its capacity to bind to a mAb specific for L-glutamic acid 60L-alanine30-L-tyrosine10 (GAT)-TsF1 strongly suggest that this protein belongs to the same family of proteins as do the GAT-TsF1 described previously. Most noteworthy is that although these TsF1 proteins show remarkable similarities, they are absolutely specific in their biologic activity; TMA-TsF1 will not suppress the response to GAT-BA-TNP and GAT-TsF1 will not suppress the response to TMA-BA-TNP. Thus the TMA-TsF1 represents a second example of a unique group of Ag-specific proteins whose function is to induce or activate other suppressor T cells in the primary immune response to Ag.     

Hapten-specific responses to the phenyltrimethylamino hapten. V. A single chain antigen-binding I-J+ first-order T suppressor factor requires antigen to induce anti-idiotypic second-order suppressor T cells

We have previously shown that a single i.p. injection of the monovalent antigen, L-tyrosine-p-azophenyltrimethylammonium in complete Freund's adjuvant induces a Ly-1+2-, idiotype-bearing, and antigen-binding first-order T suppressor (Ts1) population. We showed that soluble factors extracted from these cells could suppress delayed-type hypersensitivity responses if administered at the induction phase of the response. In this paper we additionally characterize the suppressor factor, TsF1, with respect to its biologic, serologic, and chemical properties. The studies show that the TsF1 is neither allotype nor H-2 restricted and can induce anti-idiotypic T suppressor cells (Ts2), but it requires the presence of antigen to do so. The factor binds antigen, bears I-J encoded determinants, is resistant to reduction and alkylation, and elutes as a single chain factor after adsorption onto monoclonal anti-I-J antibody-coupled Sepharose beads in the presence of dithiothreitol (DTT). This is in marked contrast to TsF2 (derived from Id-specific Ts2-containing spleen cells), which lost its suppressive activity after reduction and alkylation, and behaves as a two chain factor after adsorption and elution from anti-I-J-coupled beads in the presence of DTT. The TsF1 is discussed with respect to the properties of it and those of TsF1 from other similar idiotype-dominated antigen systems.     

In vitro generation of suppressor T cells. Induction of CD3+, IgH-restricted suppressor cells

Previous studies of the immune response of C57BL/6 mice to the 4-hydroxy-3-nitrophenyl acetyl (NP) hapten determined that challenge with antigenic forms of hapten induces both immunity and suppression. The anti-NP plaque-forming cell response can be down regulated by an Ag-induced cascade consisting of three suppressor T cell subsets. These three populations, termed Ts1, Ts2, and Ts3 have been characterized to have inducer, transducer and effector functions, respectively. Although the functions of each of these subsets have been examined in vivo, the cellular requirements for in vitro Ts induction have only been investigated for the Ts3 population. The present study characterizes the cellular events that lead to the induction of the Ts2, suppressor transducer population. Culture of naive C57BL/6 spleen cells with Ts1-derived suppressor factor in the absence of exogenous Ag leads to the generation of Ts2 cells that mediate Ag-specific suppression of NP plaque-forming cell responses. Phenotypic analyses demonstrate that a CD3+, CD4-, CD5+, CD8+, and I-J+ precursor population is stimulated by TsF1 to become mature Ts2 cells that express CD3, CD8, and I-J but not CD5. Although previous studies have reported an essential role for B cells in the induction of other Ts populations, depletion of B cells from Ts2 induction cultures had no effect on Ts2 generation. Despite the absence of B cells in these cultures, the mature Ts2 cells were functionally IgH restricted. Studies with IgH congenic B.C-8 mice suggest that this restriction specificity was imposed by the idiotype-related determinants expressed on the TsF1, not the T cell genotype.     

Production of human suppressor T cell hybridomas

To study human T cell suppression of immunoglobulin (Ig) synthesis with homogeneous populations of immunoregulatory cells, human suppressor T cell hybridomas were prepared by somatic cell fusion of concanavalin A-activated peripheral blood T cells with hypoxanthine-guanine phosphoribosyltransferase-(HGPRT, EC 2.4.2.8) deficient human leukemic CEM T cells. After selection in hypoxanthine-aminopterin-thymidine (HAT) medium and cloning by limiting cell dilution, two human T cell hybridomas were identified that produced 60 to 80% suppression of in vitro polyclonal immunoglobulin production when cocultured with pokeweed mitogen- (PWM) stimulated peripheral blood lymphocytes. Further, one of the suppressor T cell hybridomas constitutively secreted a soluble suppressor factor(s) (TsF) of m.w. 70,000 to 85,000 daltons, which produced reversible noncytotoxic inhibition of lectin-activated B cell Ig production. In contrast, this TsF did not inhibit lectin- or antigen-induced T cell proliferation, nor did it interfere with the generation or effector function of cytotoxic T cells. Additional studies indicated that this Tsf acts directly on B cells or monocytes rather than indirectly modulating the activity of immunoregulatory T cells. In summary, these studies suggest that techniques of somatic cell fusion may provide a valuable approach to further study human immunoregulatory cell-cell interactions as well as provide a source of sufficient quantities of important lymphokines for further purification and characterization.     

Reconstitution of an inactive antigen-specific T cell suppressor factor by incubation of the factor with prostaglandins

Experiments were performed to test the hypothesis that prostaglandins are crucial to the ability of an antigen-specific T cell suppressor factor to deliver a suppressive signal. In the system employed, T suppressor cells release an antigen-specific factor (TsF) that suppresses the ability of effector cells to transfer contact sensitivity (CS) skin swelling responsiveness to adoptive recipients. Culture of TsF-producing cells in the presence of indomethacin caused production of an inactive TsF that could be reconstituted by incubation of this inactive factor with low concentrations of certain prostaglandins such as PGE2 or PGE1. Subsequently, nearly all the prostaglandins were removed by dialysis, and the reconstituted TsF then acted as an antigen-specific suppressor of CS effector cells. Neither the inactive factor nor prostaglandins were suppressive alone. Furthermore, the prostaglandins are crucial to the constitution of TNBSA-F, the non-antigen-binding subunit of the TsF that probably delivers the ultimate suppressive signal. These results provide a new type of antigen-specific role for prostaglandins in immunoregulation and indicate that simple, local, hormonal molecules in physiologic concentrations can have a crucial and long-lasting role in constituting the suppressive activity of antigen-specific regulatory macromolecules released by suppressor T cells.     

The suppressor T cell induced by syngeneic splenic cell antigen down-regulates hapten-specific cytotoxic T cells by elaborating a factor inhibitory for IL2-dependent cell replication

An in vitro study has been made of the mechanism by which a suppressor T cell, that is induced in lymph nodes by a syngeneic splenic cell antigen, prevents generation of cytotoxic T cells specific for hapten-altered self antigens. When popliteal lymph node cells exposed in vivo to syngeneic splenic cells were immunized in vitro with heat-treated syngeneic TNP-coupled thymocytes and excess helper factors, the Ts remained inactive. In this condition the exposed popliteal lymph node cells routinely demonstrated approximately twice the CTL response developed by lymph node cells from normal mice. Nevertheless, when triggered in vitro by splenic antigen on either X-irradiated B or T cells, the exposed but not the normal lymph node cells exhibited reduced hapten-altered self-specific CTL responses. Furthermore, T cells within spleen cell-exposed popliteal lymph node cell populations when reexposed to splenic T cells made a factor that was found to be suppressive of CTL generation by normal lymph node cells in vitro. The nondialyzable T-cell suppressor factor (TsF) did not appear to act on lymph node precursor CTLs, nor on helper T cells but instead acted at the level of utilization of helper factors in the development of CTLs. In an examination of the effect of TsF on cellular replication, TsF was found to be nontoxic for CTLL-20, an IL-2-dependent T cell, and it did not hinder the uptake of IL-2 by receptor blockade of this cell. Nevertheless, the replication of CTLL-20 that is IL-2 driven was diminished in the presence of TsF. Similarly, TsF was found to be inhibitory for T-cell proliferation stimulated by mitogen but had no effect on a B myeloma cell proliferative response. Thus, TsF appears to act as an inhibitor of a T cell's capability to replicate despite the presence of the stimulus for replication, namely, IL-2.     

A monoclonal antibody raised to lipomodulin recognizes T suppressor factors in two independent hapten-specific suppressor networks

Five different Ag-binding suppressor factors from two types of hapten-specific Ts cell hybridomas (TsF1 inducer and TsF3 effector factors) were bound by an anti-lipomodulin mAb (141-B9), that crossreacts with rodent glycosylation inhibition factor (GIF). The Ag-specific suppressor activity in these hybridoma supernatants was bound by anti-lipomodulin columns and could be recovered by elution at acid pH. Additional evidence for the expression of lipomodulin/GIF activity on these TsF molecules was demonstrated by the ability of the eluted fractions to inhibit the glycosylation of IgE-binding peptides during their biosynthesis. The same biologic activity is associated with GIF and lipomodulin. The relationship between TsF and lipomodulin/GIF was confirmed in a serologic assay, which showed that TsF1 and TsF3 molecules, whether purified over Ag, anti-IJ or anti-TsF columns, are recognized by the mAb. 141-B9. The combined results indicate that Ag-binding Ts factors share a common antigenic determinant with phospholipase inhibitory proteins such as lipomodulin and GIF. In addition, the demonstration of glycosylation regulatory activity carried on these TsF molecules suggests a possible mode for their bioactivity.     

Insulin-specific suppressor T cell factors

Murine antibody responses to heterologous insulins are controlled by MHC-linked immune response genes. Although nonresponder mice fail to make antibody when injected with nonimmunogenic variants of insulin, we have recently shown that nonimmunogenic variants stimulate radioresistant, Lyt- 1+2- helper T cells that support secondary antibody responses. However, the helper activity can not be detected unless dominant, radiosensitive Lyt-1-2+, I-J+ suppressor T cells are removed. In this paper we report that extracts of primed Lyt-2+ suppressor T cells contain insulin-specific suppressor factors (TsF) that are capable of replacing the activity of suppressor T cells in vitro. The activity of these factors is restricted by MHC-linked genes that map to the I-J region, and immunoadsorption studies indicated that they bind antigen and bear I-J-encoded determinants. Insulin-specific TsF consists of at least two chains, one-bearing I-J and the other the antigen-binding site. Furthermore, mixing of isolated chains from different strains of mice indicates that the antigenic specificity is determined by the antigen-binding chain and the MHC restriction by the H-2 haplotype of the source of the non-antigen-binding, I-J+ chain. Moreover, mixtures containing antigen-binding chain from allogeneic cell donors and I-J+ chain from responder cell donors have activity in cultures containing responder lymphocytes. This suggests that preferential activation of suppressor T cells, rather than differential sensitivity to suppression, results in the nonresponder phenotype to insulin.     

The immune response and the eye. I. The effects of monoclonal antibodies to T suppressor factors in anterior chamber-associated immune deviation (ACAID)

We report the effects of two monoclonal antibodies (mab) specific for murine T suppressor (Ts) factors (TsF) in anterior chamber (AC)-associated immune deviation (ACAID), as induced by AC inoculation of TNP-coupled syngeneic spleen cells (TNP-Spl). One mab (14-12) is specific for Ts effector factor and can block the induction of Ts cells in ACAID if given before or after AC injection of TNP-Spl. The other mab (14-30) is specific for Ts inducer factors and blocks suppression only after given after TNP-Spl. We also studied the surface phenotype of the Ts cells induced by AC injection of TNP-Spl. We show that at least two cells are required for the adoptive transfer of suppression in TNP-ACAID. One is Lyt-2+ and 14-12+, the other is I-J+. These Ts cells have the surface phenotype of Ts effector cells as seen in other systems. These results indicate that mab which bind TsF in other systems affect Ts cells in TNP-ACAID, and that the Ts cells induced in TNP-ACAID are only of the Ts effector type.     

Induction of T cell responses in nonresponder mice by abolishing suppression with monoclonal antibodies recognizing A region-controlled, T cell-specific determinants

Mouse strains carrying the kappa allele at loci A beta, A alpha, E beta, and E alpha are nonresponders to lactate dehydrogenase B (LDHB) and to allotypic determinants of IgG2a myeloma proteins (for example, UPC10 used in this study). The nonresponsiveness to these antigens is caused by T suppressor (Ts) cells that prevent antigen-primed T helper (Th) cells from proliferating. We demonstrate here that monoclonal antibodies specific for an A region-controlled molecule selectively expressed on T cells (A-T) are capable of inducing anti-LDHB and anti-UPC10 responses of primed T cells from nonresponder strains. A monoclonal anti-J antibody that cross-reacts with the A-T molecule also induces responsiveness, whereas another J-specific antibody that lacks this cross-reactivity fails to do so. The mechanism of response induction is blocking of the interaction between the Ts cell or its factor (TsF) and the target of suppression, the antigen-specific Lyt-1+2- (Th) cell. The blocking occurs at the level of the Ts cell and the TsF. The data indicate that Ts cells and TsF carry a unique, A region-controlled molecule that is not only functionally analogous but also serologically similar to the J molecule.