Suppressor T cell circuits in contact sensitivity. II. Induction and characterization of an efferent-acting, antigen-specific, H-2-restricted, monoclonal T cell hybrid-derived suppressor factor specific for DNFB contact hypersensitivity

This report defines a methodology for the production and characterization of an antigen-specific, monoclonal T cell hybrid-derived suppressor T cell factor (TsF) that suppresses the passive transfer of 2,4-dinitrofluorobenzene (DNFB) contact hypersensitivity. Fusion of T cells from BALB/c (H-2d) mice tolerized with syngeneic DNP-spleen cells to BW 5147 thymoma cells resulted in several hybrids that constitutively produce a soluble regulatory molecule. One of these hybrids, 26.10.2, was subsequently cloned, and its soluble factor was characterized with respect to its antigen specificity, biochemical nature, MHC restriction pattern, and identity of its target cell. 26.10.2 TsF suppresses the passive transfer of delayed-type hypersensitivity (DTH) mediated by DNP- but not trinitrochlorobenzene- or oxazalone-primed DTH T cells (TDH) after a 1 hr incubation at 37 degrees C. In contrast, 26.10.2 TsF had no suppressive effect on secondary in vitro DNP-specific T cell proliferative responses. 26.10.2 TsF therefore represents an antigen-specific factor with effector (efferent-acting) function. The monoclonal TsF was shown to consist of a two-chain, disulfide-bonded molecule, and to bear a receptor(s) specific for DNP and determinants encoded by the I region of the H-2 complex. Effector suppressive activity of 26.10.2 TsF was restricted by Class I H-2Dd determinants. One cellular target of this monoclonal factor was shown to be the DNP-specific TDH cell, because DNFB-primed lymph node cells from cyclophosphamide-pretreated donors (lacking Ts-auxiliary (Ts-aux) cells) were efficiently suppressed. The TsF appears to focus on passively bound, TDH receptor-associated, DNP-Class I determinants, as suggested by the observation that freshly prepared, but not overnight cultured, DNP-specific TDH cells were susceptible to suppression.     

Antigen-specific human T cell factors. II. T cell suppressor factor: biologic properties

The in vitro induction of an ovalbumin-specific human T cell suppressor factor is described (TsF120-OA). The antigen-specific suppressive component can be purified by affinity chromatography from supernatants derived from Marbrook-Diener type cultures of peripheral blood T cells stimulated with a high dose of ovalbumin. TsF120-OA suppresses the antigen-induced PFC formation of human blood B cells in vitro in an antigen-specific way. The target of TsF120-OA activity is shown to be the T helper cell. No genetic restriction in the action of the factor is observed.     

Ultraviolet-induced suppressor T cells and factor(s) in murine contact photosensitivity. I. Biological and immunochemical characterization of factor(s) extracted from suppressor T cells

Murine contact photosensitivity (CPS) to 3,3',4',5-tetrachlorosalicylanilide (TCSA) is a highly specific, T-cell-mediated delayed-type hypersensitivity (DTH). Preexposure of the photosensitizing site to low doses of ultraviolet B(UVB) rendered mice unresponsive to challenge reaction. This unresponsiveness was associated with the generation of antigen-specific, afferent limb-acting, Lyt-1+2-,L3T4+ suppressor T cells (Ts-cps) in the spleen, thymus, and lymph node. Cell-free extract(s) obtained by freezing and thawing of these cells contained T-cell-suppressor factor (TsF) that inhibited the development of the induction phase of the CPS response to TCSA in vivo in an antigen-specific fashion. The treatments of TsF both with immunoadsorbent columns and with reduction and alkylation showed that the factor bore photoantigen-binding site(s), was reactive with monoclonal anti-I-Jd, anti-I-E alpha but not anti-I-Ad, and behaved as a single-chain factor containing both photoantigen binding and I-J molecules. By gel chromatography the majority of the suppressive activity was eluted in the fractions corresponding to molecular weights of 60-80 and 100-200 kDa. Our present study demonstrated clearly that UVB-induced unresponsiveness in the DTH reaction was mediated by a soluble suppressive factor derived from T cells.     

Antigen-specific T cell-mediated suppression. II. In vitro induction by I-J-coded L-glutamic acid50-L-tyrosine50 (GT)-specific T cell suppressor factor (GT-T8F) of suppressor T cells (T82) bearing distinct I-J determinants.

The induction of new suppressor T cells (Ts2) by suppressive extracts (TsF) from L-glutamic acid50L-tyrosine50 (GT) nonresponder mice was examined. Incubation of normal spleen cells with allogeneic GT-TsF for 2 days in vitro led to the generation of Ts2 cells able to suppress subsequent responses to the immunogen GT-methylated bovine serum albumin (GT-MBSA) in vivo. This induction occurred efficiently when TsF donor and target cells differed at all of H-2, including the I-J subregion. B10.BR (H-2k) GT-TsF, adsorbed on, then acid eluted from GT-Sepharose and anti-I-Jk [B10.A (3R) anti-B10.A (5R)]-Sepharose in a sequential fashion could induce BALB/c (H-2d) spleen cells to become Ts2 only if nanogram quantities of GT were added to the purified GT-TsF. This indicates a requirement for a molecule or molecular complex possessing both I-J determinants and antigen (GT)-binding specificity, together with GT itself, for Ts2 induction. The induced Ts2 are I-J+, since their function can be eliminated by treatment with anti-I-Jk plus C. These I-J determinants are coded for by the precursor of the Ts2 and do not represent passively adsorbed, I-J coded TsF, since anti-Ijk antiserum [(3R X DBA/2)F1 anti-5R] which cannot recognize the BALB/c (I-Jd) TsF used for induction still eliminates the activity of induced A/J (I-Jk) Ts2. These data provide further evidence for and information about the minimum of two T cells involved in antigen-specific suppressor T cell systems.     

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.     

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.     

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

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

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.     

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.     

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.     

Accessory cells in immune suppression. III. Evidence for two distinct accessory cell-dependent mechanisms of T lymphocyte-mediated suppression

Suppression of antibody secretion by the 2,4,6-trinitrophenol (TNP)-binding BALB/c myeloma, MOPC 315, by idiotype- and hapten-reactive suppressor T cells is mediated by secreted factors (TsF) and requires the presence of accessory cells (AC). Idiotype-specific TsF functions only in the presence of Ia+ AC and is completely idiotype specific. Moreover, no suppression is observed when myeloma targets and AC are separated by cell-impermeable membranes, indicating that the role of AC may be to bind, focus, and/or present TsF to the myeloma cells. In contrast, TNP-specific TsF inhibits myeloma function in the presence of TNP-protein and activated macrophages that are not Ia+. This form of suppression is nonspecific at the effector stage; i.e., anti-TNP TsF inhibits a non-TNP binding cell line, TEPC 15, as long as TNP-protein and activated macrophages are present. Moreover, suppression occurs even when myeloma targets and AC are separated by cell-impermeable membranes. These results are consistent with the view that hapten-reactive TsF binds to antigen on the surface of macrophages and induces these cells to secrete nonspecific immunosuppressive molecules. Thus, different types of AC may play fundamentally different roles in TsF-mediated suppression; they may either bind and present TsF to targets (as in the case of idiotype-specific TsF) or secrete nonspecific immunosuppressants as a consequence of a TsF-antigen interaction (hapten-specific TsF). Autonomous, suppressible targets provide valuable experimental systems for analyzing the cellular interactions in T cell-mediated suppression.     

Antigen-specific suppressor T cell interactions. I. Induction of an MHC-restricted suppressor factor specific for L-glutamic acid50-L-tyrosine50

The synthetic polymers L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT) and L-glutamic acid50-L-tyrosine50 (GT) stimulate specific suppressor T cells in certain strains of mice. Extracts from these T cells contain factors (TsF) that inhibit GAT- or GT-specific antibody responses by normal spleen cells or proliferative responses by primed T cells. We constructed T cell hybridomas that constitutively produce GAT-TsF or GT-TsF, which functionally and serologically are identical to factors extracted from suppressor T cells. In this report we demonstrate that monoclonal GT-TsF can induce specific unresponsiveness in vivo or in vitro and that this unresponsiveness is due to development of second-order antigen-specific suppressor T cells. T cell hybridomas were constructed by fusion of BW5147 with GT-TsF1 induced second-order suppressor T cells and clones that produced suppressor factor (GT-TsF2) were isolated and characterized. GT-TsF2 differs from the GT-TsF1 used to induce it in that GT-TsF1 acts across allogeneic barriers whereas GT-TsF2 does not. This restriction is controlled by genes in the H-2 gene complex and maps to the I-J subregion. GT-TsF2 is antigen-specific in suppressive activity and also in its antigen-binding site(s). Thus, GT-TsF2 closely resembles the carrier-specific, I-J+, genetically restricted factor described by Tada and his colleagues. Because GT-TsF2 was induced by GT-TsF1, we suggest cells producing GT-TsF1 are an early cell in the pathway of suppression, and that this cell is required for the activation of antigen-specific, MHC-restricted TsF.     

Cellular interactions of L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT)-specific suppressor factors. I. Inhibition of the activity of GAT-specific helper T cell clones by monoclonal GAT-specific suppressor T cell factors

Considerable information concerning the serology and biochemistry of antigen-specific, T cell-derived suppressor factors has been obtained with the use of T cell hybridomas as a source of homogeneous material. Similarly, knowledge of helper T cell products and receptors is accumulating from studies of helper T cell clones and hybridomas. Our strategy for studying the mechanisms by which suppressor factors inhibit responses was to determine whether monoclonal suppressor factors could inhibit antibody responses specific for L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT) in cultures containing unprimed splenic B cells, macrophages, and GAT-specific T cell clones as a source of helper activity. The MHC-restricted, two chain suppressor factors, GAT-TsF2, inhibited these responses if the helper T cell clones and suppressor factor were derived from H-2-compatible mice. Furthermore, responses were inhibited by briefly pulsing T cell clones with GAT-TsF2 in the presence of GAT, indicating that suppressor factors need not be present continuously. In addition, helper T cell clones adsorbed syngeneic, but not allogeneic, GAT-TsF2 in the presence of GAT. Adsorption also requires a shared antigenic specificity between the H-2b-derived helper T cells and TsF2 factor. Thus, helper T cells can serve as the cellular target of antigen-specific, MHC-restricted GAT-TsF2, and cloned helper T cells can be used as a homogeneous target population for analysis of the molecular mechanisms of T cell suppression.     

Downregulation of helper T cells by an antigen-specific monoclonal Ts factor.

The findings of previous studies in this laboratory demonstrating that conjugates of human monoclonal (myeloma) IgG (HIgG) and monomethoxypolyethylene glycol (mPEG) were able to induce in mice antigen-specific tolerance and CD8+ suppressor T (Ts) cells were confirmed in the present study. An extract (TsF) of a nonhybridized clone of Ts cells (viz., clone 23.32), which had been derived from spleen cells of mice tolerized with HIgG(mPEG)26, was shown to possess antigen-specific suppressive activity. This monoclonal TsF was able to specifically suppress in vitro antibody formation only if it was present from the beginning of the culture. From the results of the cellular dissection of the system used it was concluded that (i) the TsF had no effect on fully differentiated primed B cells or plasma cells, and (ii) the TsF inactivated carrier-primed Th cells when the culture contained concomitantly naive CD8+ T cells, accessory cells, and antigen. These data support the view that the monoclonal TsF exerted its downregulating effect on Th cells only if it could first interact with a CD8+ T cell, in the presence of accessory cells and antigen.     

A novel suppressive activity: complementation between a T cell induced with first-order T-suppressor factor and an I-J-restricted antigen-nonspecific T cell

Previous studies demonstrated that the first-order T-suppressor factor (TsF1) requires the presence of antigen to induce idiotype-specific Ts cells which readily suppress phenyltrimethylamino (TMA) hapten-specific delayed-type hypersensitivity (DTH) responses when transferred into already immune recipients. In this study we show that TsF1 in the absence of antigen induces a splenic population which limits DTH in recipient mice only when an additional accessory lymphoid population was also cotransferred. Neither of these populations alone was sufficient to mediate suppression and depletion of T cells in either population's abrogated suppression, indicating the T-cell dependency of the complementing cell types. Moreover, suppression was seen only when TMA-TsF1-induced and not normal spleen cell lysate-induced cells were cotransferred with the antigen-induced population, suggesting the requirement for a specific signal to induce the factor-induced population. Further experiments showed that the antigen-induced lymphoid population could be replaced by either heterologous antigen-induced or adjuvant alone-induced splenic populations, indicating the lack of specificity of this secondary population. Further analysis showed that the cell complementation between TMA-TsF1-induced and the nonspecific accessory lymphoid population resulted in antigen-specific and genetically restricted immune suppression. The TsF1-induced lymphoid population was not responsible for the genetic restriction, and furthermore, there was no restriction observed between the two complementing populations. However, matching of the nonspecific accessory cell with the recipient host at the I-J subregion of the H-2 complex was essential for immune suppression. Finally, the activity of complementing cells was found to be independent of cyclophosphamide-sensitive Ts populations of the recipient mice. The ramifications of these findings with reference to the existing suppressor pathways are discussed.     

Carrier-specific suppression of antibody responses by antigen-specific glycosylation-inhibiting factors

We previously established an ovalbumin (OA)-specific T cell clone from spleen cells of BDF1 mice, which had been treated by i.v. injections of OA, and constructed antigen-specific T cell hybridomas from the T cell clone. One of the hybridomas constitutively released glycosylation-inhibiting factor (GIF) which lacked affinity for OA, and was called non-specific GIF. Incubation of the same hybridoma cells with OA-pulsed syngeneic macrophages or OA-pulsed B lymphoblastoid cells of BALB/c origin resulted in the formation of GIF molecules that had affinity for OA but not for bovine serum albumin or keyhole limpet hemocyanin. Both the OA-specific GIF and nonspecific GIF bound to monoclonal anti-lipocortin and possessed I-Jb determinants. The OA-specific GIF consisted of two species of molecules, of m.w. 80,000 and 30,000 to 40,000, respectively, whereas the nonspecific GIF from unstimulated cells had an m.w. of 15,000. Intravenous injections of OA-specific GIF or nonspecific GIF into BDF1 mice suppressed both the IgE and IgG1 anti-hapten antibody responses of the animals to dinitrophenyl derivatives of OA (DNP-OA), but OA-specific GIF was much more effective than nonspecific GIF in suppressing the antibody responses. When the same preparations of GIF were injected into DNP-KHL-primed mice, OA-specific GIF and nonspecific GIF were comparable in suppressing the anti-DNP antibody response. In contrast to the 40,000 m.w. species of OA-specific GIF, the 80,000 m.w. OA-specific GIF had carrier-specific suppressive effects. The similarities of antigen-specific GIF to antigen-specific TsF suggest that the phospholipase-inhibiting activity of the molecules may be involved in the immunosuppressive effects of some antigen-specific TsF.     

Soluble factors in tolerance and contact sensitivity to DNFB in mice. VII. Characterization of a monoclonal, efferent-acting suppressor factor with specificity for DNP/H-2Kd

To study further soluble factors which regulate contact sensitivity (CS) to 2,4-dinitrofluorobenzene (DNFB), hapten-primed spleen cells from BALB/c mice were used to make T-cell hybridomas. A hybrid constitutively producing a suppressor factor was identified and cloned (clone 3-10). Incubation of BALB/c DNFB immune lymph node cells (LNC) in the 3-10 supernatant suppressed the ability of the immune cells to transfer CS to DNFB. The passive transfer of CS to oxazalone or to 2,4,6-trinitrochlorobenzene (TNCB) was not suppressed by the 3-10 factor. The hapten specificity of the 3-10 factor further was demonstrated by the ability of DNFB immune LNC but not LNC from unsensitized or from TNCB-sensitized mice to absorb the factor. The 3-10 factor also was adsorbed by DNFB-immune LNC from mice that were syngeneic with BALB/c mice at the K locus of the MHC (e.g., B10.D2 and D2.GD). Pretreatment of DNFB-immune LNC with monoclonal anti-Kd antibody or with anti-DNP antibodies blocked the ability to adsorb the factor. These results indicated that the 3-10 suppressor factor binds to DNP/H-2Kd complexes on immune LNC. Nylon wool-purified T cells (83% Thy-1.2+) from DNFB-immune LNC were able to adsorb the factor as well as unseparated immune LNC. Furthermore, treatment of immune LNC with anti-Thy-1.2 plus C' abrogated the ability of the cells to adsorb the factor, indicating that the cellular target of the 3-10 factor is a T cell. In addition, treatment of the immune LNC with an autoantiidiotypic antiserum (CS 231) plus C', which depletes DNP-specific delayed-type hypersensitivity effector T (TDH) cells, also abrogated the ability of the cells to adsorb the factor. Finally, the suppressor factor was adsorbed and eluted from DNP affinity columns but was not adsorbed by TNP affinity columns. Collectively, these results indicate that although the monoclonal 3-10 suppressor factor has affinity for DNP, focusing of the factor on the TDH cells requires recognition of DNP in the context of the appropriate MHC determinant, Kd.     

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.     

Cloned suppressor T cells derived from mice tolerized with conjugates of antigen and monomethoxypolyethylene glycol. Relationship between monoclonal T suppressor factor and the T cell receptor

Cloned Ts cells specific for the Ag, human monoclonal (myeloma) IgG, were derived from spleen cells of mice that had been immunosuppressed by treatment with a tolerogenic conjugate of HIgG and monomethoxypolyethylene glycol. The cloned Ts cells (clone 23.32) suppressed in vitro antibody responses in an Ag-specific and MHC-restricted manner. By FMF with appropriate antibody reagents, these cells were shown to be Thy-1+, CD4-, CD5-, and CD8+ and to express CD3 and the alpha beta-TCR. These results are consistent with the view that Ts cells use Ag recognition structures similar to those reported for Th cells and CTL. A soluble factor (TsF) extracted from the cloned Ts cells also suppressed in vitro antibody responses in an Ag-specific and H-2Kd-restricted manner, i.e., restricted to MHC class I molecules. The suppressive activity of this TsF could be abrogated by addition of mAb H28-710 that reacts with a determinant on the alpha-chain of TCR. Moreover, the TsF bound to and could be recovered from an immunosorbent consisting of the anti-alpha-TCR mAb H28-710 coupled to Sepharose 4B. In contrast, the TsF was not bound by immunosorbents consisting of mAb to the beta-chain of TCR (H57-597) or to V beta 8 (F23.1). It was, therefore, concluded that the TsF of clone 23.32 is serologically related to the alpha-chain of the TCR; however, it is not identical to TCR, because it lacks the determinants expressed on the TCR beta-chain that are recognized by the two anti-beta mAbs used in this study.