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.     

Soluble factors in tolerance and contact sensitivity to DNFB in mice. VIII. Regulation of T suppressor cell function by autoreactive T helper cells

When cultured with DNP-labeled I-A+ cells, Lyt 2+ T suppressor cells (Ts) from 2,4,-dinitrobenzene sulfonate (DNBS)-tolerized mice are activated to synthesize and release a suppressor factor (SSF) which suppresses the transfer of contact sensitivity to DNFB. The signals required to activate the DNBS-primed Ts to produce SSF were studied in greater detail. As previously observed with fixed DNP-labeled spleen cell stimulators, the supernatants from cultures of DNBS-primed spleen cells and glutaraldehyde-fixed DNP-labeled P388D1 cell monolayers did not contain SSF. When the tolerant cells were harvested from these monolayers and were treated with IL-1, the Ts released the synthesized SSF. Synthesis and release of SSF required Ts recognition of DNP/class I MHC on the hapten-presenting cells followed by interaction with the costimulator IL-1. When the tolerant cells were cultured with fixed DNP-labeled I-A+ or I-A- stimulators to induce SSF synthesis, release was induced by adding either unlabeled or TNP-labeled unprimed spleen cells to the cultures. The release of SSF was blocked when the second stimulators were pretreated with anti-I-A antibody but not with anti-DNP or anti-class I MHC antibodies. These results indicate that the release of SSF by DNBS-primed Lyt 2+ Ts is regulated by the activity of a self-I-A-reactive (i.e., autoreactive) T cell in the tolerant spleen cell population.     

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.     

Induction of suppressor cells by a tumor-derived suppressor factor

Murine fibrosarcomas produce a factor that activates suppressor cells to inhibit expression of delayed-type hypersensitivity (DTH) responses to dinitrochlorobenzene (DNCB). This tumor-derived suppressor factor (TDSF) was partially purified by preparative isoelectric focusing of spent medium and 3 M KCl extracts of cultured methylcholanthrene-induced and spontaneous fibrosarcomas of C3H/He mice. Incubation of 1 micrograms/ml of a fraction, isoelectric pH less than 2.9, with normal syngeneic spleen cells for 1-6 hr at 37 degrees C induced suppressor cells that inhibited the primary DTH response to DNCB upon intraperitoneal transfer to normal C3H/HeJ mice. TDSF was not present in extracts of either syngeneic embryonic fibroblasts or normal spleen cells or in medium conditioned by normal peritoneal exudate cells but was present in 3 M KCl extracts of and the spent medium from four different cultured murine fibrosarcomas. TDSF activity was not restricted at the major histocompatibility complex. The suppressor cells inhibited the efferent limb of the DTH response because (1) hyporesponsive recipients of TDSF-treated spleen cells had splenic effector T cells capable of transferring DTH to DNCB into naive secondary recipients and (2) the ability of Lyt 1+,2- effector Tdth cells to transfer a secondary DTH response to DNCB was inhibited by co-incubation with macrophages or Lyt 1-,2+ T cells treated with TDSF. Preliminary biochemical analysis suggested that TDSF was an RNA- protein complex. Thus, several murine fibrosarcomas produced a soluble factor that activated splenic suppressor cells to depress the immune response to nonneoplastic antigens. These suppressor factors represent a novel group of regulatory molecules which may be ribonucleoprotein complexes.     

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

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

Mechanism of action of a T suppressor factor (TsF) in contact sensitivity: the T cell target for TsF activity in adoptive transfer of immunity is not effector cell

The passive transfer of contact sensitivity (CS) by immune cells into normal animals requires the interaction of two distinct Ly-1+ T cells, one which is Vicia villosa lectin (VV)-nonadherent, the other which adheres to VV. Functional deletion of either cell type abrogates the adoptive transfer of CS into normal animals, whereas VV-nonadherent cells alone can transfer CS into animals pretreated with cyclophosphamide (Cy). An antigen-specific T suppressor factor, designated TNP-TsF, inhibits the transfer of CS into normal adoptive recipients. TNP-TsF mediates its suppressive activity by inducing an I-J+ subfactor (designated I-J2) from the assay population by the interaction of PC1-F (a TNP-binding subfactor of TNP-TsF) with antigen-primed Ly-2+ T cells. This I-J+ subfactor then complements TNBS-F (an antigen-nonbinding subfactor of TNP-TsF) to form an antigen-nonspecific effector molecule which suppresses DTH responses in an antigen-nonspecific fashion. We report here that TNP-TsF suppresses the adoptive transfer of CS into normal animals but not into animals pretreated with Cy. TNBS-F + I-J2, the effector complex of TNP-TsF, also suppresses the transfer of CS into normal but not Cy-treated animals. When the Ly-1 immune cells were separated into VV-adherent and -nonadherent populations, the TNBS-F + I-J2 suppressor complex suppressed the functional activity of the VV-adherent cell population, but not the VV-nonadherent cells. This suppressive activity correlates with the need for VV-adherent cells in the transfer of CS into normal but not Cy-treated recipients. When an I-J+ molecule (I-J1) from an SRBC-specific TsF was used in place of I-J2 to form a suppressor complex with TNBS-F, this TNBS-F + I-J1 TsF suppressed the transfer of CS into both normal and Cy-treated recipients. This difference in functional suppressive activity correlated with a difference in target cell specificity: TNBS-F + I-J1 suppressed the VV-nonadherent TDTH cell, whereas TNBS-F + I-J2 suppressed the VV-adherent T cell of CS. Immune cells which are transferred under conditions which do not require the VV-adherent cell for transfer are not suppressed by TNBS-F + I-J2 or TNP-TsF, but are suppressed by the TNBS-F + I-J1.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characteristics of the splenic suppressor cell--target cell interaction in experimental African trypanosomiasis

We have examined further the relationship between immunosuppression and suppressor cell activity in experimental African trypanosomiasis. In the present study we describe the nature of the interaction between splenic suppressor macrophages from Trypanosoma rhodesiense-infected C57BL/6 mice and target effector cells in the primary in vitro PFC response to SRBC. Suppressor cell potential was expressed only when cell-cell contact of a noncytolytic nature was established between infected spleen cells and normal splenic responder cells. Isolation of suppressor cells from responder cells by a cell-impermeable membrane completely abrogated suppression. Similarly, supernatant fluids from infected spleen cell cultures could not passively transfer suppression. Suppressor cells did not act via prostaglandin synthesis in that indomethacin failed to restore responsiveness to infected spleen cells or to passively suppressed normal cultures. Inhibition of DNA synthesis by irradiation of mitomycin C treatment did not block suppressor cell function, but suppressor cell effects were inhibited by exposure of infected spleen cells to silica particles or to heat treatment. We conclude that suppressor cell effects in experimental African trypanosomiasis are consistent with a suppressor macrophage acting via a noncytolytic cell-cell interaction with responder target cells.     

Soluble factors in tolerance and contact sensitivity to DNFB in mice. X. IL-2 is the activation signal mediating release of synthesized suppressor factor

Two signals are required for the in vitro activation of Lyt2+ T suppressor cells (Ts) from mice tolerized with 2,4-dinitrobenzene sulfonate (DNBS) to produce soluble suppressor factors (SSF) which suppress the transfer of contact sensitivity to dinitrofluorobenzene (DNFB). Recognition of DNP/class I MHC (signal one) stimulates the Ts to synthesize SSF. Release of SSF requires a soluble mediator (signal two) produced by the interaction of L3T4+ T cells from tolerant mice with I-A on metabolically functional cells in the DNP-presenting cell population. The purpose of this study was to examine the nature of this second Ts activation signal. Coculture of tolerant spleen cells and glutaraldehyde-fixed (Glu-) DNP-labeled spleen cells (DNP-SC) resulted in the synthesis but not release of SSF. Addition of either IL-1 or IL-2 to these cultures induced SSF release. Treatment of such cultured cells with the anti-murine IL-2 receptor antibody PC 61.5.3 blocked the IL-2- and IL-1-stimulated release of SSF. Release of SSF was also blocked when tolerant cells were cultured with (unfixed) DNP-SC in the presence of a monoclonal anti-IL-2 antibody. IL-2 but not IL-1 was able to stimulate the Ts to release synthesized SSF in the absence of L3T4+ TH activity. First, addition of IL-2 to cocultures of tolerant cells and DNP-presenting I-A- cells induced release of the synthesized SSF, whereas addition of IL-1 did not. Second, IL-2 also stimulated SSF release in cocultures of L3T4+ T cell-depleted tolerant cells and Glu-DNP-SC, whereas IL-1 did not. Tolerant cells pretreated with IL-2 and then washed were able to synthesize and release SSF upon culture with Glu-DNP-SC. Pretreatment of tolerant cells with IL-1 did not stimulate SSF release upon subsequent culture with Glu-DNP-SC. These results indicate that the Lyt2+ Ts from DNBS-tolerant mice express IL-2 receptors and IL-2 is the lymphokine which induces the Ts to release synthesized SSF. Thus, IL-2 provides a differentiative signal during the functional activation of these regulatory T cells.     

Trypanosoma cruzi-induced suppressor substance III. Activation of suppressor cells

Serum from mice infected with Trypanosoma cruzi (SSS) is known to interact with normal spleen cells to induce an immunosuppressed condition and activate splenic suppressor cells. The induction of immunosuppression by SSS was shown to be independent of, and precede the activation of, suppressor cells. Suppressor-cell activation, however, was demonstrable only after the induction of immunosuppression. Furthermore, mice that were given two aliquots of SSS at different intervals of time, exhibited suppression of humoral responses of similar duration and magnitude, regardless of the SSS transfer regimen, whereas both the length and degree of suppressor-cell activity was critically dependent on the interval of time between SSS transfers. SSS interacted with spleen cells via a trypsin-sensitive membrane site which was regenerable within a 4- to 5-hr period, yet the suppressive effects of SSS on spleen cells following interaction was resistant to treatment with trypsin. The interaction between SSS and spleen cells during brief adsorption protocols leads to immunosuppression only because extensive washing of SSS-treated spleen cells did not reverse the immunosuppression process, but did prevent the development of detectable suppressor cells. The phenomenon of suppressor-cell activation was further distinguished from immunosuppression in that supernates from culture of spleen cells derived from SSS-treated mice or T. cruzi-infected contained a factor that activated suppressor cells, but did not directly induce a state of suppression in the responding cell population.     

Soluble factors in tolerance and contact sensitivity to DNFB in mice. VI. Cellular and lymphokine requirements for stimulating suppressor factor production in vitro

Coculture of spleen cells from mice tolerized with 2,4-dinitrobenzenesulfonate (DNBS) and DNP-labeled spleen cells (DNP-SC) activates Lyt-2+ T suppressor cells (Ts) to synthesize and release a suppressor factor (SSF) into the supernatant, which suppresses the transfer of contact sensitivity to DNFB. The purpose of the present study was to examine in greater detail the signals required to activate DNBS-primed Ts to produce SSF. The supernatant from cultures of tolerant cells and glutaraldehyde-fixed DNP-SC did not have SSF. In contrast, the soluble cell lysate from these cultures did contain the suppressive activity. Pretreatment of glutaraldehyde-fixed DNP-SC with either anti-DNP or anti-class I, but not anti-class II MHC, antibodies blocked SSF synthesis. The addition of IL 1 to cultures of DNBS-tolerant cells and glutaraldehyde fixed DNP-SC restored the ability of the Ts to release the synthesized factor. These results indicate that Ts recognition of the hapten/class I MHC determinant stimulates the synthesis of SSF, and a costimulator is required to induce the release of the factor. The supernatants from cultures of either L3T4-depleted tolerant cells and DNP-SC or tolerant cells and anti-I-A antibody-treated DNP-SC had no SSF activity. The addition of a costimulator (IL 1) also restored the ability of the Ts to release the synthesized factor in cultures of L3T4-depleted tolerant cells and DNP-SC. These results suggest that an L3T4 cell in the DNBS-primed cell population interacts with I-A determinants on a cell in the DNP-stimulator population to initiate the generation of the mediator required for SSF release. This further suggests that the Ts is unable to induce the costimulator from the hapten-presenting cell during interaction with the DNP/class I MHC ligand. Therefore, the production of SSF is regulated not only by the presentation of the appropriate hapten/MHC determinant but also by the interactions of cells that function in generating the costimulator needed to induce release of the suppressor factor.     

Contact sensitivity to picryl chloride: the occurrence of B suppressor cells in the lymph nodes and spleen of immunized mice.

Mice were immunized for contact sensitivity and antibody production by painting the skin with picryl chloride. Lymph node and spleen cells taken 4 days later transferred contact sensitivity. However, cells taken at 7–8 days failed to transfer but were able to block the transfer by 4 day immune cells. These suppressor cells occurred in the regional lymph nodes, spleen and thymus. The suppressor activity of lymph node and spleen cells was due to B cells as shown by the effect of anti-θ serum and complement, nylon wool filtration and separation of EAC positive and negative cells by centrifugation on a discontinuous gradient. The transfer of fractions rich or poor in macrophages showed that the suppressor cell in the transferred population was not a macrophage. Separation using EAC rosettes suggested that B cells were responsible for the suppressor activity in the thymus.T cells isolated from the lymph nodes and spleen 7–8 days after immunization transferred contact sensitivity although the initial population was inactive. This indicates that passive transfer cells are present in the regional lymph nodes and spleen at later times after immunization but cannot be demonstrated because of the presence of suppressor B cells. However, no passive transfer cells were found in the thymus. The production of B suppressor cells required little or no T cell help and following immunization the spleens of reconstituted (B) mice were at least as active as control cells in causing suppression. There are several different suppressor cells which act in the picryl system and the B suppressor cells in immunized mice described here are distinct from the T suppressor cells in mice injected with picryl sulphonic acid.     

Oral administration of the contact sensitizer trinitrochlorobenzene: initial sensitization and subsequent appearance of a suppressor population

Our earlier studies have demonstrated that intragastric administration of the hapten trinitrochlorobenzene (TNCB) 2 to 3 weeks prior to attempting sensitization with epidermally applied hapten can abrogate development of systemic contact sensitivity (CS). In this paper, we have examined whether onset of tolerance following intragastric administration of the hapten is preceded by development of hapten-specific CS. Indeed, CS was found to be present 5 days after feeding TNCB and in most experiments the response decreased significantly by Days 10 to 12. The kinetics of development of CS by the oral and epidermal routes were strikingly similar except that the magnitude of reactivity (up to 5 days) in orally sensitized mice was somewhat less than that of epidermally sensitized mice. With the exception of Peyer's patches (PP), effector cells of CS were recovered from such gut-associated lymphoid tissues as mesenteric lymph nodes (MLN), lamina propria, and lymphocytes that are present in the intraepithelial compartment of the intestinal wall. These cells as well as spleen cells of TNCB-fed mice were able to adoptively transfer CS to naive mice. The capacity of MLN and spleen cells of TNCB-fed mice to confer CS adoptively was abrogated after treating cells with anti-Thy 1.2 and anti-Lyt 1.1 antibodies plus complement thereby identifying them as T lymphocytes. Although CS decreased by 10-12 days after feeding TNCB, the decline was reversed by pretreating mice with cyclophosphamide (CY) 2 days before giving the hapten. Whereas spleen cells from animals fed hapten 5 days earlier transferred CS readily, those from mice fed hapten 12 days earlier did not. However, when 12-day spleen cells were depleted of Lyt 2+ cells their ability to adoptively transfer CS was restored. These observations indicate that feeding TNCB to mice initially produces CS, mediated by Thy 1.2+, Lyt 1.1+ lymphocytes. CS is subsequently down-regulated by activation of Lyt 2+ suppressor cells, precursors of which are sensitive to CY.     

Differences in the age-dependent release of a low molecular weight suppressor (LMWS) and stimulators by normal and nzb/w lymphoid organs.

The age-dependent release of soluble suppressors and stimulators of DNA synthesis by cultured thymocytes and spleen cells from C57BL/6 and BALB/c mice was compared with their release by NZB/W lymphoid organs. Spleen cells from the normal strains released high levels of suppressor early in life and gradually decresing quantities with age, NZB/W spleen cells exhibited an early deficiency followed by a later excess in the production of suppressor. These differences were quantitated by dose-response studies. Thymocytes from the normal strains released stimulatory factors throughout life. In contrast, NZB/W thymocytes stopped releasing stimulatory activity and began to produce suppressor after 2 1/2 to 4 months of life. This abnormal elaboration of suppressor by thymocytes occurred 2 months before its reappearance in the autologous spleen cell supernatant. Both the early and late-appearing (less than 1000). This activity was designed as low molecular weight suppressor (LMWS). Its aberrant production by their reported functional immunologic abnormalities. The following items were discussed: the production of LMWS by adherent spleen cells, its relationship to previously described regulators, its partial purification and initial chemical characterization, and exclusion of the naturally occurring inhibitors of lymphocyte activation, cortisol, corticosterone, cold thymidine, and cyclic AMP as the active molecule.     

Soluble factors from BCG-induced suppressor cells inhibit in vitro PFC responses but not cytotoxic responses.

A macrophage-like suppressor cell is present in the spleens of BCG-infected C57BL/6 mice. This suppressor cell is capable of suppressing both in vitro cytotoxic and PFC responses of normal C57BL/6 spleen cells. Suppression was not caused by changes in the kinetics of the responses or in the quantities of antigen required for stimulation. Suppression of the in vitro cytotoxic response could not be linked to any soluble mediator. In contrast, supernatants obtained from BCG spleen cell cultures, which failed to inhibit alloantigen-induced cytotoxic responses, suppressed the in vitro PFC response to SRBC by normal C57BL/6 spleen cells. It is postulated that either BCG-induced macrophage-like suppressor cells inhibit these in vitro responses via different mechanism(s) or these responses are regulated by different suppressor cell subpopulations within the monocyte/macrophage compartment of BCG spleen cells.     

Suppression of Ag-induced release of EP (IL 1) by spleen cells of specifically desensitized donors: evidence for the role of a suppressor cell

Monocytes or macrophages may be induced to produce IL 1 by activators (e.g., lipopolysaccharide endotoxin) that act directly or by antigens/mitogens (e.g., Con A) that stimulate inducer lymphocytes to release a lymphokine that stimulates macrophages. Using guinea pigs (GP) rendered delayed hypersensitive to ovalbumin (OVA), we investigated the role of spleen cells from normal, sensitized, and specifically desensitized GP in suppressing release of IL 1, measured as endogenous pyrogen (EP), from peritoneal exudates of sensitized GP when incubated with OVA in vitro. Co-cultivation of all three sources of spleen cells with GP peritoneal exudate cells and OVA suppressed EP release as measured in the rabbit fever assay, the effect being most marked with cells from desensitized GP, intermediate with cells from sensitized GP, and least with normal cells. This suppressor activity of spleen cells on in vitro EP release was not explained by nonspecific absorption of EP by the added cells and did not affect EP release by a stimulus that activates macrophages directly (heat-killed staphylococci). It required both lymphocytes and macrophages for its effect, but unlike some other suppressor factors, it was not modified by indomethacin, an inhibitor of prostaglandin release. This appears to be the first reported evidence for cell-mediated suppression of lymphokine-mediated release of IL 1, an important modulator of the immune system through its combined role as a lymphocyte-activating factor and an inducer of fever (EP).     

The induction of nonspecific T suppressor lymphocytes by prostaglandin E1

Suppressor cell activity is induced by the addition of prostaglandin E₁ to normal mouse spleen cells (NSC). When this population is added to fresh NSC, it suppresses the primary in vitro antibody response to DNP-LPS. This suppressor cell induction requires a brain-associated thy-1 antigen-bearing cell. No role for a nylon-wool-adherent cell could be demonstrated. Suppression occurs in the absence of T cells in the responding population. The addition of indomethacin to prevent endogenous synthesis of prostaglandins suggests that prostaglandininduced suppressor activity does not require further prostaglandin synthesis in the suppressor population but does require such synthesis in the responding population.     

T suppressor efferent circuit which affects contact sensitivity to picryl chloride: the late-acting, second nonspecific T suppressor factor bears I-A determinants which are responsible for the I-A genetic restriction in its interaction with its target cell

The T suppressor efferent circuit in the picryl (TNP) system, which inhibits the passive transfer of contact sensitivity, involves at least two antigen-nonspecific factors. The second nonspecific T suppressor factor (ns-2) bears I-A determinants of both the alpha and the beta chain as shown by affinity chromatography on immobilized anti-I-A monoclonal antibodies. Sequential absorption shows that the determinants of the alpha and beta chain occur on the same molecular complex. No absorption was obtained with anti-I-E antibody. There are two genetic restrictions associated with ns-2--the first is in its release from the second T suppressor efferent cell (on exposure to antigen) and the second is in its inhibitory interaction with its target cell. Both are MHC restricted and matching in I-A (but not I-E, or I-J) is sufficient. The question was asked whether the I-A of the ns-2 was directly responsible for the I-A genetic restriction in its action. F1 TsF was made in (H-2k X H-2b)F1 mice by injecting picrylated parental cells intravenously and triggering the release of ns-2 with the corresponding picrylated parental cells. Both I-Ak- and I-Ab-positive ns-2 were produced and were separated by affinity chromatography on immobilized anti-I-A monoclonal antibody. The I-A phenotype of these separated ns-2 of F1 origin determines the genetic restriction in their action; i.e., I-Ak+ ns-2 only inhibits passive transfer by H-2k cells and I-Ab+ ns-2 only acts on H-2b cells. In contrast, the I-A haplotype of the picrylated cell used to induce the Ts cell which makes ns-2 is unimportant. It was concluded that the I-A on the ns-2, and not a possible recognition site for I-A, serves as a restriction element. This finding suggests that ns-2 may act directly on the I-A-restricted T cell which mediates contact sensitivity.     

Immunoregulatory factors from a human macrophage-like cell line. II. A human T-cell lymphokine-induced suppressor factor for lymphocyte proliferation

It has been demonstrated that the human histiocytic lymphoma-derived cell line U937, which has monocytoid characteristics, responds to a concanavalin A-induced T-cell-derived suppressor supernatant (T-SFS) with the release of a factor markedly suppressing mitogen-stimulated proliferation of normal peripheral blood lymphocytes. The suppressor material is not dialyzable, appears within 2 hr of exposure of U937 cells to the T-SFS, persists for at least 24 hr, and has a Mr of approximately 40,000 by gel chromatography. The suppressor factor does not affect the proliferation of continuous T- and B-lymphoid cell lines, distinguishing it from the inhibitor of DNA synthesis also released by U937, but appears to be specific for a stage of activation of normal lymphocytes that is independent of (a) utilization of interleukin-2 and (b) inhibition of production of interleukin-2.     

Abnormal activation and loss of suppressor T cells in the spontaneously hypertensive rat.

Suppressor T cell function in the spontaneously hypertensive rat (SHR) and normotensive Wistar Kyoto (WKY) rats was analyzed using syngeneic mixed lymphocyte reaction (SMLR) and concanavalin A (Con A) activation. A depressed SMLR was found in adult SHR but not in adult WKY. IL-2 synthesized by SHR was 40-fold lower than that of WKY, and the suppressor T cells generated in the SMLR were incapable of suppressing IgG synthesis. Precursors of cells that can be activated by Con A to become functional suppressor cells are reduced in adult SHR. Supernatant fluids derived from Con A-activated spleen cells from adult SHR failed to significantly inhibit IgG synthesis by cultures of syngeneic spleen cells compared to supernatant fluids from young SHR or WKY Con A-activated spleen cells. However, spleen cells from both adult SHR and WKY proliferated strongly and released equivalent amounts of IL-2 in response to Con A. Addition of exogenous IL-2 to the SMLR cultures in vitro restored the ability of SHR T cells to respond in the SMLR, with generation of cells capable of suppressing IgG synthesis. Administration of SHR with IL-2 in vivo also restored the suppressor T cell function in the SMLR. These results suggest a defective suppressor T cell activation and loss of suppressor T cell activity as the SHR age.     

Functional equivalence of cryptococcal and haptene-specific T suppressor factor (TsF). II. Monoclonal anti-cryptococcal TsF inhibits both phagocytosis by a subset of macrophages and transfer of contact sensitivity

Monoclonal anti-cryptococcal TsF (which inhibits phagocytosis by macrophages) and anti-picryl TsF use the same two circuits to block the transfer of contact sensitivity (CS). Both arm macrophages which then release a macrophage suppressor factor (MSF) when exposed to antigen. This MSF depresses the transfer of CS. The evidence suggests that a single molecular species of TsF (MW ca. 70 kDa), which bears an antigen-binding site and I-J determinant, is responsible for MSF production and inhibition of phagocytosis. Anti-cryptococcal TsF also arms the T acceptor cell which then releases nsTsF-1 after triggering with a specific antigen (SCPA). This nsTsF-1, which depresses the transfer of contact sensitivity, was authentic, as shown by its I-J positivity (in contrast to MSF) and its role in the production of nsTsF-2. As anti-picryl TsF also inhibits phagocytosis, it was concluded that anti-cryptococcal TsF, originally detected by the inhibition of phagocytosis, and anti-picryl TsF, originally detected by inhibition of CS, are functionally equivalent.