Regulatory mechanism of delayed-type hypersensitivity in mice. IV. Effect of suppressor T cells on the development of memory T cells involved in accelerated generation of DTH-effector cells in vitro

The effect of suppressor T cells (Ts) on the induction and the subsequent development of memory T cells for delayed-type hypersensitivity (DTH) was examined. The memory cells were induced in the spleens of mice primed previously with a low dose of reduced and alkylated ovalbumin (Ra-OA), and they generated DTH-effector T cells (DTH-Te) in a significantly accelerated fashion when cultured with OA in vitro. Ts were obtained from the spleens of mice which received OA-coupled spleen cells i.v. 4 days previously, and they inhibited antigen-specifically the induction of DTH responses in the recipient mice sensitized with alum-absorbed OA only when transferred with 5 weeks before sensitization. The spleen cells from mice given Ts together with the priming antigen 7 weeks before culture failed to generate DTH-Te in an accelerated manner on restimulation with OA in vitro. The memory cells from primed mice also did not cause accelerated generation of DTH-Te, when cultured with Ts in the presence of OA in vitro. These results indicate that both the induction of the memory cells by priming with antigen in vivo and the subsequent development of memory cells to DTH-Te by restimulation in vitro are inhibited independently by Ts. This corresponded well with the effect of Ts on the development of DTH-memory in vivo.     

Suppressor T cell recognition of major and minor histocompatibility alloantigens: selected suppression of MHC-directed responses by minor alloantigen Ts

The induction of suppression by i.v. administered alloantigens in the murine host was analyzed as a model of the possible effects of blood transfusion on transplant survival. The results indicated that suppressor T cells (Ts) specific for minor histocompatibility alloantigens could be readily induced by the i.v. presentation of minor alloantigen-disparate spleen cells. In contrast, similar priming with cells differing solely at the H-2 major histocompatibility complex stimulated only positive T cell immunity, with no evidence of suppression. The induction of H-2 directed Ts activity could be accomplished only by i.v. priming with major plus minor incompatible donor cells, suggesting that suppressor cell recognition of minor alloantigens may have facilitated the generation of Ts against H-2-encoded major transplantation antigens. A role for minor histocompatibility antigens in the regulation of H-2-specific immunity at the effector level was also indicated. Ts induced by i.v. pretreatment with minor antigen-disparate donor cells not only suppressed the delayed-type hypersensitivity (DTH) response to the relevant minor alloantigens, but also inhibited DTH against unrelated H-2 alloantigens introduced during subsequent intradermal immunization. Suppression of H-2-directed T cell reactivity was specific in that the presence of the Ts-inducing minor alloantigens was also required and occurred only when the minor and unrelated major alloantigens were presented within the same inoculum, if not on the same cell surface. The capacity of Lyt-2+Ts or Ts-derived suppressive factors specific for one set of cell surface molecules to modulate responses to an unrelated group of surface antigens does not appear to represent a general phenomenon, because similar suppression of immunity to unrelated tumor-specific transplantation antigens by minor-specific Ts was not observed. These results are discussed with respect to the possible mechanism of H-2-directed suppression and the role of the I region in Ts recognition of antigen.     

Antigen presentation in the rat: role of a nonadherent, nonphagocytic, W3/13, OX-6 positive T cell in the presentation of antigen to primed T lymphocytes

The nature of accessory cells in rat lymph nodes which can present antigen to primed T cells was investigated. Removal of adherent, phagocytic cells from antigen-primed lymph node cells by passage over glass-bead and nylon wool columns followed by treatment with carbonyl iron did not abrogate the antigen-specific proliferative response to keyhole limpet hemocyanin (KLH) or to the synthetic polypeptide L-glutamic acid-L-alanine-L-tyrosine (GAT). This T cell-enriched population was free of contaminating macrophages as determined by latex bead ingestion and morphological criteria during a 4-day culture period. Treatment of the T cell preparation with rabbit anti-rat IgG and complement or rosetting with IgG-coated sheep erythrocytes to remove any remaining B cells or macrophages did not significantly affect the proliferative response to antigen. Analysis of the T cell preparation by panning techniques with monoclonal antibodies to T cell surface markers suggested that both the responding T cell and the antigen-presenting cell were positive for the rat T cell marker, W3/13. The KLH-primed LN T cell-enriched fraction contained two distinct cell populations that were separable on the basis of their reactivity to OX-6 antibody. Two populations, an OX-6+ and an OX-6-, interacted synergistically in a KLH-dependent in vitro proliferative response. The cells within the T cell-enriched fraction that were positive for the OX-6 marker functioned primarily as the APCs, while the OX-6- cell fraction contained cells that proliferated to antigen when OX-6+ cells from either the T cell fraction or the adherent fraction were present. The implications of these findings are discussed.     

Modulation of suppressor T cell induction with gamma-interferon

The ability of antigen-coupled splenic adherent cells to induce suppressor T cells (Ts) is dependent on the presence of I-J determinants on antigen-presenting cells. After 4 days of in vitro culture, antigen-coupled adherent cells lose the capacity to induce Ts. Supernatants from Con A-stimulated lymphocyte cultures and purified interferon-gamma can sustain accessory function for the induction of Ts. Furthermore, after in vitro culture of splenic adherent cells, there is an apparent correlation between the loss of I-A determinants and the decrease in I-J-restricted Ts induction. Stimulation of Ia expression with interferon-gamma results in a simultaneous increase in the ability to induce Ts. Finally, elimination of I-A-bearing splenic adherent cells with antibody + C eliminates I-J-restricted Ts induction. The combined data imply a co-regulation of I-A and I-J on the antigen-presenting cells involved in the induction of both the Ts1 and Ts3 suppressor T cell subsets.     

The role of suppressor factors in the regulation of immune responses by ultraviolet radiation-induced suppressor T lymphocytes. I. Activity of suppressor cell culture supernatants

The purpose of this study was to determine whether soluble suppressor factors are involved in the regulation of immune responses by ultraviolet radiation-induced suppressor T lymphocytes (UV Ts). The UV Ts were induced by applying contact allergens to the ventral, unirradiated skin of mice that had been exposed 5 days earlier to UVB radiation. Supernatants from cultures that contained a mixture of UV Ts, normal responder lymphocytes, and hapten-modified stimulator cells were injected iv into normal recipients at the time of sensitization; they inhibited the induction of contact hypersensitivity (CHS) in vivo in an hapten-specific manner. The supernatants similarly suppressed the generation of specific cytotoxic T lymphocytes (CTL) in vitro. Moreover, supernatants from cultures that contained either UV Ts alone or UV Ts in combination with either the responder or the stimulator cells failed to suppress the CHS and CTL responses. These results suggest that hapten-specific inhibitory factors may participate in the regulation of immune responses by suppressor cells generated by epicutaneous sensitization of UV-irradiated mice.     

Activation of antigen-specific suppressor T lymphocytes in man involves dual recognition of self class I MHC molecules and Leu-4/T3-associated structures on the surface of inducer T lymphocytes

We showed previously that fresh Leu-2+ T cells respond to autologous antigen-primed Leu-3+ T cells by proliferation and differentiation into suppressor T cells (Ts) that specifically inhibit the response of fresh Leu-3+ cells to the original priming antigen. This study was undertaken to characterize the role of various cell surface molecules expressed by antigen-primed Leu-3+ cells in their activation of Leu-2+ Ts cells. Alloactivated Leu-3+ blasts were treated in the absence of complement with a variety of monoclonal antibodies recognizing distinct antigens on human lymphoid cells, and then were examined for their functional effects on fresh autologous T cells. Prior treatment of Leu-3+ blasts with anti-Leu-4 or anti-HLA-A,B,C framework antibodies, but not with anti-Leu-1, anti-Leu-3, anti-Leu-5, or anti-HLA-DR framework-specific antibodies, not only blocked proliferation of fresh Leu-2+ cells, it also prevented their differentiation into Ts cells. Furthermore, after their activation by Leu-3+ blasts, Leu-2+ Ts cells inhibited the response of fresh Leu-3+ cells from only those individuals who shared HLA-A,B phenotypes with suppressor-effector cells. These results suggest that both the inductive and effector phases of suppression involve dual recognition of autologous class I MHC molecules and structures associated with the Leu-4 (T3) molecule on the surface of antigen-reactive Leu-3+ cells.     

Activation via TCR or IL-2 receptor of a CD8+ suppressor T cell clone: Effect on IL-10 production and on proliferation of the suppressor T cell

In a previous study, we established CD8⁺ suppressor T cell (Ts) clone 13G2 which produced the suppressive lymphokine, interleukin-10 (IL-10). In this study, we examined what physiological activator could induce both production of IL-10 from 13G2 and the proliferation of 13G2. Both the antigenic stimulation mimicked by the anti-CD3 antibody and the T cell growth factor interleukin-2 (IL-2) induced IL-10 production from the 13G2 clone equally well. 13G2 cells proliferated remarkably with IL-2 stimulation, while anti-CD3 only slightly induced proliferation of the clone. 13G2 cells also produced IL-10 in the presence of hydroxyurea which blocked transit of cells from G₁ to S phase. However, cycloheximide blocked the production of IL-10 from the Ts clone. The study demonstrates that both the anti-CD3 antibody and IL-2 induced IL-10 synthesis of the Ts clone equally well, and the proliferative response of Ts cells was induced more by IL-2 than by anti-CD3. IL-2 proved to be a good stimulator for Ts cells to produce suppressive lymphokine and to multiply their population.Abbreviation Ts suppressor T cell - Th helper T cell - Ag antigen - APC antigen presenting cell - IL interleukin - TCR T cell receptor - mAb monoclonal antibody     

Lymphocyte function in experimental African trypanosomiasis. VIII. Loss of suppressor T cell function in lymph nodes

The immunosuppression that occurs in mice experimentally infected with African trypanosomiasis has been examined further. In the present study we have examined lymph node cells from Trypanosoma rhodesiense-infected C57Bl/6J mice for the ability to produce mitogen induced antigen-nonspecific suppressor T cells (Ts). Inguinal, mesenteric, and brachial lymph node cells were harvested from uninfected control mice and from mice at different periods of infection. These cells were cultured with or without concanavalin A (Con A) for 48 hr to induce Ts activity. After stimulation, the control and infected lymph node cells were passed over Sephadex G-10 columns to remove suppressor macrophages that arise during the infection from Con A-induced Ts. The column passed cells were then added to normal mouse responder spleen cells in a primary in vitro antibody response culture system with sheep erythrocytes (SRBC) as antigen. The resultant plaque-forming cell responses to SRBC indicated that Ts function was not induced in infected lymph node cell populations. However, early in the infection, a stimulatory signal was provided by both the untreated and Con A-treated infected lymph node cells, which was lost in the terminal stage. Determinations of T cell subpopulations revealed that the infected Lyt 2.2-bearing subpopulation was not significantly altered from normal controls. We conclude that T. rhodesense infected mice fail to mount normal lymph node cell antigen nonspecific Ts responses and that this loss of activity may be due to an intrinsic dysfunction in the suppressor T cell population.     

Antigen-induced T suppressor cells regulate the autoreactive T helper-B cell interaction

The T suppressor (Ts) cell population that functions to regulate antigen-specific MHC-restricted T helper (Th)-B cell interactions also regulates the activation of B cells by cloned autoreactive Th cells. Activated Ts cells were generated by in vivo priming and restimulation in vitro with high concentrations of the specific priming antigen. Once generated, this Ts population inhibits the Th-dependent activation of primed B cells by both antigen-specific and autoreactive T cells in an antigen-nonspecific manner. This suppression requires the participation of both Lyt-1+2- and Lyt-1-2+ T cells. It was also demonstrated that accessory cells were required for the induction of Ts cells. Moreover, the generation of suppression was MHC-restricted and required the recognition by T cells of Ia antigens on accessory cells. These studies demonstrate that the same or a very similar Ts cell population can function to inhibit the activation of B cells by antigen-specific as well as autoreactive T cells.     

Nonspecific inhibitor of DNA synthesis elaborated by T acceptor cells. I. Specific hapten- and I-J-driven liberation of an inhibitor of cell proliferation by Lyt-1-2+ cyclophosphamide-sensitive T acceptor cells armed with a product of Lyt-1+2+-specific suppressor cells

Lyt-1+2+ hapten-specific T suppressor cells (Ts) from mice injected and then painted with picryl or oxazolone derivatives produce hapten-specific T suppressor factors (TsF) in vitro. Stimulation by painting with contact sensitizer (which need not be specific) gives rise to Lyt-1-2+, I-J+, cyclophosphamide-sensitive T acceptor cells (Tacc). When the Tacc population is armed with TsF and then is exposed to specific antigen in the context of I-J-controlled determinants (antigen-presenting, haptenized spleen cells and Ts sharing the same I-J subregion), a nonspecific inhibitor of DNA synthesis (nsINH) appears in the supernatant. This inhibitor suppresses the primary DNA synthetic response to concanavalin A, lipopolysaccharide, and alloantigens in both syngeneic and allogeneic lymphocytes. The nsINH is only effective when added to lymphocyte cultures less than 8 hr after the stimulation with concanavalin A. The nsINH, however, affects neither primary nor secondary cytotoxicity in vitro. These data suggest the mouse immune system is capable of selective regulation of the response to specific antigen by the production of nonspecific soluble suppressor factor(s).     

Immunoregulatory T lymphocytes in man. Soluble antigen-specific suppressor-inducer T lymphocytes are derived from the CD4+CD45R-p80+ subpopulation

Regulation of the immune response in man is largely dependent on interactions between cells of the cluster designation 4+ (CD4+) helper/inducer sublineage and the CD8+ suppressor/cytotoxic sublineage. When cultured with autologous antigen-primed CD4+ lymphocytes, CD8+ cells differentiate into suppressor T cells (Ts) that specifically inhibit the response of fresh autologous CD4+ cells to the priming antigen only. The current study was undertaken to analyze the roles in this suppressor circuit of subpopulations of the CD4+ sublineage distinguished from one another on the basis of their binding (or lack of binding) to monoclonal antibodies against molecules p80 (Leu8) and CD45R (p220/Leu18/2H4). When examined for the proliferative responses to alloantigenic stimuli, each of the four: CD4+p80+, CD4+p80-, CD4+CD45R+, and CD4+CD45R- populations proliferated vigorously, synthesized interleukin 2 (IL-2) and interferon and released soluble IL-2 receptors. However, the responses to soluble antigens such as Candida and diphtheria toxoid were exhibited by CD4+CD45R-, CD4+p80+, and CD4+p80- cells, but not by CD4+CD45R+ cells. When examined for their ability to induced CD8+ Ts in the Candida-driven suppressor-induction culture system, only CD4+p80+ and CD4+CD45R- cells induced strong suppression. Further, when CD4+CD45R- cells were separated into CD4+CD45R-p80+ and CD4+CD45R-p80- subpopulations, despite the ability of both subpopulations to respond to Candida, only CD4+CD45R-p80+ cells induced autologous CD8+ Ts. Activated CD8+ Ts suppressed not only proliferation but also the release of soluble IL-2 receptors by autologous antigen-activated CD4+ cells. Thus, the antigen-specific suppressor-inducer T cells appear to be derived from the CD4+CD45R-p80+ (Leu3+, Leu8+, 2H4-) subpopulation of the CD4+ sublineage.     

Regulation of granulomatous inflammation in murine schistosomiasis. IV. Antigen-induced suppressor T cells down-regulate proliferation and IL-2 production

In murine schistosomiasis mansoni the cell-mediated immune response to the deposited eggs is mediated by CD4+ delayed-type hypersensitivity effector T (TDH) cells that produce vigorous granulomatous responses in the liver and intestines of acutely infected animals. The response is significantly down-modulated in chronically infected mice by Ag-specific Ts cells. The present study was undertaken to establish an in vitro model by which TDH-Ts cell interactions could be analyzed. To this end, Ts cells were induced in vitro by preculture of chronic or acute infection spleen cells with soluble egg Ag (SEA) for 48 h. The induced cells suppressed the SEA-specific proliferation of acute infection spleen cells by 80 to 95%. The induced suppressor cells were Ag specific in both induction and elicitation of function, and were not cytotoxic to the acute infection splenic target cells. Suppression by the induced cells was manifested within the first 24 h of the SEA-induced response as IL-2 produced by acute infection spleen cells was suppressed 62%. Phenotypic analysis by flow cytometry of the induced suppressor cells showed that CD8+ cells from acute infection spleens and CD4+ and CD8+ cells from chronic infection spleens were effector Ts cells. Taken together, CD4+ and CD8+ SEA-specific Ts cells can be induced in vitro to effectively suppress the SEA-specific lymphoproliferation and IL-2 production of acute infection spleen cells. Establishment of this in vitro model will allow us to further analyze the mechanisms of Ts cell-mediated suppression of TDH cells.     

T cell regulation of B cell activation: antigen-specific and antigen-nonspecific suppressor pathways are mediated by distinct T cell subpopulations

The present studies were carried out to characterize the cellular events involved in the induction and function of carrier-specific Ts cells, which selectively regulate the generation of IgG responses by Lyb-5- B cells. It was demonstrated that this regulation is in fact mediated by two distinct suppressor pathways. In one pathway, carrier-primed Lyt-1 + 2 - Ts cells are specifically activated by in vitro reexposure to the priming antigen. After this specific activation, these Lyt-1 + 2 - Ts cells are able to suppress IgG responses in an antigen-nonspecific manner. This suppression requires the participation of unprimed Lyt-1 - 2 + T cells, and is effective in both the early and the late phases of antibody responses. A second suppressor pathway requires the antigen-specific activation of primed Lyt-1 - 2 + Ts cells. Suppression of antibody responses by activated Lyt-1 - 2 + Ts cells is highly carrier specific, in contrast to the nonspecific effector function of Lyt-1 + 2 - Ts cells, appears to act without requirement for additional T cell populations; and is effective only early in the course of the antibody response. Thus, it appears that two Ts cell populations may function through distinct mechanisms to regulate the generation of IgG Lyb-5- B cell responses.     

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

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

Induction of suppressor cells to T- and B-cell proliferative responses and immunoglobulin production by monoclonal antibodies recognizing the CD3 T-cell differentiation antigen

Monoclonal antibodies (mAb's) recognizing the CD3 T-cell differentiation antigen induced the generation of suppressor cells. These cells inhibited (1) proliferative responses of human peripheral blood mononuclear cells (PBMC) to PHA and allogeneic cells in mixed leukocyte culture; (2) proliferative responses of purified E-rosette-negative cells to Staphylococcus aureus Cowans I; and (3) de novo immunoglobulin synthesis and secretion in the pokeweed mitogen (PWM)-induced differentiation system. Monoclonal antibodies recognizing other T-cell differentiation antigens (anti-Leu 2a, anti-Leu 3a, and anti-Leu 5) did not induce the generation of suppressor cells, even at very high antibody concentrations. Statistically significant differences were not observed in the ability of the OKT3 and anti-Leu 4 mAb's to induce suppressor cells. Monocytes were not required for the generation of anti-CD3-induced suppressor cells. F(ab')2 fragments of the OKT3 mAb's were equally effective when compared with intact antibody molecules in inducing suppressor cells, although they did not induce proliferative responses. Proliferation was not required for the induction of suppressor cells. Irradiation (2500 rad) of PBMC before incubation with the anti-CD3 mAb did not affect the generation of suppressor cells. Furthermore, anti-CD3-induced suppressor cells were radioresistant. Addition of recombinant IL-2 to the cultures of responding cells and suppressor cells did not reverse the suppression. In vitro treatment of anti-CD3-induced suppressor cells with either the OKT4 mAb plus complement or the OKT8 mAb plus complement partially decreased the suppression of proliferative responses of PBMC to PHA or allogeneic cells in mixed lymphocytes culture. However, treatment with both OKT4 and OKT8 mAb's plus complement or the OKT11 mAb plus complement completely abolished the suppression. These results suggest that the suppressor cells are of the T11+T4+T8- and T11+T4-T8+ phenotypes. In other experiments, T4+T8- and T8+T4- cells were isolated from PBMC treated for 48 hr with anti-CD3 mAbs. Both these two populations significantly inhibited proliferative responses of autologous PBMC to PHA and de novo immunoglobulin synthesis and secretion by mixtures of purified T4 and B cells from normal donors, in the PWM-induced differentiation system. These results demonstrate that anti-CD3-induced suppressor cells are of the T4 or T8 phenotype. Treatment of purified T4+T8- and T8+T4- cells with anti-CD3 mAb's resulted in the generation of suppressor cells, suggesting that the precursors of the anti-CD3-induced suppressor cells can belong to either of these two populations.(ABSTRACT TRUNCATED AT 400 WORDS)     

Antigen presentation in the rat. II. An Ia+ radiosensitive T cell can present antigen to primed Ia- T cells

We demonstrated previously the presence of an Ia+ (OX-6+) antigen-presenting cell within the rat T cell fraction that is capable of presenting antigen to antigen-primed OX-6-T cells. This antigen-presenting cell (T-APC) reacted with the monoclonal antibodies W3/25 and W3/13, which is known to react mainly with rat T cells. Further characterization of the T-APC indicated that the cell also reacted with the monoclonal antibody OX-19, which is highly specific for rat T cells. Moreover, the antigen-presenting function of the T-APC was sensitive to treatment with mitomycin C or gamma-irradiation (2000 rad). Under similar conditions, antigen presentation by partially purified dendritic cells or macrophages was totally resistant to these treatments. The antigen-presenting activity of gamma-irradiated T-APC was not reconstituted by the addition of the lymphokines IL 1, IL 2, or Con A supernatants. Although unirradiated T-APC were able to stimulate an MLR response, this function was also sensitive to gamma-irradiation, whereas the MLR-stimulating ability of macrophages and dendritic cells was resistant to gamma-irradiation. These data indicate that Ia+ T cells from the rat are capable of presenting antigen to antigen-primed T lymphocytes and that, in contrast to antigen presentation by macrophages and dendritic cells, the function of T-APC is gamma-radiation sensitive.     

Effect of glucocorticoids on the development of suppressive activity in human lymphocyte response to a polysaccharide purified from Candida albicans

The action of glucocorticoids on the proliferative response of human lymphocytes stimulated in vitro by MPPS has been investigated. The effect of Dex was dependent on the time of steroid addition to the cultures. Dex added at the beginning of the culture period inhibited, cell proliferation and IL 1/IL 2 synthesis, although not completely. However, a delayed addition of 24 to 48 hr resulted in an enhancing effect on cell proliferative responses that was maximal at day 4. The effect of Dex on T suppressor cell activity was then investigated. Dex added 1 day before the appearance of suppressor cells resulted in a marked decrease or disappearance of the suppressive activity. Moreover, primed T lymphocytes treated with Dex in the presence of exogenous IL 2 enhanced the proliferative responses of fresh autologous PBMC stimulated by MPPS. Taken together, our data suggest that glucocorticoids inhibit the differentiation of T suppressor cells and that IL 2 is unable to reverse this inhibitory effect.     

Inhibition of murine suppressor cell function by progesterone

The effects of progesterone on murine suppressor cell function generated in allogeneic MLCs were investigated. BALB/c splenic lymphocytes stimulated in vitro with C3H/He cells significantly suppressed the proliferative response of BALB/c lymphocytes in a secondary MLC. This suppression was highly specific for the sensitizing alloantigens since the suppressor cells had no effect on the proliferative response of BALB/c lymphocytes to third-party alloantigens. In addition, BALB/c lymphocytes stimulated with syngeneic cells were observed to nonspecifically suppress the MLC response to a lesser extent. One to 10 micrograms/ml progesterone added at initiation to suppressor cell generating cultures diminished the ability of both alloantigen specific and nonspecific suppressor cell populations to suppress the proliferative response of homologous lymphocytes to alloantigens. Experiments with pyrilamine, an antihistamine, which blocks cytotoxic T lymphocyte (CTL) generation, suggests that progesterone has a direct inhibitory effect on suppressor cell function independent of its ability to block CTL induction. The effects of progesterone on suppressor cells were not due to shifts in peak response time in MLC or induction of radiosensitive cells in progesterone-treated cultures. Estradiol at doses between 5 and 10 micrograms/ml, and cortisol at dose of 1 microgram/ml, also significantly inhibited suppressor cell function. These results suggest that the steroid hormone milieu within the placenta may effect the activity of allogeneic or nonspecific suppressor cell activity.     

The role of suppressor factors in the regulation of immune responses by ultraviolet radiation-induced suppressor T lymphocytes. II. Activity of suppressor cell culture sonicates

The purpose of this study was to determine whether multiple types of suppressor factors play a role in the regulation of immune responses by ultraviolet radiation-induced suppressor T lymphocytes (UV Ts). The UV Ts were induced by applying contact allergens to the ventral, unirradiated skin of mice exposed 5 days earlier to UVB radiation. Previous studies indicated that supernatants from cultures containing UV Ts, normal lymphocytes, and hapten-modified cells suppressed contact hypersensitivity (CHS) in vivo and cytotoxic T lymphocyte (CTL) generation in vitro in a hapten-specific manner. In this report, cell-free lysates from sonically disrupted UV Ts were examined for their ability to suppress these responses. When lysates were injected into normal animals at the time of sensitization, they inhibited CHS in a hapten-nonspecific manner. In addition, the lysates suppressed not only the induction but also the elicitation of CHS, and they suppressed the generation of CTL. Lysates prepared from spleen cells obtained from non-UV-irradiated mice or UV-irradiated, unsensitized mice failed to inhibit either response. Moreover, in contrast to the lysates, the hapten-specific UV Ts culture supernatants inhibited the induction but not the elicitation of CHS. These results suggest that both hapten-specific and nonspecific inhibitory factors may participate in the regulation of immune responses by UV Ts.     

Selective inhibition of the generation of T suppressor cells of contact sensitivity in vitro by interferon

The T suppressor (Ts) cell response in contact sensitivity is preferentially inhibited by murine interferon-alpha, beta (IFN-alpha, beta) in vivo. Previous studies in vivo have suggested that IFN exerts its effect directly on the Ts subpopulation rather than through an effect on antigen-presenting macrophages. Nevertheless, the mechanism of this selective blockade remained unclear. To better define the mechanism(s) of inhibition of suppression by IFN-alpha, beta, we determined whether IFN acted on lymphocytes, macrophages, or both. Antigen-specific T effector cells of delayed-type hypersensitivity (TDH) and Ts cells were induced in vitro by co-culture of spleen lymphocytes with bone marrow-derived antigen-presenting macrophages (BM-MA) pulse-labeled with 2,4-dinitrobenzene sulfonate (DNBSO3). TDH or Ts activity was demonstrated by transfer of the lymphocytes into naive recipient BALB/c mice after 3 days of culture. BM-MA cultured for 5 to 7 days (BM-MA d5-7) before labeling preferentially activated TDH cells (Thy-1+, Lyt-1+2-); 10- to 14-day-old BM-MA (BM-MA d10) induced Ts cells (Thy-1+, Lyt-2+), as previously shown. Treatment of the spleen lymphocyte suspension with pure mouse IFN-alpha, beta at a dose of 10(3) U/10(8) cells completely blocked the induction of Ts cells but had no effect on the induction of TDH cells. Pretreatment of the antigen-presenting BM-MA for 24 hr with IFN (10(2) U/3 X 10(5) cells) had no effect on the induction of Ts and TDH cells. Cultivation of lymphocytes on a DNP-BM-MA d6 monolayer did not result in the induction of Ts cells; however, in the presence of a goat anti-murine IFN-alpha, beta antibody, Ts cells were induced. This finding indicates that the spontaneous release of IFN-alpha, beta in those cultures prevented the induction of Ts cells. These results confirm our previous observation that Ts cells are more easily blocked by IFN-alpha, beta than TDH cells, and demonstrate that IFN affects the Ts subpopulation not via modulation of the antigen-presenting macrophages. IFN-alpha, beta-producing, antigen-presenting, or accessory cells may therefore prevent the activation of this type of Ts cell.