Characterization of suppressor T cells in graft-versus-host reactions

Intravenous (i.v.) immunization of mice with irradiated (2000 rads) allogeneic lymphoid cells induces the generation of suppressor T cells. Such suppressor T cells can suppress the anti-host delayed type hypersensitivity (DTH) by other T cells during acute Graft-versus-Host reactions in irradiated recipient mice. Suppression of anti-host DTH is detectable at least 50 days after i.v. induction of the state of suppression in the donors. The generation of suppressor T cells in the donors is associated with proliferation. Furthermore, the suppressor T cells need to proliferate further in the irradiated allogeneic hosts in order to display a maximal suppressive effect. Two types of suppressor T cells were found to be required for suppression of the anti-host DTH response: a Lyt-1+2- cell population and a Lyt-1-2+ cell population.     

Lipopolysaccharide-induced suppression of DTH-reactivity to histocompatibility antigens. I. Kinetic aspects and specificity

The effects of bacterial lipopolysaccharide (LPS) on the development of DTH-reactivity to alloantigens in mice were investigated. DTH to a particular set of alloantigens could be suppressed by treatment of responder mice with a single intravenous (i.v.) injection of 100 micrograms LPS and a simultaneous subcutaneous (s.c.) injection of the appropriate allogeneic spleen cells. The suppression lasted at least 60 days and affected the afferent limb of the DTH response as well as the efferent limb. The suppression could be adoptively transferred to naive syngeneic recipient mice by spleen cells, but not by immune serum, and proved to be antigen-specific. In spite of this specificity, the DTH-response against unrelated "third-party" alloantigens could be suppressed as well, provided the latter were presented during the induction-phase of DTH together with the alloantigens that had been used for the induction of suppression.     

Distinction between suppressors of the delayed-type hypersensitivity and the humoral response to sheep erythrocytes.

Suppressors for both delayed-type hypersensitivity (DTH) and the humoral immune response could be simultaneously induced in the spleens of mice by immunization with a high dose of SRBC. Normal recipient mice of the spleen cells from donors immunized 5 days previously elicited depressed DTH or humoral response when immunized with SRBC. The suppressive activity was found to reside in T not B enriched fraction. Four hundred rad irradiation of the primed spleen cells resulted in complete loss of DTH suppressor activity, but only in some reduction of the suppressor activity for the humoral response. In contrast, hydrocortisone treatment of the donor mice caused no loss of DTH suppressor activity while approximately half of the suppressive activity for anti-SRBC PFC response was lost. Adult thymectomy prevented completely the induction of the DTH suppressor in contrast to little loss of the suppressor activity for the humoral response. DTH suppression was antigen-specific for the induction, but nonspecific for the expression. However the suppression of the humoral response was antigen-specific not only for the induction but also for the expression. In addition, DTH suppressor was capable of suppressing both the induction and expression of DTH while the humoral response was suppressed only in the induction stage by the suppressor.     

Regulation of delayed-type hypersensitivity IV. Antigen-specific suppressor cells for delayed-type hypersensitivity induced by lipopolysaccharide and sheep erythrocytes in mice.

Mice injected subcutaneously with 1 x 10(8) sheep red blood cells (SRBC) developed high levels of delayed-type hypersensitivity (DTH) to SRBC 4-8 days after injection. Such DTH was suppressed when 100 microgram lipopolysaccharide (LPS) was injected intravenously 1-2 days before or at the time of SRBC injection. This suppression of DTH was transferable by spleen, lymph node, thymus and bone marrow cells to sensitized or normal syngeneic recipients, but could not be transferred by serum. Suppressor cells were not induced by LPS alone or SRBC alone, and they were antigen-specific since DTH to chicken red blood cells was not affected. The suppressor cells appeared in the spleen in optimum number 3-4 days after induction. They were theta-negative and Ig-positive as judged by antiserum plus complement treatment and by Ig rosette separation. Attempts to obtain soluble suppressor factor from the suppressor cells by sonication or in vitro incubation were unsuccessful. Mitomycin C treatment of the suppressor cells completely abolished the suppressor activity. Thus, LPS, in conjunction with antigen, appears to induce a population of specific suppressor B cells which are capable of regulating T cell function.     

Inducible nitric oxide synthase in human diseases

Oestrogen has the capacity to suppress T cell-dependent DTH. To explore the mechanisms whereby oestrogen exerts its effects on the immune system we have used SCID mice which are largely devoid of functional T and B lymphocytes, hence being unable to raise DTH, but display intact antigen-presenting capacity. Transfer of lymphocytes to SCID mice restores the DTH capacity. In order to analyse if oestrogen down-regulates DTH by a direct action on T cells we reconstituted SCID mice with either splenocytes or thymocytes from congenic C.B-17 or allogeneic B6 donor mice. Either donor or recipient mice were exposed to estradiol before cell transfer. DTH response was registered in recipient SCID mice 1 and 3 weeks after challenge with oxazolone (OXA). SCID mice receiving estradiol-exposed spleen cells from congenic or allogeneic donor mice displayed lower DTH responses compared with control mice. In contrast, SCID mice receiving estradiol-exposed thymocytes from congenic donor mice showed no significant difference in DTH response compared with control mice. Estradiol-treated SCID mice, transferred with either spleen cells or thymocytes from congenic, hormonally non-treated donors, displayed a significantly lower DTH response compared with control mice. In contrast, estradiol-treated SCID mice receiving hormonally non-treated allogeneic spleen cells showed no difference in DTH response compared with control mice. The results show that T lymphocytes are not the target cell population for estradiol-mediated suppression of DTH in reconstituted female SCID mice.     

Regulation of delayed-type hypersensitivity. II. Specific suppressor factor for delayed-type hypersensitivity to sheep erythrocytes in mice.

An antigen-specific suppressor factor for delayed-type hypersensitivity (DTH) to sheep red blood cells (SRBC) in mice is described. Lymph node cells and spleen cells from mice injected intravenously with 1 x 10(9) SRBC 4 days previously were incubated in vitro for 48 h in culture medium. Supernatant obtained from the culture inhibited the induction of DTH to SRBC in normal mice. It also suppressed the expression of DTH in presensitized mice. The suppression is specific as the suppressor factor had no effect on the DTH to noncross-reacting antigen, chicken red blood cells. Treatment of the spleen cells with anti-theta serum and complement prevented the production of the suppressor factor, whereas treatment with anti-Ig serum and complement had no effect. Suppressor factor produced by H-2k mice suppressed the DTH in H-2b mice. The factor thus seems to act across the H-2 barrier. The suppressor factor was not removed by adsorption with goat anti-mouse immunoglobulin immunoadsorbent, but could be adsorbed by SRBC. It was stable at 56 degrees C for 1 h, but was partially inactivated by freezing and thawing. The factor has a molecular weight of less than 35 000 daltons.     

Delayed-type hypersensitivity to allogeneic mouse epidermal cell antigens. III. Analysis of suppressor cells

The specificity of suppressor T cells (Ts cells) induced by intravenous administration of allogeneic spleen cells was studied in mice using a delayed-type hypersensitivity (DTH) assay. The DTH responses were induced by subcutaneous injection of allogeneic epidermal cells (ECs) and were assayed by footpad swelling. Afferent-phase Ts cells (Ts-aff cells) were transferred into the recipient mice before ECs immunization. Treatment with monoclonal anti-Thy-1.2 antibody and complement abolished the suppression by Ts-aff cells in the DTH response. The suppression induced by Ts-aff cells, however, was resistant to the treatment with monoclonal anti-I-A or anti-Lyt-2.2 antibody and complement. These results showed that Ts-aff cells were Lyt-2-, Ia- T cells. Efferent-phase Ts cells (Ts-eff cells) were transferred before challenge of the DTH assay. Phenotypic analysis of these Ts-eff cells showed them to be Lyt-2+, Ia- T cells. Studies using several strains of congenic mice revealed the antigen specificity of both Ts cell subsets. Adoptive transfer of Ts-eff cells required H-2 restriction, but Ts-aff cells did not. We also induced cognate suppression of the DTH responses to the alloantigens mediated by Ts-eff cells.     

MHC- and Igh-unrestricted interaction between L3T4+, Lyt-2- Ts inducer cells and L3T4-, Lyt-2+ Ts effector cells is required for T cell-dependent suppression of DTH to histocompatibility antigens

This paper describes the characteristics of T suppressor inducer (Ts ind) cells which can interact with T suppressor effector (Ts eff) cells and thereby can account for suppression of delayed-type hypersensitivity (DTH) to alloantigens. Adoptive transfer of spleen cells from mice intravenously (i.v.) injected with allogeneic spleen cells one day earlier induced an antigen-specific state of suppression in the recipients. This became apparent when DTH was induced by subcutaneous (s.c.) immunization of the recipients three days after transfer. The induction of suppression after adoptive transfer of spleen cells required Thy-1+, L3T4+, Lyt-1+2- cells. These cells that by themselves did not exert a suppressive effect induced a state of suppression in recipient mice by activation of recipient-type Ts eff cells. Therefore, the former cell type was classified as Ts ind cell. When athymic nude mice were used as recipients, Lyt-2+ precursors of Ts eff cells had to be transferred together with the Ts ind cells to induce a state of suppression in these mice. The Ts ind cells could activate Ts eff cells in MHC- and Igh-incompatible recipients. The results are discussed in relation to previously described immunoregulatory T cell pathways.     

Suppression of delayed-type hypersensitivity to histocompatibility antigens by ultraviolet radiation.

Delayed-type hypersensitivity (DTH) reactions to allogeneic histocompatibility antigens in mice could be systemically suppressed by a single exposure to UV-B irradiation. The extent of suppression reached its maximum 4 days after irradiation, gradually waned thereafter, and disappeared at Day 21. Re-exposure of these mice to UV-B after waning reinduced the state of suppression. The suppression could be transferred to naive mice by means of splenic T lymphocytes. The suppressor T (Ts) cells suppressed the proliferative activity in the lymph nodes draining the site of immunization, but not the activity of already activated DTH-reactive T cells. Phenotypical analysis of these Ts cells revealed that two subpopulations of T cells are involved: one with the Lyt-1+, 2- phenotype, the other with the Lyt-1-, 2+ phenotype.     

Suppressor T cells for delayed-type hypersensitivity to Japanese encephalitis virus.

The delayed-type hypersensitivity (DTH) to Japanese encephalitis virus (JEV) and the suppressor cells controlling it and the antibody-forming cells in inbred Swiss mice have been studied. JEV induces DTH, with a peak response at day 7 following infection which persists at low levels at least up to 119 days. Suppressor activity appeared on day 18. It was transferable by immune spleen cells. Treatment of spleen cells with anti-Thy-1.2 antisera and complement abrogated the suppressor activity. The homogenate of the spleen was equally effective in mediating suppression of DTH and the humoral response as measured by direct antibody plaque-forming cell (IgM-PFC) assay. The suppressor activity was antigen-specific both on DTH and T helper for antibody response as the immune responses against SRBC or Coxsackie B4 virus were not suppressed. The suppressor cells were sensitive to cyclophosphamide treatment when the drug was given 48 hr before their appearance. It is, therefore, concluded that in JEV infection of mice, antigen-specific suppressor T cells are generated, both for DTH and IgM antibody, which are cyclophosphamide-sensitive and mediate suppression through soluble product(s).     

Suppression of an established DTH response to ovalbumin in mice by feeding antigen after immunization

Experiments were designed to examine whether systemic delayed-type hypersensitivity responses (DTH) to ovalbumin (OVA) can be suppressed when antigen is fed after immunization, and to investigate the immunological mechanisms involved. A single 25 mg feed of OVA given 7 or 14 days after immunization with OVA in complete Freund's adjuvant (CFA) suppressed the DTH response of BDF1 mice, but had no significant effect on the serum IgG antibody response. DTH suppression was greatest when antigen was fed soon after immunization, and became less pronounced as the time interval between feeding and immunization increased. The phenomenon was also demonstrated in mice of the BALB/c strain. Cell transfer experiments suggested that the post-immunization suppression was not due to a population of suppressor cells that have been described previously in association with classical oral tolerance for DTH. We conclude that there are separate and distinct mechanisms for the prevention of induction of DTH by antigen feeding in naive mice and the suppression of expression of DTH in sensitized animals.     

Comparison of T-cell responses in self-limiting versus progressive visceral Leishmania donovani infections in golden hamsters.

Leishmania donovani infection in golden hamsters was studied as a model for human kala-azar. After intradermal inoculation of L. donovani amastigotes, hamsters developed positive skin reactions (delayed-type hypersensitivity [DTH]) to parasite antigens and lymphoid cells from these hamsters proliferated to parasite antigens in vitro and transferred DTH reactivity to normal recipients. In contrast, hamsters infected by the intracardial route developed progressive visceral infections and failed to respond to skin test antigens. Spleen cells, lymph node cells, and peripheral blood lymphocytes (PBLs) from these hamsters were unresponsive to parasite antigens in vitro, and spleen cells failed to transfer DTH to normal recipients. Spleen cells, but not PBLs, displayed depressed responses to T-cell mitogens and also suppressed the proliferative response of cells from hamsters inoculated intradermally. Removal of adherent cells restored the capacity of spleen cells, but not PBLs, to respond to parasite antigens. The nonadherent population of these spleen cells also transferred DTH to normal recipients. The adherent suppressor cells, which have the characteristics of macrophages, appear to be localized to the spleen and are apparently not responsible for the failure of peripheral lymphoid cells to respond to antigen. These studies suggest that hamsters with visceral infections develop a population of antigen-reactive cells and that in the absence of suppression these cells may express functional activities, including the capacity to elicit DTH responses.     

Auto-Delayed-Type Hypersensitivity Induced in Immunodeficient Mice withModified Self-Antigens

X-irradiated (250 rad), cyclophosphamide-treated or ATx A mice injected with syngeneic trinitrophenylated spleen cells (TNP-SC) and footpad challenged with syngeneic lymphoblasts generated delayed-type hypersensitivity (DTH) responses 24, 48 and 72 h after challenge. The syngeneic-DTH (syn-DTH) response was mediated by Lyt-1+ cells and suppressed with Lyt-1+2+3+, I-Jk+ cells. The suppressor cells were obtained from spleens or thymuses of normal syngeneic mice. Suppressor factor (SF) was extracted or released from Lyt-1+2+3+, I-Jk+ cells obtained from normal A mice (but not from X-irradiated A mice). The factor blocked the DTH responses of X-irradiated mice injected with syngeneic TNP-SC and challenged with syngeneic lymphoblasts when injected into the mice both at the induction phase and the elicitation phase of the DTH. The factor failed to abrogate allogeneic and xenogeneic DTH. However, allogeneic factor (derived from C57BL/6 mice) abolished the syn-DTH response of mice injected with syngeneic TNP-SC and challenged with syngeneic lymphoblasts. The SF was produced by Lyt-1+2+3+, I-Jk+ T cells or by thymocytes. The combined extracted product of Lyt-1+ and Lyt-2+ cells did not abrogate the syn-DTH response. Normal spleen cells depleted of phagocytes by a magnetic procedure also produced the SF. These findings indicate, therefore, that suppressive factor (or factors; see Discussion in the accompanying paper, Ref. 17) controls the immunological autoreactivity against syngeneic TNP-SC.     

Characterization of a third-order suppressor T cell (Ts3) induced by cryptococcal antigen(s).

Previous studies from our laboratory have shown that a high dose of cryptococcal culture filtrate antigen (CneF) administered intravenously induces a complex suppressor cell cascade which down-regulates the cell-mediated immune response to Cryptococcus neoformans antigens. The primary objective of this investigation was to determine whether a suppressor cell induced by immunization is required for efferent suppression of the cryptococcal delayed-type hypersensitivity (DTH) response. Our approach to this problem was to immunize CBA/J mice with CneF emulsified in complete Freund adjuvant and then 6 days later to collect spleen cells from the immunized mice and adoptively transfer these cells along with C. neoformans-specific second-order suppressor T cells (Ts2) to naive syngeneic recipients at the time of footpad challenge of the recipients with CneF. To establish which populations of cells in the spleens of immunized mice play a suppressive role, mass cytolysis with specific antibodies and complement was performed before the spleen cells were transferred to naive animals. Since the phenotype of the cells responsible for the transfer of the cryptococcal DTH response had not been completely determined, we first demonstrated that the cells responsible for DTH were L3T4+ Lyt-2- cells. Subsequently, we established that a Thy-1+ L3T4- Lyt-2+ I-J+ cell population induced by immunization was required along with C. neoformans-specific Ts2 cells for efferent suppression of the cryptococcal DTH response. In addition, we demonstrated that the suppressor cells in the immune cell population were derived from cyclophosphamide-sensitive precursors. These data indicate that a third suppressor cell population is required for efferent suppression of the cryptococcal DTH response. As in the azobenzenearsonate and 4-hydroxy-3-nitrophenyl acetyl hapten suppressor models, the Ts2 cells in the circuit mediate their effects through this third suppressor component. Since the mode of induction and the phenotype of the third C. neoformans-specific suppressor cells are similar to those reported for Ts3 cells in other antigen-specific suppression models, we referred to this third suppressor cell in the C. neoformans-specific suppressor cell cascade as a Ts3 cell.     

Modification of Immune Response by Cinnarizine

Abstract

Effects of cinnarizine on immune response in mice were investigated. Mice were orally administered with cinnarizine and were immunized with sheep red blood cells (SRBC) intravenously. Numbers of plaque forming cells (PFC) to SRBC in spleen of these mice were assayed and delayed-type hypersensitivity (DTH) response to SRBC was measured. 1) PFC response in immunization with 5 × 10⁶ cells/mouse of SRBC was enhanced by administration of 25 mg/kg of cinnarizine, while the response in immunization with 5 × 10⁸ cells/mouse was suppressed by 25 to 200 mg/kg of cinnarizine. 2) From study on timing of administration, suppression of PFC response by 6.25 to 200 mg/kg of cinnarizine was observed at 24 hr. after the immunization. 3) 12.5 to 200 mg/kg of cinnarizine suppressed polyclonal B cell activation induced by lipopolysaccharide (LPS). 4) Colchicine induced suppressor T cell inactivation was prevented by administration of 50 mg/kg of cinnarizine and it was suggested that cinnarizine may induce suppressor T cells from the study of adoptive cell transfer system. 5) 50 mg/kg of cinnarizine showed the suppression of DTH response in expression phase, but not in induction phase. It was concluded that immune responses in mice were modified by cinnarizine.     

Delayed-type hypersensitivity induced in immunodeficient mice with syngeneic modified self antigens: a suggestive model of autoimmune response

Previous studies suggested that trinitrophenyl (TNP)-modified syngeneic red cells induced humoral autoimmune response in mice with defective T cell function but not in normal mice. The ability of modified self antigen to induce autoimmune response in immunodeficient mice was further explored using the delayed-type hypersensitivity (DTH) as an assay system. Mice were immunized with syngeneic TNP-modified spleen cells (TNP-SC) and challenged by syngeneic nonmodified conconavalin A (Con A) or lipopolysaccharide (LPS)-stimulated spleen cells injected into their footpads. The DTH response was assessed 24, 48 and 72 h later by measuring the footpad swelling and was transferred to naive recipients with enriched T cells from TNP-SC-immunized irradiated A mice but not with serum or non-T cells. Adult thymectomized, X-irradiated (250 rds) and cyclophosphamide-treated mice injected with syngeneic TNP-SC generated a DTH response when subsequently challenged with syngeneic lymphoblasts (induced with Con A or LPS) but not when challenged with allogeneic blast cells. In contrast, normal mice treated in a similar manner exhibited a much less significant DTH response. SC incubated 1 to 3 h with Con A failed to elicit the DTH response of immunodeficient mice previously injected with TNP-SC. Both lymphoblasts that were induced in vitro with Con A diluted in fetal calf serum or in normal mouse serum-containing media, and lymphoblasts that were induced in vivo by interleukin 2 elicited DTH responses in X-irradiated, TNP-SC immunized mice. The syngeneic DTH response of the immunodeficient mice injected with TNP-SC was abrogated when they were simultaneously transplanted with syngeneic SC or nylon wool-passed syngeneic SC. If the transplanted splenocytes had been treated with anti-Thy-1 antiserum and complement they failed to abrogate the syngeneic-DTH response of the above mentioned mice. This result suggests that suppressor cells are programmed to control the autoimmune response induced with modified self antigens.     

Immune depression in trypanosome-infected mice. III. suppressor cells.

Spleen cells from trypanosome-infected mice strongly suppressed lymphocyte stimulation induced in normal spleen cell populations by lipopolysaccharide, concanavalin A or allogeneic (H-2-different) stimulator cells. This suppression was not H-2-restricted, as responses of spleen lymphocytes both allogeneic and syngeneic to the suppressors were inhibited. Irradiation or mitomycin C treatment of suppressor populations markedly reduced but did not eliminate suppressor activity. Suppressor populations were effective when present in very low numbers. Addition of suppressor cells to mixed lymphocyte cultures at various intervals after initiation of the cultures showed that the suppressors require 48 h to manifest their activity. Cell depletion or enrichment experiments indicate that the mechanism of suppression is complex and involves more than one cell type.     

犬蛔虫（Toxocaracanis）对感染鼠的细胞免疫和IL－1、IL－2免疫调节作用的影响

应用犬蛔虫（Ｔ．ｃａｒｎｉｓ）的感染性虫卵口饲感染Ｃ３Ｈ／ＨｅＮ鼠，体外培养后观察脾细胞的免疫学变化。感染第１－４周的脾细胞用ＣｏｎＡ刺激，Ｔ细胞的增殖反应，ＩＬ－２的诱生均明显地受到抑制，而且感染鼠脾细胞抑制了正常鼠脾细胞对ＣｏｎＡ的反应。感染鼠的脾细胞经ＳｅｐｈａｄｅｘＧ－１０过柱后，Ｔ细胞则不显示被抑制作用。表明影响Ｔ细胞被抑制作用的是感染鼠的巨噬细胞。相反，感染第１－４周的鼠所产生的ＩｇＧ和ＩｇＭ等抗体的Ｂ细胞活性增强；用ＬＰＳ刺激巨噬细胞诱生的白介素（ＩＬ）ＩＬ－１也增多。     

Suppression of BCG cell wall-induced delayed-type hypersensitivity by BCG pre-treatment. II. Induction of suppressor T cells by heat-killed BCG injection.

Previous intravenous (i.v.) injection of heat-killed Bacillus Calmette-Guérin (BCG) in mice produced a suppression of delayed-type hypersensitivity (DTH) induced with oil-treated BCG cell walls. This phenomenon was analysed by the macrophage migration inhibition (MI) test in which non-adherent spleen cells from mice which had been injected with heat-killed BCG (K-Non-ad. cells) were mixed with peritoneal exudate cells from BCG cell wall-immunized mice (effector-PEC). The test showed that the K-Non-ad. cells suppressed the MI activity in the effector-PEC, which indicated that the suppressor cells were induced in the spleen by the heat-killed BCG injections. Moreover, the suppressive effect of the K-Non-ad. cells disappeared after treatment with anti-brain associated theta serum (BA theta) and guinea-pig complement, and operated across the H-2 barrier. The suppressor cells inhibited the production or release of the migration inhibition factor from the BCG cell wall-sensitized cells in the presence of the specific antigen, purified protein derivatives (PPD). It was concluded that the injections of heat-killed BCG produced antigen non-specific suppressor T cells in DTH suppression.     

Modification of Immune Response by Cinnarizine

Effects of cinnarizine on immune response in mice were investigated. Mice were orally administered with cinnarizine and were immunized with sheep red blood cells (SRBC) intravenously. Numbers of plaque forming cells (PFC) to SRBC in spleen of these mice were assayed and delayed-type hypersensitivity (DTH) response to SRBC was measured. 1) PFC response in immunization with 5 × 10⁶ cells/mouse of SRBC was enhanced by administration of 25 mg/kg of cinnarizine, while the response in immunization with 5 × 10⁸ cells/mouse was suppressed by 25 to 200 mg/kg of cinnarizine. 2) From study on timing of administration, suppression of PFC response by 6.25 to 200 mg/kg of cinnarizine was observed at 24 hr. after the immunization. 3) 12.5 to 200 mg/kg of cinnarizine suppressed polyclonal B cell activation induced by lipopolysaccharide (LPS). 4) Colchicine induced suppressor T cell inactivation was prevented by administration of 50 mg/kg of cinnarizine and it was suggested that cinnarizine may induce suppressor T cells from the study of adoptive cell transfer system. 5) 50 mg/kg of cinnarizine showed the suppression of DTH response in expression phase, but not in induction phase. It was concluded that immune responses in mice were modified by cinnarizine.