Regulation of delayed-type hypersensitivity. I. T suppressor cells for delayed-type hypersensitivity to sheep erythrocytes in mice.

Mice injected with 1 X 10(8) sheep red blood cells (SRBC) into the footpad showed high levels of delayed-type hypersensitivity (DTH) to SRBC 4-8 days after the injection. In contrast, mice injected intravenously with 1 X 10(9) SRBC were unresponsive to DTH induction through 1 X 10(8) SRBC injected into the footpad. This suppression of DTH was maintained for at least 6 weeks and was transferable spleen, lymph node and thymus cells to normal syngeneic recipients. Bone marrow cells, on the other hand, did not contain the suppressor cells. The suppression of DTH was antigen-specific in that DTH to chicken red blood cells and contact sensitivity to 2,4-dinitrofluorobenzene was not affected. The suppressor cells were theta-positive and Ig-negative. They appeared in the spleen in optimum number 3-4 days after induction. The suppressor cells affected both the induction and manifestation of DTH. The presence of suppressor and effector cells for DTH inducible by different routes of antigenic presentation reflects the dynamic balance in the regulation of DTH.     

Characterization of a cell population which amplifies the anticryptococcal delayed-type hypersensitivity response.

Cell-mediated immunity to Cryptococcus neoformans can be detected by delayed-type hypersensitivity (DTH) to a culture filtrate antigen of C. neoformans. Recently, we have identified a population of cells in spleens of mice immunized with cryptococcal antigen that, when transferred to recipient mice at the time of immunization, amplifies the anticryptococcal DTH response. If the cell donor mice are treated with cyclosporin A during induction of the anticryptococcal DTH response, the amplifier cells are not induced, whereas the cells which transfer DTH (TDH cells) are induced. The purpose of this study was to characterize the amplifier cells with respect to their surface and functional properties and, in so doing, determine whether or not the amplifier cells are analogous to long-lived memory cells. We demonstrated that the amplifier cells were nylon-wool-nonadherent, antigen-specific, CD4 (L3T4+ Lyt-2-) T lymphocytes which appear in the spleens of mice 5 days postimmunization with cryptococcal culture filtrate antigen in complete Freund adjuvant. The amplifier T (Tamp) cells are not considered to be memory cells because they are relatively short-lived, being present 14 but not 18 days after the stimulating immunization. Moreover, the amplified anticryptococcal DTH response does not fulfill the criteria of the typical secondary immune (anamnestic) response in that the amplified response does not appear early relative to the appearance of the primary anticryptococcal DTH response, and it does not persist longer than the primary DTH response. We speculate that Tamp cells are not long-lived memory cells but rather act in a T-helper cell capacity to amplify the anticryptococcal DTH response.     

Regulation of cytokine production during the expression phase of the anticryptococcal delayed-type hypersensitivity response.

Effects of both positive and negative regulatory T cells on cellular infiltration and cytokine production during the expression phase of the anticryptococcal immune response were examined. Tamp cells, which are induced by cryptococcal antigen, significantly amplify the anticryptococcal delayed-type hypersensitivity response, whereas a cascade of T suppressor (Ts) cells inhibits the response and decreases the clearance of Cryptococcus neoformans during an infection. By using the gelatin sponge implantation model, we found that Tamp cells do not stimulate a significant increase in cellular infiltration into the sponges in response to cryptococcal antigen compared with that into delayed-type hypersensitivity-reactive sponges in immune control mice. However, Tamp cells do stimulate significant increases in the production of gamma interferon and interleukin-2 (IL-2) in the antigen-injected sponges over the level of the representative cytokine in antigen-injected sponges from the immune control mice. Likewise, Ts1 cells, induced with cryptococcal antigen, do not significantly affect antigen-induced cellular infiltration into sponges in immune mice. In contrast, decreased levels of gamma interferon and IL-2 are observed in antigen-injected sponges from Ts1-cell-recipient, immunized mice compared with those of the positive immune controls. The presence of either Tamp or Ts1 cells in immunized mice stimulates increased production of IL-5 but not IL-4 over that of the positive immune controls.     

Characterization of an in vitro-stimulated, Cryptococcus neoformans-specific second-order suppressor T cell and its precursor.

Using a cryptococcal culture filtrate antigen (CneF) in a murine model, we have demonstrated previously that a cascade of Cryptococcus neoformans-specific suppressor T cells and soluble factors function in suppressing the cryptococcal delayed-type hypersensitivity (DTH) response. In addition, we have successfully hybridized the C. neoformans-specific, first-order T-suppressor (Ts1) cell and have established that the culture supernatant (hTsF1) from this hybridoma induces second-order T-suppressor (Ts2) cells in vivo. Here we report the in vitro induction of expression-phase suppressor cells. The suppressor cells were induced by culturing nylon wool-nonadherent splenic cells from naive mice with hTsF1 in the absence of CneF. Nylon wool-nonadherent splenic cells similarly cultured with supernatants from the BW5147 thymoma cells, the fusion partners of the hybridoma, did not significantly suppress the cryptococcal DTH response. The suppressor cells were designated Ts2 cells based on their similarities in function, specificity, and phenotype, i.e. L3T4-, Lyt-2+, and I-J+, to the in vivo-induced Ts2 cells. By employing the in vitro culture technique, we demonstrated that the precursors of the functional Ts2 cells were L3T4- Lyt-1-2+ I-J- cells. The induction of Ts2 cells was not associated with [3H]thymidine incorporation; therefore, we concluded that hTsF1 induces the Lyt-2+ I-J- cells to differentiate into Lyt-2+ I-J+ functional Ts2 cells without a significant amount of proliferation. From the results of this study, a better understanding of the processes involved in the regulation of the DTH response to CneF was achieved. The in vitro culture technique will allow for further detailed studies of the interactions between the various cell populations and the Ts1 cell-derived soluble factor during the induction of Ts2 cells.     

Regulation of delayed-type hypersensitivity. III. Effect of cyclophosphamide on the suppressor cells for delayed-type hypersensitivity to sheep erythrocytes in mice.

A previous study (Eur. J. Immunol. 1977. 7: 714) has shown that mice injected intravenously (i.v.) with 4 x10(9) sheep red blood cells (SRBC) produce cells which suppress delayed-type hypersensitivity (DTH). These suppressor cells are theta-positive, antigen-specific and act via a soluble factor which does not bear immunoglobulin determinants (Eur. J. Immunol. 1978. 8: 168). The present paper demonstrates that these suppressor cells are inhibitable by cyclophosphamide (CY). Mice injected with graded amounts of CY two days prior to SRBC injection, showed maximum augmentation of DTH at 200 mg/kg body weight, a dose which completely suppressed the appearance of splenic plaque-forming cells (PFC) to SRBC. In contrast, lower doses of CY enhanced both DTH and PFC responses. Time course studies showed that CY inhibited the precursors of suppressor cells and had little or no effect on suppressor cells which have already encountered antigens. This was further confirmed by passive transfer studies which showed tha- suppressor cells were inhibited if CY was administered at the same time or 2 days before SRBC injection, but were not affected if CY was given after antigen stimulation. Direct evidence for the effect of CY on suppressor cells was obtained by cell fractination with a Ficoll density gradient. The denser suppressor cell population was absent from the spleens of mice treated with 200 mg/kg of CY 2 days before i.v. injection with 1 x 10(9) SRBC.     

Specific suppressor T cells for delayed-type hypersensitivity in susceptible mice immunized against cutaneous leishmaniasis.

BALB/c mice injected intravenously with 10(6) or higher doses of formaldehyde-fixed promastigotes (ffp) of Leishmania major developed significantly lower levels of delayed-type hypersensitivity (DTH) compared with uninjected control mice when they were subsequently immunized intradermally with ffp. The suppression of DTH was antigen specific and was also inducible with lethally irradiated promastigotes or soluble parasite antigens. The suppressive effect was adoptively transferable with splenic T cells which express the Lyt-1+2+ and L3T4+ phenotypes. These specific suppressor T cells were active against both the inductive and expressive phases of DTH. They were sensitive to 200 rads of gamma-irradiation in vitro and appeared to manifest the suppressive activity via soluble factors. In spite of this profound suppression of DTH, BALB/c mice injected intravenously with 4 X 10(7) ffp were substantially protected against a challenge infection with L. major promastigotes. The possible relationship between the suppressor T cells for DTH and prophylactic immunization against fatal cutaneous leishmanial infection in susceptible BALB/c mice is discussed.     

Junin virus-induced suppressor cells are effective only on the efferent limb of the delayed-type hypersensitivity response

Junin virus (JV), the etiological agent of Argentinian hemorrhagic fever, induces high mortality in the suckling BALB/c mouse, which correlates with delayed-type hypersensitivity (DTH)-like immune response. In contrast, the adult mouse is resistant to infection, and no DTH response can be detected. An antigen-nonspecific DTH suppressor T-cell activity induced by JV has been described that may be related to adult mouse survival. In this report, we present evidence supporting the inability of such cells, identified here as bearing the L3T4 marker, to affect the normal establishment of a DTH reaction. In the same form, virus-induced suppressor cells were unable to alter the expression of DTH effector cells in the absence of antigen-specific DTH suppressor cells. Besides, we found that a single high dose (200 mg/kg) of cyclophosphamide before or after JV inoculation was unable to alter the activity of virus-induced suppressor cells.     

Characterization of cellular infiltrates and cytokine production during the expression phase of the anticryptococcal delayed-type hypersensitivity response.

Cryptococcosis, an increasingly important opportunistic infection caused by the encapsulated yeast-like organism Cryptococcus neoformans, is limited by an anticryptococcal cell-mediated immune (CMI) response. Gaining a thorough understanding of the complex anticryptococcal CMI response is essential for developing means of controlling infections with C. neoformans. The murine cryptococcosis model utilizing footpad swelling to cryptococcal antigen (delayed-type hypersensitivity [DTH]) has proven to be a valuable tool for studying the induction and regulation of the anticryptococcal CMI response, but this technique has limitations with regard to evaluating the role of the final effector cells recruited by an ongoing CMI response. The purpose of this study was to assess the types of cells and cytokines induced into the site of cryptococcal antigen deposition in C. neoformans-infected and -immunized mice compared with those for control mice. We used a gelatin sponge implant model to examine the cells and cytokines present at the site of an anticryptococcal DTH response. Sponges implanted in infected mice and injected with cryptococcal culture filtrate antigen (CneF) 24 h before assessment had significantly increased numbers of infiltrating leukocytes compared with saline-injected sponges in the same animals. Exaggerated influxes of neutrophils and mononuclear cells were the major contributors to the increase in total numbers of cells in the DTH-reactive sponges. The numbers of CD4+ and LFA-1+ cells were found to be significantly increased in the CneF-injected sponges of infected and immunized mice over the numbers in control sponges. The numbers of large granular lymphocytes were also increased in DTH-reactive sponges compared with control sponges. Gamma interferon, interleukin 2 (IL-2), and IL-5 are clearly relevant cytokines in the anticryptococcal CMI response, since they were produced in greater amounts in the CneF-injected sponges from C. neoformans-infected and -immunized mice than in control sponges. IL-4 was not associated with the expression of DTH to cryptococcal antigen. The gelatin sponge model is an excellent tool for studying cells and cytokines involved in specific CMI responses.     

Two types of suppressor T cells that inhibit delayed-type hypersensitivity to Mycobacterium intracellulare in mice.

Mycobacterium intracellulare Mino grows progressively in the organs of C57BL/6 mice. When C57BL/6 mice were injected with strain Mino, very weak or almost no delayed-type hypersensitivity (DTH) to the specific antigen, M. intracellulare purified protein derivative, was observed. The DTH response was enhanced by cyclophosphamide pretreatment, indicating that some suppression mechanism(s) might be involved in DTH. In cell transfer experiments it was shown that two types of suppressor T cells, afferent type (TS-Aff) and efferent type (TS-Eff), are induced in the spleens of Mino-infected mice. TS-Aff were detected from the early stage to the late stage of infection. TS-Eff were detected only in the late stage of infection. These two types of suppressor T cells were both Thy-1 positive and Lyt-2 positive; however, TS-Aff seemed to be I-J positive, and TS-Eff seemed to be I-J negative. Cross-reactivity in suppression was observed between Mino and Mycobacterium bovis BCG but not between Mino and sheep erythrocytes. DTH to Mino and BCG was not cross-reactive. The possible role of suppressor T cells in M. intracellulare infection is discussed.     

Antigen-specific suppressor factors produced by T cell hybridomas for delayed-type hypersensitivity.

This study describes the generation of T hybridoma lines which secret factors specifically suppressing delayed-type hypersensitivity (DTH) to sheep red blood cells (SRBC). AKR strain-derived T lymphoma BW 5147 cells were fused with spleen cells from mice primed with SRBC and containing antigen-specific T suppressor cells for DTH. Supernants from the derived hybridomas were tested for suppression of either expression of induction of DTH to SRBC. Six lines produced specific suppressor activity for the expression of DTH; 4 lines produced suppressor activity for the induction of DTH of which only one line was antigen-specific. These lines were passaged in normal AKR mice, and the serum obtained had activity up to 10(-4) dilution. The factor was effective across the H-2 barrier.     

Induction of suppressor T cells in delayed-type hypersensitivity to Mycobacterium bovis BCG in low-responder mice.

The induction of delayed-type hypersensitivity to Mycobacterium bovis BCG was specifically inhibited by suppressor T cells in C3H/He, a strain of mice which is a low responder to BCG. The existence of these suppressor cells was confirmed by an adoptive transfer of spleen cells of BCG-injected mice into cyclophosphamide-treated recipients. The suppressor cells appeared in the spleens of the mice 2 to 7 days after intravenous BCG injection. They were sensitive to anti-theta serum and complement and did not adhere to Sephadex G-10. A pretreatment of the mice with cyclophosphamide eliminated the suppression of delayed-type hypersensitivity. These suppressor cells effectively inhibited the induction of delayed-type hypersensitivity to BCG, but showed only weak effect on the expression of it.     

Differential sensitivity to cyclophosphamide of helper T cells for humoral responses and suppressor T cells for delayed-type hypersensitivity

The relative sensitivity to cyclophosphamide (CY) of helper T cells in antibody responses and of suppressor T cells in delayed-type hypersensitivity (DTH) responses against sheep red blood cells (SRBC) was measured by pretreating cell suspensions in vitro with the microsomally activated form of CY and evaluating their subsequent function in transfer experiments. It was found that suppressor T cells involved in DTH responses were sensitive to much lower concentrations of activated CY than were helper T cells for anti-SRBC antibody responses. Since the cytotoxic activity of CY is thought to be dependent on its ability to alkylate nuclear DNA, the differential sensitivity observed may be more easily explicable in terms of additional secondary enzyme-mediated degradation or DNA repair mechanisms.     

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.     

Regulation of delayed-type hypersensitivity. VII. The role of I-J subregion gene products in the inhibition of delayed-type hypersensitivity to major histocompatibility antigens by specific suppressor T cells

Suppressor T cells for delayed-type hypersensitivity (DTH) to alloantigens are induced by injecting mice intravenously with a high dose of X-irradiated allogeneic cells. Using the same protocol, suppression of DTH directed against H-2 subregion products could also be induced, provided that the H-2 incompatibility between the cells used for the induction of suppression and the recipients includes the I-J subregion genes. Thus, the I-J subregion difference is both necessary and sufficient for the induction of suppression of DTH to the whole or part of the H-2 gene products. The suppression appears to be mediated by antigen-specific suppressor T cells which recognize the allo-I-J molecules and are able to suppress the DTH response to other H-2 subregion gene products in an associative recognition manner. T cells from (B10 × BALB/c)F₁ mice suppressively primed against B10.A(5R) cells (directed against J^kE^k antigens), when adoptively transferred to normal syngeneic recipients, were capable of suppressing the hosts' DTH response to B10.A(4R) cells (K^kA^k antigens) when the recipients were challenged with [B10.A(4R) × B10.A(5R)]F₁ cells (K^kA^k × J^kE^k). The recipients express normal DTH reactivity to B10.A(4R) cells when challenged with a mixture of B10.A(4R) and B10.A(5R) cells (K^kA^k + J^kE^k). These results provide direct evidence that when functioning as alloantigens, the I-J determinants preferentially induce suppressor T cells which specifically impair the immune response to the I-J molecules as well as other H-2 gene products if they are physically associated with the I-J determinants. The role of I-J subregions as the suppressor genes is discussed in terms of the possible application in transplantation immunity and the host's defence against infectious diseases.     

Killed Listeria-induced suppressor T cells involved in suppression of delayed-type hypersensitivity and protection against Listeria infection.

Pretreatment of mice by intravenous injection with killed Listeria provided neither delayed-type hypersensitivity to Listeria protoplasm nor protection against Listeria infection. Assuming that this suppression is due to suppressor cells, we attempted to clarify their induction and characterization. Pretreatment with killed BCG instead of killed Listeria suppressed the induction of DTH and protection in subsequent Listeria-immunized mice. Conversely, pretreatment with killed Listeria suppressed subsequent induction of DTH to PPD or protection from tuberculosis. Thus, these suppressions were induced antigen nonspecifically. Transfer of splenic non-adherent cells from killed Listeria-injected mice which had been treated with anti-BA theta serum plus complement, or had been passed through Sephadex G-10 columns, resulted in both afferent and efferent DTH suppression, suggesting that the DTH suppression is closely associated with suppressor T cells. Moreover, the splenic nonadherent cells from killed Listeria-injected mice showed suppression in vitro of listericidal activity of PEC from Listeria-immune mice in the presence of Listeria protoplasm.     

Characterisation of cyclosporine-induced suppressor cells in murine delayed-type hypersensitivity responses

The effect of Cyclosporine A (CsA) on T cell-mediated delayed-type hypersensitivity (DTH) reactions to murine alloantigens was analysed by transferring spleen cells from sensitised and suppressed mice into irradiated naive recipients. Selective removal of Thy1+, Ly1+ or Ly2+ cells prior to intravenous transfer of cells from alloantigen-sensitised mice showed that Ly1+ Thy1+ cells transferred sensitivity. Concomitant treatment of mice with alloantigen and CsA suppressed the DTH response to alloantigens, and spleen cells transferred from these suppressed mice abrogated the response of sensitised cells transferred at the same time. The suppressor cells were strain-restricted and antigen-specific with the surface phenotype Thy1+, Ly1-Ly2+.     

Naive T cells can mediate delayed-type hypersensitivity response in T cell receptor transgenic mice

We produced transgenic mice expressing Tcell receptor-αβ chain genes, derived from the chicken ovalbumin (OVA)-specific I-A^d-restricted CD4⁺CD8^? T helper cell clone 7–3–7. In transgenic mice with H-2^d genetic background (Tg-d mice), delayed-type hypersensitivity (DTH) was induced in the hind footpad by one inoculation with OVA without any previous sensitization, suggesting that naive T cells have the potential to be involved in DTH response. Spleen cells from nonimmunized Tg-d mice showed a strong T cell proliferative response to in vitro stimulation with OVA. Furthermore, these spleen cells produce cytokines including interleukin(IL)-2, IL-3, interferon-γ, granulocyte/macrophage colony-stimulating factor, macrophage inflammatory protein (MIP)-1α and MIP-1β, which may play an important role in the attraction of mononuclear cells to an antigen-challenging site.     

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.     

Immunoregulation of lysozyme-specific suppression. II. Hen egg-white lysozyme-specific monoclonal suppressor T cell factor suppresses the afferent phase of delayed-type hypersensitivity and induces second-order suppressor T cells

Culture supernatant from a monoclonal T cell lymphoma line (LH8-105) obtained by radiation leukemia virus-induced transformation of hen egg-white lysozyme (HEL)-specific suppressor T lymphocytes is able, when injected into mice, to specifically suppress the delayed-type hypersensitivity (DTH) reaction induced by HEL. The suppressor T cell factor (TsF) exhibits fine antigenic specificity since it suppresses the DTH response induced by HEL without affecting the DTH response induced by ring-necked pheasant egg-white lysozyme (REL), a lysozyme closely related to HEL. Conversely, LH8-105 TsF is able to suppress the DTH response induced by human lysozyme, distantly related to HEL but sharing a common epitope critical for induction of suppressive activity. The fine antigenic specificity of LH8-105 TsF for a restricted epitope on the HEL molecule is confirmed by binding to HEL but not to REL immunosorbents. This TsF also bears I-J determinants, as demonstrated by binding to monoclonal anti-I-J immunosorbents, and it suppresses the afferent but not the efferent phase of the DTH response to HEL. The afferent suppression is controlled by genes apparently mapping in the I-J subregion of the H-2 complex since I-J-incompatible mice are not suppressed by LH8-105 TsF injection. This inducer-type TsF induces second-order effector suppressor T cells only in HEL-primed mice indicating the primary role of antigen, in association with H-2 (I-J) products, in the afferent portion of this suppressive circuit.