Anti-Qa-2-induced T cell activation. The parameters of activation, the definition of mitogenic and nonmitogenic antibodies, and the differential effects on CD4+ vs CD8+ T cells

The MHC Ag Qa-2 is a glycolipid anchored class I molecule expressed at high levels on all peripheral T lymphocytes. In this study we found that anti-Qa-2 antibodies could stimulate the proliferation of murine T cells in vitro. Anti-Qa-2-induced proliferation required secondary cross-linking with anti-Ig antibody and the presence of PMA. Only Qa-2+ strains could be induced to proliferate by anti-Qa-2 antibody, but under the conditions employed, anti-CD3 could induce proliferation in Qa-2+ and Qa-2-strains. Interestingly, only anti-Qa-2 reagents directed against the alpha 3 domain of the Qa-2 class I molecule were effective in inducing proliferation. Furthermore, unlike purified CD4+ cells, purified CD8+ cells were unable to be stimulated by the anti-Qa-2 antibodies. These results lead to the inclusion of Qa-2 in a group of physiologically relevant, glycolipid-anchored, cell-surface molecules, mobilization of which can generate signals that initiate the proliferation of T cells. Such molecules may play a secondary role in cellular activation after the primary engagement of the TCR.     

The regulation of resistance to Schistosoma mansoni by auto-anti-idiotypic immunity. III. An analysis of effects on epitopic recognition, idiotypic expression, and anti-idiotypic reactivity at the clonal level.

Auto-anti-idiotypic mechanisms can regulate the protective immune response against Schistosoma mansoni. Anti-idiotypic responses were stimulated by immunization of mice either with nonspecifically induced lymphoblasts, produced with Con A, or with Ag-induced lymphoblasts bearing specific idiotypic receptors. The effect of the induced anti-idiotypic response upon clonotypic cellular reactivity was assessed in vitro through the suppression of antigen-mediated blast transformation by cloned T cells and in vivo by suppression of resistance to S. mansoni and delayed-type hypersensitivity responses against specific Ag. Differential regulation of humoral immune responses was studied at the levels of specific epitopic recognition, the expression of specific Id, and the production of anti-idiotypic responses directed against mAb bearing specific Id. Anti-idiotypic sensitization resulted in variable (10 to 90%) suppression of the immune response to discrete antigenic epitopes, the expression of specific idiotypic phenotypes, and anti-idiotypic, antiparatopic responses against T cell clonotypes and antibody idiotypic phenotypes. In vitro admixture and in vivo challenge studies resulted in consonant differential suppression. Thus idiotypic regulation can mold the fine specificities of the protective immune response to S. mansoni at the clonal level and may provide an approach to optimize the expression and assessment of resistance.     

Correlation of Qa-1 determinants defined by antisera and by cytotoxic T lymphocytes

Cytotoxic T lymphocytes (CTL) activated in H-2 identical, Qa-1 disparate mixed leukocyte cultures recognize H-2-nonrestricted target antigens indistinguishable by strain or tissue distribution from serologically defined Qa-1 antigens. Cloned Qa-l-specific CTL define determinants encoded by four Qa-1 genotypes; we used anti-Qa-1 sera in antibody blocking experiments to determine if these determinants reside on molecules recognized by Qa-1-specific antibodies. Antisera containing Qa-1.1-specific and TL-specific antibodies blocked recognition of two CTL-defined determinants associated with Qa-1 ^a . Although both Qa-1 and TL molecules are expressed on activated T cells from appropriate strains, our studies indicated that the CTL recognized Qa-1, not TL. In addition, anti-Qa-1.2 serum inhibited CTL recognition of Qa-1^b- and Qa-1^c-encoded determinants. Qa-1 ^d target cells are unique in that they express determinants recognized by anti-Qa-1^a CTL and by anti-Qa-1^b CTL. Killing of Qa-1 ^d targets by anti-Qa-1^a CTL was not inhibited by anti-Qa-1.1 serum, but was partially inhibited by anti-Qa-1.2 serum. Cytotoxicity of Qa-1 ^d cells by one anti-Qa-1^b CTL clone was inhibited by both anti-Qa-1.2 and anti-Qa-1.1 sera, indicating close association of both serological determinants with the determinants recognized by the CTL. Thus, all of the CTL-defined Qa-1 determinants resided on molecules recognized by Qa-1-specific antibodies, but anti-Qa-1^a CTL and Qa-1.1-specific antibodies did not have identical specificities.Abbreviations used in this paper B6 C57BL/6J - CAB concanavalin A stimulated lymphoblasts - CML cell-mediated lympholysis - CTL cytotoxic T lymphocyte - NMS normal mouse serum - MHC major histocompatibility complex - MLC mixed leukocyte culture - MR maximum release - SMDM supplemented Mishell-Dutton medium - SR spontaneous release     

Suppression of Ia-unrestricted primary anti-Qa-1 cytotoxic T lymphocyte responses by class II major histocompatibility complex-restricted cellular interactions

A model has been established for investigating the cellular interactions for the generation and regulation of primary cytotoxic T lymphocyte (CTL) responses to Qa-1 alloantigens. Although NZB anti-BALB/c one-way mixed leukocyte cultures (MLC) generate anti-Qa-1b CTL, anti-Qa-1 CTL responses are not generated during BALB/c anti-NZB one-way MLC or during two-way MLC with NZB and BALB/c spleen cells. However, depletion of L3T4+ cells from the spleens of BALB/c mice before two-way MLC with NZB spleen cells resulted in anti-Qa-1b CTL responses. Likewise, the addition of anti-L3T4 monoclonal antibody (mAb) or anti-I-Ad mAb to two-way MLC with NZB and BALB/c spleen cells resulted in the generation of anti-Qa-1b CTL. Conversely, anti-Lyt-2 mAb inhibited the generation of anti-Qa-1 CTL. These data indicate that class II major histocompatibility complex-restricted cellular interactions are capable of suppressing the generation of Ia-unrestricted anti-Qa-1 CTL responses by Lyt-2+ responder cells. This model provides a novel opportunity to both characterize the cellular interactions responsible for regulating primary CTL responses to the Qa/Tla-encoded class I molecule Qa-1, and determine the contribution of this L3T4+ Ts-dependent defect in NZB mice to the pathogenesis of autoimmunity.     

B-cell-mediated regulation of delayed-type hypersensitivity

We obtained immune sera from mice which received suppressor B cells induced in vitro, injected them into immunized mice, and measured suppression of the delayed-type hypersensitivity (DTH) of these recipient mice. In the recipients, effector-phase suppressor T (Ts) cells were induced, and the action of these Ts cells was antigen-nonspecific. The suppressive material of the sera was adsorbed on a Sepharose column coated with anti-mouse immunoglobulin antibody and acid elution of the column yielded the elute fraction that showed significant suppressive activity. The suppressive activity of the sera was also adsorbed by an antigen-coated Sepharose column, and the eluate from the column had suppressive activity. Moreover, we established antigen-specific monoclonal antibodies, some of which suppressed the DTH in an H-2-nonrestricted way. The isotype or specificity of the antibodies was not related to the suppression, because suppressive and nonsuppressive antibodies belonged to the same immunoglobulin isotype and because the antibodies that recognized the same epitope had different suppressive activities. The Fc portion was not the functional site, because the F(ab')2 fragment had the activity. The suppressive antibody induced effector-phase Ts cells, which had the anti-idiotypic receptor. These findings suggested that antigen-specific antibodies in the immune sera mediated the suppression of DTH by the induction of effector-phase Ts cells in vivo and the idiotype of the antibody stimulated the anti-idiotypic receptor of these Ts cells.     

Regulation of transplantation immunity in vivo by monoclonal antibodies recognizing host class II restriction elements. II. Effects of anti-Ia immunotherapy on host T cell responses to graft alloantigens

Results of the preceding report demonstrated that in vivo treatment with monoclonal anti-I-A antibodies provided an effective means of prolonging the survival of murine tail skin allografts. The mechanism of antibody action was shown to include the activation of alloantigen-specific suppressor T cells (Ts), although the relationship between Ts expression and graft survival was not determined. This issue was addressed in the current studies through a kinetic analysis of suppressor and effector T cell responses in control and treated allograft recipients. Donor-specific delayed-type hypersensitivity (DTH) and cytotoxic T lymphocyte (CTL) responses were detectable in untreated A/J recipients of B10.A allografts 8 days after transplantation, rising to near maximum levels by day 12. Rejection in these animals occurred by day 11. In contrast, the predominant cellular response of anti-I-A treated animals for 12 days after transplantation was that of transferable suppression, DTH and CTL reactivity not being evident until day 15, coincident with the decay of Ts activity. Rejection in these animals was observed approximately 19 days post-transplant. CTL responsiveness in the latter group could not be reconstituted by the addition of antigen-presenting cells to the secondary in vitro culture system, nor was the CTL deficit due to antibody carry-over. It is considered that the altered expression of effector cell responses to graft alloantigens is due at least in part to the in vivo inhibition of helper T cell activity by anti-I-A-induced Ts, and that rejection in the treated host results from an eventual decline in the functional expression of this regulatory T cell subset.     

Regulation of the cytotoxic T lymphocyte response against Qa-1 alloantigens

Spleen cells from B6.Tlaa (Qa-1a) mice primed against C57BL/6 (Qa-1b) splenocytes in vivo generate Qa-1-specific CTL when rechallenged with Qa-1b Ag in vitro. The addition of unirradiated Qa-1b splenocytes to these cultures inhibits the generation of Qa-1-specific CTL. By using highly purified cell populations, we demonstrate that the only cell population in resting spleen capable of causing this inhibition is NK1.1+. Although resting CD8 cells lack inhibitory activity, purified CD8 cells precultured with Con A and IL-2 inhibit anti-Qa-1 CTL. This inhibition is specific for the Qa-1b Ag expressed on the inhibitor cells, is not due to cold target competition, and is thus similar to that ascribed to veto cells. Although NK cells from resting spleen inhibit the generation of Qa-1-specific CTL, NK cells precultured in the presence of Con A and IL-2 show an approximate 30-fold increase in veto activity. Thus, NK cells represent the most likely cell population for down-regulating anti-self class I-reactive CTL.     

Characterization of T cell proliferative responses induced by anti-Qa-2 monoclonal antibodies.

The MHC class I Qa-2 Ag are attached to the cell surface by a glycanphosphatidylinositol (GPI) anchor. Crosslinking of Qa-2 and several other cell surface Ag attached by the GPI linkage has been shown to lead to cell activation. We have developed 10 new anti-Qa-2 mAb and characterized their capacity to induce proliferation of spleen cells. In the absence of anti-Ig-mediated crosslinking, none of the mAbs alone could induce activation. However, mAb 23.1 which reacts with the alpha 3 domain of Qa-2, when combined with most of the other mAbs (alpha 1, alpha 2 domain reactive), activated cells in the absence of anti-Ig crosslinking. The mAb pair 23.1 plus 24.16 was the most proficient and induced proliferation in the absence of any exogenous second signals. Responses were greatly enhanced and equivalent to those seen with anti-CD3 by the addition of phorbol myristate acetate (PMA). Ionomycin, rIL-2, or rIL-4 also potentiated anti-Qa-2 responses but less efficiently than PMA. Significant strain variation in the magnitude Qa-2-mediated proliferative responses was observed correlating with the levels of Qa-2 expressed on the cell surface. Crosslinking of Qa-2 molecules by the mAb combinations was required because monovalent Fab fragments failed to activate cells. F(ab')2 fragments of mAb 23.1 plus 24.16 induced vigorous proliferation indicating that accessory cell presentation of the mAb via Fc receptors was not required. Immobilized (plate bound) anti-Qa-2 mAb induced proliferation suggesting that the Qa-2 pathway may be distinct from that of other GPI molecules such as Thy-1 and Ly-6. Populations enriched for T cells (approximately 95%) responded as well as whole spleen cells, whereas B lymphocytes failed to proliferate to anti-Qa-2. Both CD4+ and CD8+ cells were activated following crosslinking of Qa-2. Finally, T cell activation mediated by Qa-2 induced elevation of [Ca2+]i, IL-2R expression, and the release of IL-2. These data demonstrate that crosslinking of Qa-2 on T lymphocytes represents a potent pathway for inducing cell activation.     

Cellular requirements for the generation of primary cell-mediated lympholysis responses to Qa-1 antigens

Mixed leukocyte cultures (MLC) between NZB responder spleen cells and Qa-1-disparate stimulator spleen cells were employed to determine the cellular requirements for the generation of primary anti-Qa-1 cell-mediated lympholysis (CML) responses. Although primary anti-Qa-1 cytotoxic lymphocytes (CTL) were generated during H-2-homologous stimulation, anti-Qa-1 CTL were not detectable from MLC in which the stimulators were H-2 allogeneic. Anti-Qa-1 CTL also were not generated from MLC in which the stimulators were semiallogeneic. Thus, H-2 identity between responder and stimulator cells was not sufficient to permit the generation of primary anti-Qa-1 CTL when H-2 disparity was also present. The capacity for H-2 disparity to prevent anti-Qa-1 CML responses was further demonstrated in MLC containing both H-2-allogeneic and H-2-homologous stimulator cells. Therefore, in subsequent studies we employed NZB responders and H-2-homologous, Qa-1-disparate stimulators. When various subpopulations of stimulator cells were studied for their ability to induce anti-Qa-1 CTL, nylon wool-adherent cells were found to be potent stimulators, but nylon wool-nonadherent cells were not. Furthermore, depletion of macrophages from the stimulator population abrogated the generation of anti-Qa-1 CML responses, despite the presence of responder macrophages in the culture. In contrast, all fractionated subpopulations stimulated anti-H-2 CML responses. When macrophage-enriched cells were used as stimulators, anti-Qa-1 CTL could be generated with approximately 80-fold fewer stimulator cells than when unfractionated splenocytes were used as stimulators. These findings indicated that stimulator macrophages were essential for the generation of primary anti-Qa-1 CTL. Direct evidence for macrophage expression of Qa-1-antigens was obtained by using a Qa-1b-specific CTL clone. These studies provide i) the first evidence for Qa-1 expression on macrophages, ii) a basis for comparison of the cellular interactions necessary to generate CTL against H-2K/D-encoded vs Qa-1-encoded class 1 antigens, and iii) a model for investigating the mechanisms responsible for the immunodominance of H-2K/D alloantigens.     

Regulation of primary cytotoxic T lymphocyte responses generated during mixed leukocyte culture with H-2d identical Qa-1-disparate cells

Cytotoxic lymphocyte (CTL) responses are not usually generated during primary mixed leukocyte culture (MLC) with H-2 identical cells. Thus NZB mice are unusual in that their spleen cells do mount CTL responses during primary MLC with H-2d identical stimulator cells; the predominant target antigen for these NZB responses is Qa-1b. Considering the numerous immunoregulatory defects in NZB mice, we postulated that these NZB anti-Qa-1 primary CTL responses were due to an abnormality in T suppressor cell activity. Cellular interactions capable of suppressing NZB anti-Qa-1 primary CTL responses were investigated by using one-way and two-way MLC with spleen cells from NZB mice and other H-2d strains. Although H-2d identical one-way MLC with the use of NZB responders resulted in substantial CTL responses, only minimal CTL responses were detected from two-way MLC with the use of NZB spleen cells plus nonirradiated spleen cells from other H-2d mice. Thus the presence of non-NZB spleen cells in the two-way H-2d identical MLC prevented the generation of NZB CTL. Noncytotoxic mechanisms were implicated in the suppression of the NZB CTL responses during two-way MLC, because only minimal CTL activity was generated when NZB spleen cells were cultured with semiallogeneic, H-2d identical (e.g., NZB X BALB) F1 spleen cells. The observed suppression could be abrogated with as little as 100 rad gamma-irradiation to the non-NZB spleen cells. The phenotype of these highly radiosensitive spleen cells was Thy-1+, Lyt-1+, Lyt-2-, L3T4+. The functional presence of these cells in the spleens of semiallogeneic, H-2d identical F1 mice indicated that their deficiency in NZB mice was a recessive trait. These data suggest that NZB mice lack an L3T4+ cell present in the spleens of normal mice that is capable of suppressing primary anti-Qa-1 CTL responses. This model system should facilitate additional investigations of the cellular interactions and immunoregulatory mechanisms responsible for controlling primary CTL responses against non-H-2K/D class I alloantigens. The model may also provide insight into the immunoregulatory defects of autoimmune NZB mice.     

Inhibition of the T suppressor circuit of delayed-type hypersensitivity by interferon

The effects of electrophoretically pure murine interferon (Mu-IFN-alpha beta) on the T suppressor pathway and on the T effector cell of delayed hypersensitivity (TDH) were investigated in BALB/c mice, in a 2,4-dinitrofluorobenzene (DNFB) contact-sensitivity model. Various T cell subpopulations, suppressor T cells of the afferent (Ts-aff) and efferent (Ts-eff) types, an auxiliary Ts (Ts-aux), as well as TDH were induced, and their function was assessed in transfer experiments. The results were as follows. At a dose of 5 X 10(3) U, IFN was shown to inhibit the Ts-aff response, when given to the donor animal shortly after induction of the Ts-aff subpopulation or when injected into the recipient 2 hr after spleen cell transfer. Pretreatment in vitro with IFN of the splenic cells to be transferred also abolished the Ts-aff response. Similar amounts of IFN were able to inhibit the generation of Ts-eff in the donor animals, whereas 10-fold-higher amounts were needed in vivo or in vitro to block the functional expression of Ts-eff in the recipient animal. Intravenous injection of IFN into recipients of Ts-eff on day 0 and 1 after sensitization inhibited the expression of the Ts-eff transferred 1 day before ear challenge. This suggests that the Ts-aux response required for the TDH suppression by Ts-eff is blocked by IFN. Secretion of a suppressor factor by Ts in vitro was not blocked by IFN. Treatment of the donor of suppressor factor-secreting Ts with IFN, however, blocked the induction of this Ts. The TDH were not sensitive to IFN even at amounts approximately 100 times higher than those used for the Ts inhibition in vivo as well as in vitro. These results demonstrate that low amounts of IFN may selectively block the suppressor pathway, because induction of these regulatory T cell subsets appears to be particularly sensitive to IFN. The exact mechanism of the IFN-mediated inhibition of Ts is not yet clear. The data suggest an important regulatory function of IFN in delayed-type hypersensitivity (DTH) reactions.     

Lymphocyte subsets involved in tumor-activated nonspecific feedback suppression

Cells from the spleen, lymph nodes, and peritoneum of DBA/2 mice bearing a subcutaneous tumor mediate nonspecific suppression of an in vitro antibody response to sheep red blood cells (SRBC) when cocultured with a normal T-cell subset(s). The spleen cells from the tumor-bearing mouse required for the suppression bear the Lyt 1 and Ala 1 surface markers characteristic of "inducer" T cells and activated cells, respectively. The activity of this cell population is also sensitive to irradiation. The normal T-cell subset which cooperates in the suppression bears the Qa-1 surface antigen which has been associated with suppressor cell precursors in several systems but lacks detectable surface Lyt 1 and 2 markers. Suppression of antibody responses in spleen cell cultures from tumor-bearing mice alone could also be elicited, but only when increased numbers of cells were cultured. These data are consistent with the theory that a tumor-activated, Lyt 1+ T-cell subset has the capacity to nonspecifically suppress immune responses by activating a Qa-1+ subset(s) of T suppressor cells, perhaps via feedback signals.     

Clonal analysis of the anti-Qa-1 cytotoxic T lymphocyte repertoire: definition of the Qa-1d and Qa-1c alloantigens and cross-reactivity with H-2

To characterize the four common Qa-1 allelic products, we examined in detail the CTL-defined determinants encoded by Qa-1. In previous studies with anti-Qa-1 CTL and alloantisera, investigators have described antigenic determinants present on Qa-1a and Qa-1b antigens, but they have defined Qa-1c and Qa-1d exclusively by their cross-reactivity with Qa-1a and/or Qa-1b determinants. To delineate further the CTL-defined determinants encoded by Qa-1d, we generated CTL clones with Qa-1d specificity and demonstrated that the Qa-1d molecule expressed determinants that were not detected on Qa-1a, Qa-1b, or Qa-1c target cells. Other CTL clones derived from anti-Qa-1d MLC recognized new antigenic determinants on Qa-1c that cross-reacted with Qa-1d. Each of the four common Qa-1 phenotypes was shown to exhibit unique antigenic determinants. In addition, Qa-1d anti-Qa-1a and Qa-1d anti-Qa-1b CTL confirmed extensive cross-reactivity among these Qa-1 alloantigens. Analysis of CTL from these four immunizations also resulted in the isolation of Qa-1a-specific and Qa-1d-specific CTL clones that cross-reacted with H-2Df and H-2Ks, respectively.     

Immunity to herpes simplex virus type 2. Suppression of virus-induced immune responses in ultraviolet B-irradiated mice

Ultraviolet B irradiation (280 to 320 nm) of mice at the site of intradermal infection with herpes simplex virus type 2 increased the severity of the herpes simplex virus type 2 disease and decreased delayed-type hypersensitivity (DTH) responses to viral antigen. Decrease in DTH resulted from the induction of suppressor T cells, as evidenced by the ability of spleen cells from UV-irradiated mice to inhibit DTH and proliferative responses after adoptive transfer. Lymph node cells from UV-irradiated animals did not transfer suppression. DTH was suppressed at the induction but not the expression phase. Suppressor T cells were Lyt-1+, L3T4+, and their activity was antigen-specific. However, after in vitro culture of spleen cells from UV-irradiated mice with herpes simplex virus type 2 antigen, suppressor activity was mediated by Lyt-2+ cells. Culture supernatants contained soluble nonantigen-specific suppressive factors.     

Regulatory action of immune B cells on delayed-type hypersensitivity in mice

Suppressor cells in delayed-type hypersensitivity (DTH) to soluble protein antigens were induced in vitro from BALB/c spleen cells. Transfer of these cells into syngeneic recipients resulted in suppression of the hosts' DTH responses in an antigen-specific manner. These suppressor cells were characterized as B cells by their adherence to nylon-wool columns, resistance to treatment of anti-Thy 1, -Ly 1, and -Ly 2 antibodies plus complement, adherence to anti-mouse immunoglobulin-coated dishes, and nonadherence to uncoated plastic dishes. In addition to being radiation sensitive, these suppressor B cells showed the capability of binding to the primed antigen. Thus, it was demonstrated that our in vitro-induced suppressor cells were antigen-specific B cells. When these suppressor B cells were transferred into the recipients, serum titers of specific antibodies were elevated and effector phase suppressor T cells were induced in the recipients. These results suggest that suppressor B cells exert their suppressor activity through the idiotype-anti-idiotype network.     

The differentiation of cytotoxic T cells in vitro. IV. Interleukin-2 production in primary mixed lymphocyte cultures involves cooperation between Qa-1+ and Qa-1- "helper" T cells

Studies with C57BL/6-TIaa mice have established that both Qa-1+ and Qa-1- helper T cells are required for the optimal production of Interleukin 2(IL-2) activity in primary MLC. This was established both by depletion of Qa-1 bearing cells by treatment of responder cells with anti-Qa-1 serum in the presence of complement and by positive selection (using FACS II analysis) of those cells displaying Qa-1. Furthermore, microfluoremetry revealed that the great majority of C57BL/6-TIaa and of A/J splenic T cells bore Qa-1 alloantigen but that only those with the highest antigen density were susceptible to complement-mediated lysis.     

Suppression of Hen Egg-White Lysozyme (HEL)-Specific Delayed-Type Hypersensitivity Responses in Mice by Suppressor T Cells after Neonatal Administration of Anti-Idiotypic Antibodies

Anti-idiotypic rabbit antiserum (anti-Id) directed to the idiotypes of anti-hen egg-white lysozyme (HEL) antibody from a single C3H mouse (No. 2) was shown to be capable of recognizing only a fraction of the anti-HEL antibody populations produced by other C3H mice. Experiments were performed to examine the effect of this particular anti-Id on the delayed-type hypersensitivity (DTH) response specific for the same protein antigen. A group of 60-day-old C3H mice which had been administered anti-Id within 24 hr after birth were tested for HEL-DTH response. The results indicated that the DTH response was completely suppressed by the anti-Id treatment. The inhibition of DTH reactivity is due to active suppression and involves the generation of suppressor T cells. Thus, the suppression induced with a single injection of anti-Id was transferable with both spleen cells and thymocytes from mice that received anti-Id. These suppressor cells are T cells since their ability to suppress DTH is completely abrogated by treatment in vitro with anti-Thy 1.2 serum and complement.     

Inhibition of the delayed-type hypersensitivity response by staphylococcal enterotoxin B-induced suppressor T cells

Staphylococcal enterotoxin B (SEB) is a member of a family of gram-positive bacterial exotoxins which act as superantigens in both mouse and man. The administration of this toxin has been shown to inhibit antibody responses in vivo. We have previously shown that SEB is a potent inducer in vitro of multiple T suppressor cell populations. The present studies show that administration of microgram quantities of this toxin result in a reduced capacity to manifest a delayed-type hypersensitivity (DTH) response. In addition, we find that the failure to generate a normal DTH response appears to be due to the generation of a T suppressor cell population following SEB administration. Adoptive transfer studies show that the suppressor cells bear the CD5+ I-J+ CD4- CD8- Thy 1+ surface phenotype. The relationship of these cells to suppressor T cell populations generated following in vitro activation by SEB is discussed.     

Low dose ultraviolet B-irradiated Langerhans cells preferentially activate CD4+ cells of the T helper 2 subset

UVB radiation distorts the Ag-presenting function of epidermal Langerhans cells (LC); this has been shown for the presentation of soluble Ag to primed T cells in vitro and for the initiation of delayed-type hypersensitivity in vivo, such as contact hypersensitivity (CH). Previous work has also demonstrated UVB-induced suppression of CH to be mediated ultimately by T cells. Two subsets of CD4+ Th cells, Th1 and Th2, have been identified, based on their cytokine production and functional activities. In particular, Th1 mediate delayed-type hypersensitivity, whereas Th2 do not. To investigate whether the perturbation of LC function induced by UVB radiation leads to a differential activation of these subsets of CD4+ cells, we examined the capacity of unirradiated and irradiated (200 J/m2) APC from adult BALB/c mice to present keyhole limpet hemocyanin to Ag-specific, H2d-restricted Th1 and Th2 cell lines. Four sources of APC were utilized: epidermal cells (EC), flow microfluorometry-purified Ia+ EC (LC), flow microfluorometry-purified Ia- EC, and splenic adherent cells (SAC). Unirradiated EC, LC, and SAC, but not Ia-EC, presented keyhole limpet hemocyanin to both Th1 and Th2. Irradiated EC and LC lost their ability to stimulate Th1, but retained fully their capacity to stimulate Th2. On the other hand, irradiated SAC were unable to induce proliferation of either Th1 or Th2. These findings indicate that suppression of CH mediated by UVB-irradiated LC may result from an alteration of the ratio and/or activity of Th1 and Th2 cells normally generated during the induction of such responses.     

Differential influence of 2'-deoxyguanosine on the induction and expression of suppressor T lymphocytes in vivo

Subcutaneous (sc) immunization of mice with allogeneic spleen cells can induce delayed-type hypersensitivity (DTH) to histocompatibility antigens. Intravenous immunization with irradiated allogeneic spleen cells, on the other hand, induces suppressor T (Ts) lymphocytes. These Ts cells are capable of suppressing the host-versus-graft (HvG) DTH reactivity which normally arises after sc immunization. Moreover they can suppress the development of antihost DTH effector T cells during graft-versus-host (GvH) reactions. These models for HvG and GvH DTH reactivity were used to study the influence of 2'-deoxyguanosine (dGuo) on the induction, further development, and expression of Ts cells in vivo. It was found that administration of dGuo inhibits the proliferation-dependent induction and further development of Ts cells, but not the suppression mediated by already activated Ts cells.