Autoimmune effector cells. III. Role of adjuvant and accessory cells in the in vitro induction of autoimmune encephalomyelitis

The present investigation shows that autoreactive effector cells that transfer experimental allergic encephalomyelitis (EAE) can be activated from spleens and lymph nodes of Lewis rats given a single injection of 25 micrograms myelin basic protein (BP) in incomplete Freund's adjuvant (IFA), despite the fact that the cell donors do not develop EAE. Rather, these donor rats are unresponsive to EAE when given an encephalitogenic emulsion of BP in complete Freund's adjuvant (CFA). Lymphoid cells from rats given a single injection of BP-IFA were almost as effective as cells from BP-CFA-treated rats with respect to transferring EAE after in vitro activation with BP or concanavalin A (Con A). Irrespective of whether donors received BP in IFA or CFA, BP-cultured spleen and lymph node cells (SpC and LNC, respectively) transferred EAE, whereas Con A-cultured SpC but not LNC exhibited effector cell activity. Con A-cultured LNC were able to transfer EAE if the cultures were reconstituted with irradiated adherent phagocytic cells (which could be obtained from normal Lewis rat spleens) or with conditioned medium from these adherent SpC. These findings indicate that accessory cells are required for in vitro induction of this T cell-mediated autoimmune response.     

Immunosuppression of experimental allergic encephalomyelitis. III. In vitro evidence for induction of suppressor T lymphocytes in draining lymph node cells of animals immunized with myelin basic protein complexed to lipopolysaccharides

We recently demonstrated that Lewis rats immunized with bacterial lipopolysaccharides (LPS) precomplexed to guinea pig myelin basic protein (BP) in complete Freund's adjuvant were less effective in inducing experimental allergic encephalomyelitis (EAE) than BP-immunized controls. When tested in vitro both lymph node cells (LNC) and spleen cells (SpC) of animals immunized with BP-LPS were less effective in proliferative responses to various mitogens, which included phytohemagglutinin, concanavalin A, purified protein derivative of tuberculin, LPS, and BP. Of importance immunization of rats with BP complexed to LPS results in the generation of cells in lymph nodes of these animals that suppress the mitogenic response of BP-immunized LNC and also SpC in mixed lymphocyte cultures. The suppressive effect of these cells in mixed lymphocyte culture reaction was found specifically in response to BP and to a lesser extent to LPS in LNC. SpC of BP-LPS immunized animals did not suppress the proliferative response to SpC of BP-immunized animals. Treatment of these LNC with antithymocyte serum and complement abolished this suppressive effect of LNC, suggesting that the immunoregulatory cells in LNC of BP-LPS immunized animals are suppressor T lymphocytes. The parallel between the in vitro induction of suppressor T lymphocytes in the draining LNC and the function of LPS in the development of EAE in Lewis rats suggests a possible immunologic significance of the effect.     

Antigen-specific inhibition of immune interferon production by suppressor cells of autoimmune encephalomyelitis

Previous work from this laboratory has revealed that spleen and/or lymph node cells from Lewis rats, that have recovered from an acute episode of experimental autoimmune encephalomyelitis (EAE), suppress the development of EAE when injected into syngeneic recipients subsequently challenged with myelin basic protein (MBP) in CFA. In an effort to understand the mechanism of this suppression, we measured the production of immune IFN-gamma, which may be required for the induction of an immune response, by EAE effector T cells (which transfer disease) and EAE suppressor cells when cultured in vitro with MBP. We now report that EAE effector T cells produce IFN-gamma when cultured in vitro with MBP. In contrast, spleen cells from recovered rats (which manifest suppressor activity in vivo) do not produce IFN-gamma. Moreover, in cell mixing experiments, these suppressor spleen cells inhibited the production of IFN-gamma by EAE effector cells. This inhibition was not eliminated by the removal of macrophages nor by the inhibition of PG synthesis by indomethacin. Furthermore, the inhibition was shown to be Ag-specific and mediated by nylon-adherent, radiation-sensitive splenic T cells. The findings suggest that suppressor cells regulate EAE by inhibiting IFN-gamma production by effector cells. This inhibition may result in the down-regulation of IFN-gamma-induced expression of class II major histocompatibility Ag on cells of the central nervous system, thus reducing the presentation of tissue-specific Ag (i.e., MBP) to autoreactive lymphocytes.     

Suppressor cell control of unresponsiveness to experimental allergic encephalomyelitis.

Lymph node cells (LNC) from Lewis rats rendered unresponsive to experimental allergic encephalomyelitis (EAE) by pretreatment with myelin basic protein markedly suppressed clinical (but not histologic) EAE in normal recipients later challenged with an encephalitogenic emulsion. Unresponsiveness was immunologically specific, and required viable LNC; serum transfer was ineffective. These findings suggest that suppressor cells exert control over this autoimmune disease.     

Interleukin 1 and myelin basic protein synergistically augment adoptive transfer activity of lymphocytes mediating experimental autoimmune encephalomyelitis in Lewis rats

This investigation focused on the role of adherent accessory cells and their cellular product, interleukin 1 (IL 1), in cellular immune responses associated with experimental autoimmune encephalomyelitis (EAE) in Lewis rats. Guinea pig myelin basic protein (GPMBP)-sensitized lymph node cells (LNC) responded in culture with GPMBP by undergoing activation as measured by augmented transfer of EAE to syngeneic recipients, and proliferation as measured by [3H]thymidine incorporation. GPMBP-sensitized LNC, after depletion of adherent accessory cells, no longer responded to GPMBP in the EAE transfer activation assay. In contrast, aliquots of the same LNC preparation exhibited proliferative responses to GPMBP that were only partially reduced. Addition of irradiated thymocytes to adherent cell-depleted cultures fully reconstituted responsiveness to GPMBP in the activation assay and restored full reactivity to GPMBP in the proliferation assay. Furthermore, addition of either purified human IL 1 or recombinant human IL 1 to adherent cell-depleted cultures reconstituted reactivity to GPMBP in the EAE transfer activation assay and augmented GPMBP-specific proliferative responses. Anti-Ia monoclonal antibodies blocked GPMBP + IL 1-induced cellular activation of nonadherent LNC. These results demonstrate that both IL 1 and Ia molecules are important in the pathway leading to GPMBP-induced activation of EAE-inducing T lymphocytes. Furthermore, these results suggest that different accessory signals may be required for optimal induction of GPMBP-induced lymphocyte activation vs GPMBP-specific proliferative responses.     

CD4+ suppressor cells differentially affect the production of IFN-gamma by effector cells of experimental autoimmune encephalomyelitis

Spleen cells from rats that have recovered from experimental autoimmune encephalomyelitis (EAE) suppress the production of IFN-gamma by effector T cells of EAE in an Ag-specific manner. These postrecovery suppressor cells also inhibit EAE in vivo. Fractionation of the postrecovery suppressor spleen cells on nylon wool and OX-8 coated plates yields a nylon wool-adherent CD4+ suppressor cell population that, when cocultured with effector T cells, suppresses IFN-gamma production by these effector cells. In contrast, the nylon wool-adherent, CD4+ postrecovery suppressor cell population fails to inhibit the production of IL-2 by the effector T cells. In further experiments, the effector T cell population was depleted of CD8+ cells and cocultured with the nylon wool-adherent, CD4+ postrecovery suppressor cells, and the supernatants were assayed for IFN-gamma and IL-2. IFN-gamma production was inhibited in these cultures but IL-2 production was not inhibited. Irradiated effector T cells were cocultured with CD4+ postrecovery suppressor cells, without myelin basic protein, in an effort to determine whether the mechanism of differential lymphokine suppression involved an anti-idiotypic response against effector T cells. No IL-2 was produced, indicating that there was no CD4+ suppressor cell mediated anti-idiotypic response against effector T cells. These studies suggest that the suppressor cell is a nylon wool adherent, CD4+ T cell that functions to down-regulate EAE effector T cells by differential inhibition of lymphokine production.     

Gammadelta T cells enhance the expression of experimental autoimmune encephalomyelitis by promoting antigen presentation and IL-12 production

Using an adoptive transfer model of experimental autoimmune encephalomyelitis (EAE) induced by myelin basic protein (MBP)-reactive lymph node cells (LNC), we have shown that depletion of gammadelta T cells from LNC resulted in diminished severity of EAE in recipient mice, both clinically and histopathologically. The reduced potency of gammadelta T cell-depleted LNC to induce EAE correlated with decreased cell proliferation in response to MBP. The gammadelta T cell effect upon the threshold of MBP-induced LNC proliferation and EAE transfer was restored by reconstitution of gammadelta T cells derived from either MBP-immunized or naive mice, indicating that this effect was not Ag specific. The enhancing effect of gammadelta T cells on MBP-induced proliferation and EAE transfer required direct cell-to-cell contact with LNC. The gammadelta T cell effect upon the LNC response to MBP did not involve a change in expression of the costimulatory molecules CD28, CD40L, and CTLA-4 on TCRalphabeta(+) cells, and CD40, CD80, and CD86 on CD19(+) and CD11b(+) cells. However, depletion of gammadelta T cells resulted in significant reduction in IL-12 production by LNC. That gammadelta T cells enhanced the MBP response and severity of adoptive EAE by stimulating IL-12 production was supported by experiments showing that reconstitution of the gammadelta T cell population restored IL-12 production, and that gammadelta T cell depletion-induced effects were reversed by the addition of IL-12. These results suggest a role for gammadelta T cells in the early effector phase of the immune response in EAE.     

Immunoregulation of passively induced allergic encephalomyelitis

Experimental allergic encephalomyelitis (EAE) can be readily induced passively by transfer of lymphocytes from neuroantigen immunized rats to naive recipients. This passively induced disease runs an acute, monophasic, self-limiting course, much the same as is usually seen in actively induced diseases. Here we examine the mechanisms regulating passive EAE. We report that splenectomy, thymectomy, and increasing age of recipients, manipulations which have been reported to influence recovery from actively induced EAE, have no effect on passively induced disease. EAE effector cells are not inactivated when transferred into recipients that have been actively sensitized and are beginning their recovery from clinical signs; this being a time when recovery associated suppressor cells are thought to be present. Finally, in the absence of suppressor T cells in both the recipient and in the transfer cell population, recovery from passive EAE still occurs. We conclude that suppressor T cells play no role in regulating passively induced EAE.     

Adoptively transferred experimental autoimmune encephalomyelitis in SJL/J, PL/J, and (SJL/J x PL/J)F1 mice. Influence of I-A haplotype on encephalitogenic epitope of myelin basic protein

Guinea pig basic protein (GPBP)-immune lymph node cells (LNC) from SJL, PL, and SJL x PL (F1) mice proliferated to whole GPBP and GPBP fragments 1-37, 43-88, and 89-169. All three strains of mice developed experimental allergic encephalomyelitis (EAE) by active immunization with whole GPBP or by passive transfer of LNC cultured with whole GPBP. SJL (H-2s) and PL (H-2u) mice developed EAE by active immunization with fragments 89-169 or 1-37, respectively, or by passive transfer of LNC cultured with the same Ag. F1 mice developed EAE by active immunization only with fragment 1-37 or by passive transfer of LNC cultured with either of the above fragments. Removal of macrophages (MO) from immune-F1 LNC resulted in the loss of a proliferative response and the ability to transfer EAE. Reconstitution of MO-depleted immune F1 T cells with either F1-, SJL-, or PL-MO restored the proliferative responses to whole GPBP and the three fragments. Cultures of immune F1 T cells reconstituted with any of the three MO populations and incubated with whole GPBP passively transferred EAE into naive F1 mice. Immune F1 T cells cultured with F1 MO in the presence of either fragment 1-37 or 89-169 transferred EAE. F1 T cells cultured with SJL MO were able to transfer EAE only if the Ag was fragment 89-169, whereas F1 T cells cultured with PL MO were able to transfer disease only if incubated in the presence of fragment 1-37. F1 mice are passively susceptible to EAE induced by adoptive transfer of cells reactive to either the N-terminal or C-terminal fragment and that the encephalitogenic determinant of GPBP is related to the genome of MO present in vitro.     

CD4+ suppressor cells inhibit the function of effector cells of experimental autoimmune encephalomyelitis through a mechanism involving transforming growth factor-beta.

Nylon wool adherent, CD4+ T cells from the spleens of rats that have recovered from experimental autoimmune encephalomyelitis (EAE) inhibit the in vitro production of IFN-gamma, but not IL-2, by effector cells of EAE when cocultured in the presence of myelin basic protein Ag. When anti-transforming growth factor-beta (TGF-beta) antibodies are added to the co-cultures, IFN-gamma production is restored to normal levels. Irrelevant control antibodies have no effect. The same pattern of response was obtained with cells incubated in serum-free medium. In other experiments, purified TGF-beta was added to cultures of effector cells in the presence of antigen. TGF-beta inhibited the production of IFN-gamma by these cells in a dose-dependent manner, but had no apparent inhibitory effect on IL-2 production. Finally, supernatants from cultures containing effector cells and CD4+ suppressor cells plus Ag contained measurable amounts of TGF-beta, whereas supernatants from cultures of effector cells plus Ag contained no measurable amounts of TGF-beta. These results suggest that CD4+ Ts cells of EAE regulate effector cells of EAE through a mechanism that involves the secretion of TGF-beta and that the inhibitory function of this cytokine can be reversed with neutralizing antibodies directed against TGF-beta.     

Genetic resistance in experimental autoimmune encephalomyelitis. I. Analysis of the mechanism of LeR resistance using radiation chimeras

Experimental autoimmune encephalomyelitis (EAE) is a cell-mediated autoimmune disease of the central nervous system that has been extensively studied in the rat. The Lewis rat is highly susceptible to the induction of EAE, while the Lewis resistant (LeR) rat is known to be resistant. In this paper, we demonstrate that the LeR rat, which was derived from the Lewis strain by inbreeding of fully resistant animals, is histocompatible with the Lewis strain. Radiation chimeras, a tool for distinguishing between immunologic and nonimmunologic resistance mechanisms, were utilized to analyze the cellular mechanisms involved in genetic resistance to EAE. By transplanting bone marrow cells from LeR rats into irradiated Lewis recipients, Lewis rats were rendered resistant to EAE induction. Likewise, transplanting Lewis bone marrow cells into irradiated LeR recipients rendered LeR rats susceptible. Mixed lymphoid cell chimeras using bone marrow, spleen, and thymus cells in Lewis recipient rats revealed individual lymphoid cell types and cell interactions that significantly affected the incidence and severity of EAE. Our results suggest that LeR resistance is mediated by hematopoietic/immune cells, and that cells located in the spleen appear to play a critical role in the resistance/susceptibility to EAE induction. Depletion of splenic adherent cells did not change the patterns of EAE resistance. In vivo cell mixing studies suggested the presence of a suppressor cell population in the LeR spleen preparations which exerted an inhibitory effect on Lewis autoimmune responses. Thus, the mechanism of LeR resistance appears to be different from that in other EAE-resistant animals.     

Synthetic peptides representing sequence 39 to 59 of rat V beta 8 TCR fail to elicit regulatory T cells reactive with V beta 8 TCR on rat encephalitogenic T cells.

Subpathogenic doses of syngeneic autoreactive T cells protect experimental animals against associated autoimmune disease. Preferential use of the TCR of encephalitogenic T cells suggests that this molecule serves as the target for immunoregulation in experimental autoimmune encephalomyelitis (EAE). Whether peptides derived from the V beta 8 of the rat TCR elicit regulatory T cells and produce the same vaccinating effect against EAE as do whole T cells remains unknown. Here we show that immunization of Lewis rats with V beta 8(39-59), a peptide representing residues 39 to 59 of the rat V beta 8 TCR, does not induce the production of regulatory T cells reactive to the intact TCR V beta 8 containing this sequence. Moreover, animals that had recovered from both actively induced EAE and transferred EAE did not generate regulatory T cells that recognized the V beta 8(39-59) peptide. Further, transfusion of large doses of peptide-specific T cells did not protect the animals from EAE. Our results suggest that the V beta 8(39-59) peptide may comprise so-called cryptic epitopes, which function as immunogens only when dissociated from large protein complexes.     

Nonencephalitogenic CD4-CD8- V alpha 2V beta 8.2+ anti-myelin basic protein rat T lymphocytes inhibit disease induction.

Recently there has been a number of reports suggesting that CD4-CD8- T cells participate in the processes of inflammatory reaction. In an attempt to delineate the distinctive functions of double negative (DN) T lymphocytes in an autoimmune-induced disease, we isolated and cloned such T cells, along with control CD4+ cells, from Lewis rats immunized with guinea-pig myelin basic protein in CFA. Both clones proliferated in response to the guinea-pig myelin basic protein and its synthetic encephalitogenic peptide, and expressed the same TCR V genes homologous to the mouse V alpha 2 and V beta 8.2 families that appear to be the defining entity of experimental autoimmune encephalomyeltis (EAE). Moreover, the TCR D and J region gene products of the DN cell were found to be similar to another encephalitogenic rat T cell clone. The two T clones did not differ markedly in their ability to produce TNF and IL-2 and to adhere to vascular wall-derived extracellular matrix- and laminin-coated plates. Surprising, therefore, was the finding that, although the CD4+ T lymphocytes were capable of inducing EAE, the DN cells did not elicit disease but rather inhibited subsequent EAE induction. Thus, TCR V alpha 2V beta 8.2 and its junctional region gene products are not the only prerequisite segment for a T cell to become encephalitogenic. We suggest that the important determinants of the T cell ability to induce disease are features of the T cell, other than or in addition to, the T cell receptor.     

Soluble factors in tolerance and contact sensitivity to DNFB in mice. VII. Characterization of a monoclonal, efferent-acting suppressor factor with specificity for DNP/H-2Kd

To study further soluble factors which regulate contact sensitivity (CS) to 2,4-dinitrofluorobenzene (DNFB), hapten-primed spleen cells from BALB/c mice were used to make T-cell hybridomas. A hybrid constitutively producing a suppressor factor was identified and cloned (clone 3-10). Incubation of BALB/c DNFB immune lymph node cells (LNC) in the 3-10 supernatant suppressed the ability of the immune cells to transfer CS to DNFB. The passive transfer of CS to oxazalone or to 2,4,6-trinitrochlorobenzene (TNCB) was not suppressed by the 3-10 factor. The hapten specificity of the 3-10 factor further was demonstrated by the ability of DNFB immune LNC but not LNC from unsensitized or from TNCB-sensitized mice to absorb the factor. The 3-10 factor also was adsorbed by DNFB-immune LNC from mice that were syngeneic with BALB/c mice at the K locus of the MHC (e.g., B10.D2 and D2.GD). Pretreatment of DNFB-immune LNC with monoclonal anti-Kd antibody or with anti-DNP antibodies blocked the ability to adsorb the factor. These results indicated that the 3-10 suppressor factor binds to DNP/H-2Kd complexes on immune LNC. Nylon wool-purified T cells (83% Thy-1.2+) from DNFB-immune LNC were able to adsorb the factor as well as unseparated immune LNC. Furthermore, treatment of immune LNC with anti-Thy-1.2 plus C' abrogated the ability of the cells to adsorb the factor, indicating that the cellular target of the 3-10 factor is a T cell. In addition, treatment of the immune LNC with an autoantiidiotypic antiserum (CS 231) plus C', which depletes DNP-specific delayed-type hypersensitivity effector T (TDH) cells, also abrogated the ability of the cells to adsorb the factor. Finally, the suppressor factor was adsorbed and eluted from DNP affinity columns but was not adsorbed by TNP affinity columns. Collectively, these results indicate that although the monoclonal 3-10 suppressor factor has affinity for DNP, focusing of the factor on the TDH cells requires recognition of DNP in the context of the appropriate MHC determinant, Kd.     

Experimental allergic encephalomyelitis: enhancement of cell-mediated transfer by concanavalin A.

Adoptive transfer of experimental allergic encephalomyelitis (EAE) with splenic lymphocytes from Lewis rats sensitized to myelin basic protein (BP) was potentiated by incubation of the cells in vitro with concanavalin A (Con A). Spleen cells of donors which had recovered from EAE also transferred the disease readily after activation by this procedure. In contrast, the transfer of activity of lymph node cells was not altered. We conclude that during the course of EAE a population of T cells with immunologic memory for BP is generated and persists in the spleen. Incubation with Con A activates these cells and results in marked enhancement of their ability to transfer the disease.     

Autoimmune encephalomyelitis (EAE) mediated or prevented by T lymphocyte lines directed against diverse antigenic determinants of myelin basic protein. Vaccination is determinant specific

Lines of T lymphocytes reactive against the basic protein of myelin (BP) were found in previous studies to mediate experimental autoimmune encephalomyelitis (EAE) in rats. Moreover, inoculation of rats with attenuated anti-BP line cells vaccinated them against subsequent attempts to induce active EAE by injection of BP in adjuvant. In the present study, we investigated the effects of T lymphocyte lines reactive to different antigenic determinants on the BP molecule, they are the major encephalitogenic peptide (EP) determinant present on guinea pig BP (G-BP), and minor, non-EP determinants present on bovine BP (B-BP). We found that both lines of T lymphocytes could mediate EAE. Resistance to active EAE acquired by spontaneous recovery from line mediated EAE or by vaccination with attenuated cells, however, was found to be specific for the particular BP determinant. Thus, EAE may be mediated by lines of T lymphocytes reactive to different determinants on the BP molecule, but the resistance to EAE acquired by exposure to line cells is determinant specific. This suggests that acquired resistance to EAE is directed by the receptor specificity of the autoimmune anti-BP T cells.     

HgCl2-induced perturbation of the T cell network in experimental allergic encephalomyelitis. II. In vivo demonstration of the role of T suppressor and contrasuppressor cells.

In the companion paper (J. Rossert et al., Cell. Immunol. 137, 1991), we showed by using limiting dilution analysis that Lewis (LEW) rats injected with HgCl2 and immunized with myelin (LEWHg/MYE) exhibit anti-basic protein CD4+ T helper cells (Th), at least 10-fold more frequent CD8+ T suppressor cells (Ts), and T contrasuppressor cells (Tcs). These Tcs cells were shown to be CD4+ T cells adhering to Vicia villosa (VV) lectin and allowed Th cells to proliferate despite the presence of Ts cells. The CD8+ Ts cells might be responsible for the protection from experimental allergic encephalomyelitis (EAE) observed in about 70% of LEW rats injected with HgCl2. The concomitant presence of CD4+ Tcs cells might explain that 30% of the rats escaped this protection. The aim of this work is to demonstrate in vivo the roles of CD8+ Ts cells and Tcs cells in mercury-induced protection from EAE. It will be shown that LEWHg/MYE rats depleted of CD8+ cells as well as LEWHg/MYE rats transferred with VV lectin-adherent Tcs cells develop EAE. These data demonstrate that CD8+ Ts cells are responsible for HgCl2-induced protection and that Tcs cells are involved in the control of Ts cells in vivo.     

Enhanced transfer of experimental allergic encephalomyelitis with strain 13 guinea pig lymph node cells: requirement for culture with specific antigen and allogeneic peritoneal exudate cells

Previously, we reported that transfer of experimental allergic encephalomyelitis (EAE) with sensitized peritoneal exudate cells (PEC) in strain 13 guinea pigs is markedly enhanced if the cells are first cultured with specific antigen, myelin basic protein (BP). These cells also undergo considerable antigen-specific proliferation. In contrast, the data reported here show that lymph node cells (LNC) from sensitized animals display neither enhanced transfer nor antigen-specific proliferation after culture with BP. Enhanced transfer is obtained, however, if a second nonspecific signal is available. This second signal is provided by the presence of normal allogeneic strain 2 PEC in culture. After culture with BP and strain 2 PEC, 2.5 to 5 x 10(7) strain 13 LNC transfer disease reproducibly, in contrast with approximately 1 x 10(9) previously required for successful transfer. Addition of allogeneic or syngeneic PEC without antigen does not lead to enhanced transfer by LNC. Culture with normal syngeneic PEC plus BP oly infrequently enhances transfer by LNC. The intense mixed lymphocyte reaction (MLR) induced by addition of strain 2 PEC to strain 13 LNC precludes the use of 3H-TdR incorporation for detection of proliferation by EAE effector cells. However, inhibition of transfer with low doses of mitomycin C (2 to 5 micrograms/ml) pluse the fact that EAE effector cells are found almost exclusively in the light fraction of BSA gradients after (but not before) culture suggests that the latter are induced to proliferate in culture.     

Immune response in experimentally induced uremia. II. Suppression of PHA response in uremia is mediated by an adherent, Ia-negative and indomethacin-insensitive suppressor cell

The characteristics of the adherent suppressor cell in uremic rats were examined. We found that: 1) adherent spleen cells from uremic rats display a more potent suppressor activity than do control adherent cells; 2) the suppression that is mediated by uremic adherent spleen cells cannot be eliminated by pretreatment with indomethacin, whereas the suppression that is mediated by naturally present adherent cells in the control rat is reversed by pretreatment with indomethacin; 3) the uremic adherent suppressor cell does not have Ia antigens that can be detected by the monoclonal antibodies OXL, whereas control adherent cells have Ia antigens on their surface; 4) both the control and uremic adherent suppressor cells are insensitive to mitomycin C and do not have any detectable levels of Thy 1 antigens on their surface. It appears that immune suppression in uremic rats is mediated by an adherent cell that differs from adherent cells present in control animals. The suppression in uremic rats is either not mediated by prostaglandins or may be mediated by preformed prostaglandin synthetase products.     

Oral tolerance in experimental autoimmune encephalomyelitis. III. Evidence for clonal anergy.

We have recently reported that experimental autoimmune encephalomyelitis (EAE) can be suppressed by the oral administration of myelin basic protein (MBP). The oral introduction of 20 mg MBP together with a trypsin inhibitor results in inhibition of EAE clinical signs, decreased CNS histopathologic changes and dramatically reduced MBP-specific proliferative responses in fed and challenged Lewis rats. In the present study, we have investigated the mechanism underlying MBP-induced oral tolerance in EAE. Neither lymphoid cells (lymph node cells, spleen cells, Peyer's patch lymphocytes, thymocytes) nor humoral elements derived from tolerant donors were capable of transferring the tolerance to naive recipients. Moreover, lymphoid cells obtained from orally tolerant donors exhibited a marked decrease in their capacity to transfer EAE to naive recipient rats, even after in vitro activation with MBP or Con A. We observed that EAE could be readily transferred into orally tolerant rats using MBP-specific encephalitogenic T cell lines. In vitro cell mixing studies showed that the proliferation of lymphocytes from MBP-sensitized donors was not inhibited by the addition of lymphoid cells from tolerant donors, arguing against the role of a suppressor cell. Investigation of MBP-stimulated lymphokine production showed that both IL-2 and IFN-gamma levels were substantially decreased in spleen and lymph node cell cultures from MBP-fed rats compared to vehicle-fed control animals. Furthermore, limiting dilution analyses revealed that MBP-fed rats exhibited a profound decrease in MBP-reactive, IL-2-secreting lymphocytes relative to control animals. Thus, because lymphocytes from MBP-fed rats neither proliferate nor secrete IL-2 or IFN-gamma in response to MBP and we can find no compelling evidence for the role of suppressor cells, we propose that the oral administration of MBP results in a state of clonal anergy.