Characterization of a suppressor cell line which downgrades experimental autoimmune uveoretinitis in the rat

A Ts lymphocyte line was isolated from spleens of rats primed with the retinal soluble Ag (SAg) in the anterior chamber of the eye. This line could inhibit in vitro SAg-driven proliferation of uveitogenic Th lymphocytes, in a radioresistant, Ag-independent manner. Adoptively transferred Ts line cells were found to downgrade experimental autoimmune uveoretinitis in actively immunized syngeneic recipients. The initial surface phenotype (OX8+) of the Ts line was unstable in vitro, however, the cells expressed suppressor function irrespective of phenotype. The mechanism of suppression did not appear to involve consumption of IL-2 or direct cytolysis of uveitogenic Th lymphocytes, but rather the production of a soluble suppressor factor. These findings may suggest an in vivo role for suppressor lymphocytes, capable of inhibiting primed Th cells, in the regulation of experimental autoimmune uveoretinitis.     

T cell requirement for experimental allergic encephalomyelitis induction in the rat.

The question of whether a cell-mediated or a humoral mechanism initiates EAE in rats sensitized with BP-CFA was investigated. The requirement of T cells for EAE induction was manifested when Tx, irradiated rats were reconstituted with normal lymphoid cells treated with ATS and then injected with BP-CFA. Neither EAE nor antibody was produced, indicating the T cell dependency of BP specific antibody production. More precise information regarding the role of the T cell in the production of EAE was obtained by means of passive transfer of EAE with sensitized lymphocytes. Thus, transfer of lymphoid cells from rats previously sensitized to BP-CFA into Tx, irradiated rats elicited EAE and antibodies to BP. However, no EAE followed when the transferred cells were first depleted of T cells by treatment with ATS. Nevertheless, ATP pretreatment did not depress the levels of antibody to BP produced in the transfer recipients. The latter finding indicates that the cells from animals sensitized 9 days previously were already committed to the production of antibodies to BP. Therefore, a) T cells are absolutely necessary for induction of EAE and b) antibody detected by antigen-binding is not responsible for the pathogenesis of this disease.     

Unresponsiveness to experimental allergic encephalomyelitis in mice: replacement of suppressor cells by a soluble factor

A soluble suppressor factor has been prepared from cells of mice rendered nonsusceptible to experimental allergic encephalomyelitis (EAE) by treatment with mouse spinal cord homogenate in incomplete Freund's adjuvant. The specific activity of this factor can be augmented by using a cell population enriched on plates coated with anti-mouse Fab and the specific antigen, mouse basic encephalitogen (MBE). The resultant suppressor factor had the same biologic activities as the cells from which it originated. Thus, it suppressed specifically the delayed-type hypersensitivity (DTH) response to MBE in vivo, and blocked in vitro the effector lymphocytes that adoptively transfer the DTH response. The suppressor factor reactivity was manifested also by the capacity to suppress the activity of macrophage migration inhibition factor produced by sensitized lymphocytes in the presence of the specific antigen MBE. The suppressor factor is antigen-specific and can bind the MBE in vitro and thus compete with its antibody binding. The most significant activity of the soluble suppressor factor is its ability to interfere with the induction of clinical EAE.     

Chronic relapsing experimental allergic encephalomyelitis. Cytotoxicity effected by a class II restricted T cell line specific for an encephalitogenic epitope

We have examined the possibility that Ag-specific CTL responses may play a role in the pathogenesis of CREAE by using an effector T cell line (LN400) specifically reactive to the SJL encephalitogenic epitope defined by myelin basic protein MBP residues(90-101). The LN400 cell line was capable of adoptively transferring CREAE to naive SJL mice and proliferated specifically to synthetic peptides corresponding to MBP residues(90-101) and an N-acetylated analogue of this epitope, as well as MBP. Moreover, the cell line generated Ag-specific CTL responses only against syngeneic targets that had been pulsed with these Ag. Targets pulsed with irrelevant Ag were not lysed. These CTL responses were MHC restricted to H-2s and were inhibited if targets were preincubated with mAb specific for relevant class II Ag. No inhibition was seen if targets were preincubated with mAb specific for class I Ag, indicating that the CTL responses generated by this L3T4+ Lyt-2.2- cell lines were class II restricted. Studies designed to detect nonspecific CTL through a bystander mechanism failed to demonstrate significant lysis of bystander targets by this Ag-specific cell line. These findings have relevance in defining potential mechanisms of disease induction in this model autoimmune disease.     

Modulation of experimental allergic encephalomyelitis with anti-T suppressor factor antibodies

mAb reactive with T suppressor factors (TsF) were used to alter the course of myelin basic protein-induced experimental allergic encephalomyelitis in (SJL/J x PL/J)F1 mice. In vivo administration of mAb 14-12, reactive with effector TsF, exacerbated the clinical expression of encephalomyelitis as evidenced by prolonged periods of total limb paralysis in affected animals. This aggravation of disease signs is probably related to the inhibition of effector Ts function by mAb 14-12 thus allowing T cell autoreactivity to proceed unchecked. Disease course was influenced more favorably by i.v. administration of mAb 14-30 reactive with a subset of inducer TsF. Ten days of treatment with this mAb resulted in a reduction in the incidence and severity of disease, noted as the development of minimal limb weakness but no paralysis in the majority of affected animals. Adoptive transfer experiments revealed the presence of Ag-specific Ts in mAb 14-30-treated mice that inhibited recipient Lyt-1+ responses to myelin basic protein, the immunizing autoantigen. Suppression by transferred Ts was revealed only by treatment of the donor population with anti-Lyt-1.2 plus C, however, indicating a role for contrasuppressor activity in the regulation of autoimmune T cell function. Results are considered relevant to the potential for immunotherapeutic management of multiple sclerosis in man.     

T cell lines derived from the spinal cords of mice with experimental allergic encephalomyelitis are self reactive

Experimental allergic encephalomyelitis (EAE) is an animal model of T cell-mediated, central nervous system neuropathology that may be a relevant animal model for multiple sclerosis. EAE is usually induced by sensitization of animals with a xenogeneic myelin basic protein (MBP). Recently, MBP-reactive T cell lines and clones derived from lymphoid tissue of animals with EAE have proved very useful in elucidating certain aspects of the pathogenesis in EAE. However, questions relating to how T cells actually mediate the pathologic changes seen in EAE remain unresolved. We now report for the first time the derivation of long-term, interleukin 2-dependent T cell lines and sublines from a site of pathology in murine EAE--the spinal cord. All of the spinal cord-derived T cell lines and sublines were found to be "autoreactive" in that they responded to self (murine) MBP as well as to the xenogeneic immunogen, porcine MBP. The ability to derive T cell lines and sublines from the spinal cords of mice with EAE should now aid in the elucidation of pathogenetic mechanisms in EAE by allowing for a characterization of those T cells found at the site of pathology.     

Studies of experimental allergic encephalomyelitis by using encephalitogenic T cell lines and clones in euthymic and athymic mice

The role of T-T cell interactions in the clinical course of acute experimental allergic encephalomyelitis (EAE) in mice was investigated. Myelin basic protein (MBP)-reactive and encephalitogenic T cell clones were established from long-term lines derived from susceptible strain SJL/J mice and resistant strain DDD/1 mice. The lines and clones from DDD/1 mice were obtained by immunization of congenitally athymic mice of DDD/1 origin, which had been reconstituted with syngeneic Lyt-2+-depleted splenic T cells. The clones derived from both strains bore surface phenotypes of Lyt-1+, 2- and L3T4+, and proliferated well in response to rat, rabbit, bovine, and guinea pig MBP in the presence of antigen-presenting cells with I-As. Passive EAE could be induced in syngeneic normal recipients by these clones as well as by the lines from which the clones were derived. The clinical features of the clone-induced EAE were essentially the same as those of the line-induced EAE. Furthermore, DDD/1 athymic recipients developed signs of acute EAE by the adoptive transfer of I-A-compatible syngeneic and allogeneic T cell clones, in which there was no significant difference in time of onset, maximum severity, or prognosis. These results indicate that the entire clinical course of acute EAE can be elicited by a single population of MBP-reactive T cells in the absence of the thymus and other populations of primed or unprimed T cells.     

A myelin basic protein-specific T lymphocyte line that mediates experimental autoimmune encephalomyelitis

A T lymphocyte line, BP-1, expressing the T helper phenotype was selected from Lewis rats immunized with guinea pig myelin basic protein (GP-BP) in complete Freund's adjuvant (CFA). The BP-1 line responded specifically to GP-BP but not to PPD after the first round of selection, and responded to rat but not human or bovine BP. When injected i.p. into histocompatible Lewis or F1 (Lewis X P2) recipients, the BP-1 line induced both clinical signs of experimental autoimmune encephalomyelitis (EAE) and delayed type hypersensitivity (DTH) reactions in ears challenged intradermally with GP-BP but not PPD. The severity of clinical signs and the degree of ear swelling were dependent on the dose of BP-1 cells injected. Both activities were detectable with as few as 0.1 X 10(6) BP-1 line cells and required prior activation of the line cells with GP-BP presented by accessory cells. Lewis rats that had recovered from EAE induced by injection of GP-BP in CFA were more susceptible than naive rats to BP-1 line-mediated disease, requiring as few as 0.03 X 10(6) line cells. Clinical EAE and DTH could be serially transferred into F1 (Lewis X P2) recipients with BP-1 cells and back to nonirradiated Lewis parents with activated splenocytes, suggesting that BP-1 cells persist in recipient rats. These results demonstrate the potent biologic activities of an autoreactive BP-specific T lymphocyte line. This line possesses properties similar to BP lines described previously as well as to culture-conditioned splenic T effector cells; thus, the data presented here bridge the gap between these two approaches for studying T effector lymphocyte functions.     

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.     

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.     

T cell dynamics during induction of tolerance and suppression of experimental allergic encephalomyelitis

The cell dynamics associated with induction of peripheral T cell tolerance remain largely undefined. In this study, an in vivo model was adapted to two-photon microscopy imaging, and T cell behavior was analyzed on tolerogen-induced modulation. FcγR-deficient (FcγR(-/-)) mice were unable to resist or alleviate experimental allergic encephalomyelitis when treated with Ig-myelin oligodendrocyte glycoprotein (MOG) tolerogen, an Ig carrying the MOG35-55 peptide. However, when FcγR(+/+) dendritic cells (DCs) are adoptively transferred into FcγR(-/-) mice, uptake and presentation of Ig-MOG occurs and the animals were able to overcome experimental allergic encephalomyelitis. We then fluorescently labeled FcγR(+/+) DCs and 2D2 MOG-specific TCR-transgenic T cells, transferred them into FcγR(-/-) mice, administered Ig-MOG, and analyzed both T cell-DC contact events and T cell motility. The results indicate that tolerance takes place in lymphoid organs, and surprisingly, the T cells do not become anergic but instead have a Th2 phenotype. The tolerant Th2 cells displayed reduced motility after tolerogen exposure similar to Th1 cells after immunization. However, the Th2 cells had higher migration speeds and took longer to exhibit changes in motility. Therefore, both Th1 immunity and Th2 tolerance alter T cell migration on Ag recognition, but the kinetics of this effect differ among the subsets.     

A permanent rat T cell line that mediates experimental allergic neuritis in the Lewis rat in vivo

A rat T cell line of the "helper" phenotype (W3/25-positive, OX 8-negative) has been derived from Lewis rats inoculated with P2 protein isolated from bovine PNS myelin. The line LiP2/A is exquisitely specific for P2 protein, exhibiting no reactivity to bovine basic protein or to PPD. In addition to responding strongly to the intact P2 protein, the line cells show some response to a synthetic peptide containing the neuritogenic amino acid sequence of P2 protein (SP-B, residues 66-78). Intravenous inoculation of naive rats with as few as 10(4) activated LiP2/A cells leads to the onset of mild clinical signs of experimental allergic neuritis. Higher doses of cells lead to more severe clinical disease. Histologic examination of clinically ill animals confirmed the disease as EAN. The pathologic lesions were confined to the PNS and spared the central nervous system. The lesions consisted of marked perivascular cuffs and infiltrates of inflammatory cells associated with marked degenerative changes--demyelination and some axonal degeneration.     

Kinetics and specificity of T and B cell responses in relapsing experimental allergic encephalomyelitis

T and B cell responses to myelin basic protein (MBP) and its relevant peptide fragments were examined throughout the course of MBP-induced relapsing experimental allergic encephalomyelitis (REAE) in (SJL X PL)F1 mice. T cell reactivity, measured by the antigen-driven proliferation of lymph node T cells in vitro, was directed predominantly against the encephalitogenic MBP-P2 peptide (amino acids 1 to 37) at all stages of disease. Levels of responsiveness did not correlate with disease expression, but declined over time to a relapse level that was four- to sixfold lower than that observed during peak acute stage reactivity. Relapse responses were further distinguished by the detection of host I-E restrictions on Lyt-1+ T cell recognition of P2, P2 recognition by acute-stage T cells occurring solely in the context of host I-A molecules. These data imply an increase in the heterogeneity of relapse T cell responses to MBP to include clones restricted by additional class II glycoproteins. A role for additional CNS autoantigens in the stimulation of relapse T cells is also considered. Serum antibody responses to MBP or the P2 fragment fluctuated randomly throughout R-EAE when total antibody activity (IgM plus IgG) was measured. However, analysis of individual isotypes of IgG immunoglobulins revealed an apparent correlation between peak antigen-binding activity and disease expression which may reflect either an effector or regulatory role for humoral immunity in recurrent EAE. Patterns of early antibody reactivity also distinguished F1 mice that developed or failed to develop disease signs after immunization, the latter exhibiting a consistent drop in antigen-binding activity 4 to 5 days before the usual onset of acute-stage paralysis. The results are considered with regard to possible mechanisms of chronic disease regulation in an environment of functional T cell suppression.     

Specific immune regulation of chronic-relapsing experimental allergic encephalomyelitis in mice

These studies were designed to examine immunologic means of regulating the clinical course of murine chronic-relapsing experimental allergic encephalomyelitis (R-EAE). We asked whether induction of specific immune tolerance to the major CNS myelin proteins, myelin basic protein (MBP) and proteolipid protein (PLP), could inhibit the development of R-EAE. Neuroantigen-specific tolerance was induced in SJL/J mice in a dose-dependent manner by the i.v. injection of mouse spinal cord homogenate-coupled syngeneic splenocytes (MSCH-SP) on day -7 relative to immunization on days 0 and +7. Sham-tolerized controls developed significant MBP- and PLP-specific DTH responses before the onset of clinical R-EAE. In contrast, MSCH-SP tolerized mice exhibited a dramatically reduced incidence of clinical and histologic signs of disease which correlated with the failure to develop MBP- and PLP-specific DTH responses. In 10 separate experiments, 118/149 (79%) of control mice, but only 22/137 (16%) of tolerized mice developed clinical R-EAE. Tolerance took time to develop and lasted at least 4 wk as mice injected with Ag-coupled splenocytes on day -1 relative to immunization remained susceptible to R-EAE, whereas mice injected on days -7, -14, or -28 were resistant. Tolerance induction required neuroantigens as injection of splenocytes coupled with a syngeneic mouse kidney homogenate failed to significantly alter the incidence of R-EAE or the development of neuroantigen-specific DTH responses. Thus, induction of R-EAE can be specifically and significantly regulated after the i.v. injection of splenocytes coupled with a crude, heterogeneous mixture of neuroantigens (i.e. MSCH).     

Genetic control of susceptibility to experimental allergic encephalomyelitis in mice

The genetic control of susceptibility to experimental allergic encephalomyelitis (EAE) was studied in mice. The results indicate that sensitivity to disease is not inherited in a simple Mendelian dominant way. Susceptibility to EAE is governed by genes located outside of the major histocompatibility complex and not byH-2-linkedIr genes. No correlation was observed between susceptibility to disease and the cellular immune response toward the small encephalitogenic protein.     

In trans T cell tolerance diminishes autoantibody responses and exacerbates experimental allergic encephalomyelitis

A number of Ag-specific approaches have been developed that ameliorate experimental allergic encephalomyelitis (EAE), an animal model for the human autoimmune disease multiple sclerosis. Translation to humans, however, remains a consideration, justifying the search for more insight into the mechanism underlying restoration of self-tolerance. Ig-proteolipid protein (PLP) 1 and Ig-myelin oligodendrocyte glycoprotein (MOG) are Ig chimeras carrying the encephalitogenic PLP 139-151 and MOG 35-55 amino acid sequence, respectively. Ig-PLP1 ameliorates EAE in SJL/J (H-2(s)) mice while Ig-MOG modulates the disease in C57BL/6 (H-2(b)) animals. In this study, we asked whether the chimeras would suppress EAE in F(1) mice expressing both parental MHC alleles and representing a polymorphism with more relevance to human circumstances. The results show that Ig-MOG modulates both PLP1 and MOG peptide-induced EAE in the F(1) mice, whereas Ig-PLP1 counters PLP1 EAE but exacerbates MOG-induced disease. This in trans aggravation of MOG EAE by Ig-PLP1 operates through induction of PLP1-specific T cells producing IL-5 that sustained inhibition of MOG-specific Abs leading to exacerbation of EAE. Thus, in trans T cell tolerance, which should be operative in polymorphic systems, can aggravate rather than ameliorate autoimmunity. This phenomenon possibly takes place through interference with protective humoral immunity.     

Administration of dehydroepiandrosterone suppresses experimental allergic encephalomyelitis in SJL/J mice.

Experimental allergic encephalomyelitis (EAE) is a Th1-mediated inflammatory demyelinating disease in the CNS, an animal model of multiple sclerosis. We have examined the effect of dehydroepiandrosterone (DHEA) on the development of EAE in mice. The addition of DHEA to cultures of myelin basic protein-primed splenocytes resulted in a significant decrease in T cell proliferation and secretion of (pro)inflammatory cytokines (IFN-gamma, IL-12 p40, and TNF-alpha) and NO in response to myelin basic protein. These effects were associated with a decrease in activation and translocation of NF-kappaB. In vivo administration of DHEA significantly reduced the severity and incidence of acute EAE, along with a decrease in demyelination/inflammation and expressions of (pro)inflammatory cytokines in the CNS. These studies suggest that DHEA has potent anti-inflammatory properties, which at least are in part mediated by its inhibition of NF-kappaB activation.     

Antigen-stimulated rosette formation by T lymphocytes in experimental allergic encephalomyelitis

Peripheral blood lymphocytes form rosettes in the presence of heterologous etythrocytes. Spontaneous or active rosette formation has been reported to be a measure of circulating and immunologically functional thymus-dependent lymphocytes. The present study utilizes the rosette assay to measure changes in the circulating T cells of guinea pigs sensitized with encephalitogenic myelin basic protein (BP) or with nonencephalitogenic peptide S42 known to induce cellular transformation in experimental allergic encephalomyelitis, a cell-mediated disorder of the central nervous system. The results show a significant depression in the number of active but not in the total number of rosette-forming T lymphocytes from the peripheral blood of antigen-sensitized animals. This reduction, which was not related to the encephalitogenic property of the BP, was readiiy reversible by incubating lymphocytes with the sensitizing antigen but not with histone. Under these conditions, lymphocytes from unsensitized control animals were unresponsive to stimulation by any of the antigens used. The antigenstimulated rosette assay described in this report provides a specific assay for sensitization to basic protein in BP-related demyelinating diseases.     

The immunologic response in mice unresponsive to experimental allergic encephalomyelitis

The suppressor cells that are involved in antigen-induced protection against EAE in mice were investigated with respect to their effect on the immune response. The cellular immune response to the basic encephalitogenic protein (BE) and to PPD were studied in mice with either actively induced or adoptively transferred unresponsiveness to EAE. The results demonstrate that the DTH response to BE, as assayed in the radiometric ear skin test, was suppressed in mice protected against EAE. Moreover, the passive transfer of DTH response to BE by effector lymphocytes was also inhibited by the preinjection of suppressor cells. On the other hand, the suppressor cells did not affect the response to PPD in all these experiments. The results indicate that suppressor cells that mediate unresponsiveness to EAE regulate also the cellular immune response to BE in a specific manner. These suppressor cells are probably active both at the induction and the effector phase of the immune response.