Experimental allergic encephalomyelitis: clinical disease and enhanced cellular transfer in the absence of lymphocyte proliferative responses against syngeneic MBP

Experimental allergic encephalomyelitis (EAE) was induced in Lewis rats using several different immunization protocols, and draining lymph node cells from these animals were assayed for proliferation against heterologous, homologous, and syngeneic MBP, and syngeneic spinal cord. Proliferative responses were largely stimulated by nonsyngeneic antigenic determinants and correlated better with the antigen used to induce EAE than with signs of autoimmune disease. Lymph node cells from rats immunized with either guinea pig spinal cord or syngeneic MBP did not proliferate measurably when restimulated in vitro with syngeneic MBP, yet lymphoid cells from these animals were enhanced in their capacity to transfer EAE following in vitro stimulation with syngeneic MBP.     

IL-10-dependent suppression of experimental allergic encephalomyelitis by Th2-differentiated, anti-TCR redirected T lymphocytes

We previously showed that transgenically expressed chimeric Ag-MHC-zeta receptors can Ag-specifically redirect T cells against other T cells. When the receptor's extracellular Ag-MHC domain engages cognate TCR on an Ag-specific T cell, its cytoplasmic zeta-chain stimulates the chimeric receptor-modified T cell (RMTC). This induces effector functions such as cytolysis and cytokine release. RMTC expressing a myelin basic protein (MBP) 89-101-IAs-zeta receptor can be used therapeutically, Ag-specifically treating murine experimental allergic encephalomyelitis (EAE) mediated by MBP89-101-specific T cells. In initial studies, isolated CD8+ RMTC were therapeutically effective whereas CD4+ RMTC were not. We re-examine here the therapeutic potential of CD4+ RMTC. We demonstrate that Th2-differentiated, though not Th1-differentiated, CD4+ MBP89-101-IAs-zeta RMTC prevent actively induced or adoptively transferred EAE, and treat EAE even after antigenic diversification of the pathologic T cell response. The Th2 RMTC both Th2-deviate autoreactive T cells and suppress autoantigen-specific T cell proliferation. IL-10 is critical for the suppressive effects. Anti-IL-10R blocks RMTC-mediated modulation of EAE and suppression of autoantigen proliferation, as well as the induction of IL-10 production by autoreactive T cells. In contrast to IL-10, IL-4 is required for IL-4 production by, and hence Th2 deviation of autoreactive T cells, but not the therapeutic activity of the RMTC. These results therefore demonstrate a novel immunotherapeutic approach for the Ag-specific treatment of autoimmune disease with RMTC. They further identify an essential role for IL-10, rather than Th2-deviation itself, in the therapeutic effectiveness of these redirected Th2 T cells.     

Characterization of the antigen specificity and TCR repertoire,and TCR-based DNA vaccine therapy in myelin basic protein-induced autoimmune encephalomyelitis in DA rats

Like Lewis rats, DA rats are an experimental autoimmune encephalomyelitis (EAE)-susceptible strain and develop severe EAE upon immunization with myelin basic protein (MBP). However, there are several differences between the two strains. In the present study we induced acute EAE in DA rats by immunization with MBP and MBP peptides and examined the Ag specificity and TCR repertoire of encephalitogenic T cells. It was found that although immunization with MBP and a peptide corresponding to its 62-75 sequence (MBP(62-75)) induced clinical EAE, the responses of lymph node T cells isolated from MBP-immunized rats to MBP(62-75) was marginal, indicating that this peptide contains major encephalitogenic, but not immunodominant, epitopes. The TCR analysis by CDR3 spectratyping of spinal cord T cells revealed that Vbeta10 and Vbeta15 spectratype expansion was always found in MBP(62-75)-immunized symptomatic rats. On the basis of these findings, we examined the encephalitogenicity of Vbeta10- and Vbeta15-positive T cells. First, the adoptive transfer experiments revealed that Vbeta10-positive T line cells derived from MBP(62-75)-immunized rats induced clinical EAE in recipients. Second, administration of DNA vaccines encoding Vbeta10 and Vbeta15, alone or in combination, ameliorated MBP(62-75)-induced EAE. Collectively, it was strongly suggested that Vbeta10- and Vbeta15-positive T cells are encephalitogenic. Analyses of the Ag specificity and T cell repertoire of pathogenic T cells performed in this study provide useful information for designing specific immunotherapies against autoimmune diseases.     

Competition between foreign and self proteins in antigen presentation. Ovalbumin can inhibit activation of myelin basic protein-specific T cells.

Experimental autoimmune encephalomyelitis (EAE) is an inflammatory neurological disease initiated by activated T cells specific for the autoantigen, myelin basic protein (MBP). The ability of Lewis rat splenic T cells to transfer EAE after in vitro incubation with MBP-pulsed dendritic cells (DC) was used as an index of MBP-specific T cell activation. OVA, previously processed by macrophages, was incubated with MBP and DC at the pulsing stage to determine whether it could inhibit presentation of the autoantigen. At molar equivalents of 2.5:1 and 20:1 relative to MBP, processed OVA increasingly inhibited the ability of DC to activate MBP-specific T cells for EAE transfer. Unprocessed OVA, which cannot be presented immunogenically by Lewis rat DC, was much less effective. However, processed OVA added to DC after they had been pulsed with MBP could not compete. OVA also blocked appearance of EAE when mixed with MBP/CFA in the inoculum used for active induction of the disease. Splenic T cells from MBP + OVA/CFA-immunized rats transferred EAE with a substantially delayed onset, suggesting that a reduced number of MBP-specific T cells was generated by immunizing with the OVA + MBP mixture compared with MBP alone. Overall, the data indicate that fragments of a foreign protein, OVA, which can be bound by APC, can also inhibit presentation of encephalitogenic determinants of MBP to T cells.     

Suppression of experimental autoimmune encephalomyelitis by oral administration of myelin basic protein. II. Suppression of disease and in vitro immune responses is mediated by antigen-specific CD8+ T lymphocytes

We have previously demonstrated that the oral administration of guinea pig myelin basic protein (MBP) protects Lewis rats against the induction of experimental autoimmune encephalomyelitis (EAE) when subsequently immunized with guinea pig MBP in CFA. In addition, animals made orally tolerant to MBP also have diminished proliferative and antibody responses to MBP, but not to other Ag. Nonetheless, the mechanism of oral tolerance to MBP in the EAE model remains undefined. In the present study, we report that T cells isolated from the spleen and mesenteric lymph nodes of MBP orally tolerized animals can adoptively transfer protection against EAE. Furthermore, these T cells are of the CD8+ subclass. In addition, CD8+ T cells from MBP orally tolerized animals also suppress in vitro proliferative responses and antibody responses to MBP in an Ag-specific fashion. These results demonstrate that active cellular mechanisms are initiated after oral administration of an autoantigen that can down-regulate an experimental autoimmune disease and provide the basis for the isolation and characterization of the cells mediating both in vivo and in vitro suppression.     

Indomethacin augments in vitro proliferative responses of Lewis rat lymphocytes to myelin basic protein. Implications for experimental autoimmune encephalomyelitis

Indomethacin (IM), a specific inhibitor of prostaglandin (PG) synthesis, and PGE2 were studied in terms of their ability to modulate in vitro immune responses associated with experimental autoimmune encephalomyelitis (EAE) in Lewis rats. Lymphoid cells from either the spleens or the draining lymph nodes of myelin basic protein (MBP)-sensitized rats exhibited in vitro immune responses which were enhanced in the presence of IM. Specifically, IM enhanced (i) guinea pig MBP (GPMBP)- and rat MBP (RMBP)-stimulated lymphocyte proliferation, (ii) background proliferation, and (iii) interleukin 2 (IL-2)-stimulated proliferation. Conversely, PGE2 inhibited both GPMBP- and IL-2-stimulated proliferation of MBP-sensitized lymphocytes. Together, these results indicate that PGs secreted by cultured lymphoid cells can directly mitigate MBP- or IL-2-stimulated lymphocyte proliferation. Furthermore, the observation that IM and PGE2 modulate in vitro responses of MBP-specific lymphocytes may provide insight into how the in vivo administration of IM potentiates the severity of EAE (H. Ovadia and P.Y. Paterson, Clin. Exp. Immunol. 49, 386, 1982) and how PGs may be involved in the spontaneous remission of EAE in rats.     

Genetic control of the development of experimental allergic encephalomyelitis in rats. Separation of MHC and non-MHC gene effects

Experimental allergic encephalomyelitis (EAE)-susceptible Lew and EAE-resistant Brown Norway (BN) rats and the corresponding MHC congenic strains were examined for their ability to develop clinical and histologic EAE. The ability of T cells from these animals to proliferate in vitro in response to whole guinea pig (GP) myelin basic protein (MBP), rat MBP, and to the major encephalitogenic peptide of GP MBP 66-88 (GP 68-88) was also assessed. We found that Lewis (Lew) was highly susceptible and showed good T cell responses to GP, MBP, rat MBP, and GP 68-88. Lew.1N (BN MHC on Lew background) and BN were not susceptible and T cells from these strains showed significant responses to GP MBP, but not to rat MBP or GP 68-88. Although BN.B1 (Lew MHC on BN background) was not susceptible to actively induced EAE, MBP-specific Lew T cells could transfer severe disease to BN.B1. BN.B1 T cells showed responses to GP-MBP, rat MBP, and GP 68-88 and, when transferred to naive BN.B1 or Lew, induced only mild clinical EAE in both strains. Increasing the number of T cells from BN.B1 had no effect on the severity of clinical symptoms in either recipient, suggesting some deficiency in the T cell repertoire that is necessary for induction of severe EAE. These results suggest that 1) the T cell response to rat MBP and GP68-88 (but not to sites other than 68-88 in GP MBP) is necessary for susceptibility to EAE; 2) the ability to respond to both rat MBP and GP 68-88 is determined by the MHC gene products on APC; and 3) given a permissive MHC, the T cell response that results in EAE is influenced by non-MHC genes.     

Expression of the tyrosine phosphatase SRC homology 2 domain-containing protein tyrosine phosphatase 1 determines T cell activation threshold and severity of experimental autoimmune encephalomyelitis

Experimental autoimmune encephalomyelitis (EAE) is a CD4 Th1-mediated inflammatory demyelinating disorder of the CNS and a well-established animal model for multiple sclerosis. Src homology 2 domain-containing protein tyrosine phosphatase 1 (SHP-1) is a cytosolic tyrosine phosphatase that is involved in regulating the T cell activation cascade from signals initiated through the TCR. To study the role of SHP-1 in EAE pathogenesis, we immunized B10.PL mice heterozygous for deletion of the SHP-1 gene (me(v+/-)) and B10.PL wild-type mice with the immunodominant epitope of myelin basic protein (MBP Ac1-11). T cell proliferation and IFN-gamma production were significantly increased in me(v+/-) mice after immunization with MBP Ac1-11. The frequency of MBP Ac1-11-specific CD4 T cells, analyzed by staining with fluorescently labeled tetramers (MBP1-11[4Y]: I-A(u) complexes), was increased in the draining lymph node cells of me(v+/-) mice compared with wild-type mice. In addition, me(v+/-) mice developed a more severe course of EAE with epitope spreading to proteolipid protein peptide 43-64. Finally, expansion of MBP Ac1-11-specific T cells in response to Ag was enhanced in me(v+/-) T cells, particularly at lower Ag concentrations. These data demonstrate that the level of SHP-1 plays an important role in regulating the activation threshold of autoreactive T cells.     

LF 15-0195 inhibits the development of rat central nervous system autoimmunity by inducing long-lasting tolerance in autoreactive CD4 T cells

Experimental autoimmune encephalomyelitis (EAE) is a T cell-dependent autoimmune disease induced in susceptible animals by a single immunization with myelin basic protein (MBP). LF 15-0195 is a novel immunosuppressor that has been shown to have a potent immunosuppressive effect in several pathological manifestations. The purpose of this study was to investigate the effect of this drug on the induction and progression of established rat EAE and to dissect the mechanisms involved. We show that LF 15-0195 administration at the time of MBP immunization reduces the incidence and severity of EAE in Lewis rats. This drug also inhibits ongoing and passively induced EAE, indicating that LF 15-0195 affects already differentiated pathogenic lymphocytes. Compared with lymph node cells from untreated rats, lymphocytes from MBP-immunized rats treated with LF 15-0195 proliferated equally well in response to MBP in vitro, while their ability to produce effector cytokines and to transfer EAE into syngeneic recipients was significantly reduced. This phenomenon is stable and long-lasting. Indeed, neither IL-12 nor repeated stimulation with naive APC and MBP in vitro rendered MBP-specific CD4 T cells from protected rats encephalitogenic. In conclusion, LF 15-0195 treatment suppresses EAE by interfering with both the differentiation and effector functions of autoantigen-specific CD4 T cells.     

Studies on the mechanism of suppression of experimental allergic encephalomyelitis induced by myelin basic protein-cell conjugates

The mechanism of suppression of experimental allergic encephalomyelitis (EAE) induced in Lewis rats by pretreatment with myelin basic protein (MBP) coupled to syngeneic spleen leukocytes (SL) was examined. Studies on the kinetics of the tolerance induction showed that pretreatment with MBP-SL suppressed EAE if given 7 but not 3 days before the disease-inducing injection of MBP in Freund's complete adjuvant. Treatment with cyclophosphamide 48 hr before administration of MBP-SL completely abolished the suppression of EAE. Transfer of lymph node and spleen cells from MBP-syngeneic erythrocyte conjugate (MBP-RBC) but not MBP-SL-pretreated rats resulted in suppression of disease in recipients subsequently given a disease-inducing injection of MBP. Administration of MBP coupled to SL from the histocompatible rat strain F344 resulted in suppression of the MBP-induced proliferative response of spleen cells from Lewis rats which had been given a disease-inducing injection of MBP. Taken together these results are consistent with the suppression of EAE induced by MBP-SL being mediated by suppressor T cells.     

Treatment of experimental allergic encephalomyelitis (EAE) induced by guinea pig myelin basic protein epitope 72-85 with a human MBP(87-99) analogue and effects of cyclic peptides

Experimental autoimmune encephalomyelitis (EAE) is an inflammatory and demyelinating disease of the central nervous system and is an animal model of multiple sclerosis (MS). In the present report, a linear analogue and a series of cyclic semi-mimetic peptides were designed and synthesized based on the human myelin basic protein (MBP(87-99)) epitope (Val87-His-Phe-Phe-Lys-Asn-Ile-Val-Thr-Pro-Arg-Thr-Pro90) and on Copolymer I (a mixture of random polymers of Ala, Gln, Lys and Tyr used to treat MS). These analogues were designed looking for suppressors of EAE induced by guinea pig MBP(72-85) epitope (Gln-Lys-Ser-Gln-Arg-Ser-Gln-Asp-Glu-Asn-Pro-Val) in Lewis rats. The linear analogue [Arg91,Ala96]MBP(87-99), in which Arg substitutes Lys91 and Ala substitutes Pro96, was found to be a strong inhibitor which when administered to Lewis rats together with the encephalitogenic agonist MBP(72-85) completely prevented the induction of EAE. In contrast, three N- and C-termini amide-linked cyclic semi-mimetic peptides, [cyclo-Phe-Arg-Asn-Ile-Val-Thr-Ala-Acp (1), cyclo-Phe-Ala-Arg-Gln-Acp (2), cyclo-Tyr-Ala-Lys-Gln-Acp (3)] as well as a Lys side chain and C-terminous cyclic semi mimetic peptide cyclo(Lys, Acp)-Phe-Lys-Asn-Ile-Val-Thr-Ala-Acp (4) which contain segments of MBP(87-99) or are constituted from immunophoric residues of copolymer 1, were ineffective in inducing or inhibiting EAE in Lewis rats. However co-injection of cyclic analogues with MBP(72-85) delayed the onset of EAE indicating a modulatory effect on the EAE activity of MBP(72-85). These findings suggest that molecule length, size of cyclic moiety and backbone conformation are important elements for immunogenic activity. Moreover blockade of MBP(72-85) induced EAE by the unrelated peptide [Arg91,Ala56]MBP(87-99) could indicate that the mechanism of inhibition is not due to binding competition but rather due to the delivery of a negative signal by the antagonist which overcomes the agonist response possibly through the activation of antigen specific regulatory T cells.     

髓鞘碱性蛋白片段69-85诱导建立大鼠自身免疫性脑脊髓炎模型

目的探索以大鼠髓鞘碱性蛋白片段69-85（MBP69-85）为单一抗原,建立Wistar大鼠实验性自身免疫性脑脊髓炎（EAE）模型,并观察其病理改变。方法MBP69-85以生理盐水溶解,与完全福氏佐剂（CFA）充分混匀制备免疫乳剂;雌性Wistar大鼠70只,留取10只作为正常对照组,余者根据免疫乳剂组分的不同随机分为A、B、C组（n=20）。A组：MBP69-85每只50μg＋CFA（含卡介苗6 mg）;B组：MBP69-85每只25μg＋CFA（含卡介苗6 mg）;C组：MBP69-85每只25μg＋CFA（含卡介苗12 mg）。脑和脊髓组织切片进行HE染色,MBP及神经微丝（neurofilament,NF）免疫组化检测,观察神经组织的病理改变。结果A组内部分大鼠在免疫后第12-16天发病,表现为尾部及四肢无力或麻痹、斜颈等,平均临床症状评分为2.38±1.89;B、C组均未见发病;HE染色可见神经组织内炎细胞浸润,血管＂袖套＂样病灶形成;MBP及NF免疫组化染色显示病变组织内白质脱髓鞘及轴突损伤明显。结论EAE模型建立与免疫抗原的剂量有一定的依赖关系;佐剂中的卡介苗含量不是诱导大鼠发病的主要原因;本模型具有多发性硬化的典型临床表现及病理改变,是研究多发性硬化发病机制及治疗的可靠的动物模型。     

LF 15-0195 treatment protects against central nervous system autoimmunity by favoring the development of Foxp3-expressing regulatory CD4 T cells

Experimental autoimmune encephalomyelitis (EAE) is an instructive model for the human demyelinating disease multiple sclerosis. Lewis (LEW) rats immunized with myelin-basic protein (MBP) develop EAE characterized by a single episode of paralysis, from which they recover spontaneously and become refractory to a second induction of disease. LF 15-0195 is a novel molecule that has potent immunosuppressive effects in several immune-mediated pathological manifestations, including EAE. In the present study, we show that a 30-day course of LF 15-0195 treatment not only prevents MBP-immunized LEW rats from developing EAE but also preserves their refractory phase to reinduction of disease. This effect is Ag driven since it requires priming by the autoantigen during the drug administration. In contrast to other immunosuppressive drugs, short-term treatment with this drug induces a persistent tolerance with no rebound of EAE up to 4 mo after treatment withdrawal. This beneficial effect of LF 15-0195 on EAE does not result from the deletion of MBP-specific Vbeta8.2 encephalitogenic T cells. In contrast, this drug favors the differentiation of MBP-specific CD4 T cells into Foxp3-expressing regulatory T cells that, upon adoptive transfer in syngeneic recipients, prevent the development of actively induced EAE. Finally, we demonstrate that the tolerance induced by LF 15-0195 treatment is not dependent on the presence of TGF-beta. Together, these data demonstrate that short-term treatment with LF 15-0195 prevents MBP-immunized LEW rats from EAE by favoring the development of Foxp-3-expressing regulatory CD4 T cells.     

Autoaggressive T lymphocyte lines recognizing the encephalitogenic region of myelin basic protein: in vitro selection from unprimed rat T lymphocyte populations

Autoimmune T lymphocyte lines have been established from unprimed normal rat lymph node cell populations. In a first, negative-selection round, spontaneously proliferating (SMLR) T cells were eliminated by a pulse of BUdR followed by short wave light irradiation. In a second, positive-selection round, the SMLR-depleted populations were confronted with MBP presented by syngeneic spleen adherent cells. Reactive T cells were propagated until stable, permanent T lines were established. All lines were exclusively specific for the selecting antigen, MBP, and were restricted in recognition by determinants of the own MHC. All lines expressed the differentiation marker W3/25, but not OX8. Line vLe, which was derived from Lewis (LEW) rat lymphocytes, and which recognized the encephalitogenic sequence 48-88 of MBP, was extremely efficient in mediating EAE to normal untreated LEW rats. Doses of 1 X 10(6) and greater transferred lethal EAE, whereas transient although definite disease was caused by a minimum of 1 X 10(4) cells. Rats recovering from disease were resistant against subsequent active induction of EAE. In contrast, BN rat-derived line vBN was completely incapable of transferring EAE to syngeneic rats. This lack of encephalitogenicity was a property of the T line, because vLe cells transferred severe EAE to (LEW X BN)F1 hybrid rats, whereas none of hybrid rats injected with vBN cells showed any sign of disease. The data provide strong evidence in favor of the presence of potentially autoaggressive T clones in the normal immune system, and they might suggest that the actual proportion of these clones within the natural T cell repertoire is genetically determined.     

Does the frequency and avidity spectrum of the neuroantigen-specific T cells in the blood mirror the autoimmune process in the central nervous system of mice undergoing experimental allergic encephalomyelitis?

In humans, studies of autoreactive T cells that mediate multiple sclerosis have been largely confined to testing peripheral blood lymphocytes. Little is known how such measurements reflect the disease-mediating autoreactive T cells in the CNS. This information is also not available for murine experimental allergic encephalomyelitis (EAE); the low number of T cells that can be obtained from the blood or the brain of mice prevented such comparisons. We used single-cell resolution IFN-gamma ELISPOT assays to measure the frequencies and functional avidities of myelin basic protein (MBP:87-99)-specific CD4 cells in SJL mice immunized with this peptide. Functional MBP:87-99-specific IFN-gamma-producing cells were present in the CNS during clinical signs of EAE, but not during phases of recovery. In contrast, MBP:87-99-specific T cells persisted in the blood during all stages of the disease, and were also present in mice that did not develop EAE. Therefore, the increased frequency of MBP:87-99-reactive T cells in the blood reliably reflected the primed state, but not the inflammatory activity of these cells in the brain. The functional avidity of the MBP:87-99-reactive T cells was identical in the brain and blood and did not change over 2 mo as the mice progressed from acute to chronic EAE. Therefore, high-affinity T cells did not become selectively enriched in the target organ, and avidity maturation of the MBP:87-99-specific T cell repertoire did not occur in the observation period. The data may help the interpretation of measurements made with peripheral blood lymphocytes of multiple sclerosis patients.     

When engineered to produce latent TGF-beta1, antigen specific T cells down regulate Th1 cell-mediated autoimmune and Th2 cell-mediated allergic inflammatory processes

To determine whether T cells which produce large amounts of latent TGF-beta1 are capable of down-regulating autoimmune and allergic disease, myelin basic protein (MBP)-specific and ovalbumin (OVA)-specific BALB/c cloned Th1 cells were transduced with cDNA for murine TGF-beta1 by coculture with fibroblasts producing a genetically engineered retrovirus. The transduced MBP-specific Th1 cells were found to lose the capacity to provoke EAE in BALB/c mice, and to gain instead the ability to protect against EAE in (SJLxBALB/c) F1 mice immunized with proteolipid protein (PLP). This protective effect was not obtained with OVA-specific TGF-beta1 transduced Th1 cells. The transduced OVA-specific Th1 cells did protect against airway hyperreactivity induced by Th2-cell mediated responses to inhaled OVA. This effect was again antigen specific and it also could not be obtained with untransduced OVA-specific Th1 cells. In both cases these effects of antigen specific TGF-beta1 transduced T cells were nullified by administration of neutralizing anti-TGF-beta mAb. Thus, the antigen specificity of the cloned T cells allows the site-specific local delivery of therapeutic active TGF-beta1 to both Th1 and Th2 cell-mediated inflammatory infiltrates.     

Selective blocking of voltage-gated K+ channels improves experimental autoimmune encephalomyelitis and inhibits T cell activation

Kaliotoxin (KTX), a blocker of voltage-gated potassium channels (Kv), is highly selective for Kv1.1 and Kv1.3. First, Kv1.3 is expressed by T lymphocytes. Blockers of Kv1.3 inhibit T lymphocyte activation. Second, Kv1.1 is found in paranodal regions of axons in the central nervous system. Kv blockers improve the impaired neuronal conduction of demyelinated axons in vitro and potentiate the synaptic transmission. Therefore, we investigated the therapeutic properties of KTX via its immunosuppressive and symptomatic neurological effects, using experimental autoimmune encephalomyelitis (EAE), an animal model for multiple sclerosis. The T line cells used to induce adoptive EAE were myelin basic protein (MBP)-specific, constitutively contained mRNA for Kv1.3. and expressed Kv1.3. These channels were shown to be blocked by KTX. Activation is a crucial step for MBP T cells to become encephalitogenic. The addition of KTX during Ag-T cell activation led to a great reduction in the MBP T cell proliferative response, in the production of IL-2 and TNF, and in Ca(2+) influx. Furthermore, the addition of KTX during T cell activation in vitro led a decreased encephalitogenicity of MBP T cells. Moreover, KTX injected into Lewis rats impaired T cell function such as the delayed-type hypersensitivity. Lastly, the administration of this blocker of neuronal and lymphocyte channels to Lewis rats improved the symptoms of EAE. We conclude that KTX is a potent immunosuppressive agent with beneficial effects on the neurological symptoms of EAE.     

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.     

Functional heterogeneity among CD4+ encephalitogenic T cells in recruitment of CD8+ T cells in experimental autoimmune encephalomyelitis

Inoculation of Lewis rats with live or attenuated (irradiated or paraformaldehyde-fixed) CD4+ encephalitogenic T cells (S1 line) protects the recipients from transferred experimental autoimmune encephalomyelitis (tEAE) induced by S1 cells. A CD8+ T lymphocyte population specifically activated against the EAE-inducing S1 cells can be readily isolated from the lymphoid organs of pretreated animals. We show, in the present study, that encephalitogenic T cell lines derived from Lewis rats differ in their ability to induce resistance against tEAE in vivo and to stimulate CD8+ cell proliferation in vitro. We also demonstrate that the S19 line of encephalitogenic T cells, in combination with myelin basic protein (MBP), can stimulate CD8+ cell proliferation in vitro. The CD8+ cells generated in this way strongly suppress MBP-specific T cell proliferation in vitro. This combined effect of T cells and MBP was also evident in vivo. Neither S19 cells nor MBP alone induced resistance against S19-mediated tEAE, rather coinjection of these cells and MBP was required. Our results suggest that resistance to EAE is mediated by distinct populations of encephalitogenic T cells that activate Ts cells through different mechanisms. In some instances, both autoreactive T cells and their relevant autoantigen(s) may be needed to activate Ts cells in vivo.