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.     

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.     

Antigen processing of myelin basic protein is required prior to recognition by T cells inducing EAE.

The processing and presentation of whole myelin basic protein (MBP) and a 12 amino acid encephalitogenic peptide were investigated using MBP-immune and peptide-immune murine T cell lines. Myelin basic protein is the major component of central nervous system (CNS) white matter capable of inciting an autoimmune response which leads to the disease, experimental allergic encephalomyelitis (EAE), in a number of animal species. MBP-immune T cell lines caused a form of adoptively transferred EAE when injected into naive, syngeneic recipients. It has been found that both whole MBP and peptide required processing in order to induce proliferation of the T cell lines. The proliferative response was greatest when MBP was processed under conditions in which proteolysis was prevented. The demonstration that activation of encephalitogenic MBP immune T cells requires a processed form of MBP may have relevance to the human inflammatory CNS demyelinating condition, multiple sclerosis, for which EAE is the EAE is the prime animal model.     

T cell specificity for class II (I-A) and the encephalitogenic N-terminal epitope of the autoantigen myelin basic protein

The role of class II restriction in T cell recognition of an epitope of the autoantigen myelin basic protein (MBP) has been investigated. Encephalitogenic PL/J(H-2u) and (PL/J X SJL/J(H-2s))F1 ((PLSJ)F1) clones, isolated after immunization with intact MBP, recognize the N-terminal 11 amino acid residues of MBP in association with I-Au class II molecules. The synthetic peptide MBP 1-11 has been tested in vivo for induction of EAE. Clinical and histological EAE occurs in PL/J and (PLSJ)F1 mice but not SJL/J. The class II restriction of T cells primed with MBP 1-11 has been examined in primary cultures in vitro. Similar to encephalitogenic T cell clones, isolated after continuous selection in vitro, the population of MBP 1-11-specific proliferative PL/J and (PLSJ)F1 T cells, recognize this epitope in association with I-Au class II molecules. Not all MBP-specific T cell clones which are restricted to I-Au class II molecules cause autoimmune encephalomyelitis. The specificity of these non-encephalitogenic clones has been examined in this report. These clones also recognize MBP 1-11. Thus recognition of an encephalitogenic T cell epitope is not sufficient for induction of EAE.     

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.     

Serum degradation of myelin basic protein with loss of encephalitogenic activity: evidence for an enzymatic process.

Fibrin deposition in parallel with loss of myelin basic protein (MBP), an antigenic constituent of central nervous system (CNS) myelin, within the lesions of animals with experimental allergic encephalomyelitis (EAE) suggested that degradation of MBP by proteolytic activity associated with blood clotting might be an important immunopathologic event in this prototypic autoimmune disease. Following incubation in normal rat serum at 37 °C for more than 4 hr, but not to any comparable degree in plasma, MBP had little or no encephalitogenic activity when bioassayed in guinea pigs or rats. Fragments of increasingly lower molecular weight were demonstrable by polyacrylamide gel electrophoresis after addition of MBP to rat serum; no fragments appeared after incubating the protein in rat plasma. Little or no loss of encephalitogenic activity was observed when MBP was incubated in serum containing protease inhibitors. These findings indicate that the serum-mediated degradation of MBP and concomitant loss of encephalitogenic activity is due to an enzymatic process associated with the coagulation cascade or/and the complement, kallikrein or fibrinolytic pathways. Implications of these findings concerning EAE and the multiple sclerosis process in man are discussed.     

PHA activation of encephalitogenic T cells: in vitro line selection overcomes splenic suppression

In this study we compared myelin basic protein (MBP) and phytohemagglutinin (PHA) for their ability to induce proliferation and experimental autoimmune encephalomyelitis (EAE) transfer activity in mixed cell cultures obtained from spleen and lymph nodes versus highly selected MBP-specific T cell lines and clones. Established MBP-specific cells derived initially from immune lymph nodes attained both proliferative and EAE-transfer activities after in vitro activation with either MBP or PHA. In contrast, PHA was unable to induce immune spleen cells to transfer EAE, in spite of its potent mitogenic activity. On the basis of these results, we evaluated the in vitro proliferation and differentiation responses of MBP-specific T cells during the line selection process using cells derived from both immune lymph node and immune spleen. During the initial selection process with MBP, proliferation of MBP-specific T cell precursors from immunized spleen populations was reduced relative to lymph node cells. After antigen-dependent selection the encephalitogenic cells from either organ exhibited identical in vitro response characteristics. Freshly isolated immune spleen cells were potent suppressors of MBP-specific T cell proliferation suggesting that the in vitro differences between the two organs was due to splenic suppression of the encephalitogenic cells.     

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.     

Identification of encephalitogenic V beta-4-bearing T cells in SJL mice. Further evidence for the V region disease hypothesis?

Experimental allergic encephalomyelitis (EAE) is an autoimmune disease of the central nervous system mediated by T cells bearing TCR of restricted heterogeneity. Thus, in the murine PL strain, V beta-8.2 is used by 80% of the encephalitogenic T cells. This observation has led to the successful prevention and reversal of EAE by the in vivo use of mAb directed to these restricted gene products. In SJL mice, the V beta-17a gene product has been shown to be used by approximately 50% of encephalitogenic T cells subsequent to immunization with a myelin basic protein (MBP)-derived peptide. However, the other V beta genes used by encephalitogenic T cells in SJL EAE have remained uncharacterized. We now report, for the first time, the beta-chain-encoding DNA sequence of two encephalitogenic, MBP-reactive, SJL-derived T cell clones. These clones which are specific for H-2s and the carboxyl-terminus (amino acid 92-103) of MBP, use TCR encoded by V beta-4. In addition, we demonstrate that the transfer of EAE by a heterogenous SJL-derived encephalitogenic T cell line can be prevented using an anti-V beta-4 antibody in vivo. V beta-4 usage has been previously described in a H-2u/MBP amino-terminus-reactive encephalitogenic T cell. The present findings may thus further support the "V region-disease" hypothesis.     

Modulation of adoptive cell transfers in experimental allergic encephalomyelitis by antigen treatment of donors

Experimental allergic encephalomyelitis has been adoptively transferred using lymph node cells from Strain 13 guinea pig donors sensitized with purified encephalitogenic myelin basic protein. Adoptive cell transfer was used to examine the immunocompetence of lymph node cells obtained from guinea pigs protected from disease development by treatment with MBP. Lymph node cells from guinea pigs unresponsive to EAE challenge do not adoptively transfer disease. Cells obtained from guinea pigs treated with MBP following encephalitogenic challenge are competent in adoptive transfer with respect to pathologic lesions, but not clinical disease. The clinical and pathologic responses of recipients of the histocompatible lymphocyte populations are similar to those seen in the treatment-matched donor controls, suggesting that under these circumstances lymphoid cells, rather than circulating soluble factors, are responsible for disease induction and suppression.     

Suppression of experimental autoimmune encephalomyelitis by the oral administration of myelin basic protein

The oral administration of myelin basic protein (MBP) to Lewis rats prior to an encephalitogenic challenge resulted in total inhibition or a significant delay in the onset of experimental autoimmune encephalomyelitis (EAE). In vitro lymphocyte proliferative responses to MBP were significantly decreased in MBP-fed rats when compared with vehicle-fed controls. Suppression of EAE and in vitro proliferative responses to MBP were observed to be antigen specific, since oral feeding of a control protein exerted no suppressive effect. Moreover, the specificity of MBP-induced oral tolerance was shown to be species specific, since feeding guinea pig MBP (GPMBP) or human MBP (HuMBP) induced protection only against a GPMBP or HuMBP challenge, respectively. Conversely, Lewis rats could not be orally tolerized to the self antigen rat MBP.     

Encephalitogenic T cells in the B10.PL model of experimental allergic encephalomyelitis (EAE) are of the Th-1 lymphokine subtype

T helper cells reactive to myelin basic protein are clearly implicated in the pathogenesis of murine EAE. We have developed a T cell line, BML-1 that (1) is reactive to the encephalitogenic amino terminal nonapeptide (1-9NAC) of MBP, (2) is I-Au restricted, and (3) induces relapsing EAE in B10.PL (H-2u) mice. Measurement of the lymphokine profile of BML-1 revealed secretion of IL-2, interferon-gamma and lymphotoxin but not IL-4. This profile is consistent with the Th1/DTH subtype. Coculture of BML-1 with MBP-primed B cells shows that BML-1 does not provide significant helper function in vitro. In addition, BML-1 secretion of interferon-gamma was found to inhibit LPS-induced anti-MBP antibody responses. This suggested that anti-MBP antibodies may not be necessary for induction of EAE. Sera from mice, in which severe disease was induced with the 1-9NAC peptide and Bordetella pertussis, showed no development of serum antibodies to MBP. These data show that MBP-reactive Th cells of the Th-1/DTH subtype can induce EAE and do not provide Th function for anti-MBP responses and that serum anti-MBP antibodies are not found in peptide 1-9NAC-induced disease. T cell lines specific for encephalitogenic epitopes and characterized for lymphokine secretion will provide a useful tool for understanding the role of T cells in the induction of EAE.     

Suppression of experimental autoimmune encephalomyelitis by selective blockade of encephalitogenic T-cell infiltration of the central nervous system

Multiple sclerosis (MS) is a devastating neuroinflammatory disorder of the central nervous system (CNS) in which T cells that are reactive with major components of myelin sheaths have a central role. The receptor for advanced glycation end products (RAGE) is present on T cells, mononuclear phagocytes and endothelium. Its pro-inflammatory ligands, S100-calgranulins, are upregulated in MS and in the related rodent model, experimental autoimmune encephalomyelitis (EAE). Blockade of RAGE suppressed EAE when disease was induced by myelin basic protein (MBP) peptide or encephalitogenic T cells, or when EAE occurred spontaneously in T-cell receptor (TCR)-transgenic mice devoid of endogenous TCR-alpha and TCR-beta chains. Inhibition of RAGE markedly decreased infiltration of the CNS by immune and inflammatory cells. Transgenic mice with targeted overexpression of dominant-negative RAGE in CD4+ T cells were resistant to MBP-induced EAE. These data reinforce the importance of RAGE-ligand interactions in modulating properties of CD4+ T cells that infiltrate the CNS.     

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.     

Experimental allergic encephalomyelitis: basic protein regions responsible for delayed hypersensitivity

Three separate peptide regions were isolated from the chymotrypsin digest of the encephalitogenic basic protein from bovine myelin of the central nervous system. The peptides induced delayed type hypersensitivity (DTH) and elicited delayed skin reactivity in experimental animals. However, none of the isolated peptides was capable of inducing experimental allergic encephalomyelitis (EAE). The amino acid sequence of peptide CTP-3 (Gly-Ala-Glu-Gly-Gln-Lys-Pro-Gly-Phe-OH) and peptide CTP-la were found to overlap the C-terminal sequence of encephalitogenic peptides E (residue 112–125) and T8 (residue 65–74) of the basic protein, respectively. The third DTH inducing peptide, CB1-T1, (N-Acetyl-Ala-Ser-Ala-Gln-Lys-OH) was found to overlap the N-terminal sequence of the basic protein molecule. Common to the three DTH inducing peptides, to the basic protein and to the encephalitogenic peptides E-S and T8S is the X-X-X-Gln-Lys sequence. Isolation of the regions of the basic protein that are responsible for DTH provides antigens for the study of the mechanism of cellular immunity in EAE.     

Cryptic MBP epitope 1-20 is inducing autoimmune anterior uveitis without EAE in Lewis rats

Lewis rats immunized with myelin basic protein (MBP) developed experimental autoimmune encephalomyelitis (EAE) and associated anterior uveitis (AU). Although several cryptic epitopes of MBP have strong encephalitogenic and uveitogenic properties, the peptide corresponding to the MBP residues 1-20 was uniquely capable of inducing AU without EAE. In this study, we showed that acetylation of the N-terminal amino acid did not produce encephalitogenicity, did not enhance uveitogenicity, and did not improve T cell proliferation in Lewis rats. The cytokine production profile induced by MBP(1-20) immunization was consistent with a Th1 response. In MBP-injected rats and in peptide-injected rats, the frequency of the IFN-gamma-secreting cells in MBP(69-89)-stimulated T cells was significantly higher than the frequency of IFN-gamma-secreting cells in MBP(1-20)-stimulated T cells. However, similar numbers of IFN-gamma-producing specific cells were found in the eyes of MBP(69-89) and MBP(1-20) immunized rats. In these rats, the iris-infiltrating cells consisted of a much higher percentage of CD4(+) T cells expressing L-selectin (CD62L) than did those cells found in the spinal cord. The results demonstrate that MBP(1-20) is immunogenic and uveitogenic, although it induced only weak proliferation and weak Th1 reaction. The fact that T cells with the same specificity have different effects on target organs suggested that, in the eye and spinal cord, a distinct mechanism might mediate the recruitment of cells to these organs.     

Successful immunization against experimental allergic encephalomyelitis with myelin basic protein-sensitized allogeneic lymphocytes

Prevention and suppression of experimental allergic encephalomyelitis were demonstrated in rats, guinea pigs, and rabbits immunized with allogeneic, but not with syngeneic lymphocytes from susceptible donors sensitized to myelin basic protein (MBP). Donor lymphnode, splenic, or peripheral blood lymphocytes were effective in inducing a state of unresponsiveness to an encephalitogenic challenge in either of the three species. Unresponsiveness was not obtained in recipients immunized with sensitized allogenic lymphocytes and simulatenously challenged with MBP suggesting that a time lapse between immunization and challenge is necessary for the development of protective immunity. Induced in immunized recipients, unresponsiveness was transferred into normal syngeneic recipients with immunoglobulin-G (IgG) isolated from protected donors before challenge. Furthermore, both immunized and IgG recipients failed to develop cell-mediated immunity after challenge with MBP. The results show that prevention and suppression of EAE was mediated by antibodies which inhibited the development of delayed type hypersensitivity to the challenging antigen.     

Regulation of the effector stages of experimental autoimmune encephalomyelitis via neuroantigen-specific tolerance induction. II. Fine specificity of effector T cell inhibition.

Ag-specific tolerance induced by the i.v. administration of splenocytes coupled with mouse spinal cord homogenate, containing a mixture of myelin Ag, dramatically inhibits development and expression of clinical and histologic signs of both active and adoptive forms of relapsing experimental autoimmune encephalomyelitis (R-EAE) in the SJL/J host. Here we examined the dose-dependency, route of tolerogen administration, and fine neuroantigen specificity of inhibition of adoptive R-EAE. Expression of clinical R-EAE induced by a polyclonal population of bovine myelin basic protein (MBP)-specific effector T cells was dramatically inhibited in a dose-dependent manner following the i.v., but not s.c. or i.p., injection of MBP-coupled splenocytes. The exquisite Ag specificity of the inhibition was evident by the observation that splenocytes coupled with intact bovine MBP or species variants of MBP homologous with bovine MBP within the major encephalitogenic region (amino acids 84-104), but not with proteolipid protein or mouse kidney homogenate, were able to suppress disease expression. Splenocytes coupled with the MBP84-104 peptide, containing a nested set of the major SJL/J encephalitogenic epitopes, completely inhibited peptide-specific T cell responses, but only partially inhibited the expression of disease transferred by T cells specific for intact MBP, suggesting the participation of T cell responses specific for additional MBP determinants in disease pathogenesis. However, splenocytes coupled with previously identified minor SJL/J encephalitogenic epitopes (MBP91-104 or MBP17-27), or with the Lewis rat major encephalitogenic epitope (MBP68-86), did not suppress disease expression. Collectively, the results demonstrate that MBP84-104-specific T cells and T cells specific for an as yet unidentified MBP epitope(s) contribute to the pathology of R-EAE. In addition, the results demonstrate that peptide-specific tolerance induction appears to have potential for the treatment of T cell-mediated inflammatory diseases.     

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.