Epitope spreading initiates in the CNS in two mouse models of multiple sclerosis

Chronic progression of two T cell-mediated central nervous system (CNS) demyelinating models of multiple sclerosis, relapsing EAE (R-EAE) and Theiler's murine encephalomyelitis virus-induced demyelinating disease (TMEV-IDD) is dependent on the activation of T cells to endogenous myelin epitopes (epitope spreading). Using transfer of carboxyfluorescein succinyl ester (CFSE)-labeled T-cell receptor (TCR)-transgenic T cells and mixed bone marrow chimeras, we show that activation of naive proteolipid protein (PLP)139-151-specific T cells in SJL mice undergoing PLP178-191-induced R-EAE or TMEV-IDD occurs directly in the CNS and not in the cervical lymph nodes or other peripheral lymphoid organs. Examination of the antigen-presentation capacity of antigen-presenting cell (APC) populations purified from the CNS of mice with PLP178-191-induced R-EAE shows that only F4/80-CD11c+CD45hi dendritic cells (DCs) efficiently present endogenous antigen to activate naive PLP139-151-specific T cells in vitro. In contrast, DCs as well as F4/80+CD45hi macrophages and F4/80+CD45lo microglia activate a PLP139-151-specific helper T cell line. The data suggest that naive T cells enter the inflamed CNS and are activated by local APCs, possibly DCs, to initiate epitope spreading.     

A structurally available encephalitogenic epitope of myelin oligodendrocyte glycoprotein specifically induces a diversified pathogenic autoimmune response

Multiple sclerosis is an inflammatory disease of the CNS that involves immune reactivity against myelin oligodendrocyte glycoprotein (MOG), a type I transmembrane protein located at the outer surface of CNS myelin. The epitope MOG92-106 is a DR4-restricted Th cell epitope and a target for demyelinating autoantibodies. In this study, we show that the immune response elicited by immunization with this epitope is qualitatively different from immune responses induced by the well-defined epitopes myelin basic protein (MBP) 84-96 and proteolipid protein (PLP) 139-151. Mice with MOG92-106-, but not with MBP84-96- or PLP139-151-induced experimental autoimmune encephalomyelitis developed extensive B cell reactivity against secondary myelin Ags. These secondary Abs were directed against a set of encephalitogenic peptide Ags derived from MBP and PLP as well as a broad range of epitopes spanning the complete MBP sequence. The observed diversification of the B cell reactivity represents a simultaneous spread toward a broad range of antigenic epitopes and differs markedly from T cell epitope spreading that follows a sequential cascade. The Abs were of the isotypes IgG1 and IgG2b, indicating that endogenously recruited B cells receive help from activated T cells. In sharp contrast, B cell reactivity in MBP84-96- and PLP139-151-induced experimental autoimmune encephalomyelitis was directed against the disease-inducing Ag only. These data provide direct evidence that the nature of the endogenously acquired immune reactivity during organ-specific autoimmunity critically depends on the disease-inducing Ag. They further demonstrate that the epitope MOG92-106 has the specific capacity to induce a widespread autoimmune response.     

Lymphocytes from SJL/J mice immunized with spinal cord respond selectively to a peptide of proteolipid protein and transfer relapsing demyelinating experimental autoimmune encephalomyelitis.

Relapsing experimental autoimmune encephalomyelitis (R-EAE) can be induced in SJL/J mice by immunization with spinal cord homogenate and adjuvant. The specific Ag(s) responsible for acute disease and subsequent relapses in this model is unknown. Myelin basic protein (BP), an encephalitogenic peptide of BP (BP 87-99), and proteolipid protein (PLP) can each induce R-EAE in SJL/J mice, and a peptide of PLP (PLP 139-151) has been reported to induce acute EAE. To determine the encephalitogens in cord-immunized mice with R-EAE, the in vitro proliferative responses of lymph node cells (LNC) and central nervous system mononuclear cells to BP, BP peptides, and PLP peptides were examined during acute EAE and during relapses. LNC responded only to PLP peptides 139-151 and 141-151 and did not respond to BP or its peptides during acute or chronic disease. Central nervous system mononuclear cells also preferentially responded to PLP 139-151 and 141-151 during acute and relapsing disease. A PLP 139-151 peptide-specific Th cell line was selected from LNC of cord-immunized donors. Five million peptide-specific line cells transferred severe relapsing demyelinating EAE to naive recipients. We conclude that PLP peptide 139-151 is the major encephalitogen for R-EAE in cord-immunized SJL/J mice. We demonstrate for the first time that Th cells specific for this peptide are sufficient to transfer relapsing demyelinating EAE. The predominance of a PLP immune response rather than a BP response in SJL/J mice suggests that genetic background may determine the predominant myelin Ag response in human demyelinating diseases such as multiple sclerosis.     

Synthetic Peptide dendrimers block the development and expression of experimental allergic encephalomyelitis

Multiple Ag peptides (MAPs) containing eight proteolipid protein (PLP)(139-151) peptides arranged around a dendrimeric branched lysine core were used to influence the expression and development of relapsing experimental allergic encephalomyelitis (EAE) in SJL mice. The PLP(139-151) MAPs were very efficient agents in preventing the development of clinical disease when administered after immunization with the PLP(139-151) monomeric encephalitogenic peptide in CFA. The treatment effect with these MAPs was peptide specific; irrelevant multimeric peptides such as guinea pig myelin basic protein GPBP(72-84) MAP (a dendrimeric octamer composed of the 72-84 peptide) and PLP(178-191) MAP (a dendrimeric octamer composed of the PLP(178-191) peptide) had no treatment effect on PLP(139-151)-induced EAE. PLP(139-151) MAP treatment initiated after clinical signs of paralysis also altered the subsequent course of EAE; it limited developing signs of paralysis and effectively limited the severity and number of disease relapses in MAP-treated mice over a 60-day observation period. PLP(139-151) MAP therapy initiated before disease onset acts to limit the numbers of Th17 and IFN-gamma-producing cells that enter into the CNS. However, Foxp3(+) cells entered the CNS in numbers equivalent for nontreated and PLP(139-151) MAP-treated animals. The net effect of PLP(139-151) MAP treatment dramatically increases the ratio of Foxp3(+) cells to Th17 and IFN-gamma-producing cells in the CNS of PLP(139-151) MAP-treated animals.     

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.     

Identification and characterization of a second encephalitogenic determinant of myelin proteolipid protein (residues 178-191) for SJL mice.

We previously described a synthetic peptide of myelin proteolipid protein (PLP), peptide 139-151, which induces experimental allergic encephalomyelitis in SJL/J (H-2s) mice. We have now identified an additional determinant, PLP residues 178-191, that is also a potent encephalitogen in this strain. When PLP peptide 178-191 was compared with peptide 139-151 on an equimolar basis, the day of onset of disease induced by PLP 178-191 was earlier, but the incidence, severity, and histologic features were indistinguishable. Lymph node cells from animals immunized with the whole PLP molecule responded to both PLP 178-191 and 139-151, suggesting immunologic codominance of the two epitopes. PLP 178-191 elicited stronger proliferative responses and this may relate to the earlier onset of disease induced with this peptide. Two CD4+, peptide-specific, I-A(s)-restricted T cell lines, selected by stimulation of lymph node cells with either PLP 178-191 or 139-151, were each encephalitogenic in naive syngeneic mice. The presence of multiple encephalitogenic codominant PLP epitopes within a single mouse strain emphasizes the complexity of the immune response to PLP and its potential as a target Ag in autoimmune demyelinating diseases.     

Monomeric recombinant TCR ligand reduces relapse rate and severity of experimental autoimmune encephalomyelitis in SJL/J mice through cytokine switch

Our previous studies demonstrated that oligomeric recombinant TCR ligands (RTL) can treat clinical signs of experimental autoimmune encephalomyelitis (EAE) and induce long-term T cell tolerance against encephalitogenic peptides. In the current study, we produced a monomeric I-A(s)/PLP 139-151 peptide construct (RTL401) suitable for use in SJL/J mice that develop relapsing disease after injection of PLP 139-151 peptide in CFA. RTL401 given i.v. or s.c. but not empty RTL400 or free PLP 139-151 peptide prevented relapses and significantly reduced clinical severity of EAE induced by PLP 139-151 peptide in SJL/J or (C57BL/6 x SJL)F(1) mice, but did not inhibit EAE induced by PLP 178-191 or MBP 84-104 peptides in SJL/J mice, or MOG 35-55 peptide in (C57BL/6 x SJL/J)F(1) mice. RTL treatment of EAE caused stable or enhanced T cell proliferation and secretion of IL-10 in the periphery, but reduced secretion of inflammatory cytokines and chemokines. In CNS, there was a modest reduction of inflammatory cells, reduced expression of very late activation Ag-4, lymphocyte function-associated Ag-1, and inflammatory cytokines, chemokines, and chemokine receptors, but enhanced expression of Th2-related factors, IL-10, TGF-beta3, and CCR3. These results suggest that monomeric RTL therapy induces a cytokine switch that curbs the encephalitogenic potential of PLP 139-151-specific T cells without fully preventing their entry into CNS, wherein they reduce the severity of inflammation. This mechanism differs from that observed using oligomeric RTL therapy in other EAE models. These results strongly support the clinical application of this novel class of peptide/MHC class II constructs in patients with multiple sclerosis who have focused T cell responses to known encephalitogenic myelin peptides.     

Functional activation of myelin-specific T cells by virus-induced molecular mimicry

Molecular mimicry is the process by which T cells activated in response to determinants on an infecting microorganism cross-react with self epitopes, leading to an autoimmune disease. Normally, infection of SJL/J mice with the BeAn strain of Theiler's murine encephalomyelitis virus (TMEV) results in a persistent CNS infection, leading to a chronic progressive, CD4(+) T cell-mediated demyelinating disease. Myelin damage is initiated by T cell responses to virus persisting in CNS APCs, and progressive demyelinating disease (50 days postinfection) is perpetuated by myelin epitope-specific CD4(+) T cells activated by epitope spreading. We developed an infectious model of molecular mimicry by inserting a sequence encompassing the immunodominant myelin epitope, proteolipid protein (PLP) 139-151, into the coding region of a nonpathogenic TMEV variant. PLP139-TMEV-infected mice developed a rapid onset paralytic inflammatory, demyelinating disease paralleled by the activation of PLP139-151-specific CD4(+) Th1 responses within 10-14 days postinfection. The current studies demonstrate that the early onset demyelinating disease induced by PLP139-TMEV is the direct result of autoreactive PLP139-151-specific CD4(+) T cell responses. PLP139-151-specific CD4(+) T cells from PLP139-TMEV-infected mice transferred demyelinating disease to naive recipients and PLP139-151-specific tolerance before infection prevented clinical disease. Finally, infection with the mimic virus at sites peripheral to the CNS induced early demyelinating disease, suggesting that the PLP139-151-specific CD4(+) T cells could be activated in the periphery and traffic to the CNS. Collectively, infection with PLP139-151 mimic encoding TMEV serves as an excellent model for molecular mimicry by inducing pathologic myelin-specific CD4(+) T cells via a natural virus infection.     

Detection of autoreactive myelin proteolipid protein 139-151-specific T cells by using MHC II (IAs) tetramers

Detection of autoreactive T cells using MHC II tetramers is difficult because of the low affinity of their TCR. We have generated a class II tetramer using the IA(s) class II molecule combined with an autoantigenic peptide from myelin proteolipid protein (PLP; PLP(139-151)) and used it to analyze myelin PLP(139-151)-reactive T cells. Using monomers and multimerized complexes labeled with PE, we confirmed the specificity of the reagent by bioassay and flow cytometry. The IA(s) tetramers stimulated and stained the PLP(139-151)-specific 5B6 TCR transgenic T cells and a polyclonal cell line specific for PLP(139-151), but not a control T cell line specific for PLP(178-191). We used this reagent to optimize conditions to detect low affinity autoreactive T cells. We found that high pH ( approximately 8.0) and neuraminidase treatment enhances the staining capacity of PLP(139-151) tetramer without compromising specificity. Furthermore, we found that induction of calcium fluxing by tetramers in T cells may be used as a sensitive measure to detect autoreactive T cells with a low affinity. Taken together, the data show that the tetrameric reagent binds and stimulates PLP(139-151)-reactive T cells with specificity. This tetrameric reagent will be useful in studying the evolution of PLP(139-151)-specific repertoire in naive mice and its expansion during the autoimmune disease experimental autoimmune encephalomyelitis.     

Epitope spreading is not required for relapses in experimental autoimmune encephalomyelitis

The sequential emergence of specific T lymphocyte-mediated immune reactivity directed against multiple distinct myelin epitopes (epitope spreading) has been associated with clinical relapses in experimental autoimmune encephalomyelitis (EAE), an animal model of multiple sclerosis (MS). Based on this association, an appealing and plausible model for immune-mediated progression of the advancing clinical course in MS and EAE has been proposed in which epitope spreading is the cause of clinical relapses in T cell-mediated CNS inflammatory diseases. However, the observed association between epitope spreading and disease progression is not universal, and absolute requirements for epitope spreading in progressive EAE have not been tested in the absence of multiple T cell specificities, because most prior studies have been conducted in immunocompetent mouse strains that possessed broad TCR repertoires. Consequently, the precise nature of a causal relationship between epitope spreading and disease progression remains uncertain. To determine whether relapsing or progressive EAE can occur in the absence of epitope spreading, we evaluated the course of disease in mice which possessed only a single myelin-specific TCR. These mice (transgenic/SCID +/+) exhibited a progressive and sometimes remitting/relapsing disease course in the absence of immune reactivity to multiple, spreading myelin epitopes. The results provide direct experimental evidence relevant to discussions on the mechanisms of disease progression in MS and EAE.     

Fine specificity of CD4+ T cell responses to the dominant encephalitogenic PLP 139-151 peptide in SJL/J mice

PLP 139-151(S) is the major encephalitogenic epitope of PLP in the SJL/J mouse. CD4⁺ T cells specific for PLP 139-151(S) induce a relapsing-remitting form of EAE which is similar to the human demyelinating disease MS in both clinical course and histopathology. We are interested in events involved in activation of autoreactive T cells and how to specifically regulate these immune response to both prevent and treat ongoing demyelinating disease. In the current study, we examined the effect of both amino acid substitutions and deletions in the native PLP 139-151(S) peptide to identify which residues are critical for immunogenicity and encephalitogenicity. Conservative and nonconservative substitutions at position 145 diminished or completely destroyed the encephalitogenic potential of the peptide without affecting the ability to recall a proliferative response in lymph node T cells primed with the native PLP 139-151(S) peptide indicating an interesting dichotomy between ability to induce T cell proliferation and ability to induce active clinical disease. In addition, tryptophan at position 144 was identified as a critical TCR contact site as a peptide containing an alanine for tryptophan at this position (A144) primed a unique population of T cells which did not cross react with the native PLP 139-151(S). In addition, A144 was unable to stimulate PLP 139-151(S)-specific T cells in vitro or to induce active relapsing EAE in vivo. The significance of these results to the potential development of new strategies for preventing and treating T cell-mediated autoimmune diseases is discussed.Special issue dedicated to Dr. Majorie B. Lees.     

Location of a new encephalitogenic epitope (residues 43 to 64) in proteolipid protein that induces relapsing experimental autoimmune encephalomyelitis in PL/J and (SJL x PL)F1 mice.

Synthetic peptides of proteolipid protein (PLP) were screened for their ability to induce experimental autoimmune encephalomyelitis (EAE) in SJL/J, PL/J, and (SJL x PL)F1 mice, and T cell lines were selected by stimulation of lymph node cells with PLP peptides. PLP 141-151 was found to be less encephalitogenic in SJL/J mice than PLP 139-151, due to deletion of two amino acids from the amino-terminal end. PLP 139-151 immunization induced relapsing EAE in SJL/J and F1 mice but not PL/J mice. In contrast, PLP 43-64 induced relapsing EAE in PL/J and F1 mice but not SJL/J mice. F1 T cell lines specific for either PLP 43-64 or PLP 139-151 adoptively transferred demyelinating EAE to naive F1 recipients. Haplotypes H-2s and H-2u appear to be immunologically co-dominant in F1 mice in the PLP EAE system, which differs from the H-2u dominance in F1 mice in the myelin basic protein EAE system. The identification of a PLP peptide that is encephalitogenic in PL/J mice, in addition to the previous demonstration of PLP peptides that are encephalitogenic for SWR mice (PLP 103-116) and SJL/J mice (PLP 139-151), lends support to a role for PLP as a target Ag in autoimmune demyelinating diseases.     

CD28 costimulatory blockade exacerbates disease severity and accelerates epitope spreading in a virus-induced autoimmune disease

Theiler's murine encephalomyelitis virus (TMEV) is a natural mouse pathogen which causes a lifelong persistent infection of the central nervous system (CNS) accompanied by T-cell-mediated myelin destruction leading to chronic, progressive hind limb paralysis. TMEV-induced demyelinating disease (TMEV-IDD) is considered to be a highly relevant animal model for the human autoimmune disease multiple sclerosis (MS), which is thought to be initiated as a secondary consequence of a virus infection. Although TMEV-IDD is initiated by virus-specific CD4(+) T cells targeting CNS-persistent virus, CD4(+) T-cell responses against self myelin protein epitopes activated via epitope spreading contribute to chronic disease pathogenesis. We thus examined the ability of antibodies directed against B7 costimulatory molecules to regulate this chronic virus-induced immunopathologic process. Contrary to previous studies showing that blockade of B7-CD28 costimulatory interactions inhibit the initiation of experimental autoimmune encephalomyelitis, treatment of SJL mice at the time of TMEV infection with murine CTLA-4 immunoglobulin or a combination of anti-B7-1 and anti-B7-2 antibodies significantly enhanced clinical disease severity. Costimulatory blockade inhibited early TMEV-specific T-cell and antibody responses critical in clearing peripheral virus infection. The inhibition of virus-specific immune responses led to significantly increased CNS viral titers resulting in increased damage to myelin-producing oligodendrocytes. Following clearance of the costimulatory antagonists, epitope spreading to myelin epitopes was accelerated as a result of the increased availability of myelin epitopes leading to a more severe chronic disease course. Our results raise concern about the potential use of B7-CD28 costimulatory blockade to treat human autoimmune diseases potentially associated with acute or persistent virus infections.     

Successful treatment of paralytic relapses in adoptive experimental autoimmune encephalomyelitis via neuroantigen-specific tolerance.

We have previously demonstrated that Ag-specific tolerance induced by the i.v. administration of splenocytes coupled with neuroantigens, such as mouse spinal cord homogenate, myelin basic protein (MBP), and proteolipid protein, and their encephalitogenic peptides, results in dramatic inhibition of clinical and histologic signs of both actively induced and adoptively transferred relapsing experimental autoimmune encephalomyelitis (R-EAE). We report here that the administration of splenocytes coupled with mouse spinal cord homogenate (i.e., a mixture of neuroantigens), after the first paralytic episode of adoptive R-EAE triggered by MBP-specific T cells but before the appearance of the first relapse, effectively reduced the onset and severity of all subsequent relapses, as determined by both clinical and pathologic criteria. In contrast, the i.v. administration of splenocytes coupled with MBP (i.e., the specificity of the initiating T cell response), under similar conditions, effectively inhibited the initial clinical relapse, but subsequent relapses occurred with the same incidence rate and severity as those in control animals. Collectively, these results demonstrate that neuroantigen-specific tolerance is effective at specifically down-regulating an ongoing autoimmune response. This may have potential clinical applicability for treatment of autoimmune diseases. The results also support the hypothesis that the neuroantigen specificity of later relapses of R-EAE may be due to effector T cells with specificities different from those that triggered the initial clinical episode. Thus, potential therapy for the advanced stages of R-EAE, and perhaps other autoimmune diseases, may have to be directed not simply against the effector cells initiating the disease but also against effector cells with differing specificities recruited as a result of tissue damage occurring in the initial acute disease.     

Surges of increased T cell reactivity to an encephalitogenic region of myelin proteolipid protein occur more often in patients with multiple sclerosis than in healthy subjects

We have previously shown that patients with multiple sclerosis (MS) have increased T cell responses to the immunodominant region (residues 184-209) of myelin proteolipid protein (PLP). The present study investigated whether this reactivity fluctuates over time and correlates with disease activity. We performed monthly limiting dilution assays for 12-16 mo in four healthy subjects and five patients with relapsing-remitting MS to quantify the frequencies of circulating T cells proliferating in response to PLP(41-58), PLP(184-199), PLP(190-209), myelin basic protein (MBP), MBP(82-100), and tetanus toxoid. Disease activity was monitored by clinical assessment and gadolinium-enhanced magnetic resonance imaging of the brain. There were fluctuations in the frequencies of autoreactive T cells in all subjects. Compared with healthy controls, MS patients had significantly more frequent surges of T cells reactive to the 184-209 region of PLP, but infrequent surges of T cell reactivity to MBP(82-100). There was temporal clustering of the surges of T cell reactivity to MBP(82-100) and MBP, suggesting T cell activation by environmental stimuli. Some clinical relapses were preceded by surges of T cell reactivity to PLP(184-209), and in one patient there was significant correlation between the frequency of T cells reactive to PLP(184-199) and the total number of gadolinium-enhancing magnetic resonance imaging lesions. However, other relapses were not associated with surges of T cell reactivity to the Ags tested. T cells reactive to PLP(184-209) may contribute to the development of some of the CNS lesions in MS.     

SJL Mice Infected with Acanthamoeba castellanii Develop Central Nervous System Autoimmunity through the Generation of Cross-Reactive T Cells for Myelin Antigens

We recently reported that Acanthamoeba castellanii (ACA), an opportunistic pathogen of the central nervous system (CNS) possesses mimicry epitopes for proteolipid protein (PLP) 139–151 and myelin basic protein 89–101, and that the epitopes induce experimental autoimmune encephalomyelitis (EAE) in SJL mice reminiscent of the diseases induced with their corresponding cognate peptides. We now demonstrate that mice infected with ACA also show the generation of cross-reactive T cells, predominantly for PLP 139–151, as evaluated by T cell proliferation and IA^s/dextramer staining. We verified that PLP 139–151-sensitized lymphocytes generated in infected mice contained a high proportion of T helper 1 cytokine-producing cells, and they can transfer disease to naïve animals. Likewise, the animals first primed with suboptimal dose of PLP 139–151 and later infected with ACA, developed EAE, suggesting that ACA infection can trigger CNS autoimmunity in the presence of preexisting repertoire of autoreactive T cells. Taken together, the data provide novel insights into the pathogenesis of Acanthamoeba infections, and the potential role of infectious agents with mimicry epitopes to self-antigens in the pathogenesis of CNS diseases such as multiple sclerosis.     

Identification of an encephalitogenic determinant of myelin proteolipid protein for SJL mice

PLP is the major protein constituent of central nervous system myelin. We have previously shown that SJL/J (H-2s) mice develop an acute form of EAE after immunization with PLP. The purpose of the present study was to identify an encephalitogenic determinant of PLP for SJL mice. We immunized SJL/J mice with a synthetic peptide identical to residues 130-147 QAHSLERVCHCLGKWLGH of murine PLP, a sequence having an amphipathic alpha-helical conformation. Although it did not induce disease, an overlapping peptide containing residues 139-154 HCLGKWLGHPDKFVGI was encephalitogenic. Immunization with this peptide induced severe clinical and histologic EAE in 3 of 20 mice. T cell enriched ILN cells from these mice responded specifically (3H-thymidine incorporation) to this peptide as well as to shorter analogues of this domain containing serine in place of cysteine at residues 138 and 140. Immunization with the serine-substituted PLP peptides 137-151 VSHSLGKWLGHPDKF and 139-151 HSLGKWLGHPDKF induced severe, acute EAE in 4 of 9 and 15 of 15 SJL mice, respectively, and their T cell enriched ILN cells responded not only to the analogues, but also to the native PLP sequence 139-154. These results indicate that residues 139-151 of murine PLP is an encephalitogenic determinant for SJL mice. Furthermore, like the PLP encephalitogenic domain for SWR (H-2q) mice, this determinant is also a T cell epitope with a coding sequence at the end of an exon.     

Suppressive immunization with DNA encoding a self-peptide prevents autoimmune disease: modulation of T cell costimulation

Usually we rely on vaccination to promote an immune response to a pathogenic microbe. In this study, we demonstrate a suppressive from of vaccination, with DNA encoding a minigene for residues 139-151 of myelin proteolipid protein (PLP139-151), a pathogenic self-Ag. This suppressive vaccination attenuates a prototypic autoimmune disease, experimental autoimmune encephalomyelitis, which presents clinically with paralysis. Proliferative responses and production of the Th1 cytokines, IL-2 and IFN-gamma, were reduced in T cells responsive to PLP139-151. In the brains of mice that were successfully vaccinated, mRNA for IL-2, IL-15, and IFN-gamma were reduced. A mechanism underlying the reduction in severity and incidence of paralytic autoimmune disease and the reduction in Th1 cytokines involves altered costimulation of T cells; loading of APCs with DNA encoding PLP139-151 reduced the capacity of a T cell line reactive to PLP139-151 to proliferate even in the presence of exogenous CD28 costimulation. DNA immunization with the myelin minigene for PLP-altered expression of B7.1 (CD80), and B7.2 (CD86) on APCs in the spleen. Suppressive immunization against self-Ags encoded by DNA may be exploited to treat autoimmune diseases.     

T cell repertoire diversity is required for relapses in myelin oligodendrocyte glycoprotein-induced experimental autoimmune encephalomyelitis

Comparison of TCRalphabeta repertoires of myelin oligodendrocyte glycoprotein (MOG)-specific T lymphocytes in C57BL/6 and TdT-deficient littermates (TdT(-/-)) generated during experimental autoimmune encephalomyelitis (EAE) highlights a link between a diversified TCRalphabeta repertoire and EAE relapses. At the onset of the disease, the EAE-severity is identical in TdT(+/-) and TdT(-/-) mice and the neuropathologic public MOG-specific T cell repertoires express closely similar public Valpha-Jalpha and Vbeta-Jbeta rearrangements in both strains. However, whereas TdT(+/+) and TdT(+/-) mice undergo successive EAE relapses, TdT(-/-) mice recover definitively and the lack of relapses does not stem from dominant regulatory mechanisms. During the first relapse of the disease in TdT(+/-) mice, new public Valpha-Jalpha and Vbeta-Jbeta rearrangements emerge that are distinct from those detected at the onset of the disease. Most of these rearrangements contain N additions and are found in CNS-infiltrating T lymphocytes. Furthermore, CD4(+) T splenocytes bearing these rearrangements proliferate to the immunodominant epitope of MOG and not to other immunodominant epitopes of proteolipid protein and myelin basic protein autoantigens, excluding epitope spreading to these myelin proteins. Thus, in addition to epitope spreading, a novel mechanism involving TCRalphabeta repertoire diversification contributes to autoimmune progression.     

Inhibition of murine relapsing experimental autoimmune encephalomyelitis by immune tolerance to proteolipid protein and its encephalitogenic peptides.

Tolerization of SJL/J mice with splenocytes coupled with proteolipid protein (PLP), the major protein component of central nervous system myelin, resulted in dramatic inhibition of relapsing experimental autoimmune encephalomyelitis (R-EAE) induced by mouse spinal cord homogenate (MSCH). Mice tolerized with splenocytes coupled with MSCH (a complex mixture of neuroantigens) or with purified PLP, but not purified myelin basic protein, were resistant to the development of clinical and histologic R-EAE. In addition, mice rendered tolerant to an encephalitogenic peptide of PLP were significantly protected, whereas mice tolerized to a nonencephalitogenic peptide of PLP were highly susceptible, to the induction of MSCH-induced R-EAE. Thus, immune responses directed against encephalitogenic regions of PLP appear to play a major role in the development of R-EAE induced by MSCH in SJL/J mice. These results also indicate that determinant-specific immune tolerance is a feasible approach to the regulation of a disease that involves autoimmune responses to a variety of Ag.