The myelin basic protein-specific T cell repertoire in (transgenic) Lewis rat/SCID mouse chimeras: preferential Vβ8.2 T cell receptor usage depends on an intact Lewis thymic microenvironment

In the Lewis rat, myelin basic protein (MBP)-specific, encephalitogenic T cells preferentially recognize sequence 68–88, and use the Vβ8.2 gene to encode their T cell receptors. To analyze the structural prerequisites for the development of the MBP-specific T cell repertoire, we reconstituted severe-combined immunodeficient (SCID) mice with fetal (embryonic day 15–16) Lewis rat lymphoid tissue, and then isolated MBP-specific T cell lines from the adult chimeras after immunization. Two types of chimera were constructed: SCID mice reconstituted with rat fetal liver cells only, allowing T cell maturation within a chimeric SCID thymus consisting of mouse thymic epithelium and rat interdigitating dendritic cells, and SCID mice reconstituted with rat fetal liver cells and rat fetal thymus grafts, allowing T cell maturation within the chimeric SCID and the intact Lewis rat thymic microenvironment. Without exception, the T cell lines isolated from MBP-immunized SCID chimeras were restricted by MHC class II of the Lewis rat (RT1.B¹), and none by I-A^d of the SCID mouse. Most of the T cell lines recognized the immunodominant MBP epitope 68–88. In striking contrast to intact Lewis rats, in SCID mice reconstituted by rat fetal liver only, MBP-specific T cell clones used a seemingly random repertoire of Vβ genes without a bias for Vβ8.2. In chimeras containing fetal Lewis liver plus fetal thymus grafted under the kidney capsule, however, dominant utilization of Vβ8.2 was restored. The migration of liver-derived stem cells through rat thymus grafts was documented by combining fetal tissues from wild-type and transgenic Lewis rats. The results confirm that the recognition of the immunodominant epitope 68–88 by MBP-specific encephalitogenic T cells is a genetically determined feature of the Lewis rat T cell repertoire. They further suggest that the formation of the repertoire requires T cell differentiation in a syngeneic thymic microenvironment.     

Resistance to experimental autoimmune encephalomyelitis induced by neonatal tolerization to myelin basic protein: clonal elimination vs. regulation of autoaggressive lymphocytes

The target autoantigen of experimental autoimmune encephalomyelitis (EAE), myelin basic protein (MBP), appears late in ontogeny. In the rat MBP is expressed first on days 2-3 post partum, at a development stage, when self tolerance to most other autoantigens has already developed. To shed light on the cellular mechanisms that lead to immunological self tolerance to MBP, we treated neonatal rats with high doses of MBP before ontogenetic appearance of this autoantigen. We found that high doses are required to confer MBP-specific tolerance lasting until the adult life. Neonatally tolerized, adult rats are completely resistant to induction of EAE by injection of MBP in complete Freund's adjuvant (CFA). Upon MBP CFA challenge, these animals develop a limited humoral response to MBP, but are completely unreactive to MBP on the T cell level. The function of antigen-presenting cells is unchanged by neonatal tolerization, and there is no evidence for the induction of suppressive mechanisms. Transfers of large numbers of tolerized lymphocytes to normal hosts fails to interfere with EAE inducibility. Moreover, neonatally tolerized lymphocytes do not reduce MBP reactivity of primed lymph node cells or T line cells in vitro. Finally, neonatally tolerized rats are susceptible to EAE transferred by activated primed lymphocytes or by in vitro-activated MBP-specific T line cells. The apparent deletion of MBP-specific T lymphocytes in neonatally tolerized rats is in striking contrast to the physiological self tolerance to MBP, which is characterized by the presence of MBP-specific clones in the normal immune repertoire.     

Soluble antigen therapy induces apoptosis of autoreactive T cells preferentially in the target organ rather than in the peripheral lymphoid organs

The administration of soluble myelin proteins is an effective way of down-regulating the inflammation in the central nervous system (CNS) in experimental autoimmune encephalomyelitis (EAE), an animal model of multiple sclerosis. To shed more light on the mechanism of this antigen-specific therapy, we determined the effect of the intraperitoneal (i.p.) injection of soluble myelin basic protein (MBP) on T cell apoptosis in the CNS and peripheral lymphoid organs of Lewis rats with EAE induced by inoculation with MBP and complete Freund's adjuvant. In particular we assessed the level of apoptosis of Vβ8.2⁺ T cells, which constitute the predominant encephalitogenic MBP-reactive T cell population in the Lewis rat. The daily i.p. injection of MBP for 3 days from the onset of neurological signs inhibited the further development of neurological signs of EAE. Using two-color flow cytometry we found that a single i.p. injection of MBP increased the level of apoptosis of the Vβ8.2⁺ T cell population in the CNS to 26.2 % compared to 7.4 % in saline-treated rats and 7.6 % in ovalbumin-treated rats. In contrast, treatment with MBP did not increase the level of apoptosis of the Vβ8.2⁺ population in the popliteal lymph node draining the inoculation site (1.4 %) or in the spleen (1.6 %) above that occurring in saline-treated rats (1.6 % and 1.1 %, respectively). Limiting dilution analysis revealed that the frequency of T cells reactive to the major encephalitogenic epitope, MBP_{72 – 89}, was decreased in the CNS but not in the popliteal lymphnode by this treatment. Three-color flow cytometry in MBP-treated rats demonstrated that CNS Vβ8.2⁺ T cells expressing Fas (CD95) and Fas ligand were highly vulnerable to apoptosis compared to Vβ8.2⁺ T cells not expressing these proteins. We conclude that the i.p. injection of MBP increases the spontaneously occurring Fas-mediated activation-induced apoptosis of auto reactive T cells in the CNS in EAE and that this contributes to the therapeutic effect of the injection.     

Prevention and treatment of Lewis rat experimental allergic encephalomyelitis with a monoclonal antibody to the T cell receptor Vβ8.2 segment

The predominance of T cell receptor (TCR) Vβ8.2 utilization by encephalitogenic T cells induced in Lewis rats by immunization with myelin basic protein (MBP) is controversial. Thus, both an almost exclusive usage of Vβ8.2 [Burns, F. R., Li, X., Shen, N., Offner, H., Chou, Y. K., Vandenbark, A. A. and Heber-Katz, E., J. Exp. Med. 1989. 169: 27; Chluba, J., Steeg, C., Becker, A., Wekerle, H. and Epplen, J. T., Eur. J. Immunol. 1989. 19: 279] and a quite diverse Vβ composition of CD4 T cells causing experimental autoimmune encephalomyelitis (EAE) [Sun, D., Gold, P. D., Smith, L., Brostoff, S. and Coleclough, C., Eur. J. Immunol. 1992. 22: 591; Sun, D., Le, J. and Coleclough, C., Eur. J. Immunol. 1993. 23: 494] have been reported. Using a recently developed monoclonal antibody (mAb) specific for TCR Vβ8.2, we show that postnatal treatment effectively eliminates Vβ8.2-bearing cells and prevents MBP-induced EAE in the majority of Lewis rats. Moreover, treatment of adult Lewis rats with Vβ8.2-specific mAb as late as on day 12 after MBP immunization suppressed the development of neurological symptoms. Thus, Vβ8.2-bearing cells do play a decisive role in Lewis rat EAE, and suppression of the small (5%) Vβ8.2-expressing T cell subset provides an effective therapeutic strategy.     

The role of CTLA-4 in tolerance induction and ttigen administration cell differentiation in experimental autoimmune encephalomyelitis: i. v. antigen administration

Interactions between B7 molecules on antigen-presenting cells and CTLA-4 on T cells have been shown to be important in establishing tolerance. In the present study, we examined the kinetics of tolerance induction following i.v. administration of myelin basic protein (MBP) Ac1-11 in mice transgenic for a TCR V(beta)8.2 gene derived from an encephalitogenic T cell clone specific for MBP Ac1-11. Examination of the lymph node cell (LNC) response 10 days after antigen administration demonstrated an accentuation of i.v. tolerance induction with anti-CTLA-4 blockade. Anergy was induced in splenocytes by i.v. antigen administration as shown by a decrease in MBP-specific proliferation and IL-2 production, and anti-CTLA-4 potentiated this effect. In addition, i.v. antigen plus anti-CTLA-4 and complete Freund's adjuvant was not encephalitogenic. Interestingly, i.v. tolerance (a single injection) did not inhibit experimental autoimmune encephalomyelitis (EAE) and anti-CTLA-4 administration did not alter this phenotype. These results suggest that while the majority of MBP-specific T cells are tolerized by i.v. antigen and that this process is potentiated by anti-CTLA-4 administration, a population of T cells remains that is quite efficient in mediating EAE.     

Anergy induction in encephalitogenic T cells by brain microvessel endothelial cells is inhibited by interleukin-1

Experimental autoimmune encephalomyelitis (EAE) is an inflammatory disease of the central nervous system (CNS) which can be induced, in susceptible strains like Lewis rats, by transfer of activated myelin basic protein (MBP)-specific CD4⁺ T lymphocytes. The role of cerebral endothelium in the onset of EAE, with regard to adhesion, activation and infiltration in the CNS of encephalitogenic T lymphocytes, is not fully understood. When pretreated by interferon-γ, the immortalized Lewis rat brain microvessel endothelial (RBE4) cells expressed major histocompatibility complex class II molecules and stimulated MBP-specific proliferation and cytolytic activity of the syngeneic encephalitogenic T cell line, designated PAS. However, RBE4-stimulated PAS lymphocytes subsequently entered an unresponsive state, known as anergy. When inoculated in syngeneic animals, anergic PAS cells, although still cytotoxic, failed to induce EAE, and no cell infiltration was detectable within CNS. The addition of interleukin-1β (IL-1β) during MBP presentation by RBE4 cells prevented T cell anergy induction, and maintained T cell encephalitogenicity, although PAS cells stimulated in these conditions caused delayed and attenuated clinical signs of EAE, with only discrete inflammatory lesions in the CNS, compared with EAE induced by PAS cells fully activated by thymic cells. Altogether, our results indicate that MBP presentation by brain microvessel endothelial cells to encephalitogenic T cells induces T cell anergy and loss of pathogenicity. In addition, IL-1β co-stimulation of T cells prevents anergy induction in vitro and at least partially maintains encephalitogenicity in vivo.     

Preferential distribution of Vβ 8.2-positive T cells in the central nervous system of rats with myelin basic protein-induced autoimmune encephalomyelitis

To determine the role of encephalitogenic T cells in the formation of lesions in the central nervous system (CNS), experimental autoimmune encephalomyelitis (EAE) was induced in Lewis rats by immunization with either myelin basic protein (MBP) or the synthetic peptide which corresponds to the 87–100 sequence of guinea pig MBP, and T cells expressing T cell receptor (TcR) Vβ8.2, Vβ8.5, Vβ10 and Vβ16 in the lymphoid organs and CNS were localized and quantified by flow cytometry (FCM) and immunohistochemistry. In normal rats, the percentage of T cells expressing these Vβ phenotypes to the total number of TcR αβ⁺ T cells, as determined by FCM, ranged from 5% to 10% in the lymph node. Vβi6⁺ T cells were the most predominant population among the four Vβ subsets tested. Essentially the same findings were obtained from the analysis of the lymphoid organs of rats with EAE which had been induced by immunization with the same two antigens. In sharp contrast, 15–20% of the T cells isolated from lesions of MBP-induced EAE expressed Vβ8.2⁺. Thus, the percentage of Vβ8.2⁺ T cells in the EAE lesions was threefold higher than that in the lymph node, while the proportions of Vβ8.5⁺, Vβ10⁺ and Vβ16⁺ T cells were about the same in both organs. The predominance of Vβ58.2⁺ T cells in EAE lesions was confirmed by counts of immunohistochemically stained T cells in the spinal cord. Moreover, it was revealed that (i) the predominance of Vβ8.2⁺ T cells was greatest during the development of EAE and became less obvious at the recovery stage, and (ii) at the peak stage of EAE, approximately 85% of Vβ8.2⁺ T cells were distributed in the parenchyma while 15% were in the perivascular space of the CNS vessels. These findings indicate that encephalitogenic T cells which express Vβ8.2 infiltrate the CNS at a very early stage of EAE and become the predominant population in infiltrating T cells, and further suggest that encephalitogenic T cells, not only recruit inflammatory cells in the CNS, but also cause neural tissue damage, such as demyelination.     

The myelin basic protein-specific T cell repertoire in Lewis rats: T cell receptor diversity is influenced both by intrathymic milieu and by extrathymic peptide presentation

In the Lewis rat, the T lymphocyte response to guinea pig myelin basic protein (MBP) is focused almost exclusively on epitopes nested in the MBP peptide sequence p68 – 88, and is dominated by T cell receptors (TCR) using Vβ8.2 gene elements, together with short N(D)N regions. Here we analyzed MBP-specific TCR from Lewis T cells differentiating in chimeric thymuses of Lewis rat/SCID mouse chimeras, in the absence of an intact rat thymic microen vironment (SCID_FL mice). In these T cells, the TCR Vβ repertoire is broad, N(D)N regions are significantly longer, and contain regular rates of template-independent N nucleotides. In striking contrast, a Vβ8.2 biased TCR repertoire and few N-region inserts are seen in p68 – 88-specific, Lewis rat-derived T cells differentiating in the complete rat thymic microen vironment provided by chimeric SCID mice bearing embryonic Lewis thymus grafts (SCID_FL/FT mice). A T cell repertoire resembling the one in SCID_FL mice is used by T cells of intact Lewis rats following immunization with a truncated epitope of MBP, p69 – 86. Also this selection generates a broad TCR Vβ pattern with long N(D)N regions, and higher numbers of N nucleotides. These results show that both intrathymic repertoire selection, and extrathymic peptide priming exert profound effects on the TCR usage in the anti-MBP response of Lewis rats.     

Experimental autoimmune encephalomyelitis in the rat: lessons in T-cell immunology and autoreactivity

Summary: Experimental autoimmune encephalomyelitis (EAE) in the rat is an acute paralytic disease from which most animals spontaneously recover. The disease can be induced in susceptible inbred Lewis and DA rats with myelin basic protein (MBP), or encephalitogenic MBP peptides administered in complete Freund's adjuvant (CFA). The disease can be adoptively transferred to syngeneic recipients with primed T cells that have been reactivated in vitro with antigen. EAE is mediated by CD4⁺ Th1 cells that secrete proinflammatory cytokines, and spontaneous remission is associated with CD4⁺ T cells that secrete transforming growth factor-beta (TGF-β). Studies of EAE in susceptible rats have provided many important insights into the interactions of T cells and accessory cells that culminate in the induction of the autoimmune response.     

Anti-inflammatory activity of nerve growth factor in experimental autoimmune encephalomyelitis: inhibition of monocyte transendothelial migration

In order to analyze a putative immunomodulatory effect of NGF in experimental autoimmune encephalomyelitis (EAE) of the Lewis rat, we transduced myelin basic protein (MBP)-specific CD4(+) T cells with a recombinant retrovirus encoding NGF. These T(MBP)NGF cells secreted high levels of NGF, along with an unaltered Th1-like cytokine pattern. Transfer studies showed that T(MBP)NGF cells were unable to mediate clinical EAE, when transferred alone, and, more important, they efficiently suppressed induction of clinical EAE by non-transduced MBP-specific T cells (T(MBP )cells). In contrast, NGF transduced ovalbumin-specific T cells, which secreted high NGF levels, did not affect EAE induction. Suppression of clinical EAE by T(MBP)NGF cells was associated with a general reduction of inflammatory CNS infiltrates, with a most pronounced decrease of the monocyte/macrophage component. Using a culture model of the endothelial blood-brain barrier (BBB), we found that NGF directly acts on blood-derived monocytes via the p75 NGF receptor, thus interfering with monocyte migration through the activated BBB endothelium. Our data establish NGF as an anti-inflammatory mediator interfering with T cell mediated autoimmune disease in the CNS. They further point to monocyte migration through blood vascular endothelium as one possible mechanism of NGF action.     

Modeled Microgravity Suppressed Expansion of the MBP-specific T Lymphocytes of Rats with Experimental Autoimmune Encephalomyelitis

Experimental autoimmune encephalomyelitis (EAE) is characterized by uncontrolled proliferation of autoreactive T lymphocytes, with markedly increased secretion of pro-inflammatory cytokines. To further dissect the pathogenetic pathways of this disease, we exposed T lymphocytes from EAE rats, which were specific for myelin basic protein (MBP) to a modeled microgravity (MMG) environment, using a rotated cell culture system (RCCS) that was known to suppress proliferation of normal T cells. Following exposure to MMG, the proliferation of EAE lymphocytes decreased dramatically compared to those cultured in unit gravity (UG). At the beginning of MMG, a significant increase of apoptosis of MBP-specific T lymphocytes was observed, while at a later stage, the cytokine secretion profile of exposed MBP-specific T lymphocytes was altered, as was the differentiation of Th subsets. We concluded that the function of MBP-specific T lymphocytes was disordered after exposure to MMG.     

Regulatory T cells in experimental allergic encephalomyelitis. I. Frequency and specificity analysis in normal and immune rats of a T cell subset that inhibits disease

We have shown previously that administration of myelin basic protein (MBP)-reactive T cells to naive Lewis rats induces not only autoimmune encephalomyelitis (EAE) but also a near total resistance to subsequent disease. By isolating the effector cells that are responsible for the resistance, we demonstrated that disease protection paralleled with increased numbers of a CD8+ regulatory T cell (RTC) subset and that co-injection of this RTC subset with encephalitogenic T cells aborted the pathogenic activity of the latter cells. Here, we show that a radio-sensitive splenic population of RTC also exists in naive rats that can be recruited and activated to inhibit the onset of secondary episodes of adoptive EAE. In co-transfer experiments, this protective RTC subpopulation can be isolated to neutralize the pathogenic activity of stimulatory MBP-reactive T cells in vivo. We show that the frequency of RTC with specificity for MBP-reactive T cells in naive rats is two orders of magnitude higher than the frequency of MBP-specific precursors, the activity of RTC increases substantially with age and RTC frequencies increase as a consequence of immunization with MBP-reactive cells lines. In specificity studies, we show that RTC isolated from naive rats and RTC from animals primed with one MBP-reactive cell line show cross-reactive responses to a variety of different MBP-reactive T cell lines. However, following repeated stimulation with a given MBP line, these RTC display a more limited, clonotypic response to the selecting line and assume a uniform CD8 phenotype. Finally, functional studies with RTC indicate that proliferative and lytic specificities do not necessarily correlate and that activated rat RTC are especially lytic for a Fas-sensitive murine cell line.     

Successful prevention and treatment of autoimmune encephalomyelitis by short-term administration of anti-T-cell receptor alpha beta antibody.

To identify an effective immunotherapy for T-cell-mediated autoimmune diseases, prevention and treatment of experimental autoimmune encephalomyelitis (EAE) induced in Lewis rats was attempted by administering a monoclonal antibody (mAb), R73, which is specific for rat T-cell receptor (TcR) alpha beta. Short-term administration of R73 at relatively low doses before immunization with encephalitogenic antigen, myelin basic protein (MBP), prevented the development of EAE. However, treatment with anti-CD4 and anti-Ia mAb in the same protocol was ineffective. Flow cytometric analysis demonstrated that short-term administration of R73 resulted in transient down-regulation of the TcR molecules, whereas the number of CD2-expressing T cells was well preserved. Furthermore, the response to MBP of T cells isolated from rats that were pretreated with R73 and then immunized with MBP was strongly suppressed. On the other hand, the T-cell response of R73-pretreated rats to a third-party antigen which was immunized at a later period was not inhibited. These findings suggest that in vivo administration of a low dose of R73 protects rats from EAE by inducing anergy of MBP-reactive encephalitogenic T cells. Furthermore, R73 treatment which started on day 10 of the immunization (shortly before the day of onset of clinical signs) completely suppressed the induction of EAE and that which started on day 11 (the day of onset) hastened recovery. Since the phenotypes of the TcR V beta chain of encephalitogenic T cells are not so limited as previously believed, immunotherapy with mAb against the TcR alpha beta framework may be one of the best methods for treatment of T-cell-mediated autoimmune diseases.     

Deaggregated homologous immunoglobulin-peptide conjugates induce peptide-specific T cell nonresponsiveness in vivo

Previous studies have proven the efficacy of intravenous injection of deaggregated protein as a means of inducing tolerance. In the present study, the immunodominant peptide 70 – 86 of myelin basic protein (MBP) was covalently linked to either mouse Ig or Lewis rat IgG. Lewis rats immunized with MBP in complete Freund's adjuvant were completely protected from development of experimental allergic encephalomyelitis (EAE) by their injection with as little as 40 μg of peptide conjugate on days 0 and 10 after immunization. Peptide-specific proliferative and cytokine responses by T cells from treated rats in vitro were severely depressed compared with controls, while responses to whole MBP were unaffected. Significantly, injections of 100 μg of peptide conjugate on days 0 and 4 after adoptive transfer of peptide-specific T lines protected rats from passive EAE while a single injection of 100 μg of conjugate at the onset of active EAE prevented any further disease progression. Both results suggest that primed effector cells as well as naive T cells are prone to tolerance induction by this means. The ability to intervene in ongoing immune responses with such specificity may be useful therapeutically in control of autoimmunity or allergic responses to environmental antigens.     

Minor lymphocyte stimulating (Mls) gene products in mice influence their genetic resistance or susceptibility to induction of autoimmune encephalomyelitis.

The role of the major histocompatibility complex (MHC) gene products in the genetics of experimental autoimmune encephalomyelitis (EAE) is well established. Here we demonstrate how non-MHC gene products, stimulatory to T cells specific to myelin basic protein (MBP), can affect the MHC control in determining genetic susceptibility or resistance to induction of EAE. I-As-restricted MBP-specific T cells derived from SJL/J mice are shown to cross-react with Mls-2a gene products. The Mls-2a gene product expressed by (SJL/J X BALB/c)F1 mice tolerize T cells recognizing I-As/MBP and favor the development of I-Es/d-restricted MBP-specific T cells mediating EAE in the (SJL/J x BALB/c)F1 mice. These I-Es/d/MBP-specific T cells, cross-reactive with Mls-1a, and the I-As/MBP-specific T cells, cross-reactive with Mls-2a gene products, are both eliminated by self tolerance mechanisms in the H-2-matched (SJL/J X DBA/2)F1 mice, expressing Mls-1a2a gene products, and thereby confer genetic resistance to EAE on the (SJL/J X DBA/2)F1 mice bearing EAE-permissive MHC alleles. These results reflect a developmental selection of a T cell repertoire to the self antigen MBP, imposed by self tolerance to self Mls gene products, which affect the genetic susceptibility to EAE. These studies also demonstrate that self tolerance to Mls gene products can strengthen the tolerance to organ-specific self antigens such as MBP, which may not be expressed or which are absent in the thymus at the time of thymic selection.     

Age-dependent T cell tolerance and autoimmunity to myelin basic protein

Experimental autoimmune encephalomyelitis (EAE), an animal model for multiple sclerosis, is induced by activating a subset of myelin basic protein (MBP)-specific T cells that have escaped tolerance induction. Here, we define the tolerance mechanisms that eliminate the majority of MBP-specific T cells from the periphery. We show that MBP-specific T cells undergo central tolerance mediated by bone marrow-derived antigen-presenting cells presenting exogenously derived MBP epitopes. The efficiency of tolerance is age dependent, reflecting the developmentally regulated expression of MBP. Dependence of tolerance on the amount of MBP expressed in vivo results in an age window of susceptibility to EAE in mice that peaks during puberty. These results suggest that factors regulating expression of self-antigens in vivo can influence susceptibility to autoimmunity.     

T cell receptor beta chain usage in myelin basic protein-specific rat T lymphocytes

Myelin basic protein (MBP)-specific T cell lines and clones have been established from rats of the major histocompatibility complex (MHC)-compatible Lewis and BS strains. All lines and clones are MHC class II restricted and share the CD4+ phenotype. The cells proliferate specifically in response to either a peptide representing amino acids #68-88 of guinea pig MBP, to residues #47-67 or to an unidentified myelin antigen which is distinct from MBP. All lines and clones specific for MBP express the same T cell receptor (TcR) variable (V) beta chain element, which is homologous to the mouse V beta 8.2 gene segment. Three lines/clones with the same antigen fine specificity have identical V beta D beta J beta junctions on the protein level, a region which represents part of the potential antigen-binding portion of the TcR; two of the lines express members of the V alpha 2 family. These results suggest biased usage of TcR V beta elements in rat T cells specific for MBP. Our findings broaden the basis for a rational therapeutic strategy to specifically intervene in the rodent model system of experimental allergic encephalomyelitis.     

Cytotoxic activity of V beta 8+ T cells in Crohn's disease: the role of bacterial superantigens.

In Crohn's disease, disease-related stimuli could alter the T cell receptor (TCR) repertoire. To examine the possibility that changes in function may occur in T cell subsets without obvious changes in expression of TCR, we analysed the TCR repertoire of cytotoxic T lymphocytes in Crohn's disease peripheral blood. Furthermore, we examined the effect of bacterial superantigens, staphylococcal enterotoxin B (SEB) and E (SEE) on the cytotoxic function of T cell subsets bearing different TCR V genes using MoAbs specific for CD3 and TCR V gene products in a redirected cytotoxicity assay. There was no difference between patients and controls in the cytotoxicity measured in concanavalin A (Con A)-stimulated peripheral blood mononuclear cells (PBMC) with anti-CD3 or with six of seven anti-TCR V gene MoAbs. However, the cytotoxicity of V beta 8 T cells was decreased in Crohn's disease patients. This was not due to a decrease in total or CD8+ T cells expressing V beta 8. Furthermore, in normal subjects, PBMC stimulation with SEE and SEB selectively expanded and increased the cytotoxicity of V beta 8 and V beta 12 T cells, respectively. In Crohn's disease, although SEB stimulation increased the number and cytolytic function of the V beta 12 subset, SEE stimulation failed to increase cytolytic activity of V beta 8+ T cells in spite of the expansion of V beta 8+ T cells. These results suggest that the changes in cytotoxic function observed in V beta 8 T cells in Crohn's patients may reflect previous exposure to a V beta 8-selective superantigen.     

Inhibition of experimental autoimmune encephalomyelitis in Lewis rats by nasal administration of encephalitogenic MBP peptides: synergistic effects of MBP 68-86 and 87-99

Induction of mucosal tolerance by inhalation of soluble peptides with defined T cell epitopes is receiving much attention as a means of specifically down-regulating pathogenic T cell reactivities in autoimmune and allergic disorders. Experimental autoimmune encephalomyelitis (EAE) induced in the Lewis rat by immunization with myelin basic protein (MBP) and Freund's adjuvant (CFA) is mediated by CD4+ T cells specific for the MBP amino acid sequences 68-86 and 87-99. To further define the principles of nasal tolerance induction, we generated three different MBP peptides (MBP 68-86, 87-99 and the non- encephalitogenic peptide 110-128), and evaluated whether their nasal administration on day -11, -10, -9, -8 and -7 prior to immunization with guinea pig MBP (gp-MBP) + CFA confers protection to Lewis rat EAE. Protection was achieved with the encephalitogenic peptides MBP 68-86 and 87-99, MBP 68-86 being more potent, but not with MBP 110-128. Neither MBP 68-86 nor 87-99 at doses used conferred complete protection to gp-MBP-induced EAE. In contrast, nasal administration of a mixture of MBP 68-86 and 87-99 completely blocked gp-MBP-induced EAE even at lower dosage compared to that being used for individual peptides. Rats tolerized with MBP 68-86 + 87-99 nasally showed decreased T cell responses to MBP reflected by lymphocyte proliferation and IFN-gamma ELISPOT assays. Rats tolerized with MBP 68-86 + 87-99 also had abrogated MBP-reactive IFN-gamma and tumor necrosis factor-alpha mRNA expression in lymph node cells compared to rats receiving MBP 110-128 nasally, while similar low levels of MBP-reactive transforming growth factor-beta and IL-4 mRNA expressing cells were observed in the two groups. Nasal administration of MBP 68-86 + 87-99 only slightly inhibited guinea pig spinal cord homogenate-induced EAE, and passive transfer of spleen mononuclear cells from MBP 68-86 + 87-99-tolerized rats did not protect naive rats from EAE. Finally, we show that nasal administration of MBP 68-86 + 87-99 can reverse ongoing EAE induced with gp-MBP, although higher doses are required compared to the dosage needed for prevention. In conclusion, nasal administration of encephalitogenic MBP peptides can induce antigen-specific T cell tolerance and confer incomplete protection to gp-MBP-induced EAE, and MBP 68-86 and 87-99 have synergistic effects. Non-regulatory mechanisms are proposed to be responsible for tolerance development after nasal peptide administration.      

Delineation of tissue damage mechanisms in experimental autoimmune encephalomyelitis (EAE). I. Cell detachment and lysis induced by encephalitogenic CD4+ T lymphocytes.

Myelin basic protein (MBP) reactive CD4+ T lymphocytes, capable of inducing experimental autoimmune encephalomyelitis (EAE), were examined for their ability to damage target cells of central nervous system (CNS) origin. Damage was assessed by monitoring detachment of adherent astrocytes from substratum and astrocyte lysis. MBP-specific, but non-encephalitogenic CD4+ T cells mediated astrocyte detachment but not lysis. However, encephalitogenic CD4+ T cell lines were more efficient in causing astrocyte detachment and could also cause astrocyte lysis. The detachment and lytic activities of the MBP-reactive T cell lines tested were often independent of the presence of specific antigen, and were not restricted to syngeneic major histocompatibility (MHC) antigens. MBP often augmented the detaching and, if lytic, lytic activities of these T cells. The encephalitogenic CD4+ T cells also detached and lysed allogeneic 'bystander' fibroblasts in the presence of unlabelled syngeneic astrocytes, suggesting the involvement of a soluble mediator(s). Although MBP is essential for the initiation of EAE, the presence of MBP on cells of CNS origin, such as astrocytes and oligodendrocytes, does not appear to be necessary for their damage by MBP-specific CD4+ T cells. Immune CD4+ T cells, which penetrate the CNS, may disorganize brain tissue structure by lysing astrocytes directly and by damaging other brain cells indirectly by soluble mediators. Thus cellular detachment, in addition to cell lysis, mediated by MBP-specific CD4+ cells may contribute to EAE pathogenesis.