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.     

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.     

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.     

Analysis of TCR β chains in Lewis rats with experimental allergic encephalomyelitis. II. Vβ8.2+ T cells with limited CDR3 N region additions derive from the adult thymus

Immunization of Lewis (LEW) rats with guinea pig myelin basic protein (MBP) induces a population of encephalitogenic CD4 T cells having specificity for the dominant immunogenic peptide of MBP, 68 – 86. The TCR β chains of these disease-causing T cells show three distinct features: they are almost exclusively Vβ8.2, they use AspSer as the first two amino acid residues of the third complementarity-determining region (CDR3) and these junctional region sequences show few if any non-germline N-region nucleotide additions. This last feature raises the possibility that these autoimmune T cell precursors derive from TCR gene rearrangements occurring during early, perinatal ontogeny, a period when the enzyme terminal deoxynucleotidyl transferase (TdT), responsible for N region additions, is not expressed. An alternative possibility is that these features of the TCR of MBP 68 – 86-reactive T cells are dictated by considerations of antigen selection throughout ontogeny both in the thymus and in the periphery – i.e., that such β chains are conformationally the most appropriate for triggering by an epitope of 68 – 86 complexed to class II RT1.B^l MHC molecules. We show here that active experimental allergic encephalomyelitis, while delayed in onset, occurs in heavily irradiated animals, but not in the absence of a thymus, a finding indicating that this autoimmune disease is caused by a T cell subpopulation derived from the post-irradiation adult thymus. These disease-causing T cells are heavily Vβ8.2⁺ , CDR3 AspSer⁺ and use few N region additions. We conclude that T cells with these TCR β chain features can be generated in the adult thymus and most likely reflect requirements imposed by antigen selection.     

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.     

Protection from experimental allergic encephalomyelitis by application of a bacterial superantigen.

Certain bacterial and viral T cell stimulating proteins ('superantigens') are known to be very potent activators of T cells with certain V beta receptors. When applied in vivo these molecules induce anergy in those T cells responding to them. In this study we have investigated the influence of staphylococcal enterotoxins (SE) on myelin basic protein (MBP)-specific T cells in Lewis rats. As MBP-specific T cells in rats belong exclusively to the V beta 8.2+ CD4+ subset, the induction of experimental allergic encephalomyelitis (EAE) allows for an estimation of the functional state of the respective V beta-bearing T cells after enterotoxin-induced activation. In vitro, various MBP-specific T cell lines showed a strong selective proliferative response to staphylococcal enterotoxin E (SEE) but not to other SE. The in vitro activation by SEE induced encephalitogenic potential in these cells. After application of SEE to Lewis rats the susceptibility to induction of EAE was completely abrogated. Such SEE-treated and MBP-challenged rats did not exhibit any signs of disease and their T cells did not respond to MBP in proliferation tests. This abrogation of EAE was only found with a superantigen capable of interacting specifically with V beta 8.2+ T cells. Superantigen-mediated induction of unresponsiveness may have relevance for the analysis of pathogenetic mechanisms and for therapeutic considerations in certain T cell-mediated autoimmune diseases.     

Vaccination with T cell receptor peptides primes anti-receptor cytotoxic T lymphocytes (CTL) and anergizes T cells specifically recognized by these CTL

We selected three peptides from the germ-line sequence of the Vβ8.2 and Jβ2.3 gene segments of the murine T cell receptor for antigen (TCR) which contained putative K^d- and L^d-restricted epitopes. Immunization of BALB/c (H-2^d) mice with the Vβ8.2(67–90) 23-mer peptide 1 as well as the 15-mer Vβ8.2(95–108)-peptide 2 efficiently primed specific CD8⁺ cytotoxic T lymphocyte (CTL) responses in vivo against natural TCR-Vβ8.2 epitopes. Vβ8.2⁺ T cells were not deleted in TCR peptide-immunized mice because the fractions of Vβ8.2⁺ CD4⁺ and Vβ8.2⁺ CD8⁺ T cells in spleen and lymph nodes were not altered. The proliferative response of Vβ8.2⁺ T cells to stimulation by monoclonal antibody F23.2 was selectively suppressed (by 60–80%) in peptide-immunized BALB/c mice, indicating partial anergy of this T subset. Immunization of BALB/c mice with the Jβ2.3-derived peptide 3 stimulated a CD8⁺ CTL response against a class I-restricted epitope within this Jβ segment that was also generated during natural “endogenous” processing of this self antigen. These data confirm the predictive value of major histocompatibility complex class I allele-specific motifs. The described experiments indicate that TCR peptide-primed CD8⁺ CTL recognize class I-restricted, natural Vβ/Jβ-TCR epitopes. Such anti-TCR CTL may, thus, operate in Vβ-specific immunoregulation of the T cell system suppressing their functional reactivity without deleting them.     

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.     

CD8α+ dendritic cells prime TCR‐peptide‐reactive regulatory CD4+FOXP3− T cells

CD4⁺ T cells with immune regulatory function can be either FOXP3⁺ or FOXP3^?. We have previously shown that priming of naturally occurring TCR‐peptide‐reactive CD4⁺FOXP3^? Treg specifically controls Vβ8.2⁺CD4⁺ T cells mediating EAE. However, the mechanism by which these Treg are primed to recognize their cognate antigenic determinant, which is derived from the TCRVβ8.2‐chain, is not known. In this study we show that APC derived from splenocytes of naïve mice are able to stimulate cloned CD4⁺ Treg in the absence of exogenous antigen, and their stimulation capacity is augmented during EAE. Among the APC populations, DC were the most efficient in stimulating the Treg. Stimulation of CD4⁺ Treg was dependent upon processing and presentation of TCR peptides from ingested Vβ8.2TCR⁺CD4⁺ T cells. Additionally, DC pulsed with TCR peptide or apoptotic Vβ8.2⁺ T cells were able to prime Treg in vivo and mediate protection from disease in a CD8‐dependent fashion. These data highlight a novel mechanism for the priming of CD4⁺ Treg by CD8α⁺ DC and suggest a pathway that can be exploited to prime antigen‐specific regulation of T‐cell‐mediated inflammatory disease.     

Role of natural killer cells and TCRγ δ T cells in acute autoimmune encephalomyelitis

To elucidate the role of NK cells and TCRγ δ ⁺ T cells in acute experimental autoimmune encephalomyelitis (EAE) induced in Lewis rats, the distribution, number and function of these cells were studied using several methods. Immunohistochemical and flow cytometric analysis revealed that a certain number of NK cells (17 % of the total inflammatory cells) infiltrated the central nervous system (CNS) at the peak stage of EAE and were mainly located in the perivascular region. On the other hand, virtually no TCRγ δ ⁺ T cells were found in the CNS. NK-T (NKR-P1⁺ TCRα β ⁺ ) cells were few and did not increase in number in the CNS and lymphoid organs. In the cytotoxic assay using YAC-1 cells, effector cells isolated from the spleen of rats at the peak of EAE showed essentially the same cytotoxicity as those isolated from normal controls although the total number of NK cells decreased to one fifth of that of normal rats. Furthermore, in vivo administration of anti-NK cell (3.2.3 and anti-asialo GM1), but not of anti-TCRγ δ (V65), antibodies exacerbated the clinical features of EAE and induced fatal EAE in some rats. These findings suggest that NK cells play a suppressive role in acute EAE whereas TCRγ δ ⁺ T cells are not involved in the development of or recovery from the disease.     

Apoptotic elimination of Vβ8.2+ cells from the central nervous system during recovery from experimental autoimmune encephalomyelitis induced by the passive transfer of Vβ8.2+ encephalitogenic T cells

A CD4⁺Vβ8.2⁺ T cell clone specific for the peptide 72–89 of guinea pig myelin basic protein (GMBP) was used to induce acute experimental autoimmune encephalomyelitis (EAE) in Lewis rats. To assess apoptosis in inflammatory cells infiltrating the central nervous system (CNS), we extracted cells from the spinal cord, enriched them for T cells and performed flow-cytometric analysis of their DNA stained with propidium iodide. The presence of apoptosis was confirmed by the demonstration of DNA fragmentation on gel electrophoresis. A gradual increase in the proportion of apoptotic cells was observed between 4 and 7 days after the transfer of the encephalitogenic T cells. The highest frequency of apoptotic cells (9.2 ± 1.2%) was observed 7 days after cell transfer, when clinical recovery commenced. Passive transfer of ovalbumin-specific cells resulted in only a background level (0.8%) of apoptosis in the CNS. We conclude that the apoptotic process selectively eliminates autoreactive T cells from the CNS as: (a) there was a selective disappearance of disease-relevant CD5⁺Vβ8.2⁺ cells from the CNS during the course of EAE; (b) there was a decrease in the frequency of CNS-infiltrating T cells reactive to the GMBP 72–89 peptide during the course of EAE, and in a standard proliferation assay there was a loss of in vitro reactivity of CNS-infiltrating cells to this peptide, but not to a non-CNS antigen (ovalbumin); (c) simultaneous surface labeling and DNA analysis of CNS-infiltrating cells revealed that the frequency of Vβ8.2⁺ cells was about sevenfold higher in the apoptotic T cell population than in the normal (non-apoptotic) T cell population; and (d) we were unable to detect recirculation of the Vβ8.2⁺ cells to lymphoid organs after their frequency decreased in the CNS. The selective apoptotic elimination of autoreactive T cells from the target organ of this spontaneously resolving autoimmune disease may have implications for the understanding of the mechanism by which an autoimmune attack is terminated and for the design of therapeutic strategies to facilitate this process.     

Suppression of experimental autoimmune encephalomyelitis in Lewis rats by antibodies against CD2

The immunotherapeutic potential of three anti-rat CD2 monoclonal antibodies (mAb) (OX34, OX54, OX55) and the combination of OX54 with OX55 was tested in Lewis rat experimental autoimmune encephalomyelitis (EAE). In actively induced EAE, a single injection of OX34 2 days before immunization with myelin basic protein (MBP) in complete Freund's adjuvant (CFA) completely prevented or greatly attenuated EAE in all animals. Injection of OX54 acted moderately suppressive while OX55 or OX54/55 did not affect disease severity. Abrogation of EAE by OX34 was not restricted to its application before immunization. Therapeutic administration of all three mAb and the Ab combination from onset of first clinical signs efficiently blocked progression of disease and prevented all animals from developing hind limb paresis. In adoptive transfer EAE induced with in vitro activated cells of an encephalitogenic T helper line, clinical and histological signs were completely prevented by injection of OX34 on the day of cell transfer and 4 days later, underlining the strong impact of anti-CD2 mAb on the effector phase of disease. Immunocytofluorometric analysis of peripheral blood lymphocytes after a single Ab injection demonstrated that all mAb induced a variable degree of transient reduction in T cell numbers and modulation of CD2 antigens. In contrast to the other mAb, OX34 persisted on lymphocytes for at least 11 days, which may explain its unique suppressive effect on EAE after a single injection before immunization. The assumption that prophylactic administration of OX34 also inhibits MBP-induced EAE, due to persistence into the effector phase, was substantiated by the finding that none of the mAb prevented generation of an antigen-specific cellular response in MBP/CFA-immunized animals. Since none of the Ab induced T cell unresponsiveness or inhibited T cell activation by antigen- or Ab-mediated stimulation of the T cell receptor, we suggest that their marked action on the effector phase of EAE may rely on inhibition of T cell infiltration into the central nervous system. The demonstrated efficacy of these anti-CD2 mAb in EAE suggests a potential therapeutic role that may be equal to that of anti-CD4 or anti-T cell receptor Ab.     

Bone marrow-derived dendritic cells from experimental allergic encephalomyelitis induce immune tolerance to EAE in Lewis rats

We have previously shown that dendritic cells (DC), upon being pulsed in vitro with encephalitogenic myelin basic protein peptide 68–86 (MBP 68–86) and injected subcutaneously (s.c.) back to healthy Lewis rats, transfer immune tolerance to experimental allergic encephalomyelitis (EAE) induced by immunization with MBP 68–86 and Freund's complete adjuvant (FCA). We here assumed that DC become pulsed in EAE rats, and that expansion in vitro of such ‘in vivo pulsed EAE‐DC’ might also have the capacity to induce immune tolerance to EAE, thereby eliminating the need for in vitro pulsing of DC with autoantigens which are still unknown in many autoimmune diseases in the human. In the present study, EAE‐DC were generated from bone marrow of Lewis rats, with EAE induced with MBP 68–86 + FCA, and expanded in vitro by culture with GM‐CSF and IL‐4. In comparison with DC from normal rats, EAE‐DC exhibited higher viability in the absence of growth factors, and presented specific antigen to naïve T cells in vitro. The DC derived from both EAE and healthy rats stimulated strong proliferation in an antigen‐independent manner, lasting for 4 weeks after DC were s.c. injected into healthy rats. During this time, injection of EAE‐DC did not induce clinical EAE. However, when these rats were immunized with MBP 68–86 + FCA, subsequent EAE was dramatically suppressed, and was associated with increased IFN‐γ expression, nitric oxide production, gradually reduced proliferation and cell apoptosis, compared with PBS‐injected control EAE rats. LPS‐treated DC did not induce tolerance, suggesting that the tolerance is mediated by an immature stage of DC. These observations support the hypothesis that EAE‐DC can transfer immune tolerance to EAE, thereby omitting the step of characterizing specific autoantigen. Omitting the step of loading DC with antigen not only eliminates the extremely complex procedure of defining pathogenically‐relevant autoantigens, but also avoids the risk of inducing immunogenicity of DC in the treatment of autoimmune diseases.     

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.     

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.      

In Vivo Depletion of Chicken T-Cell Subsets

In the chicken three types of T-cell receptors can be defined by monoclonal antibodies TCR1, TCR2 and TCR3, which recognize γδ T cells, and Vβ1- and Vβ2-expressing αβ T cells, respectively. In the present report we have analysed means of selectively depleting the γδ T cells and the Vβ1 ⁺αβ T cells. γδ cells, which represent up to 66% of all T cells in blood of a 6-month-old chicken, can be effectively depleted by neonatal thymectomy (Tx) to levels as low as 1%. Immunohistology demonstrates a similar depletion in lymphoid organs while intestinal epithelium-associated γδ T cells are affected by Tx to a lesser extent. Vβ1-bearing αβ T cells, which comprise about 80% of the αβ T cells, were depleted by embryonic and neonatal injection of the TCR2 antibody. In the thymus such treatment depleted only the Vβ1 ⁺αβ T cells with high density expression of T-cell receptor. Therefore, we thymectomized TCR2-treated animals in order to prevent development of mature Vβ1⁺αβ T cells from the low density immature thymocytes. Treatment of chickens with a total of 22 mg of TCR2 antibody plus Tx reduced Vβ⁺αβ T cells from an average of 65% to 10% of all T cells. In these TCR2 antibody-treated animals the Vβ2-expressing αβ T cells become the predominant type of T cell (average 85%).     

Essential role of TGF-beta in the natural resistance to experimental allergic encephalomyelitis in rats

Experimental allergic encephalomyelitis (EAE) is a T cell-mediated autoimmune disease induced in susceptible rat strains by a single immunization with myelin basic protein (MBP). The Lewis (LEW) strain is susceptible to disease induction while the Brown Norway (BN) strain is resistant. This resistance involves non-MHC genes since congenic BN-1L rats, with LEW MHC on a BN-derived background, are also resistant. In the present study we show that, upon immunization with MBP, the non-MHC-encoded resistance to develop clinical EAE in BN-1L rats is associated with a decreased production of IFN-gamma. This may be due to a difference between LEW and BN-1L rats in their ability to produce regulatory cytokines such as IL-4, IL-10 and TGF-beta. In comparison to LEW rats, immune lymph node cells from BN-1L rats express an increased amount of IL-4 mRNA but produce less IL-10. Furthermore, the sera from BN-1L rats contain higher amounts of active TGF-beta1. Therefore, we have investigated the involvement of IL-4 and TGF-beta in the resistance of BN-1L rats to develop EAE using neutralizing mAb. Neutralization of TGF-beta, but not IL-4, renders BN-1L rats susceptible to clinical EAE without affecting the proliferation or the cytokine repertoire of immune lymph node cells. With respect to the origin of the endogenous TGF-beta production, we excluded the involvement of CD8 T cells and discuss a possible role of platelets and of CD4 T cells exhibiting the CD45RC(low) phenotype.     

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.     

Serum IgM repertoire reactions to MBP/CFA immunization reflect the individual status of EAE susceptibility

Lewis rats develop experimental allergic encephalomyelitis (EAE) in response to immunization with myelin basic protein (MBP) in CFA, while Fischer rats are usually resistant. These strains, while comparably producing anti-MBP antibodies, also differ in their repertoire reactions to immunization, as measured by patterns of serum IgM reactivity with various autologous proteins. We have now scored IgM repertoire reactions to MBP/CFA immunization after treatments that alter EAE susceptibility in either strain. The results show that abrogation of EAE susceptibility in Lewis rats by a previous experience of T cell-induced passive EAE provoked a novel set of IgM reactivities that otherwise characterized the Fischer's repertoire reaction. Conversely, these reactivities were delayed in the response of Fischer rats that had been rendered EAE-susceptible by cyclophosphamide. Another IgM reactivity with a significant association to individual EAE severity in Lewis rats behaved reciprocally. Together with previous results, these observations suggest that putative regulatory mechanisms concordantly affect EAE resistance and IgM repertoire reactions, operating naturally in Fischer rats and abrogatable by cyclophosphamide treatment, whereas naturally suppressed, but restorable in Lewis rats. Other treatments altering EAE susceptibility, however, did not share these characteristics and may thus be mediated by other mechanisms.