Protection against experimental encephalomyelitis. Idiotypic autoregulation induced by a nonencephalitogenic T cell clone expressing a cross-reactive T cell receptor V gene.

The recovery process in experimental autoimmune encephalomyelitis (EAE) in Lewis rats is characterized by an increasing diversity of T cell clones directed at secondary epitopes of myelin basic protein. Of particular interest, residues 55 to 69 of guinea pig basic protein could induce protection against EAE. A nonencephalitogenic T cell clone, C455-69, that was specific for this epitope transferred protection against both active and passive EAE. Clone C4 was found to express V beta 8.6 in its Ag receptor, and residues 39 to 59 of the TCR V beta 8.6 sequence were found to be highly crossreactive with the corresponding residues 39 to 59 of TCR V beta 8.2, which is known to induce protective anti-idiotypic T cells and antibodies. Like the TCR V beta 8.2 peptide, the V beta 8.6 sequence induced autoregulation and provided effective treatment of established EAE. Thus, the EAE-protective effect of the guinea pig basic protein 55-69 sequence was most likely mediated by T cell clones such as C4 that could efficiently induce anti-TCR immunity directed at a cross-reactive regulatory idiotope.     

Synthetic peptides representing sequence 39 to 59 of rat V beta 8 TCR fail to elicit regulatory T cells reactive with V beta 8 TCR on rat encephalitogenic T cells.

Subpathogenic doses of syngeneic autoreactive T cells protect experimental animals against associated autoimmune disease. Preferential use of the TCR of encephalitogenic T cells suggests that this molecule serves as the target for immunoregulation in experimental autoimmune encephalomyelitis (EAE). Whether peptides derived from the V beta 8 of the rat TCR elicit regulatory T cells and produce the same vaccinating effect against EAE as do whole T cells remains unknown. Here we show that immunization of Lewis rats with V beta 8(39-59), a peptide representing residues 39 to 59 of the rat V beta 8 TCR, does not induce the production of regulatory T cells reactive to the intact TCR V beta 8 containing this sequence. Moreover, animals that had recovered from both actively induced EAE and transferred EAE did not generate regulatory T cells that recognized the V beta 8(39-59) peptide. Further, transfusion of large doses of peptide-specific T cells did not protect the animals from EAE. Our results suggest that the V beta 8(39-59) peptide may comprise so-called cryptic epitopes, which function as immunogens only when dissociated from large protein complexes.     

Characterization of the immune response to a secondary encephalitogenic epitope of basic protein in Lewis rats. I. T cell receptor peptide regulation of T cell clones expressing cross-reactive V beta genes.

In Lewis rats, immunization with myelin basic protein induces two distinct encephalitogenic T cell populations, those responding to the immunodominant 72-89 epitope and those specific for a secondary epitope including residues 87-99. The 72-89 specific T cells were I-A restricted and preferentially expressed V beta 8.2 in their TCR. To determine the fine specificity, MHC restriction, and TCR V beta gene use in T cells reactive to the secondary epitope, we characterized 23 T cell clones from the lymph nodes (LN) and spinal cords (SC) of rats immunized with either whole basic protein or synthetic peptides S85-99 and S87-99 that were found to be functionally similar. The S85-99/S87-99 specific clones from LN and SC were all encephalitogenic despite differences in recognition of intact basic protein and class II MHC restriction. Unlike LN clones that overexpressed V beta 8 (46%+) and V beta 6 (31%+), however, SC clones were strongly biased (86%+) in their expression of V beta 6. This V gene bias raised the possibility of TCR peptide therapy using V beta 6 peptides. The V beta 6 sequence was similar to V beta 8.2 in the CDR2 region, and the corresponding peptides from this region were found to be cross-reactive in vivo. Moreover, both peptides were effective in the treatment of EAE induced with either S85-99, biased in V beta 6+ and V beta 8+ T cells, or guinea pig basic protein, biased only in V beta 8+ T cells. These data demonstrate the presence of common immunogenic epitopes among subsets of TCR V region gene families that possess important regulatory activity on effector T cell function.     

Multiple, autoreactive TCR V beta genes utilized in response to a small pathogenic peptide of an autoantigen in EAU.

The restricted usage of particular T cell receptor beta chain genes in autoimmune disease was studied in LEW rats using T cell hybridomas specific for an immunodominant sequence of bovine retinal S-Ag, which induces experimental autoimmune uveoretinitis. T cell hybridomas from a pathogenic T cell line, R858, specific for residues 273-289 of bovine retinal S-Ag were analyzed in order to determine the contribution of their TCR V beta to self specificity as determined by recognition of the pathogenic epitope represented in the autologous rat S-Ag sequence. Six different, functional TCR rearrangements were expressed by the panel of hybridomas, including two distinct V beta 8.2 rearrangements and functional V beta 10, V beta 14, V beta 19 rearrangements, and an unidentified V beta gene. All hybridomas were Ag specific and reacted both to nonself-peptide derivatives as well as to self-peptide homologues. No unique pattern of peptide reactivity distinguished V beta 8.2+ hybridomas from V beta 8.2- hybridomas; all of the hybridomas were most reactive to the nonself sequences and reacted to self peptide with one to three orders of magnitude less sensitivity. However, all V beta 8.2+ hybridomas were much better responders overall and were activated by lower concentrations of all peptides than were V beta 8.2- hybridomas. Although V beta 8.2 gene usage is strongly associated with autoimmune pathology, these data show that in LEW rats several different TCR V beta genes are utilized in response to a short pathogenic sequence of this autoantigen and show that V beta 8.2 receptors are not uniquely self-reactive. However, the enhanced reactivity to Ag of V beta 8.2+ hybridomas relative to V beta 8.2- hybridomas specific for the same peptide may help explain the close association of V beta 8.2 TCR gene usage with pathogenicity found in autoimmune disease models.     

The immunopathology of acute experimental allergic encephalomyelitis induced with myelin proteolipid protein. T cell receptors in inflammatory lesions.

To determine whether there is predominance of T cells expressing a particular TCR V beta chain in the inflammatory lesions of an autoimmune disease model, TCR expression was analyzed in central nervous system (CNS) tissues of mice with experimental allergic encephalomyelitis (EAE). Acute EAE was induced in SJL/J mice either by sensitization with a synthetic peptide corresponding to myelin proteolipid protein residues 139-151 or by adoptive transfer of myelin proteolipid protein peptide 139-151-specific encephalitogenic T cell clones. Mice were killed when they showed clinical signs of EAE or by 40 days after sensitization or T cell transfer. Cryostat CNS and lymphoid tissue sections were immunostained with a panel of mAb to T cell markers and proportions of stained cells were counted in inflammatory foci. In mice with both actively induced and adoptively transferred EAE, infiltrates consisted of many CD3+, TCR alpha beta+, and CD4+ cells, fewer CD8+ cells, and small numbers of TCR gamma delta+ cells. Approximately 30% of CD45+ leukocytes in the inflammatory foci were T cells. Cells expressing TCR V beta 2, 3, 4, 6, 7 and 14 were detected in the infiltrates, whereas TCR V beta 8 and 11, which that are deleted in SJL mice, were absent. When EAE was induced by transfer of T cell clones that use either V beta 2, 6, 10, or 17, there was also a heterogeneous accumulation of T cells in the lesions. Similar proportions of TCR V beta+ and gamma delta+ cells were detected in EAE lesions and in the spleens of the mice. Thus, at the time that clinical signs are present in acute EAE, peripherally derived, heterogeneous TCR V beta+ cells are found in CNS lesions, even when the immune response is initiated to a short peptide Ag or by a T cell clone using a single TCR V beta.     

Pertussis toxin prevents the induction of peripheral T cell anergy and enhances the T cell response to an encephalitogenic peptide of myelin basic protein.

In a murine model of T cell-mediated autoimmune disease, experimental autoimmune encephalitis (EAE), 80% of all encephalitogenic T cell clones in H-2u mice use the V beta 8.2 TCR element. To induce EAE in susceptible strains of mice either heat-killed Bordetella pertussis organisms or Bordetella pertussis toxin (PT) must be injected in addition to Ag in CFA. We investigated the mechanisms by which PT facilitates the induction of EAE. Our data show, that PT interferes with the induction of Ag-induced peripheral T cell anergy. Furthermore it has a specific adjuvanticity for the autoantigen pAc1-11 in vivo and acts as a selective mitogen in vitro. We also tested the hypothesis that PT is a bacterial superantigen that specifically expands the V beta 8.2+ subset of T cells, thereby expanding the encephalitogenic T cell clones that are contained in this subset, so that the number of autoreactive T cells is brought over a critical threshold, necessary to induce autoimmune disease. Our data show that PT is not a superantigen. Staphylococcal enterotoxin B, a V beta 8.2-specific superantigen, does not enhance the immune response to the encephalitogenic peptide.     

Antibodies specific for VB8 receptor peptide suppress experimental autoimmune encephalomyelitis.

Recent studies from our laboratory have shown, for the first time, that a synthetic peptide from that TCR VB chain used preferentially by encephalitogenic T cells induced the formation of protective, MHC class I-restricted T cells and prevented the development of EAE in Lewis rats. In this report we 1) demonstrate that immunization with the TCR-VB8-39-59 peptide generated peptide-specific antibodies that protect against experimental autoimmune encephalomyelitis induced by either of the two distinct encephalitogenic epitopes of basic protein, and 2) characterize the production and biologic functions of rat and rabbit antibody responses to the TCR peptide. The antibodies in both species increased in titer over time, were highly specific for the immunogen by direct reaction and inhibition assays, stained only VB8+ T cells, and suppressed clinical signs and to lesser extent the number of histologic lesions of experimental autoimmune encephalomyelitis mediated by VB8+ T cells. Coupled with our previous work, these results indicate that both humoral and cellular responses to the TCR-VB8-39-59 peptide can contribute independent immunoregulatory effects on encephalitogenic T lymphocytes that use common V region genes in response to epitopes of myelin basic protein.     

Characterization of the immune response to a secondary encephalitogenic epitope of basic protein in Lewis rats. II. Biased T cell receptor V beta expression predominates in spinal cord infiltrating T cells.

The immune response of Lewis rat lymph node T cells to guinea pig myelin basic protein (GP-BP) in experimental allergic encephalomyelitis is directed primarily against a region of basic protein encompassed by residues 72-89. T cells that respond to this epitope are restricted by the RT1.B class II molecule of the MHC and use V beta 8.2 exclusively in their TCR. A second region of GP-BP, residues 87-99, also induces experimental allergic encephalomyelitis in Lewis rats but this response is restricted primarily by RT1.D. Elsewhere we describe the biologic characteristics of T cell clones responding to the synthetic peptide, s87-99, and to a related peptide, s85-99. We present a detailed analysis of TCR V beta gene expression among these clones, derived from the lymph node and spinal cord of immunized animals, and among spinal cord derived T cell clones reactive to GP-BP 72-89. We find that spinal cord-derived clones, reactive to s85-99 and to s87-99, use V beta 6 predominantly. In contrast, T cell clones derived from lymph nodes and reactive to the same peptides express multiple V beta genes including V beta 6. This difference in heterogeneity of V beta usage at the clonal level is also seen in T cell lines derived from spinal cord and immune lymph node. DNA sequence comparison of the CDR3 regions in V beta 6+ spinal cord clones revealed a conserved amino acid motif also found in the majority of V beta 6 sequences from the spinal cord anti-s85-99 line. Although V beta 6 was expressed in some lymph node-derived clones, only one contained a CDR3 region similar to that seen in spinal cord isolates. All spinal cord-derived T cell clones reactive to GP-BP 72-89 used V beta 8.2 and most (five of six) contained the AspSer residues in CDR3 previously shown to be associated with V beta 8.2 receptors expressed by the majority of lymph node T cells responding to GP-BP 72-89. These data indicate that TCR V beta usage in peripheral T cells responding to an autoantigen does not always predict the V beta usage among T cells at the site of an autoimmune attack. Possible explantations for the relative homogeneity in TCR V beta expression seen in T cell clones derived from the spinal cord are discussed.     

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

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

Nonencephalitogenic CD4-CD8- V alpha 2V beta 8.2+ anti-myelin basic protein rat T lymphocytes inhibit disease induction.

Recently there has been a number of reports suggesting that CD4-CD8- T cells participate in the processes of inflammatory reaction. In an attempt to delineate the distinctive functions of double negative (DN) T lymphocytes in an autoimmune-induced disease, we isolated and cloned such T cells, along with control CD4+ cells, from Lewis rats immunized with guinea-pig myelin basic protein in CFA. Both clones proliferated in response to the guinea-pig myelin basic protein and its synthetic encephalitogenic peptide, and expressed the same TCR V genes homologous to the mouse V alpha 2 and V beta 8.2 families that appear to be the defining entity of experimental autoimmune encephalomyeltis (EAE). Moreover, the TCR D and J region gene products of the DN cell were found to be similar to another encephalitogenic rat T cell clone. The two T clones did not differ markedly in their ability to produce TNF and IL-2 and to adhere to vascular wall-derived extracellular matrix- and laminin-coated plates. Surprising, therefore, was the finding that, although the CD4+ T lymphocytes were capable of inducing EAE, the DN cells did not elicit disease but rather inhibited subsequent EAE induction. Thus, TCR V alpha 2V beta 8.2 and its junctional region gene products are not the only prerequisite segment for a T cell to become encephalitogenic. We suggest that the important determinants of the T cell ability to induce disease are features of the T cell, other than or in addition to, the T cell receptor.     

Diverse fine specificity and receptor repertoire of T cells reactive to the major VP1 epitope (VP1230-250) of Theiler's virus: V beta restriction correlates with T cell recognition of the c-terminal residue.

Theiler's murine encephalomyelitis virus induces chronic demyelinating disease in genetically susceptible mice. The histopathological and immunological manifestation of the disease closely resembles human multiple sclerosis, and, thus, this system serves as a relevant infectious model for multiple sclerosis. The pathogenesis of demyelination appears to be mediated by the inflammatory Th1 response to viral epitopes. In this study, T cell repertoire reactive to the major pathogenic VP1 epitope region (VP1233-250) was analyzed. Diverse minimal T cell epitopes were found within this region, and yet close to 50% of the VP1-reactive T cell hybridomas used V beta 16. The majority (8/11) of the V beta 16+ T cells required the C-terminal amino acid residue on the epitope, valine at position 245, and every T cell hybridoma recognizing this C-terminal residue expressed V beta 16. However, the complementarity-determining region 3 sequences of the V beta 16+ T cell hybridomas were markedly heterogeneous. In contrast, such a restriction was not found in the V alpha usage. Only restricted residues at this C-terminal position allowed for T cell activation, suggesting that V beta 16 may recognize this terminal residue. Further functional competition analysis for TCR and MHC class II-contacting residues indicate that many different residues can be involved in the class II and/or TCR binding depending on the T cell population, even if they recognize the identical minimal epitope region. Thus, recognition of the C-terminal residue of a minimal T cell epitope may associate with a particular V beta (but not V alpha) subfamily-specific sequence, resulting in a highly restricted V beta repertoire of the epitope-specific T cells.     

Stimulation of mouse lymphocytes by a mitogen derived from Mycoplasma arthritidis (MAM). VIII. Selective activation of T cells expressing distinct V beta T cell receptors from various strains of mice by the "superantigen" MAM

Mycoplasma arthritidis T cell mitogen (MAM), in association with its MHC ligand, is recognized by T cells that express TCR-alpha/beta assembled with a product(s) of the V beta 8 gene family. We show here that lymphocytes from mice which fail to express V beta 8 products can also be activated by MAM and the resulting cultures exhibit a marked increase in V beta 6 TCR-bearing cells. Evidence was also obtained that MAM can activate T cells that express all three V beta 8 TCR. The mAb, F23.1, which recognizes all V beta 8 gene products, was strongly inhibitory for MAM-induced proliferation of CBA cells whose T cell repertoire for MAM consists of T cells that express V beta 8.2 and 8.3 TCR. In contrast, the F23.1 mAb was only weakly inhibitory for BALB/c splenocytes which express V beta 6 TCR in addition to all three V beta 8 TCR. Involvement of V beta 8.1, 8.2, 8.3, and V beta 6 in MAM-induced proliferation was confirmed by expanding lymphocyte cultures in the presence of MAM and phenotyping the activated cells for expression of individual V beta TCR. There was also evidence for a selective activation of T cells bearing specific V beta TCR because BALB/c T cell populations expanded with MAM were comprised of 46.2% V beta 8.2+ cells, 18.6% V beta 8.1+ cells, 7.6% V beta 8.3+ cells and 6.7% V beta 6+ cells. Recent studies suggest that the newly described "superantigens" including the staphylococcal enterotoxins and the self minor lymphocyte-stimulating Ag activate T cells in a manner similar to that described earlier for MAM. The discovery of shared recognition of these proteins by specific V beta TCR strongly suggests that MAM belongs to the superantigen protein family, the members of which may share cross-reactive epitopes. Inasmuch as MAM is produced by an organism which induces chronic joint disease, our findings provide the basis for a new model to study the role of superantigens in the development of chronic autoimmune type diseases.     

Restricted use of T cell receptor V genes in murine autoimmune encephalomyelitis raises possibilities for antibody therapy

Experimental allergic encephalomyelitis (EAE) is a paralytic autoimmune disease induced in susceptible animals by active immunization with myelin basic protein (MBP) or by passive transfer of MBP-specific T helper (TH) lymphocytes. We have analyzed the T cell receptor genes of 33 clonally distinct TH cells specific for a nonapeptide of MBP inducing EAE in B10.PL (H-2u) mice. All 33 TH cells used two alpha variable gene segments (V alpha 2.3, 61%; V alpha 4.2, 39%), the same alpha joining gene segment (J alpha 39), and two V beta and J beta gene segments (V beta 8.2-J beta 2.6, 79%; V beta 13-J beta 2.2, 21%). The anti-V beta 8 monoclonal antibody F23.1 was found to block completely recognition of the nonapeptide by V beta 8 TH cells in vitro and to reduce significantly the susceptibility of B10.PL mice to peptide-induced EAE.     

Regulatory T cells control autoimmunity in vivo by inducing apoptotic depletion of activated pathogenic lymphocytes

Clinical autoimmunity requires both activation of self-reactive T cells as well as a failure of peripheral tolerance mechanisms. We previously identified one such mechanism that involves regulatory T cells recognizing TCR V beta 8.2 chain-derived peptides in the context of MHC. How this regulation affects the fate of target V beta 8.2(+) T lymphocytes in vivo that mediate experimental autoimmune encephalomyelitis has remained unknown. The present study using immunoscope and CFSE-labeling analysis demonstrates that the expansion of regulatory CD4 and CD8 T cells in vivo results in apoptotic depletion of the dominant, myelin basic protein-reactive V beta 8.2(+) T cells, but not subdominant V beta 13(+) T cells. The elimination of only activated T cells by this negative feedback mechanism preserves the remainder of the naive V beta 8.2(+) T cell repertoire and at the same time results in protection from disease. These studies are the first in clearly elucidating the fate of myelin basic protein-specific encephalitogenic T cells in vivo following regulation.     

Experimental allergic encephalomyelitis mediated by cloned T cells specific for a synthetic peptide of myelin proteolipid protein. Fine specificity and T cell receptor V beta usage.

Proteolipid protein (PLP) is the major protein of central nervous system myelin. SJL (H-2s) mice immunized with a synthetic peptide corresponding to PLP residues 139-151 develop acute EAE. In this study, 6 IAs-restricted, CD4+, TCR alpha beta-bearing T cell clones were derived from SJL/J mice after immunization with this synthetic peptide. The clones responded in in vitro proliferative assays to the whole PLP molecule and to PLP peptide 139-151, but not to irrelevant Ag. They also responded to truncated and overlapping forms of the peptide but five distinct reactivity patterns were observed using these peptides. A panel of anti-TCR V beta mAb and TCR V beta-specific cDNA probes were used to determine the TCR V beta usage of the clones. Five clones were found to use four different V beta (V beta 2, V beta 6, V beta 10, or V beta 17a), whereas the V beta on the sixth clone could not be identified. Five of the clones induced EAE of varying severity upon adoptive transfer into naive syngeneic mice or mice pretreated with irradiation and pertussis and one clone was nonencephalitogenic. The Ag-specific proliferative response of all but the nonencephalitogenic clone could be blocked by an anti-CD4 mAb. Thus, the clones showed differences in their fine specifity, TCR V beta usage, sensitivity to antibody blocking, and encephalitogenic potency. These data demonstrate that the T cell response to the encephalitogenic PLP peptide 139-151 is heterogeneous.     

Limited T cell receptor beta-chain usage in the sperm whale myoglobin 110-121/E alpha dA beta d response by H-2d congenic mouse strains.

The specificity and TCR gene usage of a panel of sperm whale myoglobin (SpWMb)-reactive T cell clones from DBA/2 mice have previously been characterized, to study structure-function relationships between components of the ternary complex consisting of Ag, TCR, and MHC class II molecules, whose interaction leads to Th cell activation. These DBA/2 clones were specific for epitopes within the residue 110 to 121 region of SpWMb, in the context of the mixed isotype molecule E alpha dA beta d, and expressed the TCR V beta 8.2 gene element. SpWMb-specific T cell hybridomas from the H-2d-congenic B10.D2 mouse strain, which differs from the DBA/2 strain only in the non-MHC background, were generated and compared with the T cell hybridomas from DBA/2 mice, in order to investigate the influence of non-MHC genes on the specificity of the T cell response to the 110-121 epitope. V beta usage by these hybridomas was very homogeneous; three of three DBA/2 and eight of nine B10.D2 hybridomas specific for the 110-121 epitope, in the context of the mixed isotype molecule E alpha dA beta d, expressed the V beta 8.2 gene product. Nucleotide and amino acid sequences of D beta, J beta, and N regions were also similar. One 110-121/E alpha dA beta d-specific B10.D2 hybridoma used V beta 7, a V beta that is clonally deleted in DBA/2 mice. These experiments suggest that a similar set of TCR beta genes are used to respond to a given epitope, regardless of non-MHC background, and they support the hypothesis that, despite great variability between individuals in their non-MHC background genes, human HLA-associated diseases might result from the formation of a particular ternary complex consisting of a shared MHC molecule, a common "disease-associated" epitope, and a shared TCR.     

Conformational difference of T cell antigen receptors revealed by monoclonal antibodies to mouse V beta 5 T cell receptor for antigen determinants.

The mAb MR9-4 and MR9-8 react with T cells expressing the V beta 5.1 and -5.2 chains of the TCR. T cells expressing V beta 5.1 TCR were stained by both antibodies with similar surface fluorescence intensity. For the T cell clones and hybridomas expressing V beta 5.2 TCR, staining intensity with MR9-8 varied from negative to comparable to that stained with the anti-pan V beta 5 mAb MR9-4, whereas every V beta 5-positive T cell can be activated with either MR9-4 or -9-8 mAb, suggesting a differential binding affinity of MR9-8 mAb to V beta 5 TCR molecules. Analysis of J beta segment and V alpha chain usage in the V beta 5-positive T cell hybridomas revealed that a differential binding of MR9-8 mAb to the V beta 5.2 chain is not dependent on either the J beta segment usage or the associating V alpha chain alone. These results suggest that the differential binding of MR9-8 mAb to V beta 5.2 TCR is due to the conformational change of the V beta chain created by a combination of the V alpha (possibly J alpha) and D beta-J beta segment associating with the V beta 5.2 chain.     

Determinants of human myelin basic protein that induce encephalitogenic T cells in Lewis rats

Due to critical amino acid changes in the 72-89 sequence, the determinant of human (Hu) basic protein (BP) that induces experimental autoimmune encephalomyelitis (EAE) in Lewis rats most likely differs from rat and guinea pig BP. To discern encephalitogenic sequence(s), the immunodominant epitopes recognized by Hu-BP-specific T cell lines were identified using synthetic peptides that corresponded to the Hu-BP sequence. The Hu-BP-reactive T cell line contained two distinct specificities, one directed at the 87-99 (Hu) sequence restricted by I-E, and the second directed at the 55-74 (Hu) sequence restricted by I-A. T cells specific for the 87-99 determinant recognized both Hu- and Rt-BP, were highly encephalitogenic, and accounted for the experimental autoimmune encephalomyelitis-inducing activity of the Hu-BP line. T cells directed at the S55-74 (Hu) sequence did not recognize Rt-BP and were not encephalitogenic. The same TCR V genes (homologous to the mouse V alpha 2 and V beta 8 families) that we showed previously were utilized preferentially in response to the I-A restricted 72-89 encephalitogenic sequence were also present in T cell lines specific for both the S55-74 and S87-99 epitopes. These data indicate that encephalitogenic activity of BP in Lewis rats is related to discrete T cell epitopes that are present on or cross-react with rat-BP. Furthermore it would appear that genes in the TCR V alpha 2 and V beta 8 families are widely used in response to different BP epitopes restricted by either I-A or I-E molecules.     

The TCR repertoire of an immunodominant CD8+ T lymphocyte population

The TCR repertoire of an epitope-specific CD8(+) T cell population remains poorly characterized. To determine the breadth of the TCR repertoire of a CD8(+) T cell population that recognizes a dominant epitope of the AIDS virus, the CD8(+) T cells recognizing the tetrameric Mamu-A*01/p11C(,CM) complex were isolated from simian immunodeficiency virus (SIV)-infected Mamu-A*01(+) rhesus monkeys. This CD8(+) T cell population exhibited selected usage of TCR V beta families and complementarity-determining region 3 (CDR3) segments. Although the epitope-specific CD8(+) T cell response was clearly polyclonal, a dominance of selected V beta(+) cell subpopulations and clones was seen in the TCR repertoire. Interestingly, some of the selected V beta(+) cell subpopulations and clones maintained their dominance in the TCR repertoire over time after infection with SIV of macaques. Other V beta(+) cell subpopulations declined over time in their relative representation and were replaced by newly evolving clones that became dominant. The present study provides molecular evidence indicating that the TCR repertoire shaped by a single viral epitope is dominated at any point in time by selected V beta(+) cell subpopulations and clones and suggests that dominant V beta(+) cell subpopulations and clones can either be stable or evolve during a chronic infection.     

Preferential use of a T cell receptor V beta gene by acetylcholine receptor reactive T cells from myasthenia gravis-susceptible mice.

Experimental autoimmune myasthenia gravis (EAMG) is an important model for testing current concepts in autoimmunity and novel immunotherapies for autoimmune diseases. The EAMG autoantigen, acethylcholine receptor (AChR), is structurally and immunologically complex, a potential obstacle to the application of therapeutic strategies aimed at oligoclonal T cell populations. Inasmuch as we had previously shown that the clonal heterogeneity of T cell epitope recognition in EAMG was unexpectedly limited, we examined TCR V beta expression. AChR primed lymph node T cells and established AChR reactive T cell clones from EAMG-susceptible C57BL/6 (B6; H-2b, Mls-1b) mice showed preferential utilization of the TCR V beta 6 segment of the TCR. After in vivo priming and in vitro restimulation for 7 days with AChR or a synthetic peptide bearing an immunodominant epitope, V beta 6 expressing lymph node cells (LNC) were expanded several-fold, accounting for up to 75% of recovered viable CD4+ cells. The LNC of B6.C-H-2bm12 (bm12; H-2bm12, Mls-1b) mice, which proliferated in response to AChR but not to the B6 immunodominant peptide, failed to expand V beta 6+ cells. Inasmuch as nonimmune bm12 and B6 animals had similar numbers of V beta 6+ LNC (4-5%), this suggested that structural requirements for TCR recognition of Ag/MHC complexes dictated V beta usage. Results concerning peptide reactivity and V beta 6 expression among T cells from (B6 x bm12)F1 animals also suggested that structure-function relationships, rather than negative selection or tolerance, accounted for the strain differences between B6 and bm12. To examine the potential effects of thymic negative selection of V beta 6+ cells on the T cell response to AChR, CB6F1 (H-2bxd, Mls-1b; V beta 6-expressing) and B6D2F1 (H-2bxd, Mls-1axb; V beta 6-deleting) strains were analyzed for AChR and peptide reactivity and V beta 6 expression. Both F1 strains responded well to AChR but the response of B6D2F1 mice to peptide was significantly reduced compared to CB6F1. Short and long term cultures of peptide-reactive B6D2F1 LNC showed no expansion of residual V beta 6+ cells, although similar cultures of CB6F1 LNC were composed of more than 60% V beta 6+ cells. The results from the F1 strains further indicated that the T cell repertoire for peptide was highly constrained and that non-V beta 6 expressing cells could only partially overcome Mls-mediated negative selection of V beta 6+ TCR capable of recognizing peptide.(ABSTRACT TRUNCATED AT 400 WORDS)