Shared human T cell receptor V beta usage to immunodominant regions of myelin basic protein

Further localization of a multiple sclerosis susceptibility gene on chromosome 7q using a new T cell receptor beta-chain DNA polymorphism

Multiple sclerosis (MS) has been associated with particular HLA haplotypes and has recently been reported to also be associated with the T cell receptor (TCR) beta-chain complex. We have tried to determine the source of the TCR-beta/MS association by exploiting the pattern of linkage disequilibrium within the TCR-beta complex. We describe a new DNA polymorphism with the TCR variable region gene segment V beta 15 which appears to localize between the constant region and V beta 11. When the distribution of V beta 11-V beta 15 haplotypes in MS patients was compared to healthy controls, the strength of the V beta 11-V beta 15 MS association (p = 0.107) was much less than the MS association with the adjacent V beta 8-V beta 11 haplotype (p = 0.0010). On the basis we exclude an MS susceptibility gene telomeric to V beta 11. The reported MS association with the TCR-beta gene complex therefore does not appear to be due to genes within the diversity, joining, or constant region but more likely involves a specific gene(s) within the variable region.

T cell receptor V gene usage of islet beta cell-reactive T cells is not restricted in non-obese diabetic mice

Five islet-reactive T cell clones were established from islet-infiltrating T cells of non-obese diabetic (NOD) mice. All clones expressed CD4, but not CD8, and responded to islet cells from various strains of mice in the context of I-ANOD. They could induce insulitis when transferred into disease-resistant I-E+ transgenic NOD mice. The T cell receptor (TCR) sequences utilized by the clones were determined. Their usage of TCR V and J segments was not restricted but was rather diverse. One of the clones utilized V beta 16. The expression of V beta 16 was significantly reduced in I-E+ transgenic NOD, suggesting the possibility that the islet-reactive T cell clone expressing V beta 16 may be deleted or inactivated by I-E molecules. This clone might be one of the candidates that triggers insulitis.

Autoimmunity, microbial immunity and the immunological homunculus

Clonal deletion and anergy are believed by many immunologists to be the fundamental mechanisms responsible for self tolerance. Nevertheless, as Irun Cohen and Douglas Young point out, such notions of nonreactivity cannot explain certain key features of immune behaviour: the immunological dominance of microbial antigens that mimic self, the uniformity of autoimmune diseases and the prevalence of natural autoimmunity among the healthy. The theory of the immunological homunculus is presented here as a unifying principle.

T cell receptor beta-chain usage in experimental autoimmune uveoretinitis

Genomic rearrangements to the T-cell receptor (TCR) V beta 8 gene locus were examined in T cells derived from the lymph nodes of Lewis rats immunized with either S-Antigen or peptides derived from interphotoreceptor retinoid binding protein (IRBP). The cells used in these studies are from T-cell lines that have been selected by several cycles of antigen/IL-2 stimulations, or clones isolated from these lines. No apparent rearrangement of the V beta 8 gene was observed by Southern analysis, suggesting that if indeed there are T cells using V beta 8 gene elements they represent small proportions of the cells in these T-cell lines that induce EAU (uveitogenic T cells) and that the lines may consist of large numbers of clones. On the other hand, we have demonstrated V beta 8 gene expression in uveitogenic T-cell populations by Northern analysis and by polymerase chain reaction (PCR). Although V beta 8 gene transcripts were detectable in pathogenic, but not in non-pathogenic, T-cell lines using a V beta 8 cDNA probe, RNA from pathogenic T cell lines did not hybridize to another probe specific for rat V beta 8.2. Taken together, these results suggest that, unlike the T-cell lines that mediate experimental allergic encephalomyelitis (EAE), some T-cell lines that induce EAU do not predominantly express V beta 8.2 gene but other member(s) of the V beta 8 family.

Restricted T-cell receptor V beta gene usage by myelin basic protein-specific T-cell clones in multiple sclerosis: predominant genes vary in individuals

Recent studies in experimental autoimmune encephalomyelitis as a model for multiple sclerosis (MS) have demonstrated limited heterogeneity in T-cell antigen receptors (TCR) specific for myelin basic protein (MBP). To investigate restricted beta-chain variable-region (V beta) gene usage in humans, we analyzed TCR gene rearrangements in two lines and 34 MBP-specific T-cell clones that were isolated from five MS patients and two healthy subjects. The T cells were characterized for their specificity to MBP epitopes and HLA-restricting molecules. We demonstrate here that MBP-specific T-cell clones from these different MS patients and healthy individuals, in contrast to T cells from rodents, display a more diverse V beta gene usage as evidenced by their TCR V beta gene rearrangements. However, the different MBP-specific T-cell clones isolated from each individual MS patient showed a common V beta gene usage, suggesting individual-specific TCR restriction. Out of 16 MBP-specific clones derived from a single MS patient, 12 clones (75%) utilized the V beta 15 gene for their TCR gene rearrangement. MBP-specific clones isolated from four other MS patients also showed a consistent tendency for a predominant, but different, TCR V beta gene rearrangement. These results suggest a TCR heterogeneity among MBP-specific T-cell clones from different individuals but a limited TCR V beta gene usage among MBP-specific T-cell clones of the same individual. The predominant V beta gene used by the MBP-specific T-cell clones studied here was not found to correlate with the epitope specificity of T cells or with their restricting HLA molecule. These findings may support the possibility of intervention with monoclonal antibodies to specific V beta gene products as an approach to immune therapy of MS but also imply the necessity for an individual-specific immunotherapeutic approach.

Molecular diagnosis of cutaneous T-cell lymphoma: polymerase chain reaction amplification of T-cell antigen receptor beta-chain gene rearrangements

The goal of our study was to molecularly diagnose CTCL, by cloning the T-cell antigen receptor beta chain (TCR-beta) gene rearrangement from the malignant T cells of a patient with Sézary syndrome, in order to generate a specific oligonucleotide probe capable of detecting CTCL cells through polymerase chain reaction (PCR) amplification. Total RNA isolated from peripheral blood lymphocytes was reverse transcribed and resultant first strand cDNA was PCR amplified utilizing a concensus primer to the TCR-beta variable region (V beta) and a 3' primer to the TCR-beta constant region (C beta). PCR reaction products were subcloned into a plasmid vector and sequenced. Sequence analysis revealed that the patient's in-frame TCR-beta gene rearrangement utilized V beta 6.4, D beta 1.1, J beta 2.2, and C beta 2.1 gene segments. Oligo-primers to V beta 6.4 and J beta 2.2 were utilized to PCR amplify genomic DNA taken from the patient's blood and involved skin. Screening the amplified DNA with an oligo-probe specific for the patient's V-D-J junctional sequences resulted in the detection of the patient-specific sequences. No sequences were detected from DNA from other malignant or benign infiltrates. Thus, we have defined a "molecular fingerprint" specific for a patient's malignant T-cells and can molecularly diagnose CTCL through PCR amplification.

Heterogeneity of the T-cell receptor beta gene rearrangements generated in myelin basic protein-specific T-cell clones isolated from a patient with multiple sclerosis

Seventeen T-cell clones derived from the peripheral blood of a patient with multiple sclerosis and reactive with a synthetic peptide corresponding to residues 152-170 of the human myelin basic protein molecule were previously shown to be cytotoxic for myelin basic protein-coated target cells. Genetic restriction studies have now demonstrated that these clones recognize myelin basic protein in association with human leukocyte antigen DRw13. Studies of the T-cell receptor beta gene rearrangements generated by these clones demonstrated 12 different patterns, as evaluated by Southern blot analysis. Thus, the human T-cell response to myelin basic protein is exceedingly heterogeneous, even among T cells that recognize the same small fragment of the molecule in association with the same class II restriction element.

Assessment of antigenic determinants for the human T cell response against myelin basic protein using overlapping synthetic peptides

Immunization of experimental animals with myelin basic protein (MBP) or with specific MBP encephalitogenic determinants induces an autoimmune central nervous system (CNS) disease, experimental allergic encephalomyelitis, often studied as a model for human demyelinating disorders. This study examines the antigenic determinants of MBP recognized by human T cells using overlapping, synthetic peptides and T cell lines and clones isolated from four HLA-typed, neurologically normal subjects. T cell lines and clones isolated from individual subjects recognized at least one and as many as five distinct T cell determinants. In some instances the peptides recognized included determinants previously shown to induce experimental allergic encephalomyelitis (EAE) in experimental animals. In this group of four subjects, some determinants of MBP, including residues 5-25, 35-47, 65-75, and 81-100, were recognized by T cells derived from more than one individual suggesting that these regions may be particularly immunogenic for humans.

T cell receptor peptide therapy triggers autoregulation of experimental encephalomyelitis

Encephalitogenic T cells specific for myelin basic protein share common V beta 8 peptide sequences in their T cell receptor (TCR) that can induce autoregulatory T cells and antibodies that prevent clinical signs of experimental autoimmune encephalomyelitis (EAE). It is not known, however, if TCR peptides can treat established disease. To test its therapeutic value, TCR-V beta 8-39-59 peptide was injected into rats with clinical signs of EAE. This treatment reduced disease severity and speeded recovery, apparently by boosting anti-V beta 8 T cells and antibodies raised naturally in response to encephalitogenic V beta 8+ T cells. These results demonstrate that synthetic TCR peptides can be used therapeutically, and implicate the TCR-V beta 8-39-59 sequence as a natural idiotope involved in EAE recovery. Similarly, human TCR peptides may be effective in enhancing natural regulation of autoreactive T cells that share common V genes.

Common T-cell receptor V beta usage in oligoclonal T lymphocytes derived from cerebrospinal fluid and blood of patients with multiple sclerosis

T-cell populations were investigated in the blood and cerebrospinal fluid of patients with multiple sclerosis and other neurological diseases. Individual T cells were directly cloned from the cerebrospinal fluid and blood before in vitro expansion, and their clonotypes were compared by Southern blot analysis of the rearrangement patterns of their T-cell receptor beta chain and gamma chain genes. This allowed the determination of whether two T cell clones shared the same T-cell receptor and thus arose from identical, clonally expanded (oligoclonal) progenitor T cells. As an extension of previous studies, oligoclonal T-cell clones were identified in both cerebrospinal fluid and blood populations in 5 of 9 patients with inflammatory demyelinating disease among a total of 486 blood and cerebrospinal fluid T-cell clones. In contrast, no clonally expanded T-cell populations were found among a total of 424 clones derived from either blood of 4 normal control subjects or blood and cerebrospinal fluid of 8 patients with other neurological diseases. Analysis of T-cell receptor V beta genes among 4 oligoclonal T-cell populations derived from 3 patients with multiple sclerosis demonstrated common usage of the V beta 12 gene segment. These data suggest that oligoclonal T cells share similar specificities and that clonal expansion may have resulted from specific stimulation by an antigen. Moreover, identical clones between blood and cerebrospinal fluid were observed in 3 of 9 patients with demyelinating disease, thus providing further evidence of an equilibrium between peripheral and central nervous system immune compartments.

Interleukin-1 corrects the defective autologous mixed lymphocyte response in multiple sclerosis

Patients with chronic progressive multiple sclerosis (MS) have alterations of T cell regulation that can be measured by in vitro assays and include decreases of the autologous mixed lymphocyte reaction (AMLR). Whether a defect in cytokine secretion was involved in the altered AMLR was investigated in 29 MS patients and 13 age- and sex-matched controls. The response of CD4+ T cell populations to irradiated non-T cells was decreased in MS as compared to control subjects. As previously reported, decreases in the AMLR were similarly observed with whole T cells of MS subjects as compared to controls. The addition of recombinant interleukin (IL)-1 to cultures of either whole T cells or CD4+ T cells with irradiated non-T cells in the AMLR corrected the immune defect in subjects with MS but had no effect on the AMLR in control subjects. In contrast, addition of rIL-2 or rIL-4 to the AMLR did not correct the decreased AMLR in MS patients as compared to controls. The lymphokines IFN-gamma and TGF-beta 2 both decreased the AMLR in MS patients and controls while TNF had no effect. Further, the magnitude of the AMLR response corresponded to IL-1 secretion induced by LPS in the non-T cell population. These studies indicate that defects in IL-1 may be related to immune defects of suppression in MS patients. Selective correction of immunoregulatory defects using lymphokines or their inducers in subjects with autoimmune diseases such as MS may be possible.

Migration of hematogenous cells through the blood-brain barrier and the initiation of CNS inflammation

The central nervous system has long been considered an immunologically privileged site. Nevertheless, cells derived from the bone marrow can and do enter the CNS in a number of circumstances. Derivatives of the monocyte/macrophage lineage appear to enter and take up residence in various structures of the CNS as part of normal ontogeny and physiology. Immunocompetent cells, such as T-lymphocytes of both CD4 and CD8 positive groups, enter the nervous system in what appears to be a random fashion when they are activated by antigenic stimulation. These lymphocytes perform the required immunological surveillance of the CNS, and initiate inflammation therein during infectious and autoimmune reactions. In this review, the evidence supporting the above observations is examined, and a hypothesis for the pathogenesis of CNS inflammatory reactions is presented.

Lymphocytes cytotoxic to uveal and skin melanoma cells from peripheral blood of ocular melanoma patients

To study antitumor immunity in patients with choroidal melanoma, T cells were generated from the peripheral blood of choroidal melanoma patients by mixed lymphocyte/tumor cell culture (MLTC). Because autologous tumors are generally unavailable, an allogeneic choroidal melanoma cell line, OCM-1, was used as the specific stimulus. Lymphocyte cultures from 27 patients were characterized by cell-surface phenotypes, patterns of reactivity towards cells of the melanocytic origin and T-cell-receptor gene usage. Antimelanoma reactivity was found in cell-sorter-purified CD4+ and CD8+ T cell subsets. To analyze this reactivity, sorter-purified CD4+ and CD8+ cells from a MLTC were cloned by limiting dilution in the presence of exogenous interleukin-2 and interleukin-4 as well as irradiated OCM-1. Under these conditions, CD4+ T cells did not proliferate, perhaps because of the absence of antigen-presenting cells. However, CD8+ grew vigorously and 29 cytolytic CD8+ T cell clones were isolated. On the basis of their pattern of lysis of OCM-1, a skin melanoma cell line M-7 and its autologous lymphoblastoid cell line LCL-7, the clones were categorized into three groups. Group 1, representing 52% of the clones, lysed all three target cells, and are alloreactive. However, since OCM-1 and M-7 did not share class I antigens, these clones recognized cross-reactive epitope(s) of the histocompatibility locus antigen (HLA) molecule. Group 2, constituting 28% of the clones, lysed both the ocular and skin melanoma cell lines but not LCL-7, and were apparently melanoma-specific. Unlike classical HLA-restricted cytolytic T lymphocytes, these T cells might mediate the lysis of melanoma cells via other ligands or a more degenerate type of HLA restriction. For the latter, the HLA-A2 and -A28 alleles would have to act interchangeably as the restriction element for shared melanoma-associated antigen(s). Group 3, representing only 10% of the T cell clones, was cytotoxic only to OCM-1, but not to M-7 or LCL-7. These clones may recognize antigens unique to ocular melanoma cells. Our data suggest that choroidal melanoma patients can recognize melanoma-associated antigens common to both ocular and cutaneous melanoma cells, and presumbly their autologous tumor. Thus, choroidal melanoma, like its skin counterpart, may be responsive to immunotherapeutic regimens such as active specific or adoptive cellular immunotherapy.

Adoptive transfer of experimental allergic encephalomyelitis and localization of the encephalitogenic epitope in the SWR mouse

Adoptively-transferred experimental allergic encephalomyelitis (EAE) was induced in the SWR (H-2q) strain of mouse using lymph node cells, spleen cells, or cell lines sensitized to whole myelin basic protein (MBP). With the aid of synthetic peptides, the minimal encephalitogenic epitope of MBP for the SWR strain was localized to amino acids 87-99 of the MBP molecule. The 87-99 sequence is also encephalitogenic for the SJL strain of mouse and the Lewis rat. EAE was induced with a protocol similar to that for the induction of EAE in the SJL strain with the exception that sublethal irradiation of recipients was necessary. Mice developed typical clinical and pathological EAE 6-14 days post-transfer of cells sensitized to either whole MBP or peptide 87-99, after which they remitted. No relapses were observed. Thus, adoptively transferred EAE can be induced in irradiated H-2q mice for which the encephalitogenic epitope is one of the nested encephalitogenic epitopes for SJL (H-2s) mice, namely residues 87-99.

A myelin basic protein peptide is recognized by cytotoxic T cells in the context of four HLA-DR types associated with multiple sclerosis

We have examined previously the peptide specificity of the T cell response to myelin basic protein (MBP) in patients with multiple sclerosis (MS) and healthy controls, and demonstrated that an epitope spanning amino acids 87-106 was frequently recognized. Because this region is encephalitogenic in some experimental animals, it has been postulated that the response to the epitope may have relevance to MS. In this study, the fine specificity of this response is studied using four well-characterized, monospecific T cell lines from three MS patients and an identical twin of a patient. Each of the lines recognized a peptide with the same core sequence, amino acids 89-99, although the responses were affected to various degrees by truncations at the COOH- or NH2 terminal ends of the 87-106 epitope. Importantly, the epitope was recognized in conjunction with four different HLA-DR molecules. Also, the T cell receptor beta chain usage was heterogeneous, and each line expressed a different VDJ sequence. The four HLA-DR molecules restricting the response to this epitope have been shown to be overrepresented in MS populations in various geographic areas, suggesting that the response to this region of the MBP molecule may be relevant to the pathogenesis of MS. These findings may have important implications in designing therapeutic strategies for the disease.