Myelin basic protein-specific T-cell responses in identical twins discordant or concordant for multiple sclerosis.

Although multiple sclerosis (MS) is thought to be an autoimmune disease, the target antigen of the immune response is unknown. Both myelin basic protein (MBP) and proteolipid protein (PLP) have been considered candidate autoantigens. Because the immune response to either foreign or self antigens is influenced by the genetic background of the host, the importance of these candidate antigens has been difficult to establish in humans because of genetic diversity. To eliminate genetic differences in MS patients and healthy controls, we have studied the MBP-specific T-cell response in 6 sets of identical twins, 3 of which were concordant and 3 discordant for MS. A total of 638 short-term T-cell lines were established and characterized for MBP-specific proliferative and cytotoxic activity, fine specificity, and human leukocyte antigen (HLA) restriction. Similar frequencies of MBP-specific T cells were observed in affected and unaffected individuals. A slightly higher percentage of cytotoxic T-cell lines was found in affected individuals. For most of the cell lines, the restriction elements were the HLA class II antigens that have been reported previously to be associated with MS; no important differences with respect to HLA restriction were found between the patients and healthy individuals. The peptide epitopes of MBP that were recognized most frequently by the T-cell lines were those previously shown to be immunodominant. Differences in specificity were seen in some discordant twins indicating that, despite genetic identity, the MBP-specific T-cell repertoire may be shaped differently. These findings indicate that differences in frequency, peptide specificity, or HLA restriction are not sufficient to implicate MBP-specific T cells in the pathogenesis of MS. However, the T-cell response to MBP may still represent one necessary component with disease occurring when this response is combined with other host characteristics such as regulation of cytokine-, adhesion molecule-, or HLA-antigen expression in the nervous system or immunoregulatory mechanisms.

Skewed T-cell receptor repertoire in genetically identical twins correlates with multiple sclerosis.

Although the cause of multiple sclerosis (MS) is unknown, it is thought to involve a T cell-mediated autoimmune mechanism. Susceptibility to the disease is influenced by genetic factors such as genes of the HLA and T-cell receptor (TCR) complex. Other evidence for a genetic influence includes the low incidence in certain ethnic groups, the increased risk if there are affected family members and the increased concordance rate for disease in monozygotic twin pairs (26%), compared to dizygotic twins. Epidemiological studies indicate that there may be an additional role for environmental factors. Although the target antigen(s) are not yet identified, several myelin or myelin-associated proteins have been suspected, among them myelin basic protein. A lack of genetically comparable controls has impaired the analysis of the T-cell response in MS patients and caused disagreement on TCR usage in the disease. Here we analyse the role of TCR genes in MS by comparing TCR usage in discordant versus concordant monozygotic twins in response to self and foreign antigens. We find that after stimulation with myelin basic protein or tetanus toxoid, control twin sets as well as concordant twin sets select similar V alpha chains. Only the discordant twin sets select different TCRs after stimulation with antigens. Thus exogenous factors or the disease shape the TCR repertoire in MS patients, as seen by comparison with unaffected genetically identical individuals. This skewing of the TCR repertoire could contribute to the pathogenesis of MS and other T-cell-mediated diseases.

Diversity in fine specificity and T cell receptor usage of the human CD4+ cytotoxic T cell response specific for the immunodominant myelin basic protein peptide 87-106.

Multiple sclerosis (MS), a human demyelinating disease, is thought to be caused by an autoimmunologic process, and myelin basic protein (MBP) is considered a likely autoantigen. Studies of T cell lines (TCL) responding to different parts of the MBP molecule have indicated that amino acids 87 through 106 contain an immunodominant epitope of MBP. We have demonstrated previously that amino acids 89 through 99 represent the core of this 87-106 peptide epitope. Importantly, this epitope is not only encephalitogenic in SJL/J mice and Lewis rats but also has been shown to be recognized by human cytotoxic TCL in the context of four HLA-DR molecules that are associated with MS in different geographic areas. If the immune response to MBP peptide 87-106 was homogeneous with respect to epitope specificity and TCR usage, specific immunotherapies targeting the interaction of peptide, MHC, and TCR might be possible. In this study, the fine specificity of 29 CD4+ cytotoxic, long term, and limiting dilution TCL that had been generated against whole MBP and were derived from four MS patients and two healthy relatives was dissected using truncated and alanine-substituted peptides for the 87-106 peptide. In addition, the TCR alpha and beta chain usage of 15 CD4+ TCL was determined. Using truncated peptides, the presence of several nested immunogenic epitopes within amino acids 87 to 106 was demonstrated. TCL with identical restriction elements and similar responses to truncated peptides could be differentiated further using alanine-substituted peptides. Finally, heterogeneity of TCR usage was shown not only for those lines that differed in their peptide specificity but also for some that showed identical responses and were restricted by the same HLA-DR antigen. In conclusion, the CD4+ cytotoxic T cell response to the immunodominant MBP peptide 87-106 demonstrates a high degree of heterogeneity at the level of fine specificity and TCR usage. These findings indicate that specific immunotherapies aimed at TCR in MS will probably be more complicated than previously anticipated.

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.

HLA-DR2a is the dominant restriction molecule for the cytotoxic T cell response to myelin basic protein in DR2Dw2 individuals.

The HLA-DR2 restriction of the T cell response to myelin basic protein (MBP) was studied using murine L cells transfected with DRalpha and either DR2a or DR2b beta-chain cDNA. DR2a and DR2b represent the two isotypic DRbeta chains expressed in DR2Dw2 haplotypes. Eleven MBP-specific cytolytic T cell lines derived from patients with multiple sclerosis were isolated. Two of these cell lines recognized MBP-pulsed DR2-expressing L cell transfectants and four of them could only recognize the L cells if the adhesion molecule ICAM-1 was expressed in addition to HLA-DR2. Five of the six lines were restricted by HLA-DR2a; one line recognized Ag in conjunction with DR2b, but only if ICAM-1 was coexpressed. The remaining five lines did not lyse MBP-pulsed L cells. The ability of the DR2b molecules on transfected cells to stimulate T cells was confirmed with DR2b-allospecific T cell clones. Although five MBP-specific lines were restricted by DR2a, they recognized different parts of the MBP molecule, as demonstrated by the presentation of shorter peptides. Thus, our results suggest that DR2a is a dominant restriction molecule in MBP-specific responses by DR2+ MS patients. The results also indicate that the reported heterogeneity in MBP epitopes recognized by DR2-restricted T cells, may not be due to the use of different restriction elements but rather to the binding of different MBP peptides to DR2a molecules.

Adult human glial cells can present target antigens to HLA-restricted cytotoxic T-cells.

T-lymphocyte recognition of antigen either on antigen-presenting cells (APC) necessary for the generation of an immune response or on target cells during the effector phase of a cellular immune response requires expression of HLA molecules. Although immune mechanisms operate in many disease processes of the central nervous system (CNS), cells of the CNS generally express low levels of HLA molecules. In this study, the potential for upregulation of HLA molecules on adult human glial cells was examined. Moreover, the functional implication of this upregulation was assessed by the capacity of glial cells to process and present target antigens to HLA class I-restricted influenza-specific and class II-restricted myelin basic protein (MBP)-specific CTL lines. Glial cells cultured from adult human surgical brain specimens or cells from established glioblastoma multiforme cell lines were studied. Lysis by antigen-specific CTLs was dependent on treatment of the target cell with interferon-gamma. The lysis was HLA restricted and antigen specific. The results indicate that adult human glial cells can process and present antigen to HLA-restricted CTLs but require the upregulation of HLA molecules. These findings have implications for infectious and autoimmune diseases of the CNS.

Fine specificity and HLA restriction of myelin basic protein-specific cytotoxic T cell lines from multiple sclerosis patients and healthy individuals.

Myelin basic protein (MBP) is a candidate Ag for the autoimmune process believed to be involved in the pathogenesis of multiple sclerosis (MS). To investigate the fine specificity and HLA restriction of human MBP-specific CTL, long term T cell lines (TCL) were established from 22 MS patients and 16 healthy individuals by repeated antigenic restimulation. By using this approach, MBP-specific cytotoxic TCL were generated from 81% of the lines from MS patients and 69% of those from controls. TCL from both groups expressed the CD3+, CD4+, CD8- phenotype and secreted substantial amounts of IFN-gamma. By using large enzymatic and small synthetic peptides of MBP, TCL were primarily specific for the C-terminal part of the molecule and to a lesser extent for the N-terminal portion. Two regions of the molecule, MBP peptide 87-106 and MBP peptide 154-172, were recognized by the majority of the polyspecific lines and by four and three of 14 monospecific TCL, respectively. These highly immunogenic regions are of interest because they include sequences encephalitogenic in other species. The HLA restriction of each line was determined by using antibody blocking as well as various target cells including EBV-transformed B cells, homozygous typing cells, and fibroblasts transfected with cDNA for DR-alpha and DR-beta genes. All TCL were restricted by HLA-DR Ag. Several HLA-DR molecules restricted multiple cathepsin D-derived and synthetic MBP peptides, including the regions of peptides 87-106 and 154-172 which, respectively, were recognized in conjunction with four and three HLA-DR types. Three of these HLA-DR types are overrepresented in MS patients in different geographic regions. Together, these findings suggest that the MBP-specific cytotoxic T cell response, although not sufficient for disease, may be important for the pathogenesis of MS.

Induction of measles virus-specific human cytotoxic T cells by purified measles virus nucleocapsid and hemagglutinin polypeptides.

The measles virus polypeptide specificity of human measles virus-specific, HLA class II restricted cytotoxic T cells have been examined. Measles virus-specific CTL have been generated using purified measles virus nucleocapsid and hemagglutinin polypeptides during a primary, in vitro stimulation of bulk cultures. Both the purified preparations of measles virus nucleocapsid and hemagglutinin polypeptides were effective in stimulating a measles virus-specific CTL response. The measles virus nucleocapsid-induced CTL response could be blocked by an anti-HLA class II monoclonal antibody but not an anti-HLA class I antiserum. Moreover, considerably less measles virus nucleocapsid was required to stimulate a comparable CTL response than the measles virus hemagglutinin which suggests that the CTL response to measles virus may be skewed towards internal viral determinants of measles virus. These studies indicate that both internal and external components of measles virus are effective in inducing measles virus-specific CTL. The recognition of internal viral components may represent an important part of the T cell mediated immune response to viruses.

Impaired measles virus-specific cytotoxic T cell responses in multiple sclerosis.

To assess whether an virus-specific immune defect may be associated with multiple sclerosis (MS), we have examined the ability to generate measles virus-and influenza virus-specific cytotoxic T cells (CTL) in patients with MS, normal individuals, and other disease controls (ODC). The mean (+/- SEM) measles virus-specific CTL response for normal individuals and ODC was 26.9 +/- 2.9% (N = 17) and 26.7 +/- 2.8% (N = 13) specific lysis, respectively. In contrast, the capacity of MS patients to generate measles virus-specific CTL was markedly diminished. Peripheral blood lymphocytes from MS patients stimulated with measles virus lysed their measles virus-infected autologous B cell line at a group mean level of 6.0 +/- 1.4% (N = 16) specific lysis. MS patients had significantly lower measles virus-specific CTL responses than normal individuals (p less than 0.00001) or ODC (p less than 0.0001). Importantly, this lowered response did not reflect a generalized depressed cytolytic activity of MS patients, since influenza virus-specific CTL and NK activity from these patients were comparable to normals and ODC. Thus, in MS there is a significant depression of measles virus-specific CTL which suggests that this virus-specific immune dysfunction may play a role in the pathogenesis of this disorder.