Rat RT1.B-transfected fibroblast lines process and present myelin antigens and activate T cells to induce experimental autoimmune encephalomyelitis

The genes encoding the Lewis rat RT1.B molecule (MHC Class II I-A equivalent) were transfected and expressed in mouse DAP.3 fibroblast cells together with the gene encoding the mouse ICAM-1 molecule. Both molecules were stably expressed on the cell surface of DAP.3 cells under longterm culture conditions. The RT1.B/mICAM-1 transfectants presented antigen in a specific manner to a RT1. B-restricted rat T cell hybridoma specific for the 69-89 peptide of myelin basic protein (BP). In addition, the transfectants were able to present antigen to a BP69-89-specific rat T cell line. Presentation to a RT1.D (MHC Class II I-E equivalent)-restricted BP87-99-specific T cell line was minimal. Production of the Th1 cytokine IFN-gamma by BP69-89-specific T cells when stimulated by RT1.B/mICAM-1 transfectants correlated very well with proliferation to specific antigen. Moreover, RT1.B-transfected DAP.3 cells sufficiently stimulated BP69-89-specific T cells such that they were able to transfer experimental autoimmune encephalomyelitis (EAE) to Lewis rat recipients. Thus, the RT1.B molecule is functionally expressed on the surface of transfected Dap.3 fibroblasts and is capable of MHC Class II-restricted, antigen-specific presentation to rat T cells.

IL-7 enhances Ag-specific human T cell response by increasing expression of IL-2R alpha and gamma chains

Interleukin-7 has demonstrated potent enhancing effects on the growth and differentiation of several immature cell types, including thymocytes, and on survival of resting and antigen activated T cells. In this study, we evaluated the effects of IL-7 on post-thymic antigen-specific T cells from human blood. IL-7 was found to enhance proliferation responses and IFN-gamma secretion of myelin or recall Ag-specific Th1 cells through the selective up-regulation of the IL-2Ralpha and gamma but not beta chains in both an Ag-dependent and Ag-independent manner, but did not affect monocytes, B cells, or NK cells. These functions of IL-7 enhanced the detection of Th1 but not Th2 cell frequency by >2.5 fold, and promoted selection of Ag-specific Th1 cells by the limiting dilution method. Moreover, IL-7 pretreatment conferred increased resistance of CD4+ T cells to CD8+ cell lysis. These studies demonstrate that IL-7 promotes the growth and survival of circulating Ag-specific human Th1 cells through a mechanism that probably involves the gammac common receptor for IL-2 family members that includes IL-7.

Vaccination with BV8S2 protein amplifies TCR-specific regulation and protection against experimental autoimmune encephalomyelitis in TCR BV8S2 transgenic mice

TCR determinants overexpressed by autopathogenic Th1 cells can naturally induce a second set of TCR-specific regulatory T cells. We addressed the question of whether immune regulation could be induced naturally in a genetically restricted model in which a major portion of TCR-specific regulatory T cells expressed the same target TCR BV8S2 chain as the pathogenic T cells specific for myelin basic protein (MBP). We found vigorous T cell responses to BV8S2 determinants in naive mice that could be further potentiated by vaccination with heterologous BV8S2 proteins, resulting in the selective inhibition of MBP-specific Th1 cells and protection against experimental encephalomyelitis. Moreover, coculture with BV8S2-specific T cells or their supernatants reduced proliferation, IFN-gamma secretion, and encephalitogenic activity of MBP-specific T cells. These results suggest that immune regulation occurs through a nondeletional cytokine-driven suppressive mechanism.

EAE TCR motifs and antigen recognition in myelin basic protein-induced anterior uveitis in Lewis rats

T cells infiltrating the iris/ciliary body of Lewis rats with anterior uveitis (AU) that had been induced by myelin basic protein (MBP) immunization were previously found to share surface markers common to the T cells that cause experimental autoimmune encephalomyelitis (EAE). To determine whether these AU-associated T cells are in fact the same as those that infiltrate the central nervous system to cause EAE, we examined TCR V gene expression in T cells infiltrating the anterior chamber in rats with AU. As with EAE, we found a biased expression of Vbeta8.2 and Valpha2 in the iris/ciliary body and, although one would expect an influx of nonspecific inflammatory T cells, these biases were still evident at the peak of AU. An analysis of the TCR Vbeta8.2 and Valpha2 sequences derived from the iris/ciliary body demonstrated the presence of the same complementarity determining region 3 motifs found in MBP-specific T cells that are pathogenic for EAE and found in T cells derived from the central nervous system of rats with EAE. Finally, T cells isolated from the iris/ciliary body of rats with AU were found to proliferate in a specific fashion to MBP Ags. Thus, it appears that MBP-specific T cells are pathogenic for AU as well as EAE in the Lewis rat. In addition, the long-term presence of this highly restricted MBP response in the iris/ciliary body indicates that distinct immunoregulatory mechanisms exist in the environment of the eye. This provides an interesting model with which to address questions pertaining to the nature of T cells infiltrating the eye and their regulation during EAE and other systemic diseases.

Multiple sclerosis: the frequency of allelic forms of tumor necrosis factor and lymphotoxin-alpha

The cytokines LTa and TNF have been implicated as major mediators of tissue injury in multiple sclerosis (MS). In this study we have assessed the frequency of specific polymorphisms for these genes in MS (n = 53) and controls (n = 81) using a highly sensitive, two stage nested polymerase chain reaction (PCR), with the second stage using mutation-specific primers. Genomic DNA was extracted from blood cells and the results confirmed by direct dideoxy chain termination sequencing. The frequency of the -308 G to A mutation in the TNF promoter region in normal controls was 15% and in MS was 24%. For LTa gene the exon 3 polymorphism allele A was detected in 36% of controls and 34% of the MS patients. In MS, the combined genotype TNF G + A and LTa C + C was present 6 times more frequently (12%) than in controls (2%), and patients with this genotype showed the highest EDSS scores. We found the TNF and LTa polymorphisms to occur independently from the HLA class II DR2 allele distribution in MS. Whilst the G - A polymorphism in TNF gene promoter has been studied previously in MS, with conflicting results, this is the first study that has addressed the exon 3 polymorphism in LTa in MS. The results indicate that this polymorphism is not linked with the higher genetic predisposition for MS, but that combined TNF G + A and LTa C + C genotype might contribute to development of the disease.

A TCR V alpha CDR3-specific motif associated with Lewis rat autoimmune encephalomyelitis and basic protein-specific T cell clones

To investigate TCR V alpha gene expression in the Lewis rat model of experimental autoimmune encephalomyelitis, we obtained V alpha chain sequences from two V beta8.2+-encephalitogenic, BP72-89-specific T cell clones. Two different V alpha genes, a V alpha2 gene and a V alpha23 gene, are utilized, but both were found to contain an asparagine repeat (Asn3+) sequence present in the V alpha CDR3 region. This Asn3+ motif is also present in the previously reported sequence of a BP68-88-specific hybridoma, 510, which utilizes a different V alpha2 gene family member. In further experiments, spinal cord T cells were isolated at the onset of basic protein (BP)-induced disease and sorted for the OX-40 activation marker, which we have previously used to enrich for specifically activated T cells. Analysis of V alpha expression in the OX-40+ population revealed the biased use of three V alpha genes, V alpha1, V alpha2, and V alpha23. The Asn3+ motif was present in the V alpha CDR3 region of V alpha1, V alpha2, and V alpha23 cDNA derived from OX-40+ spinal cord T cells but found to be generally absent in the OX-40- spinal cord population. Since these Asn3+ motif-bearing V alpha chain sequences are nearly identical to those utilized by the BP-specific encephalitogenic clones described, it is likely that these V alpha sequences are derived from disease-associated T cells in the spinal cord. Thus, we demonstrate that the Asn3+ V alpha CDR3 motif is strongly associated with experimental autoimmune encephalomyelitis in the Lewis rat and propose that it plays a role in TCR recognition of a specific BP peptide/MHC complex.

A TCR V alpha CDR3-specific motif associated with Lewis rat autoimmune encephalomyelitis and basic protein-specific T cell clones

To investigate TCR V alpha gene expression in the Lewis rat model of experimental autoimmune encephalomyelitis, we obtained V alpha chain sequences from two V beta8.2+-encephalitogenic, BP72-89-specific T cell clones. Two different V alpha genes, a V alpha2 gene and a V alpha23 gene, are utilized, but both were found to contain an asparagine repeat (Asn3+) sequence present in the V alpha CDR3 region. This Asn3+ motif is also present in the previously reported sequence of a BP68-88-specific hybridoma, 510, which utilizes a different V alpha2 gene family member. In further experiments, spinal cord T cells were isolated at the onset of basic protein (BP)-induced disease and sorted for the OX-40 activation marker, which we have previously used to enrich for specifically activated T cells. Analysis of V alpha expression in the OX-40+ population revealed the biased use of three V alpha genes, V alpha1, V alpha2, and V alpha23. The Asn3+ motif was present in the V alpha CDR3 region of V alpha1, V alpha2, and V alpha23 cDNA derived from OX-40+ spinal cord T cells but found to be generally absent in the OX-40- spinal cord population. Since these Asn3+ motif-bearing V alpha chain sequences are nearly identical to those utilized by the BP-specific encephalitogenic clones described, it is likely that these V alpha sequences are derived from disease-associated T cells in the spinal cord. Thus, we demonstrate that the Asn3+ V alpha CDR3 motif is strongly associated with experimental autoimmune encephalomyelitis in the Lewis rat and propose that it plays a role in TCR recognition of a specific BP peptide/MHC complex.

Myelin basic protein-specific and TCR V beta 8.2-specific T-cell lines from TCR V beta 8.2 transgenic mice utilize the same V alpha and V beta genes: specificity associated with the V alpha CDR3-J alpha region

Our analysis of TCR V gene usage in mice transgenic for the V beta 8.2 gene has demonstrated that T cells isolated from the spinal cord of these transgenic mice during active experimental autoimmune encephalomyelitis were significantly biased for V alpha 2 expression. This V alpha 2 bias was noted in T cells derived from the periphery as well but only after stimulation with specific antigen. Thus, spinal cord-derived pathogenic T cells had already undergone activation and expansion within the central nervous system environment of these mice. As part of an investigation of regulatory function in these V beta 8.2 transgenic mice, two T cell lines were selected. The first T cell line is encephalitogenic and specific for the dominant myelin basic protein peptide NAc1-11, while the second T cell line is specific for the V beta 8.2 protein. Surprisingly, polymerase chain reaction and sequence analysis of the TCR from both the T cell lines demonstrated that they utilize identical V beta, D beta, J beta, and V alpha gene segments. The only difference found was in their use of the J alpha gene segment, indicating that this region of the TCR molecule can play a key role in determining antigen specificity.

V beta CDR3 motifs associated with BP recognition are enriched in OX-40+ spinal cord T cells of Lewis rats with EAE

Spinal cord (SC) T cells were isolated at the onset of actively induced experimental autoimmune encephalomyelitis (EAE) and sorted for the presence of the OX-40 activation marker. Previously, we reported an enhanced bias in V beta 8.2 expression as well as enhanced proliferative responses to basic protein antigens among the OX-40+ SC T cells. Here we demonstrate that CDR3 motifs associated with EAE are present at a significantly higher frequency in V beta 8.2 sequences of OX-40+ SC T cells (16/17) compared with those of OX-40- SC T cells (5/17). Thus, the OX-40 antigen may be useful as a marker to isolate and characterize autoantigen-specific T cells from the site of inflammation in T-cell-mediated autoimmune diseases.

OX-40 antibody enhances for autoantigen specific V beta 8.2+ T cells within the spinal cord of Lewis rats with autoimmune encephalomyelitis

The V beta 8.2 T cell receptor (TCR) component is the predominant V beta gene product associated with antigen specific CD4+ T cell response to the major encephalitogenic epitope of myelin basic protein (MBP) in Lewis rats. Lewis rats were actively immunized with MBP in complete Freund's adjuvant and the V beta 8.2 positive and negative cells were analyzed for IFN-gamma mRNA production and OX-40 cell surface expression during the onset of EAE. The V beta 8.2+ T cells isolated from the spinal cord produced the majority of mRNA for IFN-gamma and also showed a marked enhancement for OX-40 expression compared to V beta 8.2+ T cells isolated from the lymph nodes. Only a fraction of IL-2 receptor positive T cells examined ex vivo from the inflammatory compartments co-expressed the OX-40 antigen. These results suggested that OX-40 cell surface expression could be used to identify and isolate the most recently activated T cells ex vivo. OX-40+ T cells isolated from the spinal cord were highly enriched for the V beta 8.2 T cell receptor component compared to OX-40- or unsorted spinal cord lymphocytes. OX-40+ T cells isolated from the spinal cord had an enhanced response to MBP, whereas OX-40+ cells isolated from the lymph nodes responded to both MBP and purified protein derivative. These data suggest that activated T cells can be isolated and characterized with the OX-40 antibody which only respond to the antigens present at the local site. The data also imply that isolation of OX-40+ T cells will be useful in identifying V beta biases and autoantigen specific cells within inflamed tissues even when the antigen specificity is unknown.

Analysis of V beta 8.2 CDR3 sequences from spinal cord T cells of Lewis rats vaccinated or treated with TCR V beta 8.2-39-59 peptide

Experimental autoimmune encephalomyelitis (EAE) in the Lewis rat can be induced with the administration of Gp-BP. This disease appears to be mediated at least in part by V beta 8.2+CD4+T cells, which specifically recognize the BP72-89 encephalitogenic peptide. Treatment or protection with V beta 8.2 CDR2 39-59 peptide can suppress or prevent clinical signs of EAE, presumably through the activation of regulatory T cells. Interestingly, V beta 8.2+ T cells continue to persist in the spinal cord of protected animals, although their appearance in the central nervous system (CNS) is delayed when compared with control animals with EAE. As part of our effort to elucidate the mechanism(s) of peptide protection and therapy, we sought to determine whether the V beta 8.2+ T cells in the spinal cord of protected or treated rats were truly representative of those found in rats with clinical EAE. Therefore, we examined the following CNS samples for the Asp96Ser97 motif, which has been identified previously in V beta 8.2+ BP-specific, encephalitogenic T cell clones: 1) rats protected with V beta 8.2-39-59 peptide, 2) rats treated with V beta 8.2-39-59 peptide, and 3) control rats with EAE. Our findings indicate that EAE-associated V beta 8.2+ sequences can still be found in both peptide-treated and peptide-protected rats. It appears that administration of V beta 8.2 CDR2 peptide does not prevent EAE-associated V beta 8.2+ T cells from infiltrating the CNS and that other mechanisms are at work to prevent the development of EAE.

Analysis of V beta 8.2 CDR3 sequences from spinal cord T cells of Lewis rats vaccinated or treated with TCR V beta 8.2-39-59 peptide

Experimental autoimmune encephalomyelitis (EAE) in the Lewis rat can be induced with the administration of Gp-BP. This disease appears to be mediated at least in part by V beta 8.2+CD4+T cells, which specifically recognize the BP72-89 encephalitogenic peptide. Treatment or protection with V beta 8.2 CDR2 39-59 peptide can suppress or prevent clinical signs of EAE, presumably through the activation of regulatory T cells. Interestingly, V beta 8.2+ T cells continue to persist in the spinal cord of protected animals, although their appearance in the central nervous system (CNS) is delayed when compared with control animals with EAE. As part of our effort to elucidate the mechanism(s) of peptide protection and therapy, we sought to determine whether the V beta 8.2+ T cells in the spinal cord of protected or treated rats were truly representative of those found in rats with clinical EAE. Therefore, we examined the following CNS samples for the Asp96Ser97 motif, which has been identified previously in V beta 8.2+ BP-specific, encephalitogenic T cell clones: 1) rats protected with V beta 8.2-39-59 peptide, 2) rats treated with V beta 8.2-39-59 peptide, and 3) control rats with EAE. Our findings indicate that EAE-associated V beta 8.2+ sequences can still be found in both peptide-treated and peptide-protected rats. It appears that administration of V beta 8.2 CDR2 peptide does not prevent EAE-associated V beta 8.2+ T cells from infiltrating the CNS and that other mechanisms are at work to prevent the development of EAE.

Analysis of V beta 8-CDR3 sequences derived from central nervous system of Lewis rats with experimental autoimmune encephalomyelitis

We have recently demonstrated that a strong bias for expression of V beta 8.2 is manifested early during the onset of experimental autoimmune encephalomyelitis (EAE) induced by guinea pig basic protein (Gp-BP) immunization of Lewis rats. More importantly, the V beta 8.2 bias was observed in T cells infiltrating the spinal cord (SC) and in cerebrospinal fluid (CSF), but was not present in T cells isolated from the periphery. Here, we report the V beta 8-CDR3 sequences found in unselected SC, CSF, and lymph node (LN) T cell populations at onset of Gp-BP-induced EAE. Striking similarities were observed among sequences derived from SC and CSF. Evidence for oligoclonal expansion of V beta 8.2 sequences associated with previously characterized encephalitogenic clones was observed in both SC and CSF, but not in LN. An AspSer CDR3 motif identified in encephalitogenic clones recognizing the dominant 72-89 epitope of Gp-BP was found in 9/22 SC cDNA clones, 11/24 CSF cDNA clones, and 1/16 LN cDNA clones. Interestingly, J beta 2.7 and J beta 1.3 were also highly represented in SC and CSF, but not in LN. Given that these sequences were derived from T cells present at the site of autoimmune attack and not selected by in vitro manipulation, the data offer compelling evidence that 1) selective recruitment and/or expansion of V beta 8.2+ T cells are occurring in the central nervous system; 2) these events are at least partially dependent on V beta residues which are likely to influence Ag binding; and 3) CSF-derived T cells provide a representative view of CNS events at the onset of EAE.

Analysis of V beta 8-CDR3 sequences derived from central nervous system of Lewis rats with experimental autoimmune encephalomyelitis

We have recently demonstrated that a strong bias for expression of V beta 8.2 is manifested early during the onset of experimental autoimmune encephalomyelitis (EAE) induced by guinea pig basic protein (Gp-BP) immunization of Lewis rats. More importantly, the V beta 8.2 bias was observed in T cells infiltrating the spinal cord (SC) and in cerebrospinal fluid (CSF), but was not present in T cells isolated from the periphery. Here, we report the V beta 8-CDR3 sequences found in unselected SC, CSF, and lymph node (LN) T cell populations at onset of Gp-BP-induced EAE. Striking similarities were observed among sequences derived from SC and CSF. Evidence for oligoclonal expansion of V beta 8.2 sequences associated with previously characterized encephalitogenic clones was observed in both SC and CSF, but not in LN. An AspSer CDR3 motif identified in encephalitogenic clones recognizing the dominant 72-89 epitope of Gp-BP was found in 9/22 SC cDNA clones, 11/24 CSF cDNA clones, and 1/16 LN cDNA clones. Interestingly, J beta 2.7 and J beta 1.3 were also highly represented in SC and CSF, but not in LN. Given that these sequences were derived from T cells present at the site of autoimmune attack and not selected by in vitro manipulation, the data offer compelling evidence that 1) selective recruitment and/or expansion of V beta 8.2+ T cells are occurring in the central nervous system; 2) these events are at least partially dependent on V beta residues which are likely to influence Ag binding; and 3) CSF-derived T cells provide a representative view of CNS events at the onset of EAE.

T cell receptor V beta gene usage in the recognition of myelin basic protein by cerebrospinal fluid- and blood-derived T cells from patients with multiple sclerosis

Because of its proximity to the central nervous system, the cerebrospinal fluid (CSF) represents an important source of T cells that potentially could mediate putative autoimmune diseases such as multiple sclerosis (MS). To overcome the low CSF cellularity, we evaluated culture conditions that could expand CSF T cells, with a focus on the expression of T-cell receptor V beta genes utilized by T cells specific for the potentially encephalitogenic autoantigen myelin basic protein (BP). Expansion of "activated" CSF cells with IL-2/IL-4 plus accessory cells optimally retained BP-responsive T cells that over-expressed V beta 1, V beta 2, V beta 5, or V beta 18, compared to expansion using supernatants from PHA-stimulated blood cells, or anti-CD3 antibody that led to different V gene bias and rare reactivity to BP. Sequential evaluation of paired CSF and blood samples from a relapsing remitting MS patient indicated that BP-reactive T cells were present in CSF during the period of clinical activity, and the pattern of BP recognition in CSF was partially reflected in blood, even after CSF reactivity had dissipated during remission. Over-expressed V beta genes were not always constant, however, since in three sequential evaluations of a chronic progressive MS patient, V beta genes over-expressed in the first BP-reactive CSF switched to a different V beta gene bias that was present in the second and third CSF samples. Blood samples reflected each pattern of CSF V beta gene bias, but retained the initial bias for at least 4 months after its disappearance from CSF. These data indicate that selective expansion of IL-2/IL-4-responsive CSF cells favors growth of the BP-reactive subpopulation, and, in a limited number of patients studied, reflected clinical disease activity. In comparison, blood T cells provided a partial but longer lasting reflection of the CSF BP reactivity and V beta gene bias.

The effect of TCR V beta 8 peptide protection and therapy on T cell populations isolated from the spinal cords of Lewis rats with experimental autoimmune encephalomyelitis

Vaccination or treatment of Lewis rats with TCR V beta 8 peptides can prevent or reverse the clinical signs of experimental autoimmune encephalomyelitis (EAE) which is mediated predominantly by V beta 8.2+ CD4+/CD45R lo T cells. However, rats protected or treated with V beta 8 peptides still developed histological lesions in the spinal cord (SC), even though they remained clinically well. We sought to discern phenotypic changes characteristic of these SC infiltrating lymphocytes. In particular, we focused on whether the immunoregulatory mechanism induced by TCR peptides caused a reduction of V beta 8.2+ T cells, or induced changes in CD45R lo or hi/CD4+ subpopulations that have been associated respectively with EAE induction or recovery. In the V beta 8 peptide vaccinated rats there was a dramatic decrease in the number of V beta 8.2+ T cells isolated from the SC early in disease. During the recovery phase, however, the number of V beta 8.2+ SC T cells was similar in protected and control groups; in contrast, there was striking reduction in the number and size of CD45R hi/CD4+ T cells in the protected animals. In rats treated with V beta 8.2 peptide, no changes were observed in the number of SC V beta 8.2+ T cells or expression of V beta 8.2 message, but similar to vaccinated rats, there was a marked decrease in the number of CD45R hi/CD4+ T cells. These data suggest that vaccination with TCR peptides prevented the initial influx of encephalitogenic V beta 8.2+ T cells into the central nervous system (CNS), whereas treatment appeared to inactivate V beta 8.2+ T cells already present in the CNS. In both cases, TCR peptide-induced inhibition of the encephalitogenic T cells apparently preempted the need for CD45R hi/CD4+ T cells that may normally be necessary to resolve the disease.

Where, when, and how to detect biased expression of disease-relevant V beta genes in rats with experimental autoimmune encephalomyelitis

The biased use of V beta 8.2 and V beta 6 in rats by encephalitogenic T cells specific for the S72-89 and S87-99 epitopes of guinea pig basic protein (Gp-BP) has allowed the use of anti-V beta antibodies and synthetic TCR peptides for treatment of experimental autoimmune encephalomyelitis (EAE). Striking V gene biases also occur in human autoimmune diseases, raising the question of to what degree these biases reflect potentially pathogenic T cells. To address this question, we evaluated the expression of the EAE-associated marker V beta 8.2 and V beta 6 molecules in the periphery, spinal cord (SC), and cerebrospinal fluid (CSF) during the course of EAE, in unselected, IL-2-expanded, and Gp-BP-restimulated populations. In CSF cells, there was a strong bias for the marker V beta before the onset of EAE, but this bias was not enhanced by IL-2, which skewed the CSF population to > 80% CD8+ T cells. In SC, the marker V beta were expressed optimally during the onset of EAE, even in unselected cells, and this bias could be enhanced sequentially by IL-2 expansion and Gp-BP restimulation. During the recovery phase, however, the marker V beta 8.2 bias was obfuscated by the appearance of a heterogeneous V beta T cell population. Biased expression of the marker V genes was not detected in unselected or IL-2-expanded peripheral cells at any time during EAE. These data suggest that peripheral T cells bearing the disease-relevant V genes first appeared in CSF before disease onset and then migrated to SC beginning on the first day of clinical signs. During the recovery phase of the disease, these cells were diluted by an influx of T cells bearing other V beta genes, requiring restimulation with Gp-BP to observe the V beta 8.2 bias. These data have important implications for the interpretation of V beta gene biases that have been reported in human autoimmune diseases.

Where, when, and how to detect biased expression of disease-relevant V beta genes in rats with experimental autoimmune encephalomyelitis

The biased use of V beta 8.2 and V beta 6 in rats by encephalitogenic T cells specific for the S72-89 and S87-99 epitopes of guinea pig basic protein (Gp-BP) has allowed the use of anti-V beta antibodies and synthetic TCR peptides for treatment of experimental autoimmune encephalomyelitis (EAE). Striking V gene biases also occur in human autoimmune diseases, raising the question of to what degree these biases reflect potentially pathogenic T cells. To address this question, we evaluated the expression of the EAE-associated marker V beta 8.2 and V beta 6 molecules in the periphery, spinal cord (SC), and cerebrospinal fluid (CSF) during the course of EAE, in unselected, IL-2-expanded, and Gp-BP-restimulated populations. In CSF cells, there was a strong bias for the marker V beta before the onset of EAE, but this bias was not enhanced by IL-2, which skewed the CSF population to > 80% CD8+ T cells. In SC, the marker V beta were expressed optimally during the onset of EAE, even in unselected cells, and this bias could be enhanced sequentially by IL-2 expansion and Gp-BP restimulation. During the recovery phase, however, the marker V beta 8.2 bias was obfuscated by the appearance of a heterogeneous V beta T cell population. Biased expression of the marker V genes was not detected in unselected or IL-2-expanded peripheral cells at any time during EAE. These data suggest that peripheral T cells bearing the disease-relevant V genes first appeared in CSF before disease onset and then migrated to SC beginning on the first day of clinical signs. During the recovery phase of the disease, these cells were diluted by an influx of T cells bearing other V beta genes, requiring restimulation with Gp-BP to observe the V beta 8.2 bias. These data have important implications for the interpretation of V beta gene biases that have been reported in human autoimmune diseases.

Treatment of relapsing experimental autoimmune encephalomyelitis with T cell receptor peptides

Restricted T cell receptor (TCR) VB gene usage by T cells for recognition of antigens involved in the production of experimental autoimmune encephalomyelitis (EAE) offers the possibility of selective immunotherapy. We determined the preferential VB gene usage of lymph node-derived clones from SJL/J mice to recognize the encephalitogenic epitope PLP 139-151 and from PL/J mice to recognize the newly described encephalitogenic epitope PLP 43-64. In addition, the VB gene usage for recognition of PLP 139-151 by T cell lines derived from SJL/J spinal cords was analyzed. Lymph node-derived SJL/J lines and clones specific for PLP 139-151 expressed VB2, VB4, and VB17a preferentially, and PL/J lines and clones specific for PLP 43-64 expressed VB2 and VB8.2 preferentially. A VB4 + SJL/J clone and a VB8.2 + PL/J clone were encephalitogenic. Encephalitogenic SJL/J lines derived from spinal cord expressed VB2, VB10, VB16, and VB17a preferentially, with a predominance of VB2. Candidate TCR peptides were synthesized and tested from the VB gene families VB4, VB8.2, and VB17a, based on our data and previous data on BP-induced EAE in mice. Treatment of relapsing EAE (R-EAE) in SJL/J mice with VB4 and VB17a peptides reduced clinical and histological disease severity, and treatment of R-EAE in (PLxSJL)F1 mice with VB4 and VB8.2 peptides also reduced clinical and histological disease. The use of TCR peptide therapy may have applications for the treatment of human autoimmune diseases such as multiple sclerosis.

Maturation of the antibody response to a protein-coupled form of the organophosphorus toxin soman

We have analysed the serum antibody response of BALB/c mice to the organophosphorus toxin soman coupled to the protein carrier keyhole limpet haemocyanin (So-KLH) and compared the specificity of the serum antibodies to that of hybridomas described previously. The relative inhibitory capacities of various soman analogues for serum antibodies correlated with those for the monoclonal antibodies. Our results also demonstrate that immune memory to this organophosphorus hapten is stable for greater than 1 year. Interestingly, maturation of the serum antibody response is accompanied by fine specificity changes resulting in increased binding to soman-protein conjugates but not in significant changes in binding to free hapten analogues of soman. This finding suggests that contributions made by the protein carrier or bridge structure, including those made by amino acid side chains involved in the linkage, may play a significant role in the maturation process of antibodies recognizing protein-coupled organophosphorus haptens such as So-KLH. Structurally related but charge-dissimilar organophosphate haptens such as nitrophenylphosphocholine were poorly recognized, even when conjugated to protein with the same diazophenyl linkage used to conjugate soman. This is consistent with maintenance of high specificity in the memory immune response to soman-coupled protein.

Molecular analysis and fine specificity of antibodies against an organophosphorus hapten

We have identified four fine specificity groups reactive with the organophosphorus hapten Soman among 46 hybridomas generated in specific response to immunization with Soman-keyhole limpet hemocyanin (KLH). The different fine specificity groups do not appear to correlate with the use of particular V genes. Molecular analysis of VH genes demonstrates predominant use of VH J558 family members in hybridomas of all fine specificity groups although several different VH genes within this family as well as others are able to contribute. Diversity of VH gene usage was also apparent in primary IgM-producing hybridomas. In contrast, there appears to be restricted L chain usage; a large number (18/46) used the V kappa 1 family. Interestingly, the V kappa 1 family also plays an important role in the memory response to phosphocholine (PC)-KLH, a related organophosphate hapten which shares several structural features with Soman, particularly when coupled to protein carriers. The V kappa 1 C gene appears to predominate in the PC-KLH response. Restriction analysis of DNA from the V kappa 1-positive Soman-KLH-specific hybridomas suggests that a single V kappa 1 gene may be utilized by 17/18 but that this gene is different from V kappa 1 C and may be V kappa 1 A. We propose that members of the V kappa 1 family contribute favorably in generating combining sites that recognize all or part of the structural features shared by the two haptenic structures Soman and PC when they are coupled to protein. This most likely involves recognition of the phenyl linker moiety as the dominant feature. It appears that the L chain rather than the H chain may play a more significant role in forming the phenyl-Soman-specific combining site and perhaps the combining sites for phenyl or ring structures in general.

Molecular analysis and fine specificity of antibodies against an organophosphorus hapten

We have identified four fine specificity groups reactive with the organophosphorus hapten Soman among 46 hybridomas generated in specific response to immunization with Soman-keyhole limpet hemocyanin (KLH). The different fine specificity groups do not appear to correlate with the use of particular V genes. Molecular analysis of VH genes demonstrates predominant use of VH J558 family members in hybridomas of all fine specificity groups although several different VH genes within this family as well as others are able to contribute. Diversity of VH gene usage was also apparent in primary IgM-producing hybridomas. In contrast, there appears to be restricted L chain usage; a large number (18/46) used the V kappa 1 family. Interestingly, the V kappa 1 family also plays an important role in the memory response to phosphocholine (PC)-KLH, a related organophosphate hapten which shares several structural features with Soman, particularly when coupled to protein carriers. The V kappa 1 C gene appears to predominate in the PC-KLH response. Restriction analysis of DNA from the V kappa 1-positive Soman-KLH-specific hybridomas suggests that a single V kappa 1 gene may be utilized by 17/18 but that this gene is different from V kappa 1 C and may be V kappa 1 A. We propose that members of the V kappa 1 family contribute favorably in generating combining sites that recognize all or part of the structural features shared by the two haptenic structures Soman and PC when they are coupled to protein. This most likely involves recognition of the phenyl linker moiety as the dominant feature. It appears that the L chain rather than the H chain may play a more significant role in forming the phenyl-Soman-specific combining site and perhaps the combining sites for phenyl or ring structures in general.

Combining site specificity of monoclonal antibodies to the organophosphate hapten soman

The combining site specificities of eight monoclonal antibodies raised against the organophosphorous-containing hapten Soman are compared to monoclonal antibodies specific for a naturally occurring organophosphorous compound, phosphocholine (PC). Although these haptens share some structural and spatial features, differences in their chemical structures, most notably the presence or absence of a positive charge, appear to prevent significant cross-reactivity between antibodies specific for each. The murine memory response to PC-KLH has been shown previously to be characterized by the presence of two major groups of antibodies differentiated on the basis of their specificity for free PC and for the nitrophenyl derivative of PC, nitrophenylphosphocholine (NPPC). Interestingly, two groups of hybridoma antibodies were detected in the immune response to Soma-KLH which possess differential specificity for Soman and for a nitrophenyl derivative of Soman.