Multiple sclerosis: glatiramer acetate induces anti-inflammatory T cells in the cerebrospinal fluid

Glatiramer acetate (GA) is believed to induce GA-reactive T cells that secrete anti-inflammatory cytokines at the site of inflammation in multiple sclerosis (MS). However, GA-reactive T cells have not been established from the intrathecal compartment of MS patients, and intrathecal T cells may differ from T cells in blood. Here, we compared the phenotype of GA-reactive T cells from the cerebrospinal fluid (CSF) and blood of five MS patients treated with GA for 3-36 months, and in three of these patients also before treatment. From the CSF of these patients, all 22 T cell lines generated before and all 38 T cell lines generated during treatment were GA-reactive. GA treatment induced a more pronounced anti-inflammatory profile of GA-reactive T cell lines from CSF than from blood. While GA-reactive T cell clones from CSF were restricted by either human leukocyte antigen (HLA) -DR or HLA-DP, only HLA-DR restricted GA-reactive T cell clones were detected in blood. No cross reactivity with myelin proteins was detected in GA-reactive T cell lines or clones from CSF. These results suggest that a selected subset of GA-reactive T cells are present in the intrathecal compartment, and support an anti-inflammatory mechanism of action for GA.     

Expansion of antigen-specific T cells from cerebrospinal fluid of patients with multiple sclerosis

We have expanded cerebrospinal fluid (CSF) T lymphocytes obtained from four patients with multiple sclerosis (MS). Fresh CSF cells were placed into culture with medium, interleukin-2, irradiated autologous peripheral blood mononuclear cells, and either myelin basic protein (BP) or measles virus antigen. Two CSF cell lines demonstrated a mild degree of antigen-specific proliferation to BP, a third reacted with measles virus, and the fourth demonstrated no known antigenic specificity. The percentage of HLA-DR + cells was increased in all four cell lines. The culture procedure has thus selected for a population of activated T cells, some of which demonstrate reactivity with antigens of potential relevance to the pathogenesis of MS.     

Virus-reactive and autoreactive T cells are accumulated in cerebrospinal fluid in multiple sclerosis

Elevated numbers of B cells--plasma cells secreting antibodies to measles and mumps virus, and to myelin associated glycoprotein (MAG), one of several putative myelin autoantigens--have previously been reported in cerebrospinal fluid (CSF) from patients with multiple sclerosis (MS), while it is unknown if corresponding T cell reactivities occur. We have defined the T cell reactivities to measles and mumps virus and to MAG in an immunospot assay which is based on the detection of secretion of interferon-gamma (IFN-gamma) by single cells upon stimulation with specific antigen in short term cultures. Patients with MS had higher numbers of MAG-reactive T cells in blood compared to controls, while no differences were observed for measles or mumps virus-reactive T cells. In CSF, elevated numbers of MAG-reactive T cells and also of measles- and mumps-reactive T cells were found in patients with MS compared to other neurological diseases. A strong accumulation of antigen-reactive T cells was observed in the MS patients' CSF compared to blood. The magnitude of these T cell reactivities did not correlate with clinical MS variables. The T cell repertoire in MS thus includes, besides myelin basic protein, proteolipid protein and myelin oligodendrocyte glycoprotein, also MAG and, in addition, measles and mumps virus. It is not clear whether these T cell reactivities accumulated in the CSF have importance for the pathogenesis of MS or reflect phenomena secondary to myelin damage, or result from both these alternatives.     

Derivation of ganglioside-specific T cell lines of suppressor or helper phenotype from cerebrospinal fluid of multiple sclerosis patients

In order to investigate the specificity of activated T cells in the cerebrospinal fluid (CSF) of patients with multiple sclerosis (MS), we have cultured cells in the presence of mitogen-free IL-2 but without any antigen. Two T cell lines have been derived and showed specific reactivity to certain purified gangliosides (GM1, GD1a, GD1b and GQ1b). However, responses to other brain and viral antigens were not seen, and neither were T cell lines from peripheral blood lymphocytes (PBL) of normal, MS or other neurological disease patients stimulated by these gangliosides. Release of IL-2 could be detected after incubation of these CSF lines with specific gangliosides. One line exhibited predominantly helper/inducer (T4+) phenotype whilst the other was suppressor/cytotoxic (T8+), and further analysis indicated it could be of the suppressor phenotype. These data may have implications for T cell-induced demyelination in MS.     

TCR repertoire and cytokine profiles of cerebrospinal fluid– and peripheral blood–derived T lymphocytes from patients with multiple sclerosis

The cerebrospinal fluid (CSF) represents an important source of T lymphocytes that could be involved in the inflammatory response occurring in the central nervous system in multiple sclerosis (MS). In order to investigate whether the Vβ gene usage of CSF T lymphocytes is restricted, we analyzed the TCR Vβ expression in twelve CSF expanded by in vitro culture compared to the paired in vitro-stimulated peripheral blood T lymphocytes. The overexpression of one or two Vβ genes was demonstrated in ten CSF, but the type of Vβ over expressed varied from one patient to another. For one patient, the Vβ repertoire was also investigated by single cell cloning. High frequency of BV6S7-expressing T cell clones was observed in the CSF while no BV6S7 clone was derived from the peripheral blood T lymphocytes suggesting that these cells could be involved in the immunopathological process in the central nervous system (CNS). The cytokine patterns of the T cell clones derived from the CSF- and peripheral blood-T lymphocytes of this patient were determined. The CSF T cell clones produced higher levels of cytokines than the peripheral blood T cell clones. The high frequency of IL-4-producing-T cell clones observed in CSF demonstrate that T cells which could downregulate the inflammatory process are present in the CNS. J. Neurosci. Res. 51:759–770, 1998. © 1998 Wiley-Liss, Inc.     

Borrelia burgdorferi--specific and autoreactive T-cell lines from cerebrospinal fluid in Lyme radiculomyelitis

In 3 patients with Lyme radiculomyelitis, cellular immune reactions of cerebrospinal fluid (CSF) lymphocytes were analyzed. Phenotypic analysis of CSF cells demonstrated that the majority were T cells (CD3+) of the helper/inducer subset (CD4+). These T cells were directly expanded from the CSF by limiting dilution. A total of 505 T-cell lines were tested for Borrelia burgdorferi (Bb)-specific proliferation and also partly tested for reactivity to a panel of central and peripheral nervous system antigens. Proliferative assays revealed 33 of them to be Bb specific, 16 to be specific for myelin basic protein, 16 to be specific for peripheral myelin, 1 to be specific for cardiolipin, and 2 to be specific for galactocerebrosides. The antigen-specific proliferation was restricted by autologous human leukocyte antigen (HLA) class II molecules. The majority of CSF-derived T-cell lines stained positively for CD3, CD4, and HLA class II antigens and negatively for CD8 (cytotoxic/suppressor subset). One T-cell line provided help for the production of specific IgG by autologous B cells and secreted gamma-interferon upon stimulation with Bb antigen in the presence of autologous antigen-presenting cells. These data show that in patients with severe neurological manifestations of late Lyme disease, not only Bb-specific T-cell lines but also T cells reactive to central or peripheral nervous system autoantigens can be found.     

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.     

The same TCR (N)Dbeta(N)Jbeta junctional region is associated with several different vbeta13 subtypes in a multiple sclerosis patient at the onset of the disease

In multiple sclerosis (MS), the T-cell receptors (TCRS) of autoreactive T lymphocytes recognize various myelin components or derivatives including peptides of the myelin basic protein (MBP). Using the exhaustive immunoscope approach we showed that the T-cell repertoires of MS patients differ from those of healthy controls, with expansion of Vβ13 cell clones in cerebrospinal fluid (CSF) and in peripheral blood lymphocytes (PBLs). Sequencing of the β13⁺ chains of T cells recovered from the CSF revealed high interindividual diversity, and no particular Vβ13⁺ rearrangements were shown to be myelin-autoreactive. Within the overall Vβ13 repertoire in the CSF of patient MS3 at the onset of the disease, most of the overrepresented (N)Dβ(N)Jβ junctional regions were found to be associated with two or three different Vβ13 segments. These rearrangements were most common in the PBLs of patient MS3. No such associations were detected in the Vβ5 multigene family that was used as a control. Thus, Vβ13 T cells infiltrating the CSF from patient MS3 may have been selected on the basis of both the Vβ13 segments and the (N)Dβ(N)Jβ junctional CDR3 sequence.     

CSF cells in multiple sclerosis: monoclonal antibody analysis and relationship to peripheral blood T-cell subsets

Mononuclear cells were analyzed in CSF and blood of 102 patients with MS. In CSF, the majority (78%) of cells were T lymphocytes (T3+), and the ratio of inducer (T4+) to suppressor/cytotoxic (T8+) cells was 2:1. No characteristic alterations in CSF phenotypes could be related to changes in circulating T8 cells or to disease activity. In a group of 75 patients, CSF cell count was higher in patients with low numbers of circulating T8 cells than in those with normal T8 cells. Thus, decreases in suppressor cells in the blood of MS patients are associated with CSF pleocytosis but not with fluctuations in the ratio of different subsets in CSF. Furthermore, large numbers of T8 cells are not sequestered in CSF when these cells are decreased in peripheral blood.     

T cell receptor Vβ 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 Vβ 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 Vβ1, Vβ2, Vβ;5, or Vβ;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 Vβ genes were not always constant, however, since in three sequential evaluations of a chronic progressive MS patient, Vβ genes over-expressed in the first BP-reactive CSF switched to a different Vβ gene bias that was present in the second and third CSF samples. Blood samples reflected each pattern of CSF Vβ 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 Vβ gene bias. © 1994 Wiley-Liss, Inc.     

Frequency of T cells specific for myelin basic protein and myelin proteolipid protein in blood and cerebrospinal fluid in multiple sclerosis

T cell sensitization to two myelin components, myelin basic protein (MBP) and myelin proteolipid protein (PLP), may be important to the pathogenesis of multiple sclerosis (MS). Using the limiting dilution assay, we demonstrated that the blood of MS patients had an increased frequency of MBP-reactive T cells compared with normal subjects and patients with other neurological diseases (OND) and rheumatoid arthritis. There was no difference in T cell frequency to a synthetic peptide, PLP139-151, or Herpes simplex virus. Within cerebrospinal fluid (CSF), 37% of IL-2/IL-4-reactive T cell isolates from MS patients responded either to MBP or PLP139-151 while only 5% of similar isolates from OND patients responded to these myelin antigens. The mean relative frequency of MBP-reactive T cells within CSF from MS patients was significantly higher than that of OND patients (22 x 10(-5) cells versus 1 x 10(-5) cells) and was similar to that of MBP reactive T cells within the central nervous system of rats with experimental autoimmune encephalomyelitis. These results lend new support to the hypothesis that myelin-reactive T cells mediate disease in MS.     

A comparison of regulatory cells in spinal fluid and blood in patients with multiple sclerosis and other neurologic diseases

Multiple sclerosis is a disease in which immune abnormalities are present both in the CNS and peripheral blood. Whether these changes are primary or secondary to the disease process is not known. We tested T-cell clones derived from activated lymphocytes in the blood and CSF of MS patients and controls for their capacity to regulate T-cell responses to alloantigens. A wide spectrum of regulatory functions were observed, ranging from marked enhancement to almost complete suppression. Clones from different patient populations and anatomic sites were equivalent in their regulatory functions with the net effect of clones in each compartment being suppression. However, certain clones from CSF and peripheral blood had the capacity to stimulate autologous T cells. Percentages of such clones in the peripheral blood of MS patients were significantly higher than in controls, while percentages in MS and other neurologic diseases (OND) CSF were equivalent. Our data suggest that (1) functional suppressor cells are not lost from the blood or CSF or MS and OND patients, (2) lymphocytes that have entered the CNS in patients with MS and other CNS diseases have equivalent regulatory functions, (3) MS may be an illness in which peripheral immunologic events are important in perpetuating the disease process, and (4) responses to autologous antigens may also play a role in this perpetuation.     

Immunopathological recognition of autoantigens in multiple sclerosis

Although the aetiology of multiple sclerosis (MS) has not been established, circumstantial evidence points to the involvement of both cell-mediated and humoral immune responses in the formation of demyelinating lesions. In view of the current controversy regarding the reactivity of T lymphocytes from MS patients to myelin basic protein (MBP), we reassessed T cell reactivity in MS using a sensitive and specific indicator of cell-mediated immune response. No significant difference in the reactivity to MBP was observed between MS patients and healthy subjects. Interestingly, significant reactivity to MBP was detected in the control group comprising patients with other diseases. Nevertheless, our demonstration that polymorphism in T cell receptor (TcR) alpha chain are related to MS and that, in demyelinating lesions, TcR usage is limited, suggests that T cells may recognise particular epitopes of a critical antigen involved in this disease. The search for a specific MS antigen recognised by the intrathecally synthesized immunoglobulins typical of MS has so far been unsuccessful. However, recent work, which has focused more particularly onto myelin components with externally located epitopes accessible to the immune response, appears to be more promising. One such antigen, myelin-oligodendrocyte glycoprotein (MOG), is clearly a target for immune attack. Indeed, highly specific antibodies to MOG have been shown to cause demyelination not only in vivo but also in vitro, as demonstrated by our study of the demyelinating effects of a monoclonal anti-MOG antibody on aggregating fetal rat brain cell cultures.(ABSTRACT TRUNCATED AT 250 WORDS)     

Sensitization of cerebrospinal fluid and peripheral blood lymphocytes to myelin basic protein in multiple sclerosis

Cerebrospinal fluid (CSF) and peripheral blood (PB) lymphocyte sensitization to rabbit myelin basic protein (MBP) in 44 multiple sclerosis (MS) patients, 21 patients with other neurological diseases (OND) and 14 persons with neurosis was studied with the antigen-active rosette forming cells (Ag-ARFC) assay. The frequency of sensitization of CSF lymphocytes to MBP in groups of MS patients in the relapse stage and the chronic progressive stage was higher than in the group of MS patients in the stable stage and the OND patients. None of the healthy subjects showed a positive reaction with MBP. In BP there were no differences in the incidence of sensitization to MBP between patients in various stages of the disease, but it was higher than in the group of patients with OND and neuroses. In the patients who had suffered from MS for less than 4 years, sensitization to MBP was more common in CSF lymphocytes than in BP lymphocytes. The results suggest that primary sensitization to MBP occurs in CSF, and is probably secondary to myelin damage. However at present it is difficult to determine the extent to which sensitization of CSF and PB lymphocytes to MBP play a role in further demyelination processes.     

T cells from multiple sclerosis patients recognize immunoglobulin G from cerebrospinal fluid

Idiotopic sequences are created after V, D and J recombinations and by somatic mutations during affinity maturation of immunoglobulin (Ig) molecules, and may therefore be potential immunogenic epitopes. Idiotope-specific T cells are able to activate and sustain the B cells producing such idiotopes. It is therefore possible that idiotope-specific intrathecal T cells could help maintain the persisting intrathecal synthesis of oligoclonal IgG observed in patients with multiple sclerosis (MS). This study was undertaken to examine T-cell responses to cerebrospinal fluid (CSF) IgG. Peripheral blood mononuclear cells (PBMC) from 14 of 21 MS patients and four of 17 control patients with other neurological diseases proliferated upon stimulation with autologous CSF IgG, while five and three, respectively, responded to serum IgG. By comparison, responses to myelin basic protein were recorded in only four MS and three control patients. Data from a limited number of patients indicate that the CSF IgG responsive cells were CD4+ and human leucocyte antigen DR restricted, that PBMC also respond to CSF IgG from other MS patients and that the CSF may contain T cells responding to autologous CSF IgG. This suggests that CSF IgG, or substances bound to this IgG, may represent T-cell immunogens, which could contribute to the intrathecal immune response in MS.     

Aspects of cellular immunity in multiple sclerosis. Antigen-reactivity of lymphocytes and lymphokine activity.

Some new results of cell-mediated immunity in multiple slcerosis (MS) are presented, based on the determination of charge-changing lymphokines as products of antigen sensitive lymphocytes (C PAL), obtained by several forms of the electrophoretic mobility (EM) method. Lymphocytes from MS react to myelin basic protein (BP), the reactivity in other neurological diseases depending on the degree of destruction of nervous parenchyma. Applying a membrane-associated antigen from normal brain (NTA), positive reactivity of MS lymphocytes was obtained. Besides the usual determination of lymphokines in vitro the sensitive EM test allows the demonstration of lymphokine activities in vivo; i.e. in body fluids such as cerebrospinal fluid (CSF) and serum. In CSF of MS a high lymphokine activity was found. The differentiation of lymphokines and comparison between in vitro and in vivo activity were carried out. Moreover, a characteristic lymphokine pattern for MS with high activities in all regions of molecular weight, especially in the CSF, could be detected. On the basis of these findings, important also from the pathogenetic point of view, a diagnostic scheme for MS is suggested, consisting of a program of determination of the immuno-reactive CSF syndrome and some special procedures, including examination of lymphocyte reactivity.     

Autoimmune T cell repertoire in optic neuritis and multiple sclerosis: T cells recognising multiple myelin proteins are accumulated in cerebrospinal fluid.

Monosymptomatic unilateral optic neuritis is a common first manifestation of multiple sclerosis. Abnormal T cell responses to myelin components including myelin basic protein (MBP), proteolipid protein (PLP), and myelin-associated glycoprotein (MAG) have been implicated in the pathogenesis of multiple sclerosis. Antigen-reactive T helper type 1 (Th1)-like cells that responded by interferon gamma (IFN-gamma) secretion on antigen stimulation in vitro were counted. Untreated patients with optic neuritis and multiple sclerosis had similarly raised levels of T cells recognising MBP, PLP, and MAG in peripheral blood. Such T cells were strongly enriched in CSF. None of these myelin antigens functioned as immunodominant T cell antigen characteristic for optic neuritis or multiple sclerosis. The autoimmune T cell repertoire was not more restricted in optic neuritis (as an example of early multiple sclerosis). The autoreactive T cell repertoires differed in blood compared with CSF in individual patients with optic neuritis and multiple sclerosis. No relations were found between specificity or quantity of autoreactive T cells in blood or CSF, and clinical variables of optic neuritis or multiple sclerosis, or occurrence of oligoclonal IgG bands in CSF. The role of raised MBP, PLP, and MAG reactive Th1-like cells found in optic neuritis and multiple sclerosis remains unexplained.     

T-cell subsets in the cerebrospinal fluid and blood of patients with multiple sclerosis

The absolute numbers and ratios of helper/inducer (T4) and cytotoxic/suppressor (T8) T-cells were determined in cerebrospinal fluid (CSF) and blood of patients with multiple sclerosis (MS) and various other neurologic diseases (OND). In patients with MS, the T4:T8 ratio was higher in both blood and CSF, and the increase was significantly greater in CSF than in blood. These findings were due to an increased proportion of T4-lymphocytes in the CSF and to a decreased proportion of T8-cells in blood. These results indicate the need for additional studies of CSF lymphocytes in patients with MS.     

Myelin basic protein peptide specificity and T-cell receptor gene usage of HPRT mutant T-cell clones in patients with multiple sclerosis

Characterization of T cells responding to autoantigens is central to understanding autoimmune disease. We have used somatic mutation at the hypoxanthine guanine phosphoribosyltransferase (HPRT) gene as an index of T-cell amplification in vivo. With this strategy we previously showed that myelin basic protein–reactive T cells can be isolated only from the HPRT mutant T-cell population cultured from the peripheral blood of multiple sclerosis patients and not from normal individuals. In this study, 165 HPRT mutant and 104 wild-type clones were examined for their reactivity to myelin basic protein and overlapping peptides of myelin basic protein. Five HPRT mutant clones that recognized myelin basic protein and myelin basic protein peptides along with three clones that responded to myelin basic protein peptide alone were isolated. All but one of the eight clones recognized peptides derived from the carboxy terminus of myelin basic protein (p84-168). Sequence analysis showed heterogeneous expression of T-cell receptor Vα and Vβ genes and CDR3s. These studies showed that in vivo amplified autoimmune T cells from patients with long-standing disease use diverse T-cell receptor elements in the recognition of C-terminal myelin basic protein peptides.