Experimental autoimmune encephalomyelitis mediated by T lymphocyte lines: genotype of antigen-presenting cells influences immunodominant epitope of basic protein

Lewis rats are susceptible to experimental autoimmune encephalomyelitis (EAE), and their T lymphocytes recognize epitopes in the 68-88 sequence of guinea pig myelin basic protein (BP). BN rats are resistant to EAE, and their T lymphocytes recognize epitopes outside of the 68-88 sequence, probably in the 43-67 portion of BP. To investigate the influence of the genome of antigen-presenting cells (APC) on the dominance of BP epitopes for T lymphocyte lines, we selected anti-BP lines from (Lewis X BN)F1 rats by using the APC of Lewis, BN, or F1 origin. We now report that the F1/Lewis and F1/F1 lines recognized the 68-88 epitopes and were highly encephalitogenic in F1 rats, whereas the F1/BN line recognized the 43-67 epitopes and was only weakly encephalitogenic. Thus, the genotype of the APC can influence the immunologic dominance for T lymphocytes of BP epitopes, and this dominance in turn can influence the expression of disease.     

Specificity of T lymphocyte lines for peptides of myelin basic protein

T lymphocyte lines specific for myelin basic protein (BP) can mediate experimental autoimmune encephalomyelitis (EAE), or can protect against the active induction of the disease. To investigate the antigenic fine specificity of guinea pig (GP) BP-specific T cell lines raised from different rat strains, and to determine whether functionally different T lymphocyte lines and clones recognized the same or different regions of the BP molecule, the proliferation responses of line cells were assessed after stimulation with purified peptides of GP-BP. Lewis rat T cell lines and clones selected for responses to whole GP-BP responded selectively to the 68-88 amino acid sequence of GP-BP, but not to the 1-37, 43-67, or 89-169 sequences. The region of GP-BP recognized by Lewis T cells was additionally defined to include the 75-80 amino acid sequence, because a T cell clone responded equally to GP and rat BP which differed by only one amino acid at position 79, but did not respond to human or bovine BP, which had a Gly-His insertion in this region. T lymphocyte lines derived from the F344 and PVG (Weizmann) rat strains shared the same selective response to peptide 68-88, but lines from BN rats responded to an epitope(s) outside of the 68-88 sequence. The functional capacity of the various T cell lines to mediate experimental autoimmune encephalomyelitis (EAE) or to induce resistance against EAE was independent of their specificity for the different GP-BP peptides; lines specific for epitope(s) within or excluded from the 68-88 sequence could be encephalitogenic depending on their strain of origin, and various lines specific for the 68-88 peptide could induce both disease and protection, disease only, or neither activity.     

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

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

Characterization of T cell lines and clones from SJL/J and (BALB/c x SJL/J)F1 mice specific for myelin basic protein

Lines of thymus-derived lymphocytes reactive against bovine myelin basic protein (BP) were established in vitro from SJL/J mice. These lines are stable in long-term culture and mediate inflammatory central nervous system (CNS) lesions and a low incidence of clinical experimental allergic encephalomyelitis (EAE) when injected into recipient SJL/J mice. The line cells proliferate in response to BP of bovine, rat, or mouse origin. Clones were derived from these lines, and the characteristics of these clones were analyzed. The clones express Thy-1, Ly-1, and L3T4 antigens and are negative for Ly-T2. The clones all proliferate in response to bovine BP, with different clones showing varying degrees of cross-reactivity between bovine, rat, and mouse BP. The proliferative response is MHC-restricted; antigen-presenting cells from I-As strains are required. Compatible with their phenotype as helper cells, some of the clones will provide help to primed B cells stimulating antibody production in an in vitro assay. When injected into recipients pretreated with pertussis and irradiation, clones that showed proliferation to mouse BP induced the development of inflammatory lesions in the CNS, with mortality of 28% of the recipients. T cell lines were also established in (BALB/c x SJL/J)F1 mice. In contrast to the homozygous SJL/J lines, these lines were highly encephalitogenic, inducing a high incidence of clinical and histologic EAE when injected in vivo.     

Identification and characterization of epitopes recognized by T lymphocytes and autoantibodies from patients with herpes gestationis

Autoantibodies associated with herpes gestationis (HG), a pregnancy-associated autoimmune skin disease, target the hemidesmosomal protein BP180. It was shown that the major noncollagenous stretch of the BP180 ectodomain (NC16A) harbors epitopes recognized by HG sera. Furthermore, Abs reactive with the homologous domain of murine BP180 are known to trigger a cutaneous blistering disease in mice by passive transfer experiments. The present study was aimed at characterizing the T cell responses and specificities of autoantibodies from two HG patients. Using immunoblotting and T cell proliferation assays, we have identified a 14-amino-acid stretch of the BP180 ectodomain (MCW-1; aa 507-520) that is recognized by both T cells and autoantibodies produced by the HG patients. The neonate born to one of these HG patients showed no signs of skin disease and had no detectable T cell response to the BP180 Ag, but did have a low titer of circulating anti-BP180 autoantibodies, presumably of maternal origin. BP180-specific T cell lines and clones developed from an HG patient specifically reacted with the MCW-1 epitope. The proliferative responses of these clones were restricted to HLA-DR, but not -DQ or -DP. These Ag-specific T cells expressed alpha/beta TCRs and a CD4 memory T cell phenotype and secreted IFN-gamma and IL-2, but not IL-4 or IL-6, suggesting that they are Th1-type lymphocytes. Further characterization of these Ag-specific T cells and autoantibodies will aid in elucidating the autoimmune mechanism(s) leading to the development of HG.     

Regulation of experimental allergic encephalomyelitis. II. Appearance of suppressor cells during the remission phase of the disease

Lewis rats are susceptible to experimental autoimmune encephalomyelitis (EAE). Most rats recover from paralysis and are subsequently resistant to the disease. In an adoptive transfer system, we found that lymph node cells (LNC) from rats that had recovered from EAE protect syngeneic recipients from the disease when the latter are challenged with encephalitogenic myelin basic protein and adjuvant after receiving donor cells. Suppression is antigen-specific and requires viable LNC. In contrast to the suppressor cells we previously studied in tolerized rats, which were nonadherent T lymphocytes, the suppressor cells found in rats that have recovered from EAE adhere to glass wool. However, they are not retained on Sephadex G-10 columns to which macrophages adhere. Suppressor activity is enriched in the nylon wool-adherent LNC population (which consists of approximately 80% Ig+ cells). Our findings suggest that activation of adherent suppressor cells may be implicated in recovery from EAE. These may be adherent T cells, or B cells that produce anti-BP blocking antibodies.     

Comparison of antigen specificity, class II major histocompatibility complex restriction, and in vivo behavior of myelin basic protein-specific T cell lines and clones derived from (BALB/c x SJL/J) mice

Immunization with myelin basic protein (BP) causes experimental allergic encephalomyelitis (EAE) in certain strains of mice. SJL/J (H-2s) is the prototype sensitive strain. Although BALB/c (H-2d) is resistant to EAE through use of an identical immunization protocol, (BALB/c x SJL/J)F1 hybrid mice develop EAE after immunization with BP. T cell clones specific for BP have been isolated from a highly encephalitogenic line of (BALB/c x SJL/J)F1 hybrid T cells raised against bovine BP. The clones were examined for their H-2 restriction and specificity for heterologous forms of BP (mouse, rat, and bovine BP). The results revealed the clones cross-reacting with mouse (self) BP were almost always restricted to F1 hybrid class II major histocompatibility complex (MHC) elements. In contrast, mouse cross-reactive clones derived from a nonencephalitogenic (BALB/c x SJL/J) T cell line raised against rat BP were largely restricted to H-2d elements. These clones did not cross-react with bovine BP. Four additional lines were generated by carrying the original rat and bovine F1 T cell lines on parental antigen-presenting cells thus generating lines biased toward homozygous (SJL/J, H-2s, or BALB/c, H-2d) restriction elements. These "parentally restricted" T cell lines did not induce EAE when injected in vivo. These results suggest that in this F1 strain sensitivity to T cell-induced EAE is associated with epitopes on murine BP that associate with F1 class II MHC restricting elements. In contrast, nonencephalitogenic T cell lines contain a high proportion of murine cross-reactive clones restricted to H-2d, the haplotype of the classically resistant BALB/c mouse. This work illustrates the use of T cell lines and clones in a model system to further analyze the role of MHC restriction elements in autoimmune disease occurring in heterozygous individuals.     

Basic protein-specific T-cell lines that induce experimental autoimmune encephalomyelitis in SJL/J mice: comparison with Lewis rat lines

Myelin basic protein (BP)-specific T-cell lines were selected from SJL/J mice using techniques to select similar lines from Lewis rats. SJL/J BP-specific T-cell lines were composed of T cells with the helper/inducer phenotype (Lyt 1.2+, 2.2- and L3T4+) and proliferated in response to both the 1-37 and the 89-169 fragments of guinea pig BP. BP-specific T-cell lines transferred delayed-type hypersensitivity (DTH) responses to BP that persisted for over 60 days. Most recipient animals (32/41) developed acute experimental autoimmune encephalomyelitis (EAE), and most survivors (19/24) developed chronic relapsing EAE. Spinal cords of animals during both the acute and the chronic phases of illness contained plaques of demyelination and infiltrates of lymphocytes and macrophages. These findings differed from those of Lewis rat BP-specific lines which respond to a different region of BP, transfer DTH responses that last less than 12 days, and induce acute EAE in which demyelination does not occur.     

T lymphocyte line specific for thyroglobulin produces or vaccinates against autoimmune thyroiditis in mice

We investigated Ly-1+ T lymphocyte line cells specifically reactive to thyroglobulin (Tg) that were isolated from mice primed with mouse Tg in adjuvant. Intravenous inoculation of as few as 10(5) line cells was sufficient to cause severe and prolonged thyroiditis in recipient mice that were intact, irradiated, or athymic nudes. Disease was independent of circulating Tg antibodies, suggesting that anti-Tg T lymphocytes could cause thyroiditis unaided by antibodies. Thyroiditogenic T lymphocytes could be isolated as cell lines from apparently healthy mice that had been immunized with non-thyroiditogenic bovine Tg in adjuvant, which indicates that autoimmune effector T lymphocytes may develop covertly in the course of immunization with foreign antigens. Finally, a single i.v. inoculation of anti-Tg T lymphocyte line cells attenuated by irradiation vaccinated mice completely against subsequent development of autoimmune thyroiditis produced either by active immunization to Tg or by passive transfer of intact line cells. Vaccinated mice that were protected from inflammatory lesions of thyroiditis still produced high titers of Tg antibodies in response to active immunization. Thus, vaccination specifically inhibited thyroiditogenic T lymphocytes but not helper T lymphocytes required for the production of Tg autoantibodies.     

Experimental allergic encephalomyelitis: activation of suppressor T lymphocytes by a modified sequence of the T effector determinant

Deletion of certain amino acid residues from the amino acid sequence of the encephalitogenic determinant for guinea pigs, H-Phe-Ser-Trp-Gly-Ala-Glu-Gly-Gln-Lys-OH, destroyed its ability to induce experimental allergic encephalomyelitis (EAE), a cell-mediated autoimmune disease of myelin. The administration of the modified determinant in the form of 4 repeating pentameric sequences, H-(Phe-Ser-Trp-Gln-Lys)4-Gly-OH, activated an antigen-specific T suppressor lymphocyte subset that rendered both presensitized donors and recipients of donor T lymphocytes unresponsive to an encephalitogenic challenge. Treatment of donors or recipients with cyclophosphamide before or after lymphocyte transfer, respectively, obliterated the ability of peptide S42-sensitized T lymphocytes to induce a state of unresponsiveness to an EAE-challenge. The results establish the existence of antigenic determinants for both immunoinduction and immunoregulation of EAE. The immunoregulatory determinant that activates antigen-specific and cyclophosphamide-sensitive suppressor T lymphocyte subset is sequestered within the disease-inducing or T effector determinant.     

Host T cells are the main producers of IL-17 within the central nervous system during initiation of experimental autoimmune encephalomyelitis induced by adoptive transfer of Th1 cell lines

Experimental autoimmune encephalomyelitis (EAE), an animal model of multiple sclerosis, has long been thought to be mediated by Th1 CD4(+) T cells. Using adoptive transfer techniques, transfer of CNS specific Th1 T cells was sufficient to induce EAE in naive mice. However, recent studies found a vital role for IL-17 in induction of EAE. These studies suggested that a fraction of IL-17-producing T cells that contaminate Th1 polarized cell lines are largely responsible for initiation of EAE. In this study, we tracked the appearance and cytokine production capacity of adoptively transferred cells within the CNS of mice throughout EAE disease. IL-17-producing, adoptively transferred cells were not enriched over the low percentages present in vitro. Thus, there was no selective recruitment and/or preferential proliferation of adoptively transferred IL-17-producing cells during the induction of EAE. Instead a large number of CNS infiltrating host T cells in mice with EAE were capable of producing IL-17 following ex vivo stimulation. The IL-17-producing T cells contained both alphabeta and gammadelta TCR(+) T cells with a CD4(+)CD8(-) or CD4(-)CD8(-) phenotype. These cells concentrated within the CNS within 3 days of adoptive transfer, and appeared to play a role in EAE induction as adoptive transfer of Th1 lines derived from wild-type mice into IL-17-deficient mice induced reduced EAE clinical outcomes. This study demonstrates that an encephalitogenic Th1 cell line induces recruitment of host IL-17-producing T cells to the CNS during the initiation of EAE and that these cells contribute to the incidence and severity of disease.     

Immediate, long-lasting suppression of autoimmune encephalomyelitis by cell-bound neuroantigen

When lymphoid cells from rats recovered from experimental autoimmune encephalomyelitis (EAE) were incubated in vitro for 1 hr with myelin basic protein (BP), then washed and transferred along with anti-BP immune serum to naive recipients, those recipients immediately developed a solid, long-lasting resistance to active induction of EAE. To obtain this high level of suppression, both steps of BP-incubation of cells and transfer of immune serum were found to be essential, i.e., direct transfer of nonincubated cells plus immune serum had no comparable suppressive effect, nor had transfer of BP-incubated cells with nonimmune serum. Specificity of the suppressive effect was indicated by the finding that cells from BP-sensitized donors, incubated with BP, protected against BP-CFA-induced disease but not against disease induced with whole spinal cord homogenate (SCH-CFA). As expected, cells from SCH-CFA-sensitized donors incubated with SCH protected recipients against disease induced with either SCH-CFA or BP-CFA. The suppression appears to act early in the afferent stage of the immune response, since inoculation with incubated cells as little as 24 hr after active challenge was ineffective. There was no suppression of passively induced disease.     

Detection of autoimmune cells proliferating to myelin basic protein and selection of T cell lines that mediate experimental autoimmune encephalomyelitis (EAE) in mice

A procedure is described for the detection of an in vitro proliferative response to the autologous mouse myelin basic protein in mice injected with mouse spinal cord homogenate (MSCH) or with myelin basic proteins (BP) of mouse (MBP) or rat (RBP) origin. The administration of MSCH, but not of MBP or RBP, in a suitable adjuvant could produce a reproducible clinical disease. Nevertheless, a proliferative response to the autologous MBP could not be detected after either inoculation. Only the removal of the adherent cell fraction from the immunized cell population and its replacement with fresh naive accessory cells could reveal a proliferative response to the autologous MBP and to the heterologous RBP. A heteroclitic cross-reactivity between MBP and RBP is demonstrated. The possibility of detecting an in vitro proliferative response to BP allowed the selection and propagation in vitro of cells specific to BP. T cell lines were established that specifically proliferated in response to BP and mediated EAE in normal mice. Intravenous inoculation of as few as 10(6) line cells was capable of producing clinical signs of EAE in normal recipients within 5 to 6 days. Thus, although an inoculation of MSCH was required for active induction of the disease, T cells specifically reactive against BP are sufficient for mediation of EAE in mice.     

A myelin basic protein-specific T lymphocyte line that mediates experimental autoimmune encephalomyelitis

A T lymphocyte line, BP-1, expressing the T helper phenotype was selected from Lewis rats immunized with guinea pig myelin basic protein (GP-BP) in complete Freund's adjuvant (CFA). The BP-1 line responded specifically to GP-BP but not to PPD after the first round of selection, and responded to rat but not human or bovine BP. When injected i.p. into histocompatible Lewis or F1 (Lewis X P2) recipients, the BP-1 line induced both clinical signs of experimental autoimmune encephalomyelitis (EAE) and delayed type hypersensitivity (DTH) reactions in ears challenged intradermally with GP-BP but not PPD. The severity of clinical signs and the degree of ear swelling were dependent on the dose of BP-1 cells injected. Both activities were detectable with as few as 0.1 X 10(6) BP-1 line cells and required prior activation of the line cells with GP-BP presented by accessory cells. Lewis rats that had recovered from EAE induced by injection of GP-BP in CFA were more susceptible than naive rats to BP-1 line-mediated disease, requiring as few as 0.03 X 10(6) line cells. Clinical EAE and DTH could be serially transferred into F1 (Lewis X P2) recipients with BP-1 cells and back to nonirradiated Lewis parents with activated splenocytes, suggesting that BP-1 cells persist in recipient rats. These results demonstrate the potent biologic activities of an autoreactive BP-specific T lymphocyte line. This line possesses properties similar to BP lines described previously as well as to culture-conditioned splenic T effector cells; thus, the data presented here bridge the gap between these two approaches for studying T effector lymphocyte functions.     

Functional heterogeneity among CD4+ encephalitogenic T cells in recruitment of CD8+ T cells in experimental autoimmune encephalomyelitis

Inoculation of Lewis rats with live or attenuated (irradiated or paraformaldehyde-fixed) CD4+ encephalitogenic T cells (S1 line) protects the recipients from transferred experimental autoimmune encephalomyelitis (tEAE) induced by S1 cells. A CD8+ T lymphocyte population specifically activated against the EAE-inducing S1 cells can be readily isolated from the lymphoid organs of pretreated animals. We show, in the present study, that encephalitogenic T cell lines derived from Lewis rats differ in their ability to induce resistance against tEAE in vivo and to stimulate CD8+ cell proliferation in vitro. We also demonstrate that the S19 line of encephalitogenic T cells, in combination with myelin basic protein (MBP), can stimulate CD8+ cell proliferation in vitro. The CD8+ cells generated in this way strongly suppress MBP-specific T cell proliferation in vitro. This combined effect of T cells and MBP was also evident in vivo. Neither S19 cells nor MBP alone induced resistance against S19-mediated tEAE, rather coinjection of these cells and MBP was required. Our results suggest that resistance to EAE is mediated by distinct populations of encephalitogenic T cells that activate Ts cells through different mechanisms. In some instances, both autoreactive T cells and their relevant autoantigen(s) may be needed to activate Ts cells in vivo.     

Autoaggressive T lymphocyte lines recognizing the encephalitogenic region of myelin basic protein: in vitro selection from unprimed rat T lymphocyte populations

Autoimmune T lymphocyte lines have been established from unprimed normal rat lymph node cell populations. In a first, negative-selection round, spontaneously proliferating (SMLR) T cells were eliminated by a pulse of BUdR followed by short wave light irradiation. In a second, positive-selection round, the SMLR-depleted populations were confronted with MBP presented by syngeneic spleen adherent cells. Reactive T cells were propagated until stable, permanent T lines were established. All lines were exclusively specific for the selecting antigen, MBP, and were restricted in recognition by determinants of the own MHC. All lines expressed the differentiation marker W3/25, but not OX8. Line vLe, which was derived from Lewis (LEW) rat lymphocytes, and which recognized the encephalitogenic sequence 48-88 of MBP, was extremely efficient in mediating EAE to normal untreated LEW rats. Doses of 1 X 10(6) and greater transferred lethal EAE, whereas transient although definite disease was caused by a minimum of 1 X 10(4) cells. Rats recovering from disease were resistant against subsequent active induction of EAE. In contrast, BN rat-derived line vBN was completely incapable of transferring EAE to syngeneic rats. This lack of encephalitogenicity was a property of the T line, because vLe cells transferred severe EAE to (LEW X BN)F1 hybrid rats, whereas none of hybrid rats injected with vBN cells showed any sign of disease. The data provide strong evidence in favor of the presence of potentially autoaggressive T clones in the normal immune system, and they might suggest that the actual proportion of these clones within the natural T cell repertoire is genetically determined.     

Quantitative analysis of peptides from myelin basic protein binding to the MHC class II protein,I-Au,which confers susceptibility to experimental allergic encephalomyelitis.

BACKGROUND: An important issue in autoimmune diseases mediated by T cells, such as experimental allergic encephalomyelitis (EAE), is the affinity of the disease-inducing determinants for MHC class II proteins. Tolerance, either due to clonal deletion or anergy induction, is thought to require high-affinity interactions between peptides and MHC molecules. Low-affinity binding is compatible with the hypothesis that breaking tolerance to self proteins does not have to occur for onset of disease. In contrast, a high-affinity interaction implies that an event leading to a breakdown of tolerance is central to the autoimmune process. MATERIALS AND METHODS: Detergent-solubilized and affinity-purified I-Au was incubated with varying concentrations of a set of peptides from myelin basic protein and a biotinylated peptide agonist. The specific complexes were separated from excess peptide by capture on antibody-coated plates, and the affinity of the peptides was measured by adding europium-labeled streptavidin and measuring the resultant fluorescence. RESULTS: The immunodominant and encephalitogenic determinant, Ac 1-11, was shown to bind to I-Au relatively poorly (IC50 = 100 microM), demonstrating that in this protein, immunodominance did not correlate with high-affinity binding. In contrast with the natural sequence, the ability of shorter analogs to induce EAE did correlate with their apparent affinity. CONCLUSIONS: The dominance of the natural determinant does not arise from a high-affinity interaction with the MHC class II molecule. This suggests that other mechanisms are operative and that the specific T cell for this peptide/MHC ligand is of high affinity.     

Sex Bias in Pathogenesis of Autoimmune Neuroinflammation: Relevance for Dimethyl Fumarate Immunomodulatory/Anti-oxidant Action

In the present study, upon showing sexual dimorphism in dimethyl fumarate (DMF) efficacy to moderate the clinical severity of experimental autoimmune encephalomyelitis (EAE) in Dark Agouti rats, cellular and molecular substrate of this dimorphism was explored. In rats of both sexes, DMF administration from the day of immunization attenuated EAE severity, but this effect was more prominent in males leading to loss of the sexual dimorphism observed in vehicle-administered controls. Consistently, in male rats, DMF was more efficient in diminishing the number of CD4+ T lymphocytes infiltrating spinal cord (SC) and their reactivation, the number of IL-17+ T lymphocytes and particularly cellularity of their highly pathogenic IFN-γ+GM-CSF+IL-17+ subset. This was linked with changes in SC CD11b+CD45+TCRαβ? microglia/proinflammatory monocyte progeny, substantiated in a more prominent increase in the frequency of anti-inflammatory phygocyting CD163+ cells and the cells expressing high surface levels of immunoregulatory CD83 molecule (associated with apoptotic cells phagocytosis and implicated in downregulation of CD4+ T lymphocyte reactivation) among CD11b+CD45+TCRαβ– cells in male rat SC. These changes were associated with greater increase in the nuclear factor (erythroid-derived 2)-like 2 expression in male rats administered with DMF. In accordance with the previous findings, DMF diminished reactive nitrogen and oxygen species generation and consistently, SC level of advanced oxidation protein products, to the greater extent in male rats. Overall, our study indicates sex-specificity in the sensitivity of DMF cellular and molecular targets and encourages sex-based clinical research to define significance of sex for action of therapeutic agents moderating autoimmune neuroinflammation-/oxidative stress-related nervous tissue damage.     

In vivo regulation of experimental autoimmune encephalomyelitis by NK cells: alteration of primary adaptive responses

Innate immune responses provide the host with its first line of defense against infections. Signals generated by subsets of lymphocytes, including NK cells, NKT cells, and APC during this early host response determine the nature of downstream adaptive immune responses. In the present study, we have examined the role of innate NK cells in an autoimmune model through the use of primary immunization with the myelin oligodendrocyte glycoprotein peptide to induce experimental autoimmune encephalomyelitis (EAE). Our studies have shown that in vivo depletion of NK cells can affect the adaptive immune responses, because NK cells were found to regulate the degree of clinical paralysis and to alter immune adaptive responses to the myelin oligodendrocyte glycoprotein peptide. The requirement for NK cells was reflected by changes in the T cell responses and diminished clinical disease seen in mice treated with anti-NK1.1, anti-asialo GM1, and selected Ly49 subtype-depleted mice. In addition to alteration in T cell responses, the maturational status of dendritic cells in lymph nodes was altered both quantitatively and qualitatively. Finally, examination of TCR Vbeta usage of the brain lymphocytes from EAE mice indicated a spectra-type change in receptor expression in NK- depleted mice as compared with non-NK-depleted EAE mice. These findings further establish a recently postulated link between NK cells and the generation of autoreactive T cells.     

Expression of variable exon A-, B-, and C-specific CD45 determinants on peripheral and thymic T cell populations.

A mAb (I/24) has been generated that is specific for a determinant on mouse CD45 molecules. Reactivity of this mAb with a panel of CD45 transfected cell lines demonstrated that the determinant recognized is dependent upon expression of one or more CD45 variable exons and that exon C is sufficient for its expression. The exon C-specific epitope detected by I/24 is expressed at high density on essentially all B lymphocytes and at an intermediate density on the vast majority of CD8+ splenic T cells. Two distinct subpopulations of CD4+ splenic T cells were detected, a minor subpopulation that expresses this exon determinant at high density and a major subpopulation that expresses it at a much lower density. This first identification of a CD45RC-specific reagent allowed a comparison of the expression of exon A-, exon B-, and exon C-specific determinants on peripheral and thymic lymphoid populations. When splenic lymphocytes were analyzed for expression of CD45RA (reactive with mAb 14.8), CD45RB (reactive with mAb 23G2 or mAb 16.A), and CD45RC (reactive with mAb I/24) determinants, it was found that each of these CD45 determinants had a distinct pattern of expression on CD4+ and CD8+ T cells and B cells. CD45RB and RC epitopes were also detected at high density on a small proportion (0.7 to 4.1%) of thymocytes. Both CD45RB and RC epitopes were found predominantly on CD4-CD8- and CD4-CD8+ thymocytes but were also found on small numbers of CD4+CD8+ and CD4+CD8- cells. The population of thymocytes that expressed CD45RB and CD45RC determinants displayed a novel TCR CD3 phenotype characterized by a level of expression that was intermediate between that seen in the larger CD3 bright and CD3 dull populations of thymocytes.