Ligong Cao

Enhanced T cell responsiveness to citrulline-containing myelin basic protein in multiple sclerosis patients

Myelin basic protein (MBP), a candidate autoantigen in multiple sclerosis (MS), exists in different isoforms and charge isomers generated by differential splicing of exons and by a combination of posttranslational modifications, respectively. These various isoforms and charge isomers of MBP vary in abundance and most likely serve different functions during myelinogenesis and remyelination. The least cationic among the charge isomers of MBP is citrullinated and is referred to as MBP-C8. MBP-C8 is relatively increased in the population of MBP isomers in more developmentally immature myelin and in MS brain tissue. In a previous study, we found that MBP-C8-reactive T cells could be detected in CD4+ T cell lines (TCL) generated with MBP from both MS patients and normal controls. Here, we examined the frequency and peptide specificity of MBPC8-specific TCL generated with MBP-C8 in MS patients and controls. Ten subjects grouped in five sets, each an MS patient and a control, were studied. In all cases, the MS patient had either a higher overall number of MBP-C8-responding lines, responded with greater sensitivity to the MBPC8 antigen or both. Few lines responded to the MBP-C8 peptides but, if they did, they appeared to be specific to the carboxyl-half of the MBP-C8 molecule. Given the large amounts of citrullinated MBP in MS brain tissue, a preferential T cell response to MBP-C8 may be involved in the induction and perpetuation of this disease.

CITRULLINATED MYELIN BASIC PROTEIN INDUCES EXPERIMENTAL AUTOIMMUNE ENCEPHALOMYELITIS IN LEWIS RATS THROUGH A DIVERSE T CELL REPERTOIRE

An increased proportion of citrullinated MBP (MBP-C8) occurs in the brains of multiple sclerosis (MS) patients. In this study, MBP-C8 from guinea pig (GP) brains was isolated and found encephalitogenic in Lewis rats upon immunization. An encephalitogenic T cell line selected with MBP-C8 preferentially reacted with MBP-C8 over unmodified MBP. This T cell line responded weakly to the dominant encephalitogenic epitope, GP-MBP peptide 70-88, and did not display restricted TCR beta-chain usage (such as Vbeta88.2). The distinctive features of MBP-C8 were also demonstrated by its ability to reinduce active EAE in 70% of rats which had recovered from unmodified MBP induced EAE. These findings raise the possibility that citrullinated MBP may elicit a different pathogenic T cell repertoire for the recurrent phases of inflammatory demyelination.

Inhibition of experimental allergic encephalomyelitis in the Lewis rat by paclitaxel.

Experimental allergic encephalomyelitis (EAE), an animal model for multiple sclerosis (MS), is useful for preclinical testing for agents to be considered for treatment for this human demyelinating disease. Microtubules in lymphocytes play an important role in the cascade of human T cell activation, and paclitaxel (PTX), a microtubule stabilizer, can inhibit T cell function. A new formulation of micellar PTX, free of Cremophor and ethanol, was tested for its effect on the induction of EAE in Lewis rats. Adoptive EAE was induced with an encephalitogenic T cell line activated with guinea pig myelin basic protein (GP MBP) peptide 68-88. PTX (10 mg/kg) was administered 24 and 72 h after cell transfer. The clinical signs, fulminating in controls, were completely blocked by PTX, but mild CNS inflammation remained unaltered. A similar dose of PTX, given on days 6 and 8 to animals developing active EAE after immunization with GP MBP peptide 68-88 in complete Freunds adjuvant, greatly reduced the severity of paralysis and delayed the onset of disease by 8-9 days. Marked weight loss and severe toxicity were noted with higher and more prolonged administration. In vitro micellar PTX inhibited activation of encephalitogenic T cells by both specific antigen and mitogen. Lower doses and longer treatment programs may provide effective treatment with acceptable adverse effects with this agent in the treatment of inflammatory demyelinating disease.

Reciprocal stimulation between TNF-α and nitric oxide may exacerbate CNS inflammation in experimental autoimmune encephalomyelitis

Nitric oxide (NO) and TNF-alpha are both highly active pleotypic modulators of cell function that are abundantly generated during inflammation. Experiments in animal systems have linked the generation of NO and TNF-alpha to autoimmune pathogenesis, and blockade of either NO or TNF-alpha has been shown to impede disease development. In this study, we show that NO and TNF-alpha can act mutually to stimulate each others production. While IFN-gamma alone induces NO release from microglia, astrocytes are provoked into significant NO production only by a combination of IFN-gamma and TNF-alpha. Since both TNF-alpha and NO are abundantly generated during T-glial cell interaction, we asked whether and how NO affects TNF-alpha production. Using an in vitro system in which TNF-alpha secretion is induced in MBP-reactive T cells by co-culture with syngeneic astrocytes, we observed that the efficiency of TNF-alpha secretion was markedly increased, in a dose-dependent fashion, by addition of micromolar concentrations of a chemical generator of NO donor, sodium nitroprusside (SNP). Similarly, low concentrations of SNP significantly enhanced the IL-2 dependent growth of MBP-reactive T cells. These results suggest that autoimmune pathogenesis initiated by inflammatory responses within the CNS may result in part from a vicious cycle in which TNF-alpha and NO mutually provoke each others production.

The role of regulatory T cells in Lewis rats resistant to EAE

Adult Lewis (LEW) rats are highly susceptible to experimental autoimmune encephalomyelitis (EAE), induced actively by immunization with guinea pig (GP) myelin basic protein (MBP) in complete Freunds adjuvant or adoptively transferred with activated T lymphocytes reactive to GP MBP peptide 68-88. Once LEW rats recover from active EAE or when given MBP in incomplete Freunds adjuvant (IFA), they become resistant to further attempts to induce active or passive EAE. In this study, we examined whether such EAE-resistant rats after MBP-IFA immunization have reduced frequencies of MBP-reactive T cells, whether these T cells are anergized, and whether the activity of regulatory T cells is increased to the event that they prevent activation of MBP-specific T cell subpopulations. By limiting dilution analyses (LDA) of unfractionated splenic T cells, the levels of MBP-reactive T cells in EAE-resistant rats appeared to be approximately 5% of the levels in EAE-susceptible rats. However, a subsequent analysis of CD4+ enriched T cell populations, depleted of the CD8 subset, showed similar frequencies of MBP-reactive cells in susceptible and resistant LEW rats. Not only were the frequencies on LDA altered by suppressor cells, but also LDA comparisons based on cell proliferation and cytokine production as indicators of MBP reactive cell frequencies gave markedly different results. We conclude that MBP-reactive T cells in this model of EAE-resistant LEW rats are hyporeactive to MBP as the result of an increased activity of a regulatory subset of CD8+ T cells. These results also demonstrate that the quantitation of MBP-reactive CD4+ T cells by LDA is strongly influenced by the presence of functionally antagonistic CD8+ T cells, which cause an underestimation of responder T cell frequencies, and by the method of detecting T cell reactivity.

Immunological effects of an arginine side chain contaminating synthetically prepared peptides

The side chain, 4-methoxy-2,3,6-trimethylbenzenesulphonyl (Mtr), is a protective group coupled to arginine to mask the omega-nitrogen, in order to protect the guanidino function during peptide synthesis by the 9-fluorenylmethoxycarbonyl (Fmoc) procedure (Walker, 1994). This group is removed at the completion of peptide synthesis; however, the cleavage process can be incomplete. We have found that animals injected with a mixed population of pure, i.e. unmodified, and Mtr-containing MBP peptides have an immunodominant humoral response to the Mtr-bearing peptide. This response is dependent on the characteristics of the MBP peptide involved. For two MBP peptides, the Mtr-containing peptide had increased binding to antibody over pure peptide. For two other peptides, only the Mtr-containing peptide bound antibody while the unmodified peptide did not. In a separate system involving a polyclonal response to an unrelated peptide from beta2-microglobulin (beta2 m), the dominance of the Mtr group was also evident. These results provide further evidence that a small side chain on a single amino acid in a peptide can markedly alter the immunogenicity and antigenicity of that peptide for antibody reactivity. This evidence emphasizes the need for a critical awareness of each component of peptide synthesis and its potential to alter the immunoreactivity of the final product.

Nitric oxide and TBF-alpha exacerbate each other's production in CNS inflammation

To investigate the regulatory effect of nitric oxide via constitutive nitric oxide synthase (cNOS) in autoimmtme spinal cord injury, we examined the expression of eNOS in the spinal cord of rats with EAE and compared iNnS immunoreactivity. Also we analysed the relationship between eNOS+ cells and apoptotic cells in EAE lesions. cNOS immunoreacfivity in the spinal cords was detected in some neurons, a few astrocytes and some vesse ls at the peak stage of EAE, but its expression was not detected in the normal rat spinal cords. However, iNnS+ cells were mainly localized in perivascular cuffing as well as some astrocytes at the peak stage. By double labeling method, apeptotie cells were dispersed on the spinal cord with EAE, and these cells were in contact with eNOS+cells including neurons and astrocytes. These findings sugges t that NO via eNOS from astrocytes and neurons play an important role in eliminating inflammatory cells via apoptosis leading to central nervous sys tem repair. 284 Primary Role for Macrophages/Microglia in Mediating a Delayed Onset Neuroinflammatory Disease in GFAP-TNF-a Transgenic Mice A,K. Stalder. M. Carson, V.C. Ascnsio, TheScrippsResearchlnstinae, USA, E. Masliah, H. Powell, University of California, San Diego, USA, I.L. Campbell, The Scripps Research Institute, USA