Claude C. A. Bernard

Myelin oligodendrocyte glycoprotein : a novel candidate autoantigen in multiple sclerosis

Abstractu2002Myelin oligodendrocyte glycoprotein (MOG) is a member of the immunoglobulin superfamily expressed exclusively in central nervous system (CNS) myelin. While the function of MOG is unknown, a number of studies have shown that immune responses to MOG contribute to the autoimmune-mediated demyelination seen in animals immunized with whole CNS tissue. This paper summarizes our recent studies, which unequivocally demonstrate that MOG by itself is able to generate both an encephalitogenic T cell response and an autoantibody response in Lewis rats and in several strains of mice. In Lewis rats the injection of both native MOG and MOG35–55 peptide produces a paralytic relapsing-remitting neurological disease with extensive plaque-like demyelination. The antibody response to MOG35–55 was highly restricted, as no reactivity to either other MOG peptides or myelin proteins could be detected. Fine epitope mapping showed that antibody from serum and cerebrospinal fluid of injected rats reacted strongly to MOG37–46, which is contiguous to the dominant T cell epitope contained within MOG44–55. NOD/Lt and C57BL/6 mice were also susceptible to severe neurological disease following injection with recombinant MOG or MOG35–55 peptide, indicating that this specific CNS autoantigen, or some of its determinants, can induce a pathogenic response across animal species. Severe paralysis and extensive demyelination were seen in both strains, but NOD/Lt mice experienced a chronic relapsing disease whereas C57BL/6 mice had a chronic non-remitting disease. Moreover, transfer of MOG35–55 T cells into naive NOD/Lt mice also produced severe neurological impairment as well as histological lesions. These results emphasize that a synergism between a T cell-response and anti-MOG antibodies may be important for the development of severe demyelinating disease. This, together with our demonstration that there is a predominant T cell response to MOG in patients with multiple sclerosis, clearly indicates that MOG is probably an important target autoantigen in this disease.

Protein microarrays guide tolerizing DNA vaccine treatment of autoimmune encephalomyelitis

The diversity of autoimmune responses poses a formidable challenge to the development of antigen-specific tolerizing therapy. We developed myelin proteome microarrays to profile the evolution of autoantibody responses in experimental autoimmune encephalomyelitis (EAE), a model for multiple sclerosis (MS). Increased diversity of autoantibody responses in acute EAE predicted a more severe clinical course. Chronic EAE was associated with previously undescribed extensive intra- and intermolecular epitope spreading of autoreactive B-cell responses. Array analysis of autoantigens targeted in acute EAE was used to guide the choice of autoantigen cDNAs to be incorporated into expression plasmids so as to generate tolerizing vaccines. Tolerizing DNA vaccines encoding a greater number of array-determined myelin targets proved superior in treating established EAE and reduced epitope spreading of autoreactive B-cell responses. Proteomic monitoring of autoantibody responses provides a useful approach to monitor autoimmune disease and to develop and tailor disease- and patient-specific tolerizing DNA vaccines.

The neurite outgrowth inhibitor Nogo A is involved in autoimmune-mediated demyelination

Inhibitors associated with CNS myelin are thought to be important in the failure of axons to regenerate after spinal cord injury and in other neurodegenerative disorders. Here we show that targeting the CNS-specific inhibitor of neurite outgrowth Nogo A by active immunization blunts clinical signs, demyelination and axonal damage associated with experimental autoimmune encephalomyelitis (EAE), a model of multiple sclerosis (MS). Mice vaccinated against Nogo A produce Nogo-specific antibodies that block the neurite outgrowth inhibitory activity associated with CNS myelin in vitro. Passive immunization with anti-Nogo IgGs also suppresses EAE. Our results identify Nogo A as an important determinant of the development of EAE and suggest that its blockade may help to maintain and/or to restore the neuronal integrity of the CNS after autoimmune insult in diseases such as MS. Our finding that Nogo A is involved in CNS autoimmune demyelination indicates that this molecule may have a far more complex role than has been previously anticipated.

Experimental autoimmune encephalomyelitis: An anatomically-based explanation of clinical progression in rodents

Lactate accumulation was measured soon after decapitation in three adjacent lower spinal cord regions of rats with EAE. Results indicate that during EAE, and in correlation with the onset of clinical signs of both initial attack and short-term relapse, a differential focal increase in lactate accumulation occurs in rat spinal cord compared to Freunds Complete Adjuvant controls, with greater increase occurring in more caudal segments. A [14C]antipyrine method of estimating relative spinal cord blood flow failed to find evidence that the lactate accumulations were due to focal ischemia. Subsequent measurement of isotopic water and total protein increases in the same cord regions indicated that a slight but significant increase in vasogenic edema occurs in correlation with the increase in lactate accumulation and the onset of EAE clinical signs. The data are interpreted as lending support to a speculative theory of paralysis induced by edema during EAE, in which nerve root endoneurium is postulated as the functionally vulnerable site. More specifically, it is hypothesized that the ascending progression of clinical signs of EAE in rodents can be explained on an anatomical basis by progressive disturbance of the nodes of Ranvier in nerve root myelinated fibers.

The Structure and Function of Myelin Oligodendrocyte Glycoprotein

Abstract : Myelin oligodendrocyte glycoprotein (MOG) is a quantitatively minor component of CNS myelin whose function remains relatively unknown. As MOG is an autoantigen capable of producing a demyelinating multiple sclerosis‐like disease in mice and rats, much of the research directed toward MOG has been immunological in nature. Although the function of MOG is yet to be elucidated, there is now a relatively large amount of biochemical and molecular data relating to MOG. Here we summarize this information and include our recent findings pertaining to the cloning of the marsupial MOG gene. On the basis of this knowledge we suggest three possible functions for MOG : (a) a cellular adhesive molecule, (b) a regulator of oligodendrocyte microtubule stability, and (c) a mediator of interactions between myelin and the immune system, in particular, the complement cascade. Given that antibodies to MOG and to the myelin‐specific glycolipid galactocerebroside (Gal‐C) both activate the same signaling pathway leading to MBP degradation, we propose that there is a direct interaction between the membrane‐associated regions of MOG and Gal‐C. Such an interaction may have important consequences regarding the membrane topology and function of both molecules. Finally, we examine how polymorphisms and/or mutations to the MOG gene could contribute to the pathogenesis of multiple sclerosis.

T-cell reactivity to multiple myelin antigens in multiple sclerosis patients and healthy controls

Myelin proteins, including myelin basic protein (MBP), proteolipid protein (PLP) and myelin oligodendrocyte glycoprotein (MOG) are candidate autoantigens in MS. It is not clear whether MS patients show a predominant reactivity to one or several myelin antigens. We evaluated the IFN‐γ production induced by MBP and MOG and selected MBP‐, MOG‐ and PLP‐peptides in MS patients and healthy controls using the IFN‐γ ELISPOT assay. Most MS patients and healthy controls showed a heterogeneous anti‐myelin T‐cell reactivity. Interestingly in MS patients a positive correlation was found between the anti‐MOG and anti‐MBP T‐cell responses. No myelin peptide was preferentially recognized among the peptides tested (MBP 84–102, 143–168, MOG 1–22, 34–56, 64–86, 74–96, PLP 41–58, 184–199, 190–209). In addition the frequency of IL2R+ MBP reactive T‐cells was significantly increased in blood of MS patients as compared with healthy subjects, indicating that MBP reactive T‐cells exist in an in vivo activated state in MS patients. Most of the anti‐MBP T‐cells were of the Th1‐type because reactivity was observed in IFN‐γ but not in IL‐4 ELISPOT‐assays. Using Th1 (IL‐12) and Th2 (IL‐4) promoting conditions we observed that the cytokine secretion pattern of anti‐MBP T‐cells still is susceptible to alteration. Our data further indicate that precursor frequency analysis of myelin reactive T‐cells by proliferation‐based assays may underestimate the true frequency of myelin specific T‐cells significantly. J. Neurosci. Res. 63:290–302, 2001.

Induction of a multiple sclerosis-like disease in mice with an immunodominant epitope of myelin oligodendrocyte glycoprotein

Myelin oligodendrocyte glycoprotein (MOG) is postulated to be a target autoantigen in multiple sclerosis (MS). Here we investigated the encephalitogenicity of an immunodominant epitope of MOG, peptide 35-55, in various strains of mice. An MS-like disease was induced in NOD/Lt mice (H-2g7) and C57BL/6 mice (H-2b) by a single injection of MOG35-55 in CFA. The disease followed a relapsing-remitting course in NOD/Lt mice, whereas C57BL/6 mice developed a chronic paralytic disease. Histologically, the disease in both strains was characterized by cellular infiltration and multifocal demyelination in the CNS. Significant DTH type reactions to MOG35-55 were only seen in MOG-susceptible animals, with the NOD/Lt mice showing the strongest responses. Susceptible mice also showed specific antibody responses to MOG35-55 but not to a panel of other MOG peptides. These results provide further evidence for the role of MOG as a highly autoantigenic molecule capable of inducing severe demyelinating disease.

Perivascular T Cells Express the Pro-Inflammatory Chemokine RANTES mRNA in Multiple Sclerosis Lesions

Multiple sclerosis (MS) is an inflammatory demyelinating disease of the central nervous system (CNS), characterized by accumulation of mononuclear cells. The pathogenesis of MS is complex and probably involves soluble immune mediators, particularly cytokines, and activated memory T cells, that are thought to migrate into the CNS. During lesion formation in MS, cytokines regulate cell functions, such as cell recruitment and migration. Because the chemokine RANTES play a role in both activating and recruiting leucocytes, particularly memory T cells into inflammatory sites, the authors have assessed RANTES mRNA levels at the site of lesions. Expression levels were analysed in brain samples and compared with neurological, infectious and other controls. RANTES was expressed by activated perivascular memory T cells, predominantly located at the edge of active plaques. While RANTES mRNA was detected in all 17 MS brains analysed, it was only found in six of the 14 control patients and generally at a lower expression level. In view of the regulatory and chemotactic properties of RANTES, these results imply that RANTES in MS lesions may play an important role in the activation and/or selective accumulation of memory T cells and, thereby, in the pathogenic events associated with MS.

CCL2 and CCL5 mediate leukocyte adhesion in experimental autoimmune encephalomyelitis—an intravital microscopy study

Experimental autoimmune encephalomyelitis (EAE) models multiple sclerosis (MS) and is characterized by marked mononuclear cell influx in the brain. Several studies have demonstrated a role for chemokines during EAE. It remains to be determined whether these mediators modulate EAE primarily by mediating leukocyte influx into the CNS or by modifying lymphocyte activation and/or trafficking into lymphoid organs. After induction of EAE with MOG(35-55), leukocyte recruitment peaked on day 14 and correlated with symptom onset, TNF-alpha production and production of CCL2 and CCL5. Levels of CXCL-10 and CCL3 were not different from control animals. Using intravital microscopy, we demonstrated that leukocyte rolling and adhesion also peaked at day 14. Treatment with anti-CCL2 or anti-CCL5 antibodies just prior to the intravital microscopy prevented leukocyte adhesion, but not rolling. Our data suggest that induction of leukocyte adhesion to the brain microvasculature is an important mechanism by which CCL2 and CCL5 participate in the pathophysiology of EAE.

Targeted expression of baculovirus p35 caspase inhibitor in oligodendrocytes protects mice against autoimmune-mediated demyelination

The mechanisms underlying oligodendrocyte (OLG) loss and the precise roles played by OLG death in human demyelinating diseases such as multiple sclerosis (MS), and in the rodent model of MS, experimental autoimmune encephalomyelitis (EAE), remain to be elucidated. To clarify the involvement of OLG death in EAE, we have generated transgenic mice that express the baculovirus anti‐apoptotic protein p35 in OLGs through the Cre‐loxP system. OLGs from cre/p35 transgenic mice were resistant to tumor necrosis factor‐α‐, anti‐Fas antibody‐ and interferon‐γ‐induced cell death. cre/p35 transgenic mice were resistant to EAE induction by immunization with the myelin oligodendrocyte glycoprotein. The numbers of infiltrating T cells and macrophages/microglia in the EAE lesions were significantly reduced, as were the numbers of apoptotic OLGs expressing the activated form of caspase‐3. Thus, inhibition of apoptosis in OLGs by p35 expression alleviated the severity of the neurological manifestations observed in autoimmune demyelinating diseases.