Genetic control of pathogenic mechanisms in autoimmune demyelinating disease.

Multiple sclerosis is a disease of discrete phenotypes in different individuals. Animal models have been useful in identifying self-antigens that become the focus of autoimmune attack and genetic loci that control susceptibility to disease. We have previously demonstrated a role for Fas-dependent pathogenesis in the induction of EAE in B10.PL mice immunized with MBP. Others have indicated a Fas-independent mechanism predominates in SJL mice immunized with PLP. Here we compare the response of (B10.PLxSJL)F1 and parental mice under similar conditions for induction of EAE. The results indicate that immunodominance and dominant pathogenic mechanisms are both under genetic control, but can be inherited independently. The data also indicate that the dominant pathogenic mechanism can change during the course of disease in an individual. Elucidation of the genetic elements controlling pathogenesis during the course of disease would provide important information in designing therapeutic strategies for individuals in a heterogeneous patient population.

The role of fas ligand in vivo as a cause and regulator of pathogenesis.

Recent studies have significantly advanced our understanding of the physiological and pathogenic functions of Fas and Fas ligand (FasL) in vivo. In particular, roles for Fas-FasL interactions both in the induction and regulation of organ-specific autoimmune diseases have been defined and in some cases the specific targets and effectors of these interactions have been identified. Understanding the dynamic role of the Fas-FasL pathway in autoimmunity will provide insight into how best to modulate this interaction to achieve therapeutic benefits.

Dual role for Fas ligand in the initiation of and recovery from experimental allergic encephalomyelitis.

We have previously demonstrated a role for Fas and Fas ligand (FasL) in the pathogenesis of experimental allergic encephalomyelitis (EAE). However, using an active induction paradigm we could not distinguish between FasL expressed on activated CD4(+) T cells from that expressed on other inflammatory or resident central nervous system (CNS) cells. To address this issue, we have conducted reciprocal adoptive transfer experiments of nontransgenic or myelin basic protein-specific T cell receptor transgenic wild-type, lpr, or gld lymphocytes into congenic wild-type, lpr, and gld hosts. We found that FasL expressed on donor cells is important for the development of EAE, as FasL-deficient lymphocytes transfer attenuated disease. Furthermore, Fas expressed in the recipient animals is important for the progression of EAE, as clinical signs of disease in lpr recipients were dramatically attenuated after transfer of either wild-type or lpr T cells. Surprisingly, these experiments also identified CNS cells as a source of functional FasL. Host-derived FasL appears to be especially important in the recovery from EAE, as many gld recipients of wild-type lymphocytes develop prolonged clinical signs of disease. Thus it appears that FasL plays distinct roles in EAE during the initiation of and recovery from disease.

The role of the antigen-presenting cell in Fas-mediated direct and bystander killing: potential in vivo function of Fas in experimental allergic encephalomyelitis.

Costimulatory molecules are critical in mediating Fas-dependent direct and bystander lysis. In direct lysis, the APC is the Fas-positive target. It presents Ag to the T cell, thereby activating the T cell. The activated T cell then up-regulates FasL, allowing it to kill the APC. In bystander lysis, the APC again induces FasL expression on the T cell, but the target is a third Fas-positive cell that may lack the appropriate MHC-restricting element to activate the T cell. This study shows that ICAM-1 and B7-1 can serve as important adhesion molecules in direct killing using CD4+ T cell effectors. In bystander killing, B7-1 appears to act as a signaling molecule as well. It has been demonstrated that lpr and gld mice are less susceptible to experimental allergic encephalomyelitis than their wild-type counterparts. In this study, we show that although microglia are poor targets of direct killing, they are capable of stimulating myelin basic protein-specific T cells to kill innocent Fas-positive targets. This presents a possible mechanism for the pathogenesis of experimental allergic encephalomyelitis.

Role of Fas--FasL interactions in the pathogenesis and regulation of autoimmune demyelinating disease.

Multiple sclerosis (MS) and experimental autoimmune encephalomyelitis (EAE) represent complex processes that lead to destruction of oligodendrocytes (ODCs) and myelin. T cells are integral to the development of these diseases, but whether T cell-mediated cytolytic mechanisms are involved in the destruction of MHC Class II-negative targets, such as oligodendroglia and myelin, in the CNS is unclear. The primary lytic mechanism employed by CD4+ T cells is Fas-dependent, but can be MHC-unrestricted. Thus, T cell-mediated Fas-FasL interactions could directly contribute to the pathology of EAE and MS. This review summarizes studies from our laboratory and others that implicate Fas-FasL interactions in both the pathogenesis and regulation of demyelinating diseases.