Daniel B. Drachman - US grants

The projects contained in this proposal are all closely related to the central theme of interactions of motor nerves and skeletal muscles. Myasthenia gravis (MG) is by far the most common clinical disorder of the neuromuscular junction, affecting acetylcholine receptors. We will continue our analysis of the pathogenetic mechanisms in MG, and will undertake therapeutic trials in experimental animals. We will extend our studies of neurotrophic mechanisms, both at the level of the nerve's influence, and at the level of the muscle's response. We will study nerve sprouting and regeneration, with particular emphasis on the factors that evoke nerve growth and the axonal mechanisms by which it is sustained. We have begun an extensive study of Coxsackievirus myopathy. This viral myopathy relates closely to the theme of the proposal, because only denervated or immature muscles are susceptible to infection, and because surface receptors are essential for infection to take place. Thus, the virus will be used as a biological probe of the muscle membrane during development and denervation. Finally, we plan to continue our studies of axonal transport in normal and abnormal peripheral nerve regeneration.

Myasthenia gravis (MG), which is by far the most common clinical disorder of the neuromuscular junction, is due to an antibody-mediated autoimmune attack against acetylcholine receptors (AChRs). The major challenge in MG is to use the detailed knowledge of its pathogenesis to design immunotherapeutic strategies that will a) specifically eliminate the anti-AChR autoimmune responses; b) have long-lasting effects, and c) eventually be applicalbe to human MG: We will develop and test a series of novel strategies for specific immunotherapy in the experimental model of myasthenia gravis in the rat (EAMG). 1) We will induce and propagate AChR-specific suppressor T lymphocytes, using two approaches that have already been successful in preliminary experiments in our hands: a) incubation with lymphocytes from EAMG rats with Cyclosporin A (CsA) plus AChR in vitro, b) incubation of lymphocytes from EAMG rats syngeneic lymphocytes with covalently coupled AChR. The suppressor cells induced by these methods, or soluble suppressor factors produced by them, will first be tested in a cell culture system, and then will be used to treat rats with EAMG. 2) We will attempt to treat EAMG by immunizing rats with a pure population of AChR-sensitized lymphoblasts. This method induces a powerful and broad spectrum anti-idiotypic reaction that should down-regulate the anti-AChR immune response. 3) We will use the promising method of "total lymphoid irradiation" (TLI) to attempt to induce long lasting and specific suppression of the anti-AChR response in animals with EAMG. ULtimately, the mehtods developed in this model system should be applicable to the treatment of human MG, and other autoimmune neuromuscular disorders.

DESCRIPTION: The pathogenesis of myasthenia gravis (MG) involves an antibody-mediated autoimmune response directed against acetylcholine receptors (AChR). Although current treatment of MG with immunosuppressive agents is reasonably effective, it has important drawbacks, including overall suppression of the immune system, and other adverse side effects. The goal of specific immunotherapy has remained elusive. Since the pathogenic AChR antibody response is T cell dependent, inactivation or elimination of AChR-specific T cells interrupts the immune response, with resulting clinical benefit. However, the fact that T cell responses to AChR are highly heterogeneous presents a strategic problem in designing specific immunotherapy. This proposal will explore and capitalize on a novel strategy of safe stimulation to target the entire spectrum of AChR-specific T cells, using denatured AChR (denAChR), in conjunction with genetically engineered agents that inactivate and/or eliminate the specifically stimulated T cells. The studies will be carried out in Lewis rats with experimental autoimmune MG (EAMG). DenAChR stimulates AChR-specific T cells as strongly as native AChR, but its reduced and non-pathogenic AChR antibody response avoids the risk of exacerbating MG. Stimulation is a necessary condition for the action of the therapeutic agents. CTLA4Ig is a soluble recombinant protein that blocks the B7 family of costimulatory molecules, and may induce anergy in antigen-stimulated T cells. Preliminary studies suggest that CTLA4Ig prevents primary EAMG and inhibits secondary EAMG, with interesting changes in the AChR antibody isotypes, suggestive of a switch in T helper cells from Th1 to Th2 type. DAB389IL2 is a fusion protein that binds to IL2 receptors on antigen-activated T cells, and kills them via a lethal diphtheria toxin moiety. Preliminary studies using DAB389IL2 in vitro and in vivo show marked inhibition of immune responses to AChR. Combined use of CTLA4Ig + DAB389IL2 appears to be even more potent, with a powerful effect on the difficult-to-treat secondary immune response to AChR. We will study the effects of this strategy on antibodies to Torpedo and autoantibodies to rat