DNA-based vaccines: the future of multiple sclerosis therapy?
Review
Overview
abstract
Multiple sclerosis (MS) is the most common human inflammatory, demyelinating and degenerative disorder of the CNS. Based mostly on work in experimental autoimmune encephalomyelitis, CD4(+) T cells were long thought to play the crucial role in MS pathogenesis. Only more recently has it been recognized that other effector cell types, including CD8(+) T cells, gammadelta-T cells and B lymphocytes may also have an important role in disease initiation and perpetuation. The expression of soluble inflammatory mediators, including cytokines and free radicals, may be one of the late pathways mediating CNS tissue damage. In addition, in virtually all patients with MS, an oligoclonal banding pattern of antibodies can be detected in the cerebrospinal fluid (CSF). However, the cause of MS still remains unknown. Specifically, no single foreign or self antigen has been identified to account for clinical disease activity or the presence of surrogate disease markers. All approved pharmacotherapies have anti-inflammatory or immunoregulatory properties and work in early stages of the disease. In a recent clinical trial, BHT-3009, a DNA vaccine encoding full-length human myelin basic protein, was tested in patient with MS. BHT-3009 was safe and well tolerated. In addition, immunization with BHT-3009 induced anti-inflammatory antigen-specific immune changes consisting of a marked decrease in T-cell proliferation of IFN gamma production and a reduction in titers of myelin-specific autoantibodies in the CSF. This review will discuss these intriguing observations and the overall potential of DNA vaccination in MS.