Protective effects of progesterone administration on axonal pathology in mice with experimental autoimmune encephalomyelitis

Abstract

Experimental autoimmune encephalomyelitis (EAE), an induced model of Multiple Sclerosis presents spinal cord demyelination, axonal pathology and neuronal dysfunction. Previous work has shown that progesterone attenuated the clinical severity, demyelination and neuronal dysfunction of EAE mice (Garay et al., J. Steroid Biochem. Mol. Biol., 2008). Here we studied if progesterone also prevented axonal damage, a main cause of neurological disability. To this end, some axonal parameters were compared in EAE mice pretreated with progesterone a week before immunization with MOG 40–54 and in a group of steroid-free EAE mice. On day 16th after EAE induction, we determined in both groups and in control mice: a) axonal density in semithin sections of the spinal cord ventral funiculus; b) appearance of amyloid precursor protein (APP) immunopositive spheroids as an index of damaged axons; c) levels of the growth associated protein GAP43 mRNA and immunopositive cell bodies, as an index of aberrant axonal sprouting. Steroid-naive EAE mice showed decreased axonal density, shrunken axons, abundance of irregular vesicular structures, degenerating APP+ axons, increased expression of GAP43 mRNA and immunoreactive protein in motoneurons. Instead, EAE mice receiving progesterone treatment showed increased axonal counts, high proportion of small diameter axons, reduced APP+ profiles, and decreased GAP43 expression. In conclusion, progesterone enhanced axonal density, decreased axonal damage and prevented GAP43 hyperexpression in the spinal cord of EAE mice. Thus, progesterone also exerts protective effects on the axonal pathology developing in EAE mice.