Neuroscience
-
This paper examines the topography of neuronal degeneration in the central nervous system of the dystonia musculorum (dt) mutant mouse, revealed by selective silver impregnation, specific histochemical staining and electron microscopy. Neuronal lesions have been observed exclusively in the spinal cord, the medulla and the anterior lobe of the vermis. In the spinal cord, axonal degeneration was maximal among large and medium-sized primary sensory fibers, whereas thin caliber primary afferents were unaffected, with the exception of those containing acid phosphatase activity. ⋯ This study also suggests a simple pathophysiological mechanism for the onset and the progression of the degeneration: dystonic gene action would affect perinatally specific classes of sensory receptors, producing the degeneration of the nerve terminals and, progressively, the cell death of the sensory ganglion cells at their origin. This retrograde death, which results in the massive and early deafferentation of spinocerebellar neurons, would provoke, trans-neuronally, the impairment of these second order sensory neurons and the progressive degeneration of the spinocerebellar system. The close resemblance of the neuropathology of the mutant mouse to Friedreich's ataxia (the commonest form of human degenerative ataxic disorders) allows one to suppose that the dystonic mouse may be an optimal animal model for studying the genetic basis and the pathophysiological mechanisms of this form of human ataxia.