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Previous Article | Next Article
Journal of Neuroscience, Vol 8, 3011-3017, Copyright © 1988 by Society for Neuroscience
ARTICLE
Biochemical and physiological consequences of an age-related increase in acetylcholinesterase activity at the rat neuromuscular junction
DO Smith and M Emmerling
Department of Physiology, University of Wisconsin, Madison 53706.Acetylcholinesterase (AChE) specific activity was assayed using diaphragm muscles obtained from mature adult (10 months) and aged (25- 27 months) rats. Biochemical assays indicated significant age-related increases in the AChE specific activity of both noninnervated and innervated tissue. The different molecular forms of AChE were separated by velocity sedimentation and were further assayed. The age-related increase was manifest primarily in the 10S (G4) form in both noninnervated and innervated tissue and also the 16S (A12) form of the noninnervated samples. To ascertain more conclusively whether AChE activity in the end-plate junctional region of innervated tissue changed in the older rats, miniature end-plate currents (m.e.p.c.s) were recorded under voltage-clamp conditions before and after AChE inhibition. When AChE activity was inhibited by 10 microM echothiopate or 1 mM methanesulfonyl fluoride, m.e.p.c. amplitudes and decay time constants increased in both age groups. The magnitude of these increases was larger in the older animals. However, calculations of the relative change in m.e.p.c. amplitudes after AChE inhibition indicated that less ACh was hydrolyzed by AChE in the older animals. Inhibition of AChE did not affect mean channel open time, which was estimated from spectral analyses of ACh-induced membrane noise. These data indicate that the prolonged decay times in the older rats following AChE inhibition is quite likely due to an expanded field of postsynaptic ACh receptors and not exclusively to a change in junctional AChE.
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