Leucine Supplementation Exacerbates Atrophy In Cancer Cachectic Mice

Medicine & Science in Sports & Exercise Pub Date : 2020-07-01 DOI:10.1249/01.mss.0000685416.28401.83

Wesley S Haynie, Kyle L. Rankin, M. Rosa-Caldwell, Ka Bejarano, Seongkyun Lim, N. Greene, T. Washington

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引用次数: 2

Abstract

Delayed aging in various tissues has been observed for Snell dwarf mice (Pit1) yet muscular performance has not been characterized for this model. PURPOSE: The purpose of the present study was to characterize muscle mass and performance for 3 months old and 12 months old Snell dwarf mice in non-trained and resistance-type trained states. METHODS: Muscles of Snell dwarf mice and their wild-type littermates were exposed to 1 month of stretch-shortening contraction training. RESULTS: For non-trained muscles at both ages, muscles of Snell dwarf mice exhibited 70% less mass and 85% less isometric force relative to those of control mice. At young age, training 3 days per week had no effect regardless of mouse strain. With aging, 3 days per week training decreased muscle mass and isometric force by 12% and 25%, respectively, for control mice while no such decreases were observed for Snell dwarf mice. For control mice, training 2 days per week increased isometric force by 20% at young age with no training-induced decrements with aging. CONCLUSIONS: While Snell dwarf mice exhibit a trade-off between longevity and muscular performance, the Pit1 mutation counters age-related maladaptation to training. For wild-type muscle, modulation of frequency is a means for offsetting the maladaptive training response.

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