Abstract
Glycerophosphodiesterase 5 (GDE5) selectively hydrolyses glycerophosphocholine to choline and is highly expressed in type II fiber-rich skeletal muscles. We have previously generated that a truncated mutant of GDE5 (GDE5dC471) that lacks phosphodiesterase activity and shown that transgenic mice overexpressing GDE5dC471 in skeletal muscles show less skeletal muscle mass than control mice. However, the molecular mechanism and pathophysiological features underlying decreased skeletal muscle mass in GDE5dC471 mice remain unclear. In this study, we characterized the skeletal muscle disorder throughout development and investigated the primary cause of muscle atrophy. While type I fiber-rich soleus muscle mass was not altered in GDE5dC471 mice, type II fiber-rich muscle mass was reduced in 8-week-old GDE5dC471 mice. Type II fiber-rich muscle mass continued to decrease irreversibly in 1-year-old transgenic mice with an increase in apoptotic cell. Adipose tissue weight and blood triglyceride levels in 8-week-old and 1-year-old transgenic mice were higher than those in control mice. This study also demonstrated compensatory mRNA expression of neuromuscular junction (NMJ) components, including nicotinic acetylcholine receptors (α1, γ, and ε subunits) and acetylcholinesterase in type II fiber-rich quadriceps muscles in GDE5dC471 mice. However, we did not observe morphological changes in NMJs associated with skeletal muscle atrophy in GDE5dC471 mice. We also found that HSP70 protein levels are significantly increased in the skeletal muscles of 2-week-old GDE5dC471 mice and in mouse myoblastic C2C12 cells overexpressing GDE5dC471. These findings suggest that GDE5dC471 mouse is a novel model of early-onset irreversible type II fiber-rich myopathy associated with cellular stress.
Highlights
The physiological process of aging critically affects an individual's quality of life via gradual functional, structural, and biochemical changes
The type II fiberspecific atrophy that is characteristic of GDE5dC471 mice may be because endogenous Glycerophosphodiesterase 5 (GDE5) is highly expressed in type II-rich skeletal muscle [30]
Previous studies have indicated a close relationship between skeletal muscle atrophy and the degeneration of neuromuscular junction (NMJ) that are located at pre- and post-synapses [15,16,17]
Summary
The physiological process of aging critically affects an individual's quality of life via gradual functional, structural, and biochemical changes. Age-related decline in skeletal muscle mass and functions is defined as sarcopenia, a condition characterized by muscle weakness and fiber. Few rodent models exhibit agerelated changes in skeletal muscles spontaneously and, long-term examination is required to characterize muscle weakness and fiber atrophy during aging and senescence in these systems. Age-related skeletal muscle pathology develops in about 28 months in F344/Brown-Norway F1 hybrid rat [5], and a senescence-accelerated SAMP1, SAMP6 or SAMP8 mouse [6,7,8]. An animal model with sarcopenia-like muscle atrophy that develops more quickly is urgently needed to advance studies of this degenerative condition
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