Abstract
Activation of SIRT1, an NAD+-dependent protein deacetylase, ameliorates muscular pathophysiology of δ-sarcoglycan-deficient TO-2 hamsters and dystrophin-deficient mdx mice. We found that SIRT1 was highly expressed beneath the cellular membranes of muscle cells. To elucidate functional roles of SIRT1 on muscles, skeletal muscle-specific SIRT1 knockout mice (SIRT1-MKO) were generated. SIRT1-MKO mice showed muscular pathology similar to mild muscular dystrophies with increased numbers of centrally nucleated small myofibers and decreased numbers of middle-sized (2000–3001 μm2) myofibers compared to those of wild-type (WT) mice. Accordingly, SIRT1-MKO mice showed significantly decreased exercise capacity in treadmill and inverted hanging tests with higher levels of serum creatine kinase activities compared with those in WT mice. Evans blue dye uptake after exercise was greater in the muscles of SIRT1-MKO than those of WT mice, suggesting membrane fragility in SIRT1-MKO mice. Because SIRT1 was dominantly localized beneath the membranes of muscular cells, SIRT1 may have a new role in the membranes. We found that levels of fluorescent FM1-43 dye intake after laser-induced membrane disruption in C2C12 cells were significantly increased by SIRT1 inhibitors or Sirt1-siRNA compared with those of control cells. Inhibition of SIRT1 or SIRT1-knockdown severely disturbed the dynamic aggregation of membrane vesicles under the injured site but did not affect expression levels of membrane repair proteins. These data suggested that SIRT1 had a critical role in the resealing of membrane-ruptured muscle cells, which could affect phenotypes of SIRT1-MKO mice. To our knowledge, this report is the first to demonstrate that SIRT1 affected plasma-membrane repair mechanisms.
Highlights
Cycles of contraction and relaxation in skeletal muscles and cardiac cells induce cellular membrane friction and strain that could cause membrane rupture
Costaining of SIRT1 with membrane or cytoplasmic markers, and nuclei (Hoechst 33342) showed that high levels of SIRT1 expression were detected in the nuclei, cytosol and beneath cellular membranes (Fig 1a)
We showed that SIRT1-MKO mice had pathological and physiological characteristics similar to those of mild dystrophies, especially dysferlinopathy (Figs 1 and 2)
Summary
Cycles of contraction and relaxation in skeletal muscles and cardiac cells induce cellular membrane friction and strain that could cause membrane rupture. Plasma membrane disruption is rapidly resealed by membrane repair mechanisms for cell survival [1]. Membrane resealing is triggered by Ca2+ influx through the injured site, where Ca2+ activates Ca2+ binding proteins. SIRT1 contributes to membrane resealing acknowledgements); and grants from the Setsuro Fujii Memorial, the Osaka Foundation for Promotion of Fundamental Medical Research (YH) (https://www.weblio.jp/content/%E4%B8%80% E8%88%AC%E8%B2%A1%E5%9B%A3%E6% B3%95%E4%BA%BA%E8%97%A4%E4%BA% 95%E7%AF%80%E9%83%8E%E8%A8%98% E5%BF%B5%E5%A4%A7%E9%98%AA%E5%9F %BA%E7%A4%8E%E5%8C%BB%E5%AD%A6% E7%A0%94%E7%A9%B6%E5%A5%A8%E5%8A %B1%E4%BC%9A), the Osaka Medical Research Foundation for Intractable Diseases (RH, NI) (http://www.nanbyo.or.jp/), the Japan Research Foundation for Clinical Pharmacology (AK) (https:// www.rinyaku-fdn.or.jp/), and MSD Life Science Foundation, Public Interest Incorporates Foundation (AK, NI) (https://www.msd-lifescience-foundation.or.jp/en/). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript
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