Tomonori Ogata

Cellular adaptations in soleus muscle during recovery after hindlimb unloading

Aim:  We used a model of chronic unloading followed by reloading to examine the apoptotic responses associated with soleus muscle atrophy and subsequent recovery.

Fasting-related autophagic response in slow- and fast-twitch skeletal muscle.

This study investigated regulation of autophagy in slow-twitch soleus and fast-twitch plantaris muscles in fasting-related atrophy. Male Fischer-344 rats were subjected to fasting for 1, 2, or 3 days. Greater weight loss was observed in plantaris muscle than in soleus muscle in response to fasting. Western blot analysis demonstrated that LC3-II, a marker protein for macroautophagy, was expressed at a notably higher level in plantaris than in soleus muscle, and that the expression level was fasting duration-dependent. To identify factors related to LC3-II enhancement, autophagy-related signals were examined in both types of muscle. Phosphorylated mTOR was reduced in plantaris but not in soleus muscle. FOXO3a and ER stress signals were unchanged in both muscle types during fasting. These findings suggest that preferential atrophy of fast-twitch muscle is associated with induction of autophagy during fasting and that differences in autophagy regulation are attributable to differential signal regulation in soleus and plantaris muscle.

Differential cell death regulation between adult-unloaded and aged rat soleus muscle

Sarcopenia is characterized by increased regenerating myofibres and decreased myofibre size. Sarcopenia progression might be partially regulated by ageing-related signals associated with necrotic fibre disruption and nuclear apoptosis. This study sought to identify ageing-related signals in aged atrophying skeletal muscle by comparison with unloaded muscle atrophy in adults. Adult (6-month) and old (32-month) rats were used. Some adult rats were subjected to 2 weeks of hindlimb unloading (6-month-HU). Histological analysis found that regenerating fibres increased by about 30-fold only in 32-month aged soleus muscle compared with 6-month rats. The number of apoptotic DNA fragmented nuclei was increased by 3.9-fold in 6-month-HU and 2.8-fold in 32-month rats. Cleaved caspase-3 was observed at high levels on basal membranes and in nuclei in 32-month rats. By Western blot analysis additional ageing-related signals could be identified since (1) phosphorylated Bcl-2 content was increased in both cytosolic and mitochondrial fractions; (2) ER stress signal proteins caspase-12, CHOP/GADD153, and GRP78 were increased; and (3) stress-inducible chaperone HSP70 was decreased in soleus muscle from 32-month but not changed in 6-month-HU rats. We conclude that activation of ageing-related signals may mediate necrotic myofibre disruption and nuclear apoptosis induction that contribute to progression of sarcopenia.

Prolonged exercise training induces long-term enhancement of HSP70 expression in rat plantaris muscle.

Skeletal muscle may develop adaptive molecular chaperone enhancements as a potential defense system through repeated daily exercise stimulation. The present study investigated whether prolonged exercise training alters the expression of molecular chaperone proteins for the long term in skeletal muscle. Mature male Wistar rats were subjected for 8 wk to either a single bout of acute intermittent treadmill running (30 m/min, 5 min x 4, 5 degrees grade) or prolonged treadmill running training (15-40 m/min, 5 min x 4, 5-7 degrees grade). Levels of five molecular chaperone proteins [heat shock protein (HSP)25, HSP60, glucose-regulated protein (GRP)78, HSP70, and heat shock cognate (HSC)70] were measured in response to acute exercise and prolonged training. HSP70 levels were increased 6 and 24 h after acute exercise, but expression returned to control level within 2 days. In contrast, prolonged training had a long-term effect on HSP70 expression. Levels of HSP70 were notably increased by 4.5-fold over control 2 days after prolonged training; the enhancement was maintained for at least 14 days after training ended. However, other molecular chaperone proteins did not show adaptive changes in response to prolonged training. In addition, HSP70 enhancement by prolonged exercise training was not accompanied by transcription of HSP70 mRNA. These findings demonstrate that prolonged training can induce long-term enhancement of HSP70 expression without change at the mRNA level in skeletal muscle.

Heat‐Stress effects on the myosin heavy chain phenotype of rat soleus fibers during the early stages of regeneration

Introduction: We investigated heat‐stress effects on the adult myosin heavy chain (MyHC) profile of soleus muscle fibers at an early stage of regeneration. Methods: Regenerating fibers in adult rats were analyzed 2, 4, or 6 days after bupivacaine injection. Rats were heat stressed by immersion in water (42 ± 1°C) for 30 minutes 24 hours after bupivacaine injection and every other day thereafter. Results: No adult MyHC isoforms were observed after 2 days, whereas some fibers expressed only fast MyHC after 4 days. Heat stress increased fast and slow MyHC in regenerating fibers after 6 days. Regenerating fibers expressing only slow MyHC were observed only in heat‐stressed muscles. Bupivacaine injection increased the number of Pax7+ and MyoD+ satellite cells in regenerating fibers, more so in heat‐stressed rats. Conclusion: The results indicate that heat stress accelerates fast‐to‐slow MyHC phenotype conversion in regenerating fibers via activation of satellite cells. Muscle Nerve 52: 1047–1056, 2015