The Role of GSK-3β Phosphorylation in the Regulation of Slow Myosin Expression in Soleus Muscle during Functional Unloading

Skeletal muscle myosin phenotype (i.e., the predominance in the muscle of a particular isoform or isoforms of myosin heavy chains (MyHC)) determines the properties of muscle, such as contraction speed and fatigue. The aim of this study was to identify the functional relationship between the decrease of the nitric oxide (NO) content, the GSK-3β phosphorylation (leading to the GSK-3β activation), the NFATc1 amount in the muscle nuclei, and the MyHC I(β) isoform expression in the rat soleus muscle under gravitational unloading. Male Wistar rats were divided into five groups: the vivarium control group; the group of animals with a 7-day hind limb suspension receiving placebo; the group of animals with a hind limb suspension receiving a NO donor (L-arginine); the group of animals with a hind limb suspension receiving a NO donor and a NO-synthase inhibitor (L-NAME); and the group of animals with a hind limb suspension receiving a GSK-3β inhibitor. We have shown that a 7-day unloading leads to a NO content decrease in the soleus muscle, and this effect is prevented by L-arginine administration. In addition, administration of L-arginine blocks the GSK-3β phosphorylation decrease, NFATc1 export from the muscle nuclei, and MyHC I(β) expression decrease caused by unloading. The L-arginine effect in each case can be blocked by the NO-synthase inhibitor. Administration of the GSK-3β inhibitor prevents the unloading-induced NFATc1 export from the muscle nuclei and a decrease of the MyHC I(β) expression. The prevention of the MyHC I(β) expression decrease and the NFATc1 export from the nucleus by the selective GSK-3β inhibition confirms the hypothesis on the NO influence on the MyHC I(β) expression and the NFATc1 export from the nucleus via the GSK-3β phosphorylation decrease. Thus, the NO level decrease in the rat soleus muscle in unloading leads to the GSK-3β activation, which in turn, promotes the NFATc1 export from the nucleus and stabilization of the fast myosin phenotype.