Nonionizing Radiation as a Noninvasive Strategy in Regenerative Medicine: The Effect of Ca2+-ICR on Mouse Skeletal Muscle Cell Growth and Differentiation

Controlling cell differentiation and proliferation with minimal manipulation is one of the most important goals for cell therapy in clinical applications. In this work, we evaluated the hypothesis that the exposure of myoblast cells (C2C12) to nonionizing radiation (tuned at an extremely low-frequency electromagnetic field at calcium-ion cyclotron frequency of 13.75 Hz) may drive their differentiation toward a myogenic phenotype. C2C12 cells exposed to calcium-ion cyclotron resonance (Ca2+-ICR) showed a decrease in cellular growth and an increase in the G0/G1 phase. Severe modifications in the shape and morphology and a change in the actin distribution were revealed by the phalloidin fluorescence analysis. A significant upregulation at transcriptional and translational levels of muscle differentiation markers such as myogenin (MYOG), muscle creatine kinase (MCK), and alpha skeletal muscle actin (ASMA) was observed in exposed C2C12 cells. Moreover, the pretreatment with nifedipine (an L-type voltage-gated Ca2+ channel blocker) led to a reduction of the Ca2+-ICR effect. Consequently, it induced a downregulation of the MYOG, MCK, and ASMA mRNA expression affecting adversely the differentiation process. Therefore, our data suggest that Ca2+-ICR exposure can upregulate C2C12 differentiation. Although further studies are needed, these results may have important implications in myodegenerative pathology therapies.