Vibration acceleration enhances proliferation, migration, and maturation of C2C12 cells and promotes regeneration of muscle injury in male rats.
C2C12 cells
muscle regeneration
rats
vibration acceleration
whole-body vibration
Journal
Physiological reports
ISSN: 2051-817X
Titre abrégé: Physiol Rep
Pays: United States
ID NLM: 101607800
Informations de publication
Date de publication:
Feb 2024
Feb 2024
Historique:
revised:
11
12
2023
received:
26
09
2023
accepted:
14
12
2023
medline:
24
2
2024
pubmed:
24
2
2024
entrez:
24
2
2024
Statut:
ppublish
Résumé
Vibration acceleration (VA) using a whole-body vibration device is beneficial for skeletal muscles. However, its effect at the cellular level remains unclear. We aimed to investigate the effects of VA on muscles in vitro and in vivo using the C2C12 mouse myoblast cell line and cardiotoxin-induced injury in male rat soleus muscles. Cell proliferation was evaluated using the WST/CCK-8 assay and proportion of Ki-67 positive cells. Cell migration was assessed using wound-healing assay. Cell differentiation was examined by the maturation index in immunostained cultured myotubes and real-time polymerase chain reaction. Regeneration of soleus muscle in rats was assessed by recruitment of satellite cells, cross-sectional area of regenerated muscle fibers, number of centrally nucleated fibers, and conversion of regenerated muscle from fast- to slow-twitch. VA at 30 Hz with low amplitude for 10 min promoted C2C12 cell proliferation, migration, and myotube maturation, without promoting expression of genes related to differentiation. VA significantly increased Pax7-stained satellite cells and centrally nucleated fibers in injured soleus muscles on Day 7 and promoted conversion of fast- to slow-twitch muscle fibers with an increase in the mean cross-sectional area of regenerated muscle fibers on Day 14. VA enhanced the proliferation, migration, and maturation of C2C12 myoblasts and regeneration of injured rat muscles.
Types de publication
Journal Article
Langues
eng
Sous-ensembles de citation
IM
Pagination
e15905Subventions
Organisme : N/A
Informations de copyright
© 2024 The Authors. Physiological Reports published by Wiley Periodicals LLC on behalf of The Physiological Society and the American Physiological Society.
Références
Batra, N., Burra, S., Siller-Jackson, A. J., Gu, S., Xia, X., Weber, G. F., DeSimone, D., Bonewald, L. F., Lafer, E. M., Sprague, E., Schwartz, M. A., & Jiang, J. X. (2012). Mechanical stress-activated integrin α5β1 induces opening of connexin 43 hemichannels. Proceedings of the National Academy of Sciences of the United States of America, 109(9), 3359-3364.
Chan, Y. S., Hsu, K. Y., Kuo, C. H., Lee, S. D., Chen, S. C., Chen, W. J., & Ueng, S. W. N. (2010). Using low-intensity pulsed ultrasound to improve muscle healing after laceration injury: An in vitro and in vivo study. Ultrasound in Medicine & Biology, 36(5), 743-751.
Chen, R., Feng, L., Ruan, M., Liu, X., Adriouch, S., & Liao, H. (2013). Mechanical-stretch of C2C12 myoblasts inhibits expression of toll-like receptor 3 (TLR3) and of autoantigens associated with inflammatory myopathies. PLoS One, 8(11), e79930.
Corbiere, T. F., & Koh, T. J. (2020). Local low-intensity vibration improves healing of muscle injury in mice. Physiological Reports, 8(2), e14356.
Corbiere, T. F., Weinheimer-Haus, E. M., Judex, S., & Koh, T. J. (2018). Low-intensity vibration improves muscle healing in a mouse model of laceration injury. Journal of Functional Morphology and Kinesiology, 3(1), 1.
Da, Y., Mou, Y., Wang, M., Yuan, X., Yan, F., Lan, W., & Zhang, F. (2020). Mechanical stress promotes biological functions of C2C12 myoblasts by activating PI3K/AKT/mTOR signaling pathway. Molecular Medicine Reports, 21(1), 470-477.
Delecluse, C., Roelants, M., & Verschueren, S. (2003). Strength increase after whole-body vibration compared with resistance training. Medicine and Science in Sports and Exercise, 35(6), 1033-1041.
Folker, E. S., & Baylies, M. K. (2013). Nuclear positioning in muscle development and disease. Frontiers in Physiology, 12(4), 363.
Fowler, B. D., Palombo, K. T. M., Feland, J. B., & Blotter, J. D. (2019). Effects of whole-body vibration on flexibility and stiffness: A literature review. International Journal of Exercise Science, 12(3), 735-747.
Fujita, R., Kawano, F., Ohira, T., Nakai, N., Shibaguchi, T., Nishimoto, N., & Ohira, Y. (2014). Anti-interleukin-6 receptor antibody (MR16-1) promotes muscle regeneration via modulation of gene expressions in infiltrated macrophages. Biochimica et Biophysica Acta, 1840(10), 3170-3180.
Gao, Y., Arfat, Y., Wang, H., & Goswami, N. (2018). Muscle atrophy induced by mechanical unloading: Mechanisms and potential countermeasures. Frontiers in Physiology, 9, 235.
Garry, G. A., Antony, M. L., & Garry, D. J. (2016). Cardiotoxin induced injury and skeletal muscle regeneration. Methods in Molecular Biology, 1460, 61-71.
Ha, T. K. Q., Pham, H. T. T., Cho, H. M., Tran, V. O., Yang, J. L., Jung, D. W., Williams, D. R., & Oh, W. K. (2019). 12,23-Dione dammarane triterpenes from Gynostemma longipes and their muscle cell proliferation activities via activation of the AMPK pathway. Scientific Reports, 9(1), 1186.
Hettinger, Z. R., Hamagata, K., Confides, A. L., Lawrence, M. M., Miller, B. F., Butterfield, T. A., & Dupont-Versteegden, E. E. (2021). Age-related susceptibility to muscle damage following mechanotherapy in rats recovering from disuse atrophy. The Journals of Gerontology. Series A, Biological Sciences and Medical Sciences, 76(12), 2132-2140.
Hua, W., Zhang, M., Wang, Y., Yu, L., Zhao, T., Qiu, X., & Wang, L. (2016). Mechanical stretch regulates microRNA expression profile via NF-κB activation in C2C12 myoblasts. Molecular Medicine Reports, 14(6), 5084-5092.
Hurme, T., & Kalimo, H. (1992). Activation of myogenic precursor cells after muscle injury. Medicine and Science in Sports and Exercise, 24(2), 197-205.
Järvinen, T. A., Järvinen, T. L., Kääriäinen, M., Kalimo, H., & Järvinen, M. (2005). Muscle injuries: Biology and treatment. The American Journal of Sports Medicine, 33(5), 745-764.
Kahn, R. E., Dayanidhi, S., Lacham-Kaplan, O., & Hawley, J. A. (2023). Molecular clocks, satellite cells, and skeletal muscle regeneration. American Journal of Physiology. Cell Physiology, 324(6), C1332-C1340.
Klein-Nulend, J., Burger, E. H., Semeins, C. M., Raisz, L. G., & Pilbeam, C. C. (1997). Pulsating fluid flow stimulates prostaglandin release and inducible prostaglandin G/H synthase mRNA expression in primary mouse bone cells. Journal of Bone and Mineral Research, 12(1), 45-51.
Matsuura, T., Li, Y., Giacobino, J. P., Fu, F. H., & Huard, J. (2007). Skeletal muscle fiber type conversion during the repair of mouse soleus: Potential implications for muscle healing after injury. Journal of Orthopaedic Research, 25(11), 1534-1540.
Okamoto, M., Tanaka, H., Okada, K., Kuroda, Y., Nishimoto, S., Murase, T., & Yoshikawa, H. (2014). Methylcobalamin promotes proliferation and migration and inhibits apoptosis of C2C12 cells via the Erk1/2 signaling pathway. Biochemical and Biophysical Research Communications, 443(3), 871-875.
Rhea, M. R., Bunker, D., Marín, P. J., & Lunt, K. (2009). Effect of iTonic whole-body vibration on delayed-onset muscle soreness among untrained individuals. Journal of Strength and Conditioning Research, 23(6), 1677-1682.
Ribeiro, S., Gomes, A. C., Etxebarria, I., Lanceros-Méndez, S., & Ribeiro, C. (2018). Electroactive biomaterial surface engineering effects on muscle cells differentiation. Materials Science & Engineering. C, Materials for Biological Applications, 92, 868-874.
Stania, M., Juras, G., Slomka, K., Chmielewska, D., & Król, P. (2016). The application of whole-body vibration in physiotherapy-a narrative review. Physiology International, 103(2), 133-145.
Torvinen, S., Kannu, P., Sievänen, H., Järvinen, T. A., Pasanen, M., Kontulainen, S., et al. (2002). Effect of a vibration exposure on muscular performance and body balance. Randomized cross-over study. Clinical Physiology and Functional Imaging, 22(2), 145-152.
Uchida, R., Nakata, K., Kawano, F., Yonetani, Y., Ogasawara, I., Nakai, N., Mae, T., Matsuo, T., Tachibana, Y., Yokoi, H., & Yoshikawa, H. (2017). Vibration acceleration promotes bone formation in rodent models. PLoS One, 12(3), e0172614.
Wang, C. Z., Wang, G. J., Ho, M. L., Wang, Y. H., Yeh, M. L., & Chen, C. H. (2010). Low-magnitude vertical vibration enhances myotube formation in C2C12 myoblasts. Journal of Applied Physiology (Bethesda, MD: 1985), 109(3), 840-848.
Wang, D., Zheng, W., Xie, Y., Gong, P., Zhao, F., Yuan, B., Ma, W., Cui, Y., Liu, W., Sun, Y., Piel, M., Zhang, W., & Jiang, X. (2014). Tissue-specific mechanical and geometrical control of cell viability and Actin cytoskeleton alignment. Scientific Reports, 22, 6160.
Wang, M., Mou, Y., Da, Y., Yuan, X., Yan, F., Lan, W., et al. (2018). Effects of mammalian target of rapamycin on proliferation, apoptosis and differentiation of myoblasts undergoing mechanical stress. American Journal of Translational Research, 10(12), 4173-4182.
Wilder, R. P., & Sethi, S. (2004). Overuse injuries: Tendinopathies, stress fractures, compartment syndrome, and shin splints. Clinics in Sports Medicine, 23(1), 55-81. vi.
Yaffe, D., & Saxel, O. (1977). Serial passaging and differentiation of myogenic cells isolated from dystrophic mouse muscle. Nature, 270(5639), 725-727.
Yokoi, H., Take, Y., Uchida, R., Magome, T., Shimomura, K., Mae, T., Okamoto, T., Hanai, T., Chong, Y., Sato, S., Hikida, M., & Nakata, K. (2020). Vibration acceleration promotes endochondral formation during fracture healing through cellular chondrogenic differentiation. PLoS One, 15(3), e0229127.
Zimowska, M., Kasprzycka, P., Bocian, K., Delaney, K., Jung, P., Kuchcinska, K., Kaczmarska, K., Gladysz, D., Streminska, W., & Ciemerych, M. A. (2017). Inflammatory response during slow- and fast-twitch muscle regeneration. Muscle & Nerve, 55(3), 400-409.
Zimowska, M., Olszynski, K. H., Swierczynska, M., Streminska, W., & Ciemerych, M. A. (2012). Decrease of MMP-9 activity improves soleus muscle regeneration. Tissue Engineering. Part A, 18(11-12), 1183-1192.