The timing between skeletal muscle myoblast replication and fusion into myotubes, and the stability of regenerated dystrophic myofibres: an autoradiographic study in mdx mice

JOHN K. McGEACHIE; MIRANDA D. GROUNDS

doi:10.1046/j.1469-7580.1999.19420287.x

Abstract

In mdx mice, a model for Duchenne muscular dystrophy, the timing between the replication of myoblasts and their incorporation into myotubes was determined autoradiographically. Thirty-eight mdx mice aged 23 d were injected with tritiated thymidine to label myoblasts replicating early in the dystrophic process. At intervals from 8 h to 30 d after injection the tibialis anterior muscles were removed, processed for autoradiography and analysed for labelled central myonuclei (derived from the progeny of myoblasts which had been labelled at 23 d). At 8 h after injection there were no labelled central myonuclei, showing that the labelled myoblasts had not fused within this time. At 1 d, 2% of central myonuclei were labelled, at 2 d, up to 32% were labelled, at 3 d ∼60% were labelled, and at 4 d the labelling peaked at 74%. In the 27 mice sampled from 5–30 d after injection, the levels of central myonuclear labelling varied enormously: from 1–63%. However, there was a consistent decrease in the numbers of labelled central myonuclei with time. This may have been due to dilution of the relative numbers of labelled myonuclei due to other, nonlabelled, myoblasts replicating after the availability of tritiated thymidine, and fusing. It was also possible that labelled myofibres underwent subsequent necrosis and were eliminated from the muscle. The proposal that a regenerated myofibre can undergo a subsequent cycle of necrosis and regeneration was supported by evidence of some necrotic myofibres with labelled and unlabelled central nuclei. These results have implications for understanding the cellular biology and pathology of dystrophic muscle, particularly in relation to myoblast transfer therapy as a potential treatment of Duchenne muscular dystrophy.

Crossref Citations

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Smythe, Gayle M. Fan, Ying and Grounds, Miranda D. 2000. Enhanced migration and fusion of donor myoblasts in dystrophic and normal host muscle. Muscle & Nerve, Vol. 23, Issue. 4, p. 560.

Salimena, Maria Cristina Lagrota-Candido, Jussara and Qu�rico-Santos, Thereza 2000. Gender dimorphism influences extracellular matrix expression and regeneration of muscular tissue in mdx dystrophic mice. Histochemistry and Cell Biology, Vol. 122, Issue. 5, p. 435.

White, Jason D. Davies, Marilyn McGeachie, John and Grounds, Miranda D. 2002. An evaluation of leukaemia inhibitory factor as a potential therapeutic agent in the treatment of muscle disease. Neuromuscular Disorders, Vol. 12, Issue. 10, p. 909.

Grounds, Miranda D. and Torrisi, Jo 2004. Anti‐TNFα (Remicade®) therapy protects dystrophic skeletal muscle from necrosis. The FASEB Journal, Vol. 18, Issue. 6, p. 676.

McNally, Elizabeth M and MacLeod, Heather 2005. Therapy Insight: cardiovascular complications associated with muscular dystrophies. Nature Clinical Practice Cardiovascular Medicine, Vol. 2, Issue. 6, p. 301.

Radley, Hannah G. Davies, Marilyn J. and Grounds, Miranda D. 2008. Reduced muscle necrosis and long-term benefits in dystrophic mdx mice after cV1q (blockade of TNF) treatment. Neuromuscular Disorders, Vol. 18, Issue. 3, p. 227.

Martin, Sheree D. Collier, Fiona M. Kirkland, Mark A. Walder, Ken and Stupka, Nicole 2009. Enhanced proliferation of human skeletal muscle precursor cells derived from elderly donors cultured in estimated physiological (5%) oxygen. Cytotechnology, Vol. 61, Issue. 3, p. 93.

Leite, Paulo Emílio Corrêa de Almeida, Kessiane Belshoff Lagrota‐Candido, Jussara Trindade, Pablo da Silva, Rafael Ferreira Ribeiro, Manuel Gustavo L. Lima‐Araújo, Katia G. Santos, Wilson C. and Quirico‐Santos, Thereza 2010. Anti‐inflammatory activity of Eugenia punicifolia extract on muscular lesion of mdx dystrophic mice. Journal of Cellular Biochemistry, Vol. 111, Issue. 6, p. 1652.

White, Robert B Biérinx, Anne-Sophie Gnocchi, Viola F and Zammit, Peter S 2010. Dynamics of muscle fibre growth during postnatal mouse development. BMC Developmental Biology, Vol. 10, Issue. 1,

김주영 박광훈 Joohyung Lee and 이철현 2010. Effect of Protein Supplementation on Exercise-Induced Muscle Damage. Korean Journal of Sport Science, Vol. 21, Issue. 3, p. 1298.

Leite, Paulo Emílio Corrêa Lagrota-Candido, Jussara Moraes, Louise D'Elia, Livia Pinheiro, Douglas Florindo da Silva, Rafael Ferreira Yamasaki, Edna N. and Quirico-Santos, Thereza 2010. Nicotinic acetylcholine receptor activation reduces skeletal muscle inflammation of mdx mice. Journal of Neuroimmunology, Vol. 227, Issue. 1-2, p. 44.

Serra, Filippo Quarta, Marco Canato, Marta Toniolo, Luana De Arcangelis, Valeria Trotta, Attilio Spath, Lucia Monaco, Lucia Reggiani, Carlo and Naro, Fabio 2012. Inflammation in muscular dystrophy and the beneficial effects of non‐steroidal anti‐inflammatory drugs. Muscle & Nerve, Vol. 46, Issue. 5, p. 773.

Sellathurai, Jeeva Cheedipudi, Sirisha Dhawan, Jyotsna Schrøder, Henrik Daa and Sampaolesi, Maurilio 2013. A Novel In Vitro Model for Studying Quiescence and Activation of Primary Isolated Human Myoblasts. PLoS ONE, Vol. 8, Issue. 5, p. e64067.

Paredes, João A. Zhou, Xiaoshan Höglund, Stefan Karlsson, Anna and Fraidenraich, Diego 2013. Gene Expression Deregulation in Postnatal Skeletal Muscle of TK2 Deficient Mice Reveals a Lower Pool of Proliferating Myogenic Progenitor Cells. PLoS ONE, Vol. 8, Issue. 1, p. e53698.

McDonald, Abby A. Kunz, Matthew D. McLoon, Linda K. and Huard, Johnny 2014. Dystrophic Changes in Extraocular Muscles after Gamma Irradiation in mdx:utrophin+/− Mice. PLoS ONE, Vol. 9, Issue. 1, p. e86424.

Radley-Crabb, Hannah G. Marini, Juan C. Sosa, Horacio A. Castillo, Liliana I. Grounds, Miranda D. Fiorotto, Marta L. and Fraidenraich, Diego 2014. Dystropathology Increases Energy Expenditure and Protein Turnover in the Mdx Mouse Model of Duchenne Muscular Dystrophy. PLoS ONE, Vol. 9, Issue. 2, p. e89277.

Mazzotti, Anna L. and Coletti, Dario 2016. The Need for a Consensus on the Locution “Central Nuclei” in Striated Muscle Myopathies. Frontiers in Physiology, Vol. 7, Issue. ,

Gopinath, Suchitra D. 2017. Inhibition of Stat3 signaling ameliorates atrophy of the soleus muscles in mice lacking the vitamin D receptor. Skeletal Muscle, Vol. 7, Issue. 1,

Novak, James S. Hogarth, Marshall W. Boehler, Jessica F. Nearing, Marie Vila, Maria C. Heredia, Raul Fiorillo, Alyson A. Zhang, Aiping Hathout, Yetrib Hoffman, Eric P. Jaiswal, Jyoti K. Nagaraju, Kanneboyina Cirak, Sebahattin and Partridge, Terence A. 2017. Myoblasts and macrophages are required for therapeutic morpholino antisense oligonucleotide delivery to dystrophic muscle. Nature Communications, Vol. 8, Issue. 1,

Tabakov, V. Yu. Zinov’eva, O. E. Voskresenskaya, O. N. and Skoblov, M. Yu. 2018. Isolation and Characterization of Human Myoblast Culture In Vitro for Technologies of Cell and Gene Therapy of Skeletal Muscle Pathologies. Bulletin of Experimental Biology and Medicine, Vol. 164, Issue. 4, p. 536.

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The timing between skeletal muscle myoblast replication and fusion into myotubes, and the stability of regenerated dystrophic myofibres: an autoradiographic study in mdx mice

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The timing between skeletal muscle myoblast replication and fusion into myotubes, and the stability of regenerated dystrophic myofibres: an autoradiographic study in mdx mice

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