1. Genesis of muscle fiber-type diversity during mouse embryogenesis relies on Six1 and Six4 gene expression
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Richard, Anne-Françoise, Demignon, Josiane, Sakakibara, Iori, Pujol, Julien, Favier, Maryline, Strochlic, Laure, Le Grand, Fabien, Sgarioto, Nicolas, Guernec, Anthony, Schmitt, Alain, Cagnard, Nicolas, Huang, Ruijin, Legay, Claire, Guillet-Deniau, Isabelle, and Maire, Pascal
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EMBRYOLOGY , *LABORATORY mice , *GENE expression , *SKELETAL muscle , *MUSCLE cells , *HOMEOSTASIS , *PHENOTYPES - Abstract
Abstract: Adult skeletal muscles in vertebrates are composed of different types of myofibers endowed with distinct metabolic and contraction speed properties. Genesis of this fiber-type heterogeneity during development remains poorly known, at least in mammals. Six1 and Six4 homeoproteins of the Six/sine oculis family are expressed throughout muscle development in mice, and Six1 protein is enriched in the nuclei of adult fast-twitch myofibers. Furthermore, Six1/Six4 proteins are known to control the early activation of fast-type muscle genes in myocytes present in the mouse somitic myotome. Using double Six1:Six4 mutants (SixdKO) to dissect in vivo the genesis of muscle fiber-type heterogeneity, we analyzed here the phenotype of the dorsal/epaxial muscles remaining in SixdKO. We show by electron microscopy analysis that the absence of these homeoproteins precludes normal sarcomeric organization of the myofiber leading to a dystrophic aspect, and by immunohistochemistry experiments a deficiency in synaptogenesis. Affymetrix transcriptome analysis of the muscles remaining in E18.5 SixdKO identifies a major role for these homeoproteins in the control of genes that are specifically activated in the adult fast/glycolytic myofibers, particularly those controlling Ca2+ homeostasis. Absence of Six1 and Six4 leads to the development of dorsal myofibers lacking expression of fast-type muscle genes, and mainly expressing a slow-type muscle program. The absence of restriction of the slow-type program during the fetal period in SixdKO back muscles is associated with a decreased HDAC4 protein level, and subcellular relocalization of the transcription repressor Sox6. Six genes thus behave as essential global regulators of muscle gene expression, as well as a central switch to drive the skeletal muscle fast phenotype during fetal development. [Copyright &y& Elsevier]
- Published
- 2011
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