Differential expression of two MyoD genes in fast and slow muscles of gilthead seabream ( Sparus aurata)

Members of the myogenic regulatory gene family, including MyoD, Myf5, Myogenin and MRF4, are specifically expressed in myoblast and skeletal muscle cells and play important roles in regulating skeletal muscle development and growth. They are capable of converting a variety of non-muscle cells into myoblasts and myotubes. To better understand their roles in the development of fish muscles, we have isolated the MyoD genomic genes from gilthead seabream (Sparus aurata), analyzed the genomic structures, patterns of expression and the regulation of muscle-specific expression. We have demonstrated that seabream contain two distinct non-allelic MyoDgenes, MyoD1 and MyoD2. Sequence analysis revealed that these two MyoD genes shared a similar gene structure. Expression studies demonstrated that they exhibited overlapping but distinct patterns of expression in seabream embryos and adult slow and fast muscles. MyoD1 was expressed in adaxial cells that give rise to slow muscles, and lateral somitic cells that give rise to fast muscles. Similarly, MyoD2 was initially expressed in both slow and fast muscle precursors. However, MyoD2 expression gradually disappeared in the adaxial cells of 10- to 15-somite-stage embryos, whereas its expression in fast muscle precursor cells was maintained. In adult skeletal muscles, MyoD1 was expressed in both slow and fast muscles, whereas MyoD2 was specifically expressed in fast muscles. Treating seabream embryos with forskolin, a protein kinase A activator, inhibited MyoD1 expression in adaxial cells, while expression in fast muscle precursors was not affected. Promoter analysis demonstrated that both MyoD1 and MyoD2 promoters could drive green fluorescence protein expression in muscle cells of zebrafish embryos. Together, these data suggest that the two non-allelic MyoD genes are functional in seabream and their expression is regulated differently in fast and slow muscles. Hedgehog signaling is required for induction of MyoDexpression in adaxial cells.     

Conditional conversion of ES cells to skeletal muscle by an exogenous MyoD1 gene.

A variety of differentiated cell types can be converted to skeletal muscle cells following transfection with the myogenic regulatory gene MyoD1. To determine whether multipotent embryonic stem (ES) cells respond similarly, cultures of two ES cell lines were electroporated with a MyoD1 cDNA driven by the beta-actin promoter. All transfected clones, carrying a single copy of the exogenous gene, expressed high levels of MyoD1 mRNA. Surprisingly, although maintained in mitogen-rich medium, this ectopic expression was associated with a transactivation of the endogenous myogenin and myosin light chain 2 gene but not the endogenous MyoD1, MRF4, Myf5, the skeletal muscle actin, or the myosin heavy chain genes. Preferential myogenesis and the appearance of contracting skeletal muscle fibers were observed only when the transfected cells were allowed to differentiate in vitro, via embryoid bodies, in low-mitogen-containing medium. Myogenesis was associated with the activation of MRF4 and Myf5 genes and resulted in a significant increase in the level of myogenin mRNA. Not all cells were converted to skeletal muscle cells, indicating that only a subset of stem cells can respond to MyoD1. Moreover, the continued expression of the introduced gene was not required for myogenesis. These results show that ES cells can respond to MyoD1, but environmental factors control the expression of its myogenic differentiation function, that MyoD1 functions in ES cells even under environmental conditions that favor differentiation is not dominant (incomplete penetrance), that MyoD1 expression is required for the establishment of the myogenic program but not for its maintenance, and that the exogenous MyoD1 gene can trans-activate the endogenous myogenin and MLC2 genes in undifferentiated ES cells.     

Transdifferentiation of esophageal smooth to skeletal muscle is myogenic bHLH factor-dependent

Previously, coexpression of smooth and skeletal differentiation markers, but not myogenic regulatory factors (MRFs), was observed from E16.5 mouse fetuses in a small percentage of diaphragm level esophageal muscle cells, suggesting that MRFs are not involved in the process of initiation of developmentally programmed transdifferentiation in the esophagus. To investigate smooth-to-skeletal esophageal muscle transition, we analyzed Myf5nlacZ knock-in mice, MyoD-lacZ and myogenin-lacZ transgenic embryos with a panel of the antibodies reactive with myogenic regulatory factors (MRFs) and smooth and skeletal muscle markers. We observed that lacZ-expressing myogenic precursors were not detected in the esophagus before E15.5, arguing against the hypothesis that muscle precursor cells populate the esophagus at an earlier stage of development. Rather, the expression of the MRFs initiated in smooth muscle cells in the upper esophagus of E15.5 mouse embryos and was immediately followed by the expression of skeletal muscle markers. Moreover, transdifferentiation was markedly delayed or absent only in the absence of Myf5, suggesting that appropriate initiation and progression of smooth-to-skeletal muscle transdifferentiation is Myf5-dependent. Accordingly, the esophagus of Myf5(-/-):MyoD(-/-)embryos completely failed to undergo skeletal myogenesis and consisted entirely of smooth muscle. Lastly, extensive proliferation of muscularis precursor cells, without programmed cell death, occurred concomitantly with esophageal smooth-to-skeletal muscle transdifferentiation. Taken together, these results indicate that transdifferentiation is the fate of all smooth muscle cells in the upper esophagus and is normally initiated by Myf5.     

Differential expression of myogenic determination genes in muscle cells: possible autoactivation by the Myf gene products.

The development of muscle cells involves the action of myogenic determination factors. In this report, we show that human skeletal muscle tissue contains, besides the previously described Myf-5, two additional factors Myf-3 and Myf-4 which represent the human homologues of the rodent proteins MyoD1 and myogenin. The genes encoding Myf-3, Myf-4 and Myf-5 are located on human chromosomes 11, 1, and 12 respectively. Constitutive expression of a single factor is sufficient to convert mouse C3H 10T1/2 fibroblasts to phenotypically normal muscle cells. The myogenic conversion of 10T1/2 fibroblasts results in the activation of the endogenous MyoD1 and Myf-4 (myogenin) genes. This observation suggests that the expression of Myf proteins leads to positive autoregulation of the members of the Myf gene family. Individual myogenic colonies derived from MCA C115 cells (10T1/2 fibroblast transformed by methylcholanthrene) express various levels of endogenous MyoD1 mRNA ranging from nearly zero to high levels. The Myf-5 gene was generally not activated in 10T1/2 derived myogenic cell lines but was expressed in some MCA myoblasts. In primary human muscle cells Myf-3 and Myf-4 mRNA but very little Myf-5 mRNA is expressed. In mouse C2 and P2 muscle cell lines MyoD1 is abundantly synthesized together with myogenin. In contrast, the rat muscle lines L8 and L6 and the mouse BC3H1 cells express primarily myogenin and low levels of Myf-5 but no MyoD1. Myf-4 (myogenin) mRNA is present in all muscle cell lines at the onset of differentiation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Specific requirements of MRFs for the expression of muscle specific microRNAs, miR-1, miR-206 and miR-133

The expression of three microRNAs, miR-1, miR-206 and miR-133 is restricted to skeletal myoblasts and cardiac tissue during embryo development and muscle cell differentiation, which suggests a regulation by muscle regulatory factors (MRFs). Here we show that inhibition of C2C12 muscle cell differentiation by FGFs, which interferes with the activity of MRFs, suppressed the expression of miR-1, miR-206 and miR-133. To further investigate the role of myogenic regulators (MRFs), Myf5, MyoD, Myogenin and MRF4 in the regulation of muscle specific microRNAs we performed gain and loss-of-function experiments in vivo, in chicken and mouse embryos. We found that directed expression of MRFs in the neural tube of chicken embryos induced ectopic expression of miR-1 and miR-206. Conversely, the lack of Myf5 but not of MyoD resulted in a loss of miR-1 and miR-206 expression. Taken together our results demonstrate differential requirements of distinct MRFs for the induction of microRNA gene expression during skeletal myogenesis.     

Skeletal muscle phenotypes initiated by ectopic MyoD in transgenic mouse heart.

Forced expression of the myogenic regulatory gene MyoD in many types of cultured cells initiates their conversion into skeletal muscle. It is not known, however, if MyoD expression serves to activate all or part of the skeletal muscle program in vivo during animal development, nor is it known how limiting the influences of cellular environment may be on the regulatory effects of MyoD. To begin to address these issues, we have produced transgenic mice which express MyoD in developing heart, where neither MyoD nor its three close relatives--myogenin, Myf-5, and MRF4/herculin/Myf-6--are normally expressed. The resulting gross phenotype in offspring from multiple, independent transgenic founders includes abnormal heart morphology and ultimately leads to death. At the molecular level, affected hearts exhibit activation of skeletal muscle-specific regulatory as well as structural genes. We conclude that MyoD is able to initiate the program that leads to skeletal muscle differentiation during mouse development, even in the presence of the ongoing cardiac differentiation program. Thus, targeted misexpression of this tissue-specific regulator during mammalian embryogenesis can activate, either directly or indirectly, a diverse set of genes normally restricted to a different cell lineage and a different cellular environment.