Mary Elizabeth Pownall scite author profile

Embryological and genetic studies of mouse, bird, zebrafish, and frog embryos are providing new insights into the regulatory functions of the myogenic regulatory factors, MyoD, Myf5, Myogenin, and MRF4, and the transcriptional and signaling mechanisms that control their expression during the specification and differentiation of muscle progenitors. Myf5 and MyoD genes have genetically redundant, but developmentally distinct regulatory functions in the specification and the differentiation of somite and head muscle progenitor lineages. Myogenin and MRF4 have later functions in muscle differentiation, and Pax and Hox genes coordinate the migration and specification of somite progenitors at sites of hypaxial and limb muscle formation in the embryo body. Transcription enhancers that control Myf5 and MyoD activation in muscle progenitors and maintain their expression during muscle differentiation have been identified by transgenic analysis. In epaxial, hypaxial, limb, and head muscle progenitors, Myf5 is controlled by lineage-specific transcription enhancers, providing evidence that multiple mechanisms control progenitor specification at different sites of myogenesis in the embryo. Developmental signaling ligands and their signal transduction effectors function both interactively and independently to control Myf5 and MyoD activation in muscle progenitor lineages, likely through direct regulation of their transcription enhancers. Future investigations of the signaling and transcriptional mechanisms that control Myf5 and MyoD in the muscle progenitor lineages of different vertebrate embryos can be expected to provide a detailed understanding of the developmental and evolutionary mechanisms for anatomical muscles formation in vertebrates. This knowledge will be a foundation for development of stem cell therapies to repair diseased and damaged muscles.

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eFGF regulates Xbra expression during Xenopus gastrulation.

Isaacs

1994

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We show that, in addition to a role in mesoderm induction during blastula stages, FGF signalling plays an important role in maintaining the properties of the mesoderm in the gastrula of Xenopus laevis. eFGF is a maternally expressed secreted Xenopus FGF with potent mesoderm‐inducing activity. However, it is most highly expressed in the mesoderm during gastrulation, suggesting a role after the period of mesoderm induction. eFGF is inhibited by the dominant negative FGF receptor. Embryos overexpressing the dominant negative receptor show a change of behaviour of the dorsal mesoderm such that it moves around the blastopore lip instead of elongating in an antero‐posterior direction. In such embryos there is a reduction in Xbra expression during gastrulation. We show that during blastula stages eFGF and Xbra are able to activate the expression of each other, suggesting that they are components of an autocatalytic regulatory loop. Moreover, we show that Xbra expression in isolated gastrula mesoderm cells is maintained by eFGF, suggesting that eFGF continues to regulate the expression of Xbra in the blastopore region. In addition, overexpression of eFGF after the mid‐blastula transition results in the up‐regulation of Xbra expression during gastrula stages and causes suppression of the head and enlargement of the proctodeum, which is the converse of the posterior reductions of the FGF dominant negative receptor phenotype. These data suggest an important role for eFGF in regulating the expression of Xbra and for the eFGF‐Xbra regulatory pathway in the control of mesodermal cell behaviour during gastrula stages.

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Regulation of Hox gene expression and posterior development by the Xenopus caudal homologue Xcad3

1998

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The caudal gene codes for a homeodomain transcription factor that is required for normal posterior development in Drosophila. In this study the biological activities of the Xenopus caudal (Cdx) family member Xcad3 are examined. A series of domain-swapping experiments demonstrate that the N-terminus of Xcad3 is necessary for it to activate Hox gene expression and that this function can be replaced by the activation domain from the viral protein VP16. In addition, experiments using an Xcad3 repressor mutant (XcadEn-R), which potently blocks the activity of wild-type Xcad3, are reported. Overexpression of XcadEn-R in embryos inhibits the activation of the same subset of Hox genes that are activated by wildtype Xcad3 and leads to a dramatic disruption of posterior development. We show that Xcad3 is an immediate early target of the FGF signalling pathway and that Xcad3 posteriorizes anterior neural tissue in a similar way to FGF. Furthermore, Xcad3 is required for the activation of Hox genes by FGFs. These data provide strong evidence that Xcad3 is required for normal posterior development and that it regulates the expression of the Hox genes downstream of FGF signalling.

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