Wnt4 is a key regulator of ovary development in mammals, but its role in other vertebrates is unknown. Here, Kossack et al. show that zebrafish wnt4a is the ortholog of mammalian Wnt4 and is expressed....
The fibroblast growth factor (Fgf) signaling pathway has been implicated in many developmental processes, based largely on disruption of Fgf ligand gene functions. However, a mechanistic understanding of how Fgfs regulate each process will require...
Fibroblast growth factor (Fgf) signaling regulates many processes during development. In many cases, one tissue layer secretes an Fgf ligand that binds and activates an Fgf receptor (Fgfr) expressed by a neighboring tissue. Although many Fgf ligands have known requirements in development, less is known about the requirements for the receptors. We have generated null mutations in each of the five fgfr genes in zebrafish. Considering the many requirements for Fgf signaling throughout development and that null mutations in the mouse Fgfr1 and Fgfr2 genes are embryonic lethal, it was surprising that all zebrafish homozygous mutants are viable and fertile, with no discernable embryonic defect. Instead, we have discovered surprising complexity of the Fgf pathway, where multiple receptors are involved in coordinating developmental processes. For example, mutations in the ligand fgf8a cause loss of the midbrain-hindbrain boundary, whereas in the fgfr mutants, this phenotype is only seen in embryos that are triple mutant for fgfr1a;fgfr1b;fgfr2, but not in any single and double mutant combinations. We show that this apparent fgfr redundancy is also seen during the development of several other tissues, including posterior mesoderm, pectoral fins, viscerocranium, and neurocranium. These data therefore begin to define the Fgfrs that function with a particular Fgf ligand to regulate early development in zebrafish.
Growth and specification of the mouse intestine occurs in utero and concludes after birth. While numerous studies have examined this developmental process in the small intestine, far less is known about the cellular and molecular cues required for colon development. In this study, we examine the morphological events leading to crypt formation, epithelial cell differentiation, areas of proliferation, and the emergence and expression of a stem and progenitor cell marker Lrig1. Through multicolor lineage tracing, we show Lrig1 expressing cells are present at birth and behave as stem cells to establish clonal crypts within three weeks after birth. In addition, we use an inducible knockout mouse to eliminate Lrig1 during colon development and show loss of Lrig1 restrains proliferation within a critical developmental time window, without impacting colonic epithelial cell differentiation. Our study illustrates the morphological changes that occur during crypt development and the importance of Lrig1 in the developing colon.
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