Formation of the vertebrate limb requires specification of cell position along three axes. Proximal-distal identity is regulated by the apical ectodermal ridge (AER) at the distal tip of the growing limb. Anterior-posterior identity is controlled by signals from the zone of polarizing activity (ZPA) within the posterior limb mesenchyme. Dorsal-ventral identity is regulated by ectodermally derived signals. Recent studies have begun to identify signalling molecules that may mediate these patterning activities. Members of the fibroblast growth factor (FGF) family are expressed in the AER and can mimic its proximal-distal signalling activity. Similarly, the gene Sonic hedgehog (Shh) is expressed in the ZPA, and Shh-expressing cells, like ZPA cells, can cause digit duplications when transplanted to the anterior limb margin. In contrast, no signal has yet been identified for the dorsal-ventral axis, although Wnt-7a is expressed in the dorsal ectoderm, suggesting that it may play such a role. To test this possibility, we have generated mice lacking Wnt-7a activity. The limb mesoderm of these mice shows dorsal-to-ventral transformations of cell fate, indicating that Wnt-7a is a dorsalizing signal. Many mutant mice also lack posterior digits, demonstrating that Wnt-7a is also required for anterior-posterior patterning. We propose that normal limb development requires interactions between the signalling systems for these two axes.
An important feature of mammalian development is the generation of sexually dimorphic reproductive tracts from the Müllerian and Wolffian ducts. In females, Müllerian ducts develop into the oviduct, uterus, cervix and upper vagina, whereas Wolffian ducts regress. In males, testosterone promotes differentiation of Wolffian ducts into the epididymis, vas deferens and seminal vesicle. The Sertoli cells of the testes produce Müllerian-inhibiting substance, which stimulates Müllerian duct regression in males. The receptor for Müllerian-inhibiting substance is expressed by mesenchymal cells underlying the Müllerian duct that are thought to mediate regression of the duct. Mutations that inactivate either Müllerian-inhibiting substance or its receptor allow development of the female reproductive tract in males. These pseudohermaphrodites are frequently infertile because sperm passage is blocked by the presence of the female reproductive system. Here we show that male mice lacking the signalling molecule Wnt-7a fail to undergo regression of the Müllerian duct as a result of the absence of the receptor for Müllerian-inhibiting substance. Wnt7a-deficient females are infertile because of abnormal development of the oviduct and uterus, both of which are Müllerian duct derivatives. Therefore, we propose that signalling by Wnt-7a allows sexually dimorphic development of the Müllerian ducts.
Secreted Wnt proteins regulate many developmental processes in multicellular organisms. We have generated a targeted mutation in the mouse Wnt7b gene. Homozygous Wnt7b mutant mice die at midgestation stages as a result of placental abnormalities. Wnt7b expression in the chorion is required for fusion of the chorion and allantois during placental development. The alpha4 integrin protein, required for chorioallantoic fusion, is not expressed by cells in the mutant chorion. Wnt7b also is required for normal organization of cells in the chorionic plate. Thus, Wnt7b signaling is central to the early stages of placental development in mammals.
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