Cripto-independent Nodal signaling promotes positioning of the A–P axis in the early mouse embryo

Abstract

During early mouse development, the TGFβ-related protein Nodal specifies the organizing centers that control the formation of the anterior–posterior (A–P) axis. EGF-CFC proteins are important components of the Nodal signaling pathway, most likely by acting as Nodal coreceptors. However, the extent to which Nodal activity depends on EGF-CFC proteins is still debated. Cripto is the earliest EGF-CFC gene expressed during mouse embryogenesis and is involved in both A–P axis orientation and mesoderm formation. To investigate the relation between Cripto and Nodal in the early mouse embryo, we removed the Nodal antagonist Cerberus 1 (Cer1) and simultaneously Cripto, by generating Cer1;Cripto double mouse mutants. We observed that two thirds of the Cer1;Cripto double mutants are rescued in processes that are severely compromised in Cripto−/− embryos, namely A–P axis orientation, anterior mesendoderm and posterior neuroectoderm formation. The observed rescue is strongly reduced in Cer1;Cripto;Nodal triple mutants, suggesting that Nodal can signal extensively in the absence of Cripto, if Cer1 is also inhibited. This signaling activity drives A–P axis positioning. Our results provide evidence for the existence of Cripto-independent signaling mechanisms, by which Nodal controls axis specification in the early mouse embryo.