In humans, neural tube closure defects occur in 1:1000 pregnancies. The design of new strategies for the prevention of such common defects would benefit from an improved understanding of the molecular events underlying neurulation. Neural fold elevation is a key morphological process that acts during neurulation to drive neural tube closure. However, to date, the molecular pathways underpinning neural fold elevation have not been elucidated. Here, we use morpholino knock-down technology to demonstrate that Repulsive Guidance Molecule (RGMa)-Neogenin interactions are essential for effective neural fold elevation during Xenopus neurulation and that loss of these molecules results in disrupted neural tube closure. We demonstrate that Neogenin and RGMa are required for establishing the morphology of deep layer cells in the neural plate throughout neurulation. We also show that loss of Neogenin severely disrupts the microtubule network within the deep layer cells suggesting that Neogenin-dependent microtubule organization within the deep cells is essential for radial intercalation with the overlying superficial cell layer, thereby driving neural fold elevation. In addition, we show that sustained Neogenin activity is also necessary for the establishment of the apicobasally polarized pseudostratified neuroepithelium of the neural tube. Therefore, our study identifies a novel signaling pathway essential for radial intercalation and epithelialization during neural fold elevation and neural tube morphogenesis.
It is now well established that the netrin guidance cues and their receptors comprise a major molecular guidance system driving axon pathfinding during nervous system development. One netrin receptor, neogenin, is now emerging as a key regulator of many developmental processes throughout the embryo. Unexpectedly, a new family of neogenin ligands, the repulsive guidance molecule (RGM) family, has recently been identified. The functional outcome of neogenin activation is dictated by both the nature of the ligand as well as the developmental context. Netrin-1-neogenin interactions mediate chemoattractive axon guidance, while RGMa-neogenin interactions repel axons. Neogenin is required for the establishment of the pseudostratified epithelium of the neural tube, probably by promoting cell adhesion. In addition, a role for RGMa and neogenin in neuronal differentiation has been demonstrated. While neogenin signaling cascades are poorly understood, the opposing responses of neogenin to RGMa and netrin-1 in the context of axon guidance indicates that neogenin signaling is complex and subject to tight spatiotemporal regulation. In summary, neogenin is a multifunctional receptor regulating diverse developmental processes. Thus, its contribution to neural development is proving to be considerably more extensive than originally predicted.
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