Role of bone morphogenic protein 2 in retinal patterning and retinotectal projection.

It has been long believed that the anteroposterior (A-P) and dorsoventral (D-V) axes in the developing retina are determined independently and also that the retinotectal projection along the two axes is controlled independently. However, we recently demonstrated that misexpression of Ventroptin, a bone morphogenic protein (BMP) antagonist, in the developing chick retina alters the retinotectal projection not only along the D-V (or mediolateral) axis but also along the A-P axis. Moreover, the dorsal-high expression of BMP4 is relieved by the dorsotemporal-high expression of BMP2 at embryonic day 5 (E5) in the retina, during which Ventroptin continuously counteracts the two BMPs keeping on the countergradient expression pattern, respectively. Here, we show that the topographic molecules so far reported to have a gradient only along the D-V axis and ephrin-A2 so far only along the A-P axis are both controlled by the BMP signal, and that they are expressed in a gradient manner along the tilted axis from E6 on in the developing chick retina: the expression patterns of these oblique-gradient molecules are all changed, when BMP2 expression is manipulated in the developing retina. Furthermore, in both BMP2 knockdown embryos and ephrin-A2-misexpressed embryos, the retinotectal projection is altered along the two orthogonal axes. The expressional switching from BMP4 to BMP2 thus appears to play a key role in the retinal patterning and topographic retinotectal projection by tilting the D-V axis toward the posterior side during retinal development. Our results also indicate that BMP2 expression is essential for the maintenance of regional specificity along the revised D-V axis.

Novel G-protein-coupled receptor gene expressed specifically in the entire neural tube of the ascidian Ciona intestinalis.

We have cloned a newly identified gene, designated CiNut, C iona i ntestinalis neural-tube-specific gene. CiNut shows weak similarity to known neural receptors such as adrenergic receptors. Moreover, seven transmembrane domains are predicted based on its amino acid sequence. Zygotic expression of CiNut starts at the gastrula stage, and is restricted to the entire neural tube in the neurula- and the tailbud-stage embryos. CiNut is thus thought to be a novel G-protein-coupled receptor important for neural tube formation, and should provide a useful tool for the analysis of the molecular mechanism of neural tube formation.