Xenopus Hindbrain Patterning Requires Retinoid Signaling
Overview
Reproductive Medicine
Affiliations
We have asked how posterior neural tissue is patterned in Xenopus by assaying the involvement of endogenous retinoic acid (RA) in this process and by using the labial Hox gene, HoxD1, as a posterior marker. Although RA is able to inhibit anterior gene expression and activate expression of more posterior genes, the normal role of retinoids in anteroposterior (A/P) patterning is unclear. HoxD1 is an early posterior neurectodermal marker, expressed from midgastrula with a later anterior expression limit in the future hindbrain. We previously showed that HoxD1 was induced as an immediate early response to retinoic acid in naive ectoderm (animal caps). Here, we use a truncated RARalpha2.2 receptor (RARDelta) to dominantly interfere with retinoid signaling. In embryos injected with RARDelta expression of HoxD1 is eliminated. Conjugates of ectoderm and dorsolateral mesoderm show that retinoid receptors are required in the ectoderm for HoxD1 induction. Further, expression of Krox-20 in r3 and r5 of the presumptive hindbrain is compressed into a single stripe that suggests elimination of r5. RARalpha2.2 expression almost precisely overlaps that of HoxD1, suggesting that this receptor may normally activate HoxD1. Expression of neither more anterior genes including cement gland, forebrain, and midbrain markers nor a more posterior spinal cord marker is affected by RARDelta. These data suggest that the posterior hindbrain is the region of the nervous system most sensitive to retinoid loss. Finally, we compare the ability of RA and fibroblast growth factor (FGF) to posteriorize isolated anterior neurectoderm and show that both factors can act directly on this substrate. RA acts in a more anterior domain than does FGF; however, neither factor is equivalent to the natural posteriorizing capacity of the posterior mesoderm. We propose that endogenous retinoid and FGF signals pattern largely nonoverlapping regions along the A/P axis and that posterior neural patterning requires multiple inducers.
Generation of extracellular morphogen gradients: the case for diffusion.
Stapornwongkul K, Vincent J Nat Rev Genet. 2021; 22(6):393-411.
PMID: 33767424 DOI: 10.1038/s41576-021-00342-y.
Xenopus leads the way: Frogs as a pioneering model to understand the human brain.
Exner C, Willsey H Genesis. 2020; 59(1-2):e23405.
PMID: 33369095 PMC: 8130472. DOI: 10.1002/dvg.23405.
New roles for Wnt and BMP signaling in neural anteroposterior patterning.
Polevoy H, Gutkovich Y, Michaelov A, Volovik Y, Elkouby Y, Frank D EMBO Rep. 2019; 20(6).
PMID: 30936121 PMC: 6549026. DOI: 10.15252/embr.201845842.
Hindbrain induction and patterning during early vertebrate development.
Frank D, Sela-Donenfeld D Cell Mol Life Sci. 2018; 76(5):941-960.
PMID: 30519881 PMC: 11105337. DOI: 10.1007/s00018-018-2974-x.
Nervous System Regionalization Entails Axial Allocation before Neural Differentiation.
Metzis V, Steinhauser S, Pakanavicius E, Gouti M, Stamataki D, Ivanovitch K Cell. 2018; 175(4):1105-1118.e17.
PMID: 30343898 PMC: 6218657. DOI: 10.1016/j.cell.2018.09.040.