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ECB-ART-40578
Dev Biol 2008 Feb 15;3142:276-86. doi: 10.1016/j.ydbio.2007.11.039.
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Vasa protein expression is restricted to the small micromeres of the sea urchin, but is inducible in other lineages early in development.

Voronina E , Lopez M , Juliano CE , Gustafson E , Song JL , Extavour C , George S , Oliveri P , McClay D , Wessel G .


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Vasa is a DEAD-box RNA helicase that functions in translational regulation of specific mRNAs. In many animals it is essential for germ line development and may have a more general stem cell role. Here we identify vasa in two sea urchin species and analyze the regulation of its expression. We find that vasa protein accumulates in only a subset of cells containing vasa mRNA. In contrast to vasa mRNA, which is present uniformly throughout all cells of the early embryo, vasa protein accumulates selectively in the 16-cell stage micromeres, and then is restricted to the small micromeres through gastrulation to larval development. Manipulating early embryonic fate specification by blastomere separations, exposure to lithium, and dominant-negative cadherin each suggest that, although vasa protein accumulation in the small micromeres is fixed, accumulation in other cells of the embryo is inducible. Indeed, we find that embryos in which micromeres are removed respond by significant up-regulation of vasa protein translation, followed by spatial restriction of the protein late in gastrulation. Overall, these results support the contention that sea urchins do not have obligate primordial germ cells determined in early development, that vasa may function in an early stem cell population of the embryo, and that vasa expression in this embryo is restricted early by translational regulation to the small micromere lineage.

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Genes referenced: ddx4 LOC100887844 LOC100891456 LOC105441782 LOC115919910 LOC578749 LOC587482 LOC594236
???displayArticle.antibodies??? ddx4 Ab1 ddx4 Ab2 ddx4 Ab3 ddx4 Ab4

References [+] :
Agata, Two different evolutionary origins of stem cell systems and their molecular basis. 2006, Pubmed