beta-catenin in early development of the lancelet embryo indicates specific determination of embryonic polarity

The lancelet (amphioxus) embryo develops from a miolecithal egg and starts gastrulation when it is approximately 400 cells in size, in a fashion similar to that of some non-chordate deuterostomes. Throughout this type of gastrulation, the embryo develops characteristics such as the notochord and hollow nerve cord that commonly appear in chordates. beta-Catenin is an important factor in initiating body patterning. The behavior and developmental pattern of this protein in early lancelet development was examined in this study. Cytoplasmic beta-catenin was localized to the animal pole after fertilization and then was incorporated asymmetrically into the blastomeres during the first cleavage. Asymmetric distribution was observed at least until the 32-cell stage. The first nuclear localization was at the 64-cell stage, and involved all of the cells. At the initial gastrula stage, however, concentrated beta-catenin was found on the dorsal side. LiCl treatment affected the asymmetric pattern of beta-catenin during the first cleavage. LiCl also changed distribution of nuclear beta-catenin at the initial gastrula stage: distribution extended to cells on the animal side. Apparently associated with this change, expression domains of goosecoid, lhx3 and otx also changed to a radially symmetric pattern centered at the animal pole. However, LiCl-treated embryos were able to establish embryonic polarity. The present study suggests that in the lancelet embryo, polarity determination is independent of dorsal morphogenesis.

文昌鱼Dkk和Kremen基因家族表达图谱和功能的研究

文昌鱼长期作为脊索动物的祖先模型被研究。它与脊椎动物发育机制的比较为后者的发生和进化提供了大量证据。Wnt信号通路在动物胚胎发育中行使着多样而重要的功能：如胚胎轴系的建立，胚层分化，神经图式形成等。在腔肠动物胚胎发育的早期，Wnt/β-catenin主要参与动植物半球极性的形成和胚层分化——很可能是Wnt通路的祖先功能。而在高等脊椎动物胚胎发育的早期，Wnt/β-catenin通路对于背腹轴、前后轴和左右轴极性的建立发挥着至关重要的作用。我们的研究主要集中在文昌鱼Wnt/β-catenin信号通路的两种调节因子Dickkopf（Dkk）和Kremen，以探明这些Wnt信号调节因子的祖先功能，以及在脊椎动物中获得新功能的进化历程。分泌性蛋白Dkk是Wnt信号通路的抑制因子，协同它的高亲和性受体Kremen，在两栖类胚胎头部的发育中起着关键作用。基于脊椎动物Dkk和kremen的报道以及佛罗里达文昌鱼基因组序列信息，我们运用分子克隆的方法，得到白氏文昌鱼Dkk家族的两个基因：BbDkk124和BbDkk3，以及Kremen家族的5个基因：BbKremen-a，BbKremen-c，BbKremen-d，BbKremen-e，BbKremen-g，用整体胚胎原位杂交的方法研究了它们的表达图谱，并在293T细胞和非洲爪蟾胚胎这两个系统中检测了它们对Wnt信号活性的影响和胚胎发育表型的影响。结果表明文昌鱼Dkk和Kremen的表达区域与脊椎动物的同源基因并不相同，出现了较大分歧，但BbDkk124作为Wnt信号抑制因子的功能是保守的。Kremen家族的两个基因BbKremen-e和BbKremen-g在293T细胞内对Wnt通路的影响不显著，而在非洲爪蟾系统中，引起胚胎不同的畸形表型。我们的实验结果为脊椎动物Dkk和Kremen 基因家族的进化提供了一些资料。 此外我们还研究了文昌鱼GATA家族的基因，这个家族在脊椎动物和非脊椎动物的发育中行使重要的动能，在进化上也是非常保守的。脊椎动物的GATA基因分为两个亚群：GATA1/2/3和GATA4/5/6。通过生物信息分析，我们在文昌鱼的基因组中找到了三个GATA基因：一个GATA1/2/3亚家族基因，两个GATA4/5/6亚家族基因，另外还找到一个类GATA基因。我们克隆了白氏文昌鱼GATA123的一段序列并研究了它在早期胚胎发育中的特异性表达。结果表明GATA123在原肠胚的中内胚层表达，而在神经胚晚期和幼体早期，GATA123在脑泡和消化道中部区域表达。这种表达模式与头部发育的重要基因Otx相类似。我们的研究结果提示在文昌鱼脑泡的发育过程中GATA123和Otx很可能协同发挥着重要的作用。