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conserved regulation of Nodal-mediated left-right patterning in zebrafish and mouse.

Conserved regulation of Nodal-mediated left-right patterning in zebrafish and mouse.

机构信息

Department of Molecular and Cellular Biology, Harvard University, Cambridge, MA 02138, USA

Department of Molecular and Cellular Biology, Harvard University, Cambridge, MA 02138, USA.

出版信息

Development. 2018 Dec 10;145(24):dev171090. doi: 10.1242/dev.171090.

DOI:10.1242/dev.171090
PMID:30446628
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6307886/
Abstract

Nodal is the major effector of left-right axis development. In mice, Nodal forms heterodimers with Gdf1 and is inhibited by Cerl2/Dand5 at the node, and by Lefty1 in the lateral plate mesoderm (LPM). Studies in zebrafish have suggested some parallels, but also differences, between left-right patterning in mouse and zebrafish. To address these discrepancies, we generated single and double zebrafish mutants for (, the ortholog), and , and performed biochemical and activity assays with Spaw and Vg1/Gdf3 (the Gdf1 ortholog). Contrary to previous findings, mutants failed to initiate expression in the LPM, and asymmetric heart looping was absent, similar to mouse mutants. In blastoderm assays, Vg1 and Spaw were interdependent for target gene induction, and contrary to previous results, formed heterodimers. Loss of Dand5 or Lefty1 caused bilateral expression, similar to mouse mutants, and Lefty1 was replaceable with a uniform Nodal signaling inhibitor. Collectively, these results indicate that Dand5 activity biases Spaw-Vg1 heterodimer activity to the left, Spaw around Kupffer's vesicle induces the expression of in the LPM and global Nodal inhibition maintains the left bias of Spaw activity, demonstrating conservation between zebrafish and mouse mechanisms of left-right patterning.

摘要

节点是左右轴发育的主要效应器。在小鼠中,节点处的 Nodal 与 Gdf1 形成异二聚体,并受到 Cerl2/Dand5 和侧中胚层(LPM)中的 Lefty1 的抑制。斑马鱼的研究表明,左右模式在小鼠和斑马鱼之间存在一些相似之处,但也存在差异。为了解决这些差异,我们生成了单个和双突变体的斑马鱼,用于和,和,并进行了 Spaw 和 Vg1/Gdf3(Gdf1 同源物)的生化和活性测定。与之前的发现相反,突变体未能在 LPM 中启动表达,并且不对称心脏环化缺失,类似于小鼠突变体。在卵裂球测定中,Vg1 和 Spaw 相互依赖于靶基因诱导,与之前的结果相反,它们形成异二聚体。Dand5 或 Lefty1 的缺失导致双侧表达,类似于小鼠突变体,并且 Lefty1 可以被均匀的 Nodal 信号抑制剂取代。总的来说,这些结果表明,Dand5 活性使 Spaw-Vg1 异二聚体活性偏向左侧,Spaw 围绕 Kupffer 囊泡诱导 LPM 中表达,并通过全局 Nodal 抑制维持 Spaw 活性的左侧偏向,证明了左右模式形成的斑马鱼和小鼠机制之间的保守性。

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