Activin/Nodal signaling mediates dorsal-ventral axis formation before third quartet formation in embryos of the annelid Chaetopterus pergamentaceus.

IF 4.1 2区生物学 Q1 DEVELOPMENTAL BIOLOGY

Evodevo Pub Date : 2020-08-10 eCollection Date: 2020-01-01 DOI:10.1186/s13227-020-00161-y

Alexis R Lanza, Elaine C Seaver

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Abstract

Background: The clade of protostome animals known as the Spiralia (e.g., mollusks, annelids, nemerteans and polyclad flatworms) shares a highly conserved program of early development. This includes shared arrangement of cells in the early-stage embryo and fates of descendant cells into embryonic quadrants. In spiralian embryos, a single cell in the D quadrant functions as an embryonic organizer to pattern the body axes. The precise timing of the organizing signal and its cellular identity varies among spiralians. Previous experiments in the annelid Chaetopterus pergamentaceus Cuvier, 1830 demonstrated that the D quadrant possesses an organizing role in body axes formation; however, the molecular signal and exact cellular identity of the organizer were unknown.

Results: In this study, the timing of the signal and the specific signaling pathway that mediates organizing activity in C. pergamentaceus was investigated through short exposures to chemical inhibitors during early cleavage stages. Chemical interference of the Activin/Nodal pathway but not the BMP or MAPK pathways results in larvae that lack a detectable dorsal-ventral axis. Furthermore, these data show that the duration of organizing activity encompasses the 16 cell stage and is completed before the 32 cell stage.

Conclusions: The timing and molecular signaling pathway of the C. pergamentaceus organizer is comparable to that of another annelid, Capitella teleta, whose organizing signal is required through the 16 cell stage and localizes to micromere 2d. Since C. pergamentaceus is an early branching annelid, these data in conjunction with functional genomic investigations in C. teleta hint that the ancestral state of annelid dorsal-ventral axis patterning involved an organizing signal that occurs one to two cell divisions earlier than the organizing signal identified in mollusks, and that the signal is mediated by Activin/Nodal signaling. Our findings have significant evolutionary implications within the Spiralia, and furthermore suggest that global body patterning mechanisms may not be as conserved across bilaterians as was previously thought.

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激活素/结节信号介导环带动物Chaetopterus pergamentaceus胚胎第三四分体形成之前的背腹轴形成。

背景被称为螺旋纲（如软体动物、无脊类动物、有脊类动物和多足扁形动物）的原生动物支系具有高度保守的早期发育程序。这包括早期胚胎中细胞的共同排列以及后代细胞进入胚胎象限的命运。在螺旋体胚胎中，D象限的单细胞起着胚胎组织器的作用，将体轴模式化。组织信号的精确时间及其细胞特征在不同的螺旋体中各不相同。之前在无脊椎动物Chaetopterus pergamentaceus Cuvier, 1830中进行的实验表明，D象限在体轴形成过程中具有组织作用；然而，组织者的分子信号和确切的细胞身份尚不清楚：结果：本研究通过在C. pergamentaceus的早期分裂阶段短时间暴露于化学抑制剂，研究了信号的时间和介导组织活动的特定信号途径。对Activin/Nodal通路而非BMP或MAPK通路的化学干扰导致幼虫缺乏可检测到的背-腹轴。此外，这些数据还表明，组织活动的持续时间包括 16 个细胞阶段，并在 32 个细胞阶段之前完成：结论：C. pergamentaceus 组织器的时间和分子信号途径与另一种无脊椎动物 Capitella teleta 相似，后者的组织信号需要持续到 16 细胞阶段，并定位到微孔 2d。由于C. pergamentaceus是一种早期分枝的无脊柱动物，这些数据与C. teleta的功能基因组研究相结合，暗示了无脊柱动物背-腹轴模式化的祖先状态涉及一种组织信号，这种信号比软体动物中发现的组织信号早发生一到两次细胞分裂，而且这种信号是由Activin/Nodal信号介导的。我们的发现对螺旋目动物的进化具有重要意义，并进一步表明，整体身体模式化机制在双翅目动物中可能不像以前认为的那样保守。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Evodevo EVOLUTIONARY BIOLOGY-DEVELOPMENTAL BIOLOGY

CiteScore

7.50

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： EvoDevo publishes articles on a broad range of topics associated with the translation of genotype to phenotype in a phylogenetic context. Understanding the history of life, the evolution of novelty and the generation of form, whether through embryogenesis, budding, or regeneration are amongst the greatest challenges in biology. We support the understanding of these processes through the many complementary approaches that characterize the field of evo-devo. The focus of the journal is on research that promotes understanding of the pattern and process of morphological evolution. All articles that fulfill this aim will be welcome, in particular: evolution of pattern; formation comparative gene function/expression; life history evolution; homology and character evolution; comparative genomics; phylogenetics and palaeontology

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