Medusozoa 游泳行为的系统发育:巨轴突的作用及其可能的进化起源。

Robert W Meech
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引用次数: 0

摘要

虽然刺胞动物水螅的神经组织具有神经网结构,但一些刺胞动物髓质却含有清晰的神经束。例如,水螅类 Medusa Aglantha digitale 的神经摄食回路显示出排列和凝聚,而其近亲 Aequorea victoria 和 Clytia hemisphaerica 则没有这种现象。在某些情况下,神经凝聚的形式是快速传播的巨型轴突,其作用是逃逸或躲避。这种巨型轴突似乎是由许多细小得多的单元融合而成的。核糖体 DNA 分析已经确定了 Aglantha 和其他三棘水母 Aglaura 支系成员中基于巨轴突的逃逸游泳的发展脉络。Aglaura以及包括Colobonema sericeum等物种在内的姊妹亚支系具有独特的双泳能力,即可以高速或低速游泳。不过,Colobonema 表现出的双泳形式在生物力学和生理学上都不同于 Aglantha,也不是以巨轴为基础的。对这些密切相关物种的基因组进行比较,可能会为确定巨轴突形成和其他神经凝聚的分子基础提供一种方法。其分子机制可能涉及 "融合剂",一种可能来自病毒的小分子,它能在融合前将膜吸引到一起。利用基因组分析鉴定这些基于融合剂的机制可能会受到巨轴突进化后解剖学和生理学发生的许多变化的阻碍,但通过研究其他水螅(如虹吸亚纲)中巨轴突的趋同进化,基因组信噪比可能会得到改善。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Phylogenetics of swimming behaviour in Medusozoa: the role of giant axons and their possible evolutionary origin.

Although neural tissues in cnidarian hydroids have a nerve net structure, some cnidarian medusae contain well-defined nerve tracts. As an example, the hydrozoan medusa Aglantha digitale has neural feeding circuits that show an alignment and condensation, which is absent in its relatives Aequorea victoria and Clytia hemisphaerica. In some cases, neural condensations take the form of fast propagating giant axons concerned with escape or evasion. Such giant axons appear to have developed from the fusion of many, much finer units. Ribosomal DNA analysis has identified the lineage leading to giant axon-based escape swimming in Aglantha and other members of the Aglaura clade of trachymedusan jellyfish. The Aglaura, along with sister subclades that include species such as Colobonema sericeum, have the distinctive ability to perform dual swimming, i.e. to swim at either high or low speeds. However, the form of dual swimming exhibited by Colobonema differs both biomechanically and physiologically from that in Aglantha and is not giant axon based. Comparisons between the genomes of such closely related species might provide a means to determine the molecular basis of giant axon formation and other neural condensations. The molecular mechanism responsible may involve 'fusogens', small molecules possibly derived from viruses, which draw membranes together prior to fusion. Identifying these fusogen-based mechanisms using genome analysis may be hindered by the many changes in anatomy and physiology that followed giant axon evolution, but the genomic signal-to-noise ratio may be improved by examining the convergent evolution of giant axons in other hydrozoa, such as the subclass Siphonophora.

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