On being a Hydra with, and without, a nervous system: what do neurons add?

IF 1.9 2区生物学 Q3 BEHAVIORAL SCIENCES

Animal Cognition Pub Date : 2023-08-04 DOI:10.1007/s10071-023-01816-8

Alison Hanson

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Abstract

The small freshwater cnidarian Hydra has been the subject of scientific inquiry for over 300 years due to its remarkable regenerative capacities and apparent immortality. More recently, Hydra has been recognized as an excellent model system within neuroscience because of its small size, transparency, and simple nervous system, which allow high-resolution imaging of its entire nerve net while behaving. In less than a decade, studies of Hydra’s nervous system have yielded insights into the activity of neural circuits in vivo unobtainable in most other animals. In addition to these unique attributes, there is yet another lesser-known feature of Hydra that makes it even more intriguing: it does not require its neural hardware to live. The extraordinary ability to survive the removal and replacement of its entire nervous system makes Hydra uniquely suited to address the question of what neurons add to an extant organism. Here, I will review what early work on nerve-free Hydra reveals about the potential role of the nervous system in these animals and point towards future directions for this work.

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有神经系统和没有神经系统的九头蛇：神经元能增加什么？

300 多年来，小型淡水刺胞动物水螅一直是科学研究的主题，因为它具有非凡的再生能力和明显的永生性。最近，水螅因其体积小、透明度高和神经系统简单而被认为是神经科学领域的一个极好的模型系统。在不到十年的时间里，通过对水螅神经系统的研究，人们深入了解了体内神经回路的活动，这是其他大多数动物所无法企及的。除了这些独特的属性外，水螅还有一个鲜为人知的特点，使其更加引人入胜：它不需要神经硬件就能生存。水螅在整个神经系统被移除和替换后仍能存活的非凡能力，使它成为解决 "神经元能为现存生物体带来什么 "这一问题的独一无二的选择。在这里，我将回顾关于无神经水螅的早期研究揭示了神经系统在这些动物中的潜在作用，并指出这项工作的未来方向。

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来源期刊

Animal Cognition 生物-动物学

CiteScore

4.50

自引率

18.50%

发文量

125

审稿时长

4-8 weeks

期刊介绍： Animal Cognition is an interdisciplinary journal offering current research from many disciplines (ethology, behavioral ecology, animal behavior and learning, cognitive sciences, comparative psychology and evolutionary psychology) on all aspects of animal (and human) cognition in an evolutionary framework. Animal Cognition publishes original empirical and theoretical work, reviews, methods papers, short communications and correspondence on the mechanisms and evolution of biologically rooted cognitive-intellectual structures. The journal explores animal time perception and use; causality detection; innate reaction patterns and innate bases of learning; numerical competence and frequency expectancies; symbol use; communication; problem solving, animal thinking and use of tools, and the modularity of the mind.