Nonsynaptic encoding of behavior by neuropeptides

IF 4.9 2区心理学 Q1 BEHAVIORAL SCIENCES

Current Opinion in Behavioral Sciences Pub Date : 2024-10-23 DOI:10.1016/j.cobeha.2024.101456

Gáspár Jékely , Rafael Yuste

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Abstract

A basic tenet of neuroscience is that animal behavior is generated by neural circuits that operate through synaptic transmission. On top of this synaptic ‘chassis’ of nervous systems, neuropeptides and hormones have traditionally been considered as slow neuromodulatory signals that fine-tune synaptic circuits. However, neuropeptides can generate many behaviors, including quite complex ones, from cnidarians to humans. Moreover, neuropeptide actions span larger temporal scales than fast synaptic transmission and are thus better matched to behavioral time courses than synaptic circuits. Furthermore, in some metazoans, the effects of neuropeptides are independent of synaptic connectivity, and in many species, the systemic application of neuropeptides can trigger selective behaviors. Based on this, we argue that nonsynaptic neuropeptide signaling via chemical networks — forming a ‘chemical’ connectome — represents the ancestral mechanism to encode behavioral sequences, whereas synaptic networks co-evolved as a specialization complementing chemical networks in the control of behaviors and computational functions.

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神经肽对行为的非突触编码

神经科学的一个基本原理是，动物行为是由神经回路通过突触传递产生的。在神经系统的突触 "底盘 "之上，神经肽和激素历来被认为是微调突触回路的缓慢神经调节信号。然而，神经肽可以产生许多行为，包括相当复杂的行为，从刺胞动物到人类都是如此。此外，与快速突触传递相比，神经肽作用的时间跨度更大，因此比突触回路更符合行为时间进程。此外，在某些后生动物中，神经肽的作用与突触连接无关，而且在许多物种中，神经肽的系统应用可以触发选择性行为。基于这一点，我们认为，通过化学网络发出非突触神经肽信号--形成 "化学 "连接组--代表了编码行为序列的祖先机制，而突触网络则是作为化学网络在控制行为和计算功能方面的补充而共同进化的一种专业化机制。

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

Current Opinion in Behavioral Sciences Neuroscience-Cognitive Neuroscience

CiteScore

10.90

自引率

2.00%

发文量

135

期刊介绍： Current Opinion in Behavioral Sciences is a systematic, integrative review journal that provides a unique and educational platform for updates on the expanding volume of information published in the field of behavioral sciences.