瑞典卡罗林斯卡医学院Abdeljabbar El Manira团队报道了控制斑马鱼运动速度的脊髓回路模块的分子蓝图。相关论文于2023年11月2日发表在《自然—神经科学》杂志上。
他们使用成年斑马鱼将运动神经元(MNs)和产生节奏的V2a中间神经元(INs)的分子多样性与负责运动速度变化的模块化电路组织联系起来。他们发现MNs和V2a INs的分子多样性反映了它们的功能分离为慢、中、快亚型。此外,他们还发现了三种速度电路模块的V2a INs和MNs之间共享的分子特征。
总的来说,通过表征MNs和V2a INs的分子多样性如何与其功能,连通性和行为相关,他们的研究不仅为运动灵活性的神经元和电路多样性的分子机制提供了重要的见解,而且为绘制一般运动动作的电路提供了重要的见解。
据悉,运动动作的灵活性植根于神经元的多样性以及它们如何组织成功能电路模块,然而人们对运动电路模块化的分子基础的了解仍然有限。
附:英文原文
Title: Molecular blueprints for spinal circuit modules controlling locomotor speed in zebrafish
Author: Pallucchi, Irene, Bertuzzi, Maria, Madrid, David, Fontanel, Pierre, Higashijima, Shin-ichi, El Manira, Abdeljabbar
Issue&Volume: 2023-11-02
Abstract: The flexibility of motor actions is ingrained in the diversity of neurons and how they are organized into functional circuit modules, yet our knowledge of the molecular underpinning of motor circuit modularity remains limited. Here we use adult zebrafish to link the molecular diversity of motoneurons (MNs) and the rhythm-generating V2a interneurons (INs) with the modular circuit organization that is responsible for changes in locomotor speed. We show that the molecular diversity of MNs and V2a INs reflects their functional segregation into slow, intermediate or fast subtypes. Furthermore, we reveal shared molecular signatures between V2a INs and MNs of the three speed circuit modules. Overall, by characterizing how the molecular diversity of MNs and V2a INs relates to their function, connectivity and behavior, our study provides important insights not only into the molecular mechanisms for neuronal and circuit diversity for locomotor flexibility but also for charting circuits for motor actions in general.
DOI: 10.1038/s41593-023-01479-1
Source: https://www.nature.com/articles/s41593-023-01479-1
Nature Neuroscience:《自然—神经科学》,创刊于1998年。隶属于施普林格·自然出版集团,最新IF:28.771
官方网址:https://www.nature.com/neuro/
投稿链接:https://mts-nn.nature.com/cgi-bin/main.plex
本期文章:《自然—神经科学》:Online/在线发表
