Keyao Long, Wanyue Xu, Xun Miao, Su Wang, Menglong Rui
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引用次数: 0
Abstract
Over the lifespan of an individual, brain function requires adjustments in response to environmental changes and learning experiences. During early development, neurons overproduce neurite branches, and neuronal pruning removes the unnecessary neurite branches to make a more accurate neural circuit. Drosophila motoneurons prune their intermediate axon bundles rather than the terminal neuromuscular junction (NMJ) by degeneration, which provides a unique advantage for studying axon pruning. The pruning process of motor axon bundles can be directly analyzed by real-time imaging, and this protocol provides a straightforward method for monitoring the developmental process of Drosophila motor neurons using live cell imaging. Key features • Long-range projecting axon bundles of Drosophila motor neurons extending from soma on the ventral nerve cord (VNC) undergo degeneration rather than retraction during metamorphosis. • The pruning process of motor axon bundles can be directly observed by real-time live-cell imaging. • The complete clearance of axon bundles occurs approximately 22 h after pupal formation (22 h APF). • Mushroom body (MB) γ neuron axon pruning regulatory genes are conserved for motor neurons.
在一个人的一生中,大脑功能需要根据环境变化和学习经验进行调整。在早期发育过程中,神经元产生过多的神经突分支,神经元修剪去除不必要的神经突分支以形成更精确的神经回路。果蝇运动神经元通过退化对中间轴突束进行修剪,而不是对末梢神经肌肉连接(NMJ)进行修剪,这为研究轴突修剪提供了独特的优势。通过实时成像可以直接分析运动轴突束的修剪过程,该方案为利用活细胞成像监测果蝇运动神经元的发育过程提供了一种简单的方法。•在变态过程中,从腹侧神经索(VNC)的胞体延伸出来的果蝇运动神经元的远程突出轴突束发生变性而不是回缩。•实时活细胞成像可直接观察运动轴突束修剪过程。•轴突束的完全清除大约发生在蛹形成后22小时(22 h APF)。•蘑菇体(MB) γ神经元轴突修剪调控基因在运动神经元中是保守的。
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