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昼夜节律输出神经元中神经肽依赖性的峰电位时间精度与可塑性

Neuropeptide-Dependent Spike Time Precision and Plasticity in Circadian Output Neurons.

作者信息

Chong Bryan, Kumar Vipin, Nguyen Dieu Linh, Hopkins Makenzie A, Ferry Faith S, Spera Lucia K, Paul Elizabeth M, Hutson Anelise N, Tabuchi Masashi

机构信息

Department of Neurosciences, Case Western Reserve University School of Medicine, Cleveland, Ohio, USA.

出版信息

Eur J Neurosci. 2025 Mar;61(5):e70037. doi: 10.1111/ejn.70037.

DOI:10.1111/ejn.70037
PMID:40080910
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11906214/
Abstract

Circadian rhythms influence various physiological and behavioral processes such as sleep-wake cycles, hormone secretion, and metabolism. In Drosophila, an important set of circadian output neurons is called pars intercerebralis (PI) neurons, which receive input from specific clock neurons called DN1. These DN1 neurons can further be subdivided into functionally and anatomically distinctive anterior (DN1a) and posterior (DN1p) clusters. The neuropeptide diuretic hormones 31 (Dh31) and 44 (Dh44) are the insect neuropeptides known to activate PI neurons to control activity rhythms. However, the neurophysiological basis of how Dh31 and Dh44 affect circadian clock neural coding mechanisms underlying sleep in Drosophila is not well understood. Here, we identify Dh31/Dh44-dependent spike time precision and plasticity in PI neurons. We first find that a mixture of Dh31 and Dh44 enhanced the firing of PI neurons, compared to the application of Dh31 alone and Dh44 alone. We next find that the application of synthesized Dh31 and Dh44 affects membrane potential dynamics of PI neurons in the precise timing of the neuronal firing through their synergistic interaction, possibly mediated by calcium-activated potassium channel conductance. Further, we characterize that Dh31/Dh44 enhances postsynaptic potentials in PI neurons. Together, these results suggest multiplexed neuropeptide-dependent spike time precision and plasticity as circadian clock neural coding mechanisms underlying sleep in Drosophila.

摘要

昼夜节律影响各种生理和行为过程,如睡眠-觉醒周期、激素分泌和新陈代谢。在果蝇中,一组重要的昼夜节律输出神经元被称为脑间部(PI)神经元,它们接收来自特定时钟神经元DN1的输入。这些DN1神经元可进一步细分为功能和解剖学上不同的前部(DN1a)和后部(DN1p)集群。神经肽利尿激素31(Dh31)和44(Dh44)是已知能激活PI神经元以控制活动节律的昆虫神经肽。然而,Dh31和Dh44如何影响果蝇睡眠背后的昼夜节律神经编码机制的神经生理学基础尚不清楚。在这里,我们确定了PI神经元中Dh31/Dh44依赖性的尖峰时间精度和可塑性。我们首先发现,与单独应用Dh31和单独应用Dh44相比,Dh31和Dh44的混合物增强了PI神经元的放电。接下来我们发现,合成的Dh31和Dh44的应用通过它们的协同相互作用,可能由钙激活钾通道电导介导,在神经元放电的精确时间影响PI神经元的膜电位动态。此外,我们还发现Dh31/Dh44增强了PI神经元的突触后电位。总之,这些结果表明,多重神经肽依赖性的尖峰时间精度和可塑性是果蝇睡眠背后的昼夜节律神经编码机制。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/091b/11906214/ea38b30e3ede/EJN-61-0-g003.jpg
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本文引用的文献

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A line attractor encoding a persistent internal state requires neuropeptide signaling.一条吸引线编码一个持久的内部状态需要神经肽信号。
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