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靶向中央复合体的细胞类型特异性驱动系及其在研究神经肽表达和睡眠调节中的应用。

Cell type-specific driver lines targeting the central complex and their use to investigate neuropeptide expression and sleep regulation.

作者信息

Wolff Tanya, Eddison Mark, Chen Nan, Nern Aljoscha, Sundaramurthi Preeti, Sitaraman Divya, Rubin Gerald M

机构信息

Janelia Research Campus, Howard Hughes Medical Institute, Ashburn VA 20147.

Department of Psychology, College of Science, California State University, Hayward, California 94542.

出版信息

bioRxiv. 2025 Jan 24:2024.10.21.619448. doi: 10.1101/2024.10.21.619448.

DOI:10.1101/2024.10.21.619448
PMID:39484527
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11526984/
Abstract

The central complex (CX) plays a key role in many higher-order functions of the insect brain including navigation and activity regulation. Genetic tools for manipulating individual cell types, and knowledge of what neurotransmitters and neuromodulators they express, will be required to gain mechanistic understanding of how these functions are implemented. We generated and characterized split-GAL4 driver lines that express in individual or small subsets of about half of CX cell types. We surveyed neuropeptide and neuropeptide receptor expression in the central brain using fluorescent hybridization. About half of the neuropeptides we examined were expressed in only a few cells, while the rest were expressed in dozens to hundreds of cells. Neuropeptide receptors were expressed more broadly and at lower levels. Using our GAL4 drivers to mark individual cell types, we found that 51 of the 85 CX cell types we examined expressed at least one neuropeptide and 21 expressed multiple neuropeptides. Surprisingly, all co-expressed a small neurotransmitter. Finally, we used our driver lines to identify CX cell types whose activation affects sleep, and identified other central brain cell types that link the circadian clock to the CX. The well-characterized genetic tools and information on neuropeptide and neurotransmitter expression we provide should enhance studies of the CX.

摘要

中央复合体(CX)在昆虫大脑的许多高阶功能中起着关键作用,包括导航和活动调节。要深入了解这些功能是如何实现的,就需要有用于操纵单个细胞类型的遗传工具,以及了解它们所表达的神经递质和神经调质。我们构建并鉴定了在大约一半的CX细胞类型的单个细胞或小细胞亚群中表达的分裂型GAL4驱动系。我们利用荧光杂交技术,对中枢神经系统中的神经肽和神经肽受体表达情况进行了调查。我们检测的神经肽中,约一半仅在少数细胞中表达,其余的则在数十到数百个细胞中表达。神经肽受体的表达范围更广,但水平较低。利用我们的GAL4驱动系来标记单个细胞类型,我们发现,在我们检测的85种CX细胞类型中,有51种表达至少一种神经肽,21种表达多种神经肽。令人惊讶的是,所有这些细胞都共表达一种小分子神经递质。最后,我们利用我们的驱动系来鉴定其激活会影响睡眠的CX细胞类型,并确定了将生物钟与CX联系起来的其他中枢脑细胞类型。我们提供的这些经过充分鉴定的遗传工具以及关于神经肽和神经递质表达的信息,应该会促进对CX的研究。

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