使用生物发光监测自由移动的果蝇幼虫的大脑活动和行为。

Monitoring brain activity and behaviour in freely moving Drosophila larvae using bioluminescence.

机构信息

Brainwave-Discovery Ltd., Edinburgh, Scotland, UK.

The University of Edinburgh, Edinburgh, Scotland, UK.

出版信息

Sci Rep. 2018 Jun 18;8(1):9246. doi: 10.1038/s41598-018-27043-7.

DOI:10.1038/s41598-018-27043-7

PMID:29915372

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6006295/

Abstract

We present a bioluminescence method, based on the calcium-reporter Aequorin (AEQ), that exploits targeted transgenic expression patterns to identify activity of specific neural groups in the larval Drosophila nervous system. We first refine, for intact but constrained larva, the choice of Aequorin transgene and method of delivery of the co-factor coelenterazine and assay the luminescence signal produced for different neural expression patterns and concentrations of co-factor, using standard photo-counting techniques. We then develop an apparatus that allows simultaneous measurement of this neural signal while video recording the crawling path of an unconstrained animal. The setup also enables delivery and measurement of an olfactory cue (CO) and we demonstrate the ability to record synchronized changes in Kenyon cell activity and crawling speed caused by the stimulus. Our approach is thus shown to be an effective and affordable method for studying the neural basis of behavior in Drosophila larvae.

摘要

我们提出了一种生物发光方法，基于钙报告蛋白 Aequorin（AEQ），该方法利用靶向转基因表达模式来识别幼虫果蝇神经系统中特定神经群的活性。我们首先针对完整但受限的幼虫，改进了 Aequorin 转基因和共因子 coelenterazine 的递送方法，并使用标准的光计数技术，针对不同的神经表达模式和共因子浓度，检测产生的发光信号。然后，我们开发了一种仪器，允许在对不受限制的动物进行视频记录的同时，同时测量这种神经信号。该设置还允许传递和测量嗅觉线索（CO），我们证明了记录由刺激引起的 Kenyon 细胞活性和爬行速度同步变化的能力。因此，我们的方法被证明是一种有效且经济实惠的方法，可用于研究果蝇幼虫行为的神经基础。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a355/6006295/97f68bbcd75c/41598_2018_27043_Fig1_HTML.jpg

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使用生物发光监测自由移动的果蝇幼虫的大脑活动和行为。

Monitoring brain activity and behaviour in freely moving Drosophila larvae using bioluminescence.

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