一条控制果蝇气味追踪的中枢神经通路。

A central neural pathway controlling odor tracking in Drosophila.

作者信息

Slater Gemma, Levy Peter, Chan K L Andrew, Larsen Camilla

机构信息

Medical Research Council Centre for Developmental Neurobiology, King's College London, New Hunt's House, Guy's Campus, London SE1 1UL, United Kingdom, and.

Institute of Pharmaceutical Science, King's College, London SE1 9NH, United Kingdom.

出版信息

J Neurosci. 2015 Feb 4;35(5):1831-48. doi: 10.1523/JNEUROSCI.2331-14.2015.

DOI:10.1523/JNEUROSCI.2331-14.2015

PMID:25653345

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4315823/

Abstract

Chemotaxis is important for the survival of most animals. How the brain translates sensory input into motor output beyond higher olfactory processing centers is largely unknown. We describe a group of excitatory neurons, termed Odd neurons, which are important for Drosophila larval chemotaxis. Odd neurons receive synaptic input from projection neurons in the calyx of the mushroom body and project axons to the central brain. Functional imaging shows that some of the Odd neurons respond to odor. Larvae in which Odd neurons are silenced are less efficient at odor tracking than controls and sample the odor space more frequently. Larvae in which the excitability of Odd neurons is increased are better at odor intensity discrimination and odor tracking. Thus, the Odd neurons represent a distinct pathway that regulates the sensitivity of the olfactory system to odor concentrations, demonstrating that efficient chemotaxis depends on processing of odor strength downstream of higher olfactory centers.

摘要

趋化作用对大多数动物的生存至关重要。大脑如何在高等嗅觉处理中枢之外将感觉输入转化为运动输出，在很大程度上尚不清楚。我们描述了一组兴奋性神经元，称为奇数神经元，它们对果蝇幼虫的趋化作用很重要。奇数神经元从蘑菇体花萼中的投射神经元接收突触输入，并将轴突投射到中枢脑。功能成像显示，一些奇数神经元对气味有反应。奇数神经元被沉默的幼虫在气味追踪方面比对照组效率更低，并且更频繁地对气味空间进行采样。奇数神经元兴奋性增加的幼虫在气味强度辨别和气味追踪方面表现更好。因此，奇数神经元代表了一条独特的通路，可调节嗅觉系统对气味浓度的敏感性，这表明有效的趋化作用取决于高等嗅觉中枢下游对气味强度的处理。

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