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嗅觉反应在投射神经元的组织中被编码。

Olfactory responses of are encoded in the organization of projection neurons.

机构信息

School of Computational Sciences, Korea Institute for Advanced Study, Seoul, Republic of Korea.

出版信息

Elife. 2022 Sep 29;11:e77748. doi: 10.7554/eLife.77748.

DOI:10.7554/eLife.77748
PMID:36173095
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9616568/
Abstract

The projection neurons (PNs), reconstructed from electron microscope (EM) images of the olfactory system, offer a detailed view of neuronal anatomy, providing glimpses into information flow in the brain. About 150 uPNs constituting 58 glomeruli in the antennal lobe (AL) are bundled together in the axonal extension, routing the olfactory signal received at AL to mushroom body (MB) calyx and lateral horn (LH). Here we quantify the neuronal organization in terms of the inter-PN distances and examine its relationship with the odor types sensed by . The homotypic uPNs that constitute glomeruli are tightly bundled and stereotyped in position throughout the neuropils, even though the glomerular PN organization in AL is no longer sustained in the higher brain center. Instead, odor-type dependent clusters consisting of multiple homotypes innervate the MB calyx and LH. Pheromone-encoding and hygro/thermo-sensing homotypes are spatially segregated in MB calyx, whereas two distinct clusters of food-related homotypes are found in LH in addition to the segregation of pheromone-encoding and hygro/thermo-sensing homotypes. We find that there are statistically significant associations between the spatial organization among a group of homotypic uPNs and certain stereotyped olfactory responses. Additionally, the signals from some of the tightly bundled homotypes converge to a specific group of lateral horn neurons (LHNs), which indicates that homotype (or odor type) specific integration of signals occurs at the synaptic interface between PNs and LHNs. Our findings suggest that before neural computation in the inner brain, some of the olfactory information are already encoded in the spatial organization of uPNs, illuminating that a certain degree of labeled-line strategy is at work in the olfactory system.

摘要

从嗅觉系统的电子显微镜 (EM) 图像重建的投射神经元 (PNs) 提供了神经元解剖结构的详细视图,使我们能够一窥大脑中的信息流。约 150 个构成触角叶 (AL) 中 58 个肾小球的 uPNs 捆绑在一起在轴突延伸中,将在 AL 接收的嗅觉信号路由到蘑菇体 (MB) 蕈形体和侧角 (LH)。在这里,我们根据 PN 之间的距离来量化神经元组织,并研究其与 感知的气味类型之间的关系。构成肾小球的同型 uPNs 在整个神经丛中紧密捆绑且位置固定,即使 AL 中的肾小球 PN 组织在更高的大脑中心不再维持。相反,由多个同型组成的气味类型依赖性簇支配 MB 蕈形体和 LH 的神经支配。信息素编码和吸湿/热敏同型在 MB 蕈形体中空间分离,而除了信息素编码和吸湿/热敏同型的分离之外,在 LH 中还发现了两个不同的与食物相关的同型簇。我们发现,一组同型 uPN 之间的空间组织与某些定型嗅觉反应之间存在统计学上显著的关联。此外,一些紧密捆绑的同型的信号汇聚到特定的一群侧角神经元 (LHNs),这表明在 PN 和 LHNs 之间的突触界面处发生了同型(或气味类型)特异性信号整合。我们的发现表明,在大脑内部进行神经计算之前,某些嗅觉信息已经在 uPN 的空间组织中进行了编码,这表明在嗅觉系统中已经采用了某种程度的标记线策略。

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