Neural pathways in the pallial nerve and arm nerve cord revealed by neurobiotin backfilling in the cephalopod mollusk Octopus vulgaris.

Q4 Neuroscience Invertebrate Neuroscience Pub Date : 2019-05-10 DOI:10.1007/s10158-019-0225-y

Pamela Imperadore, Maria Grazia Lepore, Giovanna Ponte, Hans-Joachim Pflüger, Graziano Fiorito

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引用次数: 8

Abstract

Here, we report the findings after application of neurobiotin tracing to pallial and stellar nerves in the mantle of the cephalopod mollusk Octopus vulgaris and to the axial nerve cord in its arm. Neurobiotin backfilling is a known technique in other molluscs, but it is applied to octopus for the first time to be best of our knowledge. Different neural tracing techniques have been carried out in cephalopods to study the intricate neural connectivity of their nervous system, but mapping the nervous connections in this taxon is still incomplete, mainly due to the absence of a reliable tracing method allowing whole-mount imaging. In our experiments, neurobiotin backfilling allowed: (1) imaging of large/thick samples (larger than 2 mm) through optical clearing; (2) additional application of immunohistochemistry on the backfilled tissues, allowing identification of neural structures by coupling of a specific antibody. This work opens a series of future studies aimed to the identification of the neural diagram and connectome of octopus nervous system.

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头足类软体动物寻常章鱼神经生物素回填所揭示的苍白部神经和上臂神经索的神经通路。

在这里，我们报告了应用神经生物素追踪头足类软体动物章鱼(Octopus vulgaris)的外膜和星状神经及其手臂的轴神经束的结果。神经生物素回填在其他软体动物中是一种已知的技术，但据我们所知，它首次应用于章鱼。不同的神经追踪技术已经在头足类动物中进行，以研究其神经系统复杂的神经连接，但在这一分类单元中绘制神经连接仍然不完整，主要是由于缺乏可靠的追踪方法来实现全挂成像。在我们的实验中，神经生物素回填允许:(1)通过光学清除对大/厚样品(大于2mm)成像;(2)在回填组织上进一步应用免疫组织化学，通过偶联特异性抗体来识别神经结构。本研究为章鱼神经系统的神经图和连接组的识别开辟了一系列的研究方向。

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Invertebrate Neuroscience NEUROSCIENCES-

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>12 weeks

期刊介绍： Invertebrate Neurosciences publishes peer-reviewed original articles, reviews and technical reports describing recent advances in the field of invertebrate neuroscience. The journal reports on research that exploits the simplicity and experimental tractability of the invertebrate preparations to underpin fundamental advances in neuroscience. Articles published in Invertebrate Neurosciences serve to highlight properties of signalling in the invertebrate nervous system that may be exploited in the field of antiparisitics, molluscicides and insecticides. Aspects of particular interest include: Functional analysis of the invertebrate nervous system; Molecular neuropharmacology and toxicology; Neurogenetics and genomics; Functional anatomy; Neurodevelopment; Neuronal networks; Molecular and cellular mechanisms of behavior and behavioural plasticity.