当复杂的神经元结构可能无关紧要时。

When complex neuronal structures may not matter.

作者信息

Otopalik Adriane G, Sutton Alexander C, Banghart Matthew, Marder Eve

机构信息

Volen Center, Biology Department, Brandeis University, Waltham, United States.

Department of Neurobiology, Harvard Medical School, Boston, United States.

出版信息

Elife. 2017 Feb 6;6:e23508. doi: 10.7554/eLife.23508.

DOI:10.7554/eLife.23508

PMID:28165322

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5323043/

Abstract

Much work has explored animal-to-animal variability and compensation in ion channel expression. Yet, little is known regarding the physiological consequences of morphological variability. We quantify animal-to-animal variability in cable lengths (CV = 0.4) and branching patterns in the Gastric Mill (GM) neuron, an identified neuron type with highly-conserved physiological properties in the crustacean stomatogastric ganglion (STG) of We examined passive GM electrotonic structure by measuring the amplitudes and apparent reversal potentials (Es) of inhibitory responses evoked with focal glutamate photo-uncaging in the presence of TTX. Apparent Es were relatively invariant across sites (mean CV ± SD = 0.04 ± 0.01; 7-20 sites in each of 10 neurons), which ranged between 100-800 µm from the somatic recording site. Thus, GM neurons are remarkably electrotonically compact (estimated λ > 1.5 mm). Electrotonically compact structures, in consort with graded transmission, provide an elegant solution to observed morphological variability in the STG.

摘要

许多研究探讨了离子通道表达中的动物个体差异和补偿现象。然而，关于形态变异的生理后果却知之甚少。我们量化了胃磨神经元（GM）电缆长度（变异系数CV = 0.4）和分支模式的个体差异，胃磨神经元是一种已确定的神经元类型，在龙虾口胃神经节（STG）中具有高度保守的生理特性。我们通过在TTX存在的情况下测量局灶性谷氨酸光解笼引发的抑制性反应的幅度和表观反转电位（Es），来研究GM神经元的被动电紧张结构。表观Es在不同位点相对稳定（平均CV±标准差= 0.04±0.01；10个神经元中每个神经元有7 - 20个位点），这些位点距离体细胞记录位点100 - 800微米。因此，GM神经元在电紧张方面非常紧密（估计λ> 1.5毫米）。电紧张紧密结构与分级传递相结合，为STG中观察到的形态变异提供了一个优雅的解决方案。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/5360/5323043/6c5c2419e4b1/elife-23508-fig1.jpg

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当复杂的神经元结构可能无关紧要时。

When complex neuronal structures may not matter.

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