Specific inhibition and disinhibition in the higher-order structure of a cortical connectome.

IF 2.9 2区 医学 Q2 NEUROSCIENCES
Michael W Reimann, Daniela Egas Santander, András Ecker, Eilif B Muller
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引用次数: 0

Abstract

Neurons are thought to act as parts of assemblies with strong internal excitatory connectivity. Conversely, inhibition is often reduced to blanket inhibition with no targeting specificity. We analyzed the structure of excitation and inhibition in the MICrONS $mm^{3}$ dataset, an electron microscopic reconstruction of a piece of cortical tissue. We found that excitation was structured around a feed-forward flow in large non-random neuron motifs with a structure of information flow from a small number of sources to a larger number of potential targets. Inhibitory neurons connected with neurons in specific sequential positions of these motifs, implementing targeted and symmetrical competition between them. None of these trends are detectable in only pairwise connectivity, demonstrating that inhibition is structured by these large motifs. While descriptions of inhibition in cortical circuits range from non-specific blanket-inhibition to targeted, our results describe a form of targeting specificity existing in the higher-order structure of the connectome. These findings have important implications for the role of inhibition in learning and synaptic plasticity.

大脑皮层连接体高阶结构中的特异性抑制和抑制消失
神经元被认为是具有强大内部兴奋连接的集合体的一部分。相反,抑制通常被简化为没有靶向特异性的全面抑制。我们分析了 MICrONS $mm^{3}$ 数据集中的兴奋和抑制结构,该数据集是一块大脑皮层组织的电子显微镜重建。我们发现,兴奋的结构是围绕大型非随机神经元图案的前馈流,其结构是信息流从少数来源流向更多潜在目标。抑制性神经元与这些图案中特定顺序位置的神经元相连接,在它们之间实施有针对性的对称竞争。仅在成对连接中无法检测到这些趋势,这表明抑制是由这些大型图案构成的。虽然对大脑皮层回路中抑制作用的描述从非特异性的全面抑制到有针对性的抑制不等,但我们的结果描述了存在于连接组高阶结构中的一种有针对性的特异性。这些发现对抑制在学习和突触可塑性中的作用具有重要意义。
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来源期刊
Cerebral cortex
Cerebral cortex 医学-神经科学
CiteScore
6.30
自引率
8.10%
发文量
510
审稿时长
2 months
期刊介绍: Cerebral Cortex publishes papers on the development, organization, plasticity, and function of the cerebral cortex, including the hippocampus. Studies with clear relevance to the cerebral cortex, such as the thalamocortical relationship or cortico-subcortical interactions, are also included. The journal is multidisciplinary and covers the large variety of modern neurobiological and neuropsychological techniques, including anatomy, biochemistry, molecular neurobiology, electrophysiology, behavior, artificial intelligence, and theoretical modeling. In addition to research articles, special features such as brief reviews, book reviews, and commentaries are included.
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