新皮层的突触结构和重构是时空选择性的。

IF 1.2 4区 医学 Q3 ANATOMY & MORPHOLOGY
Jaerin Sohn
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引用次数: 0

摘要

大脑计算依赖于神经网络。神经元延伸轴突,如树突和轴突,这些轴突的接触形成化学突触,是中枢神经系统中信号传输的生物学基础。单个神经元的输出可以影响轴突扩散范围内的其他神经元,而单个神经元的活动可以受到其体树突场中传入的影响。因此,形态学特征结合了每个神经元可以发挥的功能作用。此外,神经元之间的突触连接表现出基于突触前和突触后神经元特征的偏好。在这里,作者回顾了新皮层中的“空间”和“时间”连接选择性。新皮质回路的组织学描述主要取决于细胞类型的分类,基因工程技术的发展允许树突和轴突以及胞体的细胞类型特异性可视化。使用特定细胞群体的遗传标记,结合免疫组织化学和亚细胞空间分辨率的成像,我们揭示了皮层布线的“空间选择性”,其中突触以突触前细胞类型特异性的方式不均匀分布在亚细胞体树突结构域上。此外,学习中的皮层突触动力学表现出突触前细胞类型依赖的“时间选择性”:皮层突触在学习阶段仅短暂出现,而学习诱导的新丘脑皮层突触持续存在,这表明不同的回路可能监督学习特异性的短暂突触和记忆特异性的不朽突触的形成。神经回路中空间配置和时间重构的选择性可能支配新皮层的不同功能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Synaptic configuration and reconfiguration in the neocortex are spatiotemporally selective

Synaptic configuration and reconfiguration in the neocortex are spatiotemporally selective

Brain computation relies on the neural networks. Neurons extend the neurites such as dendrites and axons, and the contacts of these neurites that form chemical synapses are the biological basis of signal transmissions in the central nervous system. Individual neuronal outputs can influence the other neurons within the range of the axonal spread, while the activities of single neurons can be affected by the afferents in their somatodendritic fields. The morphological profile, therefore, binds the functional role each neuron can play. In addition, synaptic connectivity among neurons displays preference based on the characteristics of presynaptic and postsynaptic neurons. Here, the author reviews the “spatial” and “temporal” connection selectivity in the neocortex. The histological description of the neocortical circuitry depends primarily on the classification of cell types, and the development of gene engineering techniques allows the cell type-specific visualization of dendrites and axons as well as somata. Using genetic labeling of particular cell populations combined with immunohistochemistry and imaging at a subcellular spatial resolution, we revealed the “spatial selectivity” of cortical wirings in which synapses are non-uniformly distributed on the subcellular somatodendritic domains in a presynaptic cell type-specific manner. In addition, cortical synaptic dynamics in learning exhibit presynaptic cell type-dependent “temporal selectivity”: corticocortical synapses appear only transiently during the learning phase, while learning-induced new thalamocortical synapses persist, indicating that distinct circuits may supervise learning-specific ephemeral synapse and memory-specific immortal synapse formation. The selectivity of spatial configuration and temporal reconfiguration in the neural circuitry may govern diverse functions in the neocortex.

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来源期刊
Anatomical Science International
Anatomical Science International 医学-解剖学与形态学
CiteScore
2.80
自引率
8.30%
发文量
50
审稿时长
>12 weeks
期刊介绍: The official English journal of the Japanese Association of Anatomists, Anatomical Science International (formerly titled Kaibogaku Zasshi) publishes original research articles dealing with morphological sciences. Coverage in the journal includes molecular, cellular, histological and gross anatomical studies on humans and on normal and experimental animals, as well as functional morphological, biochemical, physiological and behavioral studies if they include morphological analysis.
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