Location analysis of presynaptically active and silent synapses in single-cultured hippocampal neurons

IF 3.4 3区医学 Q2 NEUROSCIENCES

Frontiers in Neural Circuits Pub Date : 2024-04-23 DOI:10.3389/fncir.2024.1358570

Otoya Kitaoka, Kohei Oyabu, Kaori Kubota, Takuya Watanabe, Satoru Kondo, Teppei Matsui, S. Katsurabayashi, Katsunori Iwasaki

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引用次数: 0

Abstract

A morphologically present but non-functioning synapse is termed a silent synapse. Silent synapses are categorized into “postsynaptically silent synapses,” where AMPA receptors are either absent or non-functional, and “presynaptically silent synapses,” where neurotransmitters cannot be released from nerve terminals. The presence of presynaptically silent synapses remains enigmatic, and their physiological significance is highly intriguing. In this study, we examined the distribution and developmental changes of presynaptically active and silent synapses in individual neurons. Our findings show a gradual increase in the number of excitatory synapses, along with a corresponding decrease in the percentage of presynaptically silent synapses during neuronal development. To pinpoint the distribution of presynaptically active and silent synapses, i.e., their positional information, we employed Sholl analysis. Our results indicate that the distribution of presynaptically silent synapses within a single neuron does not exhibit a distinct pattern during synapse development in different distance from the cell body. However, irrespective of neuronal development, the proportion of presynaptically silent synapses tends to rise as the projection site moves farther from the cell body, suggesting that synapses near the cell body may exhibit higher synaptic transmission efficiency. This study represents the first observation of changes in the distribution of presynaptically active and silent synapses within a single neuron.

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单培养海马神经元突触前活跃和沉默突触的位置分析

形态上存在但无功能的突触被称为沉默突触。沉默突触分为 "突触后沉默突触 "和 "突触前沉默突触"，前者的 AMPA 受体不存在或不起作用，后者的神经递质不能从神经末梢释放。突触前沉默突触的存在仍然是一个谜，其生理意义也非常引人关注。在这项研究中，我们考察了单个神经元中突触前活跃突触和沉默突触的分布和发育变化。我们的研究结果表明，在神经元发育过程中，兴奋性突触的数量逐渐增加，而突触前沉默突触的比例则相应减少。为了精确定位突触前活跃和沉默突触的分布，即它们的位置信息，我们采用了 Sholl 分析法。我们的结果表明，突触前沉默突触在单个神经元内的分布在突触发育过程中与细胞体的不同距离并不表现出明显的模式。然而，无论神经元的发育如何，突触前沉默突触的比例随着投射点远离细胞体而呈上升趋势，这表明靠近细胞体的突触可能表现出更高的突触传递效率。这项研究首次观察到单个神经元内突触前活跃突触和沉默突触分布的变化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Frontiers in Neural Circuits NEUROSCIENCES-

CiteScore

6.00

自引率

5.70%

发文量

135

审稿时长

4-8 weeks

期刊介绍： Frontiers in Neural Circuits publishes rigorously peer-reviewed research on the emergent properties of neural circuits - the elementary modules of the brain. Specialty Chief Editors Takao K. Hensch and Edward Ruthazer at Harvard University and McGill University respectively, are supported by an outstanding Editorial Board of international experts. This multidisciplinary open-access journal is at the forefront of disseminating and communicating scientific knowledge and impactful discoveries to researchers, academics and the public worldwide. Frontiers in Neural Circuits launched in 2011 with great success and remains a "central watering hole" for research in neural circuits, serving the community worldwide to share data, ideas and inspiration. Articles revealing the anatomy, physiology, development or function of any neural circuitry in any species (from sponges to humans) are welcome. Our common thread seeks the computational strategies used by different circuits to link their structure with function (perceptual, motor, or internal), the general rules by which they operate, and how their particular designs lead to the emergence of complex properties and behaviors. Submissions focused on synaptic, cellular and connectivity principles in neural microcircuits using multidisciplinary approaches, especially newer molecular, developmental and genetic tools, are encouraged. Studies with an evolutionary perspective to better understand how circuit design and capabilities evolved to produce progressively more complex properties and behaviors are especially welcome. The journal is further interested in research revealing how plasticity shapes the structural and functional architecture of neural circuits.