Synapse-to-synapse plasticity variability balanced to generate input-wide constancy of transmitter release

bioRxiv - Neuroscience Pub Date : 2024-09-12 DOI:10.1101/2024.09.11.612562

Krisha Aghi, Ryan Schultz, Zachary L. Newman, Philipe Mendonca, Dariya Bakshinska, Ehud Y. Isacoff

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Abstract

Basal synaptic strength can vary greatly between synapses formed by an individual neuron because of diverse probabilities of action potential (AP) evoked transmitter release (Pr). Optical quantal analysis on large numbers of identified Drosophila larval glutamatergic synapses shows that short-term plasticity (STP) also varies greatly between synapses made by an individual type I motor neuron (MN) onto a single body wall muscle. Synapses with high and low Pr and different forms and level of STP have a random spatial distribution in the MN nerve terminal, and ones with very different properties can be located within 200 nm of one other. While synapses start off with widely diverse basal Pr at low MN AP firing frequency and change Pr differentially when MN firing frequency increases, the overall distribution of Pr remains remarkably constant due to a balance between the numbers of synapses that facilitate and depress as well as their degree of change and basal synaptic weights. This constancy in transmitter release can ensure robustness across changing behavioral conditions.

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平衡突触间的可塑性变化，以产生整个输入范围内递质释放的恒定性

由于动作电位（AP）诱发递质释放（Pr）的概率不同，单个神经元所形成的突触之间的基础突触强度会有很大差异。对大量已识别的果蝇幼虫谷氨酸能突触进行的光学定量分析显示，单个 I 型运动神经元（MN）与单个体壁肌肉的突触之间的短期可塑性（STP）也存在很大差异。具有高、低 Pr 值以及不同形式和 STP 水平的突触在 MN 神经末梢中的空间分布是随机的，性质迥异的突触可能相距不到 200 纳米。虽然在 MN AP 发射频率较低时，突触开始时的基础 Pr 差异很大，当 MN 发射频率增加时，突触的 Pr 也会发生不同程度的变化，但由于促进和抑制突触的数量及其变化程度与基础突触权重之间的平衡，Pr 的总体分布仍然非常稳定。这种递质释放的恒定性可以确保在不断变化的行为条件下的稳健性。

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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bioRxiv - Neuroscience

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