Variability of quantal synaptic currents in thalamocortical neurons

M. Neubig , A. Destexhe , T.J. Sejnowski
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引用次数: 2

Abstract

Broad amplitude variability and skewed distributions are characteristic features of quantal synaptic currents (minis) at central synapses. The relative contributions of the various underlying sources are still debated. Through computational models of thalamocortical neurons, we separated intra- from extra-synaptic sources. Our simulations indicate that the external factors of local input resistance and dendritic filtering generate equally small amounts of negatively skewed synaptic variability. The ability of these two factors to reduce positive skew increased as their contribution to variability increased, which in control trials for morphological, biophysical, and experimental parameters never exceeded 10% of the range. With these dendritic factors ruled out, we tested multiple release models, which led to distributions with clearly non-physiological multiple peaks. We conclude that intra-synaptic organization is the primary determinant of synaptic variability in thalamocortical neurons and, due to extra-synaptic mechanisms, is more potent than the data suggested. Thalamortical neurons, especially in rodents, constitute a remarkably favorable system for molecular genetic studies of synaptic variability and its functional consequence.

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丘脑皮质神经元量子突触电流的变异性
宽振幅变异性和偏斜分布是中央突触量子突触电流(minis)的特征。各种潜在来源的相对贡献仍在争论中。通过丘脑皮质神经元的计算模型,我们分离了突触内和突触外的来源。我们的模拟表明,局部输入阻力和树突过滤的外部因素产生同样少量的负偏斜突触变异性。这两个因素减少正偏度的能力随着其对变异性的贡献的增加而增加,在形态学、生物物理和实验参数的对照试验中,变异性从未超过范围的10%。排除这些树突因子后,我们测试了多个释放模型,得到了明显的非生理多峰分布。我们得出结论,突触内组织是丘脑皮质神经元突触变异性的主要决定因素,并且由于突触外机制,比数据显示的更有效。丘脑神经元,尤其是啮齿类动物的丘脑神经元,为突触变异性及其功能后果的分子遗传学研究提供了一个非常有利的系统。
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