Dimensionality reduction of neuronal degeneracy reveals two interfering physiological mechanisms.

IF 2.2 Q2 MULTIDISCIPLINARY SCIENCES PNAS nexus Pub Date : 2024-09-19 eCollection Date: 2024-10-01 DOI:10.1093/pnasnexus/pgae415

Arthur Fyon, Alessio Franci, Pierre Sacré, Guillaume Drion

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Abstract

Neuronal systems maintain stable functions despite large variability in their physiological components. Ion channel expression, in particular, is highly variable in neurons exhibiting similar electrophysiological phenotypes, which raises questions regarding how specific ion channel subsets reliably shape intrinsic properties of neurons. Here, we use detailed conductance-based modeling to explore how stable neuronal function is achieved despite variability in channel composition among neurons. Using dimensionality reduction, we uncover two principal dimensions in the channel conductance space that capture most of the variance of the observed variability. These two dimensions correspond to two sources of variability that originate from distinct physiologically relevant mechanisms underlying the regulation of neuronal activity, providing quantitative insights into how channel composition is linked to the electrophysiological activity of neurons. These insights allow us to understand and design a model-independent, reliable neuromodulation rule for variable neuronal populations.

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神经元退化的降维揭示了两种相互干扰的生理机制。

尽管神经元系统的生理成分变化很大，但它们仍能保持稳定的功能。尤其是离子通道的表达，在表现出相似电生理表型的神经元中变化很大，这就提出了特定离子通道子集如何可靠地塑造神经元内在特性的问题。在这里，我们利用详细的基于电导的建模来探索，尽管神经元之间的通道组成存在差异，但如何实现稳定的神经元功能。通过降维，我们发现了通道电导空间的两个主要维度，它们捕捉到了观察到的变异性的大部分方差。这两个维度对应于两种变异性来源，而这两种变异性来源于神经元活动调控的不同生理相关机制，这为我们提供了关于通道组成如何与神经元电生理活动相关联的定量见解。这些洞察力使我们能够理解并设计出一种独立于模型的、可靠的神经调控规则，用于可变的神经元群。

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