Micro-electrode array recording of extracellular electrical potentials of liquid static surface fermented Hericium erinaceus

IF 2 4区生物学 Q2 BIOLOGY

Biosystems Pub Date : 2024-08-17 DOI:10.1016/j.biosystems.2024.105298

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Abstract

Hericium erinaceus is a basidiomycetes fungus with previously uncharacterised extracellular electrophysiology. Here, we present results of recordings of the electrical potentials of fungal biofilms of this species using microelectrode arrays (MEAs). In particular, we focused on modelling the temporal and spatial progression of the low frequency ( $\leq$ 1 Hz) potentials. Culture media control studies showed that the electrical potential activity results from the growth and subsequent spiking behaviours of the mycelium extracellular matrices. An antifungal assay using nystatin suspension, 10,000 unit/mL in DPBS, provided evidence for the biological origin of electrical potentials due to targeting of the selective permeability of the cell membrane and subsequent cessation of electrical activity. Conversely, injection of L-glutamic acid increased the combined multi-channel mean firing rate from 0.04 Hz to 0.1 Hz. Analysis of bursting and spatial propagation of the extracellular signals are also presented.

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微电极阵列记录液体静态表面发酵草本植物的细胞外电位

Hericium erinaceus 是一种担子菌纲真菌，其细胞外电生理学特征以前从未被描述过。在此，我们展示了使用微电极阵列（MEA）记录该真菌生物膜电位的结果。我们特别关注低频（≤ 1 Hz）电位的时间和空间进展模型。培养基控制研究表明，电位活动源于菌丝胞外基质的生长和随后的尖峰行为。在 DPBS 中使用 10,000 单位/毫升的 Nystatin 悬浮液进行的抗真菌试验证明，电位的生物来源是细胞膜的选择渗透性和随后的电活动停止。相反，注射左旋谷氨酸可将多通道联合平均发射率从 0.04 Hz 提高到 0.1 Hz。此外，还对细胞外信号的爆发和空间传播进行了分析。

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

Biosystems 生物-生物学

CiteScore

3.70

自引率

18.80%

发文量

129

审稿时长

34 days

期刊介绍： BioSystems encourages experimental, computational, and theoretical articles that link biology, evolutionary thinking, and the information processing sciences. The link areas form a circle that encompasses the fundamental nature of biological information processing, computational modeling of complex biological systems, evolutionary models of computation, the application of biological principles to the design of novel computing systems, and the use of biomolecular materials to synthesize artificial systems that capture essential principles of natural biological information processing.