The cellular zeta potential: cell electrophysiology beyond the membrane.

IF 1.5 4区 生物学 Q4 CELL BIOLOGY
Michael Pycraft Hughes
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引用次数: 0

Abstract

The standard model of the cell membrane potential Vm describes it as arising from diffusion currents across a membrane with a constant electric field, with zero electric field outside the cell membrane. However, the influence of Vm has been shown to extend into the extracellular space where it alters the cell's ζ-potential, the electrical potential measured a few nm from the cell surface which defines how the cell interacts with charged entities in its environment, including ions, molecules, and other cells. The paradigm arising from surface science is that the ζ-potential arises only from fixed membrane surface charge, and has consequently received little interest. However, if the ζ-potential can mechanistically and dynamically change by alteration of Vm, it allows the cell to dynamically alter cell-cell and cell-molecule interactions and may explain previously unexplained electrophysiological behaviours. Whilst the two potentials Vm and ζ are rarely reported together, they are occasionally described in different studies for the same cell type. By considering published data on these parameters across multiple cell types, as well as incidences of unexplained but seemingly functional Vm changes correlating with changes in cell behaviour, evidence is presented that this may play a functional role in the physiology of red blood cells, macrophages, platelets, sperm, ova, bacteria and cancer. Understanding how these properties will improve understanding of the role of electrical potentials and charges in the regulation of cell function and in the way in which cells interact with their environment. Insight  The zeta (ζ) potential is the electrical potential a few nm beyond the surface of any suspensoid in water. Whilst typically assumed to arise only from fixed charges on the cell surface, recent and historical evidence shows a strong link to the cell's membrane potential Vm, which the cell can alter mechanistically through the use of ion channels. Whilst these two potentials have rarely been studied simultaneously, this review collates data across multiple studies reporting Vm, ζ-potential, electrical properties of changes in cell behaviour. Collectively, this points to Vm-mediated ζ-potential playing a significant role in the physiology and activity of blood cells, immune response, developmental biology and egg fertilization, and cancer among others.

细胞泽塔电位:超越膜的细胞电生理学。
细胞膜电位 Vm 的标准模型将其描述为产生于恒定电场下的跨膜扩散电流,细胞膜外的电场为零。然而,Vm 的影响已被证明可延伸至细胞外空间,它改变了细胞的 ζ 电位,即在距离细胞表面几纳米处测得的电位,它决定了细胞如何与其环境中的带电实体(包括离子、分子和其他细胞)相互作用。表面科学的范式认为,ζ电位仅由固定的膜表面电荷产生,因此很少引起人们的兴趣。然而,如果ζ电位能通过改变 Vm 发生机械和动态的变化,就能使细胞动态地改变细胞-细胞和细胞-分子之间的相互作用,并能解释以前无法解释的电生理行为。虽然 Vm 和 ζ 这两个电位很少被同时报道,但它们偶尔会在针对同一细胞类型的不同研究中被描述。通过考虑已发表的有关多种细胞类型的这些参数的数据,以及无法解释但似乎具有功能性的 Vm 变化与细胞行为变化相关的事件,有证据表明这可能在红细胞、巨噬细胞、血小板、精子、卵子、细菌和癌症的生理学中发挥功能性作用。了解这些特性将有助于更好地理解电位和电荷在调节细胞功能以及细胞与环境相互作用方面的作用。洞察力 zeta (ζ)电位是指水中任何悬浮体表面外几纳米处的电位。虽然人们通常认为zeta电位仅来自细胞表面的固定电荷,但最近和历史上的证据表明,zeta电位与细胞的膜电位Vm有密切联系,细胞可通过使用离子通道从机制上改变膜电位Vm。虽然这两种电位很少被同时研究,但本综述整理了报告 Vm、ζ电位、细胞行为变化的电特性的多项研究数据。总体而言,这表明 Vm 介导的ζ电位在血细胞的生理和活动、免疫反应、发育生物学和卵子受精以及癌症等方面发挥着重要作用。
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
Integrative Biology
Integrative Biology 生物-细胞生物学
CiteScore
4.90
自引率
0.00%
发文量
15
审稿时长
1 months
期刊介绍: Integrative Biology publishes original biological research based on innovative experimental and theoretical methodologies that answer biological questions. The journal is multi- and inter-disciplinary, calling upon expertise and technologies from the physical sciences, engineering, computation, imaging, and mathematics to address critical questions in biological systems. Research using experimental or computational quantitative technologies to characterise biological systems at the molecular, cellular, tissue and population levels is welcomed. Of particular interest are submissions contributing to quantitative understanding of how component properties at one level in the dimensional scale (nano to micro) determine system behaviour at a higher level of complexity. Studies of synthetic systems, whether used to elucidate fundamental principles of biological function or as the basis for novel applications are also of interest.
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