Membraneless physiology of the living cell. The past and the present

4open Pub Date : 2022-01-01 DOI:10.1051/fopen/2022013
Vladimir Vasilievich Matveev
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引用次数: 2

Abstract

Since the 1880s, the concept of compartmentalizing through membranes has taken a firm place in cell physiology and has defined the objects, methods, and goals of physiologists’ research for decades. A huge mass of biologists know about the important role of intra-membrane pumps, channels, and lipids, and various hypotheses about the origin of life often begin with explanations about how the lipid membrane occurred, without which it is impossible to imagine the origin of a living cell. Against this background, there was a dissonance of statements that there are membraneless organelles in the cell, the functions of which are rapidly expanding under our eyes. Physically, they are similar to coacervate droplets, which from time to time were used to explain the origin of life, and now the coacervates are being more and more often discussed when describing the physics of the nucleus and cytoplasm of modern cells. However, ideas about the coacervate nature of cytoplasm/protoplasm originated in the first half of the 19th Century, when the contents of cells were likened to jelly, but this approach gradually faded into the shadows. Nevertheless, limited research in this area continued and was completed in the form of a membraneless cell physiology. Now that the focus of attention has turned to membraneless compartmentalization, it’s time to remember the past. The sorption properties of proteins are the physical basis of membraneless cell because of water adsorbed by proteins changes the physical state of any biomolecular system, from supramolecular and subcellular structures to the cell as a whole. A thermodynamic aqueous phase is formed because adsorbed water does not mix with ordinary water and, in this cause, is separated from the surrounding solution in the form of a compartment. This article discusses the fundamental physical properties of such a phase – a biophase. As it turned out, the Meyer–Overton rule, which led to the idea of a lipid membrane, also applies to membraneless condensates.
活细胞的无膜生理学过去和现在
自19世纪80年代以来,通过膜进行区隔的概念在细胞生理学中占据了稳固的地位,并定义了几十年来生理学家研究的对象、方法和目标。大量的生物学家都知道膜内泵、通道和脂质的重要作用,关于生命起源的各种假设通常都是从解释脂质膜如何发生开始的,没有脂质膜就不可能想象活细胞的起源。在这种背景下,有一种说法是不一致的,即细胞中有无膜细胞器,其功能在我们的眼睛下迅速扩展。在物理上,它们类似于聚簇状液滴,聚簇状液滴有时被用来解释生命的起源,现在聚簇状液滴在描述现代细胞的细胞核和细胞质的物理特性时越来越经常被讨论。然而,关于细胞质/原生质凝聚性的想法起源于19世纪上半叶,当时细胞的内容物被比作果冻,但这种方法逐渐消失在阴影中。然而,这一领域的有限研究仍在继续,并以无膜细胞生理学的形式完成。现在注意力的焦点已经转向无膜区隔化,是时候记住过去了。蛋白质的吸附特性是无膜细胞的物理基础,因为蛋白质吸附的水改变了任何生物分子系统的物理状态,从超分子和亚细胞结构到整个细胞。热力学水相的形成是因为被吸附的水不与普通的水混合,在这个原因中,水以隔室的形式与周围的溶液分离。本文讨论了这种相——生物相的基本物理性质。事实证明,导致脂质膜概念的Meyer-Overton规则也适用于无膜冷凝物。
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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