The force-from-lipid principle and its origin, a 'what is true for E. coli is true for the elephant' refrain.

IF 1.8 4区 医学 Q3 GENETICS & HEREDITY
Boris Martinac, Ching Kung
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引用次数: 8

Abstract

The force-from-lipid (FFL) principle states that it is the lateral stretch force from the lipid membrane that ultimately opens mechanosensitive (MS) channels, not the external tether nor the internal cytoskeleton. Piezo channels for certain touch or proprioception and the hair-cell channels for hearing or balance apparently obey this principle, which is based on the idea that the lipid bilayer is an amphipathic compartment with a distinct internal force-distribution profile. Physical stretch or insertion of chemical impurities alters this profile, driving channel shape change to conform to the new environment. Thus, FFL governs all dynamic proteins embedded in membrane, including Kv's and TRPs. This article retraces the humble origin of the FFL concept. Paramecium research first created the mind set and the resources to electrically explore other microbial membranes. Patch clamp revealed MS-channel activities from yeast and E. coli spheroplasts. Despite formidable obstacles against interdisciplinary research, the E. coli MS-channel protein, MscL, was purified through fractionation by following its activity, much like enzyme purification. Reconstituted into a simple lipid bilayer, pure MscL retains mechanosensitivity, thus firmly establishing the FFL principle in 1994. The relatively simple MscL and its functional cousin MscS soon became ideal models for detailed analyses. Like the DNA-RNA-protein 'central dogma' or ATP synthesis, FFL is a fundamental principle, which appeared early in evolution, retained in all cellular life forms, and is expected to contribute to future molecular research on sensations, homeostasis, and embryonic development.

脂质作用原理及其起源,“对大肠杆菌适用的道理对大象也适用”。
脂质力(FFL)原理指出,最终打开机械敏感(MS)通道的是来自脂质膜的侧向拉伸力,而不是外部系索或内部细胞骨架。用于某些触觉或本体感觉的压电通道和用于听力或平衡的毛细胞通道显然遵循这一原则,这一原则是基于脂质双分子层是具有独特内力分布特征的两亲性隔室的观点。物理拉伸或化学杂质的插入改变了这种轮廓,驱动通道形状改变以适应新的环境。因此,FFL控制着嵌入膜中的所有动态蛋白,包括Kv和TRPs。本文回顾了FFL概念的卑微起源。草履虫的研究首先创造了用电探索其他微生物膜的思维模式和资源。膜片钳显示酵母和大肠杆菌球质体的ms通道活性。尽管跨学科研究存在巨大障碍,但大肠杆菌ms通道蛋白(MscL)通过跟踪其活性的分离纯化,就像酶纯化一样。纯MscL重组为简单的脂质双分子层,保留了机械敏感性,从而在1994年确立了FFL原理。相对简单的间充质干细胞及其功能性的同类间充质干细胞很快成为详细分析的理想模型。就像dna - rna -蛋白质的“中心法则”或ATP合成一样,FFL是一个基本原理,出现在进化的早期,保留在所有细胞生命形式中,并有望为未来的感觉、体内平衡和胚胎发育的分子研究做出贡献。
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
Journal of neurogenetics
Journal of neurogenetics 医学-神经科学
CiteScore
4.40
自引率
0.00%
发文量
13
审稿时长
>12 weeks
期刊介绍: The Journal is appropriate for papers on behavioral, biochemical, or cellular aspects of neural function, plasticity, aging or disease. In addition to analyses in the traditional genetic-model organisms, C. elegans, Drosophila, mouse and the zebrafish, the Journal encourages submission of neurogenetic investigations performed in organisms not easily amenable to experimental genetics. Such investigations might, for instance, describe behavioral differences deriving from genetic variation within a species, or report human disease studies that provide exceptional insights into biological mechanisms
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