可逆开关荧光蛋白:"公平开关项目"

Riccardo Nifosì, Barbara Storti, Ranieri Bizzarri
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引用次数: 0

摘要

荧光蛋白(FPs)在荧光显微镜中的应用改变了细胞生物学,通过基因融合实现了蛋白质的精确标记。一个关键的进步是改变主序列,定制其光物理性质,以满足特定的成像需求。可逆转换荧光蛋白(RSFP)是一个特别引人注目的工程突变体家族,即其光学特性可在亮态和暗态之间切换的变体,从而为显微镜成像增添了一个新的维度。过去 20 年来,RSFP 为光学成像的超分辨率(纳米镜)革命做出了巨大贡献,并为纳米尺度的细胞生物化学提供了新知识。除了高分辨率应用,RSFP 的灵活性还被用于其他非常规成像方案,如光致变色荧光共振能量转移(FRET)。在这项工作中,我们探讨了 FPs 光致变色行为的起源和发展,并研究了结构与光开关能力之间错综复杂的关系。我们还讨论了一个简单的数学模型,该模型解释了观察到的光开关动力学。尽管我们回顾了过去二十年中开发的大多数 RSFP,但我们的主要目标是提供对关键开关表型及其分子基础的清晰认识。事实上,了解光开关表型对于为特定应用选择合适的蛋白质或进一步改造现有蛋白质至关重要。为了让这幅图画更加完整,我们将详细介绍 RSFP 令人兴奋的应用,尤其是在超分辨率显微镜领域的应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Reversibly switchable fluorescent proteins: “the fair switch project”

Reversibly switchable fluorescent proteins: “the fair switch project”

Fluorescent proteins (FPs) have transformed cell biology through their use in fluorescence microscopy, enabling precise labeling of proteins via genetic fusion. A key advancement is altering primary sequences to customize their photophysical properties for specific imaging needs. A particularly notable family of engineered mutants is constituted by Reversible Switching Fluorescent Proteins (RSFPs), i.e. variant whose optical properties can be toggled between a bright and a dark state, thereby adding a further dimension to microscopy imaging. RSFPs have strongly contributed to the super-resolution (nanoscopy) revolution of optical imaging that has occurred in the last 20 years and afforded new knowledge of cell biochemistry at the nanoscale. Beyond high-resolution applications, the flexibility of RSFPs has been exploited to apply these proteins to other non-conventional imaging schemes such as photochromic fluorescence resonance energy transfer (FRET). In this work, we explore the origins and development of photochromic behaviors in FPs and examine the intricate relationships between structure and photoswitching ability. We also discuss a simple mathematical model that accounts for the observed photoswitching kinetics. Although we review most RSFPs developed over the past two decades, our main goal is to provide a clear understanding of key switching phenotypes and their molecular bases. Indeed, comprehension of photoswitching phenotypes is crucial for selecting the right protein for specific applications, or to further engineer the existing ones. To complete this picture, we highlight in some detail the exciting applications of RSFPs, particularly in the field of super-resolution microscopy.

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