Single-molecule fluorescence analysis of cellular nanomachinery components.

Annual review of biophysics and biomolecular structure Pub Date : 2007-01-01 DOI:10.1146/annurev.biophys.36.040306.132715

Reiner Peters

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引用次数: 17

Abstract

Recent progress in proteomics suggests that the cell can be conceived as a large network of highly refined, nanomachine-like protein complexes. This working hypothesis calls for new methods capable of analyzing individual protein complexes in living cells and tissues at high speed. Here, we examine whether single-molecule fluorescence (SMF) analysis can satisfy that demand. First, recent technical progress in the visualization, localization, tracking, conformational analysis, and true resolution of individual protein complexes is highlighted. Second, results obtained by the SMF analysis of protein complexes are reviewed, focusing on the nuclear pore complex as an instructive example. We conclude that SMF methods provide powerful, indispensable tools for the structural and functional characterization of protein complexes. However, the transition from in vitro systems to living cells is in the initial stages. We discuss how current limitations in the nanoscopic analysis of living cells and tissues can be overcome to create a new paradigm, nanoscopic biomedicine.

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细胞纳米机械成分的单分子荧光分析。

蛋白质组学的最新进展表明，细胞可以被认为是一个由高度精细的纳米机器状蛋白质复合物组成的大型网络。这种可行的假设需要能够高速分析活细胞和组织中单个蛋白质复合物的新方法。在这里，我们检查是否单分子荧光(SMF)分析可以满足这种需求。首先，强调了最近在可视化、定位、跟踪、构象分析和单个蛋白质复合物的真正分辨率方面的技术进展。其次，回顾了蛋白质复合物的SMF分析结果，重点介绍了核孔复合物作为一个有指导意义的例子。我们得出结论，SMF方法为蛋白质复合物的结构和功能表征提供了强大的，不可或缺的工具。然而，从体外系统到活细胞的过渡还处于初始阶段。我们讨论了如何克服目前在活细胞和组织的纳米级分析的局限性，以创造一个新的范例，纳米级生物医学。

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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Annual review of biophysics and biomolecular structure

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