超越洗涤剂胶束:非胶束和脂基膜模拟溶液态核磁共振的优点和应用。

IF 7.3 2区 化学 Q2 CHEMISTRY, PHYSICAL
Kai Klöpfer, Franz Hagn
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引用次数: 26

摘要

膜蛋白在细胞内或细胞间的信号转导和代谢物交换中起着重要的作用。因此,这类蛋白是目前上市药物中约60% %的靶标,强调了它们必不可少的生物学作用。除了功能分析外,对这类蛋白的结构和动力学研究对于充分了解其功能至关重要。尽管x射线晶体学和电子显微镜是确定膜蛋白及其复合物结构的主要方法,但核磁共振波谱可以提供(a)不结晶和(b)对EM来说太小的系统的基本信息。此外,核磁共振是在各种时间尺度上监测生物分子功能动力学的通用工具。此类研究的一个关键方面是使用类似于天然环境的膜模拟物,从而能够提取功能见解。近几十年来,膜蛋白核磁共振群落已经从相当苛刻的洗涤剂转向具有更多天然性质的膜系统。特别是,最近磷脂纳米盘主要用于溶液态核磁共振的开发和优化,但现在也用于固态核磁共振光谱。纳米圆盘由一个平面脂质双分子层组成,该双分子层被不同的(生物)聚合物包围,形成大小可调节的颗粒。在这篇综述中,我们提供了可用的膜模拟物的概述,包括纳米圆盘,两极体和bicelles,适合于高分辨率核磁共振波谱,并描述了这些先进的膜模拟物如何促进膜蛋白结构和动力学的核磁共振研究。由于膜蛋白的稳定性很大程度上取决于所选择的膜模拟物,我们强调了一个合适的系统的重要性,这个系统不一定是为溶液状态NMR应用而开发的,因此需要对每个膜蛋白进行优化。然而,基于脂质的膜模拟物提供了在高温下进行核磁共振实验的可能性,并在现实的膜环境中研究配体和伴侣蛋白复合物及其功能动力学。为了能够在选择合适的膜系统时做出明智的决定,我们提供了各种膜蛋白类别的可用选项的详细概述,从而促进了这一通常困难的选择过程,适用于广泛的所需NMR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。

Beyond detergent micelles: The advantages and applications of non-micellar and lipid-based membrane mimetics for solution-state NMR

Beyond detergent micelles: The advantages and applications of non-micellar and lipid-based membrane mimetics for solution-state NMR

Membrane proteins are important players in signal transduction and the exchange of metabolites within or between cells. Thus, this protein class is the target of around 60 % of currently marketed drugs, emphasizing their essential biological role. Besides functional assays, structural and dynamical investigations on this protein class are crucial to fully understanding their functionality. Even though X-ray crystallography and electron microscopy are the main methods to determine structures of membrane proteins and their complexes, NMR spectroscopy can contribute essential information on systems that (a) do not crystallize and (b) are too small for EM. Furthermore, NMR is a versatile tool for monitoring functional dynamics of biomolecules at various time scales. A crucial aspect of such studies is the use of a membrane mimetic that resembles a native environment and thus enables the extraction of functional insights. In recent decades, the membrane protein NMR community has moved from rather harsh detergents to membrane systems having more native-like properties. In particular, most recently phospholipid nanodiscs have been developed and optimized mainly for solution-state NMR but are now also being used for solid-state NMR spectroscopy. Nanodiscs consist of a patch of a planar lipid bilayer that is encircled by different (bio-)polymers to form particles of defined and tunable size. In this review, we provide an overview of available membrane mimetics, including nanodiscs, amphipols and bicelles, that are suitable for high-resolution NMR spectroscopy and describe how these advanced membrane mimetics can facilitate NMR studies on the structure and dynamics of membrane proteins. Since the stability of membrane proteins depends critically on the chosen membrane mimetic, we emphasize the importance of a suitable system that is not necessarily developed for solution-state NMR applications and hence requires optimization for each membrane protein. However, lipid-based membrane mimetics offer the possibility of performing NMR experiments at elevated temperatures and studying ligand and partner protein complexes as well as their functional dynamics in a realistic membrane environment. In order to be able to make an informed decision during the selection of a suitable membrane system, we provide a detailed overview of the available options for various membrane protein classes and thereby facilitate this often-difficult selection process for a broad range of desired NMR applications.

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来源期刊
CiteScore
14.30
自引率
8.20%
发文量
12
审稿时长
62 days
期刊介绍: Progress in Nuclear Magnetic Resonance Spectroscopy publishes review papers describing research related to the theory and application of NMR spectroscopy. This technique is widely applied in chemistry, physics, biochemistry and materials science, and also in many areas of biology and medicine. The journal publishes review articles covering applications in all of these and in related subjects, as well as in-depth treatments of the fundamental theory of and instrumental developments in NMR spectroscopy.
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