纳米纳米共振能量转移(nanoobret)和红移BRET对生物发光共振能量转移(BRET) Förster距离的实验测定

IF 2.5 Q1 Chemistry
Felix Weihs , Jian Wang , Kevin D.G. Pfleger , Helen Dacres
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引用次数: 7

摘要

生物发光共振能量转移(BRET)被广泛应用于蛋白质相互作用的研究,并越来越多地用于监测配体结合和分子重排。Förster距离(R0)描述了两个发色团之间发生最大能量转移的50%的物理距离,它取决于RET组分的选择。R0可以用已知长度的柔性肽连接物来分离两个发色团。了解R0有助于了解BRET系统的选择。例如,我们之前已经表明,在任何遗传编码的RET对中,BRET2表现出迄今为止最大的R0,如果能够适应其低和快速衰减的生物发光信号问题,这可能有利于研究大型大分子复合物。在这项研究中,我们确定了一系列明亮和红移BRET对的R0,包括以四甲基罗达明(TMR)、非氯TOM (NCT)、mCherry或Venus为受体的NanoBRET,以及BRET6(一种红移bret2样体系)。本研究发现,以TMR和NCT为受体配体的NanoBRET的R0值分别为6.15 nm和6.94 nm。NanoLuc-mCherry的R0为5.43 nm, NanoLuc-Venus的R0为5.59 nm, BRET6的R0为5.47 nm。这扩展了可用BRET Förster距离的调色板,为研究人员在考虑BRET系统时提供了更明智的选择,并指出具有NCT的NanoBRET作为大型大分子复合物分析工具的BRET2的良好替代品。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Experimental determination of the bioluminescence resonance energy transfer (BRET) Förster distances of NanoBRET and red-shifted BRET pairs

Experimental determination of the bioluminescence resonance energy transfer (BRET) Förster distances of NanoBRET and red-shifted BRET pairs

Bioluminescence Resonance Energy Transfer (BRET) is widely applied to study protein-protein interactions, as well as increasingly to monitor both ligand binding and molecular rearrangements. The Förster distance (R0) describes the physical distance between the two chromophores at which 50% of the maximal energy transfer occurs and it depends on the choice of RET components. R0 can be experimentally determined using flexible peptide linkers of known lengths to separate the two chromophores. Knowledge of the R0 helps to inform on the choice of BRET system. For example, we have previously shown that BRET2 exhibits the largest R0 to date for any genetically encoded RET pair, which may be advantageous for investigating large macromolecular complexes if its issues of low and fast-decaying bioluminescence signal can be accommodated.

In this study we have determined R0 for a range of bright and red-shifted BRET pairs, including NanoBRET with tetramethylrhodamine (TMR), non-chloro TOM (NCT), mCherry or Venus as acceptor, and BRET6, a red-shifted BRET2-like system. This study revealed R0 values of 6.15 nm and 6.94 nm for NanoBRET using TMR or NCT as acceptor ligands, respectively. R0 was 5.43 nm for NanoLuc-mCherry, 5.59 nm for NanoLuc-Venus and 5.47 nm for BRET6. This extends the palette of available BRET Förster distances, to give researchers a better-informed choice when considering BRET systems and points towards NanoBRET with NCT as a good alternative to BRET2 as an analysis tool for large macromolecular complexes.

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来源期刊
Analytica Chimica Acta: X
Analytica Chimica Acta: X Chemistry-Analytical Chemistry
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