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古紫质3是用于构建高荧光光遗传学报告基因的理想模板。

Archaerhodopsin 3 is an ideal template for the engineering of highly fluorescent optogenetic reporters.

作者信息

Herasymenko Krystyna, Walisinghe Danushka, Konno Masae, Barneschi Leonardo, de Waele Isabelle, Sliwa Michel, Inoue Keiichi, Olivucci Massimo, Haacke Stefan

机构信息

University of Strasbourg, CNRS, IPCMS 23 Rue du Loess 67034 Strasbourg France

Department of Chemistry, Bowling Green State University Bowling Green OH 43403 USA

出版信息

Chem Sci. 2024 Nov 18;16(2):761-774. doi: 10.1039/d4sc05120c. eCollection 2025 Jan 2.

DOI:10.1039/d4sc05120c
PMID:39634579
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11612921/
Abstract

Archaerhodopsin-3 (AR-3) variants stand out among other rhodopsins in that they display a weak, but voltage-sensitive, near-infrared fluorescence emission. This has led to their application in optogenetics both in cell cultures and small animals. However, in the context of improving the fluorescence characteristics of the next generation of AR-3 reporters, an understanding of their ultrafast light-response in light-adapted conditions, is mandatory. To this end, we present a combined experimental and computational investigation of the excited state dynamics and quantum yields of AR-3 and its DETC and Arch-5 variants. The latter always display a mixture of all-/15- and 13-/15- isomers, which leads to a bi-exponential excited state decay. The isomerisation quantum yield is reduced more than 20 times as compared to WT AR-3 and proves that the steady-state fluorescence is induced by a single absorption photon event. In wild-type AR-3, we show that a 300 fs, barrier-less and vibrationally coherent isomerization is driven by an unusual covalent electronic character of its all- retinal chromophore leading to a metastable twisted diradical (TIDIR), in clear contrast to the standard charge-transfer scenario established for other microbial rhodopsins. We discuss how the presence of TIDIR makes AR-3 an ideal candidate for the design of variants with a one-photon induced fluorescence possibly reaching the emission quantum yield of the top natural emitter neorhodopsin (NeoR).

摘要

古菌视紫红质-3(AR-3)变体在其他视紫红质中脱颖而出,因为它们表现出微弱但对电压敏感的近红外荧光发射。这使得它们在细胞培养和小动物的光遗传学中得到应用。然而,在改进下一代AR-3报告基因的荧光特性的背景下,了解它们在光适应条件下的超快光响应是必不可少的。为此,我们对AR-3及其DETC和Arch-5变体的激发态动力学和量子产率进行了实验和计算相结合的研究。后者总是显示出全反式/15-顺式和13-顺式/15-顺式异构体的混合物,这导致激发态双指数衰减。与野生型AR-3相比,异构化量子产率降低了20倍以上,这证明稳态荧光是由单个吸收光子事件诱导的。在野生型AR-3中,我们表明,一个300飞秒、无障碍且振动相干的异构化是由其全反式视黄醛发色团不寻常的共价电子特性驱动的,导致亚稳态扭曲双自由基(TIDIR),这与为其他微生物视紫红质建立的标准电荷转移情况形成鲜明对比。我们讨论了TIDIR的存在如何使AR-3成为设计单光子诱导荧光变体的理想候选者,其发射量子产率可能达到顶级天然发射体新视紫红质(NeoR)的水平。

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