Fast and Efficient Red-Absorbing Photoswitching Proteins Based on Flavin–Ligand Charge Transfer Complexes

IF 3 4区化学 Q3 CHEMISTRY, PHYSICAL

ChemPhotoChem Pub Date : 2025-02-11 DOI:10.1002/cptc.202500012

Bo Zhuang, Ursula Liebl, Marten H. Vos, Michel Sliwa

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Abstract

Recently a novel class of reversible protein photoswitches has been discovered that is based on a charge transfer (CT) complex composed of the flavin cofactor and a substrate-analogue inhibitor molecule in the family of sarcosine oxidase flavoproteins. Here, excitation of the CT band results in barrierless dissociation of the CT complex on the femtosecond timescale followed by its thermally activated reformation, on the timescale of a few nanoseconds at ambient temperature. The photoreaction is thought to involve a well-defined isomerization of the inhibitor without its dissociation from the protein. This reaction occurs with an unusually high quantum yield (~80 %), is initiated by absorption in the red part of the visible absorption spectrum, and leads to a photoproduct absorbing in the blue spectral region (negative photochromism). Therefore, this class of photoswitches can be considered a promising template for developing a new class of fast negative photochromic compounds for Life Science applications provided the lifetime of the photoproducts (‘light state’) can be prolonged. Potential future developments will be discussed.

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基于黄素配体电荷转移配合物的快速高效吸红光开关蛋白

最近发现了一类新的可逆蛋白光开关，它是基于由黄素辅助因子和肌氨酸氧化酶黄蛋白家族中的底物类似物抑制剂分子组成的电荷转移（CT）复合物。在这里，激发CT带导致CT配合物在飞秒时间尺度上无障碍解离，然后在环境温度下在几纳秒的时间尺度上进行热激活重组。光反应被认为涉及到抑制剂的明确的异构化，而不使其与蛋白质分离。该反应以异常高的量子产率（~ 80%）发生，由可见吸收光谱中红色部分的吸收引发，并导致光产物在蓝色光谱区域吸收（负光致变色）。因此，这类光开关可以被认为是开发一类新的快速负光致变色化合物的有前途的模板，用于生命科学应用，只要光产物的寿命（“光态”）可以延长。我们将讨论潜在的未来发展。

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来源期刊

ChemPhotoChem Chemistry-Physical and Theoretical Chemistry

CiteScore

5.80

自引率

5.40%

发文量

165

期刊介绍： Light plays a crucial role in natural processes and leads to exciting phenomena in molecules and materials. ChemPhotoChem welcomes exceptional international research in the entire scope of pure and applied photochemistry, photobiology, and photophysics. Our thorough editorial practices aid us in publishing authoritative research fast. We support the photochemistry community to be a leading light in science. We understand the huge pressures the scientific community is facing every day and we want to support you. Chemistry Europe is an association of 16 chemical societies from 15 European countries. Run by chemists, for chemists—we evaluate, publish, disseminate, and amplify the scientific excellence of chemistry researchers from around the globe.