用光脱羧酶制造分子:一个伟大的开始还是一个虚假的黎明?

Tobias M. Hedison, Derren J. Heyes, Nigel S. Scrutton
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引用次数: 13

摘要

光酶是化学合成和生物制造领域具有潜在吸引力的生物催化剂。它们不需要像NAD(P)H这样的辅酶,也不需要像ATP这样的高能分子,而且它们的活性可以通过光在时间和空间上精确地控制。光活化脂肪酸光脱羧酶(FAP)于2017年被发现。自发现以来,生物物理、结构和计算方法已被用于了解FAP如何利用蓝光催化脂肪酸底物的脱羧。作为一种天然的光生物催化剂,FAP可以为新型光酶的设计提供新的见解。本文就FAP酶的结构、作用机理、生物技术应用等方面进行了综述,并对开发新型光生物催化剂进行了展望。我们回顾了FAPs工程的早期成功,但也确定了在生物技术和化学科学中广泛使用这种最近发现的酶家族的主要挑战。基于这些早期的见解,请读者考虑fap的使用是否会继续蓬勃发展,或者当前的限制是否预示着虚假的曙光。
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Making molecules with photodecarboxylases: A great start or a false dawn?

Photoenzymes are potentially attractive biocatalysts for chemicals synthesis and biomanufacturing. They do not require coenzymes such as NAD(P)H, or high energy molecules like ATP, and their activity can be controlled precisely in a temporal and spatial manner by light. The light-activated fatty acid photodecarboxylase (FAP) was discovered in 2017. Since its discovery, biophysical, structural, and computational methods have been used to understand how FAP uses blue light to catalyze the decarboxylation of fatty acid substrates. As a natural photobiocatalyst, FAP could offer insights into the design of new photoenzymes. Here, we provide a perspective on the structure, mechanism and biotechnological applications of FAP enzymes, and understanding from which new photobiocatalysts could be developed. We review early success in the engineering of FAPs but also identify major challenges for wider use of this recently discovered enzyme family in biotechnology and the chemical sciences. Based on these early insights, the reader is invited to consider if the use of FAPs will continue to flourish, or whether current limitations signify a false dawn.

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来源期刊
Current research in chemical biology
Current research in chemical biology Biochemistry, Genetics and Molecular Biology (General)
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