变构调节
化学
合成生物学
蛋白质工程
受体
生物物理学
费斯特共振能量转移
结构生物学
生物化学
核糖开关
变构酶
变构调节剂
蛋白质-蛋白质相互作用
分子内力
生物传感器
核受体
配体(生物化学)
蛋白质结构
血浆蛋白结合
计算生物学
细胞质
HEK 293细胞
信号转导
细胞生物学
分子机器
定向分子进化
小分子
化学生物学
蛋白质设计
肽
蛋白质折叠
G蛋白偶联受体
作者
Zhong Guo,Oleh Smutok,Gyu Rie Lee,Zhenling Cui,Haocheng Qianzhu,Monika Kish,Cagla Ergun Ayva,Kejia Wu,Roxane Mutschler,Colin J. Jackson,Maria Micaela Fiorito,Andrew C. Warden,Oliver B. Smith,Alfredo Quijano‐Rubio,Thomas Huber,Jonathan J. Phillips,Gottfried Otting,Evgeny Katz,David Baker,Kirill Alexandrov
标识
DOI:10.1038/s41587-026-03081-9
摘要
Abstract Protein allostery underlies most information and energy processing in biology and the development of artificial allosteric proteins is a key objective of synthetic biology and biotechnology. We show that machine-learning-engineered minimal ligand-binding domains act as efficient receptors in single-component allosteric switches, despite lacking global conformational change. Such colorimetric, luminescent and electrochemical biosensors of small molecules, peptides and proteins can be compiled into intramolecular YES and AND logic gates. Furthermore, we report fully synthetic allosteric switches composed of artificial receptor and reporter domains. Hydrogen/deuterium exchange mass spectrometry and 19 F nuclear magnetic resonance analyses suggest that ligand binding reduces the conformation entropy of the system, increasing the catalytic activity of the reporter domain. The potential practical utility of this approach is demonstrated by engineering Escherichia coli cells with steroid-dependent antibiotic resistance and by developing bioelectronic devices capable of quantifying steroid hormones.
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