化学
脱羧
立体化学
酶
氨基酸
活动站点
基质(水族馆)
氧化脱羧
残留物(化学)
突变
组氨酸
生物化学
酶催化
定点突变
组合化学
化学合成
氨基酸残基
催化作用
蛋白质工程
生物催化
生物合成
人工酶
氧化脱氨基
作者
Huibin Wang,Angela Yao,Masahiro Kanaida,Takahiro Mori,Shilin Liu,Eliott Le Du,Yu‐Cong Zheng,Takayoshi Awakawa,Hans Renata,Wei‐chen Chang,Ikuro Abe
摘要
α-Tertiary amino acids (ATAAs) are versatile building blocks for the synthesis of biologically active compounds. Although synthetic and enzymatic approaches to ATAA synthesis have been developed, additional methods for ATAA production remain in high demand. Here, we report detailed mechanistic and structural analyses of TqaM, a non-heme iron-dependent oxygenase that catalyzes the key oxidative decarboxylation of a β-amino acid to generate 2-aminoisobutyric acid, a representative ATAA. In vitro analyses revealed that TqaM strictly recognizes the stereochemistry at the C2 position of the substrate and initiates the reaction by abstracting a C2-hydrogen atom with one equivalent of molecular oxygen. Structural analysis and site-directed mutagenesis suggested that an active site histidine residue functions as an acid/base catalyst and the N-terminal loop of the enzyme plays a critical role in substrate selectivity. Finally, we demonstrate TqaM’s remarkable substrate promiscuity toward α-hydroxy-β-amino acids, enabling the efficient synthesis of diverse ATAAs with potential biocatalytic applications.
科研通智能强力驱动
Strongly Powered by AbleSci AI