Campesato Lara, Marforio Tainah Dorina, Giacinto Pietro, Calvaresi Matteo, Bottoni Andrea
Dipartimento di Chimica "Giacomo Ciamician", Alma Mater Studiorum - Università di Bologna, via Francesco Selmi 2, 40126, Bologna, Italy.
Chemphyschem. 2018 Jun 19;19(12):1514-1521. doi: 10.1002/cphc.201701332. Epub 2018 Apr 17.
We investigated the catalytic mechanism of α-1,4-glucan lyases using a full QM DFT approach based on the M06-2X functional. The reaction profile of the whole catalytic process can be divided into three phases: glycosylation, deglycosylation-elimination and tautomerization. Glycosylation is a highly asynchronous S 1-like process with an energy barrier of 10.2 kcal mol . A proton moves from the Asp residue to the glycosidic oxygen. Asp acts as a nucleophile and attacks the anomeric carbon causing the cleavage of the glycosidic bond. Deglycosilation-elimination is the rate-determining step of the entire process with an overall barrier of 18.3 kcal mol . The final step (restoring the catalyst and tautomerization) occurs rather easily, since the Asp carboxylate group "assists" the proton transfer in the tautomerization process. Our computations clearly indicate that tautomerization must occur inside the enzyme before leaving the active site rather than in the aqueous solution. Outside of the protein environment the enol-AF→keto-AF process "assisted" by a water molecule has a barrier of 35.8 kcal mol .
我们采用基于M06 - 2X泛函的全量子力学密度泛函理论(QM DFT)方法研究了α-1,4-葡聚糖裂解酶的催化机制。整个催化过程的反应历程可分为三个阶段:糖基化、去糖基化-消除反应和互变异构。糖基化是一个高度异步的类似S 1的过程,能垒为10.2 kcal·mol 。一个质子从天冬氨酸残基转移到糖苷氧上。天冬氨酸作为亲核试剂攻击异头碳,导致糖苷键断裂。去糖基化-消除反应是整个过程的速率决定步骤,总势垒为18.3 kcal·mol 。最后一步(恢复催化剂和互变异构)相当容易发生,因为天冬氨酸羧基在互变异构过程中“协助”质子转移。我们的计算清楚地表明,互变异构必须在酶离开活性位点之前在酶内部发生,而不是在水溶液中。在蛋白质环境之外,由水分子“协助”的烯醇-AF→酮-AF过程的势垒为35.8 kcal·mol 。
