Catalytic mechanism of acetolactate decarboxylase from Brevibacillus brevis towards both enantiomers of α-acetolactate?
RSC Advances Pub Date: 2016-08-16 DOI: 10.1039/C6RA18264J
Abstract
Acetolactate decarboxylase catalyzes both enantiomers of α-acetolactate to give a single product, (R)-acetoin, however, the reaction details are still ambiguous. In this paper, the catalytic mechanism of ALDC using both enantiomers of α-acetolactate as substrates has been investigated by means of the combined quantum mechanical/molecular mechanical (QM/MM) approach based on the recently obtained crystal structures of ALDC in complex with the designed transition state mimics. The conversion of (S)-α-acetolactate only contains two elementary steps: the direct decarboxylation of the substrate to form an enolate intermediate, and the protonation of the intermediate to generate the final product. The decarboxylation corresponds to an energy barrier of 13.5 kcal mol?1. In the protonation process, E253 is suggested to be the more likely proton donor, and the overall energy barrier of the catalytic reaction is 23.1 kcal mol?1. The direct conversion of the non-natural substrate (R)-α-acetolactate is calculated to be difficult. It should be firstly rearranged to the natural substrate (S)-α-acetolactate by a carboxylate migration, then the converted substrate undergoes a rotation to enter the decarboxylation manifold of (S)-α-acetolactate. Since the energy barrier of carboxylate migration of (R)-AL is calculated to be only 11.2 kcal mol?1, considering the fact that the conversion of (R)-α-acetolactate to (R)-acetoin by ALDC is at a lower rate, the weak binding of (R)-α-acetolactate in the active site is thus suggested to be the main factor to lower its conversion rate.
Recommended Literature
- [1] An integrated chip for immunofluorescence and its application to analyze lysosomal storage disorders Jie Shen,Ying Zhou,Tu Lu,Junya Peng,Zhixiang Lin,Yuhong Pang,Li YuLab Chip, 2012,12, 317-324 10.1039/C1LC20845D
- [2] An aptasensor for detection of potassium ions based on RecJf exonuclease mediated signal amplification Bidou Wang,Xifeng ChenAnalyst, 2014,139, 5695-5699 10.1039/C4AN01350F
- [3] An all-solid-state imprinted polymer-based potentiometric sensor for determination of bisphenol S? Rongning Liang,Tanji Yin,Ruiqing Yao,Wei QinRSC Adv., 2016,6, 73308-73312 10.1039/C6RA14461F
- [4] An atlas of endohedral Sc2S cluster fullerenes? Li-Hua Gan,Rui Wu,Jian-Lei Tian,Patrick W. FowlerPhys. Chem. Chem. Phys., 2017,19, 419-425 10.1039/C6CP07370K
- [5] An amplified fluorescence detection of T4 polynucleotide kinase activity based on coupled exonuclease III reaction and a graphene oxide platform? Ni-Na Sun,Fengli Qu,Xiaobing Zhang,Shufang Zhang,Jinmao YouAnalyst, 2015,140, 1827-1831 10.1039/C4AN01953A
- [6] An ion-gating multinanochannel system based on a copper-responsive self-cleaving DNAzyme? Yang Chen,Di Zhou,Zheyi Meng,Jin ZhaiChem. Commun., 2016,52, 10020-10023 10.1039/C6CC03943J
- [7] An artificial CO-releasing metalloprotein built by histidine-selective metallation? Inês S. Albuquerque,Hélia F. Jeremias,Miguel Chaves-Ferreira,Dijana Matak-Vinkovic,Omar Boutureira,Carlos C. Rom?oChem. Commun., 2015,51, 3993-3996 10.1039/C4CC10204E
- [8] An alkynylboronatecycloaddition strategy to functionalised benzyne derivatives? James D. Kirkham,Patrick M. Delaney,George J. Ellames,Eleanor C. Row,Joseph P. A. HarrityChem. Commun., 2010,46, 5154-5156 10.1039/C0CC01345E
- [9] Alternative synthesis of the anti-baldness compound RU58841? RSC Adv., 2014,4, 14143-14148 10.1039/C4RA00332B
- [10] An asymmetric supercapacitor based on controllable WO3 nanorod bundle and alfalfa-derived porous carbon? Kanjun Sun,Fengting Hua,Shuzhen Cui,Yanrong Zhu,Hui Peng,Guofu MaRSC Adv., 2021,11, 37631-37642 10.1039/D1RA04788D
Journal Name:RSC Advances
research_products
-
CAS no.: 89640-58-4