Key Laboratory for Molecular Enzymology and Engineering of the Ministry of Education, National Engineering Laboratory of AIDS Vaccine, College of Life Science, Jilin University, Changchun 130023, China.
Int J Mol Sci. 2019 Mar 8;20(5):1188. doi: 10.3390/ijms20051188.
The aminotransferase from (BtrR), which is involved in the biosynthesis of butirosin, catalyzes the pyridoxal phosphate (PLP)-dependent transamination reaction to convert valienone to β-valienamine (a new β-glycosidase inhibitor for the treatment of lysosomal storage diseases) with an optical purity enantiomeric excess value. To explore the stereoselective mechanism of valienamine generated by BtrR, multiple molecular dynamics (MD) simulations were performed for the BtrR/PLP/valienamine and BtrR/PLP/β-valienamine complexes. The theoretical results showed that β-valienamine could make BtrR more stable and dense than valienamine. β-valienamine could increase the hydrogen bond probability and decrease the binding free energy between coenzyme PLP and BtrR by regulating the protein structure of BtrR, which was conducive to the catalytic reaction. β-valienamine maintained the formation of cation-p interactions between basic and aromatic amino acids in BtrR, thus enhancing its stability and catalytic activity. In addition, CAVER 3.0 analysis revealed that β-valienamine could make the tunnel of BtrR wider and straight, which was propitious to the removal of products from BtrR. Steered MD simulation results showed that valienamine interacted with more residues in the tunnel during dissociation compared with β-valienamine, resulting in the need for a stronger force to be acquired from BtrR. Taken together, BtrR was more inclined to catalyze the substrates to form β-valienamine, either from the point of view of the catalytic reaction or product removal.
(BtrR)中的氨基转移酶参与了丁硫霉素的生物合成,催化吡哆醛磷酸(PLP)依赖性转氨基反应,将瓦伦酮转化为β-瓦伦胺(一种用于治疗溶酶体贮积病的新型β-糖苷酶抑制剂),具有光学纯度对映体过量值。为了探索 BtrR 生成β-瓦伦胺的立体选择性机制,对 BtrR/PLP/β- valienamine 和 BtrR/PLP/β-valienamine 复合物进行了多次分子动力学(MD)模拟。理论结果表明,β- valienamine 可以使 BtrR 比 valienamine 更稳定和致密。β- valienamine 通过调节 BtrR 的蛋白质结构,可以增加辅酶 PLP 与 BtrR 之间氢键的概率,降低结合自由能,从而有利于催化反应。β- valienamine 保持 BtrR 中碱性和芳香族氨基酸之间的阳离子-π 相互作用,从而增强其稳定性和催化活性。此外,CAVER 3.0 分析表明,β- valienamine 可以使 BtrR 的隧道变宽变直,有利于产物从 BtrR 中排出。导向 MD 模拟结果表明,与β- valienamine 相比,在解离过程中,valienamine 与隧道中的更多残基相互作用,导致需要从 BtrR 中获得更强的力。综上所述,无论是从催化反应还是产物去除的角度来看,BtrR 都更倾向于催化底物形成β- valienamine。
