Molecular Mechanism of Double-Displacement Retaining β‑Kdo Glycosyltransferase WbbB

Glycosyltransferases (GTs) are pivotal enzymes involved in glycosidic bond synthesis, which can lead to either retention or inversion of the glycosyl moiety’s anomeric configuration. However, the catalytic mechanism for retaining GTs remains a subject of controversy. In this study, we employ MD and...

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Published inThe journal of physical chemistry. B Vol. 128; no. 31; pp. 7476 - 7485
Main Authors Rao, Deming, Zhu, Lin, Liu, Weiqiong, Guo, Zhiyong
Format Journal Article
LanguageEnglish
Published United States American Chemical Society 08.08.2024
Subjects
B: Biophysical and Biochemical Systems and Processes
Biocatalysis
carbon
glycosides
glycosidic linkages
glycosylation
glycosyltransferases
Glycosyltransferases - chemistry
Glycosyltransferases - metabolism
Hydrogen Bonding
hydrolases
Lewis bases
moieties
Molecular Dynamics Simulation
phosphates
Quantum Theory
sugars
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Summary:Glycosyltransferases (GTs) are pivotal enzymes involved in glycosidic bond synthesis, which can lead to either retention or inversion of the glycosyl moiety’s anomeric configuration. However, the catalytic mechanism for retaining GTs remains a subject of controversy. In this study, we employ MD and QM/MM metadynamics to investigate the double-displacement catalytic mechanism of the retaining β-Kdo transferase WbbB. Our findings demonstrate that the nucleophile Asp232 initiates the reaction by attacking the sugar ring containing a carboxylate at the anomeric position, forming a covalent adduct. Subsequently, the adduct undergoes a rotational rearrangement, ensuring proper orientation of the anomeric carbon for the acceptor substrate. In the second step, Glu158 acts as the catalytic base to abstract the proton of the acceptor substrate to complete the transglycosylation reaction. Notably, His265 does not function as the anticipated catalytic acid; instead, it stabilizes the phosphate group through H-bonding interactions. Our simulations support the double-displacement mechanism implicated from the crystallographic studies of WbbB. This mechanism deviates from the common S N i-type and retaining glycoside hydrolase mechanisms, thereby expanding our understanding of GT catalytic mechanisms.
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ISSN:1520-6106
1520-5207
1520-5207
DOI:10.1021/acs.jpcb.4c02073