Molecular Mechanism of Double-Displacement Retaining ß-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 QM/MM metadynamics to investigate the double-displacement catalytic mechanism of the retaining ß-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 SNi-type and retaining glycoside hydrolase mechanisms, thereby expanding our understanding of GT catalytic mechanisms.

Conformational Switch of the 250s Loop Enables the Efficient Transglycosylation in GH Family 77.

Amylomaltases (AMs) play important roles in glycogen and maltose metabolism. However, the molecular mechanism is elusive. Here, we investigated the conformational dynamics of the 250s loop and catalytic mechanism of Thermus aquaticus TaAM using path-metadynamics and QM/MM MD simulations. The results demonstrate that the transition of the 250s loop from an open to closed conformation promotes polysaccharide sliding, leading to the ideal positioning of the acid/base. Furthermore, the conformational dynamics can also modulate the selectivity of hydrolysis and transglycosylation. The closed conformation of the 250s loop enables the tight packing of the active site for transglycosylation, reducing the energy penalty and efficiently preventing the penetration of water into the active site. Conversely, the partially closed conformation for hydrolysis results in a loosely packed active site, destabilizing the transition state. These computational findings guide mutation experiments and enable the identification of mutants with an improved disproportionation/hydrolysis ratio. The present mechanism is in line with experimental data, highlighting the critical role of conformational dynamics in regulating the catalytic reactivity of GHs.

Mechanistic Insights into How the Protonation State of D234 Dictates the Reactivity in Streptomyces coelicolor ß-N-Acetylhexosaminidase.

ß-N-Acetylhexosaminidases (HEXs) play important roles in human diseases and the biosynthesis of human milk oligosaccharides. Despite extensive research, the catalytic mechanism of these enzymes remains largely unexplored. In this study, we employed quantum mechanics/molecular mechanics metadynamics to investigate the molecular mechanism of Streptomyces coelicolor HEX (ScHEX), which has shed light on the transition state structures and conformational pathways of this enzyme. Our simulations revealed that Asp242, located near the assisting residue, can switch the reaction intermediate to an oxazolinium ion or a neutral oxazoline, depending on the protonation state of the residue. Moreover, our findings indicated that the free energy barrier of the second-step reaction starting from the neutral oxazoline increases steeply due to the reduction in the anomeric carbon positive charge and the shortening of the C1-O2N bond. Our results provide valuable insights into the mechanism of substrate-assisted catalysis and could facilitate the design of inhibitors and the engineering of analogous glycosidases for biosynthesis.

Multiple approaches of loop region modification for thermostability improvement of 4,6-α-glucanotransferase from Limosilactobacillus fermentum NCC 3057.

4,6-α-glucanotransferase (4,6-α-GT), as a member of the glycoside hydrolase 70 (GH70) family, converts starch/maltooligosaccharides into α,1-6 bond-containing α-glucan and possesses potential applications in food, medical and related industries but does not satisfy the high-temperature requirement due to its poor thermostability. In this study, a 4,6-α-GT (ΔGtfB) from Limosilactobacillus fermentum NCC 3057 was used as a model enzyme to improve its thermostability. The loops of ΔGtfB as the target region were optimized using directed evolution, sequence alignment, and computer-aided design. A total of 11 positive mutants were obtained and iteratively combined to obtain a combined mutant CM9, with high resistance to temperature (50 °C). The activity of mutant CM9 was 2.08-fold the activity of the wild type, accompanied by a 5 °C higher optimal temperature, a 5.76 °C higher melting point (Tm, 59.46 °C), and an 11.95-fold longer half-life time (t1/2). The results showed that most of the polar residues in the loop region of ΔGtfB are mutated into rigid proline residues. Molecular dynamics simulation demonstrated that the root mean square fluctuation of CM9 significantly decreased by "Breathing" movement reduction of the loop region. This study provides a new strategy for improving the thermostability of 4,6-α-GT through rational loop region modification.