The Retaining Mechanism of Xylose Transfer Catalyzed by Xyloside α-1,3-Xylosyltransferase (XXYLT1): a Quantum Mechanics/Molecular Mechanics Study

Utilization of glycosyltransferases as a seamless tool for synthesis and modification of the oligosaccharides-A review

Glycosyltransferases (GTs) catalyze the transfer of active monosaccharide donors to carbohydrates to create a wide range of oligosaccharide structures. GTs display strong regioselectivity and stereoselectivity in producing glycosidic bonds, making them extremely valuable in the in vitro synthesis of oligosaccharides. The synthesis of oligosaccharides by GTs often gives high yields; however, the enzyme activity may experience product inhibition. Additionally, the higher cost of nucleotide sugars limits the usage of GTs for oligosaccharide synthesis. In this review, we comprehensively discussed the structure and mechanism of GTs based on recent literature and the CAZY website data. To provide innovative ideas for the functional studies of GTs, we summarized several remarkable characteristics of GTs, including folding, substrate specificity, regioselectivity, donor sugar nucleotides, catalytic reversibility, and differences between GTs and GHs. In particular, we highlighted the recent advancements in multi-enzyme cascade reactions and co-immobilization of GTs, focusing on overcoming problems with product inhibition and cost issues. Finally, we presented various types of GT that have been successfully used for oligosaccharide synthesis. We concluded that there is still an opportunity for improvement in enzymatically produced oligosaccharide yield, and future research should focus on improving the yield and reducing the production cost.

Multiscale QM/MM modelling of catalytic systems with ChemShell

Hybrid quantum mechanical/molecular mechanical (QM/MM) methods are a powerful computational tool for the investigation of all forms of catalysis, as they allow for an accurate description of reactions occurring at catalytic sites in the context of a complicated electrostatic environment. The scriptable computational chemistry environment ChemShell is a leading software package for QM/MM calculations, providing a flexible, high performance framework for modelling both biomolecular and materials catalysis. We present an overview of recent applications of ChemShell to problems in catalysis and review new functionality introduced into the redeveloped Python-based version of ChemShell to support catalytic modelling. These include a fully guided workflow for biomolecular QM/MM modelling, starting from an experimental structure, a periodic QM/MM embedding scheme to support modelling of metallic materials, and a comprehensive set of tutorials for biomolecular and materials modelling.

Catalytic Mechanism of Pyridoxal 5'-Phosphate-Dependent Aminodeoxychorismate Lyase: A Computational QM/MM Study

Aminodeoxychorismate lyase (ADCL) is a kind of pyridoxal-5'-phosphate (PLP)-dependent enzyme that catalyzes the conversion of 4-amino-4-deoxychorismate (ADC) to p-aminobenzoate (PABA), which is a key step for the biosynthesis of folate. To illuminate the reaction details at the atomistic level, an enzyme-substrate reactant model has been constructed, and QM/MM calculations have been performed. Our calculation results reveal that the overall catalytic cycle contains 11 elementary steps, which can be described by three stages, including the transamination reaction of PLP, the release of pyruvate and aromatization of ADC, and the recovery to the initial aldimine. During the reaction, a series of intramolecular proton transfer are involved, which are the key for the C-N bond formation and cleavage as well as the aromatization of the ADC ring. In addition to forming the Schiff base with the pocket residue Lys251 and substrate in the internal aldimine and the external aldimine, respectively, the coenzyme PLP also plays a critical role in the intramolecular proton transfer by employing its hydroxyl oxygen anion and phosphate group. These findings may provide useful information for further understanding the catalytic mechanism of other PLP-dependent enzymes.

Computer Simulation to Rationalize “Rational” Engineering of Glycoside Hydrolases and Glycosyltransferases

Glycoside hydrolases and glycosyltransferases are the main classes of enzymes that synthesize and degrade carbohydrates, molecules essential to life that are a challenge for classical chemistry. As such, considerable efforts have been made to engineer these enzymes and make them pliable to human needs, ranging from directed evolution to rational design, including mechanism engineering. Such endeavors fall short and are unreported in numerous cases, while even success is a necessary but not sufficient proof that the chemical rationale behind the design is correct. Here we review some of the recent work in CAZyme mechanism engineering, showing that computational simulations are instrumental to rationalize experimental data, providing mechanistic insight into how native and engineered CAZymes catalyze chemical reactions. We illustrate this with two recent studies in which (i) a glycoside hydrolase is converted into a glycoside phosphorylase and (ii) substrate specificity of a glycosyltransferase is engineered toward forming O-, N-, or S-glycosidic bonds.

Mechanism of Sugar Ring Contraction and Closure Catalyzed by UDP-d-apiose/UDP-d-xylose Synthase (UAXS)

Uridine diphosphate (UDP)-apiose/UDP-xylose synthase (UAXS) is a member of the short-chain dehydrogenase/reductase superfamily (SDR), which catalyzes the ring contraction and closure of UDP-d-glucuronic acid (UDP-GlcA), affording UDP-apiose and UDP-xylose. UAXS is a special enzyme that integrates ring-opening, decarboxylation, rearrangement, and ring closure/contraction in a single active site. Recently, the ternary complex structure of UAXS was crystallized from Arabidopsis thaliana. In this work, to gain insights into the detailed formation mechanism of UDP-apiose and UDP-xylose, an enzyme-substrate reactant model has been constructed and quantum mechanical/molecular mechanical (QM/MM) calculations have been performed. Our calculation results reveal that the reaction starts from the C4-OH oxidation, which is accompanied by the conformational transformation of the sugar ring from chair type to boat type. The sugar ring-opening is prior to decarboxylation, and the deprotonation of the C2-OH group is the prerequisite for sugar ring-opening. Moreover, the keto-enol tautomerization of the decarboxylated intermediate is a necessary step for ring closure/contraction. Based on our calculation results, more UDP-apiose product was expected, which is in line with the experimental observation. Three titratable residues, Tyr185, Cys100, and Cys140, steer the reaction by proton transfer from or to UDP-GlcA, and Arg182, Glu141, and D337 constitute a proton conduit for sugar C2-OH deprotonation. Although Thr139 and Tyr105 are not directly involved in the enzymatic reaction, they are responsible for promoting the catalysis by forming hydrogen-bonding interactions with GlcA. Our calculations may provide useful information for understanding the catalysis of the SDR family.

Glycosyl Oxocarbenium Ions: Structure, Conformation, Reactivity, and Interactions

Carbohydrates (glycans, saccharides, and sugars) are essential molecules in all domains of life. Research on glycoscience spans from chemistry to biomedicine, including material science and biotechnology. Access to pure and well-defined complex glycans using synthetic methods depends on the success of the employed glycosylation reaction. In most cases, the mechanism of the glycosylation reaction is believed to involve the oxocarbenium ion. Understanding the structure, conformation, reactivity, and interactions of this glycosyl cation is essential to predict the outcome of the reaction. In this Account, building on our contributions on this topic, we discuss the theoretical and experimental approaches that have been employed to decipher the key features of glycosyl cations, from their structures to their interactions and reactivity.We also highlight that, from a chemical perspective, the glycosylation reaction can be described as a continuum, from unimolecular SN1 with naked oxocarbenium cations as intermediates to bimolecular SN2-type mechanisms, which involve the key role of counterions and donors. All these factors should be considered and are discussed herein. The importance of dissociative mechanisms (involving contact ion pairs, solvent-separated ion pairs, solvent-equilibrated ion pairs) with bimolecular features in most reactions is also highlighted.The role of theoretical calculations to predict the conformation, dynamics, and reactivity of the oxocarbenium ion is also discussed, highlighting the advances in this field that now allow access to the conformational preferences of a variety of oxocarbenium ions and their reactivities under SN1-like conditions.Specifically, the ground-breaking use of superacids to generate these cations is emphasized, since it has permitted characterization of the structure and conformation of a variety of glycosyl oxocarbenium ions in superacid solution by NMR spectroscopy.We also pay special attention to the reactivity of these glycosyl ions, which depends on the conditions, including the counterions, the possible intra- or intermolecular participation of functional groups that may stabilize the cation and the chemical nature of the acceptor, either weak or strong nucleophile. We discuss recent investigations from different experimental perspectives, which identified the involved ionic intermediates, estimating their lifetimes and reactivities and studying their interactions with other molecules. In this context, we also emphasize the relationship between the chemical methods that can be employed to modulate the sensitivity of glycosyl cations and the way in which glycosyl modifying enzymes (glycosyl hydrolases and transferases) build and cleave glycosidic linkages in nature. This comparison provides inspiration on the use of molecules that regulate the stability and reactivity of glycosyl cations.

Nucleotide Sugars in Chemistry and Biology

Nucleotide sugars have essential roles in every living creature. They are the building blocks of the biosynthesis of carbohydrates and their conjugates. They are involved in processes that are targets for drug development, and their analogs are potential inhibitors of these processes. Drug development requires efficient methods for the synthesis of oligosaccharides and nucleotide sugar building blocks as well as of modified structures as potential inhibitors. It requires also understanding the details of biological and chemical processes as well as the reactivity and reactions under different conditions. This article addresses all these issues by giving a broad overview on nucleotide sugars in biological and chemical reactions. As the background for the topic, glycosylation reactions in mammalian and bacterial cells are briefly discussed. In the following sections, structures and biosynthetic routes for nucleotide sugars, as well as the mechanisms of action of nucleotide sugar-utilizing enzymes, are discussed. Chemical topics include the reactivity and chemical synthesis methods. Finally, the enzymatic in vitro synthesis of nucleotide sugars and the utilization of enzyme cascades in the synthesis of nucleotide sugars and oligosaccharides are briefly discussed.

How inverting β-1,4-galactosyltransferase-1 can quench a high charge of the by-product UDP3- in catalysis: a QM/MM study of enzymatic reaction with native and UDP-5' thio galactose substrates

The catalysis of inverting glycosyltransferases consists of several biophysical and biochemical processes during which the transfer of a sugar residue from the purine phosphate donor substrate to an acceptor substrate occurs with stereo-inversion of the anomeric C1 center at a product. During catalysis a highly charged phosphate by-product (UDP3-) is formed and a mechanism of how the enzyme stabilizes it back to the UDP2- form is not known. Using methods of molecular modeling (hybrid DFT-QM/MM calculations) we proposed and validated a catalytic mechanism of bovine inverting β-1,4-galactosyltransferase-1 (β4Gal-T1) with native (UDP-galactose) and thio donor substrates (UDP-5' thio galactose). We focused on three aspects of the mechanism not yet investigated: (i) the formation of an oxocarbenium ion intermediate, which was only found for the retaining glycosyltransferases for the time being; (ii) the mechanism of stabilization of a highly charged phosphate by-product (UDP3-) back to its standard in vivo form (UDP2-); (iii) explanation for why in experimental measurements the rate of catalysis with the thio donor substrate is only 8% of the rate of that with the natural substrate. To understand the differences in the interaction patterns between the complexes enzyme : UDP-Gal and enzyme : UDP-5S-Gal, fragmented molecular orbital (FMO) decomposition energy analysis was carried out at the DFT level.