Broadening the scope of glycosyltransferase-catalyzed sugar nucleotide synthesis.

We described the integration of the general reversibility of glycosyltransferase-catalyzed reactions, artificial glycosyl donors, and a high throughput colorimetric screen to enable the engineering of glycosyltransferases for combinatorial sugar nucleotide synthesis. The best engineered catalyst from this study, the OleD Loki variant, contained the mutations P67T/I112P/T113M/S132F/A242I compared with the OleD wild-type sequence. Evaluated against the parental sequence OleD TDP16 variant used for screening, the OleD Loki variant displayed maximum improvements in k(cat)/K(m) of >400-fold and >15-fold for formation of NDP-glucoses and UDP-sugars, respectively.

High-throughput colorimetric assays for nucleotide sugar formation and glycosyl transfer.

Glycosyltransferases are ubiquitous in nature, catalyzing glycosidic bond formation in the context of an enormous range of substrates, which include all major classes of biological molecules. Because this wide range of substrates lacks a shared, distinguishable feature that can be altered by glycosyl transfer, general assays for detection of glycosyltransferase activity have long been largely limited to low-throughput methods. Of those high-throughput assays reported in the literature, many are confined to specific glycosyl transfer reactions with modified aglycon acceptors selected for their unique analytical properties.

Enzymatic methods for glyco(diversification/randomization) of drugs and small molecules.

Glyco (randomization/diversification) is a term that encompasses strategies to diversify a core drug scaffold via enzymatic glycosylation to provide sets of analogs wherein the sole diversity element is a carbohydrate. This review covers the influence of glycosylation upon various drug properties, the classes of glycosyl-conjugating enzymes amenable to glyco(randomization/diversification) schemes, approaches to the synthesis of required substrates and specific examples of glycorandomized libraries utilizing both wild-type and engineered enzymes.

Using simple donors to drive the equilibria of glycosyltransferase-catalyzed reactions.

We report that simple glycoside donors can drastically shift the equilibria of glycosyltransferase-catalyzed reactions, transforming NDP-sugar formation from an endothermic to an exothermic process. To demonstrate the utility of this thermodynamic adaptability, we highlight the glycosyltransferase-catalyzed synthesis of 22 sugar nucleotides from simple aromatic sugar donors, as well as the corresponding in situ formation of sugar nucleotides as a driving force in the context of glycosyltransferase-catalyzed reactions for small-molecule glycodiversification. These simple aromatic donors also enabled a general colorimetric assay for glycosyltransfer, applicable to drug discovery, protein engineering and other fundamental sugar nucleotide-dependent investigations.

The impact of enzyme engineering upon natural product glycodiversification.

Glycodiversification of natural products is an effective strategy for small molecule drug development. Recently, improved methods for chemo-enzymatic synthesis of glycosyl donors has spurred the characterization of natural product glycosyltransferases (GTs), revealing that the substrate specificity of many naturally occurring GTs as too stringent for use in glycodiversification. Protein engineering of natural product GTs has emerged as an attractive approach to overcome this limitation.