Cell-free expression and biochemical characterization of polysaccharide-synthesizing glycosyltransferases

Abstract

AbstractPolysaccharides are a major class of natural polymers found abundantly across all major life forms and play a critical role as structural, metabolic, or functional components in biomolecular processes. Some polysaccharides like cellulose and hyaluronan are synthesized by membrane-bound family-2 glycosyltransferases (GTs). Despite the fact that the GT-2 family has the maximum number of deposited sequences, the biochemistry of GT-2 family enzymes is still poorly understood due to difficulties associated with GT membrane protein expression, purification, and reconstitution in lipid carriers. Here, we chosePopulus tremula x tremuloidescellulose synthase 8 (PttCesA8) andStreptococcus equisimilishyaluronan synthase (SeHas) as putative family-2-GTs to be expressed in a wheat-germ-based cell-free expression (CFE) system as proteoliposomes. The cell-free products were obtained as reconstituted liposomes directly from CFE reactions at high yields and short processing times compared to other approaches. GT enzymes expression was confirmed using SDS-PAGE and immunoblotting, and the integration of GTs in lipid layers was observed using cryogenic electron microscopy. Both GTs tested were catalytically active when incubated with their respective substrates and cofactors. The Michalis-Menten kinetic constants, Kmfor PttCesA8, was 295.8 µM, and SeHas was 321.51 µM (toward UDP N-Acetyl Glucosamine) and 207.88 µM (toward UDP Glucuronic Acid), respectively. UDP was found to actively inhibit both these GTs with apparent inhibition constants of 10.08 µM and 24.38 µM. Mutation of specific conserved residues in structure-deficit SeHas confirmed the importance of lysine-139, glutamine-248, and threonine-283 residues in hyaluronan biosynthesis. In summary, wheat-germ-based CFE can be used to express functionally active and liposome-reconstituted family-2 GTs at high yields with relative ease to enable classical enzymology assays and will also enable more detailed structural studies in the near future.