Abstract
Glycogen and starch synthases are retaining glycosyltransferases that catalyze the transfer of glucosyl residues to the non-reducing end of a growing alpha-1,4-glucan chain, a central process of the carbon/energy metabolism present in almost all living organisms. The crystal structure of the glycogen synthase from Pyrococcus abyssi, the smallest known member of this family of enzymes, revealed that its subunits possess a fold common to other glycosyltransferases, a pair of beta/alpha/beta Rossmann fold-type domains with the catalytic site at their interface. Nevertheless, the archaeal enzyme presents an unprecedented homotrimeric molecular arrangement both in solution, as determined by analytical ultracentrifugation, and in the crystal. The C-domains are not involved in intersubunit interactions of the trimeric molecule, thus allowing for movements, likely required for catalysis, across the narrow hinge that connects the N- and C-domains. The radial disposition of the subunits confers on the molecule a distinct triangular shape, clearly visible with negative staining electron microscopy, in which the upper and lower faces present a sharp asymmetry. Comparison of bacterial and eukaryotic glycogen synthases, which use, respectively, ADP or UDP glucose as donor substrates, with the archaeal enzyme, which can utilize both molecules, allowed us to propose the residues that determine glucosyl donor specificity.
Highlights
Glycogen is a polymer of ␣-1,4- and ␣-1,6-linked glucose units that provides a readily available source of energy in living organisms of the three domains: archaea, bacteria, and eukarya
Glycogen and starch synthases are retaining glycosyltransferases that catalyze the transfer of glucosyl residues to the non-reducing end of a growing ␣-1,4-glucan chain, a central process of the carbon/energy metabolism present in almost all living organisms
Polymerization is performed by specific glycosyltransferases (GT)2 of the GT-3 and GT-5 families, named glycogen (GS) or starch synthases, which catalyze the formation of ␣-1,4-glycosidic bonds using UDP- or ADP-glucose as the glucosyl donor
Summary
INSIGHTS INTO OLIGOMERIZATION AND SUBSTRATE BINDING OF EUKARYOTIC GLYCOGEN SYNTHASES*. Comparison of bacterial and eukaryotic glycogen synthases, which use, respectively, ADP or UDP glucose as donor substrates, with the archaeal enzyme, which can utilize both molecules, allowed us to propose the residues that determine glucosyl donor specificity. In contrast to animal/fungal GS, bacterial GS and plant starch synthase, which are classified in the GT-5 family, are non-regulated enzymes and use ADP glucose exclusively as the source of glucose moieties. Archaeal GS use both ADP- and UDP-glucose as glucosyl donors with similar efficiency [12,13,14] These observations are not unexpected given the higher phylogenetic proximity of eukaryotic to archaeal enzymes in comparison with their bacterial counterparts [15]. We report the crystallographic structure of the archaeal GS from Pyrococcus abyssi, which is the smallest known enzyme of the glycogen/ starch synthase superfamily (GT-3 and GT-5)
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