Abstract
Human ABO(H) blood group glycosyltransferases GTA and GTB catalyze the final monosaccharide addition in the biosynthesis of the human A and B blood group antigens. GTA and GTB utilize a common acceptor, the H antigen disaccharide alpha-l-Fucp-(1-->2)-beta-d-Galp-OR, but different donors, where GTA transfers GalNAc from UDP-GalNAc and GTB transfers Gal from UDP-Gal. GTA and GTB are two of the most homologous enzymes known to transfer different donors and differ in only 4 amino acid residues, but one in particular (Leu/Met-266) has been shown to dominate the selection between donor sugars. The structures of the A and B glycosyltransferases have been determined to high resolution in complex with two inhibitory acceptor analogs alpha-l-Fucp(1-->2)-beta-d-(3-deoxy)-Galp-OR and alpha-l-Fucp-(1-->2)-beta-d-(3-amino)-Galp-OR, in which the 3-hydroxyl moiety of the Gal ring has been replaced by hydrogen or an amino group, respectively. Remarkably, although the 3-deoxy inhibitor occupies the same conformation and position observed for the native H antigen in GTA and GTB, the 3-amino analog is recognized differently by the two enzymes. The 3-amino substitution introduces a novel intramolecular hydrogen bond between O2' on Fuc and N3' on Gal, which alters the minimum-energy conformation of the inhibitor. In the absence of UDP, the 3-amino analog can be accommodated by either GTA or GTB with the l-Fuc residue partially occupying the vacant UDP binding site. However, in the presence of UDP, the analog is forced to abandon the intramolecular hydrogen bond, and the l-Fuc residue is shifted to a less ordered conformation. Further, the residue Leu/Met-266 that was thought important only in distinguishing between donor substrates is observed to interact differently with the 3-amino acceptor analog in GTA and GTB. These observations explain why the 3-deoxy analog acts as a competitive inhibitor of the glycosyltransferase reaction, whereas the 3-amino analog displays complex modes of inhibition.
Highlights
Observations explain why the 3-deoxy analog acts as a competitive inhibitor of the glycosyltransferase reaction, whereas the 3-amino analog displays complex modes of inhibition
Glycosyltransferases in general have been implicated as indicators of cancer progression, susceptibility to infectious diseases, glycoprotein activity, and heart and autoimmune diseases, and the human ABO(H) blood group glycosyltransferases in particular are viewed as a model system for the study of action and specificity of this class of enzyme
When the primary structures of GTA and GTB were determined, it was found that they differ in only four amino acid residues which, given that they share a common acceptor, were assumed to confer their ability to distinguish between the donor substrate molecules (3)
Summary
Observations explain why the 3-deoxy analog acts as a competitive inhibitor of the glycosyltransferase reaction, whereas the 3-amino analog displays complex modes of inhibition. Glycosyltransferases in general have been implicated as indicators of cancer progression, susceptibility to infectious diseases, glycoprotein activity, and heart and autoimmune diseases (for review, see Ref. 2), and the human ABO(H) blood group glycosyltransferases in particular are viewed as a model system for the study of action and specificity of this class of enzyme. When the primary structures of GTA and GTB were determined, it was found that they differ in only four amino acid residues which, given that they share a common acceptor, were assumed to confer their ability to distinguish between the donor substrate molecules (3). It was estimated that Ki for the 3-amino analog is in the 200-nM range for GTA (5, 6)
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