Mammalian mucin-type O-glycosylation is initiated by a large family of ϳ20 UDP-GalNAc:polypeptide ␣-N-acetylgalactosaminyltransferases (ppGalNAc Ts) that transfer ␣-GalNAc from UDP-GalNAc to Ser and Thr residues of polypeptide acceptors. Characterizing the peptide substrate specificity of each isoform is critical to understanding their properties, biological roles, and significance. Presently, only the specificities of ppGalNAc T1, T2, and T10 and the fly orthologues of T1 and T2 have been systematically characterized utilizing random peptide substrates. We now extend these studies to ppGalNAc T3, T5, and T12, transferases variously associated with human disease. Our results reveal several common features; the most striking is the similar pattern of enhancements for the three residues C-terminal to the site of glycosylation for those transferases that contain a common conserved Trp. In contrast, residues N-terminal to the site of glycosylation show a wide range of isoform-specific enhancements, with elevated preferences for Pro, Val, and Tyr being the most common at the ؊1 position. Further analysis reveals that the ratio of positive (Arg, Lys, and His) to negative (Asp and Glu) charged residue enhancements varied among transferases, thus further modulating substrate preference in an isoform-specific manner. By utilizing the obtained transferase-specific preferences, the glycosylation patterns of the ppGalNAc Ts against a series of peptide substrates could roughly be reproduced, demonstrating the potential for predicting isoform-specific glycosylation. We conclude that each ppGalNAc T isoform may be uniquely sensitive to peptide sequence and overall charge, which together dictates the substrate sites that will be glycosylated.Mucin-type O-glycosylation is one of the most common post-translational modifications of secreted and membrane-associated proteins. Glycoproteins containing O-glycosylated mucin domains serve many important biological roles chiefly because of their unique biophysical and structural properties that include an extended peptide conformation and robust resistance to proteases. Consequently, glycoproteins containing O-glycosylated mucin domains function in the protection of the cell surface, the modulation of cell-cell interactions, in the inflammatory and immune response, in metastasis and tumorigenesis, and in protein sorting, targeting, and turnover (for examples see Refs.
