Charge matters: how flanking substrate charge modulates O-glycan Core elongation
Collin J Ballard, Matthew R Smutny, Lam D Chau, Collin K Wong, Haley M Aharoni, Hana K Lee, Digantkumar G Chapla, Ramon Hurtado-Guerrero, Kelley W Moremen, Thomas A Gerken. Glycobiology, cwaf014, https://doi.org/10.1093/glycob/cwaf014
Published: 10 March 2025
Mucin type O-glycan core elongation is typically performed by the C1GALT1, B3GNT6, and ST6GalNAc-I/-II O-glycosyltransferases. These enzymes target the Tn antigen (GalNAc-O-Thr/Ser) dictating the fate of O-glycan elongation, playing important roles in health and disease. Changes in transferase expression and glycan structure are commonly associated with diseases such as cancer, Tn-syndrome, and ulcerative colitis. Despite their significance, their substrate specificities and their biological roles remain elusive. Here, we examine the roles of flanking glycopeptide substrate charge using a library of differently charged glycopeptides and a small library of PSGL-1 Thr57 based charged glycopeptides. We found that C1GALT1 was most influenced by flanking charge preferring negatively charged substrates, while B3GNT6 and ST6GalNAc-II were less influenced, showing unique N- and C-terminal charge preferences. Interestingly, ST6GalNAc-I was not influenced by flanking charge. These charge specificities were further maintained against the charged PSGL-1 glycopeptides, although ST6GalNAc-I showed an increased preference towards a remote N-terminal positive charge. The observed charge preferences were to a large part driven by substrate interactions with the electrostatic surface of the transferase. We propose that negative flanking charge may assist C1GALT1 in targeting key glycosites such as in PSGL-1 and podoplanin. Our findings are consistent with a Golgi hierarchy, where the cis-Golgi localized GalNAc-Ts and C1GALT1 determine the site and thus fate of glycosylation, while the trans-Golgi less-specific ST6GalNAc-I provides a final capping function. This characterization of substrate charge preference furthers our understanding of how these enzymes select their substrates and may contribute to our understanding of their biological roles.
Mucin type O-glycan core elongation is typically performed by the C1GALT1, B3GNT6, and ST6GalNAc-I/-II O-glycosyltransferases. These enzymes target the Tn antigen (GalNAc-O-Thr/Ser) dictating the fate of O-glycan elongation, playing important roles in health and disease. Changes in transferase expression and glycan structure are commonly associated with diseases such as cancer, Tn-syndrome, and ulcerative colitis. Despite their significance, their substrate specificities and their biological roles remain elusive. Here, we examine the roles of flanking glycopeptide substrate charge using a library of differently charged glycopeptides and a small library of PSGL-1 Thr57 based charged glycopeptides. We found that C1GALT1 was most influenced by flanking charge preferring negatively charged substrates, while B3GNT6 and ST6GalNAc-II were less influenced, showing unique N- and C-terminal charge preferences. Interestingly, ST6GalNAc-I was not influenced by flanking charge. These charge specificities were further maintained against the charged PSGL-1 glycopeptides, although ST6GalNAc-I showed an increased preference towards a remote N-terminal positive charge. The observed charge preferences were to a large part driven by substrate interactions with the electrostatic surface of the transferase. We propose that negative flanking charge may assist C1GALT1 in targeting key glycosites such as in PSGL-1 and podoplanin. Our findings are consistent with a Golgi hierarchy, where the cis-Golgi localized GalNAc-Ts and C1GALT1 determine the site and thus fate of glycosylation, while the trans-Golgi less-specific ST6GalNAc-I provides a final capping function. This characterization of substrate charge preference furthers our understanding of how these enzymes select their substrates and may contribute to our understanding of their biological roles.