Abstract
Human GalNAc-T1 is a ubiquitously expressed mucin-type O-glycosyltransferase that modulates various biological pathways, including immunity, extracellular matrix formation, and salivary gland development and function. However, substrates of GalNAc-T1 are mostly unknown and the mechanistic details of regulation are not well characterized. Here, we investigate the role of the Drosophila melanogaster GalNAc-T1 ortholog PGANT5 in salivary glands and provide structural and biochemical details into its mechanism of O-glycosylation. We find that loss of pgant5 causes irregular secretory granule morphology, altered mucin packaging, and disruption of secretion. Alternative splicing of pgant5 yields two isoforms, pgant5A and pgant5B, with higher expression of pgant5A in salivary glands. Rescue with pgant5A, but not pgant5B, partially restores secretory granule morphology and salivary gland function. A single residue difference within the substrate binding pockets of PGANT5A and PGANT5B increases the in vitro activity and specificity of PGANT5A towards salivary gland mucins relative to PGANT5B, corroborating the in vivo expression and role of pgant5A in salivary glands. Our data additionally provide new insights into a catalytic domain motif that regulates GalNAc-T activity. Overall, our studies illustrate how alternative splicing of an O-glycosyltransferase that results in modest amino acid changes can influence substrate specificity to regulate tissue-specific biological functions.