The primary sequence of the esterase 6 (EST6) enzyme of Drosophila melanogaster contains four potential N-linked glycosylation sites, at residues 21, 399, 435, and 485. Here we determine the extent to which EST6 is glycosylated and how the glycosylation affects the biochemistry and physiology of the enzyme. We have abolished each of the four potential glycosylation sites by replacing the required Asn residues with Gln by in vitro mutagenesis. Five mutant genes were made, four containing mutations of each site individually and the fifth site containing all four mutations. Germline transformation was used to introduce the mutant genes into a strain of D. melanogaster null for EST6. Electrophoretic and Western blot comparisons of the mutant strains and wild-type controls showed that each of the four potential N-linked glycosylation sites in the wild-type protein is glycosylated. However, the fourth site is not utilized on all EST6 molecules, resulting in two molecular forms of the enzyme. Digestion with specific endoglycosidases showed that the glycan attached at the second site is of the high-mannose type, while the other three sites carry more complex oligosaccharides. The thermostability of the enzyme is not affected by abolition of the first, third, or fourth glycosylation sites but is reduced by abolition of the second site. Anomalously, abolition of all four sites together does not reduce thermostability. Quantitative comparisons of EST6 activities showed that abolition of glycosylation does not affect the secretion of the enzyme into the male sperm ejaculatory duct, its transfer to the female vagina during mating, or its subsequent translocation into her hemolymph. However, the activity of the mutant enzymes does not persist in the female's hemolymph for as long as wild-type esterase 6. The latter effect may compromise the role of the transferred enzyme in stimulating egg-laying and delaying receptivity to remating.