Structural characterization of complex O-linked glycans from insect-derived material

• Published in: Carbohydrate research Vol. 346; no. 9; pp. 1093 - 1104
• Main Authors: Garenaux, Estelle, Maes, Emmanuel, Levêque, S., Brassart, Colette, Guerardel, Yann
• Format: Journal Article
• Language: English
• Published: Netherlands Elsevier Ltd 01.07.2011; Elsevier
• Subjects: Animals; antigens; Apoidea; Biochemistry; Biochemistry, Molecular Biology; Carbohydrate Conformation; Formicidae; fucose; galactose; glycosylation; high performance liquid chromatography; HPLC; Insect; Isobar fractionation; Life Sciences; Mass spectrometry; Mucin; mucins; nests; nuclear magnetic resonance spectroscopy; O-Glycans; phosphates; polysaccharides; Polysaccharides - chemistry; Polysaccharides - isolation & purification; social insects; tandem mass spectrometry; Vespa; Vespula germanica; Vespula vulgaris; Wasps - chemistry; MALDI-TOF; MS; O-Glycans; PEtn; NP-HPLC; RP-HPLC; NMR; Mucin; Le x; HexNAc; dHex; ESI; Hex; GC; Insect; Mass spectrometry; HPLC; DHB; Isobar fractionation
• ISSN: 0008-6215; 1873-426X; 0008-6215
• DOI: 10.1016/j.carres.2011.04.008

[Display omitted] ► Comparison of O-glycosylation ability of two Hymenoptera species. ► Separation of oligosaccharides by a combination of normal and reverse phase HPLC. ► Deciphering of O-glycans structures from insects by MS/MS of permethylated compounds. ► Presence of Le x epitope in wasp mucins. Although insects are among the most diverse groups of the animal kingdom and may be found in nearly all environments, one can observe an obvious lack of structural data on their glycosylation ability. Hymenoptera is the second largest of all insect orders with more than 110.000 identified species and includes the most famous examples of social insects’ species such as wasps, bees and ants. In this report, the structural variety of O-glycans has been studied in two Hymenoptera species. In a previous study, we showed that major O-glycans from common wasp ( Vespula germanica) salivary mucins correspond to T and Tn antigen, eventually substituted by phosphoethanolamine or phosphate groups. More detailed structural analysis performed by mass spectrometry revealed numerous minor O-glycan structures bearing Gal, GlcNAc, GalNAc and Fuc residues. Thus, in order to investigate glycosylation diversity in insects, we used common wasp nest ( V. germanica) and hornet nest ( Vespa cabro) as starting materials. These materials were submitted to reductive β-elimination and the released oligosaccharide–alditols further fractionated by multidimensional HPLC. Tandem mass spectrometry analyses combined with NMR data revealed the presence of various families of complex O-glycans differing accordingly to both core structures and external motifs. Glycans from wasp were characterized by the presence of core types 1 and 2, Lewis X and internal Gal-Gal motifs. We also observed unusual O-glycans containing a reducing GalNAc unit directly substituted by a fucose residue. In contrast, hornet O-glycans appeared as a rather homogeneous family of core 1 type O-glycans extended by galactose oligomers.