Abstract
Nicotine is a plant-derived pyridine alkaloid with potent neurotoxic properties. A major pathway for detoxification of nicotine in mammals is via glucuronidation to produce nicotine N-glucuronide, but this process in insects remains poorly understood. Using mass spectrometry, we demonstrate that Drosophila melanogaster detoxifies nicotine through glycosylation, producing nicotine N-glycoside. Given that many new agrochemicals contain pyridine rings, we also investigated the metabolism of flonicamid and imidacloprid. We detected glycosylation of flonicamid, but not imidacloprid. A targeted RNAi screen across 21 UDP-glycosyltransferases (Ugts) identified Ugt35B1 as important for survival of nicotine exposure. CRISPR-based knockout of Ugt35B1 increases sensitivity to nicotine and flonicamid, but not to imidacloprid, nor to a structurally distinct neonicotinoid (thiamethoxam). Mass spectrometry of knockout and control flies confirms that Ugt35B1 glycosylates nicotine, its metabolite cotinine, and flonicamid. Together these findings establish Ugt35B1 as an important UGT mediating nicotine detoxification in adult D. melanogaster, revealing a previously uncharacterized insect glycosylation pathway with potential implications for herbivory, insecticide detoxification and toxicology.
