Functional characterization of Helicoverpa assulta CYP6B6 in insecticide metabolism.

The oriental tobacco budworm Helicoverpa assulta (Lepidoptera: Noctuidae) is a specialist pest that may cause serious damages to important crops such as chili pepper and tobacco. Various man-made insecticides have been applied to control the infestation of this pest. To understand how this pest copes with insecticides, it is required to identify key players involved in insecticide transformation. In this study, a P450 gene of CYP6B subfamily was identified in the oriental tobacco budworm, and its expression pattern was revealed. Moreover, the activities of HassCYP6B6 against 12 insecticides were explored using recombinant enzymes produced in the facile Escherichia coli. Data from metabolic experiments showed that HassCYP6B6 was able to metabolize conventional insecticides including organophosporates (diazinon, malathion, phoxim), carbamate propoxur, and pyrethroid esfenvalerate, while no significant metabolism was observed towards new-type pesticides such as neonicotinoids (acetamiprid, imidacloprid), diamides (chlorantraniliprole, cyantraniliprole), macrocyclic lactone (emamectin benzoate, ivermectin), and metaflumizone. Structures of metabolites were proposed based on mass spectrometry analyses. The results demonstrate that HassCYP6B6 plays important roles in the transformation of multiple insecticides via substrate-dependent catalytic mechanisms including dehydrogenation, hydroxylation and oxidative desulfurization. The findings have important applied implications for the usage of insecticides. [Display omitted] • A new P450 gene (HassCYP6B6) is identified in Helicoverpa assulta. • The recombinant HassCYP6B6 protein is successfully produced in Escherichia coli. • HassCYP6B6 enzyme is able to metabolize multiple insecticides. • Hydroxylation and desulfuration are common pathways in HassCYP6B6 catalyzed insecticide metabolism. • A unique alkyl dehydrogenated metabolite of propoxur is firstly discovered. [ABSTRACT FROM AUTHOR]