posted on 2014-04-01, 00:00authored byKin Kuan Hoi, Phillip
J. Daborn, Paul Battlay, Charles Robin, Philip Batterham, Richard A. J. O’Hair, William A. Donald
Insecticide resistance is one of
the most prevalent examples of
anthropogenic genetic change, yet our understanding of metabolic-based
resistance remains limited by the analytical challenges associated
with rapidly tracking the in vivo metabolites of
insecticides at nonlethal doses. Here, using twin ion mass spectrometry
analysis of the extracts of whole Drosophila larvae and excreta, we show that (i) eight metabolites of the neonicotinoid
insecticide, imidacloprid, can be detected when formed by susceptible
larval genotypes and (ii) the specific overtranscription of a single
gene product, Cyp6g1, associated with the metabolic
resistance to neonicotinoids, results in a significant increase in
the formation of three imidacloprid metabolites that are formed in
C–H bond activation reactions; that is, Cyp6g1 is directly linked to the enhanced metabolism of imidacloprid in vivo. These results establish a rapid and sensitive method
for dissecting the metabolic machinery of insects by directly linking
single gene products to insecticide metabolism.