The Cross-Resistance Pattern and the Metabolic Resistance Mechanism of Acetamiprid in the Brown Planthopper, Nilaparvata lugens (Stål)
Shuai Wu, Minrong He, Fujin Xia, Xueyi Zhao, Xun Liao, Rongyu Li, Ming Li
Journal:INTERNATIONAL JOURNAL OF MOLECULAR SCIENCES
IF:6.21
DOI:10.3390/ijms23169429
PMID:36012694
Published:2022-08-21
research field:分子生物学细胞信号传导心脏病学
Abstract
Acetamiprid is widely used in paddy fields for controllingNilaparvata lugens(Stål). However, the risk of resistance development, the cross-resistance pattern and the resistance mechanism of acetamiprid in this pest remain unclear. In this study, an acetamiprid-resistant strain (AC-R) was originated from a field strain (UNSEL) through successive selection with acetamiprid for 30 generations, which reached 60.0-fold resistance when compared with a laboratory susceptible strain (AC-S). The AC-R strain (G30) exhibited cross-resistance to thiamethoxam (25.6-fold), nitenpyram (21.4-fold), imidacloprid (14.6-fold), cycloxaprid (11.8-fold), dinotefuran (8.7-fold), sulfoxaflor (7.6-fold) and isoprocarb (8.22-fold), while there was no cross-resistance to etofenprox, buprofezin and chlorpyrifos. Acetamiprid was synergized by the inhibitor piperonyl butoxide (2.2-fold) and the activity of cytochrome P450 monooxygenase was significantly higher in the AC-R strain compared with the AC-S strain, suggesting the critical role of P450. The gene expression results showed that the P450 geneCYP6ER1was significantly overexpressed in AC-R compared with the AC-S and UNSEL strains. In addition, the RNA interference (RNAi) ofCYP6ER1significantly increased the susceptibility of AC-R to acetamiprid. Molecular docking predicted that acetamiprid and CYP6ER1 had close binding sites, and the nitrogen atoms had hydrogen bond interactions with CYP6ER1. These results demonstrated that the overexpression ofCYP6ER1contributed to acetamiprid resistance inN. lugens.Keywords:Nilaparvata lugens;acetamiprid;cross-resistance;cytochrome P450 monooxygenase;resistance mechanism
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