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CYP6DW3 Metabolizes Imidacloprid to Imidacloprid-urea in Whitefly ( Bemisia tabaci ).

Hu XueBuli FuMingjiao HuangChao HeJinjin LiangJing YangXuegao WeiShaonan LiuTianhua DuYao JiCheng YinPeipan GongJinYu HuHe DuRong ZhangChao WangJahangir KhajehaliQi SuXin YangYou-Jun Zhang
Published in: Journal of agricultural and food chemistry (2023)
Bemisia tabaci has developed high resistance to many insecticides and causes substantial agricultural and economic losses annually. The insecticide resistance of whitefly has been widely reported in previous studies; however, the underlying mechanism remains little known. In this study, we cloned two P450 genes: CYP6DW3 and CYP6DW5v1; these genes were markedly overexpressed in imidacloprid-resistant whitefly populations compared with susceptible populations, and knockdown of these genes decreased the imidacloprid resistance of whitefly. Moreover, heterologous expression of whitefly P450 genes in SF9 cells and metabolic studies showed that the CYP6DW3 protein could metabolize 14.11% imidacloprid and produced imidacloprid-urea in vitro . Collectively, the expression levels of CYP6DW3 and CYP6DW5v1 are positively correlated with imidacloprid resistance in B. tabaci . Our study further reveals that cytochrome P450 enzymes affect the physiological activities related to resistance in insects, which helps scholars more deeply understand the resistance mechanism, and contributes to the development of integrated pest management framework.
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