1. Knockdown of AMP-activated protein kinase increases the insecticidal efficiency of pymetrozine to Nilaparvata lugens.
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Lin, Yiguang, Ji, Huijun, Cao, Xiaocong, Cen, Yongjie, Chen, Yumei, Ji, Shuangshun, and Zheng, Sichun
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NILAPARVATA lugens , *PROTEIN kinases , *INSECTICIDE application , *PEST control , *AMINO acid sequence , *NEONICOTINOIDS - Abstract
Insecticides are the main tools used to control Nilaparvata lugens (Stål), a serious pest of rice in Asia. However, repeated application of insecticides has caused many negative effects. Reducing the amount of insecticide used, while maintaining good pest population control, would be valuable. AMP-activated protein kinase (AMPK), a sensor of cellular energy status, helps to maintain insect energy balance at the cellular and whole-body level. The role of AMPK in insect response to insecticide stimulation is unknown. We studied the functions of AMPK catalytic subunit alpha (NlAMPKα) in the development of N. lugens and in response to pymetrozine, an insecticide used to control insect pests with piercing-sucking mouthparts. A phylogenetic analysis of protein sequences from 12 species in six orders showed that insects have only the AMPKα 2 subtype. RNA interference against NlAMPKα demonstrated that blocking the AMPK pathway led to a decrease in the systemic ATP level and an increase in N. lugens mortality. NlAMPKα responded to the energy stress caused by pymetrozine treatment, which activated downstream energy metabolic pathways to compensate for the energy imbalance. However, the ATP level in pymetrozine- treated nymphs was not increased, suggesting that ATP is consumed more than synthesized. When NlAMPKα expression was reduced in pymetrozine-treated nymphs by RNAi, the ATP level was decreased and the mortality was significantly increased. At day eight post 0.5 g/3 L of pymetrozine and dsNlAMPKα treatment, nymph survival was 29.33%, which was similar to the 27.33% survival of 1 g/3 L pymetrozine-treated nymphs. Addition of dsNlAMPKα can reduce the concentration of pymetrozine used by 50% while providing comparable efficacy. These results indicate that AMPK helps maintain the energy metabolism of N. lugens in response to pymetrozine treatment. Knockdown of NlAMPKα increases the insecticidal efficiency of pymetrozine to N. lugens. [Display omitted] • NlAMPKα RNAi results in an increase in Nilaparvata lugens mortality. • NlAMPKα is responsive to the energy stress caused by pymetrozine treatment. • Knockdown of NlAMPKα increases the toxicity of pymetrozine to N. lugens. • dsNlAMPKα can reduce 50% pymetrozine used while providing comparable efficacy. • AMPK helps maintain the energy metabolism in pymetrozine-treated N. lugens. [ABSTRACT FROM AUTHOR]
- Published
- 2021
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