A midgut transcriptional regulatory loop favors an insect host to withstand a bacterial pathogen
Zhaojiang Guo, Liuhong Zhu, Zhouqiang Cheng, Lina Dong, Le Guo, Yang Bai, Qingjun Wu, Shaoli Wang, Xin Yang, Wen Xie, Neil Crickmore, Xuguo Zhou, René Lafont, Youjun Zhang
Abstract
•Increased titer of the insect hormone 20-hydroxyecdysone (20E) facilitates an insect host, Plutella xylostella, to defeat its bacterial pathogen Bacillus thuringiensis (Bt).•Glucose dehydrogenase (GLD) was identified as a new insect ecdysone-degrading enzyme that can metabolize 20E.•A midgut miRNA initiated epigenetic regulatory pathway represses GLD activity and elevates 20E titer to resist the Bt pathogen.•An as-yet uncharacterized negative feedback loop reduces excess 20E to balance hormonal homeostasis.•This study provides new insights into the immunological landscape of classical insect hormones and the molecular basis of host-pathogen coevolution. Mounting evidence suggests that insect hormones associated with growth and development also participate in pathogen defense. We have discovered a previously undescribed midgut transcriptional control pathway that modulates the availability of 20-hydroxyecdysone (20E) in a worldwide insect pest (Plutella xylostella), allowing it to defeat the major virulence factor of an insect pathogen Bacillus thuringiensis (Bt). A reduction of the transcriptional inhibitor (PxDfd) increases the expression of a midgut microRNA (miR-8545), which in turn represses the expression of a newly identified ecdysteroid-degrading glucose dehydrogenase (PxGLD). Downregulation of PxGLD reduces 20E degradation to increase 20E titer and concurrently triggers a transcriptional negative feedback loop to mitigate 20E overproduction. The moderately elevated 20E titer in the midgut activates a MAPK signaling pathway to increase Bt tolerance/resistance. These findings deepen our understanding of the functions attributed to these classical insect hormones and help inform potential future strategies that can be employed to control insect pests. Mounting evidence suggests that insect hormones associated with growth and development also participate in pathogen defense. We have discovered a previously undescribed midgut transcriptional control pathway that modulates the availability of 20-hydroxyecdysone (20E) in a worldwide insect pest (Plutella xylostella), allowing it to defeat the major virulence factor of an insect pathogen Bacillus thuringiensis (Bt). A reduction of the transcriptional inhibitor (PxDfd) increases the expression of a midgut microRNA (miR-8545), which in turn represses the expression of a newly identified ecdysteroid-degrading glucose dehydrogenase (PxGLD). Downregulation of PxGLD reduces 20E degradation to increase 20E titer and concurrently triggers a transcriptional negative feedback loop to mitigate 20E overproduction. The moderately elevated 20E titer in the midgut activates a MAPK signaling pathway to increase Bt tolerance/resistance. These findings deepen our understanding of the functions attributed to these classical insect hormones and help inform potential future strategies that can be employed to control insect pests.