Engineered fungus containing a caterpillar gene kills insects rapidly by disrupting their ecto- and endo-microbiomes.
Song HongHanchun GaoHaimin ChenChengshu WangPublished in: Communications biology (2024)
Similar to the physiological importance of gut microbiomes, recent works have shown that insect ectomicrobiotas can mediate defensive colonization resistance against fungal parasites that infect via cuticle penetration. Here we show that engineering the entomopathogenic fungus Metarhizium robertsii with a potent antibacterial moricin gene from silkworms substantially enhances the ability of the fungus to kill mosquitos, locusts, and two Drosophila species. Further use of Drosophila melanogaster as an infection model, quantitative microbiome analysis reveals that engineered strains designed to suppress insect cuticular bacteria additionally disrupt gut microbiomes. An overgrowth of harmful bacteria such as the opportunistic pathogens of Providencia species is detected that can accelerate insect death. In support, quantitative analysis of antimicrobial genes in fly fat bodies and guts indicates that topical fungal infections result in the compromise of intestinal immune responses. In addition to providing an innovative strategy for improving the potency of mycoinsecticides, our data solidify the importance of both the ecto- and endo-microbiomes in maintaining insect wellbeing.
Keyphrases
- drosophila melanogaster
- aedes aegypti
- genome wide
- genome wide identification
- immune response
- copy number
- high resolution
- adipose tissue
- staphylococcus aureus
- electronic health record
- genome wide analysis
- dna methylation
- dendritic cells
- genetic diversity
- zika virus
- antimicrobial resistance
- mass spectrometry
- fatty acid
- artificial intelligence
- multidrug resistant