Microbiome-emitted scents activate olfactory neuron-independent airway-gut-brain axis to promote host growth in Drosophila

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Authors: Lee, Jin-Woo ; Lee, Kyung-Ah ; Jang, In-Hwan ; Nam, Kibum ; Kim, Sung-Hee ; Kyung, Minsoo ; Cho, Kyu-Chan ; Lee, Ji-hoon ; You, Hyejin ; Kim, Eun-Kyoung ; Koh, Young Hoon ; Lee, Hansol ; Park, Junsun ; Hwang, Soo-Yeon ; Chung, Youn Wook ; Ryu, Choong-Min ; Kwon, Youngjoo ; Roh, Soung-Hun ; Ryu, Ji-Hwan ; Lee, Won-Jae

MeSH: Animals ; Brain* / metabolism ; Brain-Gut Axis* / physiology ; Butylene Glycols / metabolism ; Butylene Glycols / pharmacology ; Drosophila Proteins / genetics ; Drosophila Proteins / metabolism ; Drosophila melanogaster* / growth & development ; Drosophila melanogaster* / metabolism ; Drosophila melanogaster* / microbiology ; Enteroendocrine Cells / metabolism ; Microbiota* / physiology ; Odorants ; Olfactory Receptor Neurons* / metabolism ; Receptors, Odorant / genetics ; Receptors, Odorant / metabolism ; Signal Transduction ; Smell / physiology ; Somatomedins / metabolism ; Trachea / metabolism

Keywords: 2,3 Butanediol ; Fibroblast Growth Factor ; Drosophila Proteins ; 2,3 Butanediol ; Fibroblast Growth Factor ; Somatomedin ; Drosophila Protein ; Fragrance ; Brain ; Cell ; Fly ; Growth Response ; Olfactory Cue ; Oxygenation ; Signaling ; Airway ; Airway Cell ; Animal Experiment ; Animal Tissue ; Article ; Body Growth ; Brain-gut Axis ; Controlled Study ; Drosophila ; Embryo ; Enteroendocrine Cell ; Hippo Signaling ; Host Microbe Interaction ; Intestine Cell ; Nonhuman ; Odor ; Olfactory Nerve ; Olfactory Receptor ; Signal Transduction ; Smelling ; Trachea ; Animal ; Drosophila Melanogaster ; Genetics ; Growth, Development And Aging ; Metabolism ; Microbiology ; Microflora ; Olfactory Receptor Neuron ; Physiology ; Animals ; Brain ; Brain-gut Axis ; Drosophila Proteins ; Microbiota ; Odorants ; Olfactory Receptor Neurons ; Signal Transduction ; Smell ; Trachea

Abstract: While it is now accepted that the microbiome has strong impacts on animal growth promotion, the exact mechanism has remained elusive. Here we show that microbiome-emitted scents contain volatile somatotrophic factors (VSFs), which promote host growth in an olfaction-independent manner in Drosophila. We found that inhaled VSFs are readily sensed by olfactory receptor 42b non-neuronally expressed in subsets of tracheal airway cells, enteroendocrine cells, and enterocytes. Olfaction-independent sensing of VSFs activates the airway-gut-brain axis by regulating Hippo, FGF and insulin-like growth factor signaling pathways, which are required for airway branching, organ oxygenation and body growth. We found that a mutant microbiome that did not produce (2R,3R)-2,3-butanediol failed to activate the airway-gut-brain axis for host growth. Importantly, forced inhalation of (2R,3R)-2,3-butanediol completely reversed these defects. Our discovery of contact-independent and olfaction-independent airborne interactions between host and microbiome provides a novel perspective on the role of the airway-gut-brain axis in microbiome-controlled host development.