Dietary Exposure to Antibiotic Residues Facilitates Metabolic Disorder by Altering the Gut Microbiota and Bile Acid Composition.
Rou-An ChenWei-Kai WuSuraphan PanyodPo-Yo LiuHsiao-Li ChuangYi-Hsun ChenQiang LyuHsiu-Ching HsuTzu-Lung LinTing-Chin David ShenYu-Tang YangHsin-Bai ZouHuai-Syuan HuangYu-En LinChieh-Chang ChenChi-Tang HoHsin-Chih LaiMing-Shiang WuCheng-Chih HsuLee-Yan SheenPublished in: mSystems (2022)
Antibiotics used as growth promoters in livestock and animal husbandry can be detected in animal-derived food. Epidemiological studies have indicated that exposure to these antibiotic residues in food may be associated with childhood obesity. Herein, the effect of exposure to a residual dose of tylosin-an antibiotic growth promoter-on host metabolism and gut microbiota was explored in vivo . Theoretical maximal daily intake (TMDI) doses of tylosin were found to facilitate high-fat-diet-induced obesity, induce insulin resistance, and perturb gut microbiota composition in mice. The obesity-related phenotypes were transferrable to germfree recipient mice, indicating that the effects of a TMDI dose of tylosin on obesity and insulin resistance occurred mainly via alteration of the gut microbiota. Tylosin TMDI exposure restricted to early life, the critical period of gut microbiota development, altered the abundance of specific bacteria related to host metabolic homeostasis later in life. Moreover, early-life exposure to tylosin TMDI doses was sufficient to modify the ratio of primary to secondary bile acids, thereby inducing lasting metabolic consequences via the downstream FGF15 signaling pathway. Altogether, these findings demonstrate that exposure to very low doses of antibiotic residues, whether continuously or in early life, could exert long-lasting effects on host metabolism by altering the gut microbiota and its metabolites. IMPORTANCE This study demonstrates that even with limited exposure in early life, a residual dose of tylosin might cause long-lasting metabolic disturbances by altering the gut microbiota and its metabolites. Our findings reveal that the gut microbiota is susceptible to previously ignored environmental factors.
Keyphrases
- early life
- high fat diet induced
- insulin resistance
- metabolic syndrome
- type diabetes
- adipose tissue
- high fat diet
- skeletal muscle
- polycystic ovary syndrome
- signaling pathway
- weight loss
- physical activity
- dna methylation
- gene expression
- cell proliferation
- transcription factor
- weight gain
- single cell
- high intensity
- blood pressure
- microbial community