Functional and metabolic alterations of gut microbiota in children with new-onset type 1 diabetes

Xiaoxiao Yuan(Children's Hospital of Fudan University), Ruirui Wang(Shanghai University of Traditional Chinese Medicine), Bing Han(Fudan University), Chengjun Sun(Children's Hospital of Fudan University), Ruimin Chen(Fujian Medical University), Haiyan Wei(Zhengzhou University), Linqi Chen(Soochow University), Hongwei Du(Jilin University), Guimei Li(Shandong Provincial Hospital), Yu Yang(Nanchang University), Xiaojuan Chen, Lanwei Cui(Harbin Medical University), Zhenran Xu(Children's Hospital of Fudan University), Junfen Fu(Children's Hospital of Zhejiang University), Jin Wu(Sichuan University), Wei Gu(Second Affiliated Hospital of Nanjing Medical University), Zhihong Chen(Qingdao University), Xin Fang(Fujian Medical University), Hongxiu Yang(Qingdao University), Zhe Su(Shenzhen Children's Hospital), Jing Wu(Sichuan University), Qiuyue Li(Children's Hospital of Fudan University), Miaoying Zhang(Children's Hospital of Fudan University), Yufeng Zhou(Fudan University), Lei Zhang(Shanghai University of Traditional Chinese Medicine), Guang Ji(Shanghai University of Traditional Chinese Medicine), Feihong Luo(Children's Hospital of Fudan University)
Nature Communications
October 26, 2022
10.1038/s41467-022-33656-4
Cited by 147Open Access
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Abstract

Gut dysbiosis has been linked to type 1 diabetes (T1D); however, microbial capacity in T1D remains unclear. Here, we integratively profiled gut microbial functional and metabolic alterations in children with new-onset T1D in independent cohorts and investigated the underlying mechanisms. In T1D, the microbiota was characterized by decreased butyrate production and bile acid metabolism and increased lipopolysaccharide biosynthesis at the species, gene, and metabolite levels. The combination of 18 bacterial species and fecal metabolites provided excellently discriminatory power for T1D. Gut microbiota from children with T1D induced elevated fasting glucose levels and declined insulin sensitivity in antibiotic-treated mice. In streptozotocin-induced T1D mice, butyrate and lipopolysaccharide exerted protective and destructive effects on islet structure and function, respectively. Lipopolysaccharide aggravated the pancreatic inflammatory response, while butyrate activated Insulin1 and Insulin2 gene expression. Our study revealed perturbed microbial functional and metabolic traits in T1D, providing potential avenues for microbiome-based prevention and intervention for T1D.

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