肥胖儿童进行以肠道微生物群为靶点的饮食干预后肠道耐药基因组的减少。

Diminution of the gut resistome after a gut microbiota-targeted dietary intervention in obese children.

作者信息

Wu Guojun, Zhang Chenhong, Wang Jing, Zhang Feng, Wang Ruirui, Shen Jian, Wang Linghua, Pang Xiaoyan, Zhang Xiaojun, Zhao Liping, Zhang Menghui

机构信息

State Key Laboratory of Microbial Metabolism, Joint International Research Laboratory of Metabolic &Developmental Sciences, and School of Life Sciences and Biotechnology, Shanghai Jiao Tong University, Shanghai, 200240, P.R. China.

出版信息

Sci Rep. 2016 Apr 5;6:24030. doi: 10.1038/srep24030.

DOI:10.1038/srep24030

PMID:27044409

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4820771/

Abstract

The gut microbiome represents an important reservoir of antibiotic resistance genes (ARGs). Effective methods are urgently needed for managing the gut resistome to fight against the antibiotic resistance threat. In this study, we show that a gut microbiota-targeted dietary intervention, which shifts the dominant fermentation of gut bacteria from protein to carbohydrate, significantly diminished the gut resistome and alleviated metabolic syndrome in obese children. Of the non-redundant metagenomic gene catalog of ~2 × 10(6) microbial genes, 399 ARGs were identified in 131 gene types and conferred resistance to 47 antibiotics. Both the richness and diversity of the gut resistome were significantly reduced after the intervention. A total of 201 of the 399 ARGs were carried in 120 co-abundance gene groups (CAGs) directly binned from the gene catalog across both pre-and post-intervention samples. The intervention significantly reduced several CAGs in Klebsiella, Enterobacter and Escherichia, which were the major hubs for multiple resistance gene types. Thus, dietary intervention may become a potentially effective method for diminishing the gut resistome.

摘要

肠道微生物群是抗生素耐药基因（ARGs）的一个重要储存库。迫切需要有效的方法来管理肠道耐药组，以应对抗生素耐药性威胁。在本研究中，我们表明，一种针对肠道微生物群的饮食干预措施，可将肠道细菌的主要发酵类型从蛋白质转变为碳水化合物，能显著减少肠道耐药组，并缓解肥胖儿童的代谢综合征。在约2×10⁶个微生物基因的非冗余宏基因组基因目录中，鉴定出了131种基因类型中的399个ARGs，这些基因对47种抗生素具有抗性。干预后，肠道耐药组的丰富度和多样性均显著降低。在干预前后样本的基因目录中直接分类的120个共丰度基因组（CAGs）中，共携带了399个ARGs中的201个。干预显著减少了克雷伯菌属、肠杆菌属和大肠杆菌中的几个CAGs，这些菌属是多种耐药基因类型的主要聚集点。因此，饮食干预可能成为减少肠道耐药组的一种潜在有效方法。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2b0f/4820771/ef786db161e8/srep24030-f1.jpg

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Antibiotic body burden of Chinese school children: a multisite biomonitoring-based study.中国学童的抗生素体内负荷：一项基于多地点生物监测的研究。

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肥胖儿童进行以肠道微生物群为靶点的饮食干预后肠道耐药基因组的减少。

Diminution of the gut resistome after a gut microbiota-targeted dietary intervention in obese children.

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