Disequilibrium in chicken gut microflora with avian colibacillosis is related to microenvironment damaged by antibiotics

The avian colibacillosis outbreak is a disease that threatens public health, poultry production, and economic interests, even after antibiotic feed addition. It is known that avian pathogenic E. coli is a major pathogenic factor; however, the systemic characteristics of gut flora in disease samples...

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Veröffentlicht in:	The Science of the total environment 2021-03, Vol.762, p.143058-143058, Article 143058
Hauptverfasser:	Xing, Zhikai, Li, Hui, Li, Meng, Gao, Ran, Guo, Chongye, Mi, Shuangli
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Sprache:	eng
Schlagworte:	Animals Anti-Bacterial Agents Antibiotic resistance Avian colibacillosis Chickens Dynamics balance Escherichia coli Gastrointestinal Microbiome Gut microbiome Humans Intestinal microenvironment Poultry Diseases Virulence
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creator	Xing, Zhikai Li, Hui Li, Meng Gao, Ran Guo, Chongye Mi, Shuangli
description	The avian colibacillosis outbreak is a disease that threatens public health, poultry production, and economic interests, even after antibiotic feed addition. It is known that avian pathogenic E. coli is a major pathogenic factor; however, the systemic characteristics of gut flora in disease samples and how pathogens grow remain unknown. To study these issues in depth, we used the whole microbial genome shotgun sequencing technique to compare entire microbes in diseased and healthy broiler chickens. We found that it was not only E. coli that increased substantially, but most pathogenic flora also increased significantly in diseased samples. Subsequently, we proved that aminoglycoside antibiotic resistance genes were mainly found in non-E. coli strains. This suggests that E. coli survival under antibiotic stress was due to the cooperative resistance from non-E. coli strains. Among all these increasing strains, attaching and effacing pathogens could damage host intestinal epithelial cells to release oxygen in the gut to make the microenvironment more adaptable for E. coli strains. Furthermore, we observed that the functions of the T4SS/T6SS secretion system were dramatically enhanced, which could help E. coli to compete and enlarge their living spaces. Ultimately, pathogenic E. coli accumulated to cause avian colibacillosis. This study provides a new insight into intestinal microecology in diseased individuals, which would propose new treatment options for avian colibacillosis from a metagenome perspective. [Display omitted] •The first time to study microbial systemic characteristics in avian colibacillosis•The synergistic antibiotic resistance of non-E.coli contribute to E.coli survival.•AE pathogens made the gut microenvironment be more adaptable to E.coli strains.•The functions of T4SS/T6SS help E.coli compete and enlarge their living space.•The accumulation of pathogenic E.coli under these conditions leads to the disease.
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It is known that avian pathogenic E. coli is a major pathogenic factor; however, the systemic characteristics of gut flora in disease samples and how pathogens grow remain unknown. To study these issues in depth, we used the whole microbial genome shotgun sequencing technique to compare entire microbes in diseased and healthy broiler chickens. We found that it was not only E. coli that increased substantially, but most pathogenic flora also increased significantly in diseased samples. Subsequently, we proved that aminoglycoside antibiotic resistance genes were mainly found in non-E. coli strains. This suggests that E. coli survival under antibiotic stress was due to the cooperative resistance from non-E. coli strains. Among all these increasing strains, attaching and effacing pathogens could damage host intestinal epithelial cells to release oxygen in the gut to make the microenvironment more adaptable for E. coli strains. Furthermore, we observed that the functions of the T4SS/T6SS secretion system were dramatically enhanced, which could help E. coli to compete and enlarge their living spaces. Ultimately, pathogenic E. coli accumulated to cause avian colibacillosis. This study provides a new insight into intestinal microecology in diseased individuals, which would propose new treatment options for avian colibacillosis from a metagenome perspective. [Display omitted] •The first time to study microbial systemic characteristics in avian colibacillosis•The synergistic antibiotic resistance of non-E.coli contribute to E.coli survival.•AE pathogens made the gut microenvironment be more adaptable to E.coli strains.•The functions of T4SS/T6SS help E.coli compete and enlarge their living space.•The accumulation of pathogenic E.coli under these conditions leads to the disease.</description><identifier>ISSN: 0048-9697</identifier><identifier>EISSN: 1879-1026</identifier><identifier>DOI: 10.1016/j.scitotenv.2020.143058</identifier><identifier>PMID: 33127154</identifier><language>eng</language><publisher>Netherlands: Elsevier B.V</publisher><subject>Animals ; Anti-Bacterial Agents ; Antibiotic resistance ; Avian colibacillosis ; Chickens ; Dynamics balance ; Escherichia coli ; Gastrointestinal Microbiome ; Gut microbiome ; Humans ; Intestinal microenvironment ; Poultry Diseases ; Virulence</subject><ispartof>The Science of the total environment, 2021-03, Vol.762, p.143058-143058, Article 143058</ispartof><rights>2020 Elsevier B.V.</rights><rights>Copyright © 2020 Elsevier B.V. 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Furthermore, we observed that the functions of the T4SS/T6SS secretion system were dramatically enhanced, which could help E. coli to compete and enlarge their living spaces. Ultimately, pathogenic E. coli accumulated to cause avian colibacillosis. This study provides a new insight into intestinal microecology in diseased individuals, which would propose new treatment options for avian colibacillosis from a metagenome perspective. 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subjects	Animals Anti-Bacterial Agents Antibiotic resistance Avian colibacillosis Chickens Dynamics balance Escherichia coli Gastrointestinal Microbiome Gut microbiome Humans Intestinal microenvironment Poultry Diseases Virulence
title	Disequilibrium in chicken gut microflora with avian colibacillosis is related to microenvironment damaged by antibiotics
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