Specific Microbial Taxa and Functional Capacity Contribute to Chicken Abdominal Fat Deposition

Genetically selected chickens with better growth and early maturation show an incidental increase in abdominal fat deposition (AFD). Accumulating evidence reveals a strong association between gut microbiota and adiposity. However, studies focusing on the role of gut microbiota in chicken obesity in...

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Published inFrontiers in microbiology Vol. 12; p. 643025
Main Authors Xiang, Hai, Gan, Jiankang, Zeng, Daoshu, Li, Jing, Yu, Hui, Zhao, Haiquan, Yang, Ying, Tan, Shuwen, Li, Gen, Luo, Chaowei, Xie, Zhuojun, Zhao, Guiping, Li, Hua
Format Journal Article
LanguageEnglish
Published Switzerland Frontiers Media S.A 17.03.2021
Subjects
abdominal fat deposition
cecal microbiota
chickens
metabolism capacity
microbial composition
microbial functional
Microbiology
chickens
metabolism capacity
microbial functional
cecal microbiota
abdominal fat deposition
microbial composition
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Abstract Genetically selected chickens with better growth and early maturation show an incidental increase in abdominal fat deposition (AFD). Accumulating evidence reveals a strong association between gut microbiota and adiposity. However, studies focusing on the role of gut microbiota in chicken obesity in conventional breeds are limited. Therefore, 400 random broilers with different levels of AFD were used to investigate the gut microbial taxa related to AFD by 16S rRNA gene sequencing of 76 representative samples, and to identify the specific microbial taxa contributing to fat-related metabolism using shotgun metagenomic analyses of eight high and low AFD chickens. The results demonstrated that the richness and diversity of the gut microbiota decrease as the accumulation of chicken abdominal fat increases. The decrease of Bacteroidetes and the increase of Firmicutes were correlated with the accumulation of chicken AFD. The Bacteroidetes phylum, including the genera Bacteroides , Parabacteroides , and the species, B. salanitronis , B. fragilis , and P. distasonis , were correlated to alleviate obesity by producing secondary metabolites. Several genera of Firmicutes phylum with circulating lipoprotein lipase activity were linked to the accumulation of chicken body fat. Moreover, the genera, Olsenella and Slackia , might positively contribute to fat and energy metabolism, whereas the genus, Methanobrevibacter , was possible to enhance energy capture, and associated to accumulate chicken AFD. These findings provide insights into the roles of the gut microbiota in complex traits and contribute to the development of effective therapies for the reduction of chicken fat accumulation.
AbstractList Genetically selected chickens with better growth and early maturation show an incidental increase in abdominal fat deposition (AFD). Accumulating evidence reveals a strong association between gut microbiota and adiposity. However, studies focusing on the role of gut microbiota in chicken obesity in conventional breeds are limited. Therefore, 400 random broilers with different levels of AFD were used to investigate the gut microbial taxa related to AFD by 16S rRNA gene sequencing of 76 representative samples, and to identify the specific microbial taxa contributing to fat-related metabolism using shotgun metagenomic analyses of eight high and low AFD chickens. The results demonstrated that the richness and diversity of the gut microbiota decrease as the accumulation of chicken abdominal fat increases. The decrease of Bacteroidetes and the increase of Firmicutes were correlated with the accumulation of chicken AFD. The Bacteroidetes phylum, including the genera Bacteroides , Parabacteroides , and the species, B. salanitronis , B. fragilis , and P. distasonis , were correlated to alleviate obesity by producing secondary metabolites. Several genera of Firmicutes phylum with circulating lipoprotein lipase activity were linked to the accumulation of chicken body fat. Moreover, the genera, Olsenella and Slackia , might positively contribute to fat and energy metabolism, whereas the genus, Methanobrevibacter , was possible to enhance energy capture, and associated to accumulate chicken AFD. These findings provide insights into the roles of the gut microbiota in complex traits and contribute to the development of effective therapies for the reduction of chicken fat accumulation.
Genetically selected chickens with better growth and early maturation show an incidental increase in abdominal fat deposition (AFD). Accumulating evidence reveals a strong association between gut microbiota and adiposity. However, studies focusing on the role of gut microbiota in chicken obesity in conventional breeds are limited. Therefore, 400 random broilers with different levels of AFD were used to investigate the gut microbial taxa related to AFD by 16S rRNA gene sequencing of 76 representative samples, and to identify the specific microbial taxa contributing to fat-related metabolism using shotgun metagenomic analyses of eight high and low AFD chickens. The results demonstrated that the richness and diversity of the gut microbiota decrease as the accumulation of chicken abdominal fat increases. The decrease of Bacteroidetes and the increase of Firmicutes were correlated with the accumulation of chicken AFD. The Bacteroidetes phylum, including the genera Bacteroides, Parabacteroides, and the species, B. salanitronis, B. fragilis, and P. distasonis, were correlated to alleviate obesity by producing secondary metabolites. Several genera of Firmicutes phylum with circulating lipoprotein lipase activity were linked to the accumulation of chicken body fat. Moreover, the genera, Olsenella and Slackia, might positively contribute to fat and energy metabolism, whereas the genus, Methanobrevibacter, was possible to enhance energy capture, and associated to accumulate chicken AFD. These findings provide insights into the roles of the gut microbiota in complex traits and contribute to the development of effective therapies for the reduction of chicken fat accumulation.
Genetically selected chickens with better growth and early maturation show an incidental increase in abdominal fat deposition (AFD). Accumulating evidence reveals a strong association between gut microbiota and adiposity. However, studies focusing on the role of gut microbiota in chicken obesity in conventional breeds are limited. Therefore, 400 random broilers with different levels of AFD were used to investigate the gut microbial taxa related to AFD by 16S rRNA gene sequencing of 76 representative samples, and to identify the specific microbial taxa contributing to fat-related metabolism using shotgun metagenomic analyses of eight high and low AFD chickens. The results demonstrated that the richness and diversity of the gut microbiota decrease as the accumulation of chicken abdominal fat increases. The decrease of Bacteroidetes and the increase of Firmicutes were correlated with the accumulation of chicken AFD. The Bacteroidetes phylum, including the genera , , and the species, , , and , were correlated to alleviate obesity by producing secondary metabolites. Several genera of Firmicutes phylum with circulating lipoprotein lipase activity were linked to the accumulation of chicken body fat. Moreover, the genera, and , might positively contribute to fat and energy metabolism, whereas the genus, , was possible to enhance energy capture, and associated to accumulate chicken AFD. These findings provide insights into the roles of the gut microbiota in complex traits and contribute to the development of effective therapies for the reduction of chicken fat accumulation.
Genetically selected chickens with better growth and early maturation show an incidental increase in abdominal fat deposition (AFD). Accumulating evidence reveals a strong association between gut microbiota and adiposity. However, studies focusing on the role of gut microbiota in chicken obesity in conventional breeds are limited. Therefore, 400 random broilers with different levels of AFD were used to investigate the gut microbial taxa related to AFD by 16S rRNA gene sequencing of 76 representative samples, and to identify the specific microbial taxa contributing to fat-related metabolism using shotgun metagenomic analyses of eight high and low AFD chickens. The results demonstrated that the richness and diversity of the gut microbiota decrease as the accumulation of chicken abdominal fat increases. The decrease of Bacteroidetes and the increase of Firmicutes were correlated with the accumulation of chicken AFD. The Bacteroidetes phylum, including the genera Bacteroides, Parabacteroides, and the species, B. salanitronis, B. fragilis, and P. distasonis, were correlated to alleviate obesity by producing secondary metabolites. Several genera of Firmicutes phylum with circulating lipoprotein lipase activity were linked to the accumulation of chicken body fat. Moreover, the genera, Olsenella and Slackia, might positively contribute to fat and energy metabolism, whereas the genus, Methanobrevibacter, was possible to enhance energy capture, and associated to accumulate chicken AFD. These findings provide insights into the roles of the gut microbiota in complex traits and contribute to the development of effective therapies for the reduction of chicken fat accumulation.Genetically selected chickens with better growth and early maturation show an incidental increase in abdominal fat deposition (AFD). Accumulating evidence reveals a strong association between gut microbiota and adiposity. However, studies focusing on the role of gut microbiota in chicken obesity in conventional breeds are limited. Therefore, 400 random broilers with different levels of AFD were used to investigate the gut microbial taxa related to AFD by 16S rRNA gene sequencing of 76 representative samples, and to identify the specific microbial taxa contributing to fat-related metabolism using shotgun metagenomic analyses of eight high and low AFD chickens. The results demonstrated that the richness and diversity of the gut microbiota decrease as the accumulation of chicken abdominal fat increases. The decrease of Bacteroidetes and the increase of Firmicutes were correlated with the accumulation of chicken AFD. The Bacteroidetes phylum, including the genera Bacteroides, Parabacteroides, and the species, B. salanitronis, B. fragilis, and P. distasonis, were correlated to alleviate obesity by producing secondary metabolites. Several genera of Firmicutes phylum with circulating lipoprotein lipase activity were linked to the accumulation of chicken body fat. Moreover, the genera, Olsenella and Slackia, might positively contribute to fat and energy metabolism, whereas the genus, Methanobrevibacter, was possible to enhance energy capture, and associated to accumulate chicken AFD. These findings provide insights into the roles of the gut microbiota in complex traits and contribute to the development of effective therapies for the reduction of chicken fat accumulation.
Author Yu, Hui
Tan, Shuwen
Li, Hua
Yang, Ying
Luo, Chaowei
Gan, Jiankang
Li, Jing
Zeng, Daoshu
Zhao, Haiquan
Zhao, Guiping
Xiang, Hai
Li, Gen
Xie, Zhuojun
AuthorAffiliation 1 Guangdong Provincial Key Laboratory of Animal Molecular Design and Precise Breeding, Foshan University , Foshan , China
4 Institute of Animal Sciences, Chinese Academy of Agricultural Sciences , Beijing , China
2 Guangdong Tinoo’s Foods Group Co., Ltd. , Qingyuan , China
3 Xianxi Biotechnology Co. Ltd , Foshan , China
AuthorAffiliation_xml – name: 1 Guangdong Provincial Key Laboratory of Animal Molecular Design and Precise Breeding, Foshan University , Foshan , China
– name: 2 Guangdong Tinoo’s Foods Group Co., Ltd. , Qingyuan , China
– name: 3 Xianxi Biotechnology Co. Ltd , Foshan , China
– name: 4 Institute of Animal Sciences, Chinese Academy of Agricultural Sciences , Beijing , China
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Copyright Copyright © 2021 Xiang, Gan, Zeng, Li, Yu, Zhao, Yang, Tan, Li, Luo, Xie, Zhao and Li.
Copyright © 2021 Xiang, Gan, Zeng, Li, Yu, Zhao, Yang, Tan, Li, Luo, Xie, Zhao and Li. 2021 Xiang, Gan, Zeng, Li, Yu, Zhao, Yang, Tan, Li, Luo, Xie, Zhao and Li
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Keywords chickens
metabolism capacity
microbial functional
cecal microbiota
abdominal fat deposition
microbial composition
Language English
License Copyright © 2021 Xiang, Gan, Zeng, Li, Yu, Zhao, Yang, Tan, Li, Luo, Xie, Zhao and Li.
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Edited by: Xudong Sun, Heilongjiang Bayi Agricultural University, China
Reviewed by: Young Min Kwon, University of Arkansas, United States; Marcello Abbondio, University of Sassari, Italy
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Snippet Genetically selected chickens with better growth and early maturation show an incidental increase in abdominal fat deposition (AFD). Accumulating evidence...
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SubjectTerms abdominal fat deposition
cecal microbiota
chickens
metabolism capacity
microbial composition
microbial functional
Microbiology
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Title Specific Microbial Taxa and Functional Capacity Contribute to Chicken Abdominal Fat Deposition
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Volume 12
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