Abstract
Simple SummaryThe mammalian gut microbiota is an indispensable part of host health. The gut microbiota plays a crucial role in nutrient digestibility, preventing colonization of pathogens and maintaining the host immune system. Host genetics has been conclusively shown to closely related to gut microbiota. Inbreeding can cause a decrease of the host’s genetic diversity, however, remarkably little is understood about the gut microbiota of pigs during inbreeding. The Banna minipig inbred is the world’s first successful large mammalian experimental animal inbred line since 1980 from full and half-siblings of the Diannan small-ear pig. Now, Banna minipig inbred has been inbred for over 37 generations, and the inbreeding coefficient is more than 99%. This study is the first to characterize and compare the composition and function of gut microbiota between the Diannan small-ear pig and Banna minipig inbred, aiming to better understand the influence of inbreeding on the gut microbiota.The gut microbiota coevolve with the host and can be stably transmitted to the offspring. Host genetics plays a crucial role in the composition and abundance of gut microbiota. Inbreeding can cause a decrease of the host’s genetic diversity and the heterozygosity. In this study, we used 16S rRNA gene sequencing to compare the differences of gut microbiota between the Diannan small-ear pig and Banna minipig inbred, aiming to understand the impact of inbreeding on the gut microbiota. Three dominant bacteria (Stenotrophlomonas, Streptococcus, and Lactobacillus) were steadily enriched in both the Diannan small-ear pig and Banna minipig inbred. After inbreeding, the gut microbiota alpha diversity and some potential probiotics (Bifidobacterium, Tricibacter, Ruminocaccae, Christensenellaceae, etc.) were significantly decreased, while the pathogenic Klebsiella bacteria was significantly increased. In addition, the predicted metagenomic analysis (PICRUSt2) indicated that several amino acid metabolisms (‘‘Valine, leucine, and isoleucine metabolism’’, ‘‘Phenylalanine, tyrosine, and tryptophan biosynthesis’’, ‘‘Histidine metabolism’’) were also markedly decreased after the inbreeding. Altogether our data reveal that host inbreeding altered the composition and the predicted function of the gut microbiome, which provides some data for the gut microbiota during inbreeding.
Highlights
The gut microbiota is considered as the second genome of the human body [1]
In the process of inbreeding, there was no significant change in the three dominant bacteria (Stenotrophlomonas, Streptococcus, and Lactobacillus), which belonged to the TOP 4 of the Diannan small-ear pig and the TOP 3 of the Banna minipig inbred, respectively
Similar to gut microbiota diversity, we found the abundance of some beneficial bacteria was significantly reduced in the Banna minipig inbred, while the abundance of Klebsiella was significantly increased
Summary
The gut microbiota is considered as the second genome of the human body [1]. The gut microbiota in the mammalian gastrointestinal plays a vital role in improving host health [2,3], preventing colonization of pathogens, and maintaining the host immune function [4,5]. The vertical transmission of gut microbiota from mother to newborn is thought to cause lifelong host-microbial symbiosis, which plays a crucial part in early infant development [7,8]. Host genetics plays a significant role in the composition and abundance of gut microbiota [9,10,11,12]. Wang et al found that the VDR gene (encoding vitamin D receptor) was related to comprehensive the variation of gut microbiota and individual taxa [18]. Chen et al found that many bacterial communities in pig feces and cecal contents are closely related to host candidate genes, which are mainly related to host metabolism, immune function, and signal transduction [13]
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