Whole genome metagenomic analysis of the gut microbiome of differently fed infants identifies differences in microbial composition and functional genes, including an absent CRISPR/Cas9 gene in the formula-fed cohort
Matthew D. Di Guglielmo , Karl Franke , Courtney Cox , Erin L. Crowgey
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引用次数: 7
Abstract
Background
Advancements in sequencing capabilities have enhanced the study of the human microbiome. There are limited studies focused on the gastro-intestinal (gut) microbiome of infants, particularly the impact of diet between breast-fed (BF) versus formula-fed (FF). It is unclear what effect, if any, early feeding has on short-term or long-term composition and function of the gut microbiome.
Results
Using a shotgun metagenomics approach, differences in the gut microbiome between BF (n = 10) and FF (n = 5) infants were detected. A Jaccard distance principle coordinate analysis was able to cluster BF versus FF infants based on the presence or absence of species identified in their gut microbiome. Thirty-two genera were identified as statistically different in the gut microbiome sequenced between BF and FF infants. Furthermore, the computational workflow identified 371 bacterial genes that were statistically different between the BF and FF cohorts in abundance. Only seven genes were lower in abundance (or absent) in the FF cohort compared to the BF cohort, including CRISPR/Cas9; whereas, the remaining candidates, including autotransporter adhesins, were higher in abundance in the FF cohort compared to BF cohort.
Conclusions
These studies demonstrated that FF infants have, at an early age, a significantly different gut microbiome with potential implications for function of the fecal microbiota. Interactions between the fecal microbiota and host hinted at here have been linked to numerous diseases. Determining whether these non-abundant or more abundant genes have biological consequence related to infant feeding may aid in understanding the adult gut microbiome, and the pathogenesis of obesity.
期刊介绍:
The innumerable microbes living in and on our bodies are known to affect human wellbeing, but our knowledge of their role is still at the very early stages of understanding. Human Microbiome is a new open access journal dedicated to research on the impact of the microbiome on human health and disease. The journal will publish original research, reviews, comments, human microbe descriptions and genome, and letters. Topics covered will include: the repertoire of human-associated microbes, therapeutic intervention, pathophysiology, experimental models, physiological, geographical, and pathological changes, and technical reports; genomic, metabolomic, transcriptomic, and culturomic approaches are welcome.
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