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Primary succession of Bifidobacteria drives pathogen resistance in neonatal microbiota assembly
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Primary succession of Bifidobacteria drives pathogen resistance in neonatal microbiota assembly
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Journal Article
Primary succession of Bifidobacteria drives pathogen resistance in neonatal microbiota assembly
2024
Overview
Human microbiota assembly commences at birth, seeded by both maternal and environmental microorganisms. Ecological theory postulates that primary colonizers dictate microbial community assembly outcomes, yet such microbial priority effects in the human gut remain underexplored. Here using longitudinal faecal metagenomics, we characterized neonatal microbiota assembly for a cohort of 1,288 neonates from the UK. We show that the pioneering neonatal gut microbiota can be stratified into one of three distinct community states, each dominated by a single microbial species and influenced by clinical and host factors, such as maternal age, ethnicity and parity. A community state dominated by
Enterococcus faecalis
displayed stochastic microbiota assembly with persistent high pathogen loads into infancy. In contrast, community states dominated by
Bifidobacterium
, specifically
B. longum
and particularly
B. breve
, exhibited a stable assembly trajectory and long-term pathogen colonization resistance, probably due to strain-specific functional adaptions to a breast milk-rich neonatal diet. Consistent with our human cohort observation,
B. breve
demonstrated priority effects and conferred pathogen colonization resistance in a germ-free mouse model. Our findings solidify the crucial role of Bifidobacteria as primary colonizers in shaping the microbiota assembly and functions in early life.
Primary colonization by microbial communities dominated by Bifidobacteria contribute to stable gut microbiota assembly and long-term pathogen resistance in neonates.
Publisher
Nature Publishing Group UK,Nature Publishing Group
