Convergent temporal dynamics of the human infant gut microbiota

Trosvik, Pål; Stenseth, Nils Chr.; Rudi, Knut

doi:10.1038/ismej.2009.96

Cited by 91 publications

(91 citation statements)

References 31 publications

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“…In infants, early assembly of the gut microbiota has been linked to development of innate immune responses and terminal differentiation of intestinal structures (4). The dynamic process of colonization has been well studied at high taxonomic levels (5) and seems predictable based on competitive interactions between and within the dominant phyla (6). Yet at lower taxonomic levels, and at early stages of development, our knowledge of this process is incomplete.…”

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confidence: 99%

Strain-resolved community genomic analysis of gut microbial colonization in a premature infant

Morowitz

Denef

Costello³

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

186

169

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The intestinal microbiome is a critical determinant of human health. Alterations in its composition have been correlated with chronic disorders, such as obesity and inflammatory bowel disease in adults, and may be associated with neonatal necrotizing enterocolitis in premature infants. Increasing evidence suggests that strain-level genomic variation may underpin distinct ecological trajectories within mixed populations, yet there have been few strain-resolved analyses of genotype–phenotype connections in the context of the human ecosystem. Here, we document strain-level genomic divergence during the first 3 wk of life within the fecal microbiota of an infant born at 28-wk gestation. We observed three compositional phases during colonization, and reconstructed and intensively curated population genomic datasets from the third phase. The relative abundance of two Citrobacter strains sharing ~99% nucleotide identity changed significantly over time within a community dominated by a nearly clonal Serratia population and harboring a lower abundance Enterococcus population and multiple plasmids and bacteriophage. Modeling of Citrobacter strain abundance suggests differences in growth rates and host colonization patterns. We identified genotypic variation potentially responsible for divergent strain ecologies, including hotspots of sequence variation in regulatory genes and intergenic regions, and in genes involved in transport, flagellar biosynthesis, substrate metabolism, and host colonization, as well as differences in the complements of these genes. Our results demonstrate that a community genomic approach can elucidate gut microbial colonization at the resolution required to discern medically relevant strain and species population dynamics, and hence improve our ability to diagnose and treat microbial community-mediated disorders.

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mentioning

confidence: 99%

Strain-resolved community genomic analysis of gut microbial colonization in a premature infant

Morowitz

Denef

Costello³

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

186

169

View full text Add to dashboard Cite

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“…Importantly, our results show variability between replicate communities at the functional level (assessed in this study by redox potential) as well as at the taxon level. In our microcosms, as in environmental microbial communities (Trosvik et al, 2010;Burke et al, 2011), it is likely that the set of key microbial ecotypes that is present is reproducible across microcosms. However, our results suggest that variability at the taxon level can have a substantial effect on community function, even between replicate microcosms.…”

Section: Predictability Of Microbial Ecosystem Developmentmentioning

confidence: 99%

Community history affects the predictability of microbial ecosystem development

et al. 2013

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Microbial communities mediate crucial biogeochemical, biomedical and biotechnological processes, yet our understanding of their assembly, and our ability to control its outcome, remain poor. Existing evidence presents conflicting views on whether microbial ecosystem assembly is predictable, or inherently unpredictable. We address this issue using a well-controlled laboratory model system, in which source microbial communities colonize a pristine environment to form complex, nutrient-cycling ecosystems. When the source communities colonize a novel environment, final community composition and function (as measured by redox potential) are unpredictable, although a signature of the community's previous history is maintained. However, when the source communities are pre-conditioned to their new habitat, community development is more reproducible. This situation contrasts with some studies of communities of macro-organisms, where strong selection under novel environmental conditions leads to reproducible community structure, whereas communities under weaker selection show more variability. Our results suggest that the microbial rare biosphere may have an important role in the predictability of microbial community development, and that pre-conditioning may help to reduce unpredictability in the design of microbial communities for biotechnological applications.

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“…Our study reports, for the first time, the application of GAM models to elucidate the microbial ecology of specific functional traits in mangrove sediments. These niche-based species distribution models [76] have been applied to a wide range of plants, macroorganisms and microorganisms [14,[77][78][79] and consist of observations of species over a gradient of environmental parameters (or "predictors") that can have a direct or indirect effect on the establishment or survival of the species at a limited time period. GAM models assume pseudo-equilibrium between the environmental parameters and the species spatial pattern underlying the realized niche for the species studied [76].…”

Section: Discussionmentioning

confidence: 99%

Phylogenetic Diversity of Diazotrophs along an Experimental Nutrient Gradient in Mangrove Sediments

Romero

Jacobson-Meyers

Fuhrman

et al. 2015

JMSE

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Abstract:The diversity of diazotrophs was studied in the sediment of mangrove forests (Twin Cays, Belize) subjected to a long-term fertilization with nitrogen and phosphorus. Terminal Restriction Fragment Length Polymorphism (TRFLP) and cloning of PCR-amplified nifH genes were combined via in silico analysis to assign clones to TRFLP-nifH phylotypes, as well as to characterize the occurrence of phylotypes in response to environmental conditions. Results indicated that mangrove sediments from Belize harbor a unique diazotrophic community with a low metabolic diversity dominated by sulfate reducers. The variability of potential nitrogen-fixing sulfate reducers was explained by several environmental parameters, primarily by the abundance of dead roots in the sediments, and the concentration of H2S in the pore-waters. This study describes the complexity of microbial communities within the mangrove sediments with specific functional groups varying along environmental gradients.

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Convergent temporal dynamics of the human infant gut microbiota

Cited by 91 publications

References 31 publications

Strain-resolved community genomic analysis of gut microbial colonization in a premature infant

Strain-resolved community genomic analysis of gut microbial colonization in a premature infant

Community history affects the predictability of microbial ecosystem development

Phylogenetic Diversity of Diazotrophs along an Experimental Nutrient Gradient in Mangrove Sediments

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