Nutrient dominance governs the assembly of microbial communities in mixed nutrient environments

Estrela, Sylvie; Sánchez-Gorostiaga, Alicia; Vila, Jean C. C.; Sánchez, Álvaro

doi:10.1101/2020.08.06.239897

Cited by 12 publications

(17 citation statements)

References 29 publications

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“…Interestingly, in our petal community members of the Pseudomonadaceae and Enterobacteriaceae are common ( Figure A3), and recent studies have shown that these same two families tend to dominate communities assembled in minimal media with carbon as the main limiting resource (Goldford et al, 2018). In these artificial communities, as in our functional tests, Enterobacteriaceae tend to grow better on sugars, and Pseudomonadaceae in organic acids (Estrela et al, 2020). An extreme case of this potential specialization was the Rosenbergiella species, which are known nectar inhabitants.…”

Section: Functional Characterization Of Bacteria Of the Ray Petal Csupporting

confidence: 69%

“…Results of the carbon use assay indicate that most of the cultured strains differentiated along a sugar-organic acid axis, corroborating known familial proclivities (Estrela et al, 2020), with most Enterobacteriaceae specializing on sugars and most Pseudomonadaceae specializing on organic acids ( Figure A4A).…”

Section: Functional Characterization Of Bacteria Of the Ray Petal Csupporting

confidence: 69%

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Spatially explicit depiction of a floral epiphytic bacterial community reveals role for environmental filtering within petals

et al. 2021

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The microbiome of flowers (anthosphere) is an understudied compartment of the plant microbiome. Within the flower, petals represent a heterogeneous environment for microbes in terms of resources and environmental stress. Yet, little is known of drivers of structure and function of the epiphytic microbial community at the within‐petal scale. We characterized the petal microbiome in two co‐flowering plants that differ in the pattern of ultraviolet (UV) absorption along their petals. Bacterial communities were similar between plant hosts, with only rare phylogenetically distant species contributing to differences. The epiphyte community was highly culturable (75% of families) lending confidence in the spatially explicit isolation and characterization of bacteria. In one host, petals were heterogeneous in UV absorption along their length, and in these, there was a negative relationship between growth rate and position on the petal, as well as lower UV tolerance in strains isolated from the UV‐absorbing base than from UV reflecting tip. A similar pattern was not seen in microbes isolated from a second host whose petals had uniform patterning along their length. Across strains, the variation in carbon usage and chemical tolerance followed common phylogenetic patterns. This work highlights the value of petals for spatially explicit explorations of bacteria of the anthosphere.

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Section: Functional Characterization Of Bacteria Of the Ray Petal Csupporting

confidence: 69%

Section: Functional Characterization Of Bacteria Of the Ray Petal Csupporting

confidence: 69%

Spatially explicit depiction of a floral epiphytic bacterial community reveals role for environmental filtering within petals

et al. 2021

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“…Differences between the behavior of strains in pairwise versus complex communities point at higher-order ecological interactions that emerge in the community context. As previously shown in other studies, the underlying mechanisms may involve metabolic flexibility or mixed substrate utilization of the strains in the presence of competitors (41), metabolite cross-feeding and lack of waste-product inhibition and overall change in pH (11) or an excess of provided substrates in the medium.…”

Section: Discussionmentioning

confidence: 89%

Exploring the interaction network of a synthetic gut bacterial community

Weiß

Burrichter

Raj

et al. 2021

Preprint

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A key challenge in microbiome research is to predict functionality from microbial community composition. As central microbiota functions are determined by bacterial community networks it is important to gain insight into the principles that govern bacteria-bacteria interactions. Here, we focused on growth and metabolic interactions of the Oligo-Mouse-Microbiota (OMM12) synthetic bacterial community, which is increasingly used as model system in gut microbiome research. Using a bottom-up approach, we uncovered the directionality of strain-strain interactions in mono- and pairwise co-culture experiments, as well as in community batch culture. Metabolomics analysis of spent culture supernatant of individual strains in combination with genome-informed pathway reconstruction provided insights into the metabolic potential of the individual community members. Thereby, we could show that the OMM12 interaction network is shaped by both, exploitative and interference competition in vitro. In particular, Enterococcus faecalis KB1 was identified as important driver of community composition by affecting the abundance of several other consortium members. Together, this study gives fundamental insight into key drivers and mechanistic basis of the OMM12 interaction network, which serves as knowledge base for future mechanistic studies.

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“…Enrichment communities are an ideal system to test this hypothesis. In recent work, we have reported that increasing the number of supplied resources from 1 to 2 or 3 had a very small effect in the total biodiversity and did not lead to an appreciable increase in species richness (Estrela et al, 2020a; Figure 2). Consumerresource models with cross-feeding recapitulated this observation, and found that the identity of the nutrients in mixed-nutrient environments (i.e., whether they were two sugars or one sugar and one organic acid) had a larger effect on biodiversity than the number of those nutrients one adds.…”

Section: Understanding the Factors That Control The Diversity Of Microbial Communitiesmentioning

confidence: 84%

Multi-Replicated Enrichment Communities as a Model System in Microbial Ecology

2021

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Recent advances in robotics and affordable genomic sequencing technologies have made it possible to establish and quantitatively track the assembly of enrichment communities in high-throughput. By conducting community assembly experiments in up to thousands of synthetic habitats, where the extrinsic sources of variation among replicates can be controlled, we can now study the reproducibility and predictability of microbial community assembly at different levels of organization, and its relationship with nutrient composition and other ecological drivers. Through a dialog with mathematical models, high-throughput enrichment communities are bringing us closer to the goal of developing a quantitative predictive theory of microbial community assembly. In this short review, we present an overview of recent research on this growing field, highlighting the connection between theory and experiments and suggesting directions for future work.

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Nutrient dominance governs the assembly of microbial communities in mixed nutrient environments

Cited by 12 publications

References 29 publications

Spatially explicit depiction of a floral epiphytic bacterial community reveals role for environmental filtering within petals

Spatially explicit depiction of a floral epiphytic bacterial community reveals role for environmental filtering within petals

Exploring the interaction network of a synthetic gut bacterial community

Multi-Replicated Enrichment Communities as a Model System in Microbial Ecology

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