Competitive Traits Are More Important than Stress-Tolerance Traits in a Cadmium-Contaminated Rhizosphere: A Role for Trait Theory in Microbial Ecology

Wood, Jennifer L.; Tang, Caixian; Franks, Ashley E.

doi:10.3389/fmicb.2018.00121

Cited by 64 publications

(45 citation statements)

References 61 publications

(79 reference statements)

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“…However, meta-analyses of microbial communities to infer CSR strategies can be challenging due to 83 the different factors related to experimental design and techniques employed across different studies, 84 which could heavily affect the observations in comparison. Recent studies on soil-bacterial 85 communities in cadmium-contaminated rhizospheres (Wood et al 2018) and tillage-disturbed fields 86 (Schmidt et al 2018) also suggested the applicability of the CSR approach to soil-microbial 87 communities. To our knowledge, the CSR framework has not yet been employed within a single study 88 to changes in microbial communities upon disturbance in any microbiome other than soil.…”

Section: Introduction 44mentioning

confidence: 99%

Trait-based life-history strategies explain succession scenario for complex bacterial communities under varying disturbance

Santillan

Seshan

Constancias

et al. 2019

Preprint

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Originality-Significance Statement 22This study establishes, for the first time, CSR life-history strategies in the context of bacterial 23 communities. This framework is explained using community aggregated traits in an environment other 24 than soil, also a first, using a combination of ordination methods, network analysis, and genotypic 25 information from shotgun metagenomics and 16S rRNA gene amplicon sequencing. 26 Summary 27Trait-based approaches are increasingly gaining importance in community ecology, as a way of finding 28 general rules for the mechanisms driving changes in community structure and function under the 29 influence of perturbations. Frameworks for life-history strategies have been successfully applied to 30 describe changes in plant and animal communities upon disturbance. To evaluate their applicability to 31 complex bacterial communities, we operated replicated wastewater treatment bioreactors for 35 days 32 and subjected them to eight different disturbance frequencies of a toxic pollutant (3-chloroaniline), 33 starting with a mixed inoculum from a full-scale treatment plant. Relevant ecosystem functions were 34 tracked and microbial communities assessed through metagenomics and 16S rRNA gene sequencing. 35Combining a series of ordination, statistical and network analysis methods, we associated different life-36 history strategies with microbial communities across the disturbance range. These strategies were 37 evaluated using tradeoffs in community function and genotypic potential, and changes in bacterial genus 38 composition. We further compared our findings with other ecological studies and adopted a semi-39 quantitative CSR (competitors, ruderals, stress-tolerants) classification. The framework reduces 40 complex datasets of microbial traits, functions, and taxa into ecologically meaningful components to 41 help understand the system response to disturbance, and hence represents a promising tool for managing 42 microbial communities. 43

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Section: Introduction 44mentioning

confidence: 99%

Trait-based life-history strategies explain succession scenario for complex bacterial communities under varying disturbance

Santillan

Seshan

Constancias

et al. 2019

Preprint

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“…This tradeoff is reiterated by the absence of scenarios of communities excelling in both traits (figure 2, upper right). However, in certain communities lower resource acquisition costs were accompanied with lower growth yields (Figure 2, lower left), where, it is plausible that either or both of these traits trade off with some other unmeasured trait, likely stress tolerance 15,19,20 . In support of this interpretation, we previously found lower growth rate and yield in acidic soils ( Figure S1-2) 15 highlighting much higher maintenance costs of acid stress tolerance in such soils.…”

mentioning

confidence: 99%

Soil microbial communities with greater investment in resource acquisition have lower growth yield

Malik

Puissant

Goodall

et al. 2018

Preprint

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Resource acquisition and growth yield are fundamental traits of microorganisms that have consequences for ecosystem functioning. However, there is a lack of empirical observations linking these traits. Using a landscape-scale survey of temperate near-neutral pH soils, we show tradeoffs in key community-level parameters linked to these traits. Increased investment into extracellular enzymes was associated with reduced growth yield; this reduction was linked more to carbon than nitrogen acquisition enzymes suggesting smaller stoichiometric constraints on community metabolism in examined soils.

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“…This classification was mostly based on microbial substrate preferences and growth rates and has since been widely applied in various contexts (Fierer et al, 2012;Thomson et al, 2013). Several recent efforts have also applied C-S-R life history strategies to microbial systems, particularly in the context of anthropogenic environmental change (Fierer, 2017;Ho et al, 2013;Krause et al, 2014;Wood et al, 2018). Ho et al (2013) classified methane-oxidising bacteria into C-S-R life strategies based on activity, recovery from disturbances, substrate utilization patterns and stress tolerance.…”

Section: Life History Concepts In Macroecologymentioning

confidence: 99%

Defining trait-based microbial strategies with consequences for soil carbon cycling under climate change

Malik

Martiny

Brodie

et al. 2018

Preprint

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Competitive Traits Are More Important than Stress-Tolerance Traits in a Cadmium-Contaminated Rhizosphere: A Role for Trait Theory in Microbial Ecology

Cited by 64 publications

References 61 publications

Trait-based life-history strategies explain succession scenario for complex bacterial communities under varying disturbance

Trait-based life-history strategies explain succession scenario for complex bacterial communities under varying disturbance

Soil microbial communities with greater investment in resource acquisition have lower growth yield

Defining trait-based microbial strategies with consequences for soil carbon cycling under climate change

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