Integrating microbial ecology into ecosystem models: challenges and priorities

Treseder, Kathleen K.; Balser, Teri C.; Bradford, Mark A.; Brodie, Eoin L.; Dubinsky, Eric A.; Eviner, Valerie T.; Hofmockel, Kirsten; Lennon, Jay T.; Levine, Uri Y.; MacGregor, Barbara J.; Pett‐Ridge, Jennifer; Waldrop, Mark P.

doi:10.1007/s10533-011-9636-5

Cited by 223 publications

(193 citation statements)

References 110 publications

(130 reference statements)

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“…Although the importance of microbial community composition may vary with spatiotemporal scales (Schimel and Schaeffer, 2012), the inclusion of microbial physiology is essential to confidently project feedbacks between climate change and carbon cycle (Bradford, 2013). Continued development is needed to bring microbial physiology into global climate and ecosystem models (Todd-Brown et al, 2012;Treseder et al, 2012;Schimel, 2013).…”

Section: Microbial Dormancymentioning

confidence: 99%

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Microbial dormancy improves development and experimental validation of ecosystem model

et al. 2014

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Climate feedbacks from soils can result from environmental change followed by response of plant and microbial communities, and/or associated changes in nutrient cycling. Explicit consideration of microbial life-history traits and functions may be necessary to predict climate feedbacks owing to changes in the physiology and community composition of microbes and their associated effect on carbon cycling. Here we developed the microbial enzyme-mediated decomposition (MEND) model by incorporating microbial dormancy and the ability to track multiple isotopes of carbon. We tested two versions of MEND, that is, MEND with dormancy (MEND) and MEND without dormancy (MEND_wod), against long-term (270 days) carbon decomposition data from laboratory incubations of four soils with isotopically labeled substrates. MEND_wod adequately fitted multiple observations (total C-CO 2 and 14 C-CO 2 respiration, and dissolved organic carbon), but at the cost of significantly underestimating the total microbial biomass. MEND improved estimates of microbial biomass by 20-71% over MEND_wod. We also quantified uncertainties in parameters and model simulations using the Critical Objective Function Index method, which is based on a global stochastic optimization algorithm, as well as model complexity and observational data availability. Together our model extrapolations of the incubation study show that long-term soil incubations with experimental data for multiple carbon pools are conducive to estimate both decomposition and microbial parameters. These efforts should provide essential support to future field-and globalscale simulations, and enable more confident predictions of feedbacks between environmental change and carbon cycling.

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Section: Microbial Dormancymentioning

confidence: 99%

“…Microbially controlled SOM decomposition is increasingly represented in ecosystem models (Treseder et al, 2012). Other vital common evolutionary traits, however, such as microbial dormancy and community shifts are not yet represented (Jones and Lennon, 2010;Weedon et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

Microbial dormancy improves development and experimental validation of ecosystem model

et al. 2014

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“…Extensive bodies of work have provided detailed insights into the mechanism(s) on the transformation of soil C pools by extracellular enzymes excreted into the soil by microbes, thus allowing researchers to develop enzyme-driven ESMs that provide a better fit to observations, especially in changing environments (Allison et al, 2010;Treseder et al, 2012;Wieder et al, 2013;Hararuk et al, 2015). Processlevel analyses such as respiration and enzymatic transformation of added substrate are used as a proxy of microbial function, which gives valuable insight into overall microbial-mediated transformations in soils.…”

Section: Introductionmentioning

confidence: 99%

Microbial regulation of the soil carbon cycle: evidence from gene–enzyme relationships

et al. 2016

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A lack of empirical evidence for the microbial regulation of ecosystem processes, including carbon (C) degradation, hinders our ability to develop a framework to directly incorporate the genetic composition of microbial communities in the enzyme-driven Earth system models. Herein we evaluated the linkage between microbial functional genes and extracellular enzyme activity in soil samples collected across three geographical regions of Australia. We found a strong relationship between different functional genes and their corresponding enzyme activities. This relationship was maintained after considering microbial community structure, total C and soil pH using structural equation modelling. Results showed that the variations in the activity of enzymes involved in C degradation were predicted by the functional gene abundance of the soil microbial community (R 2 40.90 in all cases). Our findings provide a strong framework for improved predictions on soil C dynamics that could be achieved by adopting a gene-centric approach incorporating the abundance of functional genes into process models.

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“…In ecosystem models, microbial activity is often approached as a 'black box' (for example, a single rate for decomposition), despite continuing evidence supporting the need for more detail (for example, Schimel, 2001;Allison and Martiny, 2008;Treseder et al, 2012). The range of scales (micrometer to global) and the magnitude of microbial diversity present challenges to the development of more detailed models, but the evidence for differences in microorganisms' responses to disturbances suggest that these challenges must be met.…”

Section: Introductionmentioning

confidence: 99%

Microbial community modeling using reliability theory

et al. 2016

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Linking microbial community composition with the corresponding ecosystem functions remains challenging. Because microbial communities can differ in their functional responses, this knowledge gap limits ecosystem assessment, design and management. To develop models that explicitly incorporate microbial populations and guide efforts to characterize their functional differences, we propose a novel approach derived from reliability engineering. This reliability modeling approach is illustrated here using a microbial ecology dataset from denitrifying bioreactors. Reliability modeling is well-suited for analyzing the stability of complex networks composed of many microbial populations. It could also be applied to evaluate the redundancy within a particular biochemical pathway in a microbial community. Reliability modeling allows characterization of the system's resilience and identification of failure-prone functional groups or biochemical steps, which can then be targeted for monitoring or enhancement. The reliability engineering approach provides a new perspective for unraveling the interactions between microbial community diversity, functional redundancy and ecosystem services, as well as practical tools for the design and management of engineered ecosystems.

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Integrating microbial ecology into ecosystem models: challenges and priorities

Cited by 223 publications

References 110 publications

Microbial dormancy improves development and experimental validation of ecosystem model

Microbial dormancy improves development and experimental validation of ecosystem model

Microbial regulation of the soil carbon cycle: evidence from gene–enzyme relationships

Microbial community modeling using reliability theory

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