Community history affects the predictability of microbial ecosystem development

Pagaling, Eulyn; Strathdee, Fiona; Spears, Bryan M.; Cates, Michael E.; Allen, Rosalind J.; Free, Andrew

doi:10.1038/ismej.2013.150

Cited by 93 publications

(109 citation statements)

References 47 publications

(57 reference statements)

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“…This is particularly important in soils, which exhibit a very high species turnover rate: in one case, the bacterial and archaeal ammonia oxidizing communities in a range of Dutch agricultural soils showed above 50% change in community structure between seasons [61,62]. In another, it was shown that when colonizing a novel environment, the microbial community undergoes drastic rearrangement, and draws heavily from members of the 'rare biosphere' [9,63], a strategy which may be crucial for stressresponse [51].…”

Section: Long-term Effects: Stability and Resiliencementioning

confidence: 99%

“…Specifically, in microbial systems, where diversity and abundance are extreme and growth rates are rapid, it was formerly assumed that redundancy is so high that diversity and community composition are decoupled from functioning due to the following observations: 1) most microbial species are ubiquitous and present in very low densities, awaiting an opportunity to "bloom"; 2) the rapid adaptability of microbes means that such a system will never be so impoverished as to cease functioning; and 3) the microbial system is so tightly linked to its physical environment that it cannot be studied within the context of cause-effect that is generally necessary for BEF studies. However, recent studies have shown that community composition matters to function [5,6]: in soil, microbial communities exhibit a home-field advantage in decomposing endemic vs. foreign litter [7,8] and different communities do not become more similar when exposed to the same environment [9]. This ongoing discussion has been particularly important in the realm of ecosystem models, where stable physical parameters or very coarse microbial parameters (such as total biomass) are assumed to accurately represent microbial contributions to ecosystem function [10].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Functional Redundancy and Ecosystem Function — The Soil Microbiota as a Case Study

Jurburg¹,

Salles²

2015

Biodiversity in Ecosystems - Linking Structure and Function

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Section: Long-term Effects: Stability and Resiliencementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Functional Redundancy and Ecosystem Function — The Soil Microbiota as a Case Study

Jurburg¹,

Salles²

2015

Biodiversity in Ecosystems - Linking Structure and Function

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“…This causes that some ecosystems are functioning properly only in the original environment which is caused by coevolution of microorganisms and their adaptation to environmental conditions (Keiser et al 2011). Moreover, one of the studies has shown that different microbial communities have not become similar under the same conditions, suggesting that the original composition of microorganisms could be a predictor of the responses of a particular ecosystem and its development (Pagaling et al 2014). For that reason, it is increasingly common to classify microorganisms communities not on the basis of their taxonomic affiliation but on their functions.…”

Section: Introductionmentioning

confidence: 99%

Functional Redundancy of Soil Microbiota – Does More Always Mean Better?

Grządziel

2017

pjss

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Abstract. The proper and healthy functioning of the soil depends largely on the microorganisms abundance, including the total number of bacteria and fungi, but also their diversity. The increase in the biodiversity also increases the functional capabilities of the ecosystem but from a certain point, a further increase in the biodiversity does not bring any new features, so the general biochemical and metabolic profile of the ecosystem remains constant. It is also suggested that the loss of one or more species does not dramatically affect the functioning of the ecosystem, because the same functions can be represented by many different species. This phenomenon is called a functional redundancy and makes the soil a very stable environment with a high buffering capabilities, more often called the "soil memory". On the other hand, some unique biochemical processes are characteristic for a small group of species, for example, nitrogen fixation or toxic compounds degradation. The loss of the specialized species may lead to the decrease of a rare genes occurrence in the soil, resulting in the loss of nutrients or the accumulation of toxins.This article presents the current findings on functional redundancy in terms of soil microorganisms and its implications to the soil functioning.

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“…In particular, nutrient supply may be unpredictable, nutrient and biomass removal rates may not balance, and population sizes may be small so that random fluctuations due to birth and death events play an important role. Recent studies have shown that microbial communities can undergo unpredictable divergence from similar initial conditions [1], dramatic fluctuations in species composition [2] and even chaotic dynamics [3][4][5][6]. Stochastic models for microbial ecosystem dynamics will be needed to obtain detailed understanding of such results.…”

Section: Introductionmentioning

confidence: 99%

Oscillating microbial dynamics driven by small populations, limited nutrient supply and high death rates

Khatri

Free

Allen

2012

Journal of Theoretical Biology

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Microbial populations in the natural environment are likely to experience growth conditions very different from those of a typical laboratory experiment. In particular, removal rates of biomass and substrate are unlikely to be balanced under realistic environmental conditions. Here, we consider a single population growing on a substrate under conditions where the removal rates of substrate and biomass are not necessarily equal. For a large population, with deterministic growth dynamics, our model predicts that this system can show transient (damped) oscillations. For a small population, demographic noise causes these oscillations to be sustained indefinitely. These oscillations arise when the dynamics of changes in biomass are faster than the dynamics of the substrate, for example, due to a high microbial death rate and/or low substrate flow rates. We show that the same mechanism can produce sustained stochastic oscillations in a two-species, nutrient-cycling microbial ecosystem. Our results suggest that oscillatory population dynamics may be a common feature of small microbial populations in the natural environment, even in the absence of complex interspecies interactions.

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Community history affects the predictability of microbial ecosystem development

Cited by 93 publications

References 47 publications

Functional Redundancy and Ecosystem Function — The Soil Microbiota as a Case Study

Functional Redundancy and Ecosystem Function — The Soil Microbiota as a Case Study

Functional Redundancy of Soil Microbiota – Does More Always Mean Better?

Oscillating microbial dynamics driven by small populations, limited nutrient supply and high death rates

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