Soil microbial community responses to climate extremes: resistance, resilience and transitions to alternative states

Bardgett, Richard D.; Caruso, Tancredi

doi:10.1098/rstb.2019.0112

Cited by 177 publications

(148 citation statements)

References 124 publications

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“… 2019 ). The resistance of microbial communities to disturbances is suggested to be linked to diversity (Bardgett and Caruso 2020 ) because diversity can increase the variability of species’ responses to environmental stress and may thus buffer essential ecosystem functions against environmental fluctuations (Naeem and Li 1997 ; Yachi and Loreau 1999 ). Under controlled conditions, Lori et al .…”

Section: Introductionmentioning

confidence: 99%

Effects of simulated drought on biological soil quality, microbial diversity and yields under long-term conventional and organic agriculture

Kundel

Bodenhausen

Jørgensen

et al. 2020

FEMS Microbiology Ecology

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Drought and agricultural management influence soil microorganisms with unknown consequences for the functioning of agroecosystems. We simulated drought periods in organic (biodynamic) and conventional wheat fields and monitored effects on soil water content, microorganisms and crops. Above the wilting point, water content and microbial respiration were higher under biodynamic than conventional farming. Highest bacterial and fungal abundance were found in biodynamically managed soils, and distinct microbial communities characterised the farming systems. Most biological soil quality parameters and crop yields were only marginally affected by the experimental drought, except for arbuscular mycorrhizal fungi (AMF), which increased under the experimental drought in both farming systems. AMF were further strongly promoted by biodynamic farming resulting in almost three times higher AMF abundance under experimental drought in the biodynamic compared to the conventional farming system. Our data suggest an improved water storage capacity under biodynamic farming and confirms positive effects of biodynamic farming on biological soil quality. The interactive effects of the farming system and drought may further be investigated under more substantial droughts. Given the importance of AMF for the plant's water supply, more in-depth studies on AMF may help to clarify their role for yields under conditions predicted by future climate scenarios.

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Section: Introductionmentioning

confidence: 99%

Effects of simulated drought on biological soil quality, microbial diversity and yields under long-term conventional and organic agriculture

Kundel

Bodenhausen

Jørgensen

et al. 2020

FEMS Microbiology Ecology

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“…Following Oliver et al (2015), this capacity of ecosystems to deal with environmental stress (sometime referred to as overall resilience, see Hodgson et al (2015) and Mori (2016) for recent discussions on resilience terminologies) can be decomposed in the ecosystem resistance, that is the capacity to maintain its state during stress, and the recovery (also sometimes called 'engineering resilience'), which refers to the capacity to recover after the end of the stress (Hodgson et al, 2015;Oliver et al, 2015). Although soil microbes underpin carbon and nutrient cycling in ecosystems (Bender et al, 2016;Nannipieri et al, 2003), drivers of the microbial resistance and recovery are still poorly understood (Bardgett & Caruso, 2020;de Vries & Shade, 2013).…”

Section: Introductionmentioning

confidence: 99%

Resistance–recovery trade‐off of soil microbial communities under altered rain regimes: An experimental test across European agroecosystems

Piton

Foulquier

Martínez‐García

et al. 2020

Journal of Applied Ecology

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With the increased occurrence of climate extremes, there is an urgent need to better understand how management strategies affect the capacity of the soil microbial community to maintain its ecosystem functions (e.g. nutrient cycling). To address this issue, intact monoliths were extracted from conventional and ecological managed grasslands in three countries across Europe and exposed under common air condition (temperature and moisture) to one of three altered rain regimes (dry, wet and intermittent wet/dry) as compared to a normal regime. Subsequently, we compared the resistance and recovery of the soil microbial biomass, potential enzyme activities and community composition. The microbial community composition differed with soil management and rain regimes. Soil microbial biomass increased from the wetter to the dryer rain regime, paralleling an increase of available carbon and nutrients, suggesting low sensitivity to soil moisture reduction but nutritional limitations of soil microbes. Conversely, enzyme activities decreased with all altered rain regimes. Resistance and recovery (considering absolute distance between normal and altered rain regime) of the microbial communities depended on soil management. Conventional‐intensive management showed higher resistance of two fundamental properties for nutrient cycling (i.e. bacterial biomass and extracellular enzyme activities) yet associated with more important changes in microbial community composition. This suggests an internal community reorganization promoting biomass and activity resistance. Conversely, under ecological management bacterial biomass and enzyme activities showed better recovery capacity, whereas no or very low recovery of these properties was observed under conventional management. These management effects were consistent across the three altered rain regimes investigated, indicating common factors controlling microbial communities’ response to different climate‐related stresses. Synthesis and applications. Our study provides experimental evidence for an important trade‐off for agroecosystem management between (a) stabilizing nutrient cycling potential during an altered rain regime period at the expense of very low recovery capacity and potential long‐term effect (conventional sites) and (b) promoting the capacity of the microbial community to recover its functional potential after the end of the stress (ecological sites). Thus, management based on ecologically sound principles may be the best option to sustain long‐term soil functioning under climate change.

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“…This is potentially problematic, as it is assuming that rhizosphere processes, including contributions from mycorrhizal fungi, are not influencing the overall R S response. Previous studies have demonstrated the important role roots play in stabilising SOM (Hinsinger et al, 2009), with disturbed soils having a lower capacity to protect SOM due to mechanical disruption of macroaggregates, and hence C is more readily decomposed by microorganisms (Beare et al, 1994). Many, and potentially all, of the plant species at the site have associations with arbuscular mycorrhizae, which are known to increase SOM formation both directly as well as through their influence on soil aggregation (Rillig et al, 2001).…”

Section: Plant-induced Alteration To Soil Microhabitatmentioning

confidence: 99%

Warming increases soil respiration in a carbon-rich soil without changing microbial respiratory potential

Nyberg

Hovenden

2020

Biogeosciences

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Abstract. Increases in global temperatures due to climate change threaten to tip the balance between carbon (C) fluxes, liberating large amounts of C from soils. Evidence of warming-induced increases in CO2 efflux from soils has led to suggestions that this response of soil respiration (RS) will trigger a positive land C–climate feedback cycle, ultimately warming the Earth further. Currently, there is little consensus about the mechanisms driving the warming-induced RS response, and there are relatively few studies from ecosystems with large soil C stores. Here, we investigate the impacts of experimental warming on RS in the C-rich soils of a Tasmanian grassy sedgeland and whether alterations of plant community composition or differences in microbial respiratory potential could contribute to any effects. In situ, warming increased RS on average by 28 %, and this effect was consistent over time and across plant community composition treatments. In contrast, warming had no impact on microbial respiration in incubation experiments. Plant community composition manipulations did not influence RS or the RS response to warming. Processes driving the RS response in this experiment were, therefore, not due to plant community effects and are more likely due to increases in below-ground autotrophic respiration and the supply of labile substrate through rhizodeposition and root exudates. CO2 efflux from this high-C soil increased by more than a quarter in response to warming, suggesting inputs need to increase by at least this amount if soil C stocks are to be maintained. These results indicate the need for comprehensive investigations of both C inputs and losses from C-rich soils if efforts to model net ecosystem C exchange of these crucial, C-dense systems are to be successful.

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Soil microbial community responses to climate extremes: resistance, resilience and transitions to alternative states

Cited by 177 publications

References 124 publications

Effects of simulated drought on biological soil quality, microbial diversity and yields under long-term conventional and organic agriculture

Effects of simulated drought on biological soil quality, microbial diversity and yields under long-term conventional and organic agriculture

Resistance–recovery trade‐off of soil microbial communities under altered rain regimes: An experimental test across European agroecosystems

Warming increases soil respiration in a carbon-rich soil without changing microbial respiratory potential

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