Drought decreases incorporation of recent plant photosynthate into soil food webs regardless of their trophic complexity

Chomel, Mathilde; Lavallee, Jocelyn M.; Alvarez-Segura, Nil; Castro, Francisco de; Rhymes, Jennifer; Caruso, Tancredi; Vries, Franciska T. de; Baggs, Elizabeth M.; Emmerson, Mark; Bardgett, Richard D.; Johnson, David

doi:10.1111/gcb.14754

Cited by 41 publications

(30 citation statements)

References 78 publications

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“…8). A secondary controller of soil microbial activity and decomposition is soil moisture (Chomel et al 2019;Moyano et al 2013;Schimel 2018). As such, we also found a significant correlation between soil respiration rate and water content, which accounted for 21-33% of the soil respiration variability (Fig.…”

Section: Effect Of Stand Density On Soil C Outputsupporting

confidence: 64%

Higher stand densities can promote soil carbon storage after conversion of temperate mixed natural forests to larch plantations

Sun

Zhang

et al. 2020

Eur J Forest Res

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Soil carbon (C) reservoirs held in forests play a significant role in the global C cycle. However, harvesting natural forests tend to lead to soil C loss, which can be countered by the establishment of plantations after clear cutting. Therefore, there is a need to determine how forest management can affect soil C sequestration. The management of stand density could provide an effective tool to control soil C sequestration, yet how stand density influences soil C remains an open question. To address this question, we investigated soil C storage in 8-year pure hybrid larch (Larix spp.) plantations with three densities (2000 trees ha−1, 3300 trees ha−1 and 4400 trees ha−1), established following the harvesting of secondary mixed natural forest. We found that soil C storage increased with higher tree density, which mainly correlated with increases of dissolved organic C as well as litter and root C input. In addition, soil respiration decreased with higher tree density during the most productive periods of warm and moist conditions. The reduced SOM decomposition suggested by lowered respiration was also corroborated with reduced levels of plant litter decomposition. The stimulated inputs and reduced exports of C from the forest floor resulted in a 40% higher soil C stock in high- compared to low-density forests within 8 years after plantation, providing effective advice for forest management to promote soil C sequestration in ecosystems.

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Section: Effect Of Stand Density On Soil C Outputsupporting

confidence: 64%

Higher stand densities can promote soil carbon storage after conversion of temperate mixed natural forests to larch plantations

Sun

Zhang

et al. 2020

Eur J Forest Res

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“…By contrast, increased uptake of root-derived carbon by bacteria following rewetting is a key mechanism underlying resilience or recovery of the plant-soil system from drought [90]. Drought-induced changes in root exudation, including qualitative changes, also have implications for ecosystem function, for instance, by increasing microbial activity and respiration [92] and/or by shifting the soil microbial community towards increased decomposition of soil organic carbon [89].…”

Section: (B) Plant Community Compositionmentioning

confidence: 99%

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

Bardgett

Caruso

2020

Phil. Trans. R. Soc. B

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176

127

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A major challenge for advancing our understanding of the functional role of soil microbial communities is to link changes in their structure and function under climate change. To address this challenge requires new understanding of the mechanisms that underlie the capacity of soil microbial communities to resist and recover from climate extremes. Here, we synthesize emerging understanding of the intrinsic and extrinsic factors that influence the resistance and resilience of soil microbial communities to climate extremes, with a focus on drought, and identify drivers that might trigger abrupt changes to alternative states. We highlight research challenges and propose a path for advancing our understanding of the resistance and resilience of soil microbial communities to climate extremes, and of their vulnerability to transitions to alternative states, including the use of trait-based approaches. We identify a need for new approaches to quantify resistance and resilience of soil microbial communities, and to identify thresholds for transitions to alternative states. We show how high-resolution time series coupled with gradient designs will enable detecting response patterns to interacting drivers. Finally, to account for extrinsic factors, we suggest that future studies should use environmental gradients to track soil microbial community responses to climate extremes in space and time. This article is part of the theme issue ‘Climate change and ecosystems: threats, opportunities and solutions’.

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“…1) ( 31 ). Changes in plant physiology and phenology caused by climate change, although poorly understood, can alter soil microbial communities via changes in rhizodeposition (i.e., the release of resources from plant roots into the soil), thereby potentially modifying the microbial-mediated PSFs ( 32 , 33 ) and the capacity to change feedback effects from soil and vegetation to climate.…”

Section: Microbial Controls On Psfsmentioning

confidence: 99%

Climate change effects on plant-soil feedbacks and consequences for biodiversity and functioning of terrestrial ecosystems

et al. 2019

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Plant-soil feedbacks (PSFs) are interactions among plants, soil organisms, and abiotic soil conditions that influence plant performance, plant species diversity, and community structure, ultimately driving ecosystem processes. We review how climate change will alter PSFs and their potential consequences for ecosystem functioning. Climate change influences PSFs through the performance of interacting species and altered community composition resulting from changes in species distributions. Climate change thus affects plant inputs into the soil subsystem via litter and rhizodeposits and alters the composition of the living plant roots with which mutualistic symbionts, decomposers, and their natural enemies interact. Many of these plant-soil interactions are species-specific and are greatly affected by temperature, moisture, and other climate-related factors. We make a number of predictions concerning climate change effects on PSFs and consequences for vegetation-soil-climate feedbacks while acknowledging that they may be context-dependent, spatially heterogeneous, and temporally variable. Climate change effects on plant-soil feedbacks and consequences for biodiversity and functioning of terrestrial ecosystems.

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Drought decreases incorporation of recent plant photosynthate into soil food webs regardless of their trophic complexity

Cited by 41 publications

References 78 publications

Higher stand densities can promote soil carbon storage after conversion of temperate mixed natural forests to larch plantations

Higher stand densities can promote soil carbon storage after conversion of temperate mixed natural forests to larch plantations

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

Climate change effects on plant-soil feedbacks and consequences for biodiversity and functioning of terrestrial ecosystems

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