Climate change alters temporal dynamics of alpine soil microbial functioning and biogeochemical cycling via earlier snowmelt

Broadbent, Arthur A. D.; Snell, Helen S. K.; Michas, Antonios; Pritchard, William J.; Newbold, Lindsay K.; Cordero, Irene; Goodall, Tim; Schallhart, Nikolaus; Kaufmann, Rüdiger; Griffiths, Robert I.; Schloter, Michael; Bahn, Michael; Bardgett, Richard D.

doi:10.1038/s41396-021-00922-0

Cited by 62 publications

(48 citation statements)

References 66 publications

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“…Our results suggest that different afforested plantations changed ecosystem functioning seasonally, consistent with previous nding [60]. We found a positive relationship between microbial diversity and composition and multifunctionality in plantation forests seasonally, corroborating the positive biodiversity-ecosystem function relationships.…”

Section: Diversity-function-assembly Relationship With Seasonalitysupporting

confidence: 92%

“…A similar nding showed that oxidative activities were more variable than hydrolytic activities and increased with soil pH [59]. In addition, as mentioned previously, microbes typically invest more in enzymes, especially lignin-degrading enzymes, in summer [60]. In contrast, potential enzyme activities were potentially expected to be high in winter.…”

Section: Effect Of Seasonality On Soil Enzymessupporting

confidence: 60%

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Seasonal Variations Affect The Ecosystem Functioning And Microbial Assembly Processes In Plantation Forests

Wang¹,

Masoudi²,

Wang³

et al. 2021

Preprint

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Background: While afforestation mitigates climate concerns, the impact of afforestation on soil microbial compositions, ecological assembly processes, and multiple soil functions (multifunctionality) in afforested areas remains unclear. The Xiong'an New Area plantation forests (Pinus and Sophora forests) were selected to examine the effects of plantation types in four contrasting seasons on soil microbiomes.Results: We evaluated three functional categories (nutrient stocks, organic matter decomposition, and microbial functional genes) of multifunctionality, and the average (net) multifunctionality was quantified. The results showed that net soil multifunctionality as a broad function did not change seasonally, unlike other narrow functional categories. Bacterial communities were deterministically (variable selection and homogenous selection) structured, whereas the stochastic process of dispersal limitation was mainly responsible for the assembly and turnover of fungal and protist communities. Additionally, we showed that winter triggered an abrupt transition in the bacterial community assembly from deterministic to stochastic processes in Pinus forests that was closely associated with a reduction in the bacterial Shannon diversity, with functional patterns of a high level of nutrient cycling (nutrient stocks and organic matter decomposition). Conclusions: Overall, the present study contributes local-ecosystem prospects to model the behavior of soil biota seasonally and their implied effects on soil functioning and microbial assembly processes in plantation forests.

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Section: Diversity-function-assembly Relationship With Seasonalitysupporting

confidence: 92%

Section: Effect Of Seasonality On Soil Enzymessupporting

confidence: 60%

Seasonal Variations Affect The Ecosystem Functioning And Microbial Assembly Processes In Plantation Forests

Wang¹,

Masoudi²,

Wang³

et al. 2021

Preprint

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“…Root N is subsequently translocated to aboveground biomass (De Vries, Bloem, et al., 2012; Harrison et al., 2007), and eventually transferred to soil organic matter pools via shoot, root, and microbial turnover (Zogg et al., 2000). However, N turnover and uptake dynamics in mountain ecosystems vary strongly over the growing season (Broadbent et al., 2021), with plant and microbial uptake and competition increasing towards peak biomass (Bardgett et al., 2002). Thus, our findings from the late growing season may not reflect ecosystem N uptake and retention in the early growing season.…”

Section: Discussionmentioning

confidence: 99%

Glacier forelands reveal fundamental plant and microbial controls on short‐term ecosystem nitrogen retention

et al. 2021

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Human activities have massively increased the amount of reactive nitrogen in the biosphere, which is leading to increased nitrogen (N) inputs in terrestrial ecosystems. The retention of N is a crucial ecosystem function of both managed and natural ecosystems, and there is a long history of experimental, observational, and conceptual studies identifying its major controls. Yet, the plant and soil microbial controls on the retention of added N remain elusive. Here, we used three ecosystem chronosequences in front of retreating glaciers in the European Alps to test our hypothesis that the retention of added reactive 15N increases as succession proceeds, and to identify the plant and microbial controls on ecosystem N retention. We found that the uptake and retention of N did not change during succession, despite consistent changes in plant, soil, and microbial properties with increasing time since deglaciation. Instead, we found that plant and microbial properties that remained constant during succession controlled 15N uptake and retention: low root and microbial C/N ratios, as well as high root biomass, increased plant and microbial uptake of added N. In addition, high soil concentrations of nitrate and ammonium reduced the uptake of N in microbes and roots, respectively. Synthesis. Our results demonstrate that plant and microbial N demand, as well as soil N availability, drive the short‐term retention of added N during succession in glacier forelands. This finding represents an advance in our understanding of the fundamental controls on ecosystem N retention and the role of plant‐microbial interactions in this process. Such understanding is crucial for predicting and mitigating the response of terrestrial ecosystems to the ever‐increasing amounts of reactive N in the biosphere.

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“…We listed Betaproteobacteria here separately, as Kaiju assign them separately and does not have the SILVA132 database assignment. In the paper, Beta - and Gammaproteobacteria are summed ( 92 , 93 ). Download .…”

Section: Resultsmentioning

confidence: 99%

Microbial Nitrogen Transformation Potential in Sediments of Two Contrasting Lakes Is Spatially Structured but Seasonally Stable

Baumann

Thoma

Callbeck

et al. 2022

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Climate change alters temporal dynamics of alpine soil microbial functioning and biogeochemical cycling via earlier snowmelt

Cited by 62 publications

References 66 publications

Seasonal Variations Affect The Ecosystem Functioning And Microbial Assembly Processes In Plantation Forests

Seasonal Variations Affect The Ecosystem Functioning And Microbial Assembly Processes In Plantation Forests

Glacier forelands reveal fundamental plant and microbial controls on short‐term ecosystem nitrogen retention

Microbial Nitrogen Transformation Potential in Sediments of Two Contrasting Lakes Is Spatially Structured but Seasonally Stable

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