Mosses reduce soil nitrogen availability in a subarctic birch forest via effects on soil thermal regime and sequestration of deposited nitrogen

Koranda, Marianne; Michelsen, Anders

doi:10.1111/1365-2745.13567

Cited by 24 publications

(16 citation statements)

References 77 publications

(100 reference statements)

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“…Contrary to rst hypothesis, soils at moss-grown sites exhibited relatively high microbial biomass N, dissolved N and potential enzyme activities (Fig. 4 and Table 3), which contrasts with ndings of our previous study in a nearby birch forest, where we observed a negative effect of the moss layer on soil N availability (Koranda and Michelsen 2021). This apparent discrepancy shows that the in uence of mosses on soil microbial processes and nutrient cycling is context-speci c, depending on the factors most strongly regulating soil microbial activity in the respective ecosystem: While in the birch forest, characterized by a homogenous understorey and SOM quality, the insulating effect of the moss layer was a crucial factor for soil microbial activity (Koranda and Michelsen 2021), in tundra heath the high spatial variability in plant traits, SOM quality and soil pH mainly determined microbial community structure and nutrient availability, whereas soil temperature was comparatively less relevant.…”

Section: Effects Mosses On Microbial Decomposition Processes and Soil...contrasting

confidence: 99%

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Plant functional types drive spatial and temporal variation in soil microbial community composition and extracellular enzyme activities in a tundra heath

Koranda

Rinnan²,

Michelsen³

2022

Preprint

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Aims In this study we investigated divergent effects of two dominant plant functional types in tundra heath, dwarf shrubs and mosses, on microbial decomposition processes and soil carbon (C) and nutrient cycling. Methods We analysed samples of organic soil under three dwarf shrub species of distinct mycorrhizal association and life form (Betula nana, Empetrum hermaphroditum and Arctostaphylos alpinus) and under three moss species (Hylocomium splendens, Aulacomnium turgidum and Tomentypnum nitens) in early and late growing season. Results Our results revealed contrasting effects of shrubs and mosses on extracellular enzyme activities and soil C and nutrient pools which were linked with strong differences in soil microbial community structure. Specifically, moss soils were characterized by a bacterial-dominated microbial community associated with high soil nitrogen availability, while shrubs promoted a fungal-dominated microbial community and soil C accrual. The variation in soil microbial community composition under different plant species was explained by mycorrhizal association, root morphology, litter and soil organic matter quality and soil pH-value. Furthermore, we found that the seasonal variation in microbial biomass and enzyme activities, driven by plant belowground C allocation during the growing season, was most pronounced under the tallest shrub B. nana. Conclusion Our study demonstrates a close coupling of plant functional types with soil microbial communities, microbial decomposition processes and soil nutrient availability in tundra heath, which suggests potential strong impacts of global change-induced shifts in plant community composition on carbon and nutrient cycling in high-latitude ecosystems.

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Section: Effects Mosses On Microbial Decomposition Processes and Soil...contrasting

confidence: 99%

“…Potential hydrolytic enzyme activities were estimated by microplate assays using uorescent substrates, as described in detail in Koranda and Michelsen (2021). Soil slurries were prepared using Na-acetate buffer (pH 5.7).…”

Section: Extracellular Enzyme Activitiesmentioning

confidence: 99%

Plant functional types drive spatial and temporal variation in soil microbial community composition and extracellular enzyme activities in a tundra heath

Koranda

Rinnan²,

Michelsen³

2022

Preprint

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“…Biocrusts are ecosystem engineers at the atmosphere–soil interface, and they regulate a wide range of ecosystem functions, including C budgets (Dacal et al, 2020; García‐Palacios et al, 2018), nitrogen (N) cycles (Koranda & Michelsen, 2021; Maier et al, 2021), phosphorus (P) cycles (Kurth et al, 2021), hydrological processes (Eldridge et al, 2020), soil thermal properties (Xiao, Ma, et al, 2019) and soil stability (Algayer et al, 2014). Specifically, biocrusts regulate soil CO 2 flux not only directly through photosynthesis (Li, Hui, et al, 2021) and respiration (Guan et al, 2021, 2022) but also indirectly by altering the soil temperature (Xiao, Ma, et al, 2019), moisture (Eldridge et al, 2020), N availability (Koranda & Michelsen, 2021) and microbial community and functional structure (Wang, Wang, et al, 2021). For example, soil respiration at microsites with high biocrust coverage is significantly higher than that at microsites with low biocrust coverage (Escolar et al, 2015; Maestre et al, 2013) or in bare soils (Morillas et al, 2017; Yao et al, 2020), and biocrusts can contribute to more than 40% of CO 2 flux via soil respiration (Castillo‐Monroy et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

“…As structural components of drylands, biocrusts are soil surface communities dominated by cyanobacteria, algae, lichens and mosses (Belnap et al, 2016), and they cover ~30% of the dryland soil surface (Rodriguez‐Caballero et al, 2018). Biocrusts are ecosystem engineers at the atmosphere–soil interface, and they regulate a wide range of ecosystem functions, including C budgets (Dacal et al, 2020; García‐Palacios et al, 2018), nitrogen (N) cycles (Koranda & Michelsen, 2021; Maier et al, 2021), phosphorus (P) cycles (Kurth et al, 2021), hydrological processes (Eldridge et al, 2020), soil thermal properties (Xiao, Ma, et al, 2019) and soil stability (Algayer et al, 2014). Specifically, biocrusts regulate soil CO 2 flux not only directly through photosynthesis (Li, Hui, et al, 2021) and respiration (Guan et al, 2021, 2022) but also indirectly by altering the soil temperature (Xiao, Ma, et al, 2019), moisture (Eldridge et al, 2020), N availability (Koranda & Michelsen, 2021) and microbial community and functional structure (Wang, Wang, et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Microbial function regulates the effect of vegetation restoration on the contribution of biocrusts to soil respiration in drylands

et al. 2023

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Biocrusts are special components of dryland ecosystems and play important roles in ecosystem carbon cycles. Vegetation restoration not only affects carbon storage but also changes the characteristics of biocrusts. However, how vegetation restoration influences the contribution of biocrusts to soil carbon cycling in dryland ecosystems is poorly understood. Using continuous field measurements combined with metagenomic shotgun sequencing, we explored the effect and regulatory mechanisms of Caragana korshinskii vegetation restoration on the contribution of biocrusts to total soil respiration. We found that vegetation restoration increased the contribution of biocrusts to total soil respiration, with the biocrust contribution increasing from −5.6% for mixed biocrusts in a typical steppe to 17.1%, 18.1% and 19.6% for cyanobacteria–algae, lichen and moss biocrusts, respectively, in a Caragana korshinskii vegetation restoration area. The driving factors for total soil respiration changed from solely soil temperature to soil temperature and moisture after vegetation restoration. In contrast, the driving factors for soil respiration estimated for biocrust layers changed from precipitation alone to soil temperature and precipitation after vegetation restoration. We reveal that changes in microbial functional structure play important roles in regulating the effect of vegetation restoration and biocrusts on soil respiration. In addition, vegetation restoration also increases the microbial activity in biocrusted soils. This calls for an improved understanding of the effects of biocrusts on soil respiration under vegetation restoration scenarios to advance our ability to evaluate soil carbon releases from dryland ecosystems. Read the free Plain Language Summary for this article on the Journal blog.

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“…Mosses are a species‐rich clade found in almost all terrestrial ecosystems from the Arctic to the tropics (Geffert et al, 2013), with an often large impact on the carbon (C) and nitrogen (N) cycle (Elbert et al, 2012; Koranda & Michelsen, 2021). They live on soils, rocks and bark of living or dead trees under sometimes extreme climatic and nutrient‐poor conditions (Dierssen, 2001; Müller et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Biological nitrogen fixation, diversity and community structure of diazotrophs in two mosses in 25 temperate forests

Groß,

Hossen,

Dittrich

et al. 2023

Environmental Microbiology

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Many moss species are associated with nitrogen (N)‐fixing bacteria (diazotrophs) that support the N supply of mosses. Our knowledge relates primarily to pristine ecosystems with low atmospheric N input, but knowledge of biological N fixation (BNF) and diazotrophic communities in mosses in temperate forests with high N deposition is limited. We measured BNF rates using the direct stable isotope method and studied the total and potentially active diazotrophic communities in two abundant mosses, Brachythecium rutabulum and Hypnum cupressiforme, both growing on lying deadwood trunks in 25 temperate forest sites. BNF rates in both mosses were similar to those observed in moss species of pristine ecosystems. H. cupressiforme fixed three times more N2 and exhibited lower diazotrophic richness than B. rutabulum. Frankia was the most prominent diazotroph followed by cyanobacteria Nostoc. Manganese, iron, and molybdenum contents in mosses were positively correlated with BNF and diazotrophic communities. Frankia maintained high BNF rates in H. cupressiforme and B. rutabulum even under high chronic N deposition in Central European forests. Moss N concentration and 15N abundance indicate a rather minor contribution of BNF to the N nutrition of these mosses.

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Mosses reduce soil nitrogen availability in a subarctic birch forest via effects on soil thermal regime and sequestration of deposited nitrogen

Cited by 24 publications

References 77 publications

Plant functional types drive spatial and temporal variation in soil microbial community composition and extracellular enzyme activities in a tundra heath

Plant functional types drive spatial and temporal variation in soil microbial community composition and extracellular enzyme activities in a tundra heath

Microbial function regulates the effect of vegetation restoration on the contribution of biocrusts to soil respiration in drylands

Biological nitrogen fixation, diversity and community structure of diazotrophs in two mosses in 25 temperate forests

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