Decreased Soil Microbial Nitrogen Under Vegetation ‘Shrubification’ in the Subarctic Forest–Tundra Ecotone: The Potential Role of Increasing Nutrient Competition Between Plants and Soil Microorganisms

The consequences of warming-induced ‘shrubification’ on Arctic soil carbon storage are receiving increased attention, as the majority of ecosystem carbon in these systems is stored in soils. Soil carbon cycles in these ecosystems are usually tightly coupled with nitrogen availability. Soil microbial...

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Published in:Ecosystems (New York) 2023-11, Vol.26 (7), p.1504-1523
Main Authors: Stark, Sari, Kumar, Manoj, Myrsky, Eero, Vuorinen, Jere, Kantola, Anu M., Telkki, Ville-Veikko, Sjögersten, Sofie, Olofsson, Johan, Männistö, Minna K.
Format: Article
Language:English
Subjects:
Biomass
Biomedical and Life Sciences
Birch trees
Carbohydrates
Carbon
Carbon 13
Carbon content
Carbon cycle
Carbon dioxide
Carbon sequestration
Chitin
Climate change
climate warming
CO2 release
Deciduous trees
Density
Ecology
Ecosystems
Empetrum hermaphroditum
Environmental Management
Enzymatic activity
extracellular enzymes
Forests
Geoecology/Natural Processes
Global warming
Hydrology/Water Resources
Immobilization
Life Sciences
Microorganisms
mountain birch forest
Mountain forests
Natural resources
Nitrogen
NMR
Nuclear magnetic resonance
Nutrients
Organic matter
Organic soils
Oxidases
Phenoloxidase
Phenols
Plant Sciences
Respiration
Shrubs
Soil analysis
Soil erosion
Soil microorganisms
Soil organic matter
Soils
Taiga & tundra
Tundra
tundra heath
Zoology
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Summary:The consequences of warming-induced ‘shrubification’ on Arctic soil carbon storage are receiving increased attention, as the majority of ecosystem carbon in these systems is stored in soils. Soil carbon cycles in these ecosystems are usually tightly coupled with nitrogen availability. Soil microbial responses to ‘shrubification’ may depend on the traits of the shrub species that increase in response to warming. Increase in deciduous shrubs such as Betula nana likely promotes a loss of soil carbon, whereas the opposite may be true if evergreen shrubs such as Empetrum hermaphroditum increase. We analyzed soil organic matter stocks and 13 C NMR fractions, microbial CO 2 respiration, biomass, extracellular enzyme activities (EEAs), and their association with shrub density in northern Sweden after 20 years of experimental warming using open top chambers (OTCs). Our study sites were located in a tundra heath that stores high soil carbon quantities and where the OTCs had increased deciduous shrubs, and in a mountain birch forest that stores lower soil carbon quantities and where the OTCs had increased evergreen shrubs. We predicted that organic matter stocks should be lower and respiration and EEAs higher inside the OTCs than untreated plots in the tundra, whereas no effect should be detected in the forest. Soil organic matter stocks and 13 C NMR fractions remained unaffected at both sites. When expressed as per gram microbial biomass, respiration and EEAs for carbohydrate and chitin degradation were higher inside the OTCs, and contrasting our prediction, this effect was stronger in the forest. Unexpectedly, the OTCs also led to a substantially lower microbial biomass carbon and nitrogen irrespective of habitat. The decline in the microbial biomass counteracted increased activities resulting in no effect of the OTCs on respiration and a lower phenol oxidase activity per gram soil. Microbial biomass nitrogen correlated negatively with evergreen shrub density at both sites, indicating that ‘shrubification’ may have intensified nutrient competition between plants and soil microorganisms. Nutrient limitation could also underlie increased respiration per gram microbial biomass through limiting C assimilation into biomass. We hypothesize that increasing nutrient immobilization into long-lived evergreen shrubs could over time induce microbial nutrient limitation that contributes to a stability of accumulated soil organic matter stocks under climate warming.
ISSN:1432-9840
1435-0629
1435-0629
DOI:10.1007/s10021-023-00847-z