Rapid Shifts in Soil Nutrients and Decomposition Enzyme Activity in Early Succession Following Forest Fire

While past research has studied forest succession on decadal timescales, ecosystem responses to rapid shifts in nutrient dynamics within the first months to years of succession after fire (e.g., carbon (C) burn-off, a pulse in inorganic nitrogen (N), accumulation of organic matter, etc.) have been l...

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Bibliographic Details
Published in:Forests 2017-09, Vol.8 (9), p.347
Main Authors: Knelman, Joseph, Graham, Emily, Ferrenberg, Scott, Lecoeuvre, Aurélien, Labrado, Amanda, Darcy, John, Nemergut, Diana, Schmidt, Steven
Format: Article
Language:English
Subjects:
Annual variations
Availability
Biological activity
carbon
Cycles
Decomposition
disturbance
Dynamics
Ecological succession
ecosystem process
Environmental changes
ENVIRONMENTAL SCIENCES
Enzymatic activity
Enzyme activity
Enzymes
exoenzymes
extracellular enzymes
Forest ecosystems
forest fire
Forest fires
Forests
Glucosidase
Microbial activity
Microorganisms
N-Acetylglucosaminidase
Nitrogen
Nutrient availability
Nutrient dynamics
Nutrients
Organic matter
Seasonal variations
Soil chemistry
soil enzymes
Soil nutrients
succession
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Summary:While past research has studied forest succession on decadal timescales, ecosystem responses to rapid shifts in nutrient dynamics within the first months to years of succession after fire (e.g., carbon (C) burn-off, a pulse in inorganic nitrogen (N), accumulation of organic matter, etc.) have been less well documented. This work reveals how rapid shifts in nutrient availability associated with fire disturbance may drive changes in soil enzyme activity on short timescales in forest secondary succession. In this study, we evaluate soil chemistry and decomposition extracellular enzyme activity (EEA) across time to determine whether rapid shifts in nutrient availability (1-29 months after fire) might control microbial enzyme activity. We found that, with advancing succession, soil nutrients correlate with C-targeting β-1,4-glucosidase (BG) EEA four months after the fire, and with N-targeting β-1,4-N-acetylglucosaminidase (NAG) EEA at 29 months after the fire, indicating shifting nutrient limitation and decomposition dynamics. We also observed increases in BG:NAG ratios over 29 months in these recently burned soils, suggesting relative increases in microbial activity around C-cycling and C-acquisition. These successional dynamics were unique from seasonal changes we observed in unburned, forested reference soils. Our work demonstrates how EEA may shift even within the first months to years of ecosystem succession alongside common patterns of post-fire nutrient availability. Thus, this work emphasizes that nutrient dynamics in the earliest stages of forest secondary succession are important for understanding rates of C and N cycling and ecosystem development.
ISSN:1999-4907
1999-4907
DOI:10.3390/f8090347