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Changes in the activity of soil enzymes after fire

Junmin Pei, Jiarong Wan, Hui Wang, Changming Fang, Ming Nie, Jinquan Li

2023Geoderma32 citationsDOIOpen Access PDF

Abstract

Fire can have widespread impacts on biogeochemical processes of carbon (C) and nutrient cycling. Soil extracellular enzyme activity (EEA) plays crucial roles in biogeochemical processes, while the general response pattern of EEAs to fire remains elusive. Here, we synthesized 1064 paired observations of fire effects on eight soil EEAs of β-D-Cellobiosidase (CB), β-1,4-Glucosidase (BG), β-1,4-Xylosidase (XYL), N-acetyl-glucosaminidase (NAG), urease (URE), phosphatase (PHO), peroxidase (PER), and phenol oxidase (POX) from 51 publications on a global scale. Results showed that fire significantly decreased hydrolases of C acquisition (sum of CB, BG, and XYL), N acquisition (sum of URE and NAG), and P acquisition (PHO) EEAs by 21.0%, 25.5%, and 29.9%, respectively. In contrast, fire significantly enhanced oxidative enzyme (sum of PER and POX) activities by 12.4%. Among all experimental, environmental, and soil variables, ecosystem type and soil C and N had greater effects on the various responses of EEAs to fire across studies. In addition, changes in soil C and N pools and microbial biomass were positively correlated with changes in hydrolytic EEAs but negatively correlated with changes in oxidative EEAs. These results suggest that the differential fire effects on soil hydrolytic and oxidative EEAs may be a crucial mechanism regulating soil C and nutrient cycling following fire events.

Topics & Concepts

Biogeochemical cycleNutrient cycleChemistryBiomass (ecology)CyclingNutrientEcosystemSoil carbonEnvironmental chemistryEnvironmental scienceBiologyEcologySoil waterForestryGeographyOrganic chemistryFire effects on ecosystemsSoil Carbon and Nitrogen DynamicsHeme Oxygenase-1 and Carbon Monoxide
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