Potential soil enzyme activities are decoupled from microbial activity in dry residue-amended soil

Extracellular enzymes play an important role in the microbial acquisition of carbon (C) and organically bound nutrients, such as nitrogen (N). The objective of the present study was to investigate the effect of different soil moisture contents on potential soil enzyme activities (β-glucosidase and protease), microbial biomass and activity. Soil incubations were carried out with gravimetric moisture contents (GMC) ranging from 0.8 (air-dry) to 30%. After 14 days, respiration, net N mineralization and potential enzyme activities were lowest at GMC below 10% in the unamended samples. In the residue-amended soil, however, respiration and net N mineralization were highest at GMC of 20% or more, while potential β-glucosidase and protease activity were highest at GMC of 10% or less. Increasing the moisture content of air-dry soil after 14 days of incubation resulted in significantly reduced β-glucosidase activity, but increased protease activity. With the exception of the high potential β-glucosidase activity in the residue-amended dry soil, enzyme activities were well correlated with microbial biomass and ergosterol, a biomarker for fungal biomass. Therefore, our results suggest that across the different GMC, protease activity was mainly dependent on the continuous production by microorganisms, while β-glucosidase accumulated in the dry soil due to an increased half-life, which was the result of interactions with soil colloids. Shifts in microbial community composition may also have contributed to the observed differences.