Spatial and temporal dynamics of nitrogen fixing, nitrifying and denitrifying microbes in an unfertilzed grassland soil

Publication Type
Journal contribution (peer reviewed)
Authors
Regan, K., Stempfhuber, B., Schloter, M., Rasche, F., Prati, D., Philippot, L., Boeddinghaus, R., Kandeler, E., Marhan, S.
Year of publication
2017
Published in
Soil Biology & Biochemistry
Band/Volume
109/
Page (from - to)
214-226
Abstract

© 2016 Elsevier LtdThe microbial groups of nitrogen fixers, ammonia oxidizers, and denitrifiers largely drive the inorganic nitrogen cycle in temperate terrestrial ecosystems. Their spatial and temporal dynamics, however, vary depending on the studied scale. The present study aimed to fill a knowledge gap by providing an explicit picture of spatial and temporal dynamics of a subset of these soil microorganisms at the plot scale. We selected an unfertilized perennial grassland, where nitrogen cycling is considered to be efficient and tightly coupled to plant growth. At six times over one growing season 60 soil samples were taken from a 10 m × 10 m area and abundances of marker genes for total archaea and bacteria (16S rRNA), nitrogen fixing bacteria (nifH), ammonia oxidizing archaea (amoA AOA) and bacteria (amoA AOB), and denitrifying bacteria (nirS, nirK and nosZ) were determined by qPCR. Potential nitrification activity (PNA) and denitrifying enzyme activity (DEA) were determined. Seasonal changes in abundance patterns of marker genes were detected, and were associated with changes in substrate availability associated with plant growth stages. Potential nitrification and denitrification enzyme activities were strongly spatially structured at the studied scale, corresponding to periods of rapid plant growth, June and October, and their spatial distributions were similar, providing visual evidence of highly localized spatial and temporal conditions at this scale. Temporal variability in the N-cycling communities versus the stability of their respective potential activities provided evidence of both short-lived temporal niche partitioning and a degree of microbial functional redundancy. Our results indicate that in an unfertilized grassland, at the meter scale, abundances of microbial N-cycling organisms can exhibit transient changes, while nitrogen cycling processes remain stable.

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