Composition and activity of nitrifier communities in soil are unresponsive to elevated temperature and CO2, but strongly affected by drought

Joana Séneca,Andreas Richter,Christos Zioutis,Michael Wagner,Wolfgang Wanek,Marlies Dietrich,Alberto Canarini,Eva Simon,Judith Prommer,Michael Bahn,Erich M Pötsch,Craig W Herbold,Petra Pjevac

doi:10.1038/s41396-020-00735-7

Abstract

Nitrification is a fundamental process in terrestrial nitrogen cycling. However, detailed information on how climate change affects the structure of nitrifier communities is lacking, specifically from experiments in which multiple climate change factors are manipulated simultaneously. Consequently, our ability to predict how soil nitrogen (N) cycling will change in a future climate is limited. We conducted a field experiment in a managed grassland and simultaneously tested the effects of elevated atmospheric CO2, temperature, and drought on the abundance of active ammonia-oxidizing bacteria (AOB) and archaea (AOA), comammox (CMX) Nitrospira, and nitrite-oxidizing bacteria (NOB), and on gross mineralization and nitrification rates. We found that N transformation processes, as well as gene and transcript abundances, and nitrifier community composition were remarkably resistant to individual and interactive effects of elevated CO2 and temperature. During drought however, process rates were increased or at least maintained. At the same time, the abundance of active AOB increased probably due to higher NH4+ availability. Both, AOA and comammox Nitrospira decreased in response to drought and the active community composition of AOA and NOB was also significantly affected. In summary, our findings suggest that warming and elevated CO2 have only minor effects on nitrifier communities and soil biogeochemical variables in managed grasslands, whereas drought favors AOB and increases nitrification rates. This highlights the overriding importance of drought as a global change driver impacting on soil microbial community structure and its consequences for N cycling.

Highlights

Nitrogen (N) cycling is a fundamental process in terrestrial ecosystems, critical for the functioning of all living
Since the discovery of complete nitrifiers, there is a need for the reassessment of the relative role of each microbial group in ammonia oxidation under climate change
We report an in-depth assessment on the effect of multiple climate change drivers on soil nitrification, including (i) the quantification of functional genes and transcripts by quantitative PCR, (ii) a census of the nitrifying microorganisms by sequencing at the functional gene and transcript levels, and (iii) an estimation of gross ammonification and nitrification rates

Summary

Objectives

The goal of this study was to understand how elevated atmospheric CO2, elevated temperature and drought (D), alone or in combination, affect the relative abundance and diversity of nitrifier communities and their activity in a managed submontane grassland. We aimed to increase the 15N enrichment of the target pool to ~20 at%15N and added 100 μl of tracer solution per gram of fresh soil, after a previous photometrical determination of background NH4+ and NO3−pool sizes

Methods

Results

Conclusion