Abstract
Abstract. The coexistence of many N2O production pathways in soil hampers differentiation of microbial pathways. The question of whether fungi are significant contributors to soil emissions of the greenhouse gas nitrous oxide (N2O) from denitrification has not yet been resolved. Here, three approaches to independently investigate the fungal fraction contributing to N2O from denitrification were used simultaneously for, as far as we know, the first time (modified substrate-induced respiration with selective inhibition (SIRIN) approach and two isotopic approaches, i.e. end-member mixing approach (IEM) using the 15N site preference of N2O produced (SPN2O) and the SP/δ18O mapping approach (SP/δ18O Map)). This enabled a comparison of methods and a quantification of the importance of fungal denitrification in soil. Three soils were incubated in four treatments of the SIRIN approach under anaerobic conditions to promote denitrification. While one treatment without microbial inhibition served as a control, the other three treatments were amended with inhibitors to selectively inhibit bacterial, fungal, or bacterial and fungal growth. These treatments were performed in three variants. In one variant, the 15N tracer technique was used to estimate the effect of N2O reduction on the N2O produced, while two other variants were performed under natural isotopic conditions with and without acetylene. All three approaches revealed a small contribution of fungal denitrification to N2O fluxes (fFD) under anaerobic conditions in the soils tested. Quantifying the fungal fraction with modified SIRIN was not successful due to large amounts of uninhibited N2O production. In only one soil could fFD be estimated using modified SIRIN, and this resulted in 28 ± 9 %, which was possibly an overestimation, since results obtained by IEM and SP/δ18O Map for this soil resulted in fFD of below 15 % and 20 %, respectively. As a consequence of the unsuccessful SIRIN approach, estimation of fungal SPN2O values was impossible. While all successful methods consistently suggested a small or missing fungal contribution, further studies with stimulated fungal N2O fluxes by adding fungal C substrates and an improved modified SIRIN approach, including alternative inhibitors, are needed to better cross-validate the methods.
Highlights
The greenhouse gas nitrous oxide (N2O) contributes to global warming and to the depletion of the ozone layer in the stratosphere (Crutzen, 1970; IPCC, 2013)
All SIRIN results obtained with respect to N2O production by the fungal or bacterial fraction were unsatisfactory; fungal SPN2O values could not be assessed, and the overall results led to unsolved questions, which are discussed
Based on the presented results we conclude that the modified SIRIN approach in the form presented here is not appropriate to estimate the contribution of selected communities to denitrification from soil
Summary
The greenhouse gas nitrous oxide (N2O) contributes to global warming and to the depletion of the ozone layer in the stratosphere (Crutzen, 1970; IPCC, 2013). The largest anthropogenic N2O emissions originate from agricultural soils and are mainly produced during microbial nitrification, nitrifier denitrification and denitrification (Firestone and Davidson, 1989; Bremner, 1997; IPCC, 2013; WrageMönnig et al, 2018). In order to find mitigation strategies for N2O emissions from arable soils, it is important to understand N2O sources and sinks and improve knowledge about the production pathways and the microorganisms involved. It was believed that solely bacteria are involved in N2O formation during denitrification (Firestone and Davidson, 1989); several fungi are capable of denitrification (Bollag and Tung, 1972; Shoun et al, 1992). There are methodological approaches to disentangling sources of N2O, it is still challenging to clearly attribute N2O emitted from soil to bacterial or fungal denitrification
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