Joint control by soil moisture, functional genes and substrates on response of N2O flux to climate extremes in a semiarid grassland

•N2O flux is sensitive and insensitive to drought and heat wave, respectively.•Soil water content is a first-order predictor of seasonal variation of N2O flux.•Inter-annual variations of N2O flux are impacted by precipitation distribution.•Archaeal amoA and nirK mainly regulates climate extremes eff...

Full description

Saved in:
Bibliographic Details
Published in:Agricultural and forest meteorology 2022-04, Vol.316, p.108854, Article 108854
Main Authors: Li, Linfeng, Hao, Yanbin, Wang, Weijin, Biederman, Joel A., Wang, Yanfen, Zheng, Zhenzhen, Wen, Fuqi, Qian, Ruyan, Zhang, Biao, Song, Xiaoning, Cui, Xiaoyong, Xu, Zhihong
Format: Article
Language:English
Subjects:
Archaea
C and N substrates
climate
Drought
forests
grasslands
greenhouse gases
heat
Heat wave
meteorology
microbial carbon
nitrogen
Nitrous oxide
nitrous oxide production
regression analysis
Soil functional genes
soil water
soil water content
Water availability
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•N2O flux is sensitive and insensitive to drought and heat wave, respectively.•Soil water content is a first-order predictor of seasonal variation of N2O flux.•Inter-annual variations of N2O flux are impacted by precipitation distribution.•Archaeal amoA and nirK mainly regulates climate extremes effects on N2O flux. Nitrous oxide (N2O), the third most important greenhouse gas, contributes to the increasing frequency and severity of climate extremes. Disentangling feedbacks of climate extremes on terrestrial N2O emission is important for forecasting future climate changes. Here, we experimentally imposed extreme drought and heat wave events during three years in a semiarid grassland to investigate the responses of N2O flux. We identified that N2O flux suppression during droughts was mediated by soil water content (SWC), microbial biomass carbon (MBC), soil inorganic nitrogen (SIN) and dissolved organic carbon (DOC) contents, and the abundance of archaeal amoA, nirK, and narG. However, bacterial amoA, nirS, and nosZ remained stable. Upon rewetting following droughts, the SWC, SIN, DOC, archaeal amoA, nirK, narG, and resultant N2O fluxes recovered to the magnitude of the ambient control. In contrast, heat waves alone or in combination with drought did not impact N2O fluxes or the underlying physical, chemical and microbial states. Stepwise multiple linear regression suggested that SWC, DOC, and MBC were the key factors regulating immediate responses of N2O flux to climate extremes while the major factors regulating seasonal mean N2O flux in response to climate extremes were archaeal amoA abundance, nirK abundance, and MBC. Our results suggest that N2O fluxes were sensitive to droughts but insensitive to heat waves. Soil moisture induced changes in substrate availability, and the community size of total and functional microorganisms in soil jointly regulated N2O responses to climate extremes. The relative importance of regulating factors shifted at different timescales.
ISSN:0168-1923
1873-2240
DOI:10.1016/j.agrformet.2022.108854