AI Article Synopsis
- Microbial denitrification is crucial for soil nitrogen availability to plants, but factors affecting denitrifier communities in the rhizosphere are not fully understood.
- Waterlogging can lead to anoxic conditions, increasing denitrification and nitrogen loss, which is investigated in this study using wheat plant rhizospheres.
- Anoxia and nitrogen limitation alter denitrifier community structures and activities, with nitrogen limitation having a larger effect compared to waterlogging, especially in the rhizosphere of plants, ultimately impacting nitrogen cycling and greenhouse gas emissions.
Article Abstract
Microbial denitrification plays a key role in determining the availability of soil nitrogen (N) to plants. However, factors influencing the structure and function of denitrifier communities in the rhizosphere remain unclear. Waterlogging can result in root anoxia and increased denitrification, leading to significant N loss from soil and potential nitrous oxide (N(2)O) emissions. This study investigated denitrifier gene abundance, community structure and activity in the rhizosphere of wheat in response to anoxia and N limitation. Denitrifier community structure in the rhizosphere differed from that in bulk soil, and denitrifier gene copy numbers (nirS, nirK, nosZ) and potential denitrification activity were greater in the rhizosphere. Anoxia and N limitation, and in particular a combination of both, reduced the magnitude of this effect on gene abundance (in particular nirS) and activity, with N limitation having greater impact than waterlogging in rhizosphere soil, in contrast to bulk soil where the impact of waterlogging was greater. Increased N supply to anoxic plants improved plant health and increased rhizosphere soil pH, which resulted in enhanced reduction of N(2)O. Both anoxia and N limitation significantly influenced the structure and function of denitrifier communities in the rhizosphere, with reduced root-derived carbon postulated to play an important role.
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| http://dx.doi.org/10.1111/1574-6941.12015 | DOI Listing |
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