Journal
ECOLOGY AND EVOLUTION
Volume 11, Issue 15, Pages 9958-9969Publisher
WILEY
DOI: 10.1002/ece3.7661
Keywords
AOA; AOB; Biological Nitrification Inhibition (BNI); burning; nitrification; perennial grasses; savanna; trees
Categories
Funding
- French national programme EC2CO
- Sorbonne University Emergence program
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Savannas are characterized by the coexistence of grasses and trees, with fires being critical for their mutual existence. Grasses inhibit nitrification and trees stimulate it, favoring coexistence. However, fires can affect plant nitrogen cycling control, impacting tree-grass competition for nitrogen. Fire in a humid savanna in Ivory Coast reduced soil water content and increased soil ammonium availability, without impacting microbial abundances. Fire decreased archaeal nitrifier transcriptional activities and nitrification enzymatic activity, potentially due to the growth of nitrification-inhibiting grasses post-fire.
Savannas are characterized by the coexistence of grasses and trees. Fires are critical for their coexistence, because they decrease the survival of tree seedlings and saplings and their recruitment to the adult stage. In some humid savannas, perennial grasses inhibit nitrification and trees stimulate nitrification, which likely favors coexistence between trees and grasses. However, fires may influence plant capacity to control nitrogen cycling, which could subsequently influence tree-grass coexistence and savanna nitrogen budget. Therefore, we sampled soil in a humid savanna of Ivory Coast under the dominant nitrification-inhibiting grass species and the dominant nitrification-stimulating tree species and under bare soil before and after (i.e., 5 days) fire during the long dry season. We quantified the total microbial and nitrifier abundances and transcriptional activities and the nitrification enzyme activity. Fire decreased soil water content, probably by increasing evaporation and, maybe, by triggering the growth of grasses, and increased soil ammonium availability likely due to ash deposition and increased mineralization. Fire did not impact the total archaeal, bacterial, or fungal abundances, or that of the nitrifiers. Fire did not impact archaeal transcriptional activity and increased bacterial and fungal total transcriptional activities. In contrast, fire decreased the archaeal nitrifier transcriptional activities and the nitrification enzymatic activity, likely due to the often reported resumption of the growth of nitrification-inhibiting grasses quickly after the fire (and the subsequent increase in root exudation). These results pave the way for a better understanding of the short-term effects of fire on nitrogen cycling and tree-grass competition for nitrogen.
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