| Title | Post-fire recovery of soil microbial functions is promoted by plant growth |
| Publication Type | Journal Article |
| Year of Publication | 2022 |
| Authors | Garcia-Pausas J., Romanya J., Casals P. |
| Journal | European Journal of Soil Science |
| Volume | 73 |
| Pagination | 15 |
| Date Published | Jul |
| Type of Article | Article |
| ISBN Number | 1351-0754 |
| Accession Number | WOS:000837995300001 |
| Keywords | aboveground biomass, Agriculture, biomass, carbon turnover, catabolic functional diversity, Community structure, diversity, fire severity, forest fires, heating, mineralization, nitrogen, organic-matter, Rhizodeposition, rhizosphere, soil, soil microbial functions, substrate-induced respiration |
| Abstract | Forest fires can alter the biological properties of soils. There is increasing evidence that fires cause a shift in soil microbial communities, which play a central role in forest carbon and nutrient cycling. In this study, we evaluate the effect of soil heating on soil microbial functions. We hypothesised that fire reduces the catabolic functional diversity of soil, and that post-fire plant growth enhances its recovery. To test this, we experimentally heated a forest soil at 200 degrees C (T200) or 450 degrees C (T450). Heated and unheated soils were then incubated in tubs with or without live grass (Lolium perenne L.). We determined the functional profiles by measuring the substrate-induced respiration (SIR) using the Microresp (TM) technique and analysed nutrient availability at the end of the incubation. At both temperatures, soil heating altered the respiration responses to substrate additions and the catabolic functional diversity of soils. Functional diversity was initially reduced in T200 soils but recovered at the end of the incubation. In contrast, T450 soils initially maintained the catabolic functional diversity, but decreased at the end of the incubation. Heating-induced nutrient availability stimulated the growth of grass, which in turn increased the response to several substrates and increased the functional diversity to values similar to the unheated controls. Our results suggest that fire-driven alteration of soil microbial communities has consequences at a functional level, and that the recovery of plant communities enhances the recovery of soil microbial functions. Highlights Soil experimental heating altered microbial functions and reduced soil functional diversity. Soil heating also increased nutrient availability, enhancing plant growth. Growth of plants promoted the recovery of soil functional diversity. Post-fire recovery of functional diversity may be related to the recovery of photosynthetic tissues.
|
| Alternate Journal | Eur. J. Soil Sci. |
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Garcia-Pausas, Jordi Romanya, Joan Casals, Pere
Garcia-Pausas, Jordi/L-2984-2014; Romanya, Joan/K-7714-2014; Casals, Pere/M-2418-2014
Garcia-Pausas, Jordi/0000-0003-2727-3167; Romanya, Joan/0000-0002-4519-9653; Casals, Pere/0000-0002-0372-988X
European Union [101000289, LIFE16 CCM/ES/000065]; Spanish Ministry of Economy and Comptetitiveness (MINECO)
This study was funded by the European Union under the framework of the H2020 HoliSoils (101000289) and LIFE-CLIMARK (LIFE16 CCM/ES/000065) project. Jordi Garcia-Pausas and Pere Casals were financially supported by Spanish Ministry of Economy and Comptetitiveness (MINECO) through Juan de la Cierva and I3 contracts, respectively. CTFC is member of the CERCA network of research centres of the Generalitat de Catalunya. We also thank to Juli G. Pausas for his useful suggestions on an earlier version of the manuscript and two anonymous reviewers for constructive comments.
3
Wiley
Hoboken
1365-2389
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Garcia-Pausas, J (corresponding author), Joint Res Unit CTFC AGROTECNIO, Ctra St Llorenc de Morunys,Km 2, Solsona 25280, Catalonia, Spain.
jordi.gpausas@gmail.com
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