Natural plant disease suppressiveness in soils extends to insect pest control
2024
Harmsen, Nadine | Vesga, Pilar | Glauser, Gaetan | Klötzli, Françoise | Heiman, Clara M. | Altenried, Aline | Vacheron, Jordan | Muller, Daniel | Moënne-Loccoz, Yvan | Steinger, Thomas | Keel, Christoph | Garrido-Sanz, Daniel | Université de Lausanne | Swiss National Science Foundation | National Centres of Competence in Research (Switzerland) | Harmsen, Nadine [0009-0000-1115-5508] | Vesga, Pilar [0000-0002-8156-8110] | Glauser, Gaetan [0000-0002-0983-8614] | Heiman, Clara M. [0000-0003-4550-7537] | Vacheron, Jordan [0000-0003-0031-1338] | Moënne-Loccoz, Yvan [0000-0002-9817-1953] | Steinger, Thomas [0000-0001-8658-1579] | Keel, Christoph [0000-0002-8968-735X] | Garrido-Sanz, Daniel [0000-0003-3279-6421] | Consejo Superior de Investigaciones Científicas [https://ror.org/02gfc7t72]
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Show more [+] Less [-]Background: Since the 1980s, soils in a 22-km2 area near Lake Neuchâtel in Switzerland have been recognized for their innate ability to suppress the black root rot plant disease caused by the fungal pathogen Thielaviopsis basicola. However, the efficacy of natural disease suppressive soils against insect pests has not been studied. Results: We demonstrate that natural soil suppressiveness also protects plants from the leaf-feeding pest insect Oulema melanopus. Plants grown in the most suppressive soil have a reduced stress response to Oulema feeding, reflected by dampened levels of herbivore defense-related phytohormones and benzoxazinoids. Enhanced salicylate levels in insect-free plants indicate defense-priming operating in this soil. The rhizosphere microbiome of suppressive soils contained a higher proportion of plant-beneficial bacteria, coinciding with their microbiome networks being highly tolerant to the destabilizing impact of insect exposure observed in the rhizosphere of plants grown in the conducive soils. We suggest that presence of plant-beneficial bacteria in the suppressive soils along with priming, conferred plant resistance to the insect pest, manifesting also in the onset of insect microbiome dysbiosis by the displacement of the insect endosymbionts. Conclusions: Our results show that an intricate soil–plant-insect feedback, relying on a stress tolerant microbiome network with the presence of plant-beneficial bacteria and plant priming, extends natural soil suppressiveness from soilborne diseases to insect pests. 4oEYADM9UCsv5obDEsLZQ_Video Abstract
Show more [+] Less [-]Open access funding provided by University of Lausanne This research was funded through the 2018–2019 BiodivERsA joint call for research proposals, under the BiodivERsA3 ERA-Net COFUND program, and with the funding organizations Swiss National Science Foundation (grant SuppressSOIL no. 31BD30_186540) and ANR (grant SuppressSOIL no. ANR19-EBI3-0007). This research was also funded by the Swiss National Centre of Competence in Research (NCCR) Microbiomes (grant no. 51NF40_180575) and the University of Lausanne.
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This bibliographic record has been provided by Instituto Nacional de Investigación y Tecnología Agraria y Alimentaria