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BonaRes (Modul A, Phase 2): DiControl - Impacts on agronomical management as well as on the employment of microbial biocontrol strains on soil health and suppressivness towards pathogens - subproject A (DiControl)


Project code: 031B0514A
Contract period: 01.10.2018 - 30.09.2021
Budget: 467,750 Euro
Purpose of research: Applied research
Keywords: rhizosphere, soil microbiom, soil suppressiveness towards plant pathogens

The project aim is the investigation of the impact of long-term farming strategies (intensive and extensive) on the soil microbiome and its function in terms of soil suppressiveness against plant pathogens. In addition, the associated rhizosphere microbiome will be analyzed considering plant characteristics (model: lettuce).

Intensive farming strategies can result in substantial yield losses through accumulation of plant pathogens in soil and the occurrence of plant diseases. The ability of soils to suppress plant pathogens is a characteristic of soil quality and health. This ability is mediated to a large extent by the composition of the soil microbial community. A better understanding of how farming strategies affect soil properties such as the soil microbiome is key to proposing improved farming strategies for sustainable agriculture.
We expect to gain new insight into soil and rhizosphere microbiomes, as well as their functions involved in soil disease suppressiveness. This knowledge will allow the evaluation of farming strategies for optimizing soil functions regarding certain bacterial and fungal taxa that demonstrate positive effects on soil health, especially on the suppression of pathogens. Finding indicators for soil suppressiveness will allow the evaluation and optimization of farming strategies. Root exudate components with consistent beneficial effects on plant growth and inhibitory effects on pathogens can open new perspectives for practical application. The socio-economic part of the research enlightens consequences and interpretations of political regulations in the field and delivers recommendations for bioenergy decision-making.

Project results phase 1
Long-term farming practice such as tillage and crop rotation affect significantly the structure of prokaryotic and fungal community in the soil and in the rhizosphere. An effect on rhizosphere microbiota was revealed also by nitrogen-fertilization intensity. A higher bacterial diversity was observed in organically compared to mineral fertilized soils. Differences in growth and plant health were found on the model plant lettuce grown under controlled conditions in soils under various farming practice. Our results confirmed the crucial role of the plant in driving rhizosphere microbiota assemblage. We revealed differences in suppressiveness against the pathogen Rhizoctonia solani comparing the soils.

Expected results phase 2
We expect an effect of long-term farming practice (tillage, N-fertilization intensity, pre-crop) on the rhizosphere microbiome on different crops at field scale. We will reveal differences in plant growth/health, disease incidence (DI) and in the relative abundance of potential fungal pathogens in root affected soil depending on farming practice. The use of beneficial microorganisms (BMs) will improve plant health and reduce DI on plants. The effect of BMs will be more effective in combined treatment than in single application of a BM. The improvement of plant health will result increase soil health in short- and long-term (plant-soil feedback).

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