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Onder het maaiveld
Onder het Maaiveld is een driejarig programma van IUCN NL, De Vlinderstichting, NIOO-KNAW, WUR en het Centrum voor Bodemecologie. Samen met andere organisaties werken wij aan een structurele verandering in de omgang met onze waardevolle bodem. Ons doel? Herstel van het bodemleven in Nederland, als basis voor een gezonde natuur en een gezonde maatschappij. -
Harnessing the rhizosphere microbiome to enhance plant productivity
In Bio-Based Economy, plant materials are an essential resource for new industrial and sustainable applications. To ensure the production of sufficient plant biomass there is a need of mineral fertilizers. However, intensive fertilization causes leaching and run-off of nutrients, reduction in biodiversity, production of greenhouse gasses, global warming and changes in soil pH leading to environmental degradation. A key challenge is to intensify agricultural production methods in a way that minimizes harmful environmental effects of fertilizers. Therefore, there is an urgent need for new strategies that optimize plant growth and minimize abiotic and biotic factors that adversely affect plant growth and quality. The plant microbiome, i.e. the collective microbial communities associated with plants, harbors various fungal and bacterial genera that have beneficial effects on plant growth and health. Several bacterial genera promote plant growth and induce systemic resistance in plants against pathogens as well as insect pests. Recent 'omics'-based studies revealed that specific rhizobacteria cause substantial transcriptional changes in plants, leading to elevated levels of specific plant genes expression. Brazilian sugarcane production system is being developed towards to sustainable manner by recycling straw and vinasse (byproduct of ethanol industry), which combined practices allow less mineral fertilizers to be added into soil. In addition, the use of beneficial bacteria, such as plant growth promoting bacteria (PGPB) isolated from sugarcane rhizosphere has shown to increase plant growth and health under controlled situation. However, detailed investigation and fundamental understanding of the effect of these PGPB in different sugarcane genotypes in different soils containing different microbial community are urgent need. Therefore, this proposal aims to: (i) determine the effect of different soil microbial community composition on sugarcane growth inoculated with PGPB; (ii) identify the PGPB traits and genes involved in plant growth promotion; (iii) identify the plant traits and genes involved in plant growth promotion induced by PGPB. Potential applications of this proposal will be (i) the identified PGPB traits and genes to ensure or enhance plant biomass, yield and quality; (ii) the identified genotype-specific genes induced by PGPB responsible for enhancing plant productivity. The proposed project will provide new insights into mechanisms, traits and genes underlying PGPB-plant interactions and will yield new leads and tools to ensure/enhance sugarcane biomass for bio-based economy -
Succession of microbial functions in degraded saline soil restoration
The global saline-alkali land area has already exceeded 1.1 billion hectares. China has about 100 million hectares. Rice cultivation has been used as an effective strategy to amend saline-alkaline lands in northeastern Songnen Plain in China since the 1950s. However, it is not known the role of microbial functions during succession of soil restoration. The aim of this project is to fundamental understanding the microbial functions succession during the saline soil restoration. -
Restoring degraded lands with microbial inoculants
Land degradation usually leads to a reduction in soil fertility, decline of plant productivity, and loss of biodiversity. Introducing beneficial microbial inoculants to degraded lands represents a promising and sustainable strategy. The aim of this project is to reveal the ecological roles of microbial inoculants and soil-resident microbial community in restoring both belowground biodiversity and aboveground productivity in the degraded land. -
Deciphering the role of fungal denitrifiers in N2O production from soils
The goal of this project is to decipher the role of fungal denitrifiers in N2O production from soils under sustainable management practices. Here we apply mesocosms experiments combined with SIP and meta-omics approaches targeting the functional genes of N cycle. In addition, we design primers for fungal denitrifiers based on complete fungal genomes and soil metagenomics data. -
The role of beneficial microbe in soil aggregation
The aim of this project is to determine the ecological relationship between bacteria and soil aggregates. We inoculate individual beneficial bacteria and different microbial communities from different natural soils in simulated Mars soil, attempting to explain their improvement in soil aggregate stability by bacterial exudates (EPS), necromass and microbial functional traits. -
REPHORM - REcycled PHOsphorus Resolved by Microbes
Sufficient Phosphorus (P) and Iron (Fe) supply is essential for crop production. Most of the P and Fe in soil is not readily available for the plant, making agriculture depending on inorganic fertilizers mainly derived from depletable resources. An alternative to this unsustainable practice is to use recycled compounds recovered during wastewater treatment. This project focuses on the use of the two recycled compounds struvite (MgNH4PO4·6H2O) and vivianite (Fe3(PO4)2·8H2O) which are both insoluble and hard to synchronize with the nutrient needs during early plant development. To increase efficient nutrient release of these recycled sources, we propose the use of microbes that can solubilize P and release siderophore, both recognized traits of plant growth promoting microbes. Several plant growth-promoting microbes have been isolated, but their transfer to agriculture, so far, resulted in an inconsistent success, due to competition or resistance of the resident soil microbiome to inoculants. This project will circumvent this challenge by steering the local microbiome with the addition of recycled nutrients and will further optimize the microbiome by microbial community breeding. Overall, this project will focus on identifying microbial community members with struvite and vivianite solubilizing function, optimizing these communities, determining the role of these communities on increasing the nutrient release as well as monitoring the recruitment of these beneficial microbes in the rhizosphere and the effect on plant growth. -
ClipsMicro: Climate proof soils by steering soil and residue microbiomes
To mitigate climate change, global agricultural soils needs to store more carbon and emit less greenhouse gasses (GHG). In ClipsMicro, together with partners in agro-business, this is realised by steering soil microbes by application of novel, refined compost and crops that can reduce emissions of GHG. -
Clever Cover cropping. Synergistic Mixtures for Sustainable Soils
Since recently, Dutch farmers are required to grow cover crops in mixtures of at least two plant species.
In the Clever Cropping Project we investigated whether mixtures of cover crops have beneficial effects on soil microbiology and associated functions.
In long-term field experiments and laboratory incubations, we assessed emissions of greenhouse gasses and the diversity, abundance, and activity of microbial groups involved in environmentally relevant processes.
While in laboratory incubations we could clearly find increased beneficial microbial functioning associated with mixtures of cover crop residues, we could not observe this in a 5-year field experiment.
Overall, the use of cover crop mixtures did not have significant beneficial effects on soil microbial functioning but also no negative effects on for example greenhouse gas emissions.
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Physiological and ecological strategies of Acidobacteria
Acidobacteria is among the most abundant phylum in soils, however, their physiological capabilities and co-occurrence with soil inhabitants are still unknown.