Research

There is increased awareness that soil life and plant symbionts play a key role in natural and agricultural ecosystems. Soils, and the astonishing biotic diversity they harbour, provide a number of important services to humans, such as supplying nutrients to crops, storing and cleaning water, and by degrading pesticides and chemicals. Microbes play an essential role in this endeavour. Microbes represent the unseen majority of life on Earth and are essential for plant growth and the functioning of terrestrial ecosystems. Microbes colonize almost any substrate on Earth and associate with humans, insects, plants and soils. By doing so, microbes form highly diverse and complex communities that are organised into so-called microbiomes.

Recent work, including our own, showed that soil biodiversity and especially microbiome richness and composition is of pivotal importance for natural and agricultural systems and promotes ecosystem functioning and multifunctionality (van der Heijden et al. 1998; Wagg et al. 2014; Bender et al. 2016). There is now increased recognition that plant microbiomes and communities of soil biota can be managed to improve plant productivity and agro-ecosystem sustainability. Our research bridges “Agroecology” and “Plant-Microbiome-Interactions and aims to merge basic questions centred around plant-microbiome interactions and using this knowledge to understand ecosystem functioning and to promote or keep high plant productivity in agro-ecosystems with minimal impact on the environment. Below both research themes (Agroecology and Plant-Microbiome Interactions) are introduced:

Agroecology

We study the impact of land use and agricultural management (e.g. conventional, organic and conservation agriculture) on plant yield, yield stability, biodiversity and a range environmental and ecological factors including nutrient cycling, soil life, soil multifunctionality and microbial communities1,2. The aim of this work is to develop and design productive and sustainable farming systems using soil ecological engineering3 and microbiome management, including field inoculation with beneficial mycorrhizal fungi3,4,5. This research topic has a strong applied component and a wide range of experiments are performed in the field, especially the farming systems and tillage experiment (the FAST trial, Figure 1). We also have established networks of farmer fields where the effects of particular management practices (organic farming, crop diversification, compost application) on soil life and ecosystem multifunctionality are investigated.

Agroecology
Figure 1: Agroecology: The farming systems and Tillage experiment at Agroscope. In this experiment, we investigate the agronomic, environmental and economic performance of the main Swiss arable farming systems (organic agriculture, conventional agricultural and conservation agriculture with reduced (organic systems) or no tillage (conventional systems where herbicides (e.g. glyphosate) are used to control weeds)). Together with a wide range of partners we investigate the effects of these arable farming systems on plant yield, soil biodiversity, soil and root microbiomes, nutrient cycling, soil erosion, soil structure, global warming potential, soil carbon sequestration, disease suppressiveness. Photo Raphael Wittwer.

Plant-Microbiome-Interaction

Plants interact with a myriad of micro-organisms, several of these are beneficial. It is our goal to understand how plant microbiomes functions and how changes in underground microbial communities’ influence plant growth and a range of ecosystem functions6 .

In controlled experiments we manipulate microbial composition and diversity, and test how change in plant and soil microbiome influence plant productivity7. This work builds upon earlier work we performed with arbuscular mycorrhizal fungi, widespread plant symbionts that form symbiotic associations with the majority of land plants8 (see Figure 2) and with nitrogen fixing rhizobial symbionts of legumes9.
Symbiotic Associations
Figure 2: Symbiotic Associations: Plant root colonized by arbuscular mycorrhizal fungi (blue). 150x. Photo Marcel van der Heijden.

In these earlier experiments we showed that the presence and diversity of arbuscular mycorrhizal fungi promote plant productivity and ecosystem multifunctionality10,11 (Figure 3).
Arbuscular mycorrhizal fungi
Figure 3: Arbuscular mycorrhizal fungi: The presence of arbuscular mycorrhizal fungi has a strong impact on plant growth and plant diversity. Shown are grassland microcosms where arbuscular mycorrhizal fungi are added to a plant community planted in sterilized soil (left box) or the same plant community in a box without added arbuscular mycorrhizal fungi (right box). This is an ongoing experiment with 110 experimental microcosms, established in 2016, where the number of added mycorrhizal fungi varies from zero to 10 different taxa. Photo: Marcel van der Heijden

Moreover, we observed that arbuscular mycorrhizal fungi and rhizobia bacteria can act synergisticly by supplying different nutrients to plants and supporting plant productivity9. Currently, we also perform field experiments to test whether inoculation with beneficial soil fungi can improve sustainable plant production (Figure 4).
Field inoculation experiments to enhance sustainable plant production
Figure 4: Field inoculation experiments to enhance sustainable plant production. In replicated field experiments we test whether the addition of arbuscular mycorrhizal fungi can be used to improve plant productivity and reduce fertiliser input. Photo: Franz Bender.

Literature

  1. Knapp S., van der Heijden, M.G.A., (2018) A global meta-analysis of yield stability in organic and conservation agriculture. Nature Communications 9 (, 3632.
  2. Wittwer, R.A., Dorn, B., Jossi, W., van der Heijden, M.G.A., (2017) Cover crops support ecological intensification of arable cropping systems. Scientific Reports 7:41911 | DOI 10.1038/srep41911.
  3. Bender, S.F., Wagg, C., van der Heijden, M.G.A. (2016) An underground revolution: Biodiversity and soil ecological engineering for agricultural sustainability. Trends in Ecology and Evolution 31: 440-444.
  4. van der Heijden, M.G.A., Hartman, M. (2016) Networking in the plant microbiome. PLOS Biology 14(2): e1002378 (12-Feb.2016).
  5. Schlaeppi, K., Bender, S., Mascher, F., Russo, G., Patrignani, A., Camenzind, T., Hempel, S., Rillig, M., van der Heijden, M.G.A. (2016) High-resolution community profiling of arbuscular mycorrhizal fungi. New Phytologist 212(3), 780-791.
  6. Banerjee, S., Schlaeppi, K., van der Heijden, M.G.A., (2018) Keystone taxa in microbiology: roles, drivers and importance for microbiome functioning. Nature Reviews Microbiology 16: 567-576.
  7. Wagg C., Bender S.F., Widmer F., van der Heijden, M.G.A. (2014) Soil biodiversity and soil community composition determine ecosystem multifunctionality. Proceedings of the National Academy of Sciences USA 111 (14): 5266-5270.
  8. van der Heijden, M.G.A., Martin, F., Selosse, M.A. & Sanders, I.R. (2015) Mycorrhizal Ecology and Evolution: The past, the present and the future. Tansley Review, New Phytologist 205: 1406-1423.
  9. van der Heijden, M.G.A., de Bruin, S., Luckerhoff, L., van Logtestijn, R.S.P., Schlaeppi, K. (2016) A widespread plant-fungal-bacterial symbiosis promotes plant biodiversity, plant nutrition and seedling recruitment. ISME journal 10: 389-399
  10. van der Heijden M.G.A., Klironomos J.N., Ursic M., Moutoglis P., Streitwolf-Engel R., Boller T., Wiemken A. & Sanders I.R. (1998) Mycorrhizal fungal diversity determines plant biodiversity, ecosystem variability and productivity. Nature 396: 72-75.
  11. Wagg, C., Jansa, J., Stadler, M., Schmid, B., van der Heijden, M.G.A. (20 Below ground fungal diversity drives above ground productivity. Ecology Letters 14: 1001-1009.