Predicting the structure of soil communities from plant community taxonomy, phylogeny, and traits

Leff, Jonathan W.; Bardgett, Richard D.; Wilkinson, Anna; Jackson, Benjamin G.; Pritchard, William J.; Long, Jonathan R. De; Oakley, Simon; Mason, Kelly E.; Ostle, Nicholas J.; Johnson, David; Baggs, Elizabeth M.; Fierer, Noah

doi:10.1038/s41396-018-0089-x

Cited by 250 publications

(224 citation statements)

References 69 publications

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“…Whereas the fungal communities were distinctly different between two grasses and two legumes grown in monoculture, they became similar when the species where grown in mixtures. Furthermore, plant species identity in 4-species grassland mixtures was associated with bacterial and fungal community composition in the soil (Leff et al 2018).…”

Section: Indirect Neighbour Effects Via the Root Microbiomementioning

confidence: 99%

Linking ecology and plant pathology to unravel the importance of soil-borne fungal pathogens in species-rich grasslands

et al. 2018

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Soil-borne fungal diseases are a major problem in agriculture. A century ago, the Dutch plant pathologist Johanna Westerdijk recognized the importance of linking fungal biology with ecology to understand plant disease dynamics. To explore new ways to manage soil-borne fungal disease in agriculture by 'learning from nature', we follow in her footsteps: we link below ground plant-fungal pathogen interactions to ecological settings, i.e. natural grasslands. Ecological research hypothesised that the build-up of 'enemies' is reduced in species-rich vegetation compared to monocultures. To understand how plant diversity can suppress soilborne fungal pathogens, we first need to identify fungal actors in species-rich grasslands. Next-generation sequencing revealed a first glimpse of the potential fungal actors, but their ecological functions often remain elusive. Databases are becoming available to predict the ecological fungal guild, but classic phytopathology studies that isolate and characterize -taxonomically and functionally -, remain essential. Secondly, we need to set-up experiments that reveal ecological mechanisms underlying the complex below ground interactions between plant diversity and fungal pathogens. Several studies suggested that disease incidence of (hostspecific) pathogens is related to abundance of the host plant species. However, recent studies suggest that next to host species density, presence of heterospecific species additionally affects disease dynamics. We explore the direct and indirect ways of these neighboring plants diluting pathogen pressure. We argue that combining the expertise of plant pathologists and ecologists will improve our understanding of belowground plant-fungal pathogen interactions in natural grasslands and contribute to the design of sustainable and productive intercropping strategies in agriculture.

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Section: Indirect Neighbour Effects Via the Root Microbiomementioning

confidence: 99%

Linking ecology and plant pathology to unravel the importance of soil-borne fungal pathogens in species-rich grasslands

et al. 2018

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“…In grassland communities, aboveground pathogen pressure is determined by the phylogenetic structure of the plant community (Parker et al 2015). Whether belowground pathogen pressure is explained in a similar way has not yet been studied (but see Leff et al 2018). However, in case of such a phylogenetically structured belowground pathogen community, related plant species will experience similar pathogen pressures and therefore will likely show similar defence mechanisms.…”

Section: Future Directionsmentioning

confidence: 99%

“…While plant-soil feedback differences among taxonomically diverse plant species might be explained by phylogeny (Anacker et al 2014), very few -if any-studies have tested whether closely related congeneric species, such as sister species, have a more similar pattern of plant-soil feedback than distantly related congeneric species. Likewise, only few studies have studied the whole rhizosphere microbiome including nematodes among plant species (Leff et al 2018), while differences of only distinct parts of the microbiome were compared between congeneric plant species (Bouffaud et al 2014;Schlaeppi et al 2014). …”

Section: Introductionmentioning

confidence: 99%

Range-expanding plant species and their belowground neighbours : digging into novel interactions

Wilschut¹

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“…However, it remains to be tested how results obtained in individual plants grown in controlled conditions translate into effects in plant communities, as results on plant community level are contradictory. In both tropical forests (Barberán et al 2015) and temperate grasslands (Leff et al 2018) soil microbial community composition could be related to plant community composition, but not to plant traits. Which raises the questions:…”

Section: Rhizosphere Microbial Community Assemblymentioning

confidence: 99%

“…Plant functional traits, such as SRL, root N concentration and aboveground biomass explained microbial community composition in various studies (Legay et al 2014;Legay et al 2016;PerezJaramillo et al 2017;Fitzpatrick et al 2018), but not in Leff et al (2017) and Leff et al (2018).…”

Section: Plant Functional-traits Explain Rhizosphere Microbiomesmentioning

confidence: 99%

A plant’s inheritance : Soil legacy effects of crops and wild relatives in relation to plant functional traits

Barel¹

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During crop domestication plant characteristics have been artificially selected for, with potential unwanted side-effects as some characteristics might have been altered unintentionally. Since productivity in agriculture relies on the interactions between plant and soil, it is a necessity to study the relationship between plant traits, decomposition, microbial community composition and the possible effects on future plant growth.This thesis presents results from several experiments studying how plants influence the soil, through decomposition of plant residues, the soil microbial community assemblage, and its possible consequence for subsequent plant growth. In a crop rotation experiment plant-soil feedback effects have been studied at field scale, with legacy effects of winter cover crops as the primary focus. Influences of plant traits on litter decomposition and microbial community were studied both in a field context and under controlled greenhouse conditions. By comparing the legacy effects of crops with close-relatives from natural grasslands the effects of domestication on litter decomposition and rhizosphere microbial community composition were explored.In the field experiment, it was observed that mixtures of cover crops can perform better than the sum of their parts when the plants in the mixture complemented each other during their growth. Productivity and quality of cover crops was found to promote growth of subsequent main crops, in part through stimulation of soil fungal biomass and feedback effects of decomposing litter. In the greenhouse, growing plants were observed to suppress decomposition of root and shoot litter to varying extent depending on which plant was present and on the quality of the decomposing litter. The results also indicate that domestication has affected plant functional traits in a variety of ways, rather than having predictable effects across a range of crops. Plant functional traits are a useful approach to study legacy effects, as they predict decomposability of plant residues and partially explain the microbial community composition in the rhizosphere. Significance of plant traits as predictors varied with environmental conditions, thus interpretation of the results should be related to its context. This thesis contributes to the understanding of plant-soil interactions, with emphasis on differences and similarities of agricultural and natural ecosystems.

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Predicting the structure of soil communities from plant community taxonomy, phylogeny, and traits

Cited by 250 publications

References 69 publications

Linking ecology and plant pathology to unravel the importance of soil-borne fungal pathogens in species-rich grasslands

Linking ecology and plant pathology to unravel the importance of soil-borne fungal pathogens in species-rich grasslands

Range-expanding plant species and their belowground neighbours : digging into novel interactions

A plant’s inheritance : Soil legacy effects of crops and wild relatives in relation to plant functional traits

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