Root-Associated Bacterial and Fungal Community Profiles of<i>Arabidopsis thaliana</i>Are Robust Across Contrasting Soil P Levels

Robbins, Chanz; Thiergart, Thorsten; Hacquard, Stéphane; Garrido‐Oter, Ruben; Gans, Wolfgang; Peiter, Edgar; Schulze‐Lefert, Paul; Spaepen, Stijn

doi:10.1094/pbiomes-09-17-0042-r

Cited by 36 publications

(42 citation statements)

References 57 publications

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“…Although the composition of the root microbiota has been shown to be strongly dependent on the soil in which the plant grows (Peiffer et al ., ; Schlaeppi et al ., ), the mechanistic basis underlying the control of root‐associated microbial communities by soil nutrient availability is largely unknown. Recent reports on A. thaliana root microbiota revealed a higher impact of long‐term soil fertilization with P on fungal communities compared with bacteria (Robbins et al ., ). In this article, we significantly expanded this knowledge by studying how P availability in natural nonsterile soil and the plant's response to soil P (controlled by the PSR) jointly shape the root‐associated fungal microbiota of the AM nonhost species A. thaliana in the short term.…”

Section: Discussionmentioning

confidence: 97%

“…; Tables S6, S7). This contrasts with long‐term fertilization studies, which have reported shifts in fungal soil communities on long‐term amendment of the soil with P fertilizer (Leff et al ., ; Robbins et al ., ), and suggests that P fertilization exerts rapid effects specifically on root‐associated microbes. It is also possible that short‐term effects of P concern primarily the activity of soil fungi, rather than their presence or abundance; therefore, RNA‐ rather than DNA‐based fungal community studies are needed to account for these effects.…”

Section: Discussionmentioning

confidence: 99%

“…All available studies have shown that the structure of the rootassociated fungal microbiome is strongly dependent on the soil in which the plant grows (Shakya et al, 2013;Coleman-Derr et al, 2016;Almario et al, 2017). This 'soil effect' usually accounts for the overlapping effects of different soil characteristics associated with the soil's geographical origin and with edaphic factors, such as mineral nutrient content and, more specifically, soil P content (Almario et al, 2017;Robbins et al, 2018;Yu et al, 2018). Although such studies provide evidence that plants growing in soils which have been subjected to contrasting long-term P fertilization regimes assemble different fungal microbiomes, the assembly rules and plant-mediated effects of P remain enigmatic.…”

Section: Introductionmentioning

confidence: 99%

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Plant‐mediated effects of soil phosphorus on the root‐associated fungal microbiota in Arabidopsis thaliana

et al. 2018

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Summary Plants respond to phosphorus (P) limitation through an array of morphological, physiological and metabolic changes which are part of the phosphate (Pi) starvation response ( PSR ). This response influences the establishment of the arbuscular mycorrhizal ( AM ) symbiosis in most land plants. It is, however, unknown to what extent available P and the PSR redefine plant interactions with the fungal microbiota in soil. Using amplicon sequencing of the fungal taxonomic marker ITS 2, we examined the changes in root‐associated fungal communities in the AM nonhost species Arabidopsis thaliana in response to soil amendment with P and to genetic perturbations in the plant PSR . We observed robust shifts in root‐associated fungal communities of P‐replete plants in comparison with their P‐deprived counterparts, while bulk soil communities remained unaltered. Moreover, plants carrying mutations in the phosphate signaling network genes, phr1 , phl1 and pho2 , exhibited similarly altered root fungal communities characterized by the depletion of the chytridiomycete taxon Olpidium brassicae specifically under P‐replete conditions. This study highlights the nutritional status and the underlying nutrient signaling network of an AM nonhost plant as previously unrecognized factors influencing the assembly of the plant fungal microbiota in response to P in nonsterile soil.

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Section: Discussionmentioning

confidence: 97%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Plant‐mediated effects of soil phosphorus on the root‐associated fungal microbiota in Arabidopsis thaliana

et al. 2018

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“…Root-specific enrichment for widespread OTUs, compared to soil and RS samples was tested with a generalized linear model, as described in ref. 22 (FDR, p < 0.05). To compare generalist OTUs from this study with OTUs found in roots of Lotus japonicus 26 bacterial OTUs were directly compared using the representative sequences (Blastn, 98% sequence identity).…”

Section: Methodsmentioning

confidence: 98%

“…However, the relative importance of different abiotic and biotic factors for the evolution and maintenance of local adaptation is poorly known 17, 18 . Particularly, soil edaphic factors and soil microbes are known to influence flowering phenology and modulate host fitness in natural soils 19, 20, 21, 22, 23 , even at the scale of a few meters 24 . Yet, information about the extent to which differences in soil properties contribute to divergent selection and the maintenance of adaptive differentiation among plant populations is still limited beyond classical examples of adaptation to extreme soil conditions 25 .…”

Section: Introductionmentioning

confidence: 99%

Root microbiota assembly and adaptive differentiation among European Arabidopsis populations

Thiergart

Durán

Ellis

et al. 2019

Preprint

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20Factors that drive continental-scale variation in root microbiota and plant adaptation are poorly 21 understood. We monitored root-associated microbial communities in Arabidopsis thaliana and co-22 occurring grasses at 17 European sites across three years. Analysis of 5,625 microbial community 23 profiles demonstrated strong geographic structuring of the soil biome, but not of the root microbiota. 24Remarkable similarity in bacterial community composition in roots of A. thaliana and grasses was 25 explained by the presence of a few diverse and geographically widespread taxa that disproportionately 26 colonize roots across sites. In a reciprocal transplant between two A. thaliana populations in Sweden 27and Italy, we uncoupled soil from location effects and tested their respective contributions to root 28 2 microbiota variation and plant adaptation. The composition of the root microbiota was affected by 29 location and soil origin, and to a lesser degree by host genotype. The filamentous eukaryotes were 30 particularly strongly affected by location. Strong local adaptation between the two A. thaliana 31 populations was observed, with difference in soil properties and microbes of little importance for the 32 observed magnitude of adaptive differentiation. Our results suggest that, across large spatial scales, 33 climate is more important than are soil conditions for plant adaptation and variation in root-associated 34 filamentous eukaryotic communities. 35 36 differentiation among plant populations is still limited beyond classical examples of adaptation to 57 extreme soil conditions 25 . 58 59Here, we tested whether roots of A. thaliana and co-occurring grasses growing in various soils and 60 climatic environments establish stable associations with bacterial and filamentous eukaryotic 61 communities across a latitudinal gradient in Europe. In a reciprocal transplant between two A. thaliana 62 populations in Sweden and Italy, we uncoupled soil from location effects and experimentally tested the 63 hypothesis that soil properties and climate drive root microbiota assembly and adaptive differentiation 64 between the two A. thaliana populations. 65 66We found that a widespread set of bacteria, but not filamentous eukaryotes, establish stable associations 67 with roots of A. thaliana and grasses across 17 sites in Europe, despite strong geographical structuring 68 and variation in the surrounding soil communities. The reciprocal transplant of soil and plant genotypes 69 between two native A. thaliana populations in northern and southern Europe showed that the 70 composition of root microbiota was more affected by soil properties and location than by host genotype. 71The effect of soil was stronger than that of location for root-associated bacteria, whereas the effect of 72 location was stronger for root-associated fungi and oomycetes. Transplant location, rather than origin 73 of soil, also largely accounted for strong selection against the nonlocal A. thaliana genotype at each site. 74Our results suggest that climat...

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Soil Microbes and Food Security Nexus: Imperativeness of Microbial Biotechnology

Peter

Enemo

Uzoh

2021

Food Security and Safety

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Root-Associated Bacterial and Fungal Community Profiles ofArabidopsis thalianaAre Robust Across Contrasting Soil P Levels

Cited by 36 publications

References 57 publications

Plant‐mediated effects of soil phosphorus on the root‐associated fungal microbiota in Arabidopsis thaliana

Plant‐mediated effects of soil phosphorus on the root‐associated fungal microbiota in Arabidopsis thaliana

Root microbiota assembly and adaptive differentiation among European Arabidopsis populations

Soil Microbes and Food Security Nexus: Imperativeness of Microbial Biotechnology

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