Plant community composition steers grassland vegetation via soil legacy effects

Heinen, Robin; Hannula, S. Emilia; Long, Jonathan R. De; Huberty, Martine; Jongen, Renske; Kielak, Anna M.; Steinauer, Katja; Zhu, Feng; Bezemer, T. Martijn

doi:10.1111/ele.13497

Cited by 93 publications

(110 citation statements)

References 54 publications

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“…This observation is consistent with previous studies showing that forbs tend to grow better with grasses than with other forbs (Cahill et al, 2008), or that forbs grow better with heterospecifics than conspecifics (Semchenko et al, 2013). This is also consistent with PSF experiments showing that forbs grow better on soil conditioned by grasses than on soil conditioned by other forbs (Hendriks et al, 2013;Heinen et al, 2020). Based on recent evidence suggesting that plants with lower SRL are better at tolerating interspecific competition (Semchenko et al, 2018) and may be better able to cope with nitrogen stress (Freschet et al, 2018), we hypothesise that the production of roots with a lower SRL by D. deltoides is probably a plastic response that may increase plant fitness in the presence of grass competitors.…”

Section: Discussionsupporting

confidence: 92%

“…arrive early at a site, they will alter the biotic and abiotic components of the soil environment and create soil legacies that might affect early species performance (often negatively) as well as the growth and development of species arriving later during succession (Klironomos, 2002;Bever, 2003;Grman and Suding, 2010). Previous studies showed that early-arriving species can induce soil legacy effects through changes in the composition of soil microbial communities (e.g., accumulation of pathogenic fungi), which can then contribute to historical contingency effects by altering competitive relationships in plant communities (Kardol et al, 2007;Heinen et al, 2020). However, due to the strong interlinkage between microbial communities living in the rhizosphere and metabolites exuded by plant roots, biotic PSF effects are tightly associated with root exudation (Mommer et al, 2016;Sasse et al, 2018;Korenblum et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

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Soil chemical legacies trigger species-specific and context-dependent root responses in later arriving plants

Delory

Schempp

Spachmann

et al. 2020

Preprint

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Priority effects can have long-lasting consequences for the structure and functioning of plant communities. Currently, it is poorly understood to what extent the rhizo-sphere metabolome of plant communities is conditioned by its species composition and whether these changes affect subsequent species during assembly. We collected soil solutions from plant communities differing in species and functional group composition (forbs or grasses). We evaluated the effect of the rhizosphere metabolome found in the soil solutions on the growth, biomass allocation, and functional traits of a forb (Dianthus deltoides) and a grass species (Festuca rubra). The rhizosphere metabolome of forb and grass communities differed in composition and chemical diversity. While F. rubra did not respond to different rhizosphere solutions, soil exploration by D. deltoides roots decreased when plants received the rhizosphere solution from a grass or a forb community. Structural equation modelling showed that reduced soil exploration by D. deltoides arose via either a root growth-dependent pathway (forb metabolome) or a root trait-dependent pathway (grass metabolome). Reduced soil exploration was not connected to a decrease in total N uptake. Our findings reveal that rhizosphere chemical cues can affect later arriving plants and create belowground priority effects in grasslands.

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Section: Discussionsupporting

confidence: 92%

Section: Introductionmentioning

confidence: 99%

Soil chemical legacies trigger species-specific and context-dependent root responses in later arriving plants

Delory

Schempp

Spachmann

et al. 2020

Preprint

View full text Add to dashboard Cite

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“…Averages ± SE are shown; n = 8 [Colour figure can be viewed at wileyonlinelibrary.com] expectations based on controlled experiments ( Figure 6A,C), indicating that also the direction of these effects would need to change through time. Moreover, Heinen et al (2020) showed that fungal pathogens may also decrease over time. Long-term experiments have to determine how soil legacy effects change through time and how short-term greenhouse estimates represent (semi-)field soil legacy effects.…”

Section: Discussionmentioning

confidence: 99%

Local soil legacy effects in a multispecies grassland community are underlain by root foraging and soil nutrient availability

et al. 2020

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“…Similarly, 'current forb' soils with a legacy of previous grasses on them had very different fungal communities than 'current forb' soils with a legacy of previous forbs. Other work has shown that plant family and functional group can explain a large portion of the variation in fungal community structure (31,40,41) and that this division may play a prominent role in plant community dynamics in natural grasslands (7,42). This is likely due to species in these groups having higher similarities within than between groups in terms of functional traits (43,44) and chemical composition (45,46), which play an important role in shaping soil legacies.…”

Section: Discussionmentioning

confidence: 99%

“…These findings are in line with the conceptual idea that fungal growth rates are slower than those of bacteria (34,35) and that because of this, fungi are more stable and less affected by for instance temporal variability in the habitat or environment (31). Importantly, the more persistent effects of plants on the soil fungal communities than on bacterial communities may explain why most correlative studies that link plant responses and changes in the soil microbiome have shown that fungal communities drive plant community dynamics, while bacteria do not seem to strongly influence plant-soil-feedbacks (7,36) despite their known importance in rhizosphere processes (1,10). This is potentially due to faster turnover times of soil bacterial communities (34).…”

Section: Discussionmentioning

confidence: 99%

Persistence of plant-mediated microbial soil legacy effects in soil and inside roots

Hannula

Heinen

Huberty

et al. 2020

Preprint

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Plant-soil feedbacks are shaped by microbial legacies previous plants leave in the soil. We tested the persistence of such soil legacies after subsequent colonization by the same or other plant species, and whether the microbiome created by the previous plant explains current plant growth. Legacies of previous plants were detectable in soil fungal communities several months after their removal while concomitantly the effect of the current plant amplified in time. Remarkably, bacterial legacies faded away rapidly in the soil and bacterial communities were selected strongly by plant currently growing in the soil. Both fungal and bacterial legacies wrought by the previous plant were conserved inside the root endophytic compartment of the current plant and these endophytes affected significantly the plant growth. Hence, microbial soil legacies present at the time of plant establishment play a vital role in shaping plant growth even as the composition gradually changes in the soil after subsequent plant colonization, as they are taken up as endophytes in the plant. This suggests that plant-soil feedbacks may be partly mediated by a relatively stable endophytic community acquired in early ontogeny while the effects of previous plants detected on soil microbiomes vary between organisms studied. We further show that plants growing in their own soils harbor different endophytic microbiomes than plants growing in soils with legacy of other plants and that especially grasses are sensitive to species specific fungal pathogens while all plant species have less endophytic Streptomycetes when growing in their own soil. In conclusion, we show that soil legacies wrought by previous plants can remain present in the soils and inside the roots for months, even when subsequent plants colonize the soil and that these legacies also substantially modulate the plant growth.

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Plant community composition steers grassland vegetation via soil legacy effects

Cited by 93 publications

References 54 publications

Soil chemical legacies trigger species-specific and context-dependent root responses in later arriving plants

Soil chemical legacies trigger species-specific and context-dependent root responses in later arriving plants

Local soil legacy effects in a multispecies grassland community are underlain by root foraging and soil nutrient availability

Persistence of plant-mediated microbial soil legacy effects in soil and inside roots

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