Evidence for rapid evolution in a grassland biodiversity experiment

Moorsel, Sofia J. van; Schmid, Marc W.; Wagemaker, Cornelis A. M.; Gurp, Thomas van; Schmid, Bernhard; Vergeer, Philippine

doi:10.1101/262303

Cited by 13 publications

(19 citation statements)

References 63 publications

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“…The observed shift in plant–plant interactions are consistent with several grassland studies investigating the effects of community evolution on community productivity and niche differentiation, where it was found that common rapid evolution in plant communities can lead to increases in ecosystem functioning 4,10,11,19 . We indeed observed a positive effect of common community history on the net biodiversity effect (i.e.…”

supporting

confidence: 89%

“…The productivity benefits of increasing species diversity rely on two main mechanisms, namely selection effects and complementarity effects, the latter encompassing both facilitation and niche differentiation 8,9 . In perennial natural grasslands, complementarity effects have been shown to increase over time due to evolutionary processes 4,10,11 . Notably, greater species complementarity can result from evolutionary changes 12 – i.e.…”

mentioning

confidence: 99%

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Rapid transgenerational adaptation in response to intercropping increases facilitation and reduces competition

Stefan¹,

Engbersen²,

Schöb³

2022

Preprint

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By capitalising on positive biodiversity-productivity relationships, intercropping provides opportunities to improve agricultural sustainability. However, intercropping is generally implemented using commercial seeds that were bred for maximal productivity in monocultures, which might limit the benefits of crop diversity on yield. Plants can adapt over generations to the level of surrounding plant diversity, notably through increases in niche differentiation. However, this adaptation potential and the corresponding yield benefit potential have not been explored in annual crop systems. Here we show that plant-plant interactions among annual crops evolved towards increased facilitation and reduced competition when the plants' coexistence history matched their current diversity setting, which led to an increase in overyielding of up to 58%. These higher yield benefits were linked to character convergence between species sharing the same coexistence history for two generations. Notably, the six crop species tested converged towards taller phenotypes with lower leaf dry matter content when grown in mixtures. This study provides the first empirical evidence for the importance of parental diversity affecting plant-plant interactions and ecosystem functioning of the following generations in annual cropping systems. These results have important implications for diversified agriculture as they demonstrate the yield potential of targeted cultivars for intercropping, which can be achieved through specific breeding for mixtures.

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supporting

confidence: 89%

mentioning

confidence: 99%

Rapid transgenerational adaptation in response to intercropping increases facilitation and reduces competition

Stefan¹,

Engbersen²,

Schöb³

2022

Preprint

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“…Generally, however, the direction was in favour of greater leaf defence traits and reduced leaf damage in plants from monocultures in support of our hypothesis (1) suggesting greater selection for plant defence traits in monocultures compared with mixtures. While it has been hypothesized that selection of epigenetic variants may also be involved (Tilman & Snell‐Rood, ), this was previously tested for in these plant communities and epigenetic changes were found to parallel genetic changes (van Moorsel et al, ). Although differential responses between plants selected in monocultures versus mixtures to the rhizosphere microbial communities were observed, a greater performance of plants selected in monocultures versus mixtures when associated with the corresponding species’ own monoculture rhizosphere microbial community was rare, providing little support for our hypothesis (2).…”

Section: Discussionmentioning

confidence: 99%

Plant responses to diversity‐driven selection and associated rhizosphere microbial communities

et al. 2020

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Plant diversity loss can alter plant–plant and plant–rhizosphere microbiome interactions. These altered interactions, in turn, may exert diversity‐driven selection pressure to which plants respond with phenotypic changes. Diverse plant communities may favour the survival and fitness of individuals with traits that avoid competition. Conversely, monocultures may accumulate species‐specific pests favouring greater investment in defence traits. Yet, it is unknown how altered plant rhizosphere interactions influence the plant diversity‐driven selection for altered plant phenotypes. We tested for plant diversity‐driven selection on plant above‐ground traits and how these traits are modified by their rhizosphere microbial communities after 11 years in experimental plant monocultures and mixtures. Plants propagated from monocultures or mixtures were grown in combination with their ‘home’ versus ‘away’ arbuscular mycorrhizal fungi (AMF) or non‐AMF microbes in two separate experiments using five and eight plant species, respectively. We hypothesized that plants in monocultures may be selected for better defence and better performance in association with rhizosphere microbial communities compared with plants in mixtures. Monoculture and mixture plants significantly differed in their above‐ground phenotypes. As predicted, plant traits related to defence (greater leaf mass per area and leaf dry matter content, reduced leaf damage) were more pronounced in monoculture plants in both experiments. Effects of the rhizosphere microbial communities, which generally enhanced plant growth, tended to be species‐specific. Significant three‐way interactions between diversity‐driven selection, AMF treatment and plant species showed that home versus away effects could be positive or negative, depending on plant species. We conclude that long‐term differences in plant diversity lead to selection for altered plant phenotypes. Such differences may be further modified in association with the AMF microbial communities derived from the different plant diversity treatments, but often outcomes are species‐specific. This suggests that plant species differ in their capacity to respond to diversity loss and associated changes in rhizosphere microbial communities, making it complicated to predict community‐level responses to such loss. A free Plain Language Summary can be found within the Supporting Information of this article.

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“…c . 10 000 of 36 000 RRBS fragments in Spartina (Alvarez et al ., unpublished); >40% of bsRADseq in Heliosperma (Trucchi et al ., )) or can be annotated with known plant genes (10–15% of epiGBS loci in six grassland species; Van Moorsel et al ., ), only some of the fragments actually overlap the 5′ end of genes (Alvarez et al ., unpublished) in which increased DNA methylation has been correlated with gene silencing (Niederhuth et al ., ; Niederhuth & Schmitz, ). The functional relevance of gene body methylation outside of the 5′ end in plants appears to vary by context and across taxa (Niederhuth & Schmitz, ), and often gene body methylation is not correlated or only weakly correlated to gene expression (Bewick & Schmitz, ).…”

Section: Limitations Of Rrbs Methods For Nonmodel Speciesmentioning

confidence: 99%

Opportunities and limitations of reduced representation bisulfite sequencing in plant ecological epigenomics

2018

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Contents Summary I. Introduction II. RRBS loci as genome-wide epigenetic markers III. Exploiting functional annotation of RRBS loci IV. Limitations of RRBS methods for nonmodel species V. Maximising the impact of RRBS in plants VI. Conclusions Acknowledgements SUMMARY: Investigating the features and implications of epigenetic mechanisms across the breadth of organisms and ecosystems is important for understanding the ecological relevance of epigenetics. Several cost-effective reduced representation bisulfite sequencing approaches (RRBS) have been recently developed and applied to different organisms that lack a well annotated reference genome. These new approaches improve the assessment of epigenetic diversity in ecological settings and may provide functional insights. We assess here the opportunities and limitations of RRBS in nonmodel plant species. Well thought out experimental designs that include complementary gene expression studies, and the improvement of genomics resources for the target group, promise to maximize the effect of future RRBS studies.

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Evidence for rapid evolution in a grassland biodiversity experiment

Cited by 13 publications

References 63 publications

Rapid transgenerational adaptation in response to intercropping increases facilitation and reduces competition

Rapid transgenerational adaptation in response to intercropping increases facilitation and reduces competition

Plant responses to diversity‐driven selection and associated rhizosphere microbial communities

Opportunities and limitations of reduced representation bisulfite sequencing in plant ecological epigenomics

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