Elevated atmospheric CO<sub>2</sub>changes defence allocation in wheat but herbivore resistance persists

Johnson, Scott N.; Cibils–Stewart, Ximena; Waterman, Jamie M.; Biru, Fikadu N.; Rowe, Rhiannon C.; Hartley, Susan

doi:10.1098/rspb.2021.2536

Cited by 9 publications

(9 citation statements)

References 51 publications

(62 reference statements)

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“…With greater C availability under eCO 2 , this may be less advantageous and plants may, for example, produce more C‐based phenolic defences rather than accumulate Si (e.g. Johnson et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

“…Herbivory, for example, is widely reported to rapidly increase Si uptake as a form of induced defence (Massey et al, 2007; Waterman et al, 2021). There is emerging evidence that eCO 2 reduces Si accumulation in many grass species due, in part, to concurrent increases in C concentrations (Biru et al, 2021; Johnson et al, 2022; Johnson & Hartley, 2018). The negative relationship between C and Si in plants may be due to “stoichiometric dilution” whereby an increase in one element, by definition, necessitates lower levels of other constituents (Hodson & Guppy, 2022; Quigley et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

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Elevated atmospheric CO₂ suppresses silicon accumulation and exacerbates endophyte reductions in plant phosphorus

et al. 2023

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Many temperate grasses are both hyper‐accumulators of silicon (Si) and hosts of Epichloë fungal endophytes, functional traits which may alleviate environmental stresses such as herbivore attack. Si accumulation and endophyte infection may operate synergistically, but this has not been tested in a field setting, nor in the context of changing environmental conditions. Predicted increases in atmospheric CO2 concentrations can affect both Si accumulation and endophyte function, but these have not been studied in combination. We investigated how elevated atmospheric CO2 (eCO2), Si supplementation, endophyte‐presence and insect herbivory impacted plant growth, stoichiometry (C, N, P and Si), leaf gas exchange (rates of photosynthesis, stomatal conductance, transpiration rates) and endophyte production of anti‐herbivore defences (alkaloids) of an important pasture grass (tall fescue; Lolium arundinaceum) in the field. eCO2 and Si supplementation increased shoot biomass (+52% and +31%, respectively), whereas herbivory reduced shoot biomass by at least 35% and induced Si accumulation by 24%. Shoot Si concentrations, in contrast, decreased by 17%–21% under eCO2. Si supplementation and herbivory reduced shoot C concentrations. eCO2 reduced shoot N concentrations which led to increased shoot C:N ratios. Overall, shoot P concentrations were 26% lower in endophytic plants compared to non‐endophytic plants, potentially due to decreased mass flow (i.e. observed reductions in stomatal conductance and transpiration). Alkaloid production was not discernibly affected by any experimental treatment. The negative impacts of endophytes on P uptake were particularly strong under eCO2. We show that eCO2 and insect herbivory reduce and promote Si accumulation, respectively, incorporating some field conditions for the first time. This indicates that these drivers operate in a more realistic ecological context than previously demonstrated. Reduced uptake of P in endophytic plants may adversely affect plant productivity in the future, particularly if increased demand for P due to improved plant growth under eCO2 cannot be met. Read the free Plain Language Summary for this article on the Journal blog.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Elevated atmospheric CO₂ suppresses silicon accumulation and exacerbates endophyte reductions in plant phosphorus

et al. 2023

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“…These effects are likely due to carbon (C) being more available under eCO 2 and it being less advantageous to accumulate Si (Johnson & Hartley, 2018). Several studies report negative correlations between Si and C concentrations, including structural carbon (e.g., cellulose and lignin) (Raven, 1983; Schoelynck et al, 2010; Klotzbucher et al, 2018) and defensive compounds (e.g., phenolics) (Cooke & Leishman, 2012; Frew et al, 2016; Johnson & Hartley, 2018; Johnson et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

Contrasting impacts of herbivore induction and elevated atmospheric CO₂ on silicon defences and consequences for subsequent herbivores

Biru

Cazzonelli

Elbaum

et al. 2022

Entomologia Exp Applicata

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Plants are often sequentially attacked by multiple herbivores; feeding by one herbivore can alter host plant quality that affects the performance of subsequent herbivores. Previous studies suggest that silicon (Si) is a highly inducible defence in grasses (Poaceae) following herbivory, so could mediate such temporally separated insect herbivore interactions. Elevated atmospheric CO2 concentrations (eCO2), in contrast, often reduce Si accumulation, which potentially weakens this interaction. We examined the effects of prior feeding by Helicoverpa armigera (Hübner) (Lepidoptera: Noctuidae) on the performance of crickets, Acheta domesticus (L.) (Orthoptera: Gryllidae), subsequently feeding on the same plant. We used Brachypodium distachyon (L.) P. Beauv. grass supplemented or non‐supplemented with Si and grown in the glasshouse maintained at ambient (aCO2) or eCO2 concentrations. As hypothesized, prior feeding by caterpillars induced Si accumulation. Despite eCO2 reducing Si accumulation, initial herbivore induction of Si negated the effects of eCO2. Both, previous caterpillar herbivory and Si supplementation reduced cricket performance. Si induction by successive herbivory was additive. Plant biomass was similar in plants attacked by caterpillars alone or both herbivores, suggesting that initial Si induction by caterpillars deterred feeding by crickets. Our results demonstrate that Si induction by one herbivore negatively impacts successive herbivores, as has been demonstrated for secondary metabolite‐mediated interactions. Uniquely, however, Si induction is an irreversible defence and potentially a stronger, or perhaps longer‐lasting mediator of such herbivore interactions in some plant taxa.

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“…Elevated CO 2 changes the primary and secondary metabolism of plants by stimulating the photosynthetic rate (Zavala et al, 2017 ), which not only resulted in increased carbon:nitrogen ratio, but also changed the insect resistance in plants (Zavala et al, 2013 ; Sun et al, 2015 , 2016 ; Guo et al, 2017 ; Johnson et al, 2022 ). Meanwhile, drought stress drives plants to develop a number of physiological responses as well, such as closing stoma, increasing carbohydrate and amino acid accumulation, and activating phytohormone signaling pathways (Mcdowell et al, 2008 ; Lee and Luan, 2012 ; Danquah et al, 2014 ; Ullah et al, 2018 ; Xie et al, 2021 ), which subsequently lead to the change in plant nutritional quality (water content and C/N ratio) as well as plant chemical defenses to insects (English-Loeb et al, 1997 ; Guo et al, 2016 ; Castagneyroi et al, 2018 ; Suarez-Vidal et al, 2019 ).…”

Section: Introductionmentioning

confidence: 99%

The Reciprocal Effect of Elevated CO2 and Drought on Wheat-Aphid Interaction System

Xie

Shi

et al. 2022

Front. Plant Sci.

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Due to the rising concentration of atmospheric CO2, climate change is predicted to intensify episodes of drought. However, our understanding of how combined environmental conditions, such as elevated CO2 and drought together, will influence crop-insect interactions is limited. In the present study, the direct effects of combined elevated CO2 and drought stress on wheat (Triticum aestivum) nutritional quality and insect resistance, and the indirect effects on the grain aphid (Sitobion miscanthi) performance were investigated. The results showed that, in wheat, elevated CO2 alleviated low water content caused by drought stress. Both elevated CO2 and drought promoted soluble sugar accumulation. However, opposite effects were found on amino acid content—it was decreased by elevated CO2 and increased by drought. Further, elevated CO2 down-regulated the jasmonic acid (JA) -dependent defense, but up-regulated the salicylic acid (SA)-dependent defense. Meanwhile, drought enhanced abscisic acid accumulation that promoted the JA-dependent defense. For aphids, their feeding always induced phytohormone resistance in wheat under either elevated CO2 or drought conditions. Similar aphid performance between the control and the combined two factors were observed. We concluded that the aphid damage suffered by wheat in the future under combined elevated CO2 and drier conditions tends to maintain the status quo. We further revealed the mechanism by which it happened from the aspects of wheat water content, nutrition, and resistance to aphids.

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Elevated atmospheric CO₂changes defence allocation in wheat but herbivore resistance persists

Cited by 9 publications

References 51 publications

Elevated atmospheric CO₂ suppresses silicon accumulation and exacerbates endophyte reductions in plant phosphorus

Elevated atmospheric CO₂ suppresses silicon accumulation and exacerbates endophyte reductions in plant phosphorus

Contrasting impacts of herbivore induction and elevated atmospheric CO₂ on silicon defences and consequences for subsequent herbivores

The Reciprocal Effect of Elevated CO2 and Drought on Wheat-Aphid Interaction System

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Elevated atmospheric CO2changes defence allocation in wheat but herbivore resistance persists

Cited by 9 publications

References 51 publications

Elevated atmospheric CO2 suppresses silicon accumulation and exacerbates endophyte reductions in plant phosphorus

Elevated atmospheric CO2 suppresses silicon accumulation and exacerbates endophyte reductions in plant phosphorus

Contrasting impacts of herbivore induction and elevated atmospheric CO2 on silicon defences and consequences for subsequent herbivores

The Reciprocal Effect of Elevated CO2 and Drought on Wheat-Aphid Interaction System

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Elevated atmospheric CO₂changes defence allocation in wheat but herbivore resistance persists

Elevated atmospheric CO₂ suppresses silicon accumulation and exacerbates endophyte reductions in plant phosphorus

Elevated atmospheric CO₂ suppresses silicon accumulation and exacerbates endophyte reductions in plant phosphorus

Contrasting impacts of herbivore induction and elevated atmospheric CO₂ on silicon defences and consequences for subsequent herbivores