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Silicon-mediated herbivore defence in a pasture grass under reduced and Anthropocene levels of CO2
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Silicon-mediated herbivore defence in a pasture grass under reduced and Anthropocene levels of CO2
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Silicon-mediated herbivore defence in a pasture grass under reduced and Anthropocene levels of CO2
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Journal Article
Silicon-mediated herbivore defence in a pasture grass under reduced and Anthropocene levels of CO2
2023
Overview
The uptake and accumulation of silicon (Si) in grass plants play a crucial role in alleviating both biotic and abiotic stresses. Si supplementation has been reported to increase activity of defence-related antioxidant enzyme, which helps to reduce oxidative stress caused by reactive oxygen species (ROS) following herbivore attack. Atmospheric CO 2 levels are known to affect Si accumulation in grasses; reduced CO 2 concentrations increase Si accumulation whereas elevated CO 2 concentrations often decrease Si accumulation. This can potentially affect antioxidant enzyme activity and subsequently insect herbivory, but this remains untested. We examined the effects of Si supplementation and herbivory by Helicoverpa armigera on antioxidant enzyme (catalase, CAT; superoxide dismutase, SOD; and ascorbate peroxidase, APX) activity in tall fescue grass ( Festuca arundinacea ) grown under CO 2 concentrations of 200, 410, and 640 ppm representing reduced, ambient, and elevated CO 2 levels, respectively. We also quantified foliar Si, carbon (C), and nitrogen (N) concentrations and determined how changes in enzymes and elemental chemistry affected H. armigera relative growth rates and plant consumption. Rising CO 2 concentrations increased plant mass and foliar C but decreased foliar N and Si. Si supplementation enhanced APX and SOD activity under the ranging CO 2 regimes. Si accumulation and antioxidant enzyme activity were at their highest level under reduced CO 2 conditions and their lowest level under future levels of CO 2 . The latter corresponded with increased herbivore growth rates and plant consumption, suggesting that some grasses could become more susceptible to herbivory under projected CO 2 conditions.
