Salicylic acid-mediated reductions in yield in Nicotiana attenuata challenged by aphid herbivory

Aphid herbivory decreases primary production in natural ecosystems and reduces crop yields. The mechanism for how aphids reduce yield is poorly understood as some studies suggest aphid feeding directly impedes photosynthesis, whereas other studies suggest a change in allocation of resources from gro...

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Bibliographic Details
Published in:Arthropod-plant interactions 2013-02, Vol.7 (1), p.45-52
Main Authors: Donovan, Michael P., Nabity, Paul D., DeLucia, Evan H.
Format: Article
Language:English
Subjects:
Aphidoidea
Artificial diets
Behavioral Sciences
Biomass
Biomedical and Life Sciences
Chemical defense
Crop yield
Density
Ecology
Entomology
Fecundity
Flowering
Flowering plants
Herbivores
Herbivory
Infestation
Insects
Invertebrates
Jasmonic acid
Life Sciences
Nicotiana attenuata
Original Paper
Photosynthesis
Plant biomass
Plant growth
Plant Pathology
Plant Sciences
Plants (botany)
Primary production
Resource allocation
Resource availability
Rosette
Salicylic acid
Seed set
Survival
Tobacco
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Summary:Aphid herbivory decreases primary production in natural ecosystems and reduces crop yields. The mechanism for how aphids reduce yield is poorly understood as some studies suggest aphid feeding directly impedes photosynthesis, whereas other studies suggest a change in allocation of resources from growth to defense compounds reduces yield. To determine the mechanisms underlying reduced plant growth by aphids, Nicotiana attenuata plants, native tobacco, were infested with Myzus persicae ssp. nicotianae , tobacco-adapted green peach aphids, at low and high densities, and plant performance including fitness was assessed. To test the direct defense capacity of salicylic acid (SA) on aphid performance, we fed aphids an artificial diet with varying levels of SA and measured their survivorship and fecundity. There was no detectable effect of aphid herbivory on net photosynthesis, yet herbivory reduced plant growth, final biomass (43 % at high aphid density), and seed set (18 % at high aphid density) at both low and high aphid infestation levels. High-density aphid attack during the rosette and flowering stage caused an increase in SA levels, but caused only a transient decrease in jasmonic acid concentration at low aphid density. SA concentrations similar to those found in infested flowering plants decreased aphid fecundity, suggesting that SA was an effective chemical defense response against aphids. These results suggest that as aphid densities increased the proximal cause of reduced growth and yield was not reduced photosynthesis, but instead resources may have been mobilized for defense via the SA pathway, decreasing the availability of resources for building plant biomass.
ISSN:1872-8855
1872-8847
DOI:10.1007/s11829-012-9220-5