Elevated CO2 alters C3 plant tolerance to insect herbivory, as well as the induction kinetics of defense hormones salicylic acid (SA) and jasmonic acid (JA), but the underlying physiological mechanism causing this response is not well understood. In principle, SA could be induced under elevated CO2 by reactive oxygen signals generated in photosynthesis, ultimately influencing chemical defense. To test whether the effects of elevated CO2 on C3 plant chemical defense against herbivorous insects are modulated by photosynthesis, Arabidopsis thaliana var. Col-0 plants were grown in two 2x2x2 nested factorial combinations of ambient (400ppm) and elevated (800ppm) CO2, and two dimensions of light regimes comprising intensity (mild' 150mol E m(-2)s(-1) vs. low' light, 75mol E m(-2)s(-1)) and periodicity (continuous', 150mol E m(-2)s(-1) vs. dynamic', in which lights were turned off, then on, for 15min every 2h). Plants were challenged with herbivore damage from third instar Trichoplusia ni (cabbage looper). Consistent with experimental predictions, elevated CO2 interacted with light as well as herbivory to induce foliar concentration of SA, while JA was suppressed. Under dynamic light, foliar content of total glucosinolates was reduced. Under combination of elevated CO2 and dynamic light, T. ni removed significantly more leaf tissue relative to control plants. The observations that CO2 and light interactively modulate defense against T. ni in A. thaliana provide an empirical argument for a role of photosynthesis in C3 plant chemical defense.
1.Univ Illinois, Dept Plant Biol, 265 Morrill Hall,505 S Goodwin, Urbana, IL 61801 USA 2.Univ Illinois, Dept Entomol, 265 Morrill Hall,505 S Goodwin, Urbana, IL 61801 USA 3.Univ Illinois, Carl R Woese Inst Genom Biol, 1206 West Gregory Dr, Urbana, IL 61801 USA
Recommended Citation:
Gog, Linus,Berenbaum, May R.,DeLucia, Evan H.. Mediation of Impacts of Elevated CO2 and Light Environment on Arabidopsis thaliana (L.) Chemical Defense against Insect Herbivory Via Photosynthesis[J]. JOURNAL OF CHEMICAL ECOLOGY,2019-01-01,45(1):61-73