Airborne Ethylene May Alter Antioxidant Protection and Reduce Tolerance of Holm Oak to Heat and Drought Stress

Sergi Munné-Bosch ^*, Josep Peñuelas , Dolores Asensio , and Joan Llusià

Departament de Biologia Vegetal, Universitat de Barcelona, Facultat de Biologia, 08028 Barcelona, Spain
Unitat d'Ecofisiologia CSIC-CEAB-CREAF, Facultat de Ciències, Universitat Autònoma de Barcelona, 08193 Bellaterra, Spain

^* Corresponding author; email: smunne{at}ub.edu.

Plant-emitted ethylene has received considerable attentionas a stress hormone and is considered to play a major role atlow concentrations in the tolerance of several species to bioticand abiotic stresses. However, airborne ethylene at high concentrations,such as those found in polluted areas (20-100 nL L^-1) for severaldays, has received far less attention in studies of plant stresstolerance, though it has been shown to alter photosynthesisand reproductive stages (seed germination, flowering, and fruitripening) in some species. To assess the potential effects ofairborne ethylene on plant stress tolerance in polluted areas,the extent of oxidative stress, photo- and antioxidant protection,and visual leaf area damage were evaluated in ethylene-treated(approximately 100 nL L^-1 in air) and control (without ethylenefumigation) holm oak (Quercus ilex) plants exposed to heat stressor to a combination of heat and drought stress. Control plantsdisplayed tolerance to temperatures as high as 50°C, whichmight be attributed, at least in part, to enhanced xanthophyllde-epoxidation and 2-fold increases in ${alpha}$ -tocopherol, and theysuffered oxidative stress only when water deficit was superimposedon temperatures above 45°C. By contrast, ethylene-treatedplants showed symptoms of oxidative stress at lower temperatures(35°C) than the controls in drought, as indicated by enhancedmalondialdehyde levels, lower ${alpha}$ -tocopherol and ascorbate concentrations,and a shift of the redox state of ascorbate to its oxidizedform. In addition, ethylene-treated plants showed higher visualleaf area damage and greater reductions in the maximum efficiencyof the PSII photochemistry than controls in response to heatstress or to a combination of heat and drought stress. Theseresults demonstrate for the first time that airborne ethyleneat concentrations similar to those found in polluted areas mayreduce plant stress tolerance by altering, among other possiblemechanisms, antioxidant defenses.

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