Abstract
In a changing environment, plants need to cope with the impact of rising temperatures together with high light intensity. Here, we used lipidomics in the tomato model system to identify lipophilic molecules that enhance tolerance to combined high-temperature and high-light stress. Among several hundred metabolites, the two most strongly up-regulated compounds were α-tocopherol and plastoquinone/plastoquinol. Both are well-known lipid antioxidants and contribute to the protection of photosystem II (PSII) against photodamage under environmental stress. To address the protective function of tocopherol, an RNAi line (vte5) with decreased expression of VTE5 and reduced levels of α-tocopherol was selected. VTE5 encodes phytol kinase, which acts in the biosynthetic pathway of tocopherols. vte5 suffered strong photoinhibition and photobleaching when exposed to combined high-light and high-temperature stress, but neither stress alone produced a visible phenotype. As vte5 had plastoquinone levels similar to those of the wild type under combined stress, the strong phenotype could be attributed to the lack of α-tocopherol. These findings suggest that VTE5 protects against combined high-light and high-temperature stress and does so by supporting α-tocopherol production.
Highlights
Plants are sessile organisms and are constantly exposed to environmental challenges
Lipid extracts were isolated from fresh leaf tissue and analyzed by ultrahigh-pressure liquid chromatography coupled with atmospheric pressure chemical ionizationquadrupole time-of-flight mass spectrometry (UHPLCAPCI-quadrupole time-offlight mass spectrometry (QTOF-MS))
The high temperatures (HT) cluster was characterized by the accumulation of the saturated galactolipid MGDG-18:3/16:0, and the control and high light (HL) clusters were separated from the other clusters, represented by MGDG-18:3/16:3, MGDG-18:3/18:3, and DGDG-18:3/18:3 (Fig. 1B)
Summary
Plants are sessile organisms and are constantly exposed to environmental challenges. The salvage pathway requires phytol kinase (VTE5) and phytylphosphate kinase (VTE6), converting free phytol into phytyl diphosphate; vte and vte mutant plants accumulate less tocopherol (Valentin et al, 2006; Ischebeck et al, 2006; vom Dorp et al, 2015; Almeida et al, 2016). Apart from tocopherol, phytol may be converted into fatty acid phytyl esters (FAPEs) (Ischebeck et al, 2006; Gaude et al, 2007; Lippold et al, 2012). This process detoxifies free phytol, which has detergent-like characteristics (Dörmann, 2007)
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