Farnesyl diphosphate synthase (FPS) catalyzes the synthesis of farnesyl diphosphate from isopentenyl diphosphate and dimethylallyl diphosphate. Arabidopsis (Arabidopsis thaliana) contains two genes (FPS1 and FPS2) encoding FPS. Single fps1 and fps2 knockout mutants are phenotypically indistinguishable from wild-type plants, while fps1/fps2 double mutants are embryo lethal. To assess the effect of FPS down-regulation at postembryonic developmental stages, we generated Arabidopsis conditional knockdown mutants expressing artificial microRNAs devised to simultaneously silence both FPS genes. Induction of silencing from germination rapidly caused chlorosis and a strong developmental phenotype that led to seedling lethality. However, silencing of FPS after seed germination resulted in a slight developmental delay only, although leaves and cotyledons continued to show chlorosis and altered chloroplasts. Metabolomic analyses also revealed drastic changes in the profile of sterols, ubiquinones, and plastidial isoprenoids. RNA sequencing and reverse transcription-quantitative polymerase chain reaction transcriptomic analysis showed that a reduction in FPS activity levels triggers the misregulation of genes involved in biotic and abiotic stress responses, the most prominent one being the rapid induction of a set of genes related to the jasmonic acid pathway. Down-regulation of FPS also triggered an iron-deficiency transcriptional response that is consistent with the irondeficient phenotype observed in FPS-silenced plants. The specific inhibition of the sterol biosynthesis pathway by chemical and genetic blockage mimicked these transcriptional responses, indicating that sterol depletion is the primary cause of the observed alterations. Our results highlight the importance of sterol homeostasis for normal chloroplast development and function and reveal important clues about how isoprenoid and sterol metabolism is integrated within plant physiology and development.Isoprenoids are the largest class of all known natural products in living organisms, with tens of thousands of different compounds. In plants, isoprenoids perform essential biological functions, including maintenance of proper membrane structure and function (sterols), electron transport (ubiquinones and plastoquinones), posttranslational protein modification (dolichols serving as glycosylation cofactors and prenyl groups), photosynthesis (chlorophylls and carotenoids), and regulation of growth and development (abscisic acid, brassinosteroids, cytokinins, and GAs [Croteau et al., 2000] and strigolactones [Al-Babili and Bouwmeester, 2015]). A large number of isoprenoids also play prominent roles as mediators of interactions between plants and their environment, including a variety of defense responses against biotic and abiotic stresses (Tholl and Lee, 2011). In fact, there is hardly any aspect of plant growth, development, and reproduction not relying on isoprenoids or isoprenoid-derived compounds. In addition, many plant isoprenoids are of great economic importan...
