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Öğe The Synthetic Elicitor 2-(5-Bromo-2-Hydroxy-Phenyl)- Thiazolidine-4-Carboxylic Acid Links Plant Immunity to Hormesis(PLANT PHYSIOLOGY, 2016) RODRIGUEZ-SALUS, MELINDA; BEKTAS, YASEMİN; SCHROEDER, MERCEDES; KNOTH, COLLEEN; VU, TRANG; ROBERTS, PHILIP; KALOSHIAN, ISGOUHI; EULGEM, THOMASSynthetic elicitors are drug-like compounds that induce plant immune responses but are structurally distinct from natural defense elicitors. Using high-throughput screening, we previously identified 114 synthetic elicitors that activate the expression of a pathogen-responsive reporter gene in Arabidopsis (Arabidopsis thaliana). Here, we report on the characterization of one of these compounds, 2-(5-bromo-2-hydroxy-phenyl)-thiazolidine-4-carboxylic acid (BHTC). BHTC induces disease resistance of plants against bacterial, oomycete, and fungal pathogens and has a unique mode of action and structure. Surprisingly, we found that low doses of BHTC enhanced root growth in Arabidopsis, while high doses of this compound inhibited root growth, besides inducing defense. These effects are reminiscent of the hormetic response, which is characterized by low-dose stimulatory effects of a wide range of agents that are toxic or inhibitory at higher doses. Like its effects on defense, BHTC-induced hormesis in Arabidopsis roots is partially dependent on the WRKY70 transcription factor. Interestingly, BHTC-induced root hormesis is also affected in the auxin-response mutants axr1-3 and slr-1. By messenger RNA sequencing, we uncovered a dramatic difference between transcriptional profiles triggered by low and high doses of BHTC. Only high levels of BHTC induce typical defenserelated transcriptional changes. Instead, low BHTC levels trigger a coordinated intercompartmental transcriptional response manifested in the suppression of photosynthesis- and respiration-related genes in the nucleus, chloroplasts, and mitochondria as well as the induction of development-related nuclear genes. Taken together, our functional characterization of BHTC links defense regulation to hormesis and provides a hypothetical transcriptional scenario for the induction of hormetic root growth.Öğe The Synthetic Elicitor DPMP (2,4-dichloro-6-{(E)-[(3-methoxyphenyl)imino]methyl}phenol) Triggers Strong Immunity in Arabidopsis thaliana and Tomato(SCIENTIFIC REPORTS, 2016) BEKTAS, YASEMİN; RODRIGUEZ-SALUS, MELINDA; SCHROEDER, MERCEDES; GOMEZ, ADELINE; KALOSHIAN, ISGOUHI; EULGEM, THOMASSynthetic elicitors are drug-like compounds that are structurally distinct from natural defense elicitors. They can protect plants from diseases by activating host immune responses and can serve as tools for the dissection of the plant immune system as well as leads for the development of environmentally-safe pesticide alternatives. By high-throughput screening, we previously identified 114 synthetic elicitors that activate expression of the pathogen-responsive CaBP22-333Öğe Synthetic plant defense elicitors(FRONTIERS IN PLANT SCIENCE, 2015) BEKTAS, YASEMİN; EULGEM, THOMASo defend themselves against invading pathogens plants utilize a complex regulatorynetwork that coordinates extensive transcriptional and metabolic reprogramming. Althoughmany of the key players of this immunity-associated network are known, the detailsof its topology and dynamics are still poorly understood. As an alternative to forwardand reverse genetic studies, chemical genetics-related approaches based on bioactivesmall molecules have gained substantial popularity in the analysis of biological pathwaysand networks. Use of such molecular probes can allow researchers to access biologicalspace that was previously inaccessible to genetic analyses due to gene redundancy orlethality of mutations. Synthetic elicitors are small drug-like molecules that induce plantdefense responses, but are distinct from known natural elicitors of plant immunity. Whilethe discovery of some synthetic elicitors had already been reported in the 1970s,recent breakthroughs in combinatorial chemical synthesis now allow for inexpensivehigh-throughput screens for bioactive plant defense-inducing compounds. Along withpowerful reverse genetics tools and resources available for model plants and crop systems,comprehensive collections of new synthetic elicitors will likely allow plant scientists tostudy the intricacies of plant defense signaling pathways and networks in an unparalleledfashion. As synthetic elicitors can protect crops from diseases, without the need to bedirectly toxic for pathogenic organisms, they may also serve as promising alternatives toconventional biocidal pesticides, which often are harmful for the environment, farmers andconsumers. Here we are discussing various types of synthetic elicitors that have been usedfor studies on the plant immune system, their modes-of-action as well as their applicationin crop protection.
