Membrane-localized leucine-rich repeat receptor kinases(LRR-RKs)sense diverse extracellular signals,and coordinate and specify cellular functions in plants.However,functional understanding and identification of the ce...Membrane-localized leucine-rich repeat receptor kinases(LRR-RKs)sense diverse extracellular signals,and coordinate and specify cellular functions in plants.However,functional understanding and identification of the cellular signaling of most LRR-RKs remain a major challenge owing to their genetic redundancy,the lack of ligand information,and subtle phenotypes of LRR-RK overexpression.Here,we report an engineered rapamycin-inducible dimerization(RiD)receptor system that triggers a receptor-specific LRR-RK signaling independent of their cognate ligands or endogenous receptors.Using the RiD-receptors,we demonstrated that the rapamycin-mediated association of chimeric cytosolic kinase domains from the BRI1/BAK1 receptor/co-receptor,but not the BRI1/BRI1 or BAK1/BAK1 homodimer,is sufficient to activate downstream brassinosteroid signaling and physiological responses.Furthermore,we showed that the engineered RiD-FLS2/BAK1 could activate flagellin-22-mediated immune signaling and responses.Using the RiD system,we also identified the potential function of an unkmown orphan receptor in immune signaling and revealed the differential activities of SERK co-receptors of LRR-RKs.Our results indicate that the RiD method can serve as a synthetic biology tool for precise temporal manipulation of LRR-RK signaling and for understanding LRR-RK biology.展开更多
基金supported by grants from the Basic Research Lab Program(2020R1A4A2002901)Basic Science Research Program(2019R1A2C1003783)through the National Research Foundation of Korea(NRF)funded by the Ministry of Science and ICTthe Next-Generation BioGreen 21 Program from Rural Development Administration,Republic of Korea(PJ01314801 and PJ013220),and Korea University.
文摘Membrane-localized leucine-rich repeat receptor kinases(LRR-RKs)sense diverse extracellular signals,and coordinate and specify cellular functions in plants.However,functional understanding and identification of the cellular signaling of most LRR-RKs remain a major challenge owing to their genetic redundancy,the lack of ligand information,and subtle phenotypes of LRR-RK overexpression.Here,we report an engineered rapamycin-inducible dimerization(RiD)receptor system that triggers a receptor-specific LRR-RK signaling independent of their cognate ligands or endogenous receptors.Using the RiD-receptors,we demonstrated that the rapamycin-mediated association of chimeric cytosolic kinase domains from the BRI1/BAK1 receptor/co-receptor,but not the BRI1/BRI1 or BAK1/BAK1 homodimer,is sufficient to activate downstream brassinosteroid signaling and physiological responses.Furthermore,we showed that the engineered RiD-FLS2/BAK1 could activate flagellin-22-mediated immune signaling and responses.Using the RiD system,we also identified the potential function of an unkmown orphan receptor in immune signaling and revealed the differential activities of SERK co-receptors of LRR-RKs.Our results indicate that the RiD method can serve as a synthetic biology tool for precise temporal manipulation of LRR-RK signaling and for understanding LRR-RK biology.