Pathogen-associated molecular pattern(PAMP)-triggered immunity(PTI)is an essential layer of plant disease resistance.Robust bioassays for PTI are pre-required to dissect its molecular mechanism.In this study,we establ...Pathogen-associated molecular pattern(PAMP)-triggered immunity(PTI)is an essential layer of plant disease resistance.Robust bioassays for PTI are pre-required to dissect its molecular mechanism.In this study,we established that lateral root growth inhibition as a simple and robust measurement of PTI in rice seedlings.Specifically,flg22,a well-characterized PAMP from bacterial flagellin,was used to induce PTI in rice seedlings.While flg22 treatment induced PR gene expression and mitogen-activated protein kinase activation in the roots of rice seedlings to support the PTI triggered,this treatment substantially repressed lateral root growth,but it did not alter primary root growth.Moreover,treatments with chitin(i.e.,a fungal PAMP)and oligogalacturonides(i.e.,classical damage-associated molecular pattern)clearly inhibited the lateral root growth,although a priming step involving ulvan was required for the chitin treatment.The bioassay developed was applicable to various rice cultivars and wild species.Thus,lateral root growth inhibition represents a simple and reliable assay for studying PTI in rice plants.展开更多
Gibberella stalk rot(GSR)caused by Fusarium graminearum is one of the most devastating diseases of maize,seriously impacting maize yield and quality,as well as the ability to use technology of mechanical harvesting.En...Gibberella stalk rot(GSR)caused by Fusarium graminearum is one of the most devastating diseases of maize,seriously impacting maize yield and quality,as well as the ability to use technology of mechanical harvesting.Environmental conditions including photoperiod affect crop disease resistance.However,the mechanism underlying photoperiod-regulated maize GSR resistance remains unexplored.We found in this study that GSR resistance is regulated by the ZmPIF4.1(Phytochrome-Interacting Factor4)-ZmPTI1c(Pto-Interacting 1)-ZmMYB31 module coupled with photoperiod.The functional analysis of zmpti1c mutant indicated that ZmPTI1c negatively regulates maize GSR resistance.Short day promoted the disease progression in both zmpti1c and wild-type plants.ZmPTI1c promoter contains multiple predicted cis-acting elements for light responses.Yeast one-hybrid assay(Y1H),Electrophoretic mobility shift analysis(EMSA),and Dual-luciferase(LUC)reporter assays demonstrated that ZmPIF4.1 binds to the G-box in ZmPTI1c promoter and activates its expression.Moreover,expression levels of ZmPIF4 and ZmPTI1c were significantly higher under short day than under long day.ZmPTI1c interacted with and phosphorylated ZmMYB31.GSR resistance in zmmyb31 mutant was significantly increased than in wild type,indicating that ZmMYB31 also negatively regulated GSR resistance.Furthermore,ZmMYB31 suppressed the transcriptional activation of ZmPTI1c by ZmPIF4.1.Overall,ZmPIF4.1-ZmPTI1c-ZmMYB31negatively regulates maize immunity to GSR,which is likely modulated by photoperiod.展开更多
Pathogen/microbe-associated molecular patterns(PAMPs/MAMPs) are recognized by plant pattern recognition receptors(PRRs)localized on the cell surface to activate immune responses.This PAMP-triggered immunity(PTI) confe...Pathogen/microbe-associated molecular patterns(PAMPs/MAMPs) are recognized by plant pattern recognition receptors(PRRs)localized on the cell surface to activate immune responses.This PAMP-triggered immunity(PTI) confers resistance to a broad range of pathogenic microbes and,therefore,has a great potential for genetically engineering broad-spectrum resistance by transferring PRRs across plant families.Pathogenic effectors secreted by phytopathogens often directly target and inhibit key components of PTI signaling pathways via diverse biochemical mechanisms.In some cases,plants have evolved to produce decoy proteins that mimic the direct virulence target,which senses the biochemical activities of pathogenic effectors.This kind of perception traps the effectors of erroneous targeting and results in the activation of effector-triggered immunity(ETI) instead of suppressing PTI.This mechanism suggests that artificially designed decoy proteins could be used to generate new recognition specificities in a particular plant.In this review,we summarize recent advances in research investigating PAMP recognition by PRRs and virulence effector surveillance by decoy proteins.Successful expansion of recognition specificities,conferred by the transgenic expression of EF-Tu receptor(EFR) and AvrPphB susceptible 1(PBS1) decoys,has highlighted the considerable potential of PRRs and artificially designed decoys to expand plant resistance spectra and the need to further identify novel PRRs and decoys.展开更多
Pattern-triggered immunity(PTI)and effector-triggered immunity(ETI)are required for host defense against pathogens.Although PTI and ETI are intimately connected,the underlying molecular mechanisms remain elusive.In th...Pattern-triggered immunity(PTI)and effector-triggered immunity(ETI)are required for host defense against pathogens.Although PTI and ETI are intimately connected,the underlying molecular mechanisms remain elusive.In this study,we demonstrate that flg22 priming attenuates Pseudomonas syringae pv.tomato DC3000(Pst)AvrRpt2-induced hypersensitive cell death,resistance,and biomass reduction in Arabidopsis.Mitogen-activated protein kinases(MAPKs)are key signaling regulators of PTI and ETI.The absence of MPK3 and MPK6 significantly reduces pre-PTI-mediated ETI suppression(PES).We found that MPK3/MPK6 interact with and phosphorylate the downstream transcription factor WRKY18,which regulates the expression of AP2C1 and PP2C5,two genes encoding protein phosphatases.Furthermore,we observed that the PTI-suppressed ETI-triggered cell death,MAPK activation,and growth retardation are significantly attenuated in wrky18/40/60 and ap2c1 pp2c5 mutants.Taken together,our results suggest that the MPK3/MPK6-WRKYs-PP2Cs module underlies PES and is essential for the maintenance of plant fitness during ETI.展开更多
Plant immunity is controlled by both positive regulators such as PBS3 and EDS1 and negative regulators such as NPR3 and NPR4.However,the relationships among these important immune regulators remain elusive.In this stu...Plant immunity is controlled by both positive regulators such as PBS3 and EDS1 and negative regulators such as NPR3 and NPR4.However,the relationships among these important immune regulators remain elusive.In this study,we found that PBS3 interacts with EDS1 in both the cytoplasm and the nucleus,and is required for EDS1 protein accumulation?NPR3 and NPR4,which function as salicylic acid receptors and adaptors of Cullin3-based E3 ligase,interact with and mediate the degradation of EDS1 via the 26S proteasome.We further discovered that PBS3 inhibits the polyubiquitination and subsequent degradation of EDS1 by reducing the association of EDS1 with the Cullin3 adaptors NPR3 and NPR4.Furthermore,we showed that PBS3 and EDS1 also contribute to PAMP-triggered immunity in addition to effector-triggered immunity.Collectively,our study reveals a novel mechanism by which plants fine-tune defense resporises by inhibiting the degradation of a positive player in plant immunity.展开更多
Poly(ADP-ribosyl)ation(PARylation)is a posttranslational modification reversibly catalyzed by poly(ADP-ribose)polymerases(PARPs)and poly(ADP-ribose)glycohydrolases(PARGs)and plays a key role in multi-ple cellular proc...Poly(ADP-ribosyl)ation(PARylation)is a posttranslational modification reversibly catalyzed by poly(ADP-ribose)polymerases(PARPs)and poly(ADP-ribose)glycohydrolases(PARGs)and plays a key role in multi-ple cellular processes.The molecular mechanisms by which PARylation regulates innate immunity remain largely unknown in eukaryotes.Here we show that Arabidopsis UBC13A and UBC13B,the major drivers of lysine 63(K63)-linked polyubiquitination,directly interact with PARPs/PARGs.Activation of pathogen-associated molecular pattern(PAMP)-triggered immunity promotes these interactions and enhances PARylation of UBC13.Both parp1 parp2 and ubc13a ubc13b mutants are compromised in immune responses with increased accumulation of total pathogenesis-related(PR)proteins but decreased accu-mulation of secreted PR proteins.Protein disulfide-isomerases(PDIs),essential components of endo-plasmic reticulum quality control(ERQC)that ensure proper folding and maturation of proteins destined for secretion,complex with PARPs/PARGs and are PARylated upon PAMP perception.Significantly,PARylation of UBC13 regulates K63-linked ubiquitination of PDIs,which may further promote their disulfide isomerase activities for correct protein folding and subsequent secretion.Taken together,these results indicate that plant immunity is coordinately regulated by PARylation and K63-linked ubiquitination.展开更多
基金supported by the National Key Research and Development Program of China(Grant No.2016YFD0100602)the National Natural Science Foundation of China(Grant No.31901868)。
文摘Pathogen-associated molecular pattern(PAMP)-triggered immunity(PTI)is an essential layer of plant disease resistance.Robust bioassays for PTI are pre-required to dissect its molecular mechanism.In this study,we established that lateral root growth inhibition as a simple and robust measurement of PTI in rice seedlings.Specifically,flg22,a well-characterized PAMP from bacterial flagellin,was used to induce PTI in rice seedlings.While flg22 treatment induced PR gene expression and mitogen-activated protein kinase activation in the roots of rice seedlings to support the PTI triggered,this treatment substantially repressed lateral root growth,but it did not alter primary root growth.Moreover,treatments with chitin(i.e.,a fungal PAMP)and oligogalacturonides(i.e.,classical damage-associated molecular pattern)clearly inhibited the lateral root growth,although a priming step involving ulvan was required for the chitin treatment.The bioassay developed was applicable to various rice cultivars and wild species.Thus,lateral root growth inhibition represents a simple and reliable assay for studying PTI in rice plants.
基金supported financially by the grants from the JBGS[2021]002 project from the Jiangsu Governmentthe National Nature Science Foundation of China(32472095)+2 种基金the National Key Research and Development Program of China(2020YFE02029002)Collaborative Innovation Center for Modern Crop Production(CIC-MCP)to Xiquan Gaosupported in part by the high-performance computing platform of Bioinformatics Center,Nanjing Agricultural University。
文摘Gibberella stalk rot(GSR)caused by Fusarium graminearum is one of the most devastating diseases of maize,seriously impacting maize yield and quality,as well as the ability to use technology of mechanical harvesting.Environmental conditions including photoperiod affect crop disease resistance.However,the mechanism underlying photoperiod-regulated maize GSR resistance remains unexplored.We found in this study that GSR resistance is regulated by the ZmPIF4.1(Phytochrome-Interacting Factor4)-ZmPTI1c(Pto-Interacting 1)-ZmMYB31 module coupled with photoperiod.The functional analysis of zmpti1c mutant indicated that ZmPTI1c negatively regulates maize GSR resistance.Short day promoted the disease progression in both zmpti1c and wild-type plants.ZmPTI1c promoter contains multiple predicted cis-acting elements for light responses.Yeast one-hybrid assay(Y1H),Electrophoretic mobility shift analysis(EMSA),and Dual-luciferase(LUC)reporter assays demonstrated that ZmPIF4.1 binds to the G-box in ZmPTI1c promoter and activates its expression.Moreover,expression levels of ZmPIF4 and ZmPTI1c were significantly higher under short day than under long day.ZmPTI1c interacted with and phosphorylated ZmMYB31.GSR resistance in zmmyb31 mutant was significantly increased than in wild type,indicating that ZmMYB31 also negatively regulated GSR resistance.Furthermore,ZmMYB31 suppressed the transcriptional activation of ZmPTI1c by ZmPIF4.1.Overall,ZmPIF4.1-ZmPTI1c-ZmMYB31negatively regulates maize immunity to GSR,which is likely modulated by photoperiod.
基金supported by the Strategic Priority Research Program of the Chinese Academy of Sciences(XDB11020600)National Natural Science Foundation of China(31571968,31300234)the Youth Innovation Promotion Association of the Chinese Academy of Sciences
文摘Pathogen/microbe-associated molecular patterns(PAMPs/MAMPs) are recognized by plant pattern recognition receptors(PRRs)localized on the cell surface to activate immune responses.This PAMP-triggered immunity(PTI) confers resistance to a broad range of pathogenic microbes and,therefore,has a great potential for genetically engineering broad-spectrum resistance by transferring PRRs across plant families.Pathogenic effectors secreted by phytopathogens often directly target and inhibit key components of PTI signaling pathways via diverse biochemical mechanisms.In some cases,plants have evolved to produce decoy proteins that mimic the direct virulence target,which senses the biochemical activities of pathogenic effectors.This kind of perception traps the effectors of erroneous targeting and results in the activation of effector-triggered immunity(ETI) instead of suppressing PTI.This mechanism suggests that artificially designed decoy proteins could be used to generate new recognition specificities in a particular plant.In this review,we summarize recent advances in research investigating PAMP recognition by PRRs and virulence effector surveillance by decoy proteins.Successful expansion of recognition specificities,conferred by the transgenic expression of EF-Tu receptor(EFR) and AvrPphB susceptible 1(PBS1) decoys,has highlighted the considerable potential of PRRs and artificially designed decoys to expand plant resistance spectra and the need to further identify novel PRRs and decoys.
基金supported by grants from the National Key Research and Development Project(2022YFE0198100)National Natural Science Foundation of China(32172420)+2 种基金Natural Science Foundation of Jiangsu Province(SBK20220085)Fundamental Research Funds for the Central Universities(KYXK202009,ZJ21195012)the Startup Fund for Distinguished Scholars from Nanjing Agricultural University(to Y.W.).
文摘Pattern-triggered immunity(PTI)and effector-triggered immunity(ETI)are required for host defense against pathogens.Although PTI and ETI are intimately connected,the underlying molecular mechanisms remain elusive.In this study,we demonstrate that flg22 priming attenuates Pseudomonas syringae pv.tomato DC3000(Pst)AvrRpt2-induced hypersensitive cell death,resistance,and biomass reduction in Arabidopsis.Mitogen-activated protein kinases(MAPKs)are key signaling regulators of PTI and ETI.The absence of MPK3 and MPK6 significantly reduces pre-PTI-mediated ETI suppression(PES).We found that MPK3/MPK6 interact with and phosphorylate the downstream transcription factor WRKY18,which regulates the expression of AP2C1 and PP2C5,two genes encoding protein phosphatases.Furthermore,we observed that the PTI-suppressed ETI-triggered cell death,MAPK activation,and growth retardation are significantly attenuated in wrky18/40/60 and ap2c1 pp2c5 mutants.Taken together,our results suggest that the MPK3/MPK6-WRKYs-PP2Cs module underlies PES and is essential for the maintenance of plant fitness during ETI.
基金the National Natural Science Foundation of China(31701863)the University of South Carolina Office of Research(ASPIRE-I TrackllB,13010E244)the Postdoctoral Workstation of Jiangsu Academy of Agricultural Sciences.
文摘Plant immunity is controlled by both positive regulators such as PBS3 and EDS1 and negative regulators such as NPR3 and NPR4.However,the relationships among these important immune regulators remain elusive.In this study,we found that PBS3 interacts with EDS1 in both the cytoplasm and the nucleus,and is required for EDS1 protein accumulation?NPR3 and NPR4,which function as salicylic acid receptors and adaptors of Cullin3-based E3 ligase,interact with and mediate the degradation of EDS1 via the 26S proteasome.We further discovered that PBS3 inhibits the polyubiquitination and subsequent degradation of EDS1 by reducing the association of EDS1 with the Cullin3 adaptors NPR3 and NPR4.Furthermore,we showed that PBS3 and EDS1 also contribute to PAMP-triggered immunity in addition to effector-triggered immunity.Collectively,our study reveals a novel mechanism by which plants fine-tune defense resporises by inhibiting the degradation of a positive player in plant immunity.
基金supported by a start-up fund from Texas A&M AgriLife Research to J.S.a grant from the National Science Foundation(IOS-1951094)to P.H.and J.S.
文摘Poly(ADP-ribosyl)ation(PARylation)is a posttranslational modification reversibly catalyzed by poly(ADP-ribose)polymerases(PARPs)and poly(ADP-ribose)glycohydrolases(PARGs)and plays a key role in multi-ple cellular processes.The molecular mechanisms by which PARylation regulates innate immunity remain largely unknown in eukaryotes.Here we show that Arabidopsis UBC13A and UBC13B,the major drivers of lysine 63(K63)-linked polyubiquitination,directly interact with PARPs/PARGs.Activation of pathogen-associated molecular pattern(PAMP)-triggered immunity promotes these interactions and enhances PARylation of UBC13.Both parp1 parp2 and ubc13a ubc13b mutants are compromised in immune responses with increased accumulation of total pathogenesis-related(PR)proteins but decreased accu-mulation of secreted PR proteins.Protein disulfide-isomerases(PDIs),essential components of endo-plasmic reticulum quality control(ERQC)that ensure proper folding and maturation of proteins destined for secretion,complex with PARPs/PARGs and are PARylated upon PAMP perception.Significantly,PARylation of UBC13 regulates K63-linked ubiquitination of PDIs,which may further promote their disulfide isomerase activities for correct protein folding and subsequent secretion.Taken together,these results indicate that plant immunity is coordinately regulated by PARylation and K63-linked ubiquitination.
