Flagellin from Pseudomonas syringae pv. tabaci induced hrp-independent HR in tomato

We have previously shown that flagellin of Pseudomonas syringae pv. tabaci is an elicitor that induces a hypersensitive reaction (HR) in nonhost tomato cells. Flagellin is the major HR elicitor produced by this pathogen, as shown by the inability of a flagellin-defective mutant, ΔfliC, to induce HR. Also, a ΔfliD mutant that secretes large amounts of monomer flagellins induces a strong HR in tomato. In this study, the possible involvement of an Hrp type III secretion system (TTSS) in flagellin-induced HR was investigated using flagella-defective mutants or Hrp TTSS-defective mutants. The hrcC gene encodes HrcC protein, which is required for Hrp pilus formation in the outer membrane. An hrcC mutation, introduced into the wild-type, ΔfliC, and ΔfliD mutants of P. syringae pv. tabaci did not affect swimming motility or flagellin secretion, whereas all ΔhrcC, ΔfliC, and ΔfliD mutants lost the ability to cause disease on host tobacco leaves. However, the ΔhrcC mutant and the ΔfliD/ΔhrcC double mutant were still able to induce HR cell death, expression of one of the defense-related genes hsr203J, and the generation of hydrogen peroxide in nonhost tomato cells. Thus, flagellin is required for both pathogenicity in host tobacco and HR in nonhost tomato. On the other hand, hrp TTSS is necessary for pathogenicity on host tobacco but is not indispensable to induce HR in nonhost tomato. These results clearly show that flagellin-induced HR is hrp-independent in tomato.The nucleotide sequence data reported are available in the DDBJ/EMBL/GenBank databases under the accession number AB049570     

<Emphasis Type="Italic">N</Emphasis>,<Emphasis Type="Italic">N</Emphasis>-dimethylsphingosine,an inhibitor of sphingosine kinase,induces phytoalexin production and hypersensitive cell death of Solanaceae plants without generation of reactive oxygen species

Plant recognition of elicitors derived from pathogens induces various resistant reactions, including production of reactive oxygen species, hypersensitive cell death and accumulation of phytoalexins. Previously, we isolated a ceramide elicitor from Phytophthora infestans, which activates O₂ ⁻ production of potato suspension-cultured cells. In this study, we employed nine ceramide-related chemicals to test their elicitor activity. Although, none of the tested chemicals induced O₂ ⁻ production, N,N-dimethylsphingosine (DMS) induced accumulation of phytoalexin in potato tubers. In potato, tobacco and Nicotiana benthamiana, DMS also induced rapid cell death. DMS-treated potato cells stained with 4′,6-diamidino-2-phenylindole (DAPI) showed chromatin condensation, and isolated DNA from DMS-treated cells had ladder pattern, confirming that DMS-induced plant cell death is a hypersensitive reaction-like programmed cell death. Involvement of ceramide signaling in induction of plant defense reactions is discussed. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Glycosylation of flagellin from Pseudomonas syringae pv. tabaci 6605 contributes to evasion of host tobacco plant surveillance system

Pseudomonas syringae pv. tabaci (Pta) possesses a genetic region composed of two open reading frames (ORFs), fgt1 and fgt2, that are involved in glycosylation of flagellin. The deletion mutant Δfgt1 produced non-glycosylated flagellin, and exhibited reduced ability to cause disease in the host tobacco plant. Flagellin is known to induce plant defense responses, and the recognition of flagellin by Arabidopsis thaliana is mediated by a conserved N-terminal region, flg22, in flagellin and a leucine-rich repeat domain in the FLS2 receptor. Because flg22 localizes inside the flagellum, polymerized flagellum needs to be dissociated to be recognized. Therefore, the effect of glycosylation on flagella stability was investigated. The polymerized flagella from glycosylated flagellins were more resistant to heat treatment than those from non-glycosylated flagellins, suggesting that the glycosylation of flagellin contributes to the structural stability of flagella and prevents exposure of the flg22 region. Polymerized flagella from Pta Δfgt1 flagellin and depolymerized and glycosylated flagellin from Pta wild type induced cell death and callose deposition, and inhibited seedling growth in tobacco more effectively, whereas polymerized flagella from Pta wild-type flagellin caused a low level of these responses. These results suggest Pta might have evolved the flagellin glycosylation system to evade detection and defense response of a host by increasing flagella stability and suppressing their dissociation.     

鞭毛素蛋白FliCaaa诱导水稻免疫反应的活性测定

为阐明燕麦嗜酸菌(Acidovorax avenae subsp.avenae,Aaa)鞭毛素蛋白Fli Caaa及其结构域对水稻免疫反应的诱导作用,通过分子生物学和生物信息学方法,对Aaa菌株IPN1的鞭毛素进行基因克隆及其序列分析;在大肠杆菌中对该基因全长、N端和C端片段进行了原核表达,纯化了Fli Caaa蛋白及其截短肽段;采用水稻叶片浸润法测定了表达蛋白对水稻免疫反应的诱导活性。结果表明,通过特异性引物的PCR扩增,获得1 479 bp的鞭毛素基因fli Caaa,其编码产物含有492个氨基酸,分子量为49.4 k D,具有flagellin-N和-C两个保守结构域;原核诱导表达获得了Fli Caaa、Fli Caaa-N和Fli Caaa-C可溶性融合蛋白;3种纯化蛋白均能诱导水稻细胞死亡和H2O2产生等免疫反应,但诱导能力略有差异。     

The oligopeptide elicitor Pep-13 induces salicylic acid-dependent and -independent defense reactions in potato

The Phytophthora-derived oligopeptide elicitor, Pep-13, originally identified as an inducer of plant defense in the nonhost–pathogen interaction of parsley and Phytophthora sojae, triggers defense responses in potato. In cultured potato cells, Pep-13 treatment results in an oxidative burst and activation of defense genes. Infiltration of Pep-13 into leaves of potato plants induces the accumulation of hydrogen peroxide, defense gene expression and the accumulation of jasmonic and salicylic acids. Derivatives of Pep-13 show similar elicitor activity in parsley and potato, suggesting a receptor-mediated induction of defense response in potato similar to that observed in parsley. However, unlike in parsley, infiltration of Pep-13 into leaves leads to the development of hypersensitive response-like cell death in potato. Interestingly, Pep-13-induced necrosis formation, hydrogen peroxide formation and accumulation of jasmonic acid, but not activation of a subset of defense genes, is dependent on salicylic acid, as shown by infiltration of Pep-13 into leaves of potato plants unable to accumulate salicylic acid. Thus, in a host plant of Phytophthora infestans, Pep-13 is able to elicit salicylic acid-dependent and -independent defense responses.     

Defense responses of Arabidopsis thaliana inoculated with Pseudomonas syringae pv. tabaci wild type and defective mutants for flagellin (ΔfliC) and flagellin-glycosylation (Δorf1)

Flagellin, an essential component of the bacterial flagellar filament, is capable of inducing a hypersensitive response (HR), including cell death, in a nonhost plant. A flagellin-defective mutant (ΔfliC) of Pseudomonas syringae pv. tabaci lacks both the flagellar filament and motility, whereas a flagellin-glycosylation-defective mutant (Δorf1) retains the flagellar filament but lacks the glycosyl modification of flagellin protein. To investigate the role of flagellin protein and its glycosylation in the interaction with its nonhost Arabidopsis thaliana, we analyzed plant responses after inoculation with these bacteria. Inoculation with wild-type P. syringae pv. tabaci induced HR, with the generation of reactive oxygen species and cell death. In contrast, inoculation with either ΔfliC or Δorf1 mutant induced a low level of HR, and inoculated leaves developed a disease-like yellowing. These mutant bacteria multiplied better than the wild-type bacteria in A. thaliana. These results indicate that A. thaliana expresses a defense reaction in response to the bacterial flagellin with its glycosyl structure.     

Preliminary characterization of race-specific elicitors from<Emphasis Type="Italic">Peronospora parasitica</Emphasis> and their ability to elicit phenolic accumulation in<Emphasis Type="Italic">Arabidopsis</Emphasis>

Intercellular washing fluid (IWF) obtained from the susceptibleArabidopsis accession Ws-eds1 inoculated withPeronospora parasitica isolate Emoy-2, contained an elicitor of necrosis with ecotype specificity towardsArabidopsis accessions with particular resistance genes. This elicitor caused necrosis on the highly resistant accessions La-er, Nd-1 and partly on Col-5, but not on the susceptible accessions Ws-eds1 and Oy-0. In resistant plants, injection of IWF caused hypersensitive reaction (HR)-like cell collapse which was associated with the accumulation of phenolics and lignin-like material in walls of cells undergoing cell death. The elicitor is sensitive to proteinase K and pronase enzymes, heating and autoclaving but insensitive to periodate oxidation, freezing and thawing, and is not dialyzable. Results suggest that the elicitor is a protein. Fractionation experiments using size-exclusion membranes revealed that elicitor activity has a molecular weight in excess of 100 kDa. http://www.phytoparasitica.org posting July 13, 2003.     

细菌鞭毛素对植物免疫防卫反应及其信号机制的激发

细菌鞭毛素(flagellin)是一类可以诱导寄主植物细胞发生防卫反应的病原物相关分子模式(PAMP)因子,其活性位点是被称为flg22的N 末端保守的22个氨基酸多肽,植物体内与其结合的模式识别受体是FLS2。flg22可以诱导植物细胞发生活性氧(ROS)的猝发、细胞培养介质碱化、一氧化氮(NO)的产生,胼胝质沉积以及MAPK级联反应、防卫基因表达等多种防卫反应。本文结合本室有关水稻白叶枯病菌的研究结果,综述近年来国内外在鞭毛素诱导植物防卫反应研究领域的最新研究进展。     

Induction of peroxidase, scopoletin, phenolic compounds and resistance in Hevea brasiliensis by elicitin and a novel protein elicitor purified from Phytophthora palmivora

Elicitin and a new protein 75 kDa elicitor were purified from the culture filtrate of Phytophthora palmivora, a pathogen of Hevea brasiliensis (rubber plant). Elicitin was obtained by using a one step of DEAE cellulose chromatography and the new elicitor was obtained by two steps of chromatography: a DEAE cellulose column followed by a hydrophobic column. Both elicitors were stable to heat and a wide range of pH values, but were sensitive to ProteaseK. Both elicitors induced scopoletin, peroxidase isozymes (with substrate o-dianisidine and scopoletin) and total phenolic compounds in cell suspension of H. brasiliensis with similar kinetics. In addition, both elicitors induced peroxidase enzyme (o-dianisidine), total phenolic compounds and enhanced local resistance against P. palmivora on young rubber tree seedlings. However, the increase of peroxidase enzyme and total phenolic compounds in rubber tree seedlings was different from those in cell suspension. Furthermore, during the expression of local resistance the zoospore of P. palmivora induced the peroxidase enzyme (o-dianisidine) more rapidly and with higher level than the control plants. H. brasiliensis is more responsive to the new elicitor than elicitin in triggering defense responses. That is the new elicitor was active at a concentration lower than those required for elicitin, about a 30-fold decrease for activation defense responses in cell suspension. For induction of peroxidase enzyme (o-dianisidine), phenolic compounds and local resistance of rubber plants against P. palmivora, the 75 kDa protein was active at about a 2-fold lower concentration when compared to elicitin.     

Depolymerization of the actin cytoskeleton induces defense responses in tobacco plants

Tobacco leaf sections were treated with actin inhibitors, i.e., cytochalasins, to determine the effects of actin depolymerization on tobacco defense responses. Inoculation of the leaf sections with the pathogen Erysiphe cichoracearum, depolymerized the actin cytoskeleton, priming the cells for a hypersensitive response-like cell death. Further, expression of the acidic PR1 and PR2 genes were induced in cytochalasin-treated leaf sections. The intensity of the cytochalasin effects on the defense responses was closely correlated with the extent of actin depolymerization. This suggests that plant cells may perceive perturbation of the actin cytoskeleton, and this stimulus may trigger plant defense responses.     

Activation of Defense Responses to Fusarium Infection in Asparagus densiflorus

Defense responses to Fusarium oxysporum f. sp. asparagi and F. proliferatum were compared after root inoculation of the asparagus fern, Asparagus densiflorus vars. Myersii and Sprengeri, and cultivated asparagus, A. officinalis cv. Guelph Millennium. Both varieties of A. densiflorus exhibited a hypersensitive response with rapid death of epidermal cells within 8–24 h and restricted the fungal growth. In A. officinalis roots, rapid cell death was not found, and necrotic lesions were observed 8–14 d after fungal inoculation. Peroxidase and phenylalanine ammonia-lyase activities increased significantly in inoculated A. densiflorus but not A. officinalis plants. Local and systemic induction of peroxidase activity was detected after pathogen inoculation in root and spear tissues, respectively, of A. densiflorus. POX activity decreased in roots of inoculated A. officinalis by 8 d post-inoculation. Germination and germ tube growth were inhibited when spores of F. oxysporum f. sp. asparagi were incubated in root exudates and on root segment surfaces of inoculated A. densiflorus plants exhibiting hypersensitive cell death. Spore germination of F. proliferatum and three fungi non-pathogenic to cultivated asparagus was inhibited as well. Rapid induction of hypersensitive cell death in A. densiflorus was associated with restriction of fungal growth, and activation of peroxidase and phenylalanine ammonia-lyase, two defense enzymes thought to be important for plant disease resistance.     

Bacterial DNA activates immunity in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

To initiate defense responses against invasion of pathogenic organisms, animals and plants must recognize microbe-associated molecular patterns (MAMPs). In this study, the elicitor activity of bacterial DNA on the model plant Arabidopsis thaliana was examined. EcoRI-digested plasmid DNA induced defense responses such as generation of reactive oxygen species and deposition of callose, whereas SmaI- and HapII-digested plasmid DNA and EcoRI-digested herring DNA did not remarkably induce these responses. Further, methylation of the CpG sequence of plasmid DNA and Escherichia coli DNA reduced the level of the defense responses. The endocytosis inhibitors wortmannin and amantadine significantly inhibited DNA-induced defense responses. These results suggest that non-methylated CpG DNA, as a MAMP, induced defense responses in Arabidopsis and that non-methylated DNA seems to be translocated into the cytoplasm by endocytosis.     

鞭毛素蛋白FliCxcv对水稻免疫反应的诱导功能鉴定

 为揭示来源于番茄细菌性斑点病菌(Xanthomonas campestris pv. vesicatoria, Xcv)菌株XV18鞭毛素(FliCxcv)作为一种病原相关分子模式(PAMP)诱导水稻免疫反应的功能,本研究对FliCxcv编码基因flicxcv进行了基因克隆、序列分析、原核表达、蛋白纯化和诱导活性测定。结果表明,通过PCR特异性扩增,从Xcv菌株XV18中克隆了1 200 bp的fliCxcv基因片段,其序列与GenBank中己测序菌株的完全一致。在大肠杆菌中对该基因全长、N端和C端截短序列进行了原核表达,并获得了纯化的FliCxcv全长及其截短蛋白。将纯化蛋白浸润接种到水稻品种日本晴叶片组织,发现FliCxcv全长及其截短蛋白均能诱导水稻叶片细胞死亡、H₂O₂产生以及防卫基因(OsPAL和OsPR1b)表达等免疫反应,但诱导活性存在差异。因此,本研究验证了FliCxcv具有激发水稻细胞免疫反应的PAMP功能,为水稻免疫诱导制剂的研发提供了材料。     

A binding protein for fungal signal molecules in the cell wall of Pisum sativum

In the plant cell wall of Pisum sativum seedlings, we found an NTPase (E.C. 3.6.1.5.) with ATP-hydrolyzing activity that was regulated by an elicitor and suppressors of defense from pea pathogen Mycosphaerella pinodes. The ATPase-rich fraction was purified from pea cell walls by NaCl solubilization, ammonium sulfate precipitation, and chromatography with an ATP-conjugated agarose column and an anion-exchange column. The specific activity of the final ATPase-rich fraction increased 600-fold over that of the initial NaCl-solubilized fraction. The purified ATPase-rich fraction also had peroxidase activity and generated superoxide, both of which were regulated by the M. pinodes elicitor and suppressor (supprescins). Active staining and Western blot analysis also showed that the ATPase was copurified along with peroxidases. In this fraction, a biotinylated elicitor and the supprescins were bound primarily and specifically to ca. 55-kDa protein (CWP-55) with an N-terminal amino acid sequence of QEEISSYAVVFDA. The cDNA clone of CWP-55 contained five ACR domains, which are conserved in the apyrases (NTPases), and the protein is identical to a pea NTPase cDNA (GenBank accession AB071369). Based on these results, we discuss a role for the plant cell wall in recognizing exogenous signal molecules.     

The TIR–NBS but not LRR domains of two novel N-like proteins are functionally competent to induce the elicitor p50-dependent hypersensitive response

The tobacco N protein recognizes the helicase domain (p50) of the Tobacco mosaic virus (TMV) replicase as an elicitor and mediates hypersensitive response (HR). We obtained two cDNA clones encoding novel N-like (NL) proteins NL-C26 and NL-B69 from Nicotiana tabacum cv. Samsun NN. NL-C26 and NL-B69 had a Toll-interleukin-1 receptor/nucleotide-binding site/leucine-rich repeat (TIR–NBS–LRR) structure and showed 78% and 73% identities to N, respectively. The NL-C26 and NL-B69 genes were also expressed in N. tabacum cv. Samsun nn, which lacks the N gene. Unlike N, NL-C26 and NL-B69, when coexpressed with p50, failed to induce HR on the sites of agroinfiltration in Samsun nn leaves. However, the elicitor-dependent HR in Samsun nn was induced efficiently by chimeric N proteins with the continuous TIR–NBS domains of NL-C26 and NL-B69. On the other hand, the efficiency of HR induction varied significantly among chimeric N proteins with either of the TIR and NBS domains of the NL proteins. In contrast, chimeras carrying the LRR domains of the NL proteins did not induce HR. Thus, the TIR–NBS domains of NL-C26 and NL-B69 could functionally adapt to the LRR domain of N, which may determine the specificity for the elicitor. We speculate that the NL genes are potential HR-inducing resistance genes for undetermined pathogens other than TMV.     

Harpin-elicited hypersensitive cell death and pathogen resistance require the NDR1 and EDS1 genes

Plants sprayed with harpin, a bacterial protein that induces hypersensitive cell death (HCD), develop systemic acquired resistance (SAR) without macroscopic necrosis. HCD sometimes accompanies the development of resistance conferred by resistance (R) genes. In Arabidopsis, some R genes require one or both of the signalling components NDR1 and EDS1 for function. This study addresses whether HCD, NDR1 and EDS1 are required for induction of SAR by harpin. When Arabidopsis and tobacco leaves were sprayed with harpin, microscopic hypersensitive response (micro-HR) lesions developed. Systemic expression of PR genes and the development of resistance were accompanied by micro-HR, except in the ndr1-1 mutant, in which harpin induced micro-HR without the development of resistance or expression of the PR-1 gene. Cell death and resistance did not occur following treatment with harpin in plants that could not accumulate salicylic acid. Harpin also failed to induce resistance in Arabidopsis eds1-1 mutants. Therefore, harpin-induced resistance seems to develop concomitantly with cell death and resistance requires NDR1 and EDS1.     

Expression-based genotyping of the rice blast resistance genes in the elite maintainer line Yixiang1B

Plants employ extracellular immune receptors to perceive conserved pathogen-associated molecular patterns (PAMPs), triggering the first layer of defense known as pattern-triggered immunity (PTI). The understanding of PTI is mainly based on studies focusing on leaves. Plants are vulnerable to attack by various root pathogens including plant-parasitic nematodes. Evidence is accumulating that phytonematodes utilize their secreted effectors to suppress PTI to enable infection. PTI assays used for characterizing nematode effectors are often conducted in a non-host plant or tissue, such as leaves, because of lacking of root assays. Thus, there is a need for PTI assays in roots of host plants. Here, we tested two bacterial PAMPs (flg22 and flgII-28) and two nonpathogenic bacteria (Pseudomonas fluorescens and P. syringae strain DC3000 ΔhrcQ-U) for their ability to induce PTI responses, including the induction of defense gene expression and callose deposition, in roots of tomato and potato. We found that flg22 and the two nonpathogenic bacteria are potent in inducing defense gene expression and callose deposition in tested roots, demonstrating for the first time induction of PTI in roots of solanaceous plants. Effectors GrCEP12 and Hs10A06 were previously indicated to be involved in PTI suppression. Consistently, upon elicitor treatment, roots of transgenic plants overexpressing GrCEP12 and Hs10A06, respectively, showed a reduced level of defense gene expression or no induction of callose deposition compared to control roots. Taken together, our established root PTI assays represent a valuable tool that will facilitate the study of phytonematodes and potentially other root pathogens in their manipulation of plant immunity.