Systemic induction of H2O2 in pea seedlings pretreated by wounding and exogenous jasmonic acid

Pea seedlings (Pisum sativum L.) were used as materials to test the timings and compartments of hydrogen peroxide (H₂O₂) triggered by wounding and exogenous jasmonic acid (JA). The results showed that H₂O₂ could be systemically induced by wounding and exogenous JA. H₂O₂ increased within 1 h and reached the peak 3–5 h after wounding in either the wounded leaves or the unwounded leaves adjacent to the wounded ones and the inferior leaves far from the wounded ones. After this, H₂O₂ decreased and recovered to the control level 12 h after wounding. The activities of antioxidant enzymes, however, were rapidly increased by wounding. Diphenylene iodonium (DPI), an inhibitor of NADPH oxidase, could significantly inhibit H₂O₂ burst that was mediated by wounding and exogenous JA. Assay of H₂O₂ subcellular location showed that H₂O₂ in response to wounding and exogenous JA was predominantly accumulated in plasma membrane, cell wall and apoplasmic space. Numerous JA (gold particles) was found via immunogold electron microscopy to be located in cell wall and phloem zones of mesophyll cell after wounding.     

局部灼伤对小麦幼苗外源茉莉酸吸收与运转的影响

采用示踪技术探索了3H-JA的运输和分配规律及其受伤害胁迫的影响.外源3H-JA能够在小麦幼苗体内向上和向下运输,局部灼伤其运输与分配都发生了改变.从小麦根系饲喂的3H-JA,在植株内的分布量依序为根＞茎＞叶,时间较长(4h)时分配于心叶的3H-JA大大增加.当叶片受到局部灼伤时3H-JA向地上部的输出量减少;但局部灼伤可加快由心叶饲喂的3H-JA的向下运输,改变3H-JA在小麦幼苗各部位的分配比率.心叶饲喂短时间(5min)时,3H-JA主要积累在受到伤胁迫的展开叶(第2叶)中.向展开叶(第2叶)饲喂的3H-JA向下运输的速率高于向上运输的速率.推测JA运输及分配的变化可能在植株的防御反应中起重要作用.     

Distal transport of exogenously applied jasmonoyl-isoleucine with wounding stress

Determining the mobile signal used by plants to defend against biotic and abiotic stresses has proved elusive, but jasmonic acid (JA) and its derivatives appear to be involved. Using deuterium-labeled analogs, we investigated the distal transport of JA and jasmonoyl-isoleucine (JA-Ile) in response to leaf wounding in tobacco (Nicotiana tabacum) and tomato (Solanum lycopersicum) plants. We recovered [(2)H(2)-2]JA ([(2)H(2)]JA) and [(2)H(3)-12]JA-Ile ([(2)H(3)]JA-Ile) in distal leaves of N. tabacum and S. lycopersicum after treating wounded leaves with [(2)H(2)]JA or [(2)H(3)]JA-Ile. We found that JA-Ile had a greater mobility than JA, despite its lower polarity, and that application of exogenous JA-Ile to wounded leaves of N. tabacum led to a higher accumulation of JA and JA-Ile in distal leaves compared with wounded control plants. We also found that exudates from the stem of S. lycopersicum plants with damaged leaflets contained JA and JA-Ile at higher levels than in an undamaged plant, and a significant difference in the levels of JA-Ile was observed 30 min after wounding. Based on these results, it was found that JA-Ile is a transportable compound, which suggests that JA-Ile is a signaling cue involved in the resistance to biotic and abiotic stresses in plants.     

Induction of ASCORBATE PEROXIDASE 2 expression in wounded Arabidopsis leaves does not involve known wound-signalling pathways but is associated with changes in photosynthesis

ASCORBATE PEROXIDASE 2 (APX2) encodes a key enzyme of the antioxidant network. In excess light-stressed Arabidopsis leaves, photosynthetic electron transport (PET), hydrogen peroxide (H(2)O(2)) and abscisic acid (ABA) regulate APX2 expression. Wounded leaves showed low induction of APX2 expression, and when exposed to excess light, APX2 expression was increased synergistically. Signalling pathways dependent upon jasmonic acid (JA), chitosan and ABA were not involved in the wound-induced expression of APX2, but were shown to require PET and were preceded by a depressed rate of CO(2) fixation. This led to an accumulation of H(2)O(2) in veinal tissue. Diphenyl iodonium (DPI), which has been shown previously to be a potent inhibitor of H(2)O(2) accumulation in the veins of wounded leaves, prevented induction of APX2 expression probably by inhibition of PET. Thus, the weak induction of APX2 expression in wounded leaves may require H(2)O(2) and PET only. As in other environmental stresses, wounding of leaves resulted in decreased photosynthesis leading to increased reactive oxygen species (ROS) production. This may signal the induction of many 'wound-responsive' genes not regulated by JA-dependent or other known JA-independent pathways.     

机械伤害和外施茉莉酸对巴西橡胶树次生乳管分化的局部效应及其与茉莉酸分布的关系

采用同位素示踪技术和实验形态学的方法揭示茉莉酸在木本植物巴西橡胶树(Hevea brasiliensis Mull．Arg．)中的分布和运输的特点,并分析其与机械伤害和外施茉莉酸对巴西橡胶树次生乳管分化的诱导效应之间的关系。外施的茉莉酸进入体内后,在较长时间内大部分集中在施用部位。机械伤害阻止外施的茉莉酸进入体内,同时,又使进入的茉莉酸阻滞在受伤部位的附近。与茉莉酸在草本植物中可以向上和向下运输的情况不同,茉莉酸在木本植物巴西橡胶树中主要是向下运输的。机械伤害和外施茉莉酸对巴西橡胶树次生乳管分化的诱导效应是局部的,只在受伤和施用茉莉酸部位的树皮中诱导次生乳管的形成。机械伤害削弱外源茉莉酸对次生乳管分化的诱导效应,这与机械伤害阻止外源茉莉酸进入有关。研究结果表明,体内高水平的茉莉酸是诱导巴西橡胶树次生乳管分化所必需的。     

机械伤害和外施茉莉酸对巴西橡胶树次生乳管分化的局部效应及其与茉莉酸分布的关系

采用同位素示踪技术和实验形态学的方法揭示茉莉酸在木本植物巴西橡胶树(Hevea brasiliensis Mull.Arg.)中的分布和运输的特点,并分析其与机械伤害和外施茉莉酸对巴西橡胶树次生乳管分化的诱导效应之间的关系.外施的茉莉酸进入体内后,在较长时间内大部分集中在施用部位.机械伤害阻止外施的茉莉酸进入体内,同时,又使进入的茉莉酸阻滞在受伤部位的附近.与茉莉酸在草本植物中可以向上和向下运输的情况不同,茉莉酸在木本植物巴西橡胶树中主要是向下运输的.机械伤害和外施茉莉酸对巴西橡胶树次生乳管分化的诱导效应是局部的,只在受伤和施用茉莉酸部位的树皮中诱导次生乳管的形成.机械伤害削弱外源茉莉酸对次生乳管分化的诱导效应,这与机械伤害阻止外源茉莉酸进入有关.研究结果表明,体内高水平的茉莉酸是诱导巴西橡胶树次生乳管分化所必需的.     

Transport of [2-14C]jasmonic acid from leaves to roots mimics wound-induced changes in endogenous jasmonic acid pools in Nicotiana sylvestris

Jasmonic acid (JA) is part of a long-distance signal-transduction pathway that effects increases in de-novo nicotine synthesis in the roots of Nicotiana sylvestris Speg et Comes (Solanaceae) after leaf wounding. Elevated nicotine synthesis increases whole-plant nicotine pools and makes plants more resistant to herbivores. Leaf wounding rapidly increases JA pools in damaged leaves, and after a 90-min delay, root JA pools also increase. The systemic response in the roots could result from either: (i) the direct transport of JA from wounded leaves, or (ii) JA synthesis or its release from conjugates in roots in response to a second, systemic signal. We synthesized [2-¹⁴C]JA, and applied it to a single leaf in a quantity (189 μg) known to elicit both a whole-plant nicotine and root JA response equivalent to that found in plants subjected to leaf wounding. We quantified radioactive material in JA, and in metabolites both more and less polar than JA, from treated and untreated leaves and roots of plants in eight harvests after JA application. [2-¹⁴C]Jasmonic acid was transported from treated leaves to roots at rates and in quantities equivalent to the wound-induced changes in endogenous JA pools. The [2-¹⁴C]JA that had been transported to the roots declined at the same rate as endogenous JA pools in the roots of plants after leaf wounding. Most of the labeled material applied to leaves was metabolized or otherwise immobilized at the application site, and the levels of [2-¹⁴C]JA in untreated leaves did not increase over time. We measured the free JA pools before and after four different hydrolytic extractions of root and shoot tissues to estimate the size of the potential JA conjugate pools, and found them to be 10% or less of the free JA pool. We conclude that the direct transport of wound-induced JA from leaves to roots can account for the systemic increase in root JA pools after leaf wounding, and that metabolism into less polar structures determines the duration of this systemic increase. However, the conclusive falsification of this hypothesis will require the suppression of all other signalling pathways which could have shoot-to-root transport kinetics similar to that of endogenous JA. Received: 14 April 1997 / Accepted: 9 June 1997     

Involvement of hydrogen peroxide and nitric oxide in expression of the ipomoelin gene from sweet potato

The IPO (ipomoelin) gene was isolated from sweet potato (Ipomoea batatas cv Tainung 57) and used as a molecular probe to investigate its regulation by hydrogen peroxide (H(2)O(2)) and nitric oxide (NO) after sweet potato was wounded. The expression of the IPO gene was stimulated by H(2)O(2) whether or not the plant was wounded, but its expression after wounding was totally suppressed by the presence of diphenylene iodonium, an inhibitor of NADPH oxidase, both in the local and systemic leaves of sweet potato. These results imply that a signal transduction resulting from the mechanical wounding of sweet potato may involve NADPH oxidase, which produces endogenous H(2)O(2) to stimulate the expression of the IPO gene. The production of H(2)O(2) was also required for methyl jasmonate to stimulate the IPO gene expression. On the contrary, NO delayed the expression of the IPO gene, whereas N(G)-monomethyl-L-arginine monoacetate, an inhibitor of NO synthase, enhanced the expression of the IPO gene after the plant was wounded. This study also demonstrates that the production of H(2)O(2) stained with 3,3'-diaminobenzidine hydrochloride could be stimulated by wounding but was suppressed in the presence of NO. Meanwhile, the generation of NO was visualized by confocal scanning microscope in the presence of 4,5-diaminofluorescein diacetate after sweet potato was wounded. In conclusion, when sweet potato was wounded, both H(2)O(2) and NO were produced to modulate the plant's defense system. Together, H(2)O(2) and NO regulate the expression of the IPO gene, and their interaction might further stimulate plants to protect themselves from invasions by pathogens and herbivores.     

Jasmonic Acid is Induced in a Biphasic Manner in Response of Pea Seedlings to Wounding

The role of jasmonic acid (JA) in plant wounding response has been demonstrated. However, the source of JA in wound signaling remains unclear. In the present study, pea seedlings were used as material to investigate the systemic induction of JA and the activation of lipoxygenase (LOX)-dependent octadecanoid pathway upon wounding. The results showed that endogenous JA could induce two peaks in the wounded leaves and the stalks, while only one peak in the systemic leaves.LOX activity and its protein amount were also induced and the stimulation mainly occurred in the late phase, while one peak of induction was present after pretreatment with JA. Applied nordihydroguaiaretic acid (NDGA), an inhibitor of LOX activity, only inhibited the induction of JA in the late phase, and the resistance of pea was impaired. Furthermore, 13(S)-hydroperoxy-9(Z), 11 (E)-octadecadienoic acid (13(S)-H(P)ODE) was confirmed to be the main product of LOX throughout the experimental time. In addition, immunocytochemical analysis also revealed the occurrence of JA biosynthesis and transport upon wounding. These results demonstrated that wound-induced JA in wounded leaves resulted from Its biosynthesis and conversion from its conjugates, while in systemic leaves resulted from its transport and biosynthesis; and proved that the LOX pathway was vital to the wound-induced defense response involved in JA biosynthesis.     

Induced sink strength as a prerequisite for induced tannin biosynthesis in developing leaves of Populus

Induced defenses occur predominately in young, developing plant tissues that rely upon carbohydrate import to support their growth and development. To test the hypothesis that the induced production of carbon-based defenses is dependent upon photoassimilate import, we examined the response of developing leaves of hybrid poplar (Populus deltoides 2 P. nigra) saplings to wounding by gypsy moth caterpillars (Lymantria dispar L.) and exogenous jasmonic acid (JA). Growth rates, condensed tannin contents and acid invertase activities were measured for individual leaves and the translocation of ¹³C-labeled resources between orthostichous source-sink pairs was quantified. Results showed a substantial increase in the activity of cell wall invertase in sink leaves wounded by gypsy moth caterpillars and treated with JA. JA-induced sink leaves also imported 3-4 times as much ¹³C-labeled carbon from orthostichous source leaves relative to controls and allocated a significant portion of this imported ¹³C to condensed tannin biosynthesis. Reduced carbohydrate flow to these leaves, caused by source leaf removal, resulted in reduced condensed tannin levels and the emergence of a growth-defense tradeoff. These results indicate that (1) induced sink strength is elicited by insect wounding and JA application in hybrid poplar foliage, (2) imported resources are allocated to the production of carbon-based defenses, and (3) the level of induced defense in leaves can be constrained by the ability of leaves to import carbohydrates from source tissues. Together, these results suggest that within-canopy variations in induced resistance may arise in part because of uneven distribution of resources to induced foliage.     

Kinetics of the Accumulation of Jasmonic Acid and Its Derivatives in Systemic Leaves of Tobacco (Nicotiana tabacum cv. Xanthi nc) and Translocation of Deuterium-Labeled Jasmonic Acid from the Wounding Site to the Systemic Site

In plants, the mobile signal needed for wound-induced systemic acquired resistance (WSR) has been elusive. The signal compound involved in WSR is supposed to be JA or its derivatives. On the basis of kinetic study of the accumulation of JA or its derivatives, it was discovered that JA, JA-Ile, tuberonic acid (TA, 12-OH epi-JA), and tuberonic acid glucoside (TAG) accumulated in systemic tissues in response to mechanical wounding stress in the tobacco plant (Nicotiana tabacum). Attempts to recover deuterium-labeled JA in systemic leaves after feeding the wounded leaves with deuterium-labeled JA were successfully done. It was also found that the translocated deuterium-labeled JA was metabolized to TA in systemic leaves under feeding of deuterium-labeled JA to the wounding leaves.     

GTR1 is a jasmonic acid and jasmonoyl-l-isoleucine transporter in Arabidopsis thaliana

Jasmonates are major plant hormones involved in wounding responses. Systemic wounding responses are induced by an electrical signal derived from damaged leaves. After the signaling, jasmonic acid (JA) and jasmonoyl-l-isoleucine (JA-Ile) are translocated from wounded to undamaged leaves, but the molecular mechanism of the transport remains unclear. Here, we found that a JA-Ile transporter, GTR1, contributed to these translocations in Arabidopsis thaliana. GTR1 was expressed in and surrounding the leaf veins both of wounded and undamaged leaves. Less accumulations and translocation of JA and JA-Ile were observed in undamaged leaves of gtr1 at 30 min after wounding. Expressions of some genes related to wound responses were induced systemically in undamaged leaves of gtr1. These results suggested that GTR1 would be involved in the translocation of JA and JA-Ile in plant and may be contributed to correct positioning of JA and JA-Ile to attenuate an excessive wound response in undamaged leaves.     

A permeable cuticle is associated with the release of reactive oxygen species and induction of innate immunity

Wounded leaves of Arabidopsis thaliana show transient immunity to Botrytis cinerea, the causal agent of grey mould. Using a fluorescent probe, histological staining and a luminol assay, we now show that reactive oxygen species (ROS), including H(2)O(2) and O(2) (-), are produced within minutes after wounding. ROS are formed in the absence of the enzymes Atrboh D and F and can be prevented by diphenylene iodonium (DPI) or catalase. H(2)O(2) was shown to protect plants upon exogenous application. ROS accumulation and resistance to B. cinerea were abolished when wounded leaves were incubated under dry conditions, an effect that was found to depend on abscisic acid (ABA). Accordingly, ABA biosynthesis mutants (aba2 and aba3) were still fully resistant under dry conditions even without wounding. Under dry conditions, wounded plants contained higher ABA levels and displayed enhanced expression of ABA-dependent and ABA-reporter genes. Mutants impaired in cutin synthesis such as bdg and lacs2.3 are already known to display a high level of resistance to B. cinerea and were found to produce ROS even when leaves were not wounded. An increased permeability of the cuticle and enhanced ROS production were detected in aba2 and aba3 mutants as described for bdg and lacs2.3. Moreover, leaf surfaces treated with cutinase produced ROS and became more protected to B. cinerea. Thus, increased permeability of the cuticle is strongly linked with ROS formation and resistance to B. cinerea. The amount of oxalic acid, an inhibitor of ROS secreted by B. cinerea could be reduced using plants over expressing a fungal oxalate decarboxylase of Trametes versicolor. Infection of such plants resulted in a faster ROS accumulation and resistance to B. cinerea than that observed in untransformed controls, demonstrating the importance of fungal suppression of ROS formation by oxalic acid. Thus, changes in the diffusive properties of the cuticle are linked with the induction ROS and attending innate defenses.     

Environmental and developmental regulation of the wound-induced cell wall protein WI12 in the halophyte ice plant

A wounded gene WI12 was used as a marker to examine the interaction between biotic stress (wounding) and abiotic stress (high salt) in the facultative halophyte ice plant (Mesembryanthemum crystallinum). The deduced WI12 amino acid sequence has 68% similarity to WUN1, a known potato (Solanum tuberosum) wound-induced protein. Wounding, methyl jasmonate, and pathogen infection induced local WI12 expression. Upon wounding, the expression of WI12 reached a maximum level after 3 h in 4-week-old juvenile leaves, whereas the maximum expression was after 24 h in 8-week-old adult leaves. The temporal expression of WI12 in salt-stressed juvenile leaves was similar to that of adult leaves. The result suggests that a salt-induced switch from C3 to Crassulacean acid metabolism has a great influence on the ice plant's response to wounding. The expression of WI12 and the accumulation of WI12 protein were constitutively found in phloem and in wounded mesophyll cells. At the reproductive stage, WI12 was constitutively found in petals and styles, and developmentally regulated in the placenta and developing seeds. The histochemical analysis showed that the appearance of WI12 is controlled by both environmental and developmental factors. Immunogold labeling showed WI12 preferentially accumulates in the cell wall, suggesting its role in the reinforcement of cell wall composition after wounding and during plant development.     

Coordinate expression of AOS genes and JA accumulation: JA is not required for initiation of closing layer in wound healing tubers

Wounding induces a series of coordinated physiological responses essential for protection and healing of the damaged tissue. Wound-induced formation of jasmonic acid (JA) is important in defense responses in leaves, but comparatively little is known about the induction of JA biosynthesis and its role(s) in tuber wound-healing. In this study, the effects of wounding on JA content, expression of JA biosynthetic genes, and the involvement of JA in the initiation of closing layer formation in potato tubers were determined. In addition, the role of abscisic acid (ABA) in wound-induced JA accumulation was examined. The basal JA content in non-wounded tuber tissues was low (<3 ng g⁻¹ FW). Two hours after wounding, the JA content increased by >5-fold, reached a maximum between 4 and 6 h after wounding, and declined to near-basal levels thereafter. Tuber age (storage duration) had little effect on the pattern of JA accumulation. The expressions of the JA biosynthetic genes (StAOS2, StAOC, and StOPR3) were greatly increased by wounding reaching a maximum 2-4 h after wounding and declining thereafter. A 1-h aqueous wash of tuber discs immediately after wounding resulted in a 94% inhibition of wound-induced JA accumulation. Neither JA treatment nor inhibition of JA accumulation affected suberin polyphenolic accumulation during closing layer development indicating that JA was not essential for the initiation of primary suberization. ABA treatment did not restore JA accumulation in washed tuber tissues suggesting that leaching of endogenous ABA was either not involved or not solely involved in this loss of JA accumulation by washing. Collectively, these results indicate that JA is not required for the induction of processes essential to the initiation of suberization during closing layer development, but do not exclude the possibility that JA may be involved in other wound related responses.     

Gene-specific involvement of beta-oxidation in wound-activated responses in Arabidopsis

The coordinated induced expression of beta-oxidation genes is essential to provide the energy supply for germination and postgerminative development. However, very little is known about other functions of beta-oxidation in nonreserve organs. We have identified a gene-specific pattern of induced beta-oxidation gene expression in wounded leaves of Arabidopsis. Mechanical damage triggered the local and systemic induction of only ACX1 among acyl-coenzyme A oxidase (ACX) genes, and KAT2/PED1 among 3-ketoacyl-coenzyme A thiolase (KAT) genes in Arabidopsis. In turn, wounding induced KAT5/PKT2 only systemically. Although most of the beta-oxidation genes were activated by wound-related factors such as dehydration and abscisic acid, jasmonic acid (JA) induced only ACX1 and KAT5. Reduced expression of ACX1 or KAT2 genes, in transgenic plants expressing their corresponding mRNAs in antisense orientation, correlated with defective wound-activated synthesis of JA and with reduced expression of JA-responsive genes. Induced expression of JA-responsive genes by exogenous application of JA was unaffected in those transgenic plants, suggesting that ACX1 and KAT2 play a major role in driving wound-activated responses by participating in the biosynthesis of JA in wounded Arabidopsis plants.     

Repeated leaf wounding alters the colonization of Medicago truncatula roots by beneficial and pathogenic microorganisms

In nature, plants are subject to various stresses that are often accompanied by wounding of the aboveground tissues. As wounding affects plants locally and systemically, we investigated the impact of leaf wounding on interactions of Medicago truncatula with root-colonizing microorganisms, such as the arbuscular mycorrhizal (AM) fungus Glomus intraradices, the pathogenic oomycete Aphanomyces euteiches and the nitrogen-fixing bacterium Sinorhizobium meliloti. To obtain a long-lasting wound response, repeated wounding was performed and resulted in locally and systemically increased jasmonic acid (JA) levels accompanied by the expression of jasmonate-induced genes, among them the genes encoding allene oxide cyclase 1 (MtAOC1) and a putative cell wall-bound invertase (cwINV). After repeated wounding, colonization with the AM fungus was increased, suggesting a role of jasmonates as positive regulators of mycorrhization, whereas the interaction with the rhizobacterium was not affected. In contrast, wounded plants appeared to be less susceptible to pathogens which might be caused by JA-induced defence mechanisms. The effects of wounding on mycorrhization and pathogen infection could be partially mimicked by foliar application of JA. In addition to JA itself, the positive effect on mycorrhization might be mediated by systemically induced cwINV, which was previously shown to exhibit a regulatory function on interaction with AM fungi.