Pathogenic infection and the oxidative defences in plant apoplast

Summary The structural and functional continuum of the plant apoplast is the first site of contact with a pathogen and plays a crucial role in initiation and coordination of many defence responses. In this paper, we present an overview of the involvement of the plant apoplast in plant-pathogen interactions. The process of infection of French bean (Phaseolus vulgaris L.) plants byColletotrichum lindemuthianum is analysed. The ultrastructural features of plant defence responses to fungal infection are then compared with those observed in plants or cell suspensions treated with various elicitors. Changes in cell walls and in whole plant cells responding to infection seem to be highly similar in all systems used. Model systems of French bean and white lupin (Lupinus albus L.) are then utilised to provide some biochemical characteristics of oxidative reactions in the apoplast evoked by elicitor treatment. The species specificity of various mechanisms generating reactive oxygen species is discussed, and some details of pH-dependent H₂O₂-generating activity of peroxidases are demonstrated. As its exocellular nature is an important feature of the oxidative burst, the major consequence of this event, i.e., the oxidative cross-linking of wall components during the papilla formation and strengthening of the walls, is analysed. Finally, the possible involvement of other wall-associated and developmentally regulated H₂O₂-generating mechanisms, like amine and oxalate oxidases, in plant defence is demonstrated. It is concluded that under stress conditions, such apoplastic mechanisms might be employed to increase plants' chances of survival.Abbreviations HR hypersensitive response - IWF intercellular washing fluid - OxO oxalate oxidase - ROS reactive oxygen species - YE elicitor preparation from yeast cell walls     

High rates of extracellular superoxide production by lichens in the suborder Peltigerineae correlate with indices of high metabolic activity

Rates of extracellular superoxide radical (O₂^{· ?}) formation were measured in 34 species of lichens from different taxonomic groupings and contrasting habitats before and after desiccation stress. All 21 species from the suborder Peltigerineae produce O₂^{· ?} extracellularly at high rates, even when they are not stressed. In addition, some species show a burst of O₂^{· ?} production during rehydration following desiccation. Extracellular production of O₂^{· ?} is almost absent in the species from other lichen groups. In general, production of high levels of O₂^{· ?} and the existence of an inducible oxidative burst are best developed in species growing in wet microhabitats. Rates of O₂^{· ?} production are also positively correlated to previously published indices of lichen metabolic activity. Preliminary studies on the identity of the O₂^{· ?} producing enzymes suggest that they do not possess the classical characteristics of those suggested to produce reactive oxygen species in higher plants. Patterns of O₂^{· ?} production are discussed in terms of the strategies used by different lichens groups in their defence against pathogenic fungi and bacteria.     

Glyoxal oxidases: their nature and properties

H₂O₂ has been found to be required for the activity of the main microbial enzymes responsible for lignin oxidative cleavage, peroxidases. Along with other small radicals, it is implicated in the early attack of plant biomass by fungi. Among the few extracellular H₂O₂-generating enzymes known are the glyoxal oxidases (GLOX). GLOX is a copper-containing enzyme, sharing high similarity at the level of active site structure and chemistry with galactose oxidase. Genes encoding GLOX enzymes are widely distributed among wood-degrading fungi especially white-rot degraders, plant pathogenic and symbiotic fungi. GLOX has also been identified in plants. Although widely distributed, only few examples of characterized GLOX exist. The first characterized fungal GLOX was isolated from Phanerochaete chrysosporium. The GLOX from Utilago maydis has a role in filamentous growth and pathogenicity. More recently, two other glyoxal oxidases from the fungus Pycnoporus cinnabarinus were also characterized. In plants, GLOX from Vitis pseudoreticulata was found to be implicated in grapevine defence mechanisms. Fungal GLOX were found to be activated by peroxidases in vitro suggesting a synergistic and regulatory relationship between these enzymes. The substrates oxidized by GLOX are mainly aldehydes generated during lignin and carbohydrates degradation. The reactions catalysed by this enzyme such as the oxidation of toxic molecules and the production of valuable compounds (organic acids) makes GLOX a promising target for biotechnological applications. This aspect on GLOX remains new and needs to be investigated.     

H2O2参与AM真菌与烟草共生过程

以烟草((Nicotiana tabacum,品种CF90NF)为寄主,苗期接种丛枝菌根(AM)真菌摩西球囊霉(Glomus mosseae,G.m),测定G.m与烟草共生过程中烟草根部H2O2含量以及多胺氧化酶(PAO)和过氧化物酶(POD)活性;研究外源H2O2对G.m侵染烟草的影响以及H2O2清除剂和合成抑制剂对烟草侧根H2O2含量及烟草侧根和菌丝中H2O2荧光强度的影响,以探究H2O2在AM真菌侵染烟草过程中的作用。结果表明,接种G.m 20d后烟草侧根中出现H2O2含量的猝发,一定浓度的外源H2O2促进G.m对烟草的侵染,而H2O2清除剂抗坏血酸(AsA)显著削弱烟草侧根和菌丝中的H2O2荧光强度,降低G.m对烟草的侵染率,表明H2O2参与G.m与烟草共生过程;在G.m与烟草共生过程中,PAO和POD活性显著升高,PAO抑制剂二氨基十二烷(DADD)和POD抑制剂水杨羟肟酸(SHAM)显著降低烟草侧根中H2O2荧光强度,对菌丝中H2O2荧光强度无显著影响,表明烟草根部和G.m均可产生H2O2,PAO和POD参与烟草侧根中H2O2的合成,菌丝中可能存在其他来源的H2O2。     

The oxidative burst protects plants against pathogen attack: Mechanism and role as an emergency signal for plant bio-defence — a review

Various aspects, mechanisms and functions of the oxidative burst with generation of O₂⁻ superoxide anions in plant cells, which is stimulated by active defence-inducing agents such as fungal infection or elicitor treatment, were reviewed mainly on the basis of experimental evidence obtained in a system of Solanaceae plants and Phytophthora spp. The oxidative burst may be due to an O₂⁻-generating NADPH oxidase in the plasma membrane, which is activated with combinations of cytosolic proteins, Ca²⁺, calmodulin and protein kinase, following stimulation by elicitor molecules. The oxidative burst may play the role of an internal emergency signal for induction of the metabolic cascade for active defence.     

Interactive effects of silicon and arbuscular mycorrhiza in modulating ascorbate-glutathione cycle and antioxidant scavenging capacity in differentially salt-tolerant <Emphasis Type="Italic">Cicer arietinum</Emphasis> L. genotypes subjected to long-term salinity

Salinity is the major environmental constraint that affects legume productivity by inducing oxidative stress. Individually, both silicon (Si) nutrition and mycorrhization have been reported to alleviate salt stress. However, the mechanisms adopted by both in mediating stress responses are poorly understood. Thus, pot trials were undertaken to evaluate comparative as well as interactive effects of Si and/or arbuscular mycorrhiza (AM) in alleviating NaCl toxicity in modulating oxidative stress and antioxidant defence mechanisms in two Cicer arietinum L. (chickpea) genotypes—HC 3 (salt-tolerant) and CSG 9505 (salt-sensitive). Plants subjected to different NaCl concentrations (0–100 mM) recorded a substantial increase in the rate of superoxide radical (O₂ ^·?), H₂O₂, lipoxygenase (LOX) activity and malondialdehyde (MDA) content, which induced leakage of ions and disturbed Ca²⁺/Na⁺ ratio in roots and leaves. Individually, Si and AM reduced oxidative burst by strengthening antioxidant enzymatic activities (superoxide dismutase (SOD), catalase (CAT) and guaiacol peroxidase (GPOX)). Si was relatively more efficient in reducing accumulation of stress metabolites, while mycorrhization significantly up-regulated antioxidant machinery and modulated ascorbate-glutathione (ASA-GSH) cycle. Combined applications of Si and AM complemented each other in reducing reactive oxygen species (ROS) build-up by further enhancing the antioxidant defence responses. Magnitude of ROS-mediated oxidative burden was lower in HC 3 which correlated strongly with more effective AM symbiosis, better capacity to accumulate Si and stronger defence response when compared with CSG 9505. Study indicated that Si and/or AM fungal amendments upgraded salt tolerance through a dynamic shift from oxidative destruction towards favourable antioxidant defence system in stressed chickpea plants.     

Expression of a Trichoderma reesei β-1,4 endo-xylanase in tall fescue modifies cell wall structure and digestibility and elicits pathogen defence responses

An endo-xylanase from Trichoderma reesei (xyn2) has been expressed in tall fescue targeted to the vacuole, apoplast or Golgi, constitutively under the control of the rice actin promoter, and to the apoplast under the control of a senescence enhanced gene promoter. Constitutive xylanase expression in the vacuole, apoplast, and golgi, resulted in only a small number of plants with low enzyme activities and in reduced plant growth in apoplast, and golgi targeted plants. Constitutive expression in the apoplast also resulted in increased levels of cell wall bound hydroxycinnamic acid monomers and dimers, but no significant effect on cell wall xylose or arabinose content. In situ constitutive xylanase expression in the Golgi also resulted in increased ferulate dimers. However, senescence induced xylanase expression in the apoplast was considerably higher and did not affect plant growth or the level of monomeric hydroxycinnamic acids or lignin in the cell walls. These plants also showed increased levels of ferulate dimers, and decreased levels of xylose with increased levels of arabinose in their cell walls. While the release of cell wall hydroxycinnamic acids on self digestion was enhanced in these plants in the presence of exogenously applied ferulic acid esterase, changes in cell wall composition resulted in decreases in both tissue digestibility and cellulase mediated sugar release. In situ detection of H₂O₂ production mediated by ethylene release in leaves of plants expressing apoplast xylanase could be leading to increased dimerisation. High-level xylanase expression in the apoplast also resulted in necrotic lesions on the leaves. Together these results indicate that xylanase expression in tall fescue may be triggering plant defence responses analogous to foliar pathogen attack mediated by ethylene and H₂O₂.     

Salicylic acid-induced superoxide generation catalyzed by plant peroxidase in hydrogen peroxide-independent manner

It has been reported that salicylic acid (SA) induces both immediate spike and long lasting phases of oxidative burst represented by the generation of reactive oxygen species (ROS) such as superoxide anion radical (O₂^•−). In general, in the earlier phase of oxidative burst, apoplastic peroxidase are likely involved and in the late phase of the oxidative burst, NADPH oxidase is likely involved. Key signaling events connecting the 2 phases of oxidative burst are calcium channel activation and protein phosphorylation events. To date, the known earliest signaling event in response to exogenously added SA is the cell wall peroxidase-catalyzed generation of O₂^•− in a hydrogen peroxide (H₂O₂)-dependent manner. However, this model is incomplete since the source of the initially required H₂O₂ could not be explained. Based on the recently proposed role for H₂O₂-independent mechanism for ROS production catalyzed by plant peroxidases (Kimura et al., 2014, Frontiers in Plant Science), we hereby propose a novel model for plant peroxidase-catalyzed oxidative burst fueled by SA.     

In planta measurements of oxidative bursts elicited by avirulent and virulent bacterial pathogens suggests that H2O2 is insufficient to elicit cell death in tobacco

A rapid and localized programmed cell death – the hypersensitive response (HR) – is a widely utilized plant resistance mechanism against pathogens. Studies have implicated H₂O₂ generation as a key elicitory mechanism in the HR. The causal relationship between the kinetics of the in planta oxidative burst, the HR and certain defence gene expression was examined. H₂O₂ generation following challenge with avirulent strains of Pseudomonas syringae pv. (P. s. pv.) syringae occurred in two phases. The effects of ROS generation were investigated using the H₂O₂-responsive transgene AoPR10-GUS, the dually responsive (H₂O₂ and salicylic acid) PR1a-GUS as well as measures of cell death. Co-application of catalase with P. s. pv. syringae into tobacco leaf panels suppressed AoPR10- and PR1a-GUS expression and cell death. Conversely, varying H₂O₂ generation with glucose: glucose oxidase influenced both defence gene expression and cell death. AoPR10-GUS proved to be primarily responsive to apoplastic not intracellular oxidative stress, suggesting that the apoplasm was a distinctive source of oxidative signals. A biphasic oxidative burst was also observed with virulent P. s. pv. tabaci, which, although delayed compared to that observed during HR, persisted at equivalent levels for a longer period. Taking all these data together we suggest that either (1) additional factors to the apoplastic oxidative burst are required to explain the rapid kinetics of defence signalling and cell death associated with the HR or (2) P. s. pv. tabaci successfully suppresses the effects of H₂O₂ generation by an unknown mechanism.     

The oxidative burst in plant defense: Function and signal transduction

The rapid production and accumulation of active oxygen species (AOS), the oxidative burst, has been shown to occur in a variety of plant/pathogen systems. In particular, two species, hydrogen peroxide (H₂O₂) and the superoxide radical anion O₂^? have received considerable attention. H₂O₂ and O₂^?, while acting directly as antimicrobial agents, may also serve as second messengers or catalysts in plants to activate a more diverse set of defense responses. Some of the better studied downstream responses promoted by AOS are (1) the cross-linking of cell wall proteins, (2) the induction of defense-related genes, (3) the stimulation of phytoalexin biosynthesis and (4) promotion of the hypersensitive response (HR). A useful model for studying the oxidative burst in plants is the neutrophil NADPH ox-idase complex, the primary source of AOS production in mammals. Several of the subunits of the neutrophil NADPH oxidase complex have been immunologically identified in plants. Furthermore, many of the components known to be involved in the signal transduction pathway in neutrophils have also been found to play a role in the oxidative burst in plants. Just as various ligands activate the oxidase complex in neutrophils, several ligands (elicitors or pathogens) also lead to induction of the oxidative burst in plant cells. The similarities between the neutrophil and plant oxidative bursts will be elaborated in this review. Following stimulation with elicitors, different signal transduction pathways are activated in plants, depending on the source of elicitor used. While the identities and chronologies of the major intermediates in these pathways remain largely unknown, there is strong evidence at least for participation of phospholipases, H⁺/K⁺ exchange, Ca²⁺ influxes, protein kinases and phosphatases, and GTP binding proteins. In an effort to integrate these various signaling events into a single scheme, we have constructed a hypothetical model that proposes how different elicitors might induce the oxidative burst in the same cell by different pathways.     

Effect of iron and phagocytosis on murine macrophage activation in vitro

Iron-exposed murine macrophages have a modified bactericidal activity as shown by previous observations. In order to assess the role of iron in macrophage activation, as measured by free radical production and by intracellular bacterial killing, murine peritoneal macrophages were cultivated in the presence of various sources of iron, human iron-saturated transferrin and ammonium ferric citrate, or iron chelators, Desferal, and human Apo-transferrin, and were infected with an enteropathogenic strain ofE. coli. The release of nitrite (NO₂ ^?), and the production of superoxide anion (O₂ ^?) and hydrogen peroxide (H₂O₂) by the phagocytes were measured and compared to the production by uninfected macrophages. The synergistic action with murine r.IFN-γ was also studied in the radical production reaction and for the bactericidal activity of macrophages. Our results show that in vitro phagocytosis ofE. coli induced elevated production of NO₂ ^? and H₂O₂ by macrophages, and that oxygen derivatives were released independently of the presence of added iron or chelator. Despite a phagocytosis-related enhancement of NO₂ ^? release, reactive nitrogen intermediates (RNI) are not directly involved in the bactericidal mechanism, as revealed by increased intracellular killing owing to RNI inhibitors. Moreover, bacterial killing may depend on oxygen derivatives, as suggested by the effect of the antioxidant sodium ascorbate leading to both a diminished H₂O₂ production and a decreased bactericidal activity of macrophages.     

Active oxygen species production in tobacco cells elicited by cryptogein*

We analyse the relationship between active oxygen species (AOS) production and pH changes induced in tobacco cells by cryptogein, a fungal proteinaceous elicitor of defence mechanisms in plants. When tobacco cells were treated with cryptogein, an intracellular acidification, an alkalinization of the extracellular medium and a transient burst of AOS (H₂O₂) were observed. Treatment of elicited cells with either diphenyleneiodonium (DPI), an inhibitor of the neutrophil NADPH oxidase, or Tiron, which scavenges O₂^˙? abolished AOS production. These data suggest the involvement of a NADPH oxidase-like enzyme leading to H₂O₂ production through O₂^˙? dismutation. Although H₂O₂ production could be, per se, the origin of the pH changes observed, we showed that it was not the main cause, since DPI and Tiron did not inhibit extracellular alkalinization. On the other hand, cryptogein-induced changes in pH could be abolished using fusicoccin (FC), which is known to stimulate the plasmalemma H⁺ ATPase. Consequently, the observed changes in pH induced by cryptogein could be mainly due to the inhibition of the plasmalemma H⁺-ATPase activity. Furthermore, changes in extracellular pH were shown to modulate the intensity of AOS production by elicited cells. The possible regulation of the NAD(P)H oxidase activity of plant cells by changes in pH is further discussed.     

Molecular mechanisms of generation for nitric oxide and reactive oxygen species, and role of the radical burst in plant immunity

Rapid production of nitric oxide (NO) and reactive oxygen species (ROS) has been implicated in the regulation of innate immunity in plants. A potato calcium-dependent protein kinase (StCDPK5) activates an NADPH oxidase StRBOHA to D by direct phosphorylation of N-terminal regions, and heterologous expression of StCDPK5 and StRBOHs in Nicotiana benthamiana results in oxidative burst. The transgenic potato plants that carry a constitutively active StCDPK5 driven by a pathogen-inducible promoter of the potato showed high resistance to late blight pathogen Phytophthora infestans accompanied by HR-like cell death and H₂O₂ accumulation in the attacked cells. In contrast, these plants showed high susceptibility to early blight necrotrophic pathogen Alternaria solani, suggesting that oxidative burst confers high resistance to biotrophic pathogen, but high susceptibility to necrotrophic pathogen. NO and ROS synergistically function in defense responses. Two MAPK cascades, MEK2-SIPK and cytokinesis-related MEK1-NTF6, are involved in the induction of NbRBOHB gene in N. benthamiana. On the other hand, NO burst is regulated by the MEK2-SIPK cascade. Conditional activation of SIPK in potato plants induces oxidative and NO bursts, and confers resistance to both biotrophic and necrotrophic pathogens, indicating the plants may have obtained during evolution the signaling pathway which regulates both NO and ROS production to adapt to wide-spectrum pathogens.     

Hydrogen peroxide-independent generation of superoxide catalyzed by soybean peroxidase in response to ferrous ion

It is well documented that extracellular alkalization occurs in plants under the challenges by pathogenic microbes. This may eventually induce the pH-dependent extracellular peroxidase-mediated oxidative burst at the site of microbial challenges. By employing the purified proteins of horseradish peroxidase as a model, we have recently proposed a likely role for free Fe²⁺ in reduction of ferric enzyme of plant peroxidases into ferrous intermediate and oxygen-bound form of enzyme known as Compound III which may eventually releases superoxide anion radical (O₂^•−), especially under alkaline condition, possibly contributing to the plant defense mechanism. In the present study, we employed the purified protein of soybean peroxidase (SBP) as an additional model, and examined the changes in the redox status of enzyme accompanying the generation of O₂^•− in response to Fe²⁺ under alkaline condition.     

Rapid Stimulation of an Oxidative Burst during Elicitation of Cultured Plant Cells : Role in Defense and Signal Transduction

Stimulation of cultured plant cells with elicitors of the defense response leads to the rapid destruction of a variety of water-soluble compounds including indoleacetic acid and certain fluorescent dyes. This destructive activity, which is often vigorously manifested within 5 minutes of elicitor addition, is shown to derive from the rapid production of H₂O₂ and its use by extracellular peroxidases. Because of its speed of appearance, this oxidative burst may qualify as the first induced line of defense against invading pathogens. Since H₂O₂ has been implicated as a second messenger of hormone-stimulated metabolic changes in some animal cells, its possible role in transduction of the defense signal in plants was also examined. Not only did exogenous H₂O₂ alone stimulate phytoalexin production in the plant cell suspension, but inhibition of elicitor-stimulated phytoalexin production was observed upon addition of catalase and other inhibitors of the oxidative burst. Furthermore, for inhibition to occur, the presence of catalase was required during elicitor addition, since if introduction of the enzyme was delayed until 1 hour after addition of the elicitor, no inhibition resulted. These results suggest that H₂O₂ also plays an important role in inducing subsequent defense responses such as phytoalexin production.     

Responses of antioxidant enzymes to cold and high light are not correlated to freezing tolerance in natural accessions of Arabidopsis thaliana

Low temperatures and high light cause imbalances in primary and secondary reactions of photosynthesis, and thus can result in oxidative stress. Plants employ a range of low‐molecular weight antioxidants and antioxidant enzymes to prevent oxidative damage, and antioxidant defence is considered an important component of stress tolerance. To figure out whether oxidative stress and antioxidant defence are key factors defining the different cold acclimation capacities of natural accessions of the model plant Arabidopsis thaliana, we investigated hydrogen peroxide (H₂O₂) production, antioxidant enzyme activity and lipid peroxidation during a time course of cold treatment and exposure to high light in four differentially cold‐tolerant natural accessions of Arabidopsis (C24, Nd, Rsch, Te) that span the European distribution range of the species. All accessions except Rsch (from Russia) had elevated H₂O₂ in the cold, indicating that production of reactive oxygen species is part of the cold response in Arabidopsis. Glutathione reductase activity increased in all but Rsch, while ascorbate peroxidase and superoxide dismutase were unchanged and catalase decreased in all but Rsch. Under high light, the Scandinavian accession Te had elevated levels of H₂O₂. Te appeared most sensitive to oxidative stress, having higher malondialdehyde (MDA) levels in the cold and under high light, while only high light caused elevated MDA in the other accessions. Although the most freezing‐tolerant, Te had the highest sensitivity to oxidative stress. No correlation was found between freezing tolerance and activity of antioxidant enzymes in the four accessions investigated, arguing against a key role for antioxidant defence in the differential cold acclimation capacities of Arabidopsis accessions.