Elicitor‐induced changes of wall‐bound and secreted peroxidase activities in suspension‐cultured spruce (Picea abies) cells are attenuated by auxins

In ectomycorrhizae auxins are proposed to attenuate elicitor-induced defence reactions in the host plant. To examine this hypothesis we compared the elicitor-induced accumulation of peroxidase isoforms between suspension-cultured spruce (Picea abies[L.] Karst.) cells incubated in media with and without auxins. In spruce cells changes in ionically and covalently wall-bound as well as symplasmic peroxidase (EC 1.11.1.7) activities were observed when elicitors from the following fungal species were applied: (1) Hebeloma crustuliniforme, an ectomycorrhizal partner of spruce; (2) Suillus variegatus, an ectomycorrhizal fungus incompatible with spruce; (3) Heterobasidion annosum, a spruce pathogen. Activity staining after SDS-PAGE and western blotting showed an accumulation of an ionically wall-bound 38-kDa peroxidase isoform. In addition, two covalently wall-bound isoforms (34 and 53 kDa) that could be released from spruce cell walls by cellulase and pectinase treatment were also induced by elicitors from these fungi. Moreover, in cells cultured without auxins all the elicitors triggered a rapid and transient accumulation of ionically wall-bound peroxidases, which reached a maximum activity 48 h after elicitor application. This early and transient peroxidase accumulation was diminished and delayed in cells cultured in the presence of auxins. In contrast, activity of peroxidases released into the culture medium of spruce cells or into the medium of protoplasts was suppressed by the elicitors of Hebeloma crustuliniforme. However, this suppression was attenuated by the action of auxins. It is suggested that under natural conditions, in infected spruce roots, the elicitors of the compatible fungus cause both suppression of the peroxidase (which is secreted to the free space of the roots), and induction of wall-bound and symplasmic peroxidases. On the other hand, auxins synthesized by the fungus could weaken these different elicitor-mediated effects.     

Defence-related Enzymes in Pepper Roots During Interactions with Arbuscular Mycorrhizal Fungi and/or Verticillium dahliae

Previous studies have described that arbuscular mycorrhizal fungi (AMF) can reduce the deleterious effect of Verticillium dahliae Kleb. on pepper growth and yield. In mycorrhizal plants, the bioprotection against soil-borne pathogens can result from the preactivation of defence responses that include some structural modifications and the accumulation of Pathogenesis-Related (PR) proteins. Our first objective was to study if V. dahliae induced defence mechanisms in roots before infected pepper developed visible symptoms of disease. The second aim was to determine if AMF induced defence-related enzymatic activities in pepper roots before or after pathogen’s attack. Results showed that the colonization of pepper roots by Glomus deserticola (Trappe, Bloss and Menge) induced the appearance of new isoforms of acidic chitinases, superoxide dismutase (SOD) and, at early stages, peroxidases. In contrast, V. dahliae neither stimulated the phenylpropanoid pathway nor elicited hydrolytic activities in infected pepper roots. Only in mycorrhizal plants, the inoculation with V. dahliae slightly increased both phenylalanine ammonia-lyase (PAL) and peroxidase activities two weeks later. Mycorrhizal-specific induction of new isoforms of acidic chitinases and SOD together with enhanced peroxidase and PAL activities 2 weeks after pathogen inoculation could be involved in the biocontrol of Verticillium-induced wilt in pepper by AMF.     

The activity of peroxidase in various cell fractions of wheat plants infected with Septoria nodorum berk.

The activities of peroxidase isoforms and hydrogen peroxide content in leaf cuttings of wheat (Triticum aestivum L., cv. Diamant) resistant to Septoria blotch were studied during aging and following the infection with Septoria nodorum Berk. The differential activation of peroxidase isoforms was regulated by hydrogen peroxide level in the tissue. At early stages of fungus development in plant tissues, the decrease in the activities of soluble, membrane and ion-bound fractions of peroxidase elevated the level of hydrogen peroxide in infected tissues and rapidly activated peroxidase isoforms in infected tissues as compared to the aging ones even before disease symptoms appeared. The anionic peroxidases, which were first to respond to the pathogen, seem to stand for wheat resistance to fungal infections and the protection of leaf tissues from oxidative stress.     

Phytochrome-mediated effects on extracellular peroxidase activity, lignin content and bending resistance in etiolated Vicia faba epicotyls

Etiolated Vicia faba seedlings were exposed to continuous red light to investigate whether changes in extracellular peroxidase activity were correlated in time and localization with changes in extension growth and/or lignin content in the subapical region of the epicotyl. Continuous red light: (a) increased extracellular peroxidase activity after a lag of ca 0.5 h, followed by a maximum peak after 2.5 h due to slightly acidic isoforms (pI = 6–6.5, according to isoelectrofocusing gels), a minimum after 4 h and a second maximum after 8 h due to acidic isoforms (pI=4–5), (b) increased lignin content and epicotyl resistance to bending after a lag of ca 4 h, i.e. simultaneously with changes in acidic extracellular peroxidase activity, and (c) reduced extension growth to a stable rate after a lag of ca 1 h, not coinciding with the kinetics of any of the extracellular peroxidase isoforms. These effects of continuous red light were at least partially mediated by phytochrome. Tissue printing and anatomical studies revealed red light effects on extracellular peroxidase activity and lignin content mainly in the outer cortical parenchyma. The results are consistent with the involvement of phyto-chrome-mediated effects on extracellular peroxidases (acidic isoforms) in the transduction chain leading to lignin responses to red light.     

Effect of stress conditions on the activity and isozyme composition of peroxidase of vacuoles and tissue extract of red beet roots

Changes in the enzymatic activity of phenol-dependent peroxidase (PO) of vacuoles and tissue extract of red beet (Beta vulgaris L.) roots in different phases of plant development and in hyperosmotic stress and pathogen infection were found. The highest activity was observed during root growth and the lowest PO activity occurred in dormancy, respectively. Activation of the enzyme was observed in infected roots. The isozyme composition of PO was characterized by lability, and the number of cationic isoforms varied significantly. The optimum pH of the enzyme changed depending on the growth phase and stressor, tending to shift towards low values at rest and in hyperosmotic stress. The shift in the optimum pH coincided with the appearance of additional cationic PO isoforms.     

Role of Reactive Oxygen Species and Antioxidant Enzymes in Systemic Virus Infections of Plants

Oxidative stress in compatible virus-host plant interactions was studied in cucumber mosaic virus and zucchini yellow mosaic virus-infected Cucumis sativus and Cucurbita pepo plants. Both cucumber mosaic virus- and zucchini yellow mosaic virus-infected plants showed an enhanced peroxidation of polyunsaturated fatty acids indicating an advanced disintegration of membranes. Radical intermediates formed during lipid peroxidation co-oxidize pigment molecules and might thus account for virus-induced yellowing symptoms. Furthermore in infected plants an induction of superoxide dismutases, catalases, total peroxidases and ascorbate peroxidases was observed. All the peroxidase isoforms detected in Cucumis sativus and Cucurbita pepo , however, not only functioned as radical scavengers but also catalysed the formation of H₂O₂. Thus it can be presumed that the enhancement of peroxidases contributes to the oxidative stress in systemic plant-virus interactions. By way of oxidation of indole-3-acetic acid upregulated peroxidases might also be responsible for growth reductions and malformations in virus-infected plants.     

Changes in activity of antioxidative enzymes in wheat (Triticum aestivum) seedlings under cold acclimation

Activated oxygen species such as superoxide radicals, singlet oxygen, hydrogen peroxide and hydroxyl radicals can be produced in plants exposed to low, non-freezing, non-injurious temperatures. To prevent or alleviate oxidative injury, plants have evolved several mechanisms which include scavenging by natural antioxidants and enzymatic antioxidant systems such as superoxide dismutases, catalase and peroxidases. Although overproduction of hydrogen peroxide and increased tolerance to oxidative stress can be induced in wheat by low-temperature treatments, data concerning changes in the enzymatic antioxidant systems are almost absent. With the aim to provide this information, antioxidant enzyme (superoxide dismutases, catalase and peroxidases) activities were analysed in leaves and roots of Triticum aestivum cvs Brasilia (frost resistant in field) and Eridano (less frost resistant in field) seedlings grown at day/night temperatures of 24/22°C (control treatment) and 12/5°C (low-temperature treatment). Our data showed that superoxide dismutase activities were unaffected by low-temperature treatment both in leaves and roots. Catalase activity in leaves and roots was decreased in 12/5°C-grown seedlings, but Brasilia maintained higher catalase activity than Eridano. Differences were also observed in guaiacol peroxidase activities between control and acclimated seedlings: Higher guaiacol peroxidase activities were found in the leaves of 12/5°C-grown seedlings while in roots these activities were lower. Moreover, Brasilia guaiacol peroxidase activities were higher than Eridano. Superoxide dismutase and peroxidase zymogram analyses showed that synthesis of new isoforms was not induced by low-temperature treatment. Changes in the activities of antioxidant enzymes induced by cold acclimation support the hypothesis that a frost-resistant wheat cultivar, in comparison with a less frost-resistant one, maintains a better defence against activated oxygen species during low-temperature treatment.     

Identification of a cell wall peroxidase in red calli of Prunus incisa Thunb.

Red calli occur frequently in callus cultures of Prunus incisa Thunb. Calli that become red in color stop growing and turn brown while calli that remain green continue to grow. This study was carried out to compare the accumulation of antioxidant activity in red and green calli. The anthocyanin content, peroxidase isoforms and peroxidase activity were different in red and green calli. Red calli contained higher levels of anthocyanins, cell wall peroxidase activity and lower soluble peroxidase activity than green calli. A basic cell wall peroxidase (pI 10.0) was present only in red calli. Two acidic peroxidases (pI 6.0 and 6.8) had higher accumulation in green calli than in red calli. In the cell wall fraction of red calli, a peroxidase isoform with an apparent molecular mass of 30 kDa was found. MALDI -TOF mass spectrometry and internal amino acid sequence analysis indicate that this protein has a very high similarity with the cell wall peroxidase of Beta vulgarisL .     

The relationship between the resistance of Aegilops umbellulata Zhuk. seedlings to Septoria nodorum Berk. and peroxidase isozyme pattern

The resistance of Aegilops umbellulata Zhuk. to blotch pathogen Septoria nodorum Berk. has been studied. Cytoplasmic peroxidase activity in normal seedlings could not be used for biochemical prediction of Ae. umbellulata resistance to Septoria blotch. At the same time, isoperoxidases with pI ～7.5 and infection-induced activity of anionic isoforms with pI ～3.5 were markers of the resistant Aegilops plants. Aegilops resistance to the fungus depended on the activity of cell wall peroxidases.     

Activity and isoforms of peroxidases, lignin and anatomy, during adventitious rooting in cuttings of Ebenus cretica L

Adventitious rooting of Ebenus cretica cuttings was studied in order to examine a) the rooting ability of different genotypes in relation to electrophoretic patterns of peroxidases. b) the activity and electrophoretic patterns of soluble and wall ionically bound peroxidases, the lignin content and anatomical changes in the control and IBA treated cuttings of and genotypes in the course of adventitious root formation. In addition, a fraction of soluble cationic peroxidases was separated by gel filtration chromatography from the total soluble peroxidases of a genotype. No rooting occurred in cuttings without IBA-treatment. In both genotypes, electrophoretic patterns of soluble anionic peroxidases revealed two common peroxidase isoforms, while a fast-migrating anionic peroxidase isoform (A3) appeared only in genotypes. Both genotypes showed similar patterns of soluble, as well as wall ionically bound cationic peroxidase isoforms. The number of isoforms was unchanged during the rooting process (induction, initiation and expression phase) but an increase in peroxidase activity (initiation phase) followed by decrease has been found in IBA-treated cuttings. During initiation phase the lignin content was almost similar to that on day 0 in genotype while it was reduced at by about 50% in genotype at the respective time. Microscopic observations revealed anatomical differences between genotypes. According to this study, the and genotypes display differences in anatomy, lignin content, activity of soluble peroxidases and the electrophoretic patterns of soluble anionic peroxidase isoforms. The A3-anionic peroxidase isoform could be used as biochemical marker to distinguish and genotypes of E. cretica and seems to be correlated to lignin synthesis in rooting process.     

Induction of chitinases and of translatable mRNA for these enzymes in melon plants infected with Collectotrichum lagenarium

In melon plants infected with Colletotrichum langenarium, there is a strong increase in the activity of chitinase, an enzyme with a potential defensive function against pathogens. In order to investigate the molecular mechanisms involved in the regulation of chitinase gene expression, antisera have been raised against two purified chitinases (I and II) from infected melon plants. Changes induced by infection in the rate of synthesis of chitinases were determined using direct immunoprecipitation of enzymes labelled in vivo with [³⁵S]methionine. A large but transient increase in the rate of chitinase synthesis occurred 5 days after inoculation. The in vitro synthesis of chitinases was then studied in healthy and infected melon plants. Poly(A)RNA was fractionated by sucrose gradient density centrifugation, and translated in a rabbit reticulocyte lysate. The transition products were then separated by fast protein liquid chromatography (FPLC) and further analysed by SDS-polyacrylamide gel electrophoresis. The identification of in vitro synthesized chitinases was performed by immunoprecipitation. The obtained results indicated the presence of chitinases in in vitro translation products of mRNA from infected, but not from healthy melon seedlings. It is concluded therefore, that infection of melon seedlings by a pathogen caused an increase in the translatable mRNAs for host chitinases.     

Changes in Composition of Soluble Intercellular Proteins Isolated from Healthy and TMV-Infected Nicotiana tabacum L. cv. Xanthi-nc

Changes in ribonucleases (RNases), phosphomonoesterase (PME), phosphodiesterase (PDE), glucose-6-phosphate dehydrogenase (G6P DH), polyphenoloxidases, peroxidases and proteases activity and PR-proteins composition in leaf tissue and intercellular fluid (ICF) isolated from leaf tissue of healthy and TMV-infected hypersensitive tobacco (Nicotiana tabacum L. cv. Xanthi-nc) plants (non-inoculated leaves) were studied. The amount of the proteins and the enzymes of intercellular space was less than 3 % of the total amount of proteins and the enzymes found in homogenate of healthy leaves. The TMV infection did not significantly change this observation. The great increase in the activities of the enzymes was observed in homogenates of the infected leaves, especially of the enzymes involved in biosynthesis of precursors needed for virus multiplication (G6P DH, RNase, PME, PDE). This is in contrast with the activities of the enzymes of ICF, which were only partly increased. The ICF proteins of infected plants were separated by means of ion exchange chromatography on DEAE cellulose. The isozymes of peroxidase, polyphenoloxidase, PME and PDE were identified. Using discontinuous nondenaturating polyacrylamide gel electrophoresis of DEAE cellulose fractions, the detection of isozymes of peroxidases and PR-proteins was performed. By means of SDS-PAGE the molecular masses of PR-proteins were identified: 15 – 16 kDa (group 1), 27 – 28 kDa (group 3: chitinases) and 36 – 40 kDa (group 2a: -1,3-glucanases).     

Inducible Proteins in Citrus Rootstocks with Different Tolerance Towards the Root Rot Pathogen Phytophthora palmivora

Activities of defence‐related proteins (β‐1,3‐glucanases, chitinases and peroxidases) and concentrations of total soluble phenolics were measured in roots and leaves of non‐infected and infected plants to investigate the response of different citrus rootstock genotypes to the root rot pathogen Phytophthora palmivora Butler. Infection with the pathogen increased concentrations of total proteins, total phenolics and β‐1,3‐glucanase activity in roots of all genotypes, and increases were associated with the extent of root mass reductions and thus susceptibility of the plants. Root chitinase and root peroxidase levels were slightly reduced or unaltered upon infection. β‐1,3‐Glucanase activity was also elevated in leaves of infected plants, but increases did not differ between tolerant and susceptible rootstocks. Effects of root infection on leaves were typically the reverse of effects on roots for chitinase‐ and peroxidase levels and more pronounced in susceptible rootstock genotypes. Although differences in enzyme expression were observed between susceptible and tolerant citrus seedlings, effects were usually associated with disease progression, and not with resistance to P. palmivora. It is suggested that increased activities of the proteins and soluble phenolics studied are not implicated in the primary defence to Phytophthora root diseases, but may contribute to the inhibition of the pathogen during infection in tolerant citrus.     

Peroxidase activity and inducibility in the sea fan coral exposed to a fungal pathogen

The enzymatic defense mechanisms of Gorgonia ventalina to the fungal pathogen Aspergillus sydowii may play important roles in colony resistance to infection. In this study, we examined the role of the superfamily of peroxidase enzymes in the coral response to a naturally occurring pathogen. We examined the inducibility of peroxidases by experimentally exposing corals to A. sydowii and found that peroxidase activity was induced after an 8 day incubation period. In contrast, naturally infected corals collected from the reef had lower peroxidase activity when compared to healthy corals. Infected sea fans from the field also had less measurable protein in their tissues and increased purple sclerites near infection sites and it is likely that these infections are months old. Using native-PAGE activity gels, we detected 5 peroxidase isozymes in healthy corals, indicating that multiple isoforms of peroxidase with a plurality of possible functions are present in this coral. The role of the peroxidase enzymes in disease resistance was examined by testing anti-fungal activity of commercially available and partially purified sea fan peroxidases. In both cases there was significant, dose-dependent anti-fungal activity. While peroxidases are ubiquitous enzymes involved in many cellular pathways, we also hypothesize that G. ventalina utilizes these enzymes as an integral component in disease resistance pathways. As such, they may also contribute to the initiation of physiochemical defenses such as melanization and lipid soluble anti-fungal metabolites.     

Peroxidase Isoenzymes in Strawberry Roots Infected with Binucleate Rhizoctonia spp. and their Implication in Disease Resistance

Infection of strawberry plants with binucleate Rhizoctonia spp. results in an increase in peroxidase activity and the appearance of new isoforms of the enzyme. In healthy and diseased roots of two different strawberry genotypes seven peroxidase isoenzymes were found. In healthy strawberry cv. Senga Sengana, which was moderately resistant to infection, four isoenzymes (1, 2, 5, and 6) were found. Moreover the activity of these isoenzymes was increased and three new isoenzymes (3, 4, and 7) were found in infected roots. In the strawberry hybrid 3/2/86/88/R, which is very susceptible to infection, only isoenzyme 2 was present in the roots of healthy plants. Following infection, the activity of isoenzyme 2 was increased and five new isoenzymes (1, 4, 5, 6, and 7) were detectable. The results obtained indicate that strawberry resistance to binucleate Rhizoctonia may be correlated with peroxidase isoenzyme profile with particular reference to isoform 3, which is only present in infected roots of the moderately resistant cv., Senga Sengana.     

Investigation of phosphoeno/pyruvate carboxylase (PEPCase) in Mesembryanthemum crystallinum L. in C3 and CAM photosynthetic states

When exposed to osmotic stress, Mesembryanthemum crystallinum plants switch from C₃ to CAM photosynthesis. Phosphoenolpyruvate carboxylase (PEPCase) is a key enzyme in CAM plants, being responsible for the initial fixation of CO₂. In C₃ plants the enzyme has been shown to be involved in the replenishing of TCA cycle intermediates and in the operation of stomatal guard cells. Multiple PEPCase isoforms were observed in C₃-performing leaves with four isoelectric points of 5.2, 5.5, 5.6 and 5.9 and four apparent subunit molecular masses of 105, 108, 113 and 116 kDa. In some instances, subunits of different size possessed exactly the same pI. The induction of CAM led to the predominance of a new isoform of pI 6.5 with subunit molecular mass of 108 kDa, but in addition, changes were observed in some of the isoforms present in the C₃ plant. PEPCase subunits were purified from the C₃ and CAM forms of M. crystallinum and subjected to pep-tide mapping. Two distinct though similar sets of maps were obtained, one from the CAM isoform (pI 6.5) and C₃-associated subunits of pi 5.9 and another for C₃ subunits of pI 5.2 and 5.5. It was inferred from these data that the C₃ isoforms expressed in the leaf were derived from at least two genes. The C₃ isoform (pI 5.9) showing greatest similarity to the CAM isoform in terms of peptide mapping also increased in response to salt stress. It is speculated that the CAM isoform may have evolved from this enzyme.     

Induction of PR proteins and resistance by the biocontrol agent Clonostachys rosea in wheat plants infected with Fusarium culmorum

Clonostachys rosea (CR) is a common worldwide saprophyte with destructive effect against several plant pathogenic fungi showing antagonistic features against a wide variety of pathogens. We recently isolated a strain of C. rosea, named CR47, from wheat crown infected with Fusarium culmorum (FC); this strain proved to be effective against Fusarium seed borne diseases of cereals under field condition. In this paper the function of C. rosea applied as seed treatment on wheat seedling growth was investigated. In addition, we investigated the expression pattern of peroxidases and chitinases as well as PR4 proteins following both CR treatments of seeds and FC infection and also in the three-component system pathogen–antagonist–wheat. Several chitinase isoforms were induced by CR-treatment both in coleoptiles and roots, whereas some peroxidase isoforms were induced only in the presence of both antagonist and pathogen. In the latter case, it seems that CR-treatment by itself promotes plant growth and reduces the peroxidase expression, while enhances some chitinase isoforms probably involved in cell wall disruption. Moreover, both the antagonist and the pathogen studied induced PR4 protein expression, which probably exerts its role on the invading microorganisms by a translation-inhibitory process that could be ascribed to their ribonuclease activity.     

Overexpression of the endogenous peroxidase-like gene spi 2 in transgenic Norway spruce plants results in increased total peroxidase activity and reduced growth

Peroxidases constitute a large family of proteins found in all higher plants. Owing to the complexity of the peroxidase isoenzyme family it has been difficult to assess the precise function of individual peroxidase enzymes. In this work we have studied the effects of an endogenous peroxidase-like gene from Norway spruce [Picea abies (L.) Karst], spi 2, on the development and growth of Norway spruce somatic embryo plants. Embryogenic cells of Norway spruce transformed with spi 2 under control of the maize ubi-1 promoter showed up to 40 times higher total peroxidase activity than the control cells; regenerated plants overexpressing spi 2 showed an increased total peroxidase activity. Based on these results and the overall sequence similarity with cationic peroxidases we conclude that spi 2 encodes a peroxidase. Overexpression of spi 2 resulted in increased sensitivity to stress, leading to a reduction in epicotyl formation and in height growth compared with control plants. The plants overexpressing spi 2 also showed a deeper phloroglucinol staining but similar levels of Klason lignin.