Elicitation of diacetylenic compounds in suspension cultured cells of eggplant

Induction of stress metabolites in the suspension cultured cells of eggplant (Solanum melongena L.) was examined. When autoclaved RNase A or nigeran, both of which are nonspecific phytoalexin elicitors in bean cells, were added to the cell culture of eggplant, greatly enhanced levels of three compounds were observed. One of them was cis-pentadeca-6-ene-1,3-diyne-5,15-diol, a novel diacetylenic compound. This compound has considerable fungitoxic activity. Also identified was falcarindiol, another fungitoxic diacetylenic compound previously reported as one of the phytoalexins in infected tomato fruits and leaves. Elicited compounds preferentially accumulated in the culture medium rather than in the cells and decreased to original levels during prolonged culturing. The elicitation of these compounds was closely correlated with cellular damage in terms of the decrease of growth rate and was inhibited by 10 micromolar cycloheximide.     

Phytotoxin production by Alternaria linicola and phytoalexin production by the linseed host

Alternaria linicola produced a wide range of secondary metabolites when grown in a defined culture medium. Reverse phase chromatography fractions produced disease-like symptoms on linseed cultivars and a range of non-host species indicating the presence of phytotoxic components. Characterised via thin layer chromatography, these included the non-host specific phytotoxins tenuazonic acid, alternariol monomethyl ether, tentoxin and two destruxin-type compounds (which closely resembled destruxin A and destruxin B). The identity of four of the compounds was confirmed by two dimensional thin layer chromatography and proton nuclear magnetic resonance spectroscopy. In a second experiment, Linum leaf material infected with conidia of A. linicola and blastospores of Melampsora lini was extracted using a facilitated diffusion extraction technique. The resultant extracts contained a number of compounds which were fungitoxic to Cladosporium cladospiroides and, to a lesser extent, Alternaria brassicicola. One such compound corresponded to the phytoalexin coniferyl alcohol. Quantitative differences in the amount of the fungitoxic compounds produced between the inoculated and uninoculated resistant and susceptible host genotype combinations suggested that the production of fungitoxic compounds was greater in response to attempted colonisation. On this basis it is proposed that phytoalexin production is a component of the resistance reaction. The results from these investigations are discussed in relation to recent research on the ecology of the pathogen and the possible roles of phytotoxin production by the pathogen and phytoalexin production by the host on disease development.     

Capsidiol: Its role in the resistance of Capsicum annuum to Phytophthora capsici

Inoculation of the stems of three Capsicum annuum L. cultivars showing different degrees of sensitivity to the fungal pathogen Phytophthora capsici , resulted in a hypersensitive reaction being expressed along the stems. One of the peppers (cv. Smith-5) showed resistance by total inhibition of fungal growth. Capsidiol, a phytoalexin, which accumulates in the area of necrosis appears to be involved in this resistance. Capsidiol accumulation was analyzed by gas chromatography and was correlated with the restricted growth of P. capsici , in vivo and in vitro, confirming the former's fungistatic and fungitoxic properties. The capacity to inhibit pathogenic growth was evident only when capsidiol production exceeded 1 204 μg ml^-1, a level reached in the resistant variety after 6 days of incubation. Experiments on induced resistance showed that a second inoculation of the stems of the three cultivars also resulted in necrosis and in an accumulation of capsidiol, although to a lesser extent than in the first inoculation. The greater accumulation of capsidiol in the stems of cv. Smith-5 is in accordance with the resistance shown by this cultivar to P. capsici , and confirms the implication of capsidiol in the disease resistance of this cultivar to fungal pathogens. Capsidiol has a fungistatic character at a mean concentration of 3.75 mM, and is fungitoxic at levels above 5 mM. This level must be exceeded and all the growing hyphae must be affected for capsidiol to qualify from being fungistatic to being fungitoxic.     

Phytoalexins and polar metabolites from the oilseeds canola and rapeseed: differential metabolic responses to the biotroph Albugo candida and to abiotic stress

The metabolites produced in leaves of the oilseeds canola and rapeseed (Brassica rapa L.) inoculated with either different races of the biotroph Albugo candida or sprayed with CuCl(2) were determined. This investigation established consistent phytoalexin (spirobrassinin, cyclobrassinin, and rutalexin) and phytoanticipin (indolyl-3-acetonitrile, arvelexin, caulilexin C, and 4-methoxyglucobrassicin) production in canola and rapeseed in response to both biotic and abiotic elicitation. In addition, a wide number of polar metabolites were isolated from infected leaves, including six new phenylpropanoids and two new flavonoids. The extractable chemical components of zoosporangia of A. candida and the anti-oomycete activity of phytoalexins were determined as well. Overall, the results suggest that during the initial stage of the interaction, leaves of B. rapa have a similar response to virulent and avirulent races of A. candida, with respect to the accumulation of chemical defenses. After this stage, despite the higher phytoalexin concentration, the "compatible" races could overcome the plant defense system for further infection, but growth of the "incompatible" races was inhibited. Since results of bioassays showed that cyclobrassinin and brassilexin were more inhibitory to A. candida than rutalexin, the apparent redirection of the phytoalexin pathway towards rutalexin, avoiding cyclobrassinin and brassilexin accumulation might be caused by the pathogen. Alternatively, A. candida might be able to detoxify both cyclobrassinin and brassilexin, similar to necrotrophic plant pathogens. Overall, the correlation between phytoalexin production in infected or stressed leaves and the outcome of the plant-pathogen interaction suggested that A. candida was able to elude the plant defense mechanisms by, for example, redirecting the phytoalexin biosynthetic pathway.     

<Emphasis Type="Italic">Streptomyces scabiei</Emphasis> and its toxin thaxtomin A induce scopoletin biosynthesis in tobacco and <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

Streptomyces scabiei is the predominant causal agent of common scab of potato in North America. The virulence of common scab-causing streptomycetes relies on their capacity to synthesize thaxtomins. In this study, the effects of S. scabiei infection and of thaxtomin A, the main toxin produced by S. scabiei, were tested for the elicitation of plant defense molecules in the model plants tobacco (Nicotiana tabacum) and Arabidopsis thaliana. Tobacco leaves infected with spores of S. scabiei strain EF-35 or infiltrated with purified thaxtomin A produced a blue fluorescent compound that was not detected in leaves infiltrated with spores of a S. scabiei mutant deficient in thaxtomin A biosynthesis. Thin layer chromatography and high performance liquid chromatography identified this fluorescent compound as scopoletin, a plant defense phytoalexin. Arabidopsis seedlings grown in liquid medium also excreted scopoletin as a reaction to S. scabiei and thaxtomin A. The effects of the presence of scopoletin on S. scabiei were also investigated. The phytoalexin scopoletin caused a slight reduction of bacterial growth and a severe decrease of thaxtomin A production. Scopoletin was shown to inhibit thaxtomin A production by repression of a gene involved in the toxin biosynthesis.     

Biosynthesis of scopoletin in Hevea brasiliensis leaves inoculated with Phytophthora palmivora

Inoculation of resistant (R) and susceptible (S) Hevea brasiliensisleaves with Phytophthora palmivorainduced foliar necrosis and biosynthesis of scopoletin (Scp), considered as a Heveaphytoalexin. The degree of resistance of four clones, as classified by the necrotic lesions, was related to the rapidity and intensity of Scp production. The resistant BPM-24, and marked partially resistant clone PB-235, displayed an early secretion of scopoletin that intensified and lasted longer than the weak partially resistant RRIT251, and susceptible clone RRIM600. The lesion size and amount of Scp after infection were positively correlated to the concentration of spores applied to Hevealeaves. In addition, in leaflets inoculated with high spore concentration, Scp reached the highest level earlier than those with low spore concentration. A fungitoxic effect of Scp on mycelium growth was shown in bioassays; the I₅₀ value tested on Phytophthora palmivora was relatively the same as on Phytophthora botryosa, but much lower than those found on other leaf pathogens of rubber tree, Corynespora cassiicolaand Colletotrichum gloeosporioides. The lesion size and level of Scp upon spore inoculation may be appropriate for classifying Heveaclones according to their R/S with respect to P. palmivora     

Expression of the 12-oxophytodienoic acid 10,11-reductase gene in the compatible interaction between pea and fungal pathogen

Suppressors produced by Mycosphaerella pinodes are glycopeptides to block pea defense responses induced by elicitors. A clone, S64, was isolated as cDNA for suppressor-inducible gene from pea epicotyls. The treatment of pea epicotyls with suppressor alone induced an increase of S64 mRNA within 1 h, and it reached a maximum level at 3 h after treatment. The induction was not affected by application of the elicitor, indicating that the suppressor has a dominant action to regulate S64 gene expression. S64 was also induced by inoculation with a virulent pathogen, M. pinodes, but not by inoculation with a non-pathogen, Ascochyta rabiei, nor by treatment with fungal elicitor. The deduced structure of S64 showed high homology to 12-oxophytodienoic acid reductase (OPR) in Arabidopsis thaliana. A recombinant protein derived from S64 had OPR activity, suggesting compatibility-specific activation of the octadecanoid pathway in plants. Treatment with jasmonic acid (JA) or methyl jasmonic acid, end products of the octadecanoid pathway, inhibited the elicitor-induced accumulation of PAL mRNA in pea. These results indicate that the suppressor-induced S64 gene expression leads to the production of JA or related compounds, which might contribute to the establishment of compatibility by inhibiting the phenylpropanoid biosynthetic pathway.     

A Phytoalexin-Like Flavonol Involved in the Carnation (Dianthus caryophyllus)-Fusarium oxysporum f. sp. dianthi Pathosystem

The fungitoxic flavonol triglycoside, kaempferide 3‐O‐[2^G‐β‐d ‐glucopyranosyl]‐β‐rutinoside, is a constituent of the carnation cultivar ‘Novada’, known as one of the most resistant cultivar to Fusarium oxysporum f. sp. dianthi, causative agent of Fusarium wilt. Due to its constitutive presence within the carnation tissues, this antifungal flavonol should be considered as a phytoanticipin; its biosynthesis, however, is stimulated by the inoculation with F. oxysporum f. sp. dianthi, just as is the rule for a typical phytoalexin. The results seem to indicate that in carnation the concentration of some preformed antifungal flavonoids may be significantly increased by a fungal presence: owing to their fungitoxic properties, these molecules could cooperate, together with the unconstitutive and postinfectional anthranilic acid‐derivative phytoalexins, to the plant defensive response against Fusarium attacks.     

Accumulation of antifungal compounds in tea leaf tissue infected withBipolaris carbonum

Varietal resistance of tea towardsBipolaris carbonum was tested following detached leaf inoculation technique. Among the fourteen varieties tested, three were found to be highly susceptible, while other three were resistant. Leaf exudates and diffusates collected from the resistant varieties were more fungitoxic than those from the susceptible ones. Two antifungal compounds isolated from healthy andB. carbonum-infected tea leaves exhibited clear inhibition zones atR _F 0.8 and 0.65, respectively, in a chromatographic bioassay. On the basis of their color reaction on TLC and UV-spectra these were identified to be catechin and pyrocatechol. Resistant and susceptible varieties accumulated 439–510 and 187–212 μg/g fresh mass tissue of pyrocatechol, respectively, 2 d after inoculation withB. carbonum, while a low concentration (45–58 μg/g) of this compound was detected in healthy leaf tissue.     

Delayed chlorophyll accumulation and pigment photodestruction in the epicotyls of dark-grown pea (Pisum sativum)

A comparison was performed of the tetrapyrrole transformations that occur upon irradiation of epicotyl or leaves of dark-grown Pisum sativum L. (var. Zsuzsi, Hungary). High performance liquid chromatography analysis after continuous or flash-irradiation showed that the biosynthetic pathway from protochlorophyllide (Pchlide) to chlorophyll (Chl) a was markedly slowed down at the step of the reduction of geranylgeranyl(gg)-Chl to dihydrogeranylgeranyl (dhgg)-Chl in epicotyls, whereas phytyl-Chl was synthesized in leaves subjected to the same light treatments. Quantitative pigment analysis during continuous irradiations of different intensities also showed that significant Pchlide photodestruction occurred in epicotyls even under weak light. When both Pchlide and chlorophyllide and/or chlorophylls were present in epicotyls, Pchlide photodestruction was faster under 630-nm light than under 670-nm light, which indicates that this process is most efficiently promoted by Pchlide excitation. Pre-incubation of epicotyl segments with 10 m M ascorbate partly alleviated pigment photodestruction in white light. It is concluded that formation of photoactive Pchlide–Pchlide oxidoreductase complexes is important to prevent fast pigment photooxidation after Pchlide accumulation in the dark.     

The ABC transporter BcatrB from Botrytis cinerea exports camalexin and is a virulence factor on Arabidopsis thaliana

Arabidopsis thaliana is known to produce the phytoalexin camalexin in response to abiotic and biotic stress. Here we studied the mechanisms of tolerance to camalexin in the fungus Botrytis cinerea , a necrotrophic pathogen of A. thaliana . Exposure of B. cinerea to camalexin induces expression of BcatrB , an ABC transporter that functions in the efflux of fungitoxic compounds. B. cinerea inoculated on wild-type A. thaliana plants yields smaller lesions than on camalexin-deficient A. thaliana mutants. A B. cinerea strain lacking functional BcatrB is more sensitive to camalexin in vitro and less virulent on wild-type plants, but is still fully virulent on camalexin-deficient mutants. Pre-treatment of A. thaliana with UV-C leads to increased camalexin accumulation and substantial resistance to B. cinerea. UV-C-induced resistance was not seen in the camalexin-deficient mutants cyp79B2/B3 , cyp71A13 , pad3 or pad2 , and was strongly reduced in ups1 . Here we demonstrate that an ABC transporter is a virulence factor that increases tolerance of the pathogen towards a phytoalexin, and the complete restoration of virulence on host plants lacking this phytoalexin.     

Wounding of Arabidopsis leaves causes a powerful but transient protection against Botrytis infection

Physical injury inflicted on living tissue makes it vulnerable to invasion by pathogens. Wounding of Arabidopsis thaliana leaves, however, does not conform to this concept and leads to immunity to Botrytis cinerea , the causal agent of grey mould. In wounded leaves, hyphal growth was strongly inhibited compared to unwounded controls. Wound-induced resistance was not associated with salicylic acid-, jasmonic acid- or ethylene-dependent defence responses. The phytoalexin camalexin was found to be involved in this defence response as camalexin-deficient mutants were not protected after wounding and the B. cinerea strains used here were sensitive to this compound. Wounding alone did not lead to camalexin production but primed its accumulation after inoculation with B. cinerea , further supporting the role of camalexin in wound-induced resistance. In parallel with increased camalexin production, genes involved in the biosynthesis of camalexin were induced faster in wounded and infected plants in comparison with unwounded and infected plants. Glutathione was also found to be required for resistance, as mutants deficient in γ-glutamylcysteine synthetase showed susceptibility to B. cinerea after wounding, indicating that wild-type basal levels of glutathione are required for the wound-induced resistance. Furthermore, expression of the gene encoding glutathione- S -transferase 1 was primed by wounding in leaves inoculated with B. cinerea . In addition, the priming of MAP kinase activity was observed after inoculation of wounded leaves with B . cinerea compared to unwounded inoculated controls. Our results demonstrate how abiotic stress can induce immunity to virulent strains of B. cinerea , a process that involves camalexin and glutathione.     

Induction of defence-related biochemical changes in okra leaves to powdery mildew disease by several plant-derived agents

Certain plant-derived agents (PDA) which could induce resistance in okra leaves against powdery mildew (Erysiphe cichoracearum) and biochemical changes in treated leaves were investigated during 2011 and 2012 growing seasons. At the two-leaf old, four- and eight-week leaves of the greenhouse-grown okra plants were sprayed with either PDA two days before inoculation with conidia. Among all tested PDA, neem seed oil (NSO) caused the highest protection, followed by jojoba oil (JO) and extract of Reynoutria sachalinensis. Moreover, levels of total protein, activity of peroxidase, polyphenyloxidase and chitinase and total phenols content of treated two-leaf old highly increased after application of NSO and JO, but not by the pathogen (untreated control). Finally, based on conidia germination, lack of the fungitoxic effect of JO and RE and also the slight effect of NSO (9–13.75%) may demonstrate the main role of these agents for inducing resistance through the activation of biochemical defence in treated leaves.     

The ABC transporter BcatrB affects the sensitivity of Botrytis cinerea to the phytoalexin resveratrol and the fungicide fenpiclonil

During pathogenesis, fungal pathogens are exposed to a variety of fungitoxic compounds. This may be particularly relevant to Botrytis cinerea, a plant pathogen that has a broad host range and, consequently, is subjected to exposure to many plant defense compounds. In practice, the pathogen is controlled with fungicides belonging to different chemical groups. ATP-binding cassette (ABC) transporters might provide protection against plant defense compounds and fungicides by ATP-driven efflux mechanisms. To test this hypothesis, we cloned BcatrB, an ABC transporter-encoding gene from B. cinerea. This gene encodes a 1,439 amino acid protein with nucleotide binding fold (NBF) and transmembrane (TM) domains in a [NBF-TM6]2 topology. The amino acid sequence has 31 to 67% identity with ABC transporters from various fungi. The expression of BcatrB is up regulated by treatment of B. cinerea germlings with the grapevine phytoalexin resveratrol and the fungicide fenpiclonil. BcatrB replacement mutants are not affected in saprophytic growth on different media but are more sensitive to resveratrol and fenpiclonil than the parental isolate. Furthermore, virulence of deltaBcatrB mutants on grapevine leaves was slightly reduced. These results indicate that BcatrB is a determinant in sensitivity of B. cinerea to plant defense compounds and fungicides.     

The phytopathogenic fungus Alternaria brassicicola: Phytotoxin production and phytoalexin elicitation

The metabolites and phytotoxins produced by the phytopathogenic fungus Alternaria brassicicola (Schwein.) Wiltshire, as well as the phytoalexins induced in host plants, were investigated. Brassicicolin A emerged as the most selective phytotoxic metabolite produced in liquid cultures of A. brassicicola and spirobrassinin as the major phytoalexin produced in infected leaves of Brassica juncea (whole plants). In detached infected leaves of B. juncea, the main component was N′-acetyl-3-indolylmethanamine, the product of detoxification of the phytoalexin brassinin by A. brassicicola. In addition, the structure elucidation of three hitherto unknown metabolites having a fusicoccane skeleton was carried out and the antifungal activity of several plant defenses against A. brassicicola was determined.     

Phytoalexin Accumulation in Arabidopsis thaliana during the Hypersensitive Reaction to Pseudomonas syringae pv syringae

Inoculation of leaves of Arabidopsis thaliana (L.) Heynh. with the wheat pathogen, Pseudomonas syringae pv syringae, resulted in the expression of the hypersensitive reaction and in phytoalexin accumulation. No phytoalexin accumulation was detected after infiltration of leaves with a mutant of P. s. syringae deficient in the ability to elicit a hypersensitive reaction; with the crucifer pathogen, Xanthomonas campestris pv campestris; or with 10 millimolar potassium phosphate buffer (pH 6.9). Phytoalexin accumulation was correlated with the restricted in vivo growth of P. s. syringae. A phytoalexin was purified by a combination of reverse phase flash chromatography, thin layer chromatography, followed by reverse phase high performance liquid chromatography. The Arabidopsis phytoalexin was identified as 3-thiazol-2′-yl-indole on the basis of ultraviolet, infrared, mass spectral, ¹H-nuclear magnetic resonance, and ¹³C-nuclear magnetic resonance data.     

Identification of Scopoletin as a Phytoalexin of the Rubber Tree Hevea brasiliensis1

In leaves of Hevea sp. the production of a blue fluorescing phytoalexin is induced by various fungi. This compound is shown by chromatographic and spectrophotometric means to be scopoletin.     

A stress-inducible resveratrol O-methyltransferase involved in the biosynthesis of pterostilbene in grapevine

Stilbenes are considered the most important phytoalexin group in grapevine (Vitis vinifera) and they are known to contribute to the protection against various pathogens. The main stilbenes in grapevine are resveratrol and its derivatives and, among these, pterostilbene has recently attracted much attention due both to its antifungal and pharmacological properties. Indeed, pterostilbene is 5 to 10 times more fungitoxic than resveratrol in vitro and recent studies have shown that pterostilbene exhibits anticancer, hypolipidemic, and antidiabetic properties. A candidate gene approach was used to identify a grapevine resveratrol O-methyltransferase (ROMT) cDNA and the activity of the corresponding protein was characterized after expression in Escherichia coli. Transient coexpression of ROMT and grapevine stilbene synthase in tobacco (Nicotiana benthamiana) using the agroinfiltration technique resulted in the accumulation of pterostilbene in tobacco tissues. Taken together, these results showed that ROMT was able to catalyze the biosynthesis of pterostilbene from resveratrol both in vitro and in planta. ROMT gene expression in grapevine leaves was induced by different stresses, including downy mildew (Plasmopara viticola) infection, ultraviolet light, and AlCl(3) treatment.