Necrosis-inducing proteins of Rhynchosporium commune, effectors in quantitative disease resistance.

The barley pathogen Rhynchosporium commune secretes necrosis-inducing proteins NIP1, NIP2, and NIP3. Expression analysis revealed that NIP1 transcripts appear to be present in fungal spores already, whereas NIP2 and NIP3 are synthesized after inoculation of host plants. To assess the contribution of the three effector proteins to disease development, deletion mutants were generated. The development of these fungal mutants on four barley cultivars was quantified in comparison with that of the parent wild-type strain and with two fungal strains failing to secrete an "active" NIP1 avirulence protein, using quantitative polymerase chain reaction as well as microscopic imaging after fungal green fluorescent protein tagging. The impact of the three deletions varied quantitatively depending on the host genotype, suggesting that the activities of the fungal effectors add up to produce stronger growth patterns and symptom development. Alternatively, recognition events of differing intensities may be converted into defense gene expression in a quantitative manner.

A GFP-based assay to quantify the impact of effectors on the ex planta development of the slowly growing barley pathogen Rhynchosporium commune.

A growth assay was established for the barley pathogen Rhynchosporium commune with EGFP-tagged fungal mutants. This assay was used to study the effect of four antibiotics (hygromycin B, nourseothricin, kanamycin, phleomycin) and a herbicide (phosphinothricin) on fungal development. Fitting the growth curves to the modified Gompertz model allowed calculating growth parameters, such as lag periods of fungal colony formation and mycelial growth rates as well as EC(50) values. Except kanamycin all compounds were efficient inhibitors so that the corresponding resistance-conferring genes can be used as markers for selection of fungal transformation-based mutants. In addition the assay was used to quantify the inhibitory activity of a barley secondary metabolite, the indole alkaloid gramine.

Sterol glycosides and cerebrosides accumulate in Pichia pastoris, Rhynchosporium secalis and other fungi under normal conditions or under heat shock and ethanol stress.

The occurrence of glycolipids such as sterol glycosides, acylated sterol glycosides, cerebrosides and glycosyldiacylglycerols was examined in the three yeast species Candida albicans, Pichia pastoris and Pichia anomala, as well as in the six fungal species Sordaria macrospora, Pyrenophora teres, Ustilago maydis, Acremonium chrysogenum, Penicillium olsonii and Rhynchosporium secalis. Cerebroside was found in all organisms tested, whereas acylated sterol glycosides and glycosyldiacylglycerols were not found in any organism. Sterol glycosides were detected in P. pastoris strain GS115, U. maydis, S. macrospora and R. secalis. This glycolipid occurred in both yeast and filamentous forms of U. maydis but in neither form of C. albicans. This suggests that sterol glycoside is not correlated with the separately grown dimorphic forms of these organisms. Cerebrosides and sterol glycosides from P. pastoris and R. secalis were purified and characterized by mass spectrometry and nuclear magnetic resonance spectroscopy. The cerebrosides are beta-glucosyl ceramides consisting of a saturated alpha-hydroxy or non-hydroxy fatty acid and a Delta4,8-diunsaturated, C9-methyl-branched sphingobase. Sterol glycoside from P. pastoris was identified as ergosterol-beta-D-glucopyranoside, whereas the sterol glucosides from R. secalis contain two derivatives of ergosterol. The biosynthesis of sterol glucoside in P. pastoris CBS7435 and GS115 depended on the culture conditions. The amount of sterol glucoside in cells grown in complete medium was much lower than in cells from minimal medium and a strong increase in the content of sterol glucoside was observed when cells were subjected to stress conditions such as heat shock or increased ethanol concentrations. From these data we suggest that, in addition to Saccharomyces cerevisiae, new yeast and fungal model organisms should be used to study the physiological functions of glycolipids in eukaryotic cells. This suggestion is based on the ubiquitous and frequent occurrence of cerebrosides and sterol glycosides, both of which are rarely detected in S. cerevisiae. We suggest P. pastoris and two plant pathogenic fungi to be selected for this approach.

Heterologous expression of the avirulence gene product, NIP1, from the barley pathogen Rhynchosporium secalis.

NIP1, the product of the avirulence gene AvrRrs1 from Rhynchosporium secalis, a fungal pathogen of barley, is a small secreted cysteine-rich protein. This protein is essential for the specific recognition of the fungus by host plants carrying the complementary resistance gene Rrs1. Different heterologous expression systems were tested to produce sufficient quantities of NIP1 to allow its utilization in receptor identification and isolation. In addition, protein amounts higher than those produced in fungal cultures are required to determine its 3D structure and to analyze its interaction with a receptor. The most efficient method, the synthesis of a His-tag fusion protein in Escherichia coli combined with a refolding procedure, yielded up to 3 mg of recombinant NIP1 from a 1-liter bacterial culture. After removal of the His-tag, the recombinant protein showed the same physicochemical characteristics as the native NIP1 and, most importantly, full biological activity.

Fungal pathogenicity.

Successful penetration of living plant tissue by fungal pathogens is preceded by an exchange of signals between both organisms. Recent mutational approaches revealed the importance of cAMP-dependent signalling pathways for fungal development and virulence on their hosts.

Transformation of the plant pathogenic fungus, Rhynchosporium secalis.

The barley leaf scald fungus, Rhynchosporium secalis, was transformed to hygromycin-B and phleomycin resistance using the hph gene from E. coli and the ble gene from Streptoalloteichus hindustanus under the control of Aspergillus nidulans promoter and terminator sequences. Plasmid DNA was introduced into fungal protoplasts by PEG/CaCl2 treatment. Transformation frequencies varied from 59 to 493 transformants per 10 microg of DNA and 5 x 10(7) protoplasts. The antibiotic-resistant phenotype appeared to be stable under selective, as well as under non-selective, conditions for several generations. Co-transformation using the E. coli uidA gene under the control of A. nidulans promoter and terminator sequences on a non-selectable plasmid occurred at frequencies of up to 66%.

The race-specific elicitor, NIP1, from the barley pathogen, Rhynchosporium secalis, determines avirulence on host plants of the Rrs1 resistance genotype.

NIP1, a small phytotoxic protein secreted by the barley pathogen Rhynchosporium secalis, is a race-specific elicitor of defense responses in barley cultivars carrying the resistance gene, Rrs1. Co-inoculation employing spores from a virulent fungal race together with the NIP1 protein converted the phenotype of the interaction from compatible to incompatible only on Rrs1-containing plants. In addition, transformation of a virulent fungal race with the nip1 gene yielded avirulent transformants. This demonstrated that the protein is the product of a fungal avirulence gene. The fungal genome was found to contain a single copy of the nip1 gene. Sequence analysis of nip1 cDNA and genomic clones revealed that the gene consists of two exons and one intron. The derived amino acid sequence comprised a secretory signal peptide of 22 amino acids and a cysteine-rich mature protein of 60 amino acids. All fungal races that were avirulent on barley cultivars of the Rrs1 resistance genotype carry and express the nip1 gene and secrete an elicitor-active NIP1 polypeptide. In contrast, races lacking this gene were virulent. In addition, single nucleotide exchanges were detected in the coding region of the nip1 alleles in one virulent fungal race and in a race whose interaction with barley is not controlled by the Rrs1 gene. The resulting exchanges of single amino acids render the gene products elicitor-inactive. Thus, the R.secalis-barley interaction provides the first example of a pathosystem conforming to the gene-for-gene hypothesis in which a plant with a particular resistance gene recognizes a pathogen by a virulence factor, i.e. one of its offensive weapons. On the fungal side, in turn, recognition by the host plant is eluded by either deletion of the encoding gene or alteration of the primary structure of the gene product.

Cultivar-specific elicitation of barley defense reactions by the phytotoxic peptide NIP1 from Rhynchosporium secalis.

Resistance of barley to the phytopathogenic fungus, Rhynhosporium secalis race US238.1, was found to be controlled by resistance gene Rrs1, which segregated in a manner characteristics for a codominant gene. PRHv-1, a thaumatin-like pathogenesis-related protein, was shown to be encoded by a gene family on chromosome 1. As part of the barley defense response, significant accumulation of PRHv-1 and peroxidase transcripts was induced early during pathogenesis in two Rrs1 cultivars but not or to a lower level in a near-isogenic, susceptible rrs1 cultivar or a cultivar lacking known resistance genes. R. secalis secretes a small group of necrosis-inducing peptides. One of these, NIP1, which was detected in culture filtrates only of fungal race US238.1, was found to elicit the accumulation of PRHv-1 and peroxidase mRNAs in Rrs1 cultivars with a time course similar to that upon fungal infection. Therefore, NIP1 is a candidate for the product of fungal avirulence gene avrRrs1, which, together with barley resistance gene Rrs1, determines incompatibility of the interaction.

Stimulation of Barley Plasmalemma H+-ATPase by Phytotoxic Peptides from the Fungal Pathogen Rhynchosporium secalis.

A small family of necrosis-inducing peptides has been identified as virulence factors of Rhynchosporium secalis, a fungal pathogen of barley (Hordeum vulgare L.) Two members of this family, NIP1 and NIP3, were found to stimulate the phosphohydrolyzing activity of the Mg2+-dependent, K+-stimulated H+-ATPase of plasma membrane vesicles isolated from barley leaves by partitioning in an aqueous two-phase system. Stimulation of enzyme activity was saturated by 10 to 15 [mu]M fungal protein. Another member of the peptide family, NIP2, did not affect the enzyme, indicating that it has a different mode of action.

Diurnal periodicity of chalcone-synthase activity during the development of oat primary leaves.

Chalcone-synthase (CHS) activity was followed during the development of primary leaves of oat (Avena sativa L.) seedlings grown under different illumination conditions. Continuous darkness and continuous light resulted in similar time courses of enzyme activity. The maximum of CHS activity in etiolated leaves was delayed by 1 d and reached about half the level of that of light-grown leaves. In seedlings grown under defined light-dark cycles a diurnal rhythm of CHS activity and its protein level was observed which followed the rhythm of CHS-mRNA translational activity (Knogge et al. 1986). This rhythm persisted in continuous light after a short-term pre-exposure to the light-dark cycle but not in continuous darkness.

Occurrence of phytoalexins and other putative defense-related substances in uninfected parsley plants.

Considerable amounts of the following substances were found in uninfected parsley (Petroselinum crispum) cotyledons: furanocoumarins, the putative phytoalexins of this and some related plant species, two enzymes of the furanocoumarin pathway (S-adenosyl-L-methionine: xanthotoxol and S-adenosyl-L-methionine: bergaptol O-methyltransferases), two hydrolytic enzymes (1,3-ß-glucanase, EC 3.2.1.39, and chitinase, EC 3.2.1.14), and 'pathogenesis-related' proteins. The furanocoumarins and the methyltransferase activities reached their highest levels at the onset of cotyledon senescence as the hydrolytic enzymes increased from low to relatively high activity values. The relative amounts of pathogenesis-related proteins 1 and 2, as well as the corresponding mRNAs, also increased markedly. Two enzymes of general phenylpropanoid metabolism, L-phenylalanine ammonia-lyase and 4-coumarate: CoA ligase, decreased in activity in a biphasic fashion during cotyledon development. At all developmental stages, the levels of these putative defense-related agents in total cotyledon extracts were too high to enable detection of, possibly, additional changes upon infection with zoospores of Phytophthora megasperma f. sp. glycinea, a fungal pathogen to which parsley shows a non-host, hypersensitive resistance response.

The role of chalcone synthase in the regulation of flavonoid biosynthesis in developing oat primary leaves.

The role of chalcone synthase in the regulation of flavonoid biosynthesis during organogenesis of oat primary leaves has been investigated at the level of enzyme activity and mRNA translation in vitro. Chalcone synthase was purified about 500-fold. The apparent Km values were 1.5 and 6.3 microM for 4-coumaroyl-CoA and malonyl-CoA, respectively. The end products of oat flavonoid biosynthesis, three C-glucosylflavones, did not inhibit the reaction at concentrations as measured up to 60 microM each. Apigenin (4',5,7-trihydroxyflavone), a stable structural analog of the reaction product, 2',4,4',6'-tetrahydroxychalcone, was found to be a strong competitive inhibitor of 4-coumaroyl-CoA binding and a strong noncompetitive inhibitor of malonyl-CoA binding. Although apigenin is not supposed to be an intermediate of C-glucosylflavone biosynthesis, this compound might be a valuable tool for future kinetic studies. To date, there is no indication of chalcone synthase regulation by feedback or similar mechanisms which modulate enzyme activity. Mathematical correlation of chalcone synthase activity and flavonoid accumulation during leaf development, however, indicates that chalcone synthase is the rate-limiting enzyme of the pathway. By in vitro translation studies using preparations of total RNA from different leaf stages, we could demonstrate for the first time that the translational activity of chalcone synthase mRNA undergoes marked daily changes. The high values found at the end of the dark phase suggest that light does not exert direct influence on flavonoid biosynthesis but probably functions by controlling the basic diurnal rhythm.

Tissue-distribution of secondary phenolic biosynthesis in developing primary leaves of Avena sativa L.

Primary leaves of oats (Avena sativa L.) have been used to study the integration of secondary phenolic metabolism into organ differentiation and development. In particular, the tissue-specific distribution of products and enzymes involved in their biosynthesis has been investigated. C-Glucosylflavones along with minor amounts of hydroxycinnamic-acid esters constitute the soluble phenolic compounds in these leaves. In addition, considerable amounts of insoluble products such as lignin and wall-bound ferulic-acid esters are formed. The tissue-specific activities of seven enzymes were determined in different stages of leaf growth. The rate-limiting enzyme of flavonoid biosynthesis in this system, chalcone synthase, together with chalcone isomerase (EC 5.5.1.6) and the terminal enzymes of the vitexin and isovitexin branches of the pathway (a flavonoid O-methyltransferase and an isovitexin arabinosyltransferase) are located in the leaf mesophyll. Since the flavonoids accumulate predominantly (up to 70%) in both epidermal layers, an intercellular transport of products is postulated. In contrast to the flavonoid enzymes, L-phenylalanine ammonia-lyase (EC 4.3.1.5), 4-coumarate: CoA ligase (EC 6.2.1.12), and S-adenosyl-L-methionine: caffeate 3-O-methyltransferase (EC 2.1.1.-), all involved in general phenylpropanoid metabolism, showed highest activities in the basal leaf region as well as in the epidermis and the vascular bundles. We suggest that these latter enzymes participate mainly in the biosynthesis of non-flavonoid phenolic products, such as lignin in the xylem tissue and wall-bound hydroxycinnamic acid-esters in epidermal, phloem, and sclerenchyma tissues.

Purification, characterization, and kinetic mechanism of S-adenosyl-L-methionine: vitexin 2"-O-rhamnoside 7-O-methyltransferase of Avena sativa L.

An O-methyltransferase catalyzing the transfer of the methyl group of S-adenosyl-L-methionine to the A-ring 7-hydroxyl group of vitexin 2"-O-rhamnoside has been isolated from oat primary leaves and purified 180-fold by protein fractionation with (NH4)2SO4 and chromatography on DEAE-cellulose and S-adenosyl-L-homocysteine-sepharose. Km values for S-adenosyl-L-methionine and the flavonoid substrate were 1.6 microM and 15 microM, respectively. The lack of methyltransfer to biosynthetic intermediates suggests that the reaction is the last step in the biosynthetic pathway to the oat flavonoid 7-O-methylvitexin 2"-O-rhamnoside. Based on results obtained from kinetic inhibition studies and affinity chromatography a mono-iso Theorell-Chance mechanism is proposed with the nucleotide substrate binding before the flavonoid.

Application of liquid chromatography to a study on 4-coumarate: coenzyme A ligase activity.

This report describes the separation of components from a 4-coumarate:CoA ligase assay by means of liquid chromatography. With the aid of polyamide column chromatography it is possible to enrich and isolate chromatographically and UV spectroscopically pure p-coumaroyl-CoA using as a solvent 0.01% NH4OH in methanol subsequent to water and methanol alone. High performance liquid chromatography on octadecylsilane-bonded silica stationary phase allows a discontinuous determination of ligase activity. All components - ATP, Coenzyme A, p-coumaric acid, and the products AMP and p-coumaroyl-CoA - can be separated and accurately quantified within 20 min using a water-acetonitrile gradient, containing 1% phosphoric acid. The presented HPLC method may be used to affirm the accuracy of optical tests.