Tenuazonic acid,toxin of rice blast fungus,induces disease resistance and reactive oxygen production in plants

Effects of tenuazonic acid (TA) on rice leaf segments and on their interaction with compatible races of the blast fungus (Magnaporthe grisea, former name is Pyricularia oryzae) were studied. TA induced small brown necrotic spots on leaves Application of TA (1 or 5 mM) to leaves in mixtures with M. grisea spores induced a local disease resistance, which reduced the frequency of compatible lesions. TA was not fungitoxic but, in contact with the leaf, increased the capability of leaf diffusates to inhibit germination of M. grisea spores. In the infected leaves, the diffusate fungitoxicity was higher than in the healthy ones. Antioxidant enzymes, superoxide dismutase and catalase, and scavengers of hydroxyl radical, mannitol and formate, strongly inhibited the TA-induced diffusate fungitoxicity. It is suggested that the disease resistance induced by TA is mediated, at least partially, by generation of reactive oxygen species by rice leaves, which inhibit the development of the fungus directly or indirectly.     

FKBP22 is part of chaperone/folding catalyst complexes in the endoplasmic reticulum of Neurospora crassa

FKBP22 is a dimeric protein in the lumen of the endoplasmic reticulum, which exhibits a chaperone as well as a PPIase activity. It binds via its FK506 binding protein (FKBP) domain directly to the Hsp70 chaperone BiP that stimulates the chaperone activity of FKBP22. Here we demonstrate additionally the association of FKBP22 with the molecular chaperones and folding catalysts Grp170, alpha-subunit of glucosidase II, PDI, ERp38, and CyP23. These proteins are associated with FKBP22 in at least two protein complexes. Furthermore, we report an essential role for FKBP22 in the development of microconidiophores in Neurospora crassa.     

Ascherxanthone B from Aschersonia luteola, a new antifungal compound active against rice blast pathogen Magnaporthe grisea

Aims:  Fungicide resistance now exists in the rice blast fungus, Magnaporthe grisea , necessitating the need for new active agents. Fungi isolated from habitats in Thailand were screened with reference to this problem.
Methods and Results:  A new, reliable in vitro screening system based on a microdilution plate format was set up using a virulent strain of M. grisea THL 16. Culture broth extracts from approximately 800 fungal strains were investigated, one of these, Aschersonia luteola BCC 8774, was found to produce an active fungicidal compound, ascherxanthone B, with an IC₉₀ value of 0·58 μg ml⁻¹ (0·95 μmol l⁻¹). An in vivo study of anti-blast efficacy of ascherxanthone B showed a positive effect in disease reduction.
Conclusions:  Previous report has shown that a species of Aschersonia produces ascherxanthone A. Research on the species, A. luteola BCC 8774, led to the discovery of related novel metabolite, ascherxanthone B with fungicidal properties.
Significance and Impact of the Study:  Current methods of rice blast control seem to fail leading to increase in crop losses. Our discovery of the anti-blast activity shown by ascherxanthone B is the first step in the development of a potentially novel fungicide.     

Cloning of the blasticidin S deaminase gene (BSD) from Aspergillus terreus and its use as a selectable marker for Schizosaccharomyces pombe and Pyricularia oryzae

Aspergillus terreus produces a unique enzyme, blasticidin S deaminase, which catalyzes the deamination of blasticidin S (BS), and in consequence confers high resistance to the antibiotic. A cDNA clone derived from the structural gene for BS deaminase (BSD) was isolated by transforming Escherichia coli with an Aspergillus cDNA expression library and directly selecting for the ability to grow in the presence of the antibiotic. The complete nucleotide sequene of BSD was determined and proved to contain an open reading frame of 393 bp, encoding a polypeptide of 130 amino acids. Comparison of its nulceotide sequence with that of bsr, the BS deaminase gene isolated from Bacillus cereus, indicated no homology and a large difference in codon usage. The activity of BSD expressed in E. coli was easily quantified by an assay based on spectrophotometric recording. The BSD gene was placed in a shuttle vector for Schizosaccharomyces pombe, downstream of the SV40 early region promoter, and this allowed direct selection with BS at high frequency, following transformation into the yeast. The BSD gene was also employed as a selectable marker for Pyricularia oryzae, which could not be transformed to BS resistance by bsr. These results promise that the BSD gene will be useful as a new dominant selectable marker for eukaryotes.     

NUT1, a major nitrogen regulatory gene inMagnaporthe grisea, is dispensable for pathogenicity

NUT1, a gene homologous to the major nitrogen regulatory genesnit-2 ofNeurospora crassa andareA ofAspergillus nidulans, was isolated from the rice blast fungus,Magnaporthe grisea. NUT1 encodes a protein of 956 amino acid residues and, likenit-2 andareA, has a single putative zinc finger DNA-binding domain. Functional equivalence ofNUT1 toareA was demonstrated by introducing theNUT1 gene by DNA-mediated transformation into anareA loss-of-function mutant ofA. nidulans. The introducedNUT1 gene fully complemented theareA null mutation, restoring to the mutant the ability to utilize a variety of nitrogen sources. In addition, the sensitivity ofAspergillus NUT1 transformants to ammonium repression of extracellular protease activity was comparable to that of wild-typeA. nidulans. Thus,NUT1 andareA encode functionally equivalent gene products that activate expression of nitrogen-regulated genes. A one-step gene disruption strategy was used to generatenutl ^– mutants ofM. grisea by transforming a rice-infecting strain with a disruption vector in which a gene for hygromycin B phosphotransferase (Hyg) replaced the zinc-finger DNA-binding motif ofNUT1. Of 31 hygromycin B (hyg B)-resistant transformants shown by Southern hybridization to contain a disruptedNUT1 gene (nut1::Hyg), 26 resulted from single-copy replacement events at theNUT1 locus. Althoughnut1 ^– transformants ofM. grisea failed to grown on a variety of nitrogen sources, glutamate, proline and alanine could still be utilized. This contrasts withA. nidulans where disruption of the zinc-finger region ofareA prevents utilization of nitrogen sources other than ammonium and glutamine. The role ofNUT1 and regulation of nitrogen metabolism in the disease process was evaluated by pathogenicity assays. The infection efficiency ofnut1 ^– transformants on susceptible rice plants was similar to that of the parental strain, although lesions were reduced in size. These studies demonstrate that theM. grisea NUT1 gene activates expression of nitrogen-regulated genes but is dispensable for pathogenicity.     

Comparison of rice lines derived through anther culture and the pedigree method in relation to blast (Pyricularia grisea Sacc.) resistance

Crosses were made between Fanny (highly susceptible to blast) and 11 cultivars differing in blast resistance. Using the pedigree method (PM) segregating generations were evaluated and selected for blast resistance. Via anther culture (AC), doubled-haploids were obtained from F₁ plants and from F₂ blast-susceptible plants. Pedigree and anther culture-derived lines were planted together and evaluated for blast resistance under rainfed conditions at the Santa Rosa Experiment Station, Villavicencio, Colombia. The principal objective was to compare PM and AC in terms of their efficiency in producing rice lines resistant to blast. Results of a stratified analysis showed an association between method and blast resistance. Results of the logit-model analysis showed that AC produced a significantly (P=0.0001) higher proportion of lines with initial blast resistance (leaf- and neck-blast reaction 4) than did PM across all cross types. Stable blast resistance was assessed based on field performance over 3 years. AC was superior to PM in generating stable resistance for only some cross types. Consequently, with a few exceptions, AC can be used as effectively as PM to develop rice cultivars resistant to blast, with savings in time and labor. Additionally, blast-resistant lines were obtained either by the pedigree method or by anther culture from crosses between blast-susceptible cultivars (Fanny/CICA4 and Fanny/Colombial). This excludes somaclonal variation as a possible mechanism responsible for this resistance and suggests that a recombination of minor genes could have occurred and was fixed through either method. However, the stability of the resistance was greater in pedigree-derived lines. The implications of these findings for rice blast-resistance breeding are discussed.     

Nitrogen form and silicon nutrition effects on resistance to blast disease of rice

The effect of N form and Si nutrition on rice (Oryza sativa L.) susceptibility to blast disease (caused by Pyricularia oryzae Cav.) was assessed in the greenhouse with nutrient solution culture. The N form supplied to the susceptible cultivar IR50 affected the relative infection efficiency (RIE) of P. oryzae measured as lesions/cm² leaf. Plants given NO₃ ^- were more susceptible than plants receiving NH₄ ⁺-N. This result may partially explain why plants grown in nonflooded soil, where NO₃ ^- is the main source of inorganic N, are more susceptible to blast than plants grown in flooded soils, where NH₄ ⁺ is the main inorganic N source. Nitrate-N and Mn concentration were higher in leaf blades of plants grown with NO₃ ^-. Total-N, Si, and Fe concentration were not affected by N form. The addition of Si significantly increased IR50 resistance to blast. With 2.2 mol m^-3 Si in solution, RIE values were lower by more than 90% than the control with no Si added in solution. The effect of Si accumulation in leaves at various positions was further studied in cultivars having differing levels of resistance (IR50, IR36, and IAC165). Silicon addition significantly reduced RIE in the three cultivars. Silicon concentration in the topmost leaves (the only leaves showing typical blast lesions) was not significantly different among the three cultivars when 2.2 mol m^-3 Si was used. Silicon was an important component in the mechanism of resistance to blast and it was effective regardless of the original level of resistance of the cultivar used. Contribution from the Agronomy Unit, Agronomy-Physiology-Agroecology Division, International Rice Research Institute (IRRI), P.O. Box 933, 1099 Manila, Philippines, and Colegio de Postgraduados, Mexico. Part of a thesis submitted by the senior author in partial fulfillment of the requirements for the M.S. degree.     

差异显示法分离水稻抗稻瘟病相关基因

采用mRNA差异显示技术,分析水稻稻瘟病抗源材料“地谷”叶片受稻瘟病菌侵染前后的基因的表达差异,获得87个差异片段。对这87个差异片段进行了回收、重扩增与克隆,并对其中的81个片段进行了杂交鉴定。斑点杂交结果证实其中6个片段受稻瘟病菌诱导表达。进一步克隆测序并进行数据库比对分析表明其中一个与水稻4号染色体中一推测的苹果酸合成酶高度同源,一个与水稻11号染色体上的RPR1基因高度同源,RPR1基因具有保守的NBS-LRR结构,并与水稻防卫反应的信号传导有关;另一个与水稻第6号染色体上一推测的硫氧还蛋白高度同源,其余3个为新的cDNA片段。