Rhizobacterially induced protection of watermelon against Didymella bryoniae.

AIMS: To identify rhizobacteria from the Mekong Delta of Vietnam, which can systemically protect watermelon against Didymella bryoniae and elucidate the mechanisms involved in the protection conferred by isolate Pseudomonas aeruginosa 23(1-1). METHODS AND RESULTS: Bacteria were isolated from watermelon roots and their antagonistic ability tested in vitro. Of 190 strains, 68 were able to inhibit D. bryoniae by production of antibiotics. Four strains were able to reduce foliar infection by D. bryoniae when applied to watermelon seeds before sowing. Strain Ps. aeruginosa 23(1-1) was chosen for investigations of the mechanisms involved in protection and ability to control disease under field conditions. In the field, the bacterium was able to significantly reduce disease in two consecutive seasons and increase yield. Furthermore, it colonized watermelon plants endophytically, with higher numbers in plants infected by D. bryoniae than in noninoculated plants. To elucidate the mechanisms involved in protection, the infection biology of the pathogen was studied in bacterially treated and control plants. Pseudomonas aeruginosa 23(1-1) treatment inhibited pathogen penetration and this was associated with hydrogen peroxide accumulation, increased peroxidase activity and occurrence of new peroxidase isoforms, thus indicating that resistance was induced. CONCLUSIONS: The endophytic bacterium Ps. aeruginosa 23(1-1) can control D. bryoniae in watermelon by antibiosis and induced resistance under greenhouse and field conditions. SIGNIFICANCE AND IMPACT OF THE STUDY: These findings suggest that rhizobacteria from native soils in Vietnam can be used to control gummy stem blight of watermelon through various mechanisms including induction of resistance.

Infection biology and defence responses in sorghum against Colletotrichum sublineolum.

AIMS: To investigate the infection biology of Colletotrichum sublineolum (isolate CP2126) and defence responses in leaves of resistant (SC146), intermediately resistant (SC326) and susceptible (BTx623) sorghum genotypes. METHODS AND RESULTS: Infection biology and defence responses were studied quantitatively by light microscopy, H(2)O(2) accumulation by DAB staining and HRGP accumulation by immunological methods. Inhibition of conidial germination and appressorium formation may represent prepenetration defence responses on the leaf surface. Inducible defence responses in the resistant genotypes included decreases in formation of appressoria as well as accumulation of H(2)O(2), HRGPs and phytoalexins. Concomitant with these inducible responses, fungal growth was stopped during or just after penetration in genotypes SC146 and SC326. High levels of H(2)O(2) accumulating at late infection stages (5 days after inoculation) in the susceptible genotype BTx623 correlated with necrosis and tissue degeneration. CONCLUSIONS: The early accumulation of H(2)O(2) and HRGPs indicates roles in defence whereas the late accumulation in genotype BTx623 correlated with successful pathogenesis. SIGNIFICANCE AND IMPACT OF THE STUDY: The fact that there is a significant correlation between induced accumulation of H(2)O(2), papilla formation and cell wall cross-linking, as evidenced by HRGP accumulation, and cessation of pathogen growth in resistant genotypes may help exploit host resistance in sorghum.

Molecular characterization of the oxalate oxidase involved in the response of barley to the powdery mildew fungus.

Previously we reported that oxalate oxidase activity increases in extracts of barley (Hordeum vulgare) leaves in response to the powdery mildew fungus (Blumeria [syn. Erysiphe] graminis f.sp. hordei) and proposed this as a source of H2O2 during plant-pathogen interactions. In this paper we show that the N terminus of the major pathogen-response oxalate oxidase has a high degree of sequence identity to previously characterized germin-like oxalate oxidases. Two cDNAs were isolated, pHvOxOa, which represents this major enzyme, and pHvOxOb', representing a closely related enzyme. Our data suggest the presence of only two oxalate oxidase genes in the barley genome, i.e. a gene encoding HvOxOa, which possibly exists in several copies, and a single-copy gene encoding HvOxOb. The use of 3' end gene-specific probes has allowed us to demonstrate that the HvOxOa transcript accumulates to 6 times the level of the HvOxOb transcript in response to the powdery mildew fungus. The transcripts were detected in both compatible and incompatible interactions with a similar accumulation pattern. The oxalate oxidase is found exclusively in the leaf mesophyll, where it is cell wall located. A model for a signal transduction pathway in which oxalate oxidase plays a central role is proposed for the regulation of the hypersensitive response.

Mechanisms of Induced Resistance in Barley Against Drechslera teres.

ABSTRACT Quantitative and qualitative histopathological methods and molecular analyses were used to study the mechanisms by which preinoculation with either of the nonbarley pathogens, Bipolaris maydis and Septoria nodorum, inhibited growth of Drechslera teres. Collectively, our data suggest that induced resistance is the principal mechanism responsible for impeding the pathogen. The enhancement of resistance in the host was primarily manifested during penetration by D. teres, and after penetration, where growth of D. teres ceased soon after development of infection vesicles. Thus, 24 h after pretreatment with B. maydis or S. nodorum, the penetration frequency from D. teres appressoria was reduced from 42.7% in the controls to 9.5 and 14.8%, respectively. The reductions were associated with increased formation of fluorescent papillae in induced cells (early defense reaction). The postpenetrational inhibition of D. teres completely stopped fungal growth and was apparently linked to an enhancement of multicellular hypersensitive responses in inducer-treated leaves (late defense reaction). Papillae formation and multicellular hypersensitive reactions were also observed in fully susceptible, noninduced control leaves, but they were inadequate to stop fungal progress. Northern blots from leaves treated with either inducer alone support the conclusion that induced resistance is involved in suppression of D. teres by increased formation of papillae and hypersensitive reactions. Thus, the blots showed strong expression of several defense response genes that are involved in these reactions in barley attacked by Erysiphe graminis f. sp. hordei.