John E. Sherwood

Wheat Puroindolines Enhance Fungal Disease Resistance in Transgenic Rice

Antimicrobial peptides play a role in the immune systems of animals and plants by limiting pathogen infection and growth. The puroindolines, endosperm-specific proteins involved in wheat seed hardness, are small proteins reported to have in vitro antimicrobial properties. Rice, the most widely used cereal crop worldwide, normally does not contain puroindolines. Transgenic rice plants that constitutively express the puroindoline genes pinA and/or pinB throughout the plants were produced. PIN extracts of leaves from the transgenic plants reduced in vitro growth of Magnaporthe grisea and Rhizoctonia solani, two major fungal pathogens of rice, by 35 to 50%. Transgenic rice expressing pinA and/or pinB showed significantly increased tolerance to M. grisea (rice blast), with a 29 to 54% reduction in symptoms, and R. solani (sheath blight), with an 11 to 22% reduction in symptoms. Puroindolines are effective in vivo in antifungal proteins and could be valuable new tools in the control of a wide range of fungal pathogens of crop plants.

Oxidative burst elicited by Bacillus mycoides isolate Bac J, a biological control agent, occurs independently of hypersensitive cell death in sugar beet.

Response of sugar beet cultivars C40 and USH11 to syringe infiltration of live and dead Bacillus mycoides isolate Bac J, a biological control agent, and virulent and avirulent isolates of Erwinia carotovora pv. betavasculorum was measured by monitoring systemic acquired resistance control of Cercospora beticola, specific activity of chitinase and beta-glucanase, the oxidative burst, and hypersensitive cell death at the infiltration site. Priming sugar beet with B. mycoides Bac J (1 x 10(8) cells/ml) and avirulent isolates of E. carotovora pv. betavasculorum (1 x 10(6) cells/ml) reduced C. beticola symptoms by nearly 70% on distal, untreated leaves. Systemic resistance responses elicited by live B. mycoides Bac J and avirulent E. carotovora pv. betavasculorum isolates, measured by assays for chitinase and beta-glucanase, were statistically equivalent, and biphasic hydrogen peroxide production was observed. Although similar in timing, the second hydrogen peroxide burst was twofold lower for B. mycoides Bac J than for avirulent E. carotovora pv. betavasculorum. Hypersensitive cell death was elicited by avirulent E. carotovora pv. betavasculorum but not B. mycoides Bac J. An oxidative burst was elicited by spray-applied B. mycoides Bac J under both light and green light conditions, indicating that the signal produced by B. mycoides Bac J was not reliant on the stomata for entry into sugar beet. A working model for signal delivery and systemic resistance induction by B. mycoides Bac J in sugar beet is proposed.

Polymerase chain reaction detection of Ustilago hordei in leaves of susceptible and resistant barley varieties.

ABSTRACT Although Ustilago hordei infects barley seedlings, symptoms of the disease covered smut are not visible until heading. Natural or artificial inoculation usually results in inconsistent infection, even in highly susceptible lines. Thus, breeding for resistance to covered smut is time consuming and difficult. The ribosomal DNA internal transcribed spacer (ITS) regions of U. hordei were sequenced and a primer pair was developed for polymerase chain reaction (PCR). These primers amplified a 574-bp fragment from DNA of Ustilago spp., but did not amplify DNA from barley or other common barley pathogens. DNA extracted from as few as four U. hordei sporidia was detected by this method. U. hordei DNA was amplified from leaf tissue of inoculated susceptible and resistant plants at different stages of plant development in differential varieties. Growth of the fungus in different leaves of an individual plant was variable. Several highly resistant varieties were shown to contain U. hordei DNA in the first three to four leaves, but not in later leaves. Thus, although the fungus can infect many resistant plants, the plants remain symptomless. Detection of U. hordei prior to heading should assist efforts for breeding for resistance and provide clues concerning the mechanisms of resistance employed by different resistance genes.

Puroindolines: their role in grain hardness and plant defence.

The puroindolines are unique tryptophan-rich proteins found only in the Triticeae. There are just two proteins known as puroindolines, puroindoline a and b (Gautier et al., 1994). Puroindoline A (PINA) and B (PINB) are small, cysteine rich, and hydrophobic endosperm-specific proteins that are involved in two major roles. These roles are wheat functionality and end use properties (reviewed in Morris, 2002), and seed defence against fungal pathogens. The puroindolines are important in affecting wheat end use properties because of their control of wheat grain hardness. Wheat grain hardness is an important grain trait as it affects nearly all end product quality traits. The puroindolines have also been demonstrated to have potent antifungal properties. Both of the major roles of puroindolines have been demonstrated via a combination of genetic research and plant genetic engineering, and are the subject of this review.

Molecular analysis of the pheromone and pheromone receptor genes of Ustilago hordei.

Cell-cell signaling is an integral part of the sexual and disease cycles of the smut fungi, which must mate to be pathogenic. This study reports the cloning and characterization of the pheromone genes Uhmfa1 and Uhmfa2 from MAT-1 and MAT-2 mating types of U. hordei, respectively, and the pheromone receptor gene Uhpra2 from MAT-2 cells. Similar to other fungal pheromone genes, Uhmfa1 and Uhmfa2 encode precursor peptides. Uhpra2 encodes a protein with sequence similarity to the 7-transmembrane class of G-protein coupled receptors. Deletion of Uhmfa1 and Uhpra1, and their subsequent replacement, confirmed the role of these genes in initiation of the sexual cycle. Uhmfa1 and Uhmfa2 were differentially expressed in various cell types and when opposite mating-type cells were grown together. The predicted mature pheromones of each mating type were synthesized, and each specifically induced conjugation tube formation in cells of the opposite mating type.

Pulsed-field gel electrophoresis fingerprinting for identification of Azospirillum species

Pulsed-field gel electrophoresis (PFGE) was used to obtain macrorestriction fingerprints of restriction enzyme-cut DNA of natural isolates of Azospirillum spp. Metabolic profiles, along with other phenotypic characteristics, were compared with these fingerprints to differentiate among the azospirilla isolates. A wide diversity of phenotypes (e.g., colony color, motility, and accumulation of poly-β-hydroxybutyrate granules) was observed among the natural isolates of azospirilla. PFGE revealed that TCTAGA, the sequence recognized by Xba1, is rare in the genome of azospirilla. The PFGE fingerprint revealed that azospirilla associated with different crops have a very similar genetic background. PFGE fingerprints were more consistent in the identification of azospirilla isolates from specific hosts than the metabolic fingerprints. For further differentiation at strain level, metabolic, physiological, and morphological profiles provide additional information.

Pheromone-Related Inhibitors of Ustilago hordei Mating and Tilletia tritici Teliospore Germination.

ABSTRACT Ustilago hordei, the causal agent of barley covered smut, produces mating pheromones that break down to smaller peptide compounds that act as potent inhibitors of mating and germination in several fungi. The pheromones are members of the farnesylated family of proteins. Synthetic peptide analogs of the pheromone derivatives, ranging in size from 4 mers to full length pheromones, were farnesylated, methyl esterified, or both and tested for mating or teliospore germination inhibition with U. hordei or Tilletia tritici, respectively. N-Acetyl-S-farnesylcysteine, which inhibits processing of Ras, and other sulfur-containing compounds such as homocysteine or methionine, were likewise modified and tested. The most potent inhibitors were methionine methyl ester and modified 4-mer peptides from both pheromones. Alanine scanning of the inhibitory 4 mers determined that the native amino acid sequence was specific for a high level of activity. The sulfur amino acids appear to be required for inhibition. Glasshouse studies using selected antagonists of mating and teliospore germination as seed treatments inhibited covered smut of barley and common bunt of wheat, although the level of control was inconsistent. The use of pheromone-related antagonists to mating or teliospore germination is a promising, novel strategy for control of smut and bunt diseases.