Osmotic stress adaptation, compatible solutes accumulation and biocontrol efficacy of two potential biocontrol agents on Fusarium head blight in wheat

Fusarium head blight (FHB) caused by Gibberella zeae (anamorph = Fusarium graminearum) is a devastating disease that causes extensive yield and quality losses to wheat in humid and semi-humid regions of the world. Biological control has been demonstrated to be effective under laboratory conditions but a few biocontrol products have been effective under field conditions. The improvement in the physiological quality of biocontrol agents may improve survival under field conditions, and therefore, enhance biocontrol activity. Bacillus subtilis RC 218 and Brevibacillus sp. RC 263 were isolated from wheat anthers and showed significant effect on control of FHB under greenhouse assays. This study showed the effect of water availability measured as water activity (a_W) using a growth medium modified with NaCl, glycerol and glucose on: (i) osmotic stress tolerance, (ii) viability in modified liquid medium, (iii) quantitative intracellular accumulation of betaine and ectoine and (iv) the biocontrol efficacy of the physiologically improved agents. Viability of B. subtilis RC 218 in NaCl modified media was similar to the control. Brevibacillus sp. RC 263 showed a limited adaptation to growth in osmotic stress. Betaine was detected in high levels in modified cells but ectoine accumulation was similar to the control cells. Biocontrol activity was studied in greenhouse assays on wheat inoculated at anthesis period with F. graminearum RC 276. Treatments with modified bacteria reduced disease severity from 60% for the control to below 20%. The physiological improvement of biocontrol agents could be an effective strategy to enhance stress tolerance and biocontrol activity under fluctuating environmental conditions.     

Microencapsulation of Bacillus subtilis B99-2 and its biocontrol efficiency against Rhizoctonia solani in tomato

Biological control is a promising approach to protecting plants from disease. Bacillus subtilis has been widely used in agriculture for promoting plant growth and biocontrol. However, their short shelf life limits the application of biological pesticides. The objectives of this study were to develop a microencapsulation procedure of B. subtilis B99-2 using maltodextrin and gum arabic as wall materials to determine the optimum conditions of spray-drying in microencapsulation, evaluate storage stability of microcapsules, and assess their biocontrol efficiency against Rhizoctonia solani in tomato under field conditions. We microencapsulated the Bacillus thallus by spray-drying with various concentrations of the wall material. Maltodextrin was found to be an efficient wall material, especially at concentrations higher than 80%, while gum arabic did not affect the bacterial survival rate. The mean survival rate of B. subtilis was more than 90%, when spray drying was performed at 145 °C, with a feed flow rate of 550 mL h⁻¹, and a spray pressure of 0.15 MPa. B. subtilis microcapsule survival rate was 87.53% after 540 d of storage, which was a longer shelf life than that of wettable powders. Moreover, its biocontrol efficacy reached 79.91% when a dosage of 300 g hm⁻² was used, the microcapsule showed higher control efficacy than Thiram wettable powder against R. solani in tomato under field conditions. All these characteristics indicated that B. subtilis microcapsules have the potential to become a successful biocontrol product.     

Combined application of botanical formulations and biocontrol agents for the management of Fusarium oxysporum f. sp. cubense (Foc) causing Fusarium wilt in banana

Plant products along with biocontrol agents were tested against Fusarium wilt of banana caused by Fusarium oxysporum f. sp. cubense (Foc). Of the 22 plant species tested, the leaf extract of Datura metel (10%) showed complete inhibition of the mycelial growth of Foc. Two botanical fungicides, Wanis 20 EC and Damet 50 EC along with selected PGPR strains with known biocontrol activity, Pseudomonas fluorescens 1, Pf1 and Bacillus subtilis, TRC 54 were tested individually and in combination for the management of Fusarium wilt under greenhouse and field conditions. Combined application of botanical formulation and biocontrol agents (Wanis 20 EC + Pf1 + TRC 54) reduced the wilt incidence significantly under greenhouse (64%) and field conditions (75%). Reduction in disease incidence was positively correlated with the induction of defense-related enzymes peroxidase (PO) and polyphenol oxidase (PPO). Three antifungal compounds (two glycosides and one ester) in D. metel were separated and identified using TLC, RP-HPLC (Reverse Phase-High Pressure Liquid Chromatography) and mass spectrometry. In this study it is clear that combined application of botanical formulations and biocontrol agents can be very effective in the management of Fusarium wilt of banana.     

Comparison of the efficacy of chitosan with that of a fluorescent pseudomonad for the control of Fusarium head blight disease of cereals and associated mycotoxin contamination of grain

Fusarium culmorum can cause Fusarium head blight (FHB) disease of cereals, resulting in yield loss and contamination of grain with the trichothecene mycotoxin, deoxynivalenol (DON). In this study, we compared the efficacy of a biological control agent (Pseudomonas fluorescens strain MKB 158) with the biochemical chitosan (the deacetylated derivative of chitin) in controlling FHB disease of wheat and barley. Both agents were equally effective in reducing DON contamination of grain caused by F. culmorum. Under both glasshouse and field conditions, treatment with commercially available crabshell-derived chitosan reduced the severity of FHB symptom development on wheat and barley by ?74% (P ? 0.050). While treatment with P. fluorescens reduced the severity of FHB symptom development on these cereals by ?48% (P ? 0.050). Chitosan and P. fluorescens respectively prevented ?58 and ?35% of the FHB-associated reductions in 1000-grain weight in wheat and barley (P ? 0.050). Both agents significantly reduced the DON content of wheat and barley under both glasshouse and field conditions (P ? 0.050) and were equally efficacious in doing so (?74 and ?79% reductions due to chitosan and P. fluorescens, respectively). Crude chitin extracts from crabshells and crude chitosan-based formulations prepared from crabshells and eggshells were also tested under field conditions, but were not as effective as the commercial crabshell-derived preparation in controlling FHB disease. This is the first report on the use of chitosan for the control of Fusarium head blight disease and DON contamination of grain.     

Population dynamics of the Fusarium head blight biocontrol agent Cryptococcus flavescens OH 182.9 on wheat anthers and heads

Cryptococcus flavescens OH 182.9 (NRRL Y-30216) reduces Fusarium head blight (FHB) incited by Fusarium graminearum and deoxynivalenol (DON) contamination of grain. Yet little is known about the population dynamics of OH 182.9 on wheat heads and anthers. Biomass of OH 182.9 was produced in liquid culture and applied to greenhouse and field grown wheat prior to and during early anthesis. In greenhouse studies, populations of OH 182.9 were similar on anthers for heads inoculated before (Feekes 10.5) or early in flowering (Feekes 10.5.1) but were 1–3 log units lower in Feekes 10.5 inoculated wheat after 8–10 days. In greenhouse and field studies, OH 182.9 colonized anthers inside florets prior to anthesis. In the field, populations of OH 182.9 on anthers increased or, less frequently, remained stable through 12 days, regardless of application time and peaked at 1–2 log units higher than in the greenhouse. Strain OH 182.9 reduced FHB severity (P < 0.05, FPLSD) but not other disease parameters in the same field study. Application of OH 182.9 at split boot (Feekes 10.1) or Feekes 10.5.1 resulted in higher populations on spikelets treated at flowering on a CFU/g fresh weight tissue basis and as a percentage of the total recoverable microbial population in one of two field studies. Scanning electron microscopy revealed cells of OH 182.9 in microcolonies, groups of several cells and as individual cells, most frequently on the abaxial surfaces of glume and lemma tissues and near the apex of palea tissues. The survival of yeast OH 182.9 on anthers and wheat heads for 12 days and more suggests the strain has the potential to reduce late kernel infections by F. graminearum that can increase DON.     

Concentration and cultivar effects on efficacy of CLO-1 biofungicide in controlling Fusarium head blight of wheat

Fusarium head blight (FHB) is a destructive disease of wheat in Canada and Clonostachys rosea strain ACM941 has been identified as a promising biological control agent for managing FHB. In the present research the concentration and cultivar effects on the efficacy of CLO-1, a formulated product of C. rosea strain ACM941, in controlling FHB and deoxynivalenol (DON) contamination in wheat was studied. Of the eight concentrations ranging from 10⁴ to 10⁸ cfu mL⁻¹ evaluated, significant effects were generally observed for concentrations at or above 10⁶ cfu mL⁻¹ in the greenhouse and field trials in 2009 and 2010. In the greenhouse, CLO-1 reduced the area under the disease progress curve (AUDPC) by 65–83%, Fusarium damaged kernels (FDK) by 68–92%, and DON by 51–95%. Under field conditions, CLO-1 reduced FHB index by 30–46%, FDK by 31–39%, and DON by 22–33%. These effects were numerically lower but not significantly different from those of the registered fungicide Folicur® (tebuconazole) used in these trials. When applied onto wheat cultivars differing in resistance to FHB in field trials in 2009 and 2010, CLO-1 was most effective on the moderately resistant cultivar AC Nass (representing the highest level of resistance commercially available) and least effective on the highly susceptible cultivar AC Foremost. Results of this study suggest that CLO-1 is a promising biocontrol product that may be used in combination with cultivar resistance for managing FHB in wheat.     

小麦赤霉病拮抗菌JB7的拮抗活性及鉴定

由禾谷镰刀菌(Fusarium graminearum, Fg)引起的赤霉病是限制小麦生产的主要病害之一。生物防治是一种高效且可持续的防治方法。【目的】从小麦种子内筛选具有抑制禾谷镰刀菌的菌株并对其生防潜力进行评估,为小麦赤霉病生防制剂的开发与利用提供菌种资源及理论支撑。【方法】采用平板对峙、孢子萌发法和无菌上清液抑菌试验筛选小麦种子内对禾谷镰刀菌具有拮抗活性的内生菌株;利用扫描电镜(scanning electron microscope, SEM)和共聚焦扫描电镜(confocal laser scanning microscope, CLSM)观察并分析无菌上清液对Fg的分生孢子形态、膜完整性以及胞内活性氧的影响;通过盆栽试验验证内生菌对小麦赤霉病的生防效果;应用二代Illumina HiSeq测序平台进行全基因组测序。【结果】从小麦种子中分离出一株高效抑制Fg生长的内生菌株JB7,其衰亡期无菌上清液对Fg孢子萌发抑制率高达85.23%。菌株JB7的无菌上清液使Fg孢子表面凹陷,破坏其细胞膜,造成核酸和蛋白质的渗漏,诱导Fg菌丝活性氧的累积,引起Fg菌丝可溶性蛋白和丙二醛含量的显著升高。该菌株具有分泌蛋白酶、纤维素酶、葡聚糖酶和产铁载体的能力。盆栽试验表明菌株JB7能显著降低小麦赤霉病的病情指数(P<0.05)。经全基因组学鉴定为甲基营养型芽孢杆菌(Bacillus methylotrophicus) JB7,该菌株基因组中含有12个抑菌功能的次级代谢产物合成基因簇。【结论】菌株JB7能抑制禾谷镰刀菌的生长,对小麦赤霉病有较强的防效,可作为生物防治小麦赤霉病的候选菌株。     

Effect of light quality on Bacillus amyloliquefaciens JBC36 and its biocontrol efficacy

Light is one of the most important environmental signals regulating physiological processes of many microorganisms. However, very few studies have been reported on the qualitative or quantitative effects of light on control of postharvest spoilage using antagonistic bacteria. In this study, we investigated the effects of white, red, green, and blue light at photon flux densities of 40, 240, and 360 μmol m^?2 s^?1 on Bacillus amyloliquefaciens JBC36 (JBC36), which has been reported as a promising candidate for biocontrol of green and blue mold on mandarin fruit. With the exception of blue light at 240 and 360 μmol m^?2 s^?1, light generally stimulated growth of JBC36 compared to the controls grown in the dark. Red light increased swarming motility irrespective of intensity and significantly enhanced biofilm formation at 240 μmol m^?2 s^?1. Production of antifungal metabolites and antifungal activity on Penicillium digitatum was also affected by light quality. Interestingly, antifungal activity was significantly increased when JBC36 and P. digitatum was co-incubated under red and green light at an intensity of 240 μmol m^?2 s^?1. We also demonstrated that the quality of light resulted in changes in colonization of JBC36 on mandarin fruit and control of green mold. In particular, red light increased the population level on mandarin fruit and biocontrol efficacy against green mold. These results represent the first report on the effect of light quality on an antagonistic bacterium for the control of postharvest spoilage. We believe that an improved understanding of the JBC36 response to light quality may help in the development of strategies to increase biocontrol efficacy of postharvest spoilage.     

Evaluation of fluorescent pseudomonads for plant growth promotion,antifungal activity against Rhizoctonia solani on common bean,and biocontrol potential

Fluorescent pseudomonads are ubiquitous bacteria that are common inhabitants of the rhizosphere and are the most studied group within the genus Pseudomonas. Bacterial isolates (n = 103) from the rhizosphere of wheat and common bean were assessed as potential biocontrol agents in this study. Fungal inhibition tests were performed by a plate assay in which each isolate was tested directly for the production of hydrogen cyanide, protease, siderophore and cellulase. Production of DAPG was verified by using an analytical high performance liquid chromatography assay (HPLC). Plant growth promotion was assessed in phytochamber trials and biocontrol activity was evaluated in greenhouse trials. In all, 52 bacterial isolates with antifungal activity against Rhizoctonia solani were found. Of the 52 isolates, 41 were selected according to their high efficiency in in vitro antagonism, which was shown as inhibition zones in the dual-culture assay. Six of the 41 rhizobacteria, including isolates UTPF7, UTPF13, UTPF18, UTPF22, UTPF27 and strain CHA0 produced HCN. Production of protease enzyme was detected for all isolates excluding UTPF30 isolate. Although some stains appeared not to produce any compound with affinity for ferric iron, other isolates produced prolific amounts, creating a large zone of orange (up to 160 mm², i.e., UTPF16). Seventeen of 41 isolates of fluorescent pseudomonads including strain CHAO produced different amounts of DAPG ranging from 0.6 to 11.4 ng/10⁸ cfu. A total of 39 isolates induced statistically significant effects on plant growth compared with the non-treated control for at least one parameter. The predominant influence observed was increased root length. No bacteria could completely protect the plant against R. solani, although all isolates significantly increased fresh weight as compared to the infested control in greenhouse trials. Pseudomonas fluorescens isolates UTPF16 and UTPF26 significantly (P < 0.05) decreased the number of seedlings with damping-off symptoms in the means of the experiments.     

Evaluation of biocontrol agents and potassium silicate for the management of powdery mildew of zucchini

Investigations were conducted under greenhouse and field conditions to evaluate the effects of potential biocontrol agents (BCAs) and soluble silicon (Si) on powdery mildew of zucchini caused by Podosphaera xanthii. Five BCAs were applied as foliar sprays to zucchini leaves and Si was drenched weekly into the rhizosphere of these plants.In the greenhouse, all BCAs provided significant control of powdery mildew with fungal isolates, reducing disease levels by up to 90%. Si alone reduced powdery mildew by as much as 35% and improved the efficacy of most of the biocontrol agents. Higher disease pressure reduced the efficacy of Si on powdery mildew but did not affect the performance of the BCAs. In the field, a disease reduction of 10–70% was achieved by BCAs and Si. Lower temperatures and high humidity ranges were suitable for optimal performances. The efficacy of the bacterial BCA, Serratia marcescens – B15 and silicon diminished at temperatures above 25 °C. The fungal BCAs (Clonostachys rosea – EH and Trichothecium roseum – H20) were better suited to higher temperatures (25–30 °C) and were tolerant of low RH values. Application of K₂SiO₂ to zucchini roots increased the level of Si in the leaves, which was responsible for suppression of the disease.     

Production of the postharvest biocontrol agent Bacillus subtilis CPA-8 using low cost commercial products and by-products

The aim of this research was to identify a low cost medium based on commercial products and by-products that provided maximum Bacillus subtilis CPA-8 growth and maintained biocontrol efficacy. Low cost media combining economical nitrogen and carbon sources such as yeast extract, peptone, soy products, sucrose, maltose and molasses were tested. Tests were carried out in 250-ml flasks containing 50 ml of each tested medium. Maximum cell growth (>3 × 10⁹ CFU ml^?1) was obtained in defatted soy flour 44% combined with sucrose or molasses media. Second, CPA-8 production was scaled up in a 5-l fermenter and CPA-8 population dynamics, pH and oxygen consumption in the optimized medium (defatted soy flour 44% – molasses) was recorded. In these tests, there was a 5-h lag phase before growth, after which exponential growth occurred and maximum production was 3 × 10⁹ CFU ml^?1 after 20 h. Fruit trials with cells and cell free supernatants from CPA-8 grown in optimized medium maintained biocontrol efficacy against Monilinia fructicola on peaches, resulting in disease reductions up to 95%. CPA-8 populations survived in wounds on inoculated peaches, regardless of the culture media used. The results show that B. subtilis CPA-8 can be produced in a low cost medium combining inexpensive nitrogen and carbon sources (40 g l^?1 defatted soy flour 44%, 5 g l^?1 molasses plus mineral trace supplements) in shake flasks and a laboratory fermenter (5 l). The results could be used to provide a reliable basis for scaling up the fermentation process to an industrial level.     

Isolation,identification of sludge-lysing strain and its utilization in thermophilic aerobic digestion for waste activated sludge

A strain of sludge-lysing bacteria was isolated from waste activated sludge (WAS) in this study. The result of 16S rRNA gene analysis demonstrated that it was a species of new genus Brevibacillus (named Brevibacillus sp. KH3). The strain could release the protease with molecule weight of about 40 kDa which could enhance the efficiency of sludge thermophilic aerobic digestion. During the sterilized sludge digestion experiment inoculated with Brevibacillus sp. KH3, the maximum protease activity was 0.41 U/ml at pH 8 and 50 °C, and maximum TSS removal ratio achieved 32.8% after 120 h digestion at pH 8 and 50 °C. In the case of un-sterilized sludge digestion inoculated with Brevibacillus sp. KH3, TSS removal ratio in inoculated-group was 54.8%, increasing at 11.86% compared with un-inoculation (46.2%). The result demonstrated that inoculation of Brevibacillus sp. KH3 could help to degrade the EPS and promote the collapse of cells and inhibit the growth of certain kinds of microorganisms. It indicated that Brevibacillus sp. KH3 strain had a high potential to enhance WAS-degradation efficiency in thermophilic aerobic digestion.     

Efficacy of Bacillus subtilis and Trichoderma asperellum against Pythium aphanidermatum in tomatoes

Seedling damping-off disease caused by Pythium aphanidermatum is the most important seedling disease in tomato production in Kenya. The disease causes seedling losses of up to 30%. Greenhouse trials were conducted to evaluate the application of Bacillus subtilis and Trichoderma asperellum, as seed coating for management of damping-off in tomato from April 2011 to August 2014. Tomato seeds (var. Rio Grande) were coated with either B. subtilis or T. asperellum at a concentration of 10⁶ CFU/ml. The interaction between the two biocontrol agents and NPK fertilizer was assessed. To simulate the effect of high disease pressure, the coated seeds were planted in P. aphanidermatum inoculated media. The post-emergence seedling damping-off on seeds coated with B. subtilis and T. asperellum was 20.19% and 24.07% respectively while the control (non-coated) had 65.89% seedling mortality. A combination of NPK fertilizer and biocontrols in seedling management resulted to a significantly higher dry mass compared to the use of either biocontrol agent or fertilizer alone (P ⩽ 0.001). This study indicates that coating of tomato seeds with B. subtilis and T. asperellum may be useful in the management of damping-off disease.     

Evaluation of biological seed treatments in combination with management practices for the control of Fusarium dry rot of potato

Seed-borne diseases of potato represent a significant constraint to potato production in the US. The use of an effective fungicide in combination with good management practices during cutting and storage, prior to planting, is essential to reducing disease. The efficacy of two biocontrol agents (Bacillus subtilis and Trichoderma harzianum), and a commercially formulated mixture of the chemicals fludioxonil plus mancozeb, applied as seed treatments in combination with different management practices, were evaluated over two years for the control of seed piece decay and sprout rot caused by Fusarium sambucinum. Treatments were made 10 days prior to planting and at planting, and tubers were re-stored at either 18 °C and 95% RH with forced air ventilation at 5950 l min⁻¹ (optimal conditions), at 25 °C in the dark without ventilation (sub-optimal), or not stored at all prior to planting. Seed piece and sprout health were evaluated in vitro and agronomic impacts evaluated in field experiments. Results showed that the biological control agents B. subtilis and T. harzianum provided good control of sprout rot and seed piece decay caused by F. sambucinum, when seed was re-stored under optimal conditions or not re-stored at all. Under optimal conditions, treatment with B. subtilis reduced sprout rot and seed piece decay on average by 66% and 84%, respectively. Treatment with T. harzianum reduced sprout rot and seed piece decay on average by 70% and 81%, respectively. Treatment with fludioxonil + mancozeb reduced sprout rot and seed piece decay under both re-storage regimes. Under optimal conditions, disease incidence and severity was reduced on average by 81% and 97%, respectively. Neither biological control agent reduced seed piece decay incidence under either re-storage regime compared to the untreated controls.     

Spatial distribution and antifungal interactions of a Bacillus biological control agent on wheat surfaces

The proximity of a biological control agent and its associated anti-microbial metabolites to pathogens on plant surfaces can determine the outcome of disease control. In this study we investigated whether deficiencies in inoculum deposition and localization could explain the inability of the biological control agent Bacillus amyloliquefaciens strain TrigoCor to consistently control Fusarium head blight in the field, despite producing effective and consistent disease control in greenhouse settings. Using epifluorescent stereomicroscopy and confocal laser scanning microscopy, we visualized the coverage of wheat spike surfaces by Bacillus post-application in greenhouse and field environments, and determined that there are large unprotected areas on wheat spikes sprayed with commercial-scale field equipment, as compared to typical greenhouse applications. Additionally, we found that in conditions of low relative humidity, antifungal compounds produced by Bacillus were not able to diffuse across wheat surfaces in biologically relevant amounts, further suggesting that the inadequate coverage of wheat surfaces by Bacillus could be directly limiting disease control. Bacillus cells were easily rinsed off wheat surfaces within 8 h of application, indicating that rainfastness might be an additional limitation of biological control in field settings. Finally, we observed the inhibition of Fusarium graminearum spore germination by TrigoCor inoculum on wheat surfaces, confirming this as a mode of action for TrigoCor biocontrol. Future optimization efforts for biological control agents applied to above-ground plant parts should focus on enhancing the rainfastness, quantity, and spatial coverage of the inoculum on plant surfaces.     

Dry flowable formulations of antagonistic Bacillus subtilis strain T429 by spray drying to control rice blast disease

Dry flowable formulations of Bacillus subtilis strain T429 with fungicidal activity against the rice blast fungus Magnaporthe grisea were synthesized by spray drying. Inert ingredients including wetting agents, dispersants, disintegrants, and adhesives that show good biocompatibility with B. subtilis T429 were obtained. The formulations were optimized by a four-factor and three-level orthogonal experiment. The optimal contents of the wetting agent AEO-5, dispersant NNO, disintegrant (NH₄)₂SO₄, and adhesive CMC-Na were 1%, 9%, 5%, and 1% respectively, the filler kaolinite supplemented to 100%. The mixture was suspended in the fermentation broth of T429 at a ratio of 20% (m/v). After being ground in a ball mill for 3 h, the suspension was spray-dried, and the dry flowable formulations were obtained. The formulation showed good physical characteristics, such as high dispersibility and viability. After 12 months of storage at room temperature, it revealed long shelf life and high viability. Field tests in rice crops illustrated that dry flowable formulations at 50 and 75 g/667 m² concentrations were as effective as a commercial fungicide in controlling rice blast, control efficiency up to 77.6% and 78.5%, respectively. No significant differences in disease control efficiency were observed between the formulations and the chemical pesticide tricyclazole (79.5%). Overall, a new shelf-stable and effective dry flowable formulation of the biocontrol agent B. subtilis T429 was obtained by spray drying to control rice blast.     

Enrichment,isolation, and characterization of phenol-degrading Pseudomonas resinovorans strain P-1 and Brevibacillus sp. strain P-6

The objectives of this research were to isolate pure phenol-degrading strains from enriched mixed cultures, monitoring the variations of species during the enrichment period. Two strains were isolated from the acclimated mixed culture. They were identified as Pseudomonas resinovorans strain P-1 and Brevibacillus sp. strain P-6. DGGE indicated that strain P. resinovorans appeared at the beginning, and maintained well during the enrichment period. The second strain, Brevibacillus sp., did not appear in the initial stage, but showed up after 2 weeks of enrichment. The optimum growth temperatures for P. resinovorans and Brevibacillus sp. were 31 and 39 °C, respectively. P. resinovorans could degrade phenol completely within 57.5 h, when the initial phenol concentration was lower than 600 mg l⁻¹. If the initial phenol concentration was lower than 200 mg l⁻¹, Brevibacillus sp. could remove phenol completely within 93.1 h. It was obvious that the phenol-degrading ability of P. resinovorans was much better than that of Brevibacillus sp. The metabolic pathway for P. resinovorans phenol degradation was assigned to the meta-cleavage activity of catechol 2,3-dioxygenase.     

Investigation of the effect of nitrogen on severity of Fusarium Head Blight in barley

The effect of nitrogen on Fusarium Head Blight (FHB) in a susceptible barley cultivar was investigated using gel-based proteomics. Barley grown with either 15 or 100 kg ha^? 1 N fertilizer was inoculated with Fusarium graminearum (Fg). The storage protein fraction did not change significantly in response either to N level or Fg, whereas eighty protein spots in the water-soluble albumin fraction increased and 108 spots decreased more than two-fold in intensity in response to Fg. Spots with greater intensity in infected plants contained fungal proteins (9 spots) and proteolytic fragments of plant proteins (65 spots). Identified fungal proteins included two superoxide dismutases, l-xylulose reductase in two spots, peptidyl prolyl cis–trans isomerase and triosephosphate isomerase, and proteins of unknown function. Spots decreasing in intensity in response to Fg contained plant proteins possibly degraded by fungal proteases. Greater spot volume changes occurred in response to Fg in plants grown with low nitrogen, although proteomes of uninfected plants were similar for both treatments. Correlation of proteome changes with measurement of Fusarium-damaged kernels, fungal biomass and mycotoxin levels indicated that increased Fusarium infection occurred in barley with low N and suggests control of N fertilization as a possible way to minimise FHB in barley.     

Soil microbial biomass influence on growth and biocontrol efficacy of Trichoderma harzianum

Hyphal growth and biocontrol efficacy of Trichoderma harzianum may depend on its interactions with biotic components of the soil environment. Effects of soil microbial biomass on growth and biocontrol efficacy of the green fluorescent protein transformant T. harzianum ThzID1-M3 were investigated using different levels of soil microbial biomass (153, 328, or 517 μg biomass carbon/g of dry soil). Hyphal growth of T. harzianum was significantly inhibited in soil containing 328 or 517 μg biomass carbon/g of dry soil compared with soil containing 153 μg biomass carbon/g. However, when ThzID1-M3 was added to soil as an alginate pellet formulation, recoverable populations of ThzID1-M3 varied, with the highest populations in soil containing 517 μg biomass carbon/g. When sclerotia of Sclerotinia sclerotiorum were added to soils (10 sclerotia per 150 g soil) with ThzID1-M3 (20 pellets per 150 g soil), colonization of sclerotia by ThzID1-M3 was significantly lower in the soil containing the highest level of biomass. Addition of alginate pellets of ThzID1-M3 to soils (10 pellets per 50 g) resulted in increased indigenous microbial populations (total fungi, bacteria, fluorescent Pseudomonas spp., and actinomycetes). Our results suggest that higher levels of microbial soil biomass result in increased interactions between introduced T. harzianum and soil microorganisms, and further that microbial competition in soil favors a shift from hyphal growth to sporulation in T. harzianum, potentially reducing its biocontrol efficacy.