Extruded Granular Formulation with Biomass of Biocontrol Gliocladium virens and Trichoderma spp. to Reduce Damping-off of Eggplant Caused by Rhizoctonia solani and Saprophytic Growth of the Pathogen in Soil-less Mix

Extruded granular formulations containing rice flour, gluten, Pyrax, vermiculite, canola oil, and fermentor-produced biomass of isolates of Gliocladium virens (Gl-3, Gl-21 and Gl-32), Trichoderma hamatum (TRI-4 and 31-3), T. harzianum (Th-32 and Th-87) and T. viride (Tv-101) were evaluated for their effect on the reduction of eggplant damping-off caused by Rhizoctonia solani, reduction of pathogen inoculum and proliferation of the isolates in a soil-less mix. Granules with all isolates except 31-3 significantly (P < 0.01) reduced damping-off, and granules with Gl-3, Gl-21, Gl-32, TRI-4 and Th-87 yielded stands comparable to that (90%) of the non-infested control. Granules with isolates Gl-21 and TRI-4 were the most effective in the reduction of saprophytic growth of R. solani, and there was a significant inverse correlation (r ² = - 0.82) between eggplant stand and saprophytic growth of the pathogen over all treatments. Isolate propagules proliferated to about 10⁷ colony-forming units (CFU) g^?1 of soil-less mix after a 6-week incubation, but there was no correlation between the number of CFU and eggplant stand or saprophytic growth reduction of the pathogen. Granules with Gl-21 and TRI-4 amended to pathogen-infested soil-less mix at a rate as low as 0.06% significantly (P < 0.05) reduced damping-off and pathogen saprophytic growth, and a rate of 0.25% of Gl-21 granules resulted in an eggplant stand comparable to that of the non-infested control. There was no significant correlation between the rate of granule amendment and the proliferation of Gl-21 and TRI-4. Granules of Gl-21 and TRI-4 also significantly prevented the spread of R. solani in flats of eggplant seedlings when the biocontrol granules were applied to the soil-less mix 1 day before the pathogen inoculum.     

Interactions of Gliocladium virens with Rhizoctonia solani and Pythium ultimum in Non-sterile Potting Medium

Interactions of Gliocladium virens with Pythium ultimum and Rhizoctonia solani under simulated in vivo conditions were observed microscopically. Different types of propagules of the three fungi were paired on nitrocellulose membranes and incubated at 25°C in non-sterile potting medium in Petri dishes for 1-5 days. Alginate-wheat bran prill were used as carriers for G. virens. Prill inoculated with G. virens and pre-incubated in potting medium for 3-5 days before placement on membranes did not inhibit the germination of Pythium sporangia, but subsequent Pythium growth was markedly stunted and distorted, with some hyphal collapse and cytoplasmic leakage. G. virens had no visible effect on older Pythium mycelium. Two to 5 days' growth of G. virens caused cytoplasmic leakage of Rhizoctonia mycelium, prevented secondary branching of hyphae and occasionally coiled around Rhizoctonia hyphae. Prill that were newly colonized by G. virens, but not prill pre-incubated for 3 or 5 days, stimulated the growth of Pythium mycelium and sporangia, Rhizoctonia mycelium and unprimed monilioid cells, probably by supplying nutrients. The timing of the interactions and their specificity for the different pathogen propagules were consistent with the production of gliotoxin by G. virens. This view was supported by in vitro experiments, in which pathogen propagules were incubated in a range of concentrations of gliotoxin in potato dextrose broth. Pythium sporangia and mycelium were inhibited by 1 or 2 μmg ml^-1, but Rhizoctonia monilioid cells and mycelium required 3-5 μmg ml^-1 for inhibition. At the lowest effective concentrations the inhibition was sometimes reversible, but propagules were killed at high concentrations of gliotoxin.     

Biocontrol of Damping-off Diseases Caused by Rhizoctonia solani and Pythium ultimum with Alginate Prills of Gliocladium virens, Trichoderma hamatum and Various Food Bases

Alginate prills were formulated with the biomass of isolates of Gliocladium virens and Trichoderma spp. and various food bases (wheat bran, corn cobs, peanut hulls, soy fiber, castor pomace, cocoa hulls and chitin). Alginate prills with G. virens (Gl-21) biomass and all food bases except cocoa hull meal significantly reduced the damping-off of zinnia in a soil-less mix caused by Rhizoctonia solani and Pythium ultimum. The prills with bran, soy fiber, castor pomace or chitin resulted in stands similar to those in the non-infested control. In soil, prills with all the food bases and Thrichoderma hamatum (TRI-4) biomass controlled the damping-off of cotton caused by R. solani and gave stands comparable to, or better than, those in the non-infested control soil. Prills with all the food bases resulted in a proliferation of Gl-21 in a soil-less mix and of Gl-21 and TRI-4 in soil. Prills with food bases and TRI-4 biomass reduced the survival of R. solani in infested beet seed to less than 30%, with bran and chitin being the most effective food bases; prills with Gl-21 biomass and all food bases also reduced the survival of R. solani in beet seed, but not as much as did prills with TRI-4 biomass. In prills containing wheat bran, soy fiber or chitin, the biocontrol isolate Th-58 (T. harzianum) was almost as effective as TRI-4, but isolate Gl-3 (G. virens) was less effective. There was no significant interaction between the biocontrol fungus and the food base. The results suggest that the intrinsic properties of a selected fungus isolate are more important than some formulation variables in biocontrol.     

Field efficacy of insect pathogen,botanical, and jasmonic acid for the management of wheat midge Sitodiplosis mosellana and the impact on adult parasitoid Macroglenes penetrans populations in spring wheat

The wheat midge, Sitodiplosis mosellana, is a serious pest of wheat worldwide. In North America, management of S. mosellana in spring wheat relies on the timely application of pesticides, based on midge adults levels caught in pheromone traps or seen via field scouting during wheat heading. In this context, biopesticides can be an effective alternative to pesticides for controlling S. mosellana within an Integrated Pest Management program. A field study using insect pathogenic fungus Beauveria bassiana GHA, nematode Steinernema Jeltiae with Barricade polymer gel 1%, pyrethrin, combined formulations of B. bassiana GHA and pyrethrin, Jasmonic acid (JA) and chlorpyrifos (chemical check) was performed to determine to which extent they affect midge larval populations, kernel damage levels, grain yield, and quality, and the impacts on adult parasitoid Macroglenes penetrans populations. The results indicated that biopesticides JA and S. Jeltiae were the most effective in reducing larval populations and kernel damage levels, and produced a higher spring wheat yield when compared to the water control at both study locations (East Valier and North Valier, Montana, USA). Increased test weight in wheat had been recorded with two previous biopesticides at East Valier but not for North Valier, when compared over water control. These results were comparable in efficacy to the chlorpyrifos. This study also suggested that B. bassiana and pyrethrin may work synergistically, as exemplified by lower total larval populations and kernel damage levels when applied together. This study did not demonstrate the effect of any treatments on M. penetrans populations.