Tetranychus urticae and Myzus persicae are one of the most serious insect pests in many crops, vegetables, flowers, and fruit trees worldwide. Many insecticides have been developed to control green peach aphid and two spotted spider mite, but resistance to almost all insecticides has reduced their control effect. Particular groups of plant-beneficial microbials are not only root colonizers that provide plant disease suppression, but in addition are able to infect and kill insect larvae. Antimicrobial compounds produced by biocontrol microbes are effective weapons against a vast diversity of organisms such as fungi, nematodes, and viruses. In this study, we evaluated the effectiveness of mixtures plant extracts and improvement of culture process biocontrol microbials on insecticidal activity. Azadirachta indica and Derris elliptica mixed with micorbials, which are nutrient sources of mung bean extract and lecithin, were more effective than other the mixtures. Leaf spraying with the mixture of Pseudomonas fluorescens significantly showed the highest insecticidal power in vivo for 24 hours after treatment. The effect of spraying mixture was more than 50% at 2000 times dilution, and the spraying concentration of 90% or more showed a dilution of up to 500 times. Our results indicated that the nutrient sources of microbe act as a key antimicrobial metabolite in biocontrol of insect pests, and mixing with plant extracts can provide synergistic effects as an optimal usage of the biocontrol agents.

Effectiveness of Beauveria bassiana ERL as entomopathogenic fungi against thrips pupae were evaluated on greenhouse cucumber(bumnong backdadagi), rose(Affinity) respectively. Control efficacy was calculated by the formula, (Dcontrol - Dtreatment)/Dcontrol x 100, where Dcontrol is the average density of thrips on the plots in which any pesticides and entomopathogenic fungi was not relesed and Dtreatment is the average density of thrips on the plots in which entomopathogenic fungi were released respectively. As a result, control efficacies of Beauveria bassiana ERL 10^7 cfu/g treatment against thrips on cucumber was 89.4~91.3%, respectively. In addition, control efficacy of Beauveria bassiana ERL 10^8 treatment against thrips on cucumber was 92.0~93.2%. Also, control efficacies of Beauveria bassiana ERL treatment against thrips on cucumber was 61.5-69.2%. Thus, even thrips control flow that occurs in the solanaceae vegetables thrips current period is officially Beauveria bassiana ERL 10 ^ 7 to effective treatment cfu / g, pepper and tomato cucumber and rose to occur will be effective. These results demonstrate the promise of entomopathogenic fungi, especially Beauveria bassiana ERL for management of thrips pupae. In addition to thrips control that is occurring in the solanaceae vegetables such as peppers and tomatoes will be effective.

The pursuit of fungal biocontrol agents is a complex process but there can be no doubt that the process of finding an optimal isolate for a particular target needs to draw on a large-scale program to assess many candidate cultures. The supply of such cultures is facilitated by the existence of so enormous, comprehensive and accessible source of germplasm as exists in the USDA-ARS Collection of Entomopathogenic Fungal Cultures (ARSEF). This collection includes more than 13,000 isolates of more than 710 fungal taxa from 1,300 hosts and substrates from 2,440 locations. The global dependence on very few entomopathogenic fungal species–most notably, species of Beauveria and Metarhizium–is understandable within regulatory and commercial constraints, but might actually represent an undesirable and unhealthy degree of stability in the realm of fungal biocontrol of insect pests. deserves to be reconsidered by broadening the spectrum of highly specific pathogens and the means by which they might be applied. Unfortunately, a recent change in the rules of nomenclature applicable to such pleomorphic fungi as Beauveria, Metarhizium, Isaria, and the numerous other entomopathogens of the ascomycete order Hypocreales have not contributed to stability or certainty in how–and, indeed, which–names of fungal genera are to be applied. Some of the effects of the changes that became effective on 1 January 2012 will be discussed. Many familiar names of entomopathogenic fungi are necessarily changing under these new rules, but the choices of which names much be used and which must be discontinued may not be definitively stabilized until 2023 (at the next International Botanical Congress after the 2017 Congress in Shenzhen, China).