Beauveria bassiana is a promising candidate for the biocontrol of many important insect pests. The cuticle is the site of attachment of fungal spores after invading the host body. Cuticle-degrading enzymes (CDE) are a set of enzymes possessed by entomopathogenic fungi that ensure successful penetration. The current study indicated the extraction of crude cuticle-degrading enzymes from B. bassiana, as a mixture of mycelium and CDE, offers enhanced pathogenicity to its host. Tris-HCL, calcium chloride, potassium hydrogen phosphate, sodium phosphate, magnesium sulfate, zinc chloride, and olive oil were mixed in a 50 ml Erlenmeyer flask to extract CDE from the lab strain of B. bassiana. After centrifugation of the mixture, the supernatant was separated as extracellular enzymes. The media was subjected to SDS-PAGE analysis for enzyme characterization. Stacking gel (4%) and resolving gel (12%) were used with a pH of 8.6 to determine the molecular masses of the samples (enzymes) in kDa. The results showed that after staining and de-staining the gel, different bands of various sizes appeared. When compared with a standard key, the bands were found at 19, 50, 25, 32, and 34.25 kDa, confirming the presence of proteases, lipases, and chitinase, respectively. The extracted CDE can be used with different combinations of mycelial medium of B. bassiana or other entomopathogenic fungi to enhance their pathogenicity against insect pests. The extracted crude enzymes were used against larvae, pupae, and adults at concentrations of 5, 10, 15, 20, and 25µl. The mortality rate in larvae and adults was recorded as 78.50±2.10% and 80±2.15% at 25µl/ml, respectively. At lower concentrations (5µl/ml), the mortality was 13.33±1.92%, followed by the control group. A low percentage of adult emergence (10±2.63%) from pupae was observed in treated insects, and a higher adult emergence (65.0±5.77%) was observed in the untreated group of insects. The results showed that mortality and adult emergence from pupae were concentration-dependent. Therefore, adding CDE to the mycelium of B. bassiana enhanced its pathogenicity against different life stages of Bactrocera dorsalis.

Beauveria bassiana; Pathogenicity; Bactrocera dorsalis; Enzyme characterization; Insect biocontrol

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