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The biotic factors that affect crop productivity are mainly pathogenic agents and pests. Several insect pests cause 15% to 35% of agricultural crop loss and affect economic sustainability practices1. Insects belonging to the orders Coleoptera, Hemiptera, and Lepidoptera are the major orders of devastating pests. The highly adaptive nature of the environment has benefited lepidopterans in evolving several survival mechanisms. Amongst lepidopteran insects, Helicoverpa armigera (Cotton bollworm) can feed on around 180 different crops and cause significant damage to their reproductive tissues2. Worldwide, H. armigera infestation has resulted in a loss of around $5 billion3. Cotton, chickpeas, pigeon peas, tomatoes, sunflowers, and other crops are hosts for H. armigera. It completes its lifecycle on different parts of host plants. Eggs laid by female moths get hatched on the leaves, followed by their feeding on vegetative tissues during larval stages. The larval stage is the most destructive due to its voracious and highly adaptable nature4,5. H. armigera shows a global distribution and encroachment to new territories due to its remarkable attributes, such as polyphagy, excellent migratory abilities, higher fecundity, strong diapause, and the emergence of resistance to existing insect control strategies6.
Diverse chemical molecules from terpenes, flavonoids, alkaloids, polyphenols, cyanogenic glucosides, and many others are widely used for the control of H. armigera infestation7. However, frequent application of chemical molecules imparts adverse effects on the environment and human health due to the acquisition of their residues. Also, they show a detrimental effect on various pest predators, resulting in an ecological imbalance8,9. Therefore, there is a necessity to investigate safe and eco-friendly options for chemical molecules of pest control.
Natural insecticidal molecules produced by plants (phytochemicals) can be used as a promising alternative to chemical pesticides. These phytochemicals include various secondary metabolites belonging to the classes alkaloids, terpenoids, and phenolics7,10. Quercetin is one of the most abundant flavonoids (phenolic compound) present in various grains, vegetables, fruits, and leaves. It shows feeding deterrent and insecticidal activity against insects; also, it is not harmful to natural enemies of pests11,12. Thus, this protocol demonstrates the feeding assay using quercetin to assess its toxic effect on H. armigera.
Various bioassay methods have been developed to evaluate the effect of natural and synthetic molecules on an insect's feeding, growth, development, and behavioral patterns13. Commonly used methods include the leaf disk assay, choice feeding assay, droplet feeding assay, contact assay, diet covering assay, and obligate feeding assay13,14. These methods are classified based on how pesticides are applied to insects. The obligate feeding assay is one of the most commonly used, sensitive, simple, and adaptable methods to test probable insecticides and their lethal dose14. In an obligate feeding assay, the molecule of interest is mixed with an artificial diet. This provides consistency and control over the diet composition, generating robust and reproducible results. Important variables affecting feeding assays are the developmental stage of the insect, choice of insecticide, environmental factors, and sample size. The duration of the assay, interval between two data recordings, frequency and amount of diet fed, health of insects, and handling skill of operators can also influence the outcome of feeding assays14,15.
This study aims to demonstrate the obligate feeding assay to evaluate the effect of quercetin on H. armigera survival and fitness. Assessment of various parameters, such as insect body weight, mortality rate, and developmental defects, will provide insights into the insecticidal effects of quercetin. Meanwhile, measuring nutritional parameters, including the efficiency of conversion of ingested food (ECI), efficiency of conversion of digested food (ECD), and approximate digestibility (AD), will highlight the antifeedant attributes of quercetin.