Abstract
Since its inception, antisense oligonucleotides (ASOs) have been extensively used in functional genomics. Recent advancements in chemical modification and delivery technology extend its applications to the targeted management of crop pests. ASO was conceptualized in the early 1970s and first applied to inhibit retrovirus replication in chickens. The principles of ASOs rely on target complementarity by hybridizing with the mRNA and inhibiting the function. However, the application of ASO received little attention because of its high instability in the biological environment. Initial ASOs, featuring phosphorothioate linkages, laid the groundwork for subsequent advancements, by addressing challenges such as nuclease degradation and cellular uptake limitations. The second generation introduced 2'-modifications to enhance stability and specificity while allowing reversible gene regulation. Third-generation ASOs incorporated innovative chemical modifications like locked nucleic acids (LNAs), peptide nucleic acids (PNAs), phosphoramidate morpholino oligomers (PMOs), 2′-deoxy-2′-fluoro-d-arabinonucleic acid (FANA), cyclohexene nucleic acids (CeNAs), and tricyclo-DNA (tcDNA), offering enhanced efficacy and stability. ASO technology continues to evolve, promising precision medicine and customized therapies for genetic diseases. In agriculture, ASOs selectively target essential genes in pests or pathogens, which would be a novel option for providing precise crop protection and reducing reliance on conventional pesticides. Recent studies demonstrated successful ASO application in thrips, psyllids, Gypsy moths, scale insects, citrus greening, and Zebra-chip diseases. Additionally, ASOs hold the potential for improving crop yield and quality by modulating gene expression related to plant growth, development, and stress responses. They can enhance abiotic stress tolerance, regulate genes associated with specific traits, and offer alternative strategies for managing diseases, such as targeting S-genes in tomatoes for resistance against bacterial spots. These applications antecede the oligo-based pesticides that will revolutionize future agriculture by reducing pesticide uses and harmful impacts on the ecosystem. Further advancements in environmental stability, field efficacy, delivery formulation, and environmental safety would mold this technology into a novel tool for sustainable crop protection. This review highlights the fundamentals of ASO, recent advancements in design chemistry, delivery systems, validation and optimization process, and its potential in customized pest management. This would serve as a ready reckoner for future ASO research and application.
Published Version
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