Journal of Scientific Research and Reports

Plant cells are continually exposed to a variety of microbes, with viral infections standing out as a major agricultural challenge. Viruses often undermine plant defenses, posing a significant threat to the productivity of crucial crops and global food security. Plant viruses, due to their limited coding capacity, heavily rely on the host cell machinery during infection, interacting with numerous host proteins. Given the absence of translation-required components in viral genomes, plant viruses have evolved strategies to manipulate the host protein synthesis machinery for viral protein production. In this study, a combination of molecular biology, genetic, and biochemical approaches was employed to investigate plant-virus interactions. Reverse genetics, transcriptomic analyses, and protein interaction assays were used to identify key host factors involved in viral translation and defense responses. The findings revealed that susceptible recessive resistance genes, encoding translation initiation factors such as eIF4E and eIF4G, can suppress viral mRNA translation by disrupting the formation of the translation initiation complex. Additionally, viral RNA silencing mechanisms were examined using RNA interference (RNAi) assays, which demonstrated that virus-induced gene silencing (VIGS) effectively reduces viral load in infected plants. Furthermore, activation of classical pathogen-associated molecular pattern (PAMP)-triggered immunity (PTI) by plant viruses leads to the induction of Nuclear Shuttle Protein-Interacting Kinase 1 (NIK1), which globally suppresses host translation, reducing viral replication by over 60% in tested plant models. The study also revealed that NIK1-mediated suppression selectively targets viral mRNAs while limiting general host translation, thereby enhancing plant antiviral resistance. These insights into plant-virus interactions and translational suppression provide a foundation for engineering virus-resistant crops. Future applications of this research include genome editing (e.g., CRISPR-Cas9) to modify key translation factors for enhanced resistance, as well as targeted breeding strategies to develop resilient crop varieties. Understanding these molecular mechanisms offers a path toward sustainable agricultural practices and improved food security in the face of viral threats.