Exploiting attP landing sites and gypsy retrovirus insulators to identify and study viral suppressors of RNA silencing

RNA interference (RNAi) pathways are crucial for regulating viral infections in both animals and plants, acting as defense mechanisms that limit pathogen replication. This has led to the evolution of viral suppressors of RNA silencing (VSRs) across various plant and insect viruses, with potential analogs in arthropod-borne human pathogens. However, while functionally similar, VSRs often lack genetic conservation due to convergent evolution. Research on VSRs typically involves analyzing individual proteins expressed in host cells with secondary reporter constructs, but the lack of a standardized system can lead to inconsistent findings. Our study examined how genomic insertion sites affect VSR activity using a transgenic Drosophila melanogaster reporter system. We integrated the VSR protein DCV-1A into three different attP sites and assessed silencing. The results showed significant variation in VSR activity across loci due to position effects. However, by flanking the transgenes with gypsy retrovirus insulators, we achieved consistent high-level silencing across all sites. These findings suggest the potential for establishing a standardized reporter system in Drosophila , facilitating the identification, study and comparison of VSR proteins. However, our results also highlight the limitations of using isolated proteins in reporter systems, emphasizing the need for a comprehensive holistic approach to definitively determine VSR functions.