Characterizing the role of RSD-6 in the biogenesis of virus-derived small interfering RNAs and the modulation of viral pathogenesis

Small interfering RNAs (siRNAs) produced through the processing of viral double-stranded RNAs mediate potent antiviral RNA interference (RNAi) in eukaryotes. In Caenorhabditis elegans , such an antiviral defense is further amplified through the production of secondary siRNAs, yet the mechanisms by which secondary virus-derived siRNAs (vsiRNAs) confer protection remain poorly understood. Here, we characterize the role of rsd-6 , which encodes a Tudor domain protein and plays important role in antiviral RNAi, in vsiRNA biogenesis and modulation of viral pathogenesis. Using CRISPR Cas9-generated rsd-6 null mutants, we show that both primary and secondary vsiRNAs accumulate normally in the absence of RSD-6, indicating that it functions downstream of secondary vsiRNA biogenesis. We further showed that secondary vsiRNAs generated in rrf-1 -independent manner remained detected in the absence of RSD-6 and viral replication is further enhanced in rrf-1;rsd-6 double mutants compared to rrf-1 single mutants, suggesting a role of rsd-6 in mediating antiviral guided by all secondary vsiRNAs. Consistently, rsd-6 mutants exhibited more severe pathogenesis upon Orsay virus infection compared to rrf-1 mutants, underscoring its role as a major determinant of viral disease outcome. Domain characterization established that the N-terminal tandem domains of RSD-6 are required for antiviral activity, while the C-terminal Tudor domains are dispensable. Functional conservation was confirmed in C. briggsae , where silencing of the rsd-6 homolog enhanced viral replication. Together, our findings identify RSD-6 as a key effector acting downstream of secondary vsiRNA production and highlight its conserved role in modulating viral replication and pathogenesis across Caenorhabditis species.