Abstract
Small noncoding RNAs are versatile regulators of gene expression, capable of guiding the silencing of complementary mRNAs through their association with Argonaute proteins. This RNA-guided silencing, known as RNA interference (RNAi), is a conserved mechanism that shapes diverse biological processes, from development to genome defense. Central to the effectiveness of RNAi is the precise loading of small RNAs into their appropriate Argonaute partners, a step that ensures both specificity and fidelity in target recognition. Although most organisms harbor multiple classes of small RNAs and a corresponding repertoire of Argonautes, the rules that dictate their selective pairing remain only partially understood. Caenorhabditis elegans, with its expanded array of small RNA classes and Argonaute proteins, provides a powerful system to probe these mechanisms. In this review, we synthesize current knowledge on small RNA loading specificity, integrating insights from C. elegans with findings from other organisms. We focus on the interplay between small RNA biogenesis, biochemical properties of small RNAs, structural features of Argonautes, post-translational modifications, and the spatiotemporal coexpression patterns that together orchestrate precise Argonaute loading.