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Cell-free reconstitution reveals the molecular mechanisms for the initiation of secondary siRNA biogenesis in plants

Yuriki Sakurai, Kyungmin Baeg, Andy Y.W. Lam, Keisuke Shoji, Yukihide Tomari, Hiro‐oki Iwakawa

2021Proceedings of the National Academy of Sciences39 citationsDOIOpen Access PDF

Abstract

Secondary small interfering RNA (siRNA) production, triggered by primary small RNA targeting, is critical for proper development and antiviral defense in many organisms. RNA-dependent RNA polymerase (RDR) is a key factor in this pathway. However, how RDR specifically converts the targets of primary small RNAs into double-stranded RNA (dsRNA) intermediates remains unclear. Here, we develop an in vitro system that allows for dissection of the molecular mechanisms underlying the production of trans-acting siRNAs, a class of plant secondary siRNAs that play roles in organ development and stress responses. We find that a combination of the dsRNA-binding protein, SUPPRESSOR OF GENE SILENCING3; the putative nuclear RNA export factor, SILENCING DEFECTIVE5, primary small RNA, and Argonaute is required for physical recruitment of RDR6 to target RNAs. dsRNA synthesis by RDR6 is greatly enhanced by the removal of the poly(A) tail, which can be achieved by the cleavage at a second small RNA-binding site bearing appropriate mismatches. Importantly, when the complementarity of the base pairing at the second target site is too strong, the small RNA-Argonaute complex remains at the cleavage site, thereby blocking the initiation of dsRNA synthesis by RDR6. Our data highlight the light and dark sides of double small RNA targeting in the secondary siRNA biogenesis.

Topics & Concepts

BiogenesisCell biologyBiologyCellSmall interfering RNAComputational biologyGeneGeneticsRNAPlant Molecular Biology ResearchChromosomal and Genetic VariationsPlant Genetic and Mutation Studies