Genome-wide identification of conserved RNA structure in plastids

The systematic discovery of functional RNA structures directly from sequence remains a central challenge in genomics. Plastid genomes, with their deep evolutionary history and extensive data availability, provide an ideal system to address this challenge. Here, we developed a stringent, covariation-based pipeline that integrates well-established and novel tools to perform an unbiased screen for conserved secondary structures across ~14,000 plastid genomes. Our analysis identified a repertoire of 51 conserved RNA motifs. Beyond recovering known functional classes, we uncover novel structures within the UTRs and introns of key photosynthetic genes, including psbN and atpF, pointing to previously unknown regulatory hubs. This work provides a stringent atlas of conserved plastid RNA structures, reveals an extensive layer of post-transcriptional regulation, and establishes a robust framework for structural genomics in other systems, including nuclear genomes.