Pervasive downstream RNA hairpins dynamically dictate start-codon selection

Xiang, Yezi; Huang, Wenze; Tan, Lianmei; Chen, Tianyuan; He, Yang; Irving, Patrick S.; Weeks, Kevin M.; Zhang, Qiangfeng Cliff; Dong, Xinnian

Pervasive downstream RNA hairpins dynamically dictate start-codon selection

Yezi Xiang, Wenze Huang, Lianmei Tan, Tianyuan Chen, Yang He, Patrick S. Irving, Kevin M. Weeks, Qiangfeng Cliff Zhang and Xinnian Dong ()
Additional contact information
Yezi Xiang: Duke University
Wenze Huang: Tsinghua University
Lianmei Tan: Duke University
Tianyuan Chen: Duke University
Yang He: Duke University
Patrick S. Irving: University of North Carolina
Kevin M. Weeks: University of North Carolina
Qiangfeng Cliff Zhang: Tsinghua University
Xinnian Dong: Duke University

Nature, 2023, vol. 621, issue 7978, 423-430

Abstract: Abstract Translational reprogramming allows organisms to adapt to changing conditions. Upstream start codons (uAUGs), which are prevalently present in mRNAs, have crucial roles in regulating translation by providing alternative translation start sites1–4. However, what determines this selective initiation of translation between conditions remains unclear. Here, by integrating transcriptome-wide translational and structural analyses during pattern-triggered immunity in Arabidopsis, we found that transcripts with immune-induced translation are enriched with upstream open reading frames (uORFs). Without infection, these uORFs are selectively translated owing to hairpins immediately downstream of uAUGs, presumably by slowing and engaging the scanning preinitiation complex. Modelling using deep learning provides unbiased support for these recognizable double-stranded RNA structures downstream of uAUGs (which we term uAUG-ds) being responsible for the selective translation of uAUGs, and allows the prediction and rational design of translating uAUG-ds. We found that uAUG-ds-mediated regulation can be generalized to human cells. Moreover, uAUG-ds-mediated start-codon selection is dynamically regulated. After immune challenge in plants, induced RNA helicases that are homologous to Ded1p in yeast and DDX3X in humans resolve these structures, allowing ribosomes to bypass uAUGs to translate downstream defence proteins. This study shows that mRNA structures dynamically regulate start-codon selection. The prevalence of this RNA structural feature and the conservation of RNA helicases across kingdoms suggest that mRNA structural remodelling is a general feature of translational reprogramming.

Date: 2023
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DOI: 10.1038/s41586-023-06500-y

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