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Abstract Examining the dynamicity of RNA structure has deepened our understanding of its vast biological functions. Perhaps the protein complex that encounters the most diverse landscape of RNA structure is the ribosome. In translation, the ribosome must linearize countless mRNA conformations for proper protein production. Some RNA structures, however, reliably make up sequences which hinder the ability of the ribosome to maintain its reading frame. The most well-studied of these structures is the RNA pseudoknot. Here, we present an approach utilizing dimethyl sulfate probing with mutational profiling and sequencing (DMS MaP-Seq) to precisely examine RNA unwinding. We employ the method to understand the unfolding of the Sugarcane Yellow Leaf Virus pseudoknot (ScYLV_PK). Notably, we find that the helical junction is stabilized in the presence of the ribosome and is contingent upon hydrogen bonding at the 27^thresidue of ScYLV_PK. Additionally, it is demonstrated that the ribosome destabilizes wildtype ScYLV_PKin a manner independent of A/P-site occupancy. Together, these results establish DMS MaP-Seq as a sensitive tool for detecting ribosome-induced RNA conformational changes and reveal specific structural motifs that govern pseudoknot stability during translation. 

Abstract Translation of mRNA into functional proteins is a fundamental process underlying many aspects of plant growth and development. Yet, the role of translational regulation in plants across diverse tissue types, including seeds, is not well known due to the lack of methods targeting these processes. Studying the seed translatome could unveil seed‐specific regulatory mechanisms, offering valuable insights for breeding efforts to enhance seed traits. Polysome profiling is a widely used technique for studying mRNAs being translated. However, the traditional method is time‐consuming and has a low polysome recovery rate; therefore, it requires substantial starting material. This is particularly challenging for species or mutants with limited seed quantities. Additionally, seed polysome fractions often yield low quality RNA due to the abundance of various compounds that interfere with conventional RNA extraction protocols. Here we present a robust polysome extraction method incorporating a size‐exclusion step for polysome concentration streamlined with a rapid RNA extraction method optimized for seeds. This protocol works across multiple plant species and offers increased speed and robustness, requiring less than half the amount of seed tissue and time compared to conventional methods while ensuring high polysome recovery and yield of high‐quality RNA for downstream experiments. These features make this protocol an ideal tool for studying seed translation efficiency and hold broad applicability across various plant species and tissues. © 2024 Wiley Periodicals LLC. Basic Protocol 1: Robust polysome extraction for seeds Basic Protocol 2: Rapid fraction total RNA extraction 

Proper codon/anticodon pairing within the ribosome necessitates linearity of the transcript. Any structures formed within a messenger RNA (mRNA) must be unwound before the respective codon is interpreted. Linearity, however, is not always the norm; some intricate structures within mRNA are able to exert unique ribosome/mRNA interactions to regulate translation. Intrinsic kinetic and thermal stability in many of these structures are efficient in slowing translation causing pausing of the ribosome. Altered translation kinetics arising from atypical interactions have been shown to affect intersubunit rotation. Here, we employ single-molecule Förster resonance energy transfer (smFRET) to observe changes in intersubunit rotation of the ribosome as it approaches downstream structured nucleic acid. The emergence of the hyperrotated state is critically dependent on the distance between downstream structure and the ribosome, suggesting interactions with the helicase center are allosterically coupled to intersubunit rotation. Further, molecular dynamics (MD) simulations were performed to determine ribosomal protein/mRNA interactions that may play a pivotal role in helicase activity and ultimately unwinding of downstream structure.