Abstract
Decoding is thought to be governed by a conformational transition in the ribosome—open (off) to closed (on)—that occurs upon codon–anticodon pairing in the A site. Ribosomal ambiguity (ram) mutations increase miscoding and map to disparate regions, consistent with a role for ribosome dynamics in decoding, yet precisely how these mutations act has been unclear. Here, we solved crystal structures of 70S ribosomes harboring 16S ram mutations G299A and G347U in the absence A-site tRNA (A-tRNA) and in the presence of a near-cognate anticodon stem-loop (ASL). In the absence of an A-tRNA, each of the mutant ribosomes exhibits a partially closed (on) state. In the 70S-G347U structure, the 30S shoulder is rotated inward and intersubunit bridge B8 is disrupted. In the 70S-G299A structure, the 30S shoulder is rotated inward and decoding nucleotide G530 flips into the anti conformation. Both of these mutant ribosomes adopt the fully closed (on) conformation in the presence of near-cognate A-tRNA, just as they do with cognate A-tRNA. Thus, these ram mutations act by promoting the open (off) to closed (on) transition, albeit in somewhat distinct ways. This work reveals the functional importance of 30S shoulder rotation for productive aminoacylated-tRNA incorporation.
Highlights
During protein synthesis, ribosomes select correct aminoacyl-tRNAs by monitoring the nucleotide pairing between the anticodon of the tRNA and the codon on the mRNA in the aminoacyl (A) site
Previous structures of 70S-G299A and 70S-G347U ribosomes with cognate A-site anticodon stem-loop (ASL) showed a disruption of bridge B8 [21]
We solved a 3.7-Astructure of the 70S-G299A ribosome containing ASLLeu paired to UUC, that is, with a C–U mismatch at the third position of the codon–anticodon helix (Figure 2A; Supplementary Table S1; Supplementary Figure S1)
Summary
Ribosomes select correct aminoacyl-tRNAs (aa-tRNAs) by monitoring the nucleotide (nt) pairing between the anticodon of the tRNA and the codon on the mRNA in the aminoacyl (A) site. Aminoacyl-tRNA binds the ribosome as part of a ternary complex with EF-Tu and GTP [8]. Initial binding, mediated by the interaction of 50S ribosomal proteins L7/12 with EF-Tu [9], is followed by sampling of the A-site codon by the tRNA. Codon-anticodon pairing in the 30S A site leads to activation of EF-Tu and GTP hydrolysis. A perfect match between codon and anticodon stabilizes A-site tRNA binding at both stages of decoding and promotes GTPase activation and aa-tRNA accommodation [10,11,12,13]
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