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RNA sectors and allosteric function within the ribosome

Allison S. Walker, William P. Russ, Rama Ranganathan, Alanna Schepartz

2020Proceedings of the National Academy of Sciences39 citationsDOIOpen Access PDF

Abstract

The ribosome translates the genetic code into proteins in all domains of life. Its size and complexity demand long-range interactions that regulate ribosome function. These interactions are largely unknown. Here, we apply a global coevolution method, statistical coupling analysis (SCA), to identify coevolving residue networks (sectors) within the 23S ribosomal RNA (rRNA) of the large ribosomal subunit. As in proteins, SCA reveals a hierarchical organization of evolutionary constraints with near-independent groups of nucleotides forming physically contiguous networks within the three-dimensional structure. Using a quantitative, continuous-culture-with-deep-sequencing assay, we confirm that the top two SCA-predicted sectors contribute to ribosome function. These sectors map to distinct ribosome activities, and their origins trace to phylogenetic divergences across all domains of life. These findings provide a foundation to map ribosome allostery, explore ribosome biogenesis, and engineer ribosomes for new functions. Despite differences in chemical structure, protein and RNA enzymes appear to share a common internal logic of interaction and assembly.

Topics & Concepts

RibosomeEukaryotic Ribosome5.8S ribosomal RNARibosome biogenesisBiologyRibosomal RNAComputational biologyRNARibosomal proteinGeneticsGeneRNA and protein synthesis mechanismsRNA modifications and cancerRNA Research and Splicing
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