Abstract
To synthesize a protein, a ribosome moves along a messenger RNA (mRNA), reads it codon by codon, and takes up the corresponding ternary complexes which consist of aminoacylated transfer RNAs (aa-tRNAs), elongation factor Tu (EF-Tu), and GTP. During this process of translation elongation, the ribosome proceeds with a codon-specific rate. Here, we present a general theoretical framework to calculate codon-specific elongation rates and error frequencies based on tRNA concentrations and codon usages. Our theory takes three important aspects of in-vivo translation elongation into account. First, non-cognate, near-cognate and cognate ternary complexes compete for the binding sites on the ribosomes. Second, the corresponding binding rates are determined by the concentrations of free ternary complexes, which must be distinguished from the total tRNA concentrations as measured in vivo. Third, for each tRNA species, the difference between total tRNA and ternary complex concentration depends on the codon usages of the corresponding cognate and near-cognate codons. Furthermore, we apply our theory to two alternative pathways for tRNA release from the ribosomal E site and show how the mechanism of tRNA release influences the concentrations of free ternary complexes and thus the codon-specific elongation rates. Using a recently introduced method to determine kinetic rates of in-vivo translation from in-vitro data, we compute elongation rates for all codons in Escherichia coli. We show that for some tRNA species only a few tRNA molecules are part of ternary complexes and, thus, available for the translating ribosomes. In addition, we find that codon-specific elongation rates strongly depend on the overall codon usage in the cell, which could be altered experimentally by overexpression of individual genes.
Highlights
In the past decades, the function and structure of the ribosome were intensively studied [1, 2]
To address this long-lasting puzzle, we developed a comprehensive theoretical framework on protein synthesis by ribosomes in bacteria based on current biochemical knowledge about ribosomal kinetics in vitro [7, 41,42,43,44,45,46]
We described translation elongation as a Markov process with 12 different ribosomal transition rates and considered two alternative pathways of tRNA release from the ribosomal E site
Summary
The function and structure of the ribosome were intensively studied [1, 2]. Published theories [30,31,32,33,34,35] on tRNA concentration dependent elongation rates have some limitations because they ignored fundamental aspects of ribosome translation These aspects include (i) the proper distinction between the concentration of free ternary complexes and the measured tRNA concentrations, a distinction that was not considered in [30, 33]; (ii) the dependence of the free ternary complexes on the recharging of deacetylated tRNA by new amino acids which was not taken into account in [30,31,32]; (iii) the different in-vitro and in-vivo values for the rates of aa-tRNA decoding, accommodation, peptide bond formation and translocation [36], a difference that was ignored in [30,31,32]; and (iv) the competition between cognate, near-, and non-cognate ternary complexes for initial binding to ribosomes, which has a strong influence on the translation process [31] but was ignored in [32, 34, 35]. Our theory sheds light on the intricate relationships between the internal dynamics of the ribosome, the availability of ternary complexes, and the codon usages, both for the 2-1-2 and for the 2-3-2 pathway of tRNA release from the E site
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