Synonymous Codon Usage, Accuracy of Translation, and Gene Length in Caenorhabditis elegans

In many unicellular organisms, invertebrates, and plants, synonymous codon usage biases result from a coadaptation between codon usage and tRNAs abundance to optimize the efficiency of protein synthesis. However, it remains unclear whether natural selection acts at the level of the speed or the accuracy of mRNAs translation. Here we show that codon usage can improve the fidelity of protein synthesis in multicellular species. As predicted by the model of selection for translational accuracy, we find that the frequency of codons optimal for translation is significantly higher at codons encoding for conserved amino acids than at codons encoding for nonconserved amino acids in 548 genes compared between Caenorhabditis elegans and Homo sapiens. Although this model predicts that codon bias correlates positively with gene length, a negative correlation between codon bias and gene length has been observed in eukaryotes. This suggests that selection for fidelity of protein synthesis is not the main factor responsible for codon biases. The relationship between codon bias and gene length remains unexplained. Exploring the differences in gene expression process in eukaryotes and prokaryotes should provide new insights to understand this key question of codon usage. Received: 18 June 2000 / Accepted: 10 November 2000     

Internal ribosome entry site-mediated translation of a mammalian mRNA is regulated by amino acid availability

The cationic amino acid transporter, Cat-1, facilitates the uptake of the essential amino acids arginine and lysine. Amino acid starvation causes accumulation and increased translation of cat-1 mRNA, resulting in a 58-fold increase in protein levels and increased arginine uptake. A bicistronic mRNA expression system was used to demonstrate the presence of an internal ribosomal entry sequence (IRES) within the 5'-untranslated region of the cat-1 mRNA. This study shows that IRES-mediated translation of the cat-1 mRNA is regulated by amino acid availability. This IRES causes an increase in translation under conditions of amino acid starvation. In contrast, cap-dependent protein synthesis is inhibited during amino acid starvation, which is well correlated with decreased phosphorylation of the cap-binding protein, eIF4E. These findings reveal a new aspect of mammalian gene expression and regulation that provides a cellular stress response; when the nutrient supply is limited, the activation of IRES-mediated translation of mammalian mRNAs results in the synthesis of proteins essential for cell survival.     

Codon usage and protein length-dependent feedback from translation elongation regulates translation initiation and elongation speed

Essential cellular functions require efficient production of many large proteins but synthesis of large proteins encounters many obstacles in cells. Translational control is mostly known to be regulated at the initiation step. Whether translation elongation process can feedback to regulate initiation efficiency is unclear. Codon usage bias, a universal feature of all genomes, plays an important role in determining gene expression levels. Here, we discovered that there is a conserved but codon usage-dependent genome-wide negative correlation between protein abundance and CDS length. The codon usage effects on protein expression and ribosome flux on mRNAs are influenced by CDS length; optimal codon usage preferentially promotes production of large proteins. Translation of mRNAs with long CDS and non-optimal codon usage preferentially induces phosphorylation of initiation factor eIF2α, which inhibits translation initiation efficiency. Deletion of the eIF2α kinase CPC-3 (GCN2 homolog) in Neurospora preferentially up-regulates large proteins encoded by non-optimal codons. Surprisingly, CPC-3 also inhibits translation elongation rate in a codon usage and CDS length-dependent manner, resulting in slow elongation rates for long CDS mRNAs. Together, these results revealed a codon usage and CDS length-dependent feedback mechanism from translation elongation to regulate both translation initiation and elongation kinetics.     

Translation termination is involved in histone mRNA degradation when DNA replication is inhibited

The levels of replication-dependent histone mRNAs are coordinately regulated with DNA synthesis. A major regulatory step in histone mRNA metabolism is regulation of the half-life of histone mRNAs. Replication-dependent histone mRNAs are the only metazoan mRNAs that are not polyadenylated. Instead, they end with a conserved stem-loop structure, which is recognized by the stem-loop binding protein (SLBP). SLBP is required for histone mRNA processing, as well as translation. We show here, using histone mRNAs whose translation can be regulated by the iron response element, that histone mRNAs need to be actively translated for their rapid degradation following the inhibition of DNA synthesis. We also demonstrate the requirement for translation using a mutant SLBP which is inactive in translation. Histone mRNAs are not rapidly degraded when DNA synthesis is inhibited or at the end of S phase in cells expressing this mutant SLBP. Replication-dependent histone mRNAs have very short 3' untranslated regions, with the stem-loop located 30 to 70 nucleotides downstream of the translation termination codon. We show here that the stability of histone mRNAs can be modified by altering the position of the stem-loop, thereby changing the distance from the translation termination codon.     

Translation of aberrant mRNAs lacking a termination codon or with a shortened 3'-UTR is repressed after initiation in yeast

A novel mRNA surveillance for mRNA lacking a termination codon (nonstop mRNA) has been proposed in which Ski7p is thought to recognize stalled ribosomes at the 3' end of mRNA. Here we report our analysis of translation and decay of nonstop mRNAs in Saccharomyces cerevisiae. Although the reduction of nonstop mRNAs was only 4.5-fold, a level that is sufficient for residual protein synthesis, translation products of nonstop mRNAs were hardly detectable. We show that nonstop mRNAs were associated with polysomes, but not with Pab1p. We also show that ribosomes translating nonstop mRNA formed stable and heavy polysome complexes with mRNA. These data suggest that ribosome stalling at the 3' end of nonstop mRNA may block further rounds of translation, hence repressing protein synthesis. Furthermore, it was found that the 5' --> 3' decay pathway was accelerated for nonstop mRNA decay in the absence of Ski7p. We also found that translation of aberrant mRNAs with a shortened 3'-UTR was repressed, suggesting that an improper spatial distance between the termination codon and the 3' end of mRNA results in translation repression.     

Computer simulation of ribosome editing

A stochastic model of protein synthesis was modified by including the process of dissociating peptidyl-tRNA from ribosomes. To simulate ribosome editing, the probability of dissociation was assumed to be high if the peptidyl-tRNA was erroneous; that is, if it resulted from transfer of a peptide to an aminoacyl-tRNA that was inappropriate relative to the mRNA codon. The effects of amino acid starvation on protein synthesis were simulated both by increasing the probability of such erring at and by reducing the conditional probability of elongation at “hungry” codons, those whose correct amino acid was in short supply. These probabilities were varied systematically to simulate tryptophan limitation during synthesis of coat protein from bacteriophage MS2.Significant reduction, during starvation, in the synthesis of complete coat protein required large reductions in the probability of elongation at hungry codons but only small increases in the probability of erring. Enhanced dissociation of peptidyl-tRNA during starvation, followed rapidly by dissociation of ribosomes from mRNA, led to reductions in mean polysome size, a result that had been interpreted by others as due to some effect of starvation on the initiation of protein synthesis.Results from experiments by Goldman (1982) on the cell-free synthesis of MS2 coat protein during tryptophan starvation could be mimicked in detail by the computer simulations. A simple competition between correct and erroneous amino acids was sufficient to explain the tryptophan dependence of complete coat protein and internal peptide syntheses. Values for the Michaelis constants were derived from the computer simulations.     

Generation of protein isoform diversity by alternative initiation of translation at non-AUG codons

The use of several translation initiation codons in a single mRNA, by expressing several proteins from a single gene, contributes to the generation of protein diversity. A small, yet growing, number of mammalian mRNAs initiate translation from a non-AUG codon, in addition to initiating at a downstream in-frame AUG codon. Translation initiation on such mRNAs results in the synthesis of proteins harbouring different amino terminal domains potentially conferring on these isoforms distinct functions. Use of non-AUG codons appears to be governed by several features, including the sequence context and the secondary structure surrounding the codon. Selection of the downstream initiation codon can occur by leaky scanning of the 43S ribosomal subunit, internal entry of ribosome or ribosomal shunting. The biological significance of non-AUG alternative initiation is demonstrated by the different subcellular localisations and/or distinct biological functions of the isoforms translated from the single mRNA as illustrated by the two main angiogenic factor genes encoding the fibroblast growth factor 2 (FGF2) and the vascular endothelial growth factor (VEGF). Consequently, the regulation of alternative initiation of translation might have a crucial role for the biological function of the gene product.     

Deficiency of dietary EAA preferentially inhibits mRNA translation of ribosomal proteins in liver of meal-fed rats

The goal of these studies was to investigate the mechanisms by which amino acid supply regulates global rates of protein synthesis as well as the translation of ribosomal protein (rp) mRNAs in liver. In the experiments conducted, male weanling rats were trained over a 2-wk period to consume their daily food intake within 3 h. On day 14, rats were fed the control diet or an isocaloric, isonitrogenous diet lacking glycine, tryptophan, leucine, or the branched-chain amino acids (BCAA) for 1 h. Feeding Trp-, Leu-, or BCAA-deficient diets resulted in significant reductions in serum insulin, hepatic protein synthesis, eukaryotic initiation factor 2B (eIF2B) activity, and phosphorylation of eIF4E-binding protein 1 (4E-BP1) and ribosomal protein S6 kinase (S6K1). Phosphorylation of eIF2alpha was inversely related to eIF2B activity under all conditions. Alterations in the hepatic synthesis of rp were assessed by changes in the distribution of rp (S4, S8, L26) mRNAs across sucrose density gradients and compared with non-rp (beta-actin, albumin) mRNAs. In all dietary treatments, non-rp mRNAs were mostly polysome associated. Conversely, the proportion of rp mRNAs residing in polysomes was two- to fivefold less in rats fed diets lacking tryptophan, leucine, or BCAA compared with rats fed the control diet. Total hepatic abundance of all mRNAs examined did not differ among treatment groups. For all parameters examined, there were no differences between rats fed the glycine-deficient diet and rats fed the control diet. The data suggest that essential amino acid (EAA) deficiency inhibits global rates of liver protein synthesis via a block in translation initiation. Additionally, the translation of rp mRNAs is preferentially repressed in association with decreased S6K1 phosphorylation.     

Requirements for ribosomal protein S1 for translation initiation of mRNAs with and without a 5' leader sequence

It has previously been proposed that Escherichia coli ribosomal protein S1 is required for the translation of highly structured mRNAs. In this study, we have examined the influence of structural features at or near the start codon of different mRNAs. The requirement for ribosomal protein S1 for translation initiation was determined when (i) the ribosome-binding site (RBS) was either preceded by a 5' non-translated leader sequence; (ii) the RBS was located 5' proximal to a mRNA start codon; and (iii) the start codon was the 5' terminal codon as exemplified by leaderless mRNAs. In vitro translation studies revealed that the leaderless lambda cl mRNA is translated with Bacillus stearothermophilusribosomes, naturally lacking a ribosomal protein S1 homologue, whereas ompA mRNA containing a 5' leader is not. These studies have been verified by toeprinting with E. coli ribosomes depleted for S1. We have shown that S1 is required for ternary complex formation on ompA mRNA but not for leaderless mRNAs or for mRNAs in which the RBS is close to the 5' end.     

Ribosome-mediated translational pause and protein domain organization.

Because regions on the messenger ribonucleic acid differ in the rate at which they are translated by the ribosome and because proteins can fold cotranslationally on the ribosome, a question arises as to whether the kinetics of translation influence the folding events in the growing nascent polypeptide chain. Translationally slow regions were identified on mRNAs for a set of 37 multidomain proteins from Escherichia coli with known three-dimensional structures. The frequencies of individual codons in mRNAs of highly expressed genes from E. coli were taken as a measure of codon translation speed. Analysis of codon usage in slow regions showed a consistency with the experimentally determined translation rates of codons; abundant codons that are translated with faster speeds compared with their synonymous codons were found to be avoided; rare codons that are translated at an unexpectedly higher rate were also found to be avoided in slow regions. The statistical significance of the occurrence of such slow regions on mRNA spans corresponding to the oligopeptide domain termini and linking regions on the encoded proteins was assessed. The amino acid type and the solvent accessibility of the residues coded by such slow regions were also examined. The results indicated that protein domain boundaries that mark higher-order structural organization are largely coded by translationally slow regions on the RNA and are composed of such amino acids that are stickier to the ribosome channel through which the synthesized polypeptide chain emerges into the cytoplasm. The translationally slow nucleotide regions on mRNA possess the potential to form hairpin secondary structures and such structures could further slow the movement of ribosome. The results point to an intriguing correlation between protein synthesis machinery and in vivo protein folding. Examination of available mutagenic data indicated that the effects of some of the reported mutations were consistent with our hypothesis.     

Two modes of amber codon read-through in vitro

Read-through translation of bacteriophage R17 amB2 coat cistron carrying an amber mutation at the seventh codon was studied in vitro using the crude cell extract (S30) derived from an Escherichia coli nonsuppressor strain. Despite the presence of termination factors as well as ribosome-releasing factor (RRF) which prevent the read-through translation [M. Ryoji, J. W. Karpen, and A. Kaji (1981) J. Biol. Chem. 256, 5798-5801], synthesis of coat-like protein still persists at a low level in this system. Characterization of this protein by peptide fingerprinting and amino acid sequencing was performed to reexamine the generally accepted notion that it is produced by amino acid misinsertion to the amber mutation codon. The results indicated, however, that the major population of this coat-like protein is produced as a result of reinitiation of translation from the eighth codon. Read-through by amino acid misinsertion in this system becomes predominant only when the Mg2+ concentration is higher than 16 mM.     

Effects of codon distributions and tRNA competition on protein translation

Translation is a central cellular process and the complexity of its mechanism necessitates mathematical frameworks to better understand system properties and make quantitative predictions. We have developed a gene sequence-specific mechanistic model for translation which accounts for all the elementary steps of translation elongation. Included in our model is the nonspecific binding of tRNAs to the ribosomal A site, and we find that the competitive, nonspecific binding of the tRNAs is the rate-limiting step in the elongation cycle for every codon. By introducing our model in terms of the Michaelis-Menten kinetic framework, we determine that these results are due to the tRNAs that do not recognize the ribosomal A site codon acting as competitive inhibitors to the tRNAs that do recognize the ribosomal A site codon. We present the results of a sensitivity analysis to determine the contribution of elongation cycle kinetic parameters of each codon on the overall translation rate, and observe that the translation rates of mRNAs are controlled by segments of rate-limiting codons that are sequence-specific. Along these lines, we find that the relative position of codons along the mRNA determines the optimal protein synthesis rate.     

Deciphering the rules by which dynamics of mRNA secondary structure affect translation efficiency in Saccharomyces cerevisiae

Messenger RNA (mRNA) secondary structure decreases the elongation rate, as ribosomes must unwind every structure they encounter during translation. Therefore, the strength of mRNA secondary structure is assumed to be reduced in highly translated mRNAs. However, previous studies in vitro reported a positive correlation between mRNA folding strength and protein abundance. The counterintuitive finding suggests that mRNA secondary structure affects translation efficiency in an undetermined manner. Here, we analyzed the folding behavior of mRNA during translation and its effect on translation efficiency. We simulated translation process based on a novel computational model, taking into account the interactions among ribosomes, codon usage and mRNA secondary structures. We showed that mRNA secondary structure shortens ribosomal distance through the dynamics of folding strength. Notably, when adjacent ribosomes are close, mRNA secondary structures between them disappear, and codon usage determines the elongation rate. More importantly, our results showed that the combined effect of mRNA secondary structure and codon usage in highly translated mRNAs causes a short ribosomal distance in structural regions, which in turn eliminates the structures during translation, leading to a high elongation rate. Together, these findings reveal how the dynamics of mRNA secondary structure coupling with codon usage affect translation efficiency.     

TISs-ST: a web server to evaluate polymorphic translation initiation sites and their reflections on the secretory targets

Background  

The nucleotide sequence flanking the translation initiation codon (start codon context) affects the translational efficiency of eukaryotic mRNAs, and may indicate the presence of an alternative translation initiation site (TIS) to produce proteins with different properties. Multi-targeting may reflect the translational variability of these other protein forms. In this paper we present a web server that performs computations to investigate the usage of alternative translation initiation sites for the synthesis of new protein variants that might have different functions.     

Coordinate accumulation of contractile protein mRNAs during myoblast differentiation.

The synthesis of contractile protein mRNAs has been studied during the differentiation of quail skeletal muscle myoblasts in culture. Eight contractile protein mRNAs were identified by translation of total cellular RNA isolated from differentiated myofibers in wheat germ and reticulocyte lysates. Products of the translation systems were fractionated by two-dimensional gel electrophoresis, and incorporation of [³⁵S]methionine into individual contractile proteins was quantitated by computerized densitometry of autoradiograms. These translation assay systems were used to quantitate levels of contractile protein mRNAs in cultures of myoblasts undergoing highly synchronous differentiation. Our results show that dividing myoblasts contain very little, if any, translatable contractile protein mRNA. The mRNAs coding for myosin heavy chain, the musclespecific actin, three myosin light chains, two tropomyosin subunits, and one troponin subunit begin to coordinately accumulate at fusion, when contractile protein synthesis is activated. Their levels increase 50- to 200-fold during the next 30 hr, paralleling increases in the rates of contractile protein synthesis. These results indicate that the contractile protein mRNAs accumulate coordinately during myoblast differentiation and that contractile protein synthesis is regulated by changes in the levels of these mRNAs.     

Selective destabilization of polypeptides synthesized from NMD-targeted transcripts

The translation of mRNAs that contain a premature termination codon (PTC) generates truncated proteins that may have toxic dominant negative effects. Nonsense-mediated decay (NMD) is an mRNA surveillance pathway that degrades PTC-containing mRNAs to limit the production of truncated proteins. NMD activation requires a ribosome terminating translation at a PTC, but what happens to the polypeptides synthesized during the translation cycle needed to activate NMD is incompletely understood. Here, by establishing reporter systems that encode the same polypeptide sequence before a normal termination codon or PTC, we show that termination of protein synthesis at a PTC is sufficient to selectively destabilize polypeptides in mammalian cells. Proteasome inhibition specifically rescues the levels of nascent polypeptides produced from PTC-containing mRNAs within an hour, but also disrupts mRNA homeostasis within a few hours. PTC-terminated polypeptide destabilization is also alleviated by depleting the central NMD factor UPF1 or SMG1, the kinase that phosphorylates UPF1 to activate NMD, but not by inhibiting SMG1 kinase activity. Our results suggest that polypeptide degradation is linked to PTC recognition in mammalian cells and clarify a framework to investigate these mechanisms.