The control of lambda DNA terminase synthesis.

Nu1 and A, the genes coding for bacteriophage lambda DNA terminase, rank among the most poorly translated genes expressed in E. coli. To understand the reason for this low level of translation the genes were cloned into plasmids and their expression measured. In addition, the wild type DNA sequences immediately preceding the genes were reduced and modified. It was found that the elements that control translation are contained in the 100 base pairs upstream from the initiation codon. Interchanging these upstream sequences with those of an efficiently translated gene dramatically increased the translation of terminase subunits. It seems unlikely that the rare codons present in the genes, and any feature of their mRNA secondary structure play a role in the control of their translation. The elimination of cos from plasmids containing Nu1 and A also resulted in an increase in terminase production. This result suggests a role for cos in the control of late gene expression. The terminase subunit overproducer strains are potentially very useful for the design of improved DNA packaging and cosmid mapping techniques.     

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.     

The Effects of Codon Context on In Vivo Translation Speed

We developed a bacterial genetic system based on translation of the his operon leader peptide gene to determine the relative speed at which the ribosome reads single or multiple codons in vivo. Low frequency effects of so-called “silent” codon changes and codon neighbor (context) effects could be measured using this assay. An advantage of this system is that translation speed is unaffected by the primary sequence of the His leader peptide. We show that the apparent speed at which ribosomes translate synonymous codons can vary substantially even for synonymous codons read by the same tRNA species. Assaying translation through codon pairs for the 5′- and 3′- side positioning of the 64 codons relative to a specific codon revealed that the codon-pair orientation significantly affected in vivo translation speed. Codon pairs with rare arginine codons and successive proline codons were among the slowest codon pairs translated in vivo. This system allowed us to determine the effects of different factors on in vivo translation speed including Shine-Dalgarno sequence, rate of dipeptide bond formation, codon context, and charged tRNA levels.     

The rates of macromolecular chain elongation modulate the initiation frequencies for transcription and translation inEscherichia coli

Here we show that most macromolecular biosynthesis reactions in growing bacteria are sub-saturated with substrate. The experiments should in part test predictions from a previously proposed model (Jensen & Pedersen 1990) which proposed a central role for the rates of the RNA and peptide chain elongation reactions in determining the concentration of initiation competent RNA polymerases and ribosomes and thereby the initiation frequencies for these reactions. We have shown that synthesis of ribosomal RNA and the concentration of ppGpp did not exhibit the normal inverse correlation under balanced growth conditions in batch cultures when the RNA chain elongation rate was limited by substrate supply. The RNA chain elongation rate for the polymerase transcribinglacZ mRNA was directly measured and found to be reduced by two-fold under conditions of high ppGpp levels. In the case of translation, we have shown that the peptide elongation rate varied at different types of codons and even among codons read by the same tRNA species. The faster translated codons probably have the highest cognate tRNA concentration and the highest affinity to the tRNA. Thus, the ribosome may operate close to saturation at some codons and be unsaturated at synonymous codons. Therefore, not only translation of the codons for the seven amino acids, whose biosynthesis is regulated by attenuation, but also a substantial fraction of the other translation reactions may be unsaturated. Recently, we have obtained results which indicate that also many ribosome binding sites are unsaturated with their substrate, i.e. with ribosomes. This observation affects the interpretation of many results obtained by use of reporter genes, because the expression from such genes is strongly influenced by the general physiology of the cell.     

Codon usage determines translation rate in Escherichia coli

We wish to determine whether differences in translation rate are correlated with differences in codon usage or with differences in mRNA secondary structure. We therefore inserted a small DNA fragment in the lacZ gene either directly or flanked by a few frame-shifting bases, leaving the reading frame of the lacZ gene unchanged. The fragment was chosen to have "infrequent" codons in one reading frame and "common" codons in the other. The insert in these constructs does not seem to give mRNAs that are able to form extensive secondary structures. The translation time for these modified lacZ mRNAs was measured with a reproducibility better than plus or minus one second. We found that the mRNA with infrequent codons inserted has an approximately three-seconds longer translation time than the one with common codons. In another set of experiments we constructed two almost identical lacZ genes in which the lacZ mRNAs have the potential to generate stem structures with stabilities of about -75 kcal/mol. In this way we could investigate the influence of mRNA structure on translation rate. This type of modified gene was generated in two reading frames with either common or infrequent codons similar to our first experiments. We find that the yield of protein from these mRNAs is reduced, probably due to the action in vivo of an RNase. Nevertheless, the data do not indicate that there is any effect of mRNA secondary structure on translation rate. In contrast, our data persuade us that there is a difference in translation rate between infrequent codons and common codons that is of the order of sixfold.     

Translation efficiencies of synonymous codons are not always correlated with codon usage in tobacco chloroplasts

Codon usage in chloroplasts is different from that in prokaryotic and eukaryotic nuclear genomes. However, no experimental approach has been made to analyse the translation efficiency of individual codons in chloroplasts. We devised an in vitro assay for translation efficiencies using synthetic mRNAs, and measured the translation efficiencies of five synonymous codon groups in tobacco chloroplasts. Among four alanine codons (GCN, where N is U, C, A or G), GCU was the most efficient for translation, whereas the chloroplast genome lacks tRNA genes corresponding to GCU. Phenylalanine and tyrosine are each encoded by two codons (UUU/C and UAU/C, respectively). Phenylalanine UUC and tyrosine UAC were translated more than twice as efficiently than UUU and UAU, respectively, contrary to their codon usage, whereas translation efficiencies of synonymous codons for alanine, aspartic acid and asparagine were parallel to their codon usage. These observations indicate that translation efficiencies of individual codons are not always correlated with codon usage in vitro in chloroplasts. This raises an important issue for foreign gene expression in chloroplasts.     

Translation efficiencies of synonymous codons for arginine differ dramatically and are not correlated with codon usage in chloroplasts

Codon usage in chloroplast mRNAs is different from that in prokaryotic and cytosolic mRNAs. We previously devised an in vitro assay for translation efficiencies using synthetic mRNAs, and measured translation efficiencies of five synonymous codon groups in tobacco chloroplasts. Using this assay, we here report our analysis of four additional synonymous codon groups in tobacco chloroplasts. We found that translation efficiencies of three arginine codons AGA, CGU and CGA differ dramatically, ca. 10-fold difference although the three arginine codons possess similar codon usage. Translation of AGA is very high, while CGA is translated extremely low. CGA is used frequently in chloroplasts but rare in Escherichia coli. The single tRNA species reads two histidine codons (CAU and CAC) and this is also the case for two glutamic acid codons (GAA and GAG) and two arginine codons (GCU and GCA). Their translation efficiencies, however, differ significantly. These observations suggest that individual codons posses their intrinsic efficiencies.     

Causal signals between codon bias,mRNA structure,and the efficiency of translation and elongation

Ribosome profiling data report on the distribution of translating ribosomes, at steady‐state, with codon‐level resolution. We present a robust method to extract codon translation rates and protein synthesis rates from these data, and identify causal features associated with elongation and translation efficiency in physiological conditions in yeast. We show that neither elongation rate nor translational efficiency is improved by experimental manipulation of the abundance or body sequence of the rare AGG tRNA. Deletion of three of the four copies of the heavily used ACA tRNA shows a modest efficiency decrease that could be explained by other rate‐reducing signals at gene start. This suggests that correlation between codon bias and efficiency arises as selection for codons to utilize translation machinery efficiently in highly translated genes. We also show a correlation between efficiency and RNA structure calculated both computationally and from recent structure probing data, as well as the Kozak initiation motif, which may comprise a mechanism to regulate initiation.     

Rare codons cluster

Most amino acids are encoded by more than one codon. These synonymous codons are not used with equal frequency: in every organism, some codons are used more commonly, while others are more rare. Though the encoded protein sequence is identical, selective pressures favor more common codons for enhanced translation speed and fidelity. However, rare codons persist, presumably due to neutral drift. Here, we determine whether other, unknown factors, beyond neutral drift, affect the selection and/or distribution of rare codons. We have developed a novel algorithm that evaluates the relative rareness of a nucleotide sequence used to produce a given protein sequence. We show that rare codons, rather than being randomly scattered across genes, often occur in large clusters. These clusters occur in numerous eukaryotic and prokaryotic genomes, and are not confined to unusual or rarely expressed genes: many highly expressed genes, including genes for ribosomal proteins, contain rare codon clusters. A rare codon cluster can impede ribosome translation of the rare codon sequence. These results indicate additional selective pressures govern the use of synonymous codons, and specifically that local pauses in translation can be beneficial for protein biogenesis.     

An apparent rare-codon effect on the rate of translation of a Neurospora gene.

As the result of two mutually compensating frameshift mutations, three successive codons with third-position A were generated in the Neurospora crassa am (NADP-specific glutamate dehydrogenase: GDH) gene. These codons do not occur at all elsewhere in the gene and only infrequently in other highly expressed Neurospora genes. The double-frameshift strain produces only 25 to 35% of the normal level of GDH, whether measured as enzyme activity or as immunoprecipitable protein, but its level of GDH mRNA is normal. Although the modified enzyme is somewhat more heat-sensitive than the wild-type in vitro, its stability in vivo was found to be indistinguishable from that of the wild-type. It is concluded that the introduction of consecutive rare codons reduces the efficiency of translation of the mRNA. The possible mechanisms of such an effect are discussed.     

Synonymous codon preferences in bacteriophage T4: a distinctive use of transfer RNAs from T4 and from its host Escherichia coli.

Codon usage data of bacteriophage T4 genes were compiled and synonymous codon preferences were investigated in comparison with tRNA availabilities in an infected cell. Since the genome of T4 is highly AT rich and its codon usage pattern is significantly different from that of its host Escherichia coli, certain codons of T4 genes need to be translated by appropriate host transfer RNAs present in minor amounts. To avoid this predicament, T4 phage seems to direct the synthesis of its own tRNA molecules and these phage tRNAs are suggested to supplement the host tRNA population with isoacceptors that are normally present in minor amounts. A positive correlation was found in that the frequency of E. coli optimal codons in T4 genes increases as the number of protein monomers per phage particle increases. A negative correlation was also found between the number of protein monomers per phage and the frequency of "T4 optimal codons", which are defined as those codons that are efficiently recognized by T4 tRNAs. From these observations it was proposed that tRNAs from the host are predominantly used for translation of highly expressed T4 genes while tRNAs from T4 tend to be used for translation of weakly expressed T4 genes. This distinctive tRNA-usage in T4 may be an optimization of translational efficiency, and an adjustment of T4-encoded tRNAs to the synonymous codon preferences, which are largely influenced by the high genomic AT-content, would have occurred during evolution.     

Modulation of lambda integrase synthesis by rare arginine tRNA

Lambda's int gene contains an anomalously high frequency of the rare arginine codons AGA and AGG when compared to genes of Escherichia coli or to the rest of phage lambda. These are the least frequent codons in genes of E. coli and are recognized by the rarest tRNAs. The presence of these codons reduces the translation rate and, depending on the context, this can strongly modulate translational efficiency by a variety of mechanisms. In this study, we show that expression of the natural int gene may also be modulated by rare arginine codon usage, and we explore this mechanism.     

Rare codon clusters at 5'-end influence heterologous expression of archaeal gene in Escherichia coli

Proteins from hyperthermophilic microorganisms are attractive candidates for novel biocatalysts because of their high resistance to temperature extremes. However, archaeal genes are usually poorly expressed in Escherichia coli because of differences in codon usage. Genes from the thermoacidophilic archaea Sulfolobus solfataricus and Thermoplasma acidophilum contain high proportions of rare codons for arginine, isoleucine, and leucine, which are recognized by the tRNAs encoded by the argU, ileY, and leuW genes, respectively, and which are rarely used in E. coli. To examine the effects of these rare codons on heterologous expression, we expressed the Sso_gnaD and Tac_gnaD genes from S. solfataricus and T. acidophilum, respectively, in E. coli. The Sso_gnaD product was expressed at very low levels when the open reading frame (ORF) was cloned in pRSET and expressed in E. coli BL21(DE3), and was expressed at much higher levels in the E. coli BL21(DE3)-CodonPlus RIL strain, which contains extra copies of the argU, ileY, and leuW tRNA genes. In contrast, Tac_gnaD was expressed at similar levels in both E. coli strains. Comparison of the Sso_gnaD and Tac_gnaD gene sequences revealed that the 5'-end of the Sso_gnaD sequence was rich in AGA(arg) and ATA(Ile) codons. These codons were replaced with the codons commonly used in E. coli by polymerase chain reaction-mediated site-directed mutagenesis. The results of expression studies showed that a non-tandem repeat of rare codons is critical in the observed interference in heterologous expression of this gene. We concluded that the level of heterologous expression of Sso_gnaD in E. coli was limited by the clustering of the rare codons in the ORF, rather than on the rare codon frequency.