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.     

Structure of the gene encoding the exoglucanase of Cellulomonas fimi

In Cellulomonas fimi the cex gene encodes an exoglucanase (Exg) involved in the degradation of cellulose. The gene now has been sequenced as part of a 2.58-kb fragment of C. fimi DNA. The cex coding region of 1452 bp (484 codons) was identified by comparison of the DNA sequence to the N-terminal amino acid (aa) sequence of the Exg purified from C. fimi. The Exg sequence is preceded by a putative signal peptide of 41 aa, a translational initiation codon, and a sequence resembling a ribosome-binding site five nucleotides (nt) before the initiation codon. The nt sequence immediately following the translational stop codon contains four inverted repeats, two of which overlap, and which can be arranged in stable secondary structures. The codon usage in C. fimi appears to be quite different from that of Escherichia coli. A dramatic (98.5%) bias occurs for G or C in the third position for the 35 codons utilized in the cex gene.     

Assembly and functional expression of murine glutathione reductase cDNA: a sequence missing in expressed sequence tag libraries

Glutathione reductase (GR) is a chemotherapeutic target. Murine GRcDNA, which contains 85% GC in the 38 codons following the start codon, was assembled from the PCR-amplified exon 1 and a downstream cDNA prior to expression in Escherichia coli as a His(6)-tagged protein. Recombinant GR, an FAD-containing homodimer, corresponds in its enzymic and spectral properties to GR isolated from murine Ehrlich ascites tumor cells. Another cDNA, representing GR with a mitochondrial targeting sequence, yielded two distinct enzymically active expression products.     

SNPs occur in regions with less genomic sequence conservation

Rates of SNPs (single nucleotide polymorphisms) and cross-species genomic sequence conservation reflect intra- and inter-species variation, respectively. Here, I report SNP rates and genomic sequence conservation adjacent to mRNA processing regions and show that, as expected, more SNPs occur in less conserved regions and that functional regions have fewer SNPs. Results are confirmed using both mouse and human data. Regions include protein start codons, 3' splice sites, 5' splice sites, protein stop codons, predicted miRNA binding sites, and polyadenylation sites. Throughout, SNP rates are lower and conservation is higher at regulatory sites. Within coding regions, SNP rates are highest and conservation is lowest at codon position three and the fewest SNPs are found at codon position two, reflecting codon degeneracy for amino acid encoding. Exon splice sites show high conservation and very low SNP rates, reflecting both splicing signals and protein coding. Relaxed constraint on the codon third position is dramatically seen when separating exonic SNP rates based on intron phase. At polyadenylation sites, a peak of conservation and low SNP rate occurs from 30 to 17 nt preceding the site. This region is highly enriched for the sequence AAUAAA, reflecting the location of the conserved polyA signal. miRNA 3' UTR target sites are predicted incorporating interspecies genomic sequence conservation; SNP rates are low in these sites, again showing fewer SNPs in conserved regions. Together, these results confirm that SNPs, reflecting recent genetic variation, occur more frequently in regions with less evolutionarily conservation.     

Functional significance of an evolutionarily conserved alanine (GCA) resume codon in tmRNA in Escherichia coli

Occasionally, ribosomes stall on mRNAs prior to the completion of the polypeptide chain. In Escherichia coli and other eubacteria, tmRNA-mediated trans-translation is a major mechanism that recycles the stalled ribosomes. The tmRNA possesses a tRNA-like domain and a short mRNA region encoding a short peptide (ANDENYALAA in E. coli) followed by a termination codon. The first amino acid (Ala) of this peptide encoded by the resume codon (GCN) is highly conserved in tmRNAs in different species. However, reasons for the high evolutionary conservation of the resume codon identity have remained unclear. In this study, we show that changing the E. coli tmRNA resume codon to other efficiently translatable codons retains efficient functioning of the tmRNA. However, when the resume codon was replaced with the low-usage codons, its function was adversely affected. Interestingly, expression of tRNAs decoding the low-usage codon from plasmid-borne gene copies restored efficient utilization of tmRNA. We discuss why in E. coli, the GCA (Ala) is one of the best codons and why all codons in the short mRNA of the tmRNA are decoded by the abundant tRNAs.     

A synthetic arabinose-inducible promoter confers high levels of recombinant protein expression in hyperthermophilic archaeon Sulfolobus islandicus

Despite major progresses in genetic studies of hyperthermophilic archaea, recombinant protein production in these organisms always suffers from low yields and a robust expression system is still in great demand. Here we report a versatile vector that confers high levels of protein expression in Sulfolobus islandicus, a hyperthermophilic crenarchaeon. Two expression vectors, pSeSD and pEXA, harboring 11 unique restriction sites were constructed. They contain coding sequences of two hexahistidine (6×His) peptide tags and those coding for two protease sites, the latter of which make it possible to remove the peptide tags from expressed recombinant proteins. While pEXA employed an araS promoter for protein expression, pSeSD utilized P(araS-SD), an araS derivative promoter carrying an engineered ribosome-binding site (RBS; a Shine-Dalgarno [SD] sequence). We found that P(araS-SD) directed high levels of target gene expression. More strikingly, N-terminal amino acid sequencing of recombinant proteins unraveled that the protein synthesized from pEXA-N-lacS lacked the designed 6×His tag and that translation initiation did not start at the ATG codon of the fusion gene. Instead, it started at multiple sites downstream of the 6×His codons. Intriguingly, inserting an RBS site upstream of the ATG codon regained the expression of the 6×His tag, as shown with pSeSD-N-lacS. These results have yielded novel insight into the archaeal translation mechanism. The crenarchaeon Sulfolobus can utilize N-terminal coding sequences of proteins to specify translation initiation in the absence of an RBS site.     

In vivo translational inaccuracy in Escherichia coli: missense reporting using extremely low activity mutants of Vibrio harveyi luciferase

A convenient, sensitive assay for measurement of in vivo missense translational errors is reported that uses luciferase activity generated by mistranslation of a gene encoding an inactive mutant alpha chain of the Vibrio harveyi enzyme. Mutations were introduced at alpha45 His, a position known to be highly intolerant of amino acids other than histidine. To normalize for any variations in expression level, the concentration of wild-type luciferase alphabeta dimer was determined by a novel assay using co-refolding of active/wild-type beta enzyme subunits with inactive alpha subunits in lysate with an excess of exogenously added active alpha subunits. Four His alpha45 missense mutants of luciferase encoded by leucine codons (CUC, CUU, CUG, and UUG) had histidine misincorporation rates of 2.0 x 10(-6), 1.3 x 10(-6), 9.0 x 10(-8), and 1.5 x 10(-8) respectively, a variation of over 133-fold among synonymous codons. Any substantial contribution of mutation was ruled out by a Luria-Delbrück fluctuation test. The two leucine codons with the highest rates, CUU and CUC, have a single central-mismatch to the histidyl-tRNAQUG anticodon. Aminoglycoside antibiotics known to enhance mistranslation increased the error rate of the CUC codon more than those of the CUU and CUG codons, consistent with the hypothesis that CUC codon mistranslation arises primarily from miscoding events such as the selection of noncognate histidyl-tRNAQUG at the central position of the codon.     

Analysis of sequence patterns proximal to the stop codons in Oryza sativa

Abstract

A comprehensive analysis of sequence patterns around the stop codons was performed, by using more than 26,000 rice full-length cDNA sequences. Here it is shown that the bias was most outstanding at the position immediately before the stop codons (?1 codon), where the AAC codon was strongly preferred among ANC codons. Compared with other positions, the codon immediately after the stop codons (+1 codon) also displayed an apparent difference, and had a strong consensus for base A at the first, C at the second, and A at the third letters, respectively. Notably, the base biases at the positions directly downstream of the stop codons, such as the +4, +5 and +6 positions, were much stronger than other positions in the 3′-UTR region, suggesting that those base positions might act as an extended stop signal in the process of protein synthesis. Examination of the relationship between sequence pattern and gene expression level, assessed by CAI values and EST counting, revealed a tendency towards bigger base biases for highly expressed genes. It could be inferred that the translation stop signal is possibly involved in many sequence recognition elements other than the stop codons; highly expressed genes should hold strong sequence consensus around the stop codons for efficient translation termination.     

The translational termination signal database (TransTerm) now also includes initiation contexts.

The TransTerm database of termination codon contexts has been extended to include sense codon usage, and initiation codon contexts. The database was constructed from 23,721 coding sequences from 93 organisms. The database contains: a) the sequence around the termination codon (-10, +10); b) the sequence around the initiation codon (-20, +10); c) the length, 'G+C%' of the third position of codons (GC3), the 'codon adaptation index' (CAI) and the 'effective number of codons' statistic (Nc); d) summary tables for each organism including total codon usage, stop codon and tetranucleotide stop-signal usage, and matrices tallying base frequencies at each position around the initiation and termination codons. The data are arranged to facilitate investigation of the relationships between the three phases of protein synthesis. The database is available electronically from EMBL.     

Cloning and nucleotide sequence of ovine prolactin cDNA

A cDNA expression library was constructed in the lambda gt 11 phage vector using ovine (o) pituitary mRNA. The clone, pOP1, carrying a 934-bp insert contains an open reading frame beginning with the first nucleotide (nt) and ending with the stop codon TAA at nt position 781. Two potential translation start codons (ATGs) are present in the 5' region of this cDNA. Translation initiation could occur at the 5' proximal ATG at nt position 61. The nucleotide sequence around this ATG (TCCATGG), resembles the optimum sequence context for translation initiation by the eukaryotic ribosomes, as defined by mutational analysis [Kozak, Cell 44 (1986) 283-292)], with its substitution of the A at -3 of the consensus sequence by a T residue in this clone. Translation initiated at this codon could potentially code for the entire pre-prolactin (pre-PRL) molecule. The 3'-untranslated region is 154 nt long and contains a polyadenylation signal AATAAA. The deduced amino acid sequence agrees in totality with the published amino acid sequence of the mature hormone. The present study reports on the nucleotide sequence of o-PRL mRNA and the deduced amino acid sequence in the signal peptide of the hormone.     

Translational Effects of Mutations and Polymorphisms in a Repressive Upstream Open Reading Frame of the Human Cytomegalovirus UL4 Gene

The human cytomegalovirus (HCMV) gpUL4 mRNA contains a 22-codon upstream open reading frame (uORF2), the peptide product of which represses downstream translation by blocking translation termination at its own stop codon and by causing ribosomes to stall on the mRNA. A distinctive feature of this unusual mechanism is its strict dependence on the uORF2 peptide sequence. To delineate sequence elements that function in the inhibitory mechanism, deletions and missense mutations affecting the previously uncharacterized amino-terminal region of uORF2 were analyzed in transient-transfection and infection assays. These experiments identified multiple codons in this region that are necessary for inhibition of downstream translation by uORF2 and, in conjunction with previous results, demonstrated that amino acids dispersed throughout the uORF2 peptide participate in the repressive mechanism. In contrast to the highly conserved carboxy terminus, the amino-terminal portion of the uORF2 peptide is polymorphic. A survey of uORF2 sequences in HCMV clinical isolates revealed that although most have uORF2 sequences that are predicted to retain the uORF2 inhibitory activity, approximately 15% contain polymorphisms at codons that are essential for full inhibition by uORF2. Consistent with predictions based on analyses of engineered mutations, two viral isolates with uORF2 sequences that do not inhibit downstream translation in transfection assays expressed much more gpUL4 protein but similar levels of UL4 mRNA compared to the levels produced by the prototypic laboratory strain HCMV (Towne) and another clinical isolate with an inhibitory variant uORF2. These results demonstrate that uORF2 is polymorphic in sequence and repressive activity and suggest that the uORF2 regulatory mechanism, although prevalent among natural HCMV isolates, is not absolutely essential for viral replication.     

Codon Usage in Plastid Genes Is Correlated with Context, Position Within the Gene, and Amino Acid Content

Highly expressed plastid genes display codon adaptation, which is defined as a bias toward a set of codons which are complementary to abundant tRNAs. This type of adaptation is similar to what is observed in highly expressed Escherichia coli genes and is probably the result of selection to increase translation efficiency. In the current work, the codon adaptation of plastid genes is studied with regard to three specific features that have been observed in E. coli and which may influence translation efficiency. These features are (1) a relatively low codon adaptation at the 5′ end of highly expressed genes, (2) an influence of neighboring codons on codon usage at a particular site (codon context), and (3) a correlation between the level of codon adaptation of a gene and its amino acid content. All three features are found in plastid genes. First, highly expressed plastid genes have a noticeable decrease in codon adaptation over the first 10–20 codons. Second, for the twofold degenerate NNY codon groups, highly expressed genes have an overall bias toward the NNC codon, but this is not observed when the 3′ neighboring base is a G. At these sites highly expressed genes are biased toward NNT instead of NNC. Third, plastid genes that have higher codon adaptations also tend to have an increased usage of amino acids with a high G + C content at the first two codon positions and GNN codons in particular. The correlation between codon adaptation and amino acid content exists separately for both cytosolic and membrane proteins and is not related to any obvious functional property. It is suggested that at certain sites selection discriminates between nonsynonymous codons based on translational, not functional, differences, with the result that the amino acid sequence of highly expressed proteins is partially influenced by selection for increased translation efficiency. Received: 21 July 1999 / Accepted: 5 November 1999