UGA suppression by normal tRNA Trp in Escherichia coli: codon context effects.

The nucleotide sequences at the 3' side of in-phase UGA termination codons in mRNAs of various prokaryotic genes were re-examined. An adenine (A) residue is found to be adjacent to the 3' side of UGA in mRNAs which code for readthrough proteins by the suppression of UGA by normal Escherichia coli tRNA Trp. It is suggested that the nature of the nucleotide following a UGA codon determines whether the UGA signals inefficiently or efficiently the termination of polypeptide chain synthesis: an A residue at this position permits the UGA readthrough process.     

An rRNA Fragment and Its Antisense Can Alter Decoding of Genetic Information

rRNA plays a central role in protein synthesis and is intimately involved in the initiation, elongation, and termination stages of translation. However, the mode of its participation in these reactions, particularly as to the decoding of genetic information, remains elusive. In this paper, we describe a new approach that allowed us to identify an rRNA segment whose function is likely to be related to translation termination. By screening an expression library of random rRNA fragments, we identified a fragment of the Escherichia coli 23S rRNA (nucleotides 74 to 136) whose expression caused readthrough of UGA nonsense mutations in certain codon contexts in vivo. The antisense RNA fragment produced a similar effect, but in neither case was readthrough of UAA or UAG observed. Since termination at UGA in E. coli specifically requires release factor 2 (RF2), our data suggest that the fragments interfere with RF2-dependent termination.     

Polyamines enhance readthrough of the UGA termination codon in a mammalian messenger RNA

The polyamines spermidine and spermine stimulate the readthrough of the UGA termination codon of rabbit beta-globin mRNA when it is translated in a rabbit reticulocyte cell-free system. The other major polyamine, putrescine, does not show this effect. The polyamine induced readthrough is specific for UGA as the UAA termination codon of alpha-globin mRNA is not read through and general translational misreading errors are not occurring in the presence of spermidine or spermine. The probable mechanism of this effect and some possible regulatory implications are discussed.     

Characterization of the stop codon readthrough signal of Colorado tick fever virus segment 9 RNA

Termination codon readthrough is utilized as a mechanism of expression of a growing number of viral and cellular proteins, but in many cases the mRNA signals that promote readthrough are poorly characterized. Here, we investigated the readthrough signal of Colorado tick fever virus (CTFV) segment 9 RNA (Seg-9). CTFV is the type-species of the genus Coltivirus within the family Reoviridae and is a tick-borne, double-stranded, segmented RNA virus. Seg-9 encodes a 36-kDa protein VP9, and by readthrough of a UGA stop codon, a 65-kDa product, VP9'. Using a reporter system, we defined the minimal sequence requirements for readthrough and confirmed activity in both mammalian and insect cell-free translation systems, and in transfected mammalian cells. Mutational analysis revealed that readthrough was UGA specific, and that the local sequence context around the UGA influenced readthrough efficiency. Readthrough was also dependent upon a stable RNA stem-loop structure beginning eight bases downstream from the UGA codon. Mutational analysis of this stem-loop revealed a requirement for the stem region but not for substructures identified within the loop. Unexpectedly, we were unable to detect a ribosomal pause during translation of the CTFV signal, suggesting that the mechanism of readthrough, at least at this site, is unlikely to be dependent upon RNA secondary-structure induced ribosomal pausing at the recoded stop codon.     

Growth at low temperature suppresses readthrough of the UGA stop codon during the expression of Bacillus subtilis flgM gene in Escherichia coli

The efficient production of recombinant proteins in Escherichia coli requires a proper termination of translation to ensure the synthesis of only the desired product. During the recombinant production of Bacillus subtilis flgM in E. coli, we detected an additional polypeptide of molecular mass higher than the expected, corresponding to a product of a translational readthrough of the UGA stop codon. In this paper we show that the readthrough was abolished when the synthesis of the recombinant protein was carried out at 25 degrees C. The possible causes that contribute to reduce the proportion of readthrough protein species against the correct terminated product are discussed.     

Possible incorporation of phosphoserine into globin readthrough protein via bovine opal suppressor phosphoseryl-tRNA

Suppressor [32P]phosphoseryl-tRNA, prepared using bovine seryl-tRNA synthetase and ATP:seryl-tRNA phosphotransferase, was mixed with rabbit reticulocyte lysates containing endogenous hemoglobin mRNA having the termination codon UGA (opal). The chromatographic pattern of the lysate on Sephacryl S-200 showed that the radioactivity of [32P]phosphate in the hot trichloroacetic acid-precipitate (phosphoprotein) was eluted at the position between mature hemoglobin and globin subunits. The phosphoprotein, obtained by chromatography on S-200, moved to the position corresponding to that of globin readthrough protein on SDS-PAGE. The analyses of the hydrolyzate of the phosphoprotein showed the presence of phosphoserine in the protein. These results suggest that animal opal suppressor tRNA functions in vitro to transfer phosphoserine to the position of the termination codon UGA (opal) on mRNA.     

Ribosomal Readthrough at a Short UGA Stop Codon Context Triggers Dual Localization of Metabolic Enzymes in Fungi and Animals

Translation of mRNA into a polypeptide chain is a highly accurate process. Many prokaryotic and eukaryotic viruses, however, use leaky termination of translation to optimize their coding capacity. Although growing evidence indicates the occurrence of ribosomal readthrough also in higher organisms, a biological function for the resulting extended proteins has been elucidated only in very few cases. Here, we report that in human cells programmed stop codon readthrough is used to generate peroxisomal isoforms of cytosolic enzymes. We could show for NAD-dependent lactate dehydrogenase B (LDHB) and NAD-dependent malate dehydrogenase 1 (MDH1) that translational readthrough results in C-terminally extended protein variants containing a peroxisomal targeting signal 1 (PTS1). Efficient readthrough occurs at a short sequence motif consisting of a UGA termination codon followed by the dinucleotide CU. Leaky termination at this stop codon context was observed in fungi and mammals. Comparative genome analysis allowed us to identify further readthrough-derived peroxisomal isoforms of metabolic enzymes in diverse model organisms. Overall, our study highlights that a defined stop codon context can trigger efficient ribosomal readthrough to generate dually targeted protein isoforms. We speculate that beyond peroxisomal targeting stop codon readthrough may have also other important biological functions, which remain to be elucidated.     

Functional analysis of the interplay between translation termination, selenocysteine codon context, and selenocysteine insertion sequence-binding protein 2

A selenocysteine insertion sequence (SECIS) element in the 3'-untranslated region and an in-frame UGA codon are the requisite cis-acting elements for the incorporation of selenocysteine into selenoproteins. Equally important are the trans-acting factors SBP2, Sec-tRNA[Ser]Sec, and eEFSec. Multiple in-frame UGAs and two SECIS elements make the mRNA encoding selenoprotein P (Sel P) unique. To study the role of codon context in determining the efficiency of UGA readthrough at each of the 10 rat Sel P Sec codons, we individually cloned 27-nucleotide-long fragments representing each UGA codon context into a luciferase reporter construct harboring both Sel P SECIS elements. Significant differences, spanning an 8-fold range of UGA readthrough efficiency, were observed, but these differences were dramatically reduced in the presence of excess SBP2. Mutational analysis of the "fourth base" of contexts 1 and 5 revealed that only the latter followed the established rules for hierarchy of translation termination. In addition, mutations in either or both of the Sel P SECIS elements resulted in differential effects on UGA readthrough. Interestingly, even when both SECIS elements harbored a mutation of the core region required for Sec incorporation, context 5 retained a significantly higher level of readthrough than context 1. We also show that SBP2-dependent Sec incorporation is able to repress G418-induced UGA readthrough as well as eRF1-induced stimulation of termination. We conclude that a large codon context forms a cis-element that works together with Sec incorporation factors to determine readthrough efficiency.     

The application of 8-aminoguanosine triphosphate, a new inhibitor of GTP cyclohydrolase I, to the purification of the enzyme from human liver

Unfractionated tRNAs from a number of prokaryotes and eukaryotes were examined for their ability to promote termination codon readthrough in a cell-free system isolated from Saccharomyces cerevisiae. tRNA from the dimorphic fungus Candida albicans was found to have significant UGA and UAG readthrough activity and this activity was present in tRNA extracted from both the yeast and the hyphal phase of the fungus. Unusually the efficiency of readthrough activity in vitro was not affected by the [psi] determinant. C. albicans tRNA was fractionated by one-dimensional and two-dimensional gel electrophoresis and both readthrough activities appeared to be associated with a single species of tRNA.     

Transcriptome-wide investigation of stop codon readthrough in Saccharomyces cerevisiae

Translation of mRNA into a polypeptide is terminated when the release factor eRF1 recognizes a UAA, UAG, or UGA stop codon in the ribosomal A site and stimulates nascent peptide release. However, stop codon readthrough can occur when a near-cognate tRNA outcompetes eRF1 in decoding the stop codon, resulting in the continuation of the elongation phase of protein synthesis. At the end of a conventional mRNA coding region, readthrough allows translation into the mRNA 3’-UTR. Previous studies with reporter systems have shown that the efficiency of termination or readthrough is modulated by cis-acting elements other than stop codon identity, including two nucleotides 5’ of the stop codon, six nucleotides 3’ of the stop codon in the ribosomal mRNA channel, and stem-loop structures in the mRNA 3’-UTR. It is unknown whether these elements are important at a genome-wide level and whether other mRNA features proximal to the stop codon significantly affect termination and readthrough efficiencies in vivo. Accordingly, we carried out ribosome profiling analyses of yeast cells expressing wild-type or temperature-sensitive eRF1 and developed bioinformatics strategies to calculate readthrough efficiency, and to identify mRNA and peptide features which influence that efficiency. We found that the stop codon (nt +1 to +3), the nucleotide after it (nt +4), the codon in the P site (nt -3 to -1), and 3’-UTR length are the most influential features in the control of readthrough efficiency, while nts +5 to +9 had milder effects. Additionally, we found low readthrough genes to have shorter 3’-UTRs compared to high readthrough genes in cells with thermally inactivated eRF1, while this trend was reversed in wild-type cells. Together, our results demonstrated the general roles of known regulatory elements in genome-wide regulation and identified several new mRNA or peptide features affecting the efficiency of translation termination and readthrough.     

Selenocysteine insertion or termination: factors affecting UGA codon fate and complementary anticodon:codon mutations.

Translation of UGA as selenocysteine instead of termination occurs in numerous proteins, and the process of recording UGA requires specific signals in the corresponding mRNAs. In eukaryotes, stem-loops in the 3' untranslated region of the mRNAs confer this function. Despite the presence of these signals, selenocysteine incorporation is inefficient. To investigate the reason for this, we examined the effects of the amount of deiodinase cDNA on UGA readthrough in transfected cells, quantitating the full-length and UGA terminated products by Western blotting. The gene for the selenocysteine-specific tRNA was also cotransfected to determine if it was limiting. We find that the concentrations of both the selenoprotein DNA and the tRNA affect the ratio of selenocysteine incorporation to termination. Selenium depletion was also found to decrease readthrough. The fact that the truncated peptide is synthesized intracellularly demonstrates unequivocally that UGA can serve as both a stop and a selenocysteine codon in a single mRNA. Mutation of UGA to UAA (stop) or UUA (leucine) in the deiodinase mRNA abolishes deiodinase activity; but activity is partially restored when selenocysteine tRNAs containing complementary mutations are contransfected. Thus, UGA is not essential for selenocysteine incorporation in mammalian cells, provided that codon:anticodon complementarity is maintained.     

Influence of codon context on UGA suppression and readthrough.

We studied the influence of the codon context on UGA suppression by a suppressor tRNA and on UGA readthrough by a normal tRNA in Escherichia coli. This was done by a series of constructs where only the immediate context of the TGA codon was varied by only one nucleotide at a time. For both UGA suppression and UGA readthrough the codon context had a similar influence according to the following rules. (1) The nature of the nucleotide immediately adjacent to the 3' side of the UGA is an important determinant; at that position the level of UGA translation is influenced by the nucleotides in the order A greater than G greater than C greater than U. (2) At extremely high or low levels of UGA translation this influence of the adjacent 3' nucleotide is not seen. (3) In all cases, the nature of both the nucleotide immediately adjacent to the 5' side of the codon and that following the base adjacent to the 3' side of the codon have little effect, if any, on UGA translation. The varying influence of the codon context effect on UGA translation is discussed in relation to its role in gene expression.     

A novel suppressor tRNA from the dimorphic fungus Candida albicans

Unfractionated tRNAs from a number of prokaryotes and eukaryotes were examined for their ability to promote termination codon readthrough in a cell-free system isolated from Saccharomyces cerevisiae. tRNA from the dimorphic fungus Candida albicans was found to have significant UGA and UAG readthrough activity and this activity was present in tRNA extracted from both the yeast and the hyphal phase of the fungus. Unusually the efficiency of readthrough activity in vitro was not affected by the [psi] determinant. C. albicans tRNA was fractionated by one-dimensional and two-dimensional gel electrophoresis and both readthrough activities appeared to be associated with a single species of tRNA.     

An RNA-binding protein recognizes a mammalian selenocysteine insertion sequence element required for cotranslational incorporation of selenocysteine.

In mammalian selenoprotein mRNAs, the recognition of UGA as selenocysteine requires selenocysteine insertion sequence (SECIS) elements that are contained in a stable stem-loop structure in the 3' untranslated region (UTR). In this study, we investigated the SECIS elements and cellular proteins required for selenocysteine insertion in rat phospholipid hydroperoxide glutathione peroxidase (PhGPx). We developed a translational readthrough assay for selenoprotein biosynthesis by using the gene for luciferase as a reporter. Insertion of a UGA or UAA codon into the coding region of luciferase abolished luciferase activity. However, activity was restored to the UGA mutant, but not to the UAA mutant, upon insertion of the PhGPx 3' UTR. The 3' UTR of rat glutathione peroxidase (GPx) also allowed translational readthrough, whereas the PhGPx and GPx antisense 3' UTRs did not. Deletion of two conserved SECIS elements in the PhGPx 3' UTR (AUGA in the 5' stem or AAAAC in the terminal loop) abolished readthrough activity. UV cross-linking studies identified a 120-kDa protein in rat testis that binds specifically to the sense strands of the PhGPx and GPx 3' UTRs. Direct cross-linking and competition experiments with deletion mutant RNAs demonstrated that binding of the 120-kDa protein requires the AUGA SECIS element but not AAAAC. Point mutations in the AUGA motif that abolished protein binding also prevented readthrough of the UGA codon. Our results suggest that the 120-kDa protein is a significant component of the mechanism of selenocysteine incorporation in mammalian cells.     

Eukaryotic release factor 1 (eRF1) abolishes readthrough and competes with suppressor tRNAs at all three termination codons in messenger RNA.

It is known from experiments with bacteria and eukaryotic viruses that readthrough of termination codons located within the open reading frame (ORF) of mRNAs depends on the availability of suppressor tRNA(s) and the efficiency of termination in cells. Consequently, the yield of readthrough products can be used as a measure of the activity of polypeptide chain release factor(s) (RF), key components of the translation termination machinery. Readthrough of the UAG codon located at the end of the ORF encoding the coat protein of beet necrotic yellow vein furovirus is required for virus replication. Constructs harbouring this suppressible UAG codon and derivatives containing a UGA or UAA codon in place of the UAG codon have been used in translation experiments in vitro in the absence or presence of human suppressor tRNAs. Readthrough can be virtually abolished by addition of bacterially-expressed eukaryotic RF1 (eRF1). Thus, eRF1 is functional towards all three termination codons located in a natural mRNA and efficiently competes in vitro with endogenous and exogenous suppressor tRNA(s) at the ribosomal A site. These results are consistent with a crucial role of eRF1 in translation termination and forms the essence of an in vitro assay for RF activity based on the abolishment of readthrough by eRF1.     

Suppression of UAA and UGA termination codons in mutant murine leukemia viruses.

Genomes of mammalian type C retroviruses contain a UAG termination codon between the gag and pol coding regions. The pol region is expressed in the form of a gag-pol fusion protein following readthrough suppression of the UAG codon. We have used oligonucleotide-directed mutagenesis to change the UAG in Moloney murine leukemia virus to UAA or UGA. These alternate termination codons were also suppressed, both in infected cells and in reticulocyte lysates. Thus, the signal or context inducing suppression of UAG in wild-type Moloney murine leukemia virus is also effective with UAA and UGA. Further, mammalian cells and cell extracts contain tRNAs capable of translating UAA and UGA as amino acids. To our knowledge, this is the first example of natural suppression of UAA in higher eucaryotes.     

The effect of eukaryotic release factor depletion on translation termination in human cell lines

Two competing events, termination and readthrough (or nonsense suppression), can occur when a stop codon reaches the A-site of a translating ribosome. Translation termination results in hydrolysis of the final peptidyl-tRNA bond and release of the completed nascent polypeptide. Alternatively, readthrough, in which the stop codon is erroneously decoded by a suppressor or near cognate transfer RNA (tRNA), results in translation past the stop codon and production of a protein with a C-terminal extension. The relative frequency of termination versus readthrough is determined by parameters such as the stop codon nucleotide context, the activities of termination factors and the abundance of suppressor tRNAs. Using a sensitive and versatile readthrough assay in conjunction with RNA interference technology, we assessed the effects of depleting eukaryotic releases factors 1 and 3 (eRF1 and eRF3) on the termination reaction in human cell lines. Consistent with the established role of eRF1 in triggering peptidyl-tRNA hydrolysis, we found that depletion of eRF1 enhances readthrough at all three stop codons in 293 cells and HeLa cells. The role of eRF3 in eukarytotic translation termination is less well understood as its overexpression has been shown to have anti-suppressor effects in yeast but not mammalian systems. We found that depletion of eRF3 has little or no effect on readthrough in 293 cells but does increase readthrough at all three stop codons in HeLa cells. These results support a direct role for eRF3 in translation termination in higher eukaryotes and also highlight the potential for differences in the abundance or activity of termination factors to modulate the balance of termination to readthrough reactions in a cell-type-specific manner.     

Polyamines enhance synthesis of the RNA polymerase sigma 38 subunit by suppression of an amber termination codon in the open reading frame

The mechanisms by which polyamines stimulate synthesis of the RNA polymerase sigma(38) subunit in Escherichia coli were studied. Polyamine stimulation was observed only in strains in which the 33rd codon of RpoS mRNA is a UAG termination codon instead of a CAG codon for glutamine in wild-type E. coli. Readthrough of the termination codon by Gln-tRNA(supE) was stimulated by polyamines. This stimulation was found to be caused by an increase in both the level of suppressor tRNA(supE) and the binding affinity of Gln-tRNA(supE) for ribosomes. The stimulatory effect was observed with a UAG termination codon but not with UGA and UAA codons. Readthrough of the UAG termination codon at the 270th amino acid position of RpoS mRNA was also stimulated by polyamines, indicating that polyamines stimulate readthrough of a UAG codon regardless of its location within the RpoS mRNA. When cell viability of an E. coli strain having a termination codon in the 33rd position of RpoS mRNA was compared using cells cultured with or without putrescine, it was higher in cells cultured with putrescine than in cells cultured without putrescine. The level of sigma(38) subunit in the cells cultured with putrescine was higher than that in cells cultured without putrescine on days 2, 4, and 8, but the level of sigma(70) subunit was almost the same in cells cultured with or without putrescine. These results confirm that elevated expression of the rpoS gene is important for cell viability at late stationary phase.