Translational termination comes of age.

Translational termination has been a largely ignored aspect of protein synthesis for many years. However, the recent identification of new release-factor genes, the mapping of release-factor functional sites and in vitro reconstitution experiments have provided a deeper understanding of the termination mechanism. In addition, protein-protein interactions among release factors and with other proteins have been revealed. The three-dimensional structures of a prokaryotic ribosome recycling factor and eukaryotic release factor 1 (eRF1) mimic the shape of transfer RNA, indicating that they bind to the same ribosomal site. Post-termination events in bacteria have been clarified, linking termination, ribosomal recycling and translation initiation.

Sequestration of specific tRNA species cognate to the last sense codon of an overproduced gratuitous protein.

High-level expression of non-functional model proteins, derived from elongation factor EF-Tu by the deletion of an essential domain, greatly inhibits the growth of Escherichia coli partly deficient in peptidyl-tRNA hydrolase. High-level expression in wild-type cells has little effect on growth. The inhibitory effect is therefore presumably due to the sequestration of essential tRNA species, partly in the form of free peptidyl-tRNA. The growth inhibitory effect can be modulated by changing the last sense codon in the genes encoding the model proteins. Thus, replacement of Ser by Lys or His at this position increases growth inhibition. The effects of 11 changes studied are related to the rates of accumulation previously observed of the corresponding families of peptidyl-tRNA. Two non-exclusive hypotheses are proposed to account for these observations: first, the last sense codon of mRNA is a preferred site of peptidyl-tRNA drop-off in cells, due to the slow rate of translation termination compared with sense codon translation; secondly, the relatively long pause of the ribosome at the stop codon (of the order of 1 s), results in significant temporary sequestration on the ribosome of the tRNA cognate to the last sense codon.

Third position base changes in codons 5' and 3' adjacent UGA codons affect UGA suppression in vivo.

The base sequence around nonsense codons affects the efficiency of nonsense codon suppression. Published data, comparing different nonsense sites in a mRNA, implicate the two bases downstream of the nonsense codon as major determinants of suppression efficiency. However, the results we report here indicate that the nature of the contiguous upstream codon can also affect nonsense suppression, as can the third (wobble) base of the contiguous downstream codon. These conclusions are drawn from experiments in which the two Ser codons UCU233 and UCG235 in a nonsense mutant form (UGA234) of the trpA gene in Escherichia coli have been replaced with other Ser codons by site-directed mutagenesis. Suppression of these trpA mutants has been studied in the presence of a UGA nonsense suppressor derived from glyT. We speculate that the non-site-specific effects of the two adjacent downstream bases may be largely at the level of the termination process, whereas more site-specific or codon-specific effects may operate primarily on the activity of the suppressor tRNA.

Mutants of pheV in Escherichia coli affecting control by attenuation of the pheS, T and pheA operons. Two distinct mechanisms for de-attenuation.

Two mutants of pheV, a gene coding for tRNA(Phe) in Escherichia coli, were previously isolated because they affect attenuator control of the pheS, T operon when the mutant pheV genes are carried by the plasmid pBR322. We show that the two mutants (A44 and A46) affect attenuator control by different mechanisms. The effect of mutant A44 on pheS, T expression can be progressively decreased by overproduction of Phe-tRNA synthetase, consistent with the mutant tRNA acting as a competitive inhibitor of the enzyme. By contrast, the effect on attenuation of mutant A46 increases with overproduction of Phe-tRNA synthetase, indicating that the mutant must be charged to affect attenuation; we propose that this mutant affects translation directly and causes derepression by competing with wild-type tRNA in translation of the attenuator region leader peptide. Mutant A46 but not mutant A44 leads to further de-attenuation in a miaA background. The presence of two different mechanisms for de-attenuation is further indicated by the finding that a second attenuator controlled by Phe codon translation, from the pheA operon, is affected quite differently by the mutant tRNAs. Finally, experiments involving the introduction of the mutations A44 and A46 into an amber suppressor derived from tRNA(Phe) suggest that both species can function in protein synthesis but with reduced efficiency; mutant A46 is less efficient than mutant A44, consistent with a defect in elongation.

An effect of codon context on the mistranslation of UGU codons in vitro.

Effects of codon context on nonsense codon suppression may act either through release factor recognition of termination codons or aminoacyl-tRNA selection by the ribosome. The latter hypothesis has been studied by comparing misreading by Escherichia coli UGA suppressor tryptophan tRNA of UGU (cysteine) codons in two synthetic polymers, poly(U-G) and poly( U5 , G), which differ in sequence around the UGU codons. In vitro translation of these polymers in a cell-free system from E. coli yielded selection errors of 4 X 10(-3) and 1.75 X 10(-2) for UGU codons in poly(U-G) and poly( U5 , G), respectively. This difference suggests that codon context may significantly affect misincorporation of amino acids into protein.

The effect of point mutations affecting Escherichia coli tryptophan tRNA on anticodon-anticodon interactions and on UGA suppression.

tRNA species in Escherichia coli that translate codons starting with U contain 2-methyl-thio-N6-isopentenyl-adenosine in position 37, 3' adjacent to the anticodon. The role of this hypermodification in protein synthesis and trp operon attenuation has been investigated. Temperature-jump relaxation methods have been applied to study the interaction between E. coli tRNAPro, with anticodon VGG (V is uridine-5-oxyacetic acid) complementary to that of tRNATrp, and three species of E. coli tRNATrp: wild type tRNATrp (with ms2i6A37 and G24), UGA suppressor tRNATrp (with ms2i6A37 and A24 in the dihydrouridine stem but the same anticodon CCA), and the same suppressor molecule but ms2i6A-deficient as a result of the mutation miaA. Complex formation between tRNAPro and ms2i6A-containing tRNATrp shows thermodynamic parameters close to those found for several other pairs of tRNA with complementary anticodons. However, ms2i6A-deficient tRNATrp makes less stable complexes with tRNAPro, which dissociate eightfold faster. No effect on the complementary anticodon interaction of the mutation in the dihydrouridine stem can be detected. When the tRNA analogous to the opal codon, E. coli tRNASerIV (anticodon VGA) replaces tRNAPro in similar experiments, very weak complexes are observed with both normally hypermodified species of tRNATrp, the wild type and UGA suppressor; these show a lifetime about 50-fold shorter than with tRNAPro, but are again similar. No complex formation is detectable with the ms2i6A-deficient species. This may explain why the hypermodification is necessary for the efficient suppression of the UGA terminator of Q beta coat protein in vitro. The data on complexes with tRNAPro suggest that deficiency in ms2i6A may also reduce the efficiency of UGG reading. Thus, miaA may affect trp operon attenuation by slowing translation of the tandem UGG codons in the leader sequence. Temperature-jump differential spectra suggest that ms2i6 stabilizes the anticodon interaction by improved stacking of base 37.

Release factor RF3 abolishes competition between release factor RF1 and ribosome recycling factor (RRF) for a ribosome binding site.

The dependence of the rate of ribosomal recycling (from initiation via protein elongation and termination, and then back to initiation) on the concentrations of release factor RF1 and the ribosome recycling factor (RRF) has been studied in vitro. High RF1 concentration was found to reduce the rate of ribosomal recycling and the extent of this reduction depended on stop codon context. The inhibitory effect of high RF1 concentrations can be reversed by a corresponding increase in RRF concentration. This indicates that RF1 and RRF have mutually exclusive and perhaps overlapping binding sites on the ribosome. Addition of release factor RF3 to the translation system abolishes the inhibitory effect of high RF1 concentration and increases the overall rate of ribosome recycling. These data can be explained by a three-step model for termination where the first step is RF1-promoted hydrolysis of peptidyl-tRNA. The second step is an intrinsically slow dissociation of RF1 which is accelerated by RF3. The third step, catalysed by RRF and elongation factor G, leads to mobility of the ribosome on mRNA allowing it to enter a further round of translation. In the absence of RF3, RF1 can re-associate rapidly with the ribosome after peptidyl-tRNA hydrolysis, preventing RRF from entering the ribosomal A-site and thereby inhibiting ribosomal recycling. The overproduction of RF1 in cells deficient in RRF or lacking RF3 has effects on growth rate predicted by the in vitro experiments.

A direct estimation of the context effect on the efficiency of termination.

An in vitro assay in which terminating Escherichia coli ribosomes with different stop signals in the A-site compete for a limited amount of a release factor (RF1 or RF2) has been used to estimate the relative termination efficiencies at stop codons with different adjacent downstream nucleotides. The assay allows direct measurements of relative kcat/Km parameters for the productive association of release factors to ribosomes. The kcat/Km parameter is larger for UAA(U) than for UAA(C) programmed ribosomes and the difference in kcat/Km is much larger for RF2 (about 80%) than for RF1 (about 30%). These differences in the kcat/Km parameter are not affected by the addition of release factor RF3. The only discernible effect of RF3 is a considerable acceleration of RF1/2 recycling.The estimated kcat/Km parameters correlate well with the affinities of release factors for ribosomes programmed with different stop signals. These affinities were estimated from the extent of inhibition of ribosomal recycling by high concentrations of release factors in the absence of release factor RF3. The affinity for RF2 depends on the immediate downstream context of the stop codon in the translated mRNA and is about three times higher for UAA(U) than for UAA(C). The corresponding difference in affinities for RF1 is twofold. For all stop signals studied, the estimated affinity of RF2 for terminating ribosomes is much lower than that of RF1. It is also striking that the affinity of ribosomes for a chromosomally expressed RF2 is at least three times higher than for RF2 isolated from an overproducing E. coli strain.

Initiation factors IF1 and IF2 synergistically remove peptidyl-tRNAs with short polypeptides from the P-site of translating Escherichia coli ribosomes.

A novel function of initiation factors IF1 and IF2 in Escherichia coli translation has been identified. It is shown that these factors efficiently catalyse dissociation of peptidyl-tRNAs with polypeptides of different length from the P-site of E. coli ribosomes, and that the simultaneous presence of both factors is required for induction of drop-off. The factor-induced drop-off occurs with both sense and stop codons in the A-site and competes with peptide elongation or termination. The efficiency with which IF1 and IF2 catalyse drop-off decreases with increasing length of the nascent polypeptide, but is quite significant for hepta-peptidyl-tRNAs, the longest polypeptide chains studied. In the absence of IF1 and IF2 the rate of drop-off varies considerably for different peptidyl-tRNAs, and depends both on the length and sequence of the nascent peptide. Efficient factor-catalysed drop-off requires GTP but not GTP hydrolysis, as shown in experiments without guanine nucleotides, with GDP or with the non-cleavable analogue GMP-PNP.Simultaneous overexpression of IF1 and IF2 in vivo inhibits cell growth specifically in some peptidyl-tRNA hydrolase deficient mutants, suggesting that initiation factor-catalysed drop-off of peptidyl-tRNA can occur on a significant scale in the bacterial cell. Consequences for the bacterial physiology of this previously unknown function of IF1 and IF2 are discussed.

Shutdown in protein synthesis due to the expression of mini-genes in bacteria.

Mutants of Escherichia coli partially deficient in peptidyl-tRNA hydrolase are killed by the expression of certain very short open reading frames (mini-genes), encoded by the wild-type bar regions of phage lambda. According to the current hypothesis, protein synthesis is shut off, and the host cells die, after essential tRNA species become sequestered due to abnormal translation termination (drop-off) of mini-gene-encoded peptides as peptidyl-tRNA. Here we study variants of bar mini-genes, both in vivo and in vitro, in order to identify the structural elements that influence this inhibition of protein synthesis. Three parameters were measured during the expression of these variants: the rates of normal translation termination, peptidyl-tRNA dissociation from the ribosome and hydrolysis of peptidyl-tRNA by peptidyl-tRNA hydrolase were measured. Previous observations that RRF, EF-G and RF3 stimulated drop-off were confirmed and extended; stimulation by these factors can reach 30-fold. Both factor-stimulated and spontaneous drop-off depended on the nature of the stop signal. The degree of inhibition of cell growth following induction of mini-gene expression could be accounted for in terms of a toxicity index comprising the three parameters above. Inhibition was greatly reduced in cells lacking RF3. Mini-genes with more efficient Shine/Dalgarno sequences killed cells even with normal peptidyl-tRNA hydrolase activity. It is proposed that the retranslation by ribosomes of mini-gene transcripts with efficient ribosome binding (Shine/Dalgarno) sequences strongly contributes to the inhibitory effects of mini-gene expression on protein synthesis.

The nucleotide sequence of rpsL and its flanking regions in Salmonella typhimurium.

The ribosomal protein (r-protein)-encoding gene, rpsL, and regions flanking it, from Salmonella typhimurium, have been sequenced directly from polymerase chain reaction-amplified chromosomal DNA. The deduced amino acid sequence is identical to that of the Escherichia coli rpsL encoded r-protein. At the nucleotide level, the similarity is 98%, suggesting a strong pressure for the conservation of this important protein. More surprisingly, the noncoding sequences surrounding the gene are also conserved at the 98% level, suggesting that they too are functionally important.

Codon context and protein synthesis: enhancements of the genetic code.

The sequence around stop codons strongly affects termination efficiency and the probability of alternative events to termination such as frameshifting and stop codon readthrough. Where tRNA suppressors of nonsense codons are present, both the efficiency of suppression and of the termination process appear to be affected by stop codon context. Since context can affect suppressor tRNA function directly, an influence on sense codon translation or suppression might be expected, but has not yet been clearly demonstrated. Statistical analyses of coding sequences indicate non-random contexts for both stop and sense codons, and non-random occurrence of codon pairs. Highly expressed genes show clear preferences among stop codons and their contexts, whereas inefficient stop signals are exploited in a variety of recoding processes.

Protection against non-enzymatic deacylation of Met-tRNA Met m by the ribosome : an approach to the measurement of aminoacyl-tRNA : ribosome affinity constants.

When bound to E. coli 70S ribosomes in the presence of poly (A, U, G) at 37 degrees C, Met-tRNA Met m is hydrolysed 20 times slower than when free in solution under the same conditions (lifetimes of 8.3 h and 22 min respectively). It is shown how this large difference in rate of hydrolysis may be used to study the equilibrium of aminoacyl-tRNA binding to ribosomes.

Missense substitutions lethal to essential functions of EF-Tu.

We have used a simple selection and screening method to isolate function defective mutants of EF-Tu. From 28 mutants tested, 12 different missense substitutions, individually lethal to some essential function of EF-Tu, were identified by sequencing. In addition we found a new non-lethal missense mutation. The frequency of isolation of unique mutations suggests that this method can be used to easily isolate many more. The lethal mutations occur in all three structural domains of EF-Tu, but most are in domain II. We aim to use these mutants to define functional domains on EF-Tu.

Photocrosslinking of thiolated aminoacyl-tRNA to ribosomal RNA and proteins.

tRNA has been converted to a form that can be photoactivated by chemical modification of some of the exposed cytidine residues to thio-4-uridine A certain percentage of the modified molecules can be charged and bound to the ribosome; thiolated fMet-tRNAfMet is bound to the P-site as shown by puromycin reactivity. Near the UV irradiation produces covalent crosslinks between total thiolated AA-tRNA or fMet-tRNAfMet and the ribosome. AA-tRNA becomes crosslinked to both 30S and 50S subunits but fMet-tRNAfMet to 50S subunits alone. In each case, crosslinking of tRNA was found to be not only to ribosomal proteins, but also to rRNA. The covalent complexes appear sufficiently stable to allow identification of the proteins or rRNA sequences involved.

A radioactive assay for the physiological activity of the tryptophan synthetase alpha subunit in crude extracts of Escherichia coli.

A modified assay has been devised for the physiological reaction, indole-3-glycerol phosphate to Trp, of the enzyme tryptophan synthetase. The assay may be applied to crude bacterial extracts, and is based on the measurement of incorporation of radioactivity from [3H]Ser into Trp. Comparison with previous colorimetric assays indicates an improvement in sensitivity of about 30-fold, and advantages in terms of sample economy and simplified manipulation.

Regulation of protein synthesis by minigene expression.

Peptidyl-tRNA hydrolase (Pth), an enzyme essential for Escherichia coli viability, scavenges peptidyl-tRNA released during abortive polypeptide chain elongation. Bacterial strains of E coli partially defective in Pth activity are unable to maintain bacteriophage lambda growth. Phage mutations that overcome the bacterial defect have been located to several regions in the lambda genome named bar. Plasmid constructs expressing just the bar region are toxic and cause a general arrest of protein synthesis in Pth-defective cells. Inspection of the nucleotide sequence from two bar regions reveals the short coding sequence AUG AUA Stop, spaced by an AT-rich segment from a Shine Dalgarno-like sequence (S-D). These sequences have been named minigenes. Base changes altering the putative S-D, the two sense codons, or the stop codon have been found to reduce Bar-toxicity. Transcripts containing bar function as mRNA. Upon expression in pth mutants, wild-type (bar+) transcripts are found associated with ribosomes. In addition, bar+ RNA forms ternary complexes with the 30S ribosomal subunit and the initiator tRNA and can be released upon run-off translation in the same way as an authentic mRNA. A cell free system for protein synthesis reproduces the in vivo effects: bar+ expression inhibits protein synthesis, bar+ RNA sequences are associated with ribosomes in the inhibited extracts, addition of purified Pth restores synthesis, and excess of tRNA(Lys), specific for the last sense codon in a mutant toxic minigene, prevents protein synthesis inhibition. Also, bar expression promotes association of methionine with ribosomes possibly in a translation complex. These results are consistent with a model proposing tRNA starvation to explain the behaviour of a pth mutant, thermosensitive for protein synthesis.

Effect of oligonucleotide AGAGGAGGU on protein synthesis in vitro.

The oligonucleotide AGAGGAGGU, complementary to the 3' end of 16S RNA has been shown to inhibit 70S initiation complex formation on E. coli ribosomes (Taniguchi, T. and Weissmann, C., 1978. Nature, 275, 770-772). We have prepared this nonanucleotide in larger quantities by a combination of DEAE cellulose-urea chromatography and reverse phase (RPC 5) chromatography. The inhibitory effect of AGAGGAGGU on initiation complex formation has been confirmed. Furthermore, when added to a complete system for in vitro protein synthesis, the translation of Q beta RNA was inhibited by the nonanucleotide. No selectivity was observed in the inhibition of the coat protein and replicase protein synthesis. When both Q beta RNA and pAUG were present, some stimulation of pAUG binding to 70S ribosomes was observed on addition of AGAGGAGGU, as previously reported (Taniguchi and Weissmann, ibid). No effect was observed in the absence of Q beta RNA. This observation is discussed.

Interaction between dimeric methionyl-tRNA synthetase and methionine accepting tRNAs from E. coli.-- Studies by partial ribonuclease digestion.

Using different ribonucleases we have studied the digestion pattern of the two methionine accepting tRNAs, the initiator tRNAfMet and the elongator tRNAmMet from E. coli. The positions and intensities of cleavages are compared to those obtained when the tRNAs are complexed to methionyl-tRNA synthetase. Our results, in comparison with other studies, suggest a general pattern of interaction between tRNAs and their cognate synthetases including the amino acid stem and the anticodon region. Furthermore a lack of involvement of the central region and especially the extra arm seems to be a unique feature of the initiator tRNAMetf.

Purification of active Escherichia coli ribosome recycling factor (RRF) from an osmo-regulated expression system.

Ribosome release factor (RRF) from Escherichia coli was overproduced from an osmo-expression vector. More than 40% of cell protein was RRF after 6 h of induction. A purification scheme is described that produced 50 mg of RRF from an initial culture of 2 L. The recycling time for ribosomes synthesising the tripeptide fMet-Phe-Leu in vitro in the absence of RF3 was reduced from 40 to 15 s by the addition of purified 1.5 microM RRF.