Frameshifting by eukaryotic ribosomes during expression of Escherichia coli release factor 2.

Normal translation of the gene for E. coli release factor 2 (RF-2) is characterized by a +1 frameshift event that occurs with 30-50% efficiency. Frameshifting on synthetic RF-2 mRNA by eukaryotic ribosomes has also been observed, even though they lack the capability to interact with the frameshift signal in the same manner as prokaryotic ribosomes. We have mutagenized the sequence of the RF-2 gene to eliminate the need for a frameshift, thereby allowing frameshifting efficiency to be measured by direct comparison of RF-2 production from the mutant with production from the wild-type. Measurements using this approach confirm that frameshifting by rabbit reticulocyte lysate ribosomes occurs at the frameshift region, but with a limited efficiency of approximately 0.4%.     

Frameshift autoregulation in the gene for Escherichia coli release factor 2: partly functional mutants result in frameshift enhancement.

The regulation of release factor 2 (RF-2) synthesis in Escherichia coli occurs, at least in part, through autoregulatory feedback exerted at a unique frameshifting step required during RF-2 translation. We have constructed fusions between the genes for RF-2 and E. coli trpE which make direct measurement of frameshifting efficiency possible since both products of regulation, the termination product and the frameshift product, are stable. The addition of purified RF-2 to in vitro expressions of these fusion genes was found to result in decreased frameshifting and increased termination at the regulation site. The frame-shifted trpE-RF-2 products synthesized from these fusions are unique with respect to their functional release factor activities; when tested in assays of two intermediate steps of translational termination, they were found to be partially active for the function of ribosome binding, but inactive for peptidyl-tRNA hydrolysis (release). These are the first examples of release factor mutants selectively active for only one of these function. In vivo these chimeric proteins promote large increases in frameshifting at the RF-2 frameshift region, thereby reversing normal negative autoregulatory feedback and instead supporting fully efficient frameshifting in their own synthesis. This activity provides new evidence for the importance of ribosomal pausing in directing efficient frameshifting at the RF-2 frameshift region.     

Is the in-frame termination signal of the Escherichia coli release factor-2 frameshift site weakened by a particularly poor context?

The synthesis of release factor-2 (RF-2) in bacteria is regulated by a high efficiency +1 frameshifting event at an in-frame UGA stop codon. The stop codon does not specify the termination of synthesis efficiently because of several upstream stimulators for frameshifting. This study focusses on whether the particular context of the stop codon within the frameshift site of the Escherichia coli RF-2 mRNA contributes to the poor efficiency of termination. The context of UGA in this recoding site is rare at natural termination sites in E.coli genes. We have evaluated how the three nucleotides downstream from the stop codon (+4, +5 and +6 positions) in the native UGACUA sequence affect the competitiveness of the termination codon against the frameshifting event. Changing the C in the +4 position and, separately, the A in the +6 position significantly increase the termination signal strength at the frameshift site, whereas the nucleotide in the +5 position had little influence. The efficiency of particular termination signals as a function of the +4 or +6 nucleotides correlates with how often they occur at natural termination sites in E.coli; strong signals occur more frequently and weak signals are less common.     

Use of tRNA suppressors to probe regulation of Escherichia coli release factor 2

It has been suggested that Escherichia coli release factor 2 (RF-2) translation is autoregulated. Mature RF-2 protein can terminate its own nascent synthesis at an intragenic, in-phase UGA codon, or alternatively, a +1 frameshift can occur that leads to completion of the RF-2 polypeptide. Translational termination presumably increases with RF-2 concentration, providing negative regulatory feedback. We now show, in lacZ/RF-2 fusions, that translation of a UAG codon at the position of the UGA competes with frameshifting, which proves one postulate of the translational autoregulatory model. We also identify a nearby sequence that is required for high-frequency frameshifting and suggest a constraint for the codon preceding the shift point. Both these sequences are incorporated into a model for frameshifting. Our measurements allow us to compute the relative rates in vivo of these reactions: release factor action, frameshifting and tRNA selection at an amber codon.     

Recognition of translational termination signals

Ribosomes can specifically shift at certain codons so that the mRNA is read in two different reading frames. To determine if frameshifting occurs at the level of termination, polymers of defined sequence containing AUG, a coding sequence and an in- or out-of-phase nonsense codon were used to bind a termination substrate or to program synthesis and release of dipeptides in a highly purified in vitro translation system. fMet-tRNA bound to ribosomes with AUGUAA, AUGUAAn, AUGUUU, AUGUUA or AUGUAn was not a substrate for release factor RF-1. In contrast, AUGU1UAA, AUGU3UAAn, AUGU4UAAn, AUGU5UAAn effected RF-1-dependent release of fMet from ribosomes. This suggests that nonsense codons can stimulate release whether they occur in- or out-of-phase. Addition of exogenous UAA and RF-1 stimulated release with all oligonucleotides tested. Propagation restricted the RF-1-dependent recognition of out-of-phase nonsense codons but did not restrict recognition of in-phase UAA in AUGU3UAAn. Release of dipeptides from ribosomes programmed with AUGU4UAAn occurred without EF-G and with a mutant lacking EF-G activity, suggesting that out-of-phase termination can occur prior to translocation outside the ribosomal A-site. We propose that the ribosome X RF complex is required to complete proteins, but is also able to frameshift at a nonsense codon resulting in occasional out-of-phase termination of protein synthesis.     

Overproduction of release factor reduces spontaneous frameshifting and frameshift suppression by mutant elongation factor Tu.

Mutant forms of elongation factor Tu encoded by tufA8 and tufB103 in Salmonella typhimurium cause suppression of some but not all frameshift mutations. All of the suppressed mutations in S. typhimurium have frameshift windows ending in the termination codon UGA. Because both tufA8 and tufB103 are moderately efficient UGA suppressors, we asked whether the efficiency of frameshifting is influenced by the level of misreading at UGA. We introduced plasmids synthesizing either one of the release factors into strains in which the tuf mutations suppress a test frameshift mutation. We found that overproduction of release factor 2 (which catalyzes release at UGA and UAA) reduced frameshifting promoted by the tuf mutations at all sites tested. However, at one of these sites, trpE91, overproduction of release factor 1 also reduced suppression. The spontaneous level of frameshift "leakiness" at three sites in trpE, each terminating in UGA, was reduced in strains carrying the release factor 2 plasmid. We conclude that both spontaneous and suppressor-enhanced reading-frame shifts are influenced by the activity of peptide chain release factors. However, the data suggest that the effect of release factor on frameshifting does not necessarily depend on the presence of the normal triplet termination signal.     

Antisense-induced ribosomal frameshifting

Programmed ribosomal frameshifting provides a mechanism to decode information located in two overlapping reading frames by diverting a proportion of translating ribosomes into a second open reading frame (ORF). The result is the production of two proteins: the product of standard translation from ORF1 and an ORF1–ORF2 fusion protein. Such programmed frameshifting is commonly utilized as a gene expression mechanism in viruses that infect eukaryotic cells and in a subset of cellular genes. RNA secondary structures, consisting of pseudoknots or stem–loops, located downstream of the shift site often act as cis-stimulators of frameshifting. Here, we demonstrate for the first time that antisense oligonucleotides can functionally mimic these RNA structures to induce +1 ribosomal frameshifting when annealed downstream of the frameshift site, UCC UGA. Antisense-induced shifting of the ribosome into the +1 reading frame is highly efficient in both rabbit reticulocyte lysate translation reactions and in cultured mammalian cells. The efficiency of antisense-induced frameshifting at this site is responsive to the sequence context 5′ of the shift site and to polyamine levels.     

Lack of peptide-release activity responding to codon UGA in Mycoplasma capricolum.

In Mycoplasma capricolum, a relative of Gram-positive eubacteria with a high genomic AT-content (75%), codon UGA is assigned to tryptophan instead of termination signal. Thus, in this bacterium the release factor 2 (RF-2), that recognizes UAA and UGA termination codons in eubacteria such as Escherichia coli and Bacillus subtilis, would be either specific to UAA or deleted. To test this, we have constructed a cell-free translation system using synthetic mRNA including codon UAA [mRNA(UAA)], UAG [mRNA(UAG)] and UGA [mRNA(UGA)] in-frame. In the absence of tryptophan, the translation of mRNA(UGA) ceased at UGA sites without appreciable release of the synthesized peptides from the ribosomes, whereas with mRNA(UAA) or mRNA(UAG) the bulk of the peptides was released. Upon addition of the E.coli S-100 fraction or B.subtilis S-100 fraction to the translation system, the synthesized peptides with mRNA(UGA) were almost completely released from the ribosomes, presumably because of the presence of RF-2 active to UGA in the added S-100 fraction. These data suggest that RF-2 is deleted or its activity to UGA is strongly weakened in M.capricolum.     

Requirement for ribosome-releasing factor for the release of ribosomes at the termination codon.

With the use of 3H-labeled R 17 amB2 phage RNA having an UAG codon at the seventh triplet of the coat cistron, release of the RNA from ribosomes at the termination codon was studied. The ribosome-releasing factor previously described was shown to stimulate the process of mRNA release at the termination factor (RF-1). GTP was required for this process and guanosine 5'-(beta,gamma-methylene)triphosphate could not replace GTP. No apparent change of size of R 17 RNA was observed during the release of the R 17 RNA from the ribosomes. The ribosome-releasing factor is distinct from the known termination codon-specific factor such as RF-1.     

Rous sarcoma virus RNA stability requires an open reading frame in the gag gene and sequences downstream of the gag-pol junction.

The intracellular accumulation of the unspliced RNA of Rous sarcoma virus was decreased when translation was prematurely terminated by the introduction of nonsense codons within its 5' proximal gene, the gag gene. Subcellular fractionation of transfected cells suggested that nonsense codon-mediated instability occurred in the cytoplasm. Analysis of constructs containing an in-frame deletion in the nucleocapsid domain of gag, which prevents interaction between the Gag protein and viral RNA, showed that an open reading frame extending to approximately 30 nucleotides from the natural gag termination codon was needed for RNA stability. Sequences at the gag-pol junction necessary for ribosomal frameshifting were not required for RNA stability; however, sequences located 100 to 200 nucleotides downstream of the natural gag termination codon were found to be necessary for stable RNA. The stability of RNAs lacking this downstream sequence was not markedly affected by premature termination codons. We propose that this downstream RNA sequence may interact with ribosomes translating gag to stabilize the RNA.     

Near-cognate peptidyl-tRNAs promote +1 programmed translational frameshifting in yeast

Translational frameshifting is a ubiquitous, if rare, form of alternative decoding in which ribosomes spontaneously shift reading frames during translation elongation. In studying +1 frameshifting in Ty retrotransposons of the yeast S. cerevisiae, we previously showed that unusual P site tRNAs induce frameshifting. The frameshift-inducing tRNAs we show here are near-cognates for the P site codon. Their abnormal decoding induces frameshifting in either of two ways: weak codon-anticodon pairing allows the tRNA to disengage from the mRNA and slip +1, or an unusual codon-anticodon structure interferes with cognate in-frame decoding allowing out-of-frame decoding in the A site. We draw parallels between this mechanism and a proposed mechanism of frameshift suppression by mutant tRNAs.     

Analysis of effects of tRNA:message stability on frameshift frequency at the Escherichia coli RF2 programmed frameshift site.

The codon that is in-frame prior to +1 frameshifting at the E.coli prfB (RF2 gene) frameshift site is randomized to create thirty-two variants. These alleles vary 1000-fold in frameshift-dependent expression in fusions to lacZ. Frameshifting is more frequent at sites where the in-frame codon ends in uridine, as if third position wobble pairs to message uridine facilitate slippage into the +1 frame. Consistent with other studies of programmed frameshift sites, efficient frameshifting depends on stable message:tRNA base pairs after rephasing. For complexes with mispairs, frameshift frequency depends on the nature, number, and position of mispairs. Central purine:purine mispairs are especially inhibitory. Relative stabilities of +1 rephased complexes are estimated from published data on the stabilities of tRNA:tRNA complexes. Stability correlates with frameshifting over its entire range, which suggests that stability is an important determinant of the probability of translation of the rephased complex.     

Role of premature translational termination in the regulation of expression of the phi X174 lysis gene

Expression of the phi X174 lysis (E) gene, a member of an overlapping gene pair, appears to depend on a frameshift-induced chain termination by ribosomes translating the upstream D gene. A -1 reading frameshift, possibly induced by misreading of an alanine codon as a doublet, causes ribosomes to terminate translation at two different sites, suggesting two modes of regulating expression of the E gene. One frameshift can cause translational termination at a stop codon(s) near the E gene ribosome binding site (RBS), resulting in reinitiation by ribosomes at the E gene RBS. Termination at a second site some 70 bases upstream from the E gene RBS, while too far away to allow ribosomal re-initiation at the E gene RBS, probably results in an unmasking of the message, allowing entry of a new ribosome at the E gene RBS.     

Codon recognition in polypeptide chain termination: site directed crosslinking of termination codon to Escherichia coli release factor 2.

An RNA synthesized in vitro was positioned on the Escherichia coli ribosome at the P site with tRNAala, and with a termination codon, UAA, as the next codon in the A site. Such a complex bound stoichiometric amounts of release factor 2 (RF-2); a corresponding RNA with UAC in place of UAA was not a template for the factor. An RNA containing 4-thio-UAA in place of the UAA supported binding of RF-2, and this has allowed site-directed crosslinking from the first position of the termination codon to answer two long standing questions about the termination of protein biosynthesis, the position of the termination codon and its proximity to the release factor during codon recognition. An RF-2.mRNA crosslinked product was detected, indicating the release factor and the termination codon are in close physical contact during the codon recognition event of termination. The 4-thio-U crosslinked also to the ribosome but only to the 30S subunit, and the proteins and the rRNA site concerned were identified. RF-2 decreased significantly the crosslinking to the ribosomal components, but no new crosslink sites were found. If the stop codon was deliberately displaced from the decoding site by one codon's length then a different pattern of crosslinking in particular to the rRNA resulted. These observations are consistent with a model of codon recognition by RF-2 at the decoding site, without a major shift in position of the codon.     

Cloning of the Mycoplasma capricolum gene encoding peptide-chain release factor

In Mycoplasma capricolum (Mc), a relative of Gram⁺ eubacteria with a high genomic A+T-content, the UGA codon is assigned to Trp instead of being a stop codon. We previously showed the lack of peptide-chain release factor (RF) activity in vitro responding to the UGA codon in this bacterium [Inagaki et al., Nucleic Acids Res. 21 (1993) 1335–1338]. To obtain more information on the translation termination mechanism of Mc, we isolated and sequenced the gene encoding RF. The deduced amino-acid sequence has no RF-2-specific + 1 frameshift site and shows 50 and 36% identity to Escherichia coli RF-1 and RF-2, respectively. We conclude that this gene encodes the putative RF-1 which would possess the conserved ‘five-domain’ structure of RF family found in various organisms     

The nucleic acid-binding zinc finger protein of potato virus M is translated by internal initiation as well as by ribosomal frameshifting involving a shifty stop codon and a novel mechanism of P-site slippage.

The genes for the capsid protein CP and the nucleic acid-binding 12K protein (pr12) of potato virus M (PVM) constitute the 3' terminal gene cluster of the PVM RNA genome. Both proteins are presumably translated from a single subgenomic RNA. We have identified two translational strategies operating in pr12 gene expression. Internal initiation at the first and the second AUG codon of the pr12 coding sequence results in the synthesis of the 12K protein. In addition the protein is produced as a CP/12K transframe protein by ribosomal frameshifting. For these studies parts of the CP and pr12 coding sequences including the putative frameshift region were introduced into an internal position of the beta-glucuronidase gene. Mutational analyses in conjunction with in vitro translation experiments identified a homopolymeric string of four adenosine nucleotides which together with a 3' flanking UGA stop codon were required for efficient frameshifting. The signal AAAAUGA is the first frameshift signal with a shifty stop codon to be analyzed in the eukaryotic system. Substitution of the four consecutive adenosine nucleotides by UUUU increased the efficiency of frameshifting, while substitution by GGGG or CCCC dramatically reduced the synthesis of the transframe protein. Also, UAA and UAG could replace the opal stop codon without effect on the frameshifting event, but mutation of UGA to the sense codon UGG inhibited transframe protein formation. These findings suggest that the mechanism of ribosomal frameshifting at the PVM signal is different from the one described by the 'simultaneous slippage' model in that only the string of four adenosine nucleotides represents the slippery sequence involved in a -1 P-site slippage.     

Analysis of tetra- and hepta-nucleotides motifs promoting -1 ribosomal frameshifting in Escherichia coli

Programmed ribosomal -1 frameshifting is a non-standard decoding process occurring when ribosomes encounter a signal embedded in the mRNA of certain eukaryotic and prokaryotic genes. This signal has a mandatory component, the frameshift motif: it is either a Z_ZZN tetramer or a X_XXZ_ZZN heptamer (where ZZZ and XXX are three identical nucleotides) allowing cognate or near-cognate repairing to the -1 frame of the A site or A and P sites tRNAs. Depending on the signal, the frameshifting frequency can vary over a wide range, from less than 1% to more than 50%. The present study combines experimental and bioinformatics approaches to carry out (i) a systematic analysis of the frameshift propensity of all possible motifs (16 Z_ZZN tetramers and 64 X_XXZ_ZZN heptamers) in Escherichia coli and (ii) the identification of genes potentially using this mode of expression amongst 36 Enterobacteriaceae genomes. While motif efficiency varies widely, a major distinctive rule of bacterial -1 frameshifting is that the most efficient motifs are those allowing cognate re-pairing of the A site tRNA from ZZN to ZZZ. The outcome of the genomic search is a set of 69 gene clusters, 59 of which constitute new candidates for functional utilization of -1 frameshifting.