ArfA Recruits RF2 into Stalled Ribosomes

During translation in Escherichia coli, the ribosome rescue factor YaeJ and the alternative ribosome rescue factor (ArfA, previously called YhdL) can release stalled ribosomes from mRNA. Here, I used a reconstituted cell-free protein synthesis system to examine YaeJ- and ArfA-dependent recycling of stalled ribosomes, in which mRNA lacks in-frame stop codons. It is shown that YaeJ alone could recycle the ribosome but that ArfA required the presence of release factor 2 (RF2). Furthermore, I show that RF2 binds to stalled ribosomes only in the presence of ArfA, demonstrating that ArfA recruits RF2 into the A site of the ribosome to facilitate peptidyl-tRNA hydrolysis. It is also demonstrated that the efficiency of the ArfA-dependent process decreases rapidly with an increase in mRNA length downstream of the A site of the ribosome whereas YaeJ function is maintained on mRNA with sufficient length. From the results, I discuss differences of in vivo roles of these two systems in addition to the well-known tmRNA-dependent trans-translation system.     

Protein synthesis factors (RF1, RF2, RF3, RRF, and tmRNA) and peptidyl-tRNA hydrolase rescue stalled ribosomes at sense codons

During translation, ribosomes stall on mRNA when the aminoacyl-tRNA to be read is not readily available. The stalled ribosomes are deleterious to the cell and should be rescued to maintain its viability. To investigate the contribution of some of the cellular translation factors on ribosome rescuing, we provoked stalling at AGA codons in mutants that affected the factors and then analyzed the accumulation of oligopeptidyl (peptides of up to 6 amino acid residues, oligopep-)-tRNA or polypeptidyl (peptides of more than 300 amino acids in length, polypep-)-tRNA associated with ribosomes. Stalling was achieved by starvation for aminoacyl-tRNA(Arg4) upon induced expression of engineered lacZ (β-galactosidase) reporter gene harboring contiguous AGA codons close to the initiation codon or at internal codon positions together with minigene ATGAGATAA accompanied by reduced peptidyl-tRNA hydrolase (Pth). Our results showed accumulations of peptidyl-tRNA associated with ribosomes in mutants for release factors (RF1, RF2, and RF3), ribosome recycling factor (RRF), Pth, and transfer-messenger RNA (tmRNA), implying that each of these factors cooperate in rescuing stalled ribosomes. The role of these factors in ribosome releasing from the stalled complex may vary depending on the length of the peptide in the peptidyl-tRNA. RF3 and RRF rescue stalled ribosomes by "drop-off" of peptidyl-tRNA, while RF1, RF2 (in the absence of termination codon), or Pth may rescue by hydrolyzing the associated peptidyl-tRNA. This is followed by the disassembly of the ribosomal complex of tRNA and mRNA by RRF and elongation factor G.     

ArfA recognizes the lack of mRNA in the mRNA channel after RF2 binding for ribosome rescue

Although trans-translation mediated by tmRNA-SmpB has long been known as the sole system to relieve bacterial stalled ribosomes, ArfA has recently been identified as an alternative factor for ribosome rescue in Escherichia coli. This process requires hydrolysis of nascent peptidyl-tRNA by RF2, which usually acts as a stop codon-specific peptide release factor. It poses a fascinating question of how ArfA and RF2 recognize and rescue the stalled ribosome. Here, we mapped the location of ArfA in the stalled ribosome by directed hydroxyl radical probing. It revealed an ArfA-binding site around the neck region of the 30S subunit in which the N- and C-terminal regions of ArfA are close to the decoding center and the mRNA entry channel, respectively. ArfA and RF2 sequentially enter the ribosome stalled in either the middle or 3′ end of mRNA, whereas RF2 induces a productive conformational change of ArfA only when ribosome is stalled at the 3′ end of mRNA. On the basis of these results, we propose that ArfA functions as the sensor to recognize the target ribosome after RF2 binding.     

YaeJ is a novel ribosome-associated protein in Escherichia coli that can hydrolyze peptidyl-tRNA on stalled ribosomes

In bacteria, ribosomes often become stalled and are released by a trans-translation process mediated by transfer-messenger RNA (tmRNA). In the absence of tmRNA, however, there is evidence that stalled ribosomes are released from non-stop mRNAs. Here, we show a novel ribosome rescue system mediated by a small basic protein, YaeJ, from Escherichia coli, which is similar in sequence and structure to the catalytic domain 3 of polypeptide chain release factor (RF). In vitro translation experiments using the E. coli-based reconstituted cell-free protein synthesis system revealed that YaeJ can hydrolyze peptidyl–tRNA on ribosomes stalled by both non-stop mRNAs and mRNAs containing rare codon clusters that extend downstream from the P-site and prevent Ala-tmRNA•SmpB from entering the empty A-site. In addition, YaeJ had no effect on translation of a normal mRNA with a stop codon. These results suggested a novel tmRNA-independent rescue system for stalled ribosomes in E. coli. YaeJ was almost exclusively found in the 70S ribosome and polysome fractions after sucrose density gradient sedimentation, but was virtually undetectable in soluble fractions. The C-terminal basic residue-rich extension was also found to be required for ribosome binding. These findings suggest that YaeJ functions as a ribosome-attached rescue device for stalled ribosomes.     

Live virus-free or die: coupling of antivirus immunity and programmed suicide or dormancy in prokaryotes

Background

mtRF1 is a vertebrate mitochondrial protein with an unknown function that arose from a duplication of the mitochondrial release factor mtRF1a. To elucidate the function of mtRF1, we determined the positions that are conserved among mtRF1 sequences but that are different in their mtRF1a paralogs. We subsequently modeled the 3D structure of mtRF1a and mtRF1 bound to the ribosome, highlighting the structural implications of these differences to derive a hypothesis for the function of mtRF1.

Results

Our model predicts, in agreement with the experimental data, that the 3D structure of mtRF1a allows it to recognize the stop codons UAA and UAG in the A-site of the ribosome. In contrast, we show that mtRF1 likely can only bind the ribosome when the A-site is devoid of mRNA. Furthermore, while mtRF1a will adopt its catalytic conformation, in which it functions as a peptidyl-tRNA hydrolase in the ribosome, only upon binding of a stop codon in the A-site, mtRF1 appears specifically adapted to assume this extended, peptidyl-tRNA hydrolyzing conformation in the absence of mRNA in the A-site.

Conclusions

We predict that mtRF1 specifically recognizes ribosomes with an empty A-site and is able to function as a peptidyl-tRNA hydrolase in those situations. Stalled ribosomes with empty A-sites that still contain a tRNA bound to a peptide chain can result from the translation of truncated, stop-codon less mRNAs. We hypothesize that mtRF1 recycles such stalled ribosomes, performing a function that is analogous to that of tmRNA in bacteria.

Reviewers

This article was reviewed by Dr. Eugene Koonin, Prof. Knud H. Nierhaus (nominated by Dr. Sarah Teichmann) and Dr. Shamil Sunyaev.     

Reconstitution of mammalian mitochondrial translation system capable of correct initiation and long polypeptide synthesis from leaderless mRNA

Mammalian mitochondria have their own dedicated protein synthesis system, which produces 13 essential subunits of the oxidative phosphorylation complexes. We have reconstituted an in vitro translation system from mammalian mitochondria, utilizing purified recombinant mitochondrial translation factors, 55S ribosomes from pig liver mitochondria, and a tRNA mixture from either Escherichia coli or yeast. The system is capable of translating leaderless mRNAs encoding model proteins (DHFR and nanoLuciferase) or some mtDNA-encoded proteins. We show that a leaderless mRNA, encoding nanoLuciferase, is faithfully initiated without the need for any auxiliary factors other than IF-2mt and IF-3mt. We found that the ribosome-dependent GTPase activities of both the translocase EF-G1mt and the recycling factor EF-G2mt are insensitive to fusidic acid (FA), the translation inhibitor that targets bacterial EF-G homologs, and consequently the system is resistant to FA. Moreover, we demonstrate that a polyproline sequence in the protein causes 55S mitochondrial ribosome stalling, yielding ribosome nascent chain complexes. Analyses of the effects of the Mg concentration on the polyproline-mediated ribosome stalling suggested the unique regulation of peptide elongation by the mitoribosome. This system will be useful for analyzing the mechanism of translation initiation, and the interactions between the nascent peptide chain and the mitochondrial ribosome.     

Identification of residues required for stalled-ribosome rescue in the codon-independent release factor YaeJ

The YaeJ protein is a codon-independent release factor with peptidyl-tRNA hydrolysis (PTH) activity, and functions as a stalled-ribosome rescue factor in Escherichia coli. To identify residues required for YaeJ function, we performed mutational analysis for in vitro PTH activity towards rescue of ribosomes stalled on a non-stop mRNA, and for ribosome-binding efficiency. We focused on residues conserved among bacterial YaeJ proteins. Additionally, we determined the solution structure of the GGQ domain of YaeJ from E. coli using nuclear magnetic resonance spectroscopy. YaeJ and a human homolog, ICT1, had similar levels of PTH activity, despite various differences in sequence and structure. While no YaeJ-specific residues important for PTH activity occur in the structured GGQ domain, Arg118, Leu119, Lys122, Lys129 and Arg132 in the following C-terminal extension were required for PTH activity. All of these residues are completely conserved among bacteria. The equivalent residues were also found in the C-terminal extension of ICT1, allowing an appropriate sequence alignment between YaeJ and ICT1 proteins from various species. Single amino acid substitutions for each of these residues significantly decreased ribosome-binding efficiency. These biochemical findings provide clues to understanding how YaeJ enters the A-site of stalled ribosomes.     

Solution Structure of the Catalytic Domain of the Mitochondrial Protein ICT1 That Is Essential for Cell Vitality

The ICT1 protein was recently reported to be a component of the human mitoribosome and to have codon-independent peptidyl-tRNA hydrolysis activity via its conserved GGQ motif, although little is known about the detailed mechanism. Here, using NMR spectroscopy, we determined the solution structure of the catalytic domain of the mouse ICT1 protein that lacks an N-terminal mitochondrial targeting signal and an unstructured C-terminal basic-residue-rich extension, and we examined the effect of ICT1 knockdown (mediated by small interfering RNA) on mitochondria in HeLa cells using flow cytometry. The catalytic domain comprising residues 69-162 of the 206-residue full-length protein forms a structure with a β1-β2-α1-β3-α2 topology and a structural framework that resembles the structure of GGQ-containing domain 3 of class 1 release factors (RFs). Half of the structure, including the GGQ-containing loop, has essentially the same sequence and structure as those in RFs, consistent with the peptidyl-tRNA hydrolysis activity of ICT1 on the mitoribosome, which is analogous to RFs. However, the other half of the structure differs in shape from the corresponding part of RF domain 3 in that in ICT1, an α-helix (α1), instead of a β-turn, is inserted between strand β2 and strand β3. A characteristic groove formed between α1 and the three-stranded antiparallel β-sheet was identified as a putative ICT1-specific functional site by a structure-based alignment. In addition, the structured domain that recognizes stop codons in RFs is replaced in ICT1 by a C-terminal basic-residue-rich extension. It appears that these differences are linked to a specific function of ICT1 other than the translation termination mediated by RFs. Flow cytometry analysis showed that the knockdown of ICT1 results in apoptotic cell death with a decrease in mitochondrial membrane potential and mass. In addition, cytochrome c oxidase activity in ICT1 knockdown cells was decreased by 35% compared to that in control cells. These results indicate that ICT1 function is essential for cell vitality and mitochondrial function.     

Structural basis of l-tryptophan-dependent inhibition of release factor 2 by the TnaC arrest peptide

In Escherichia coli, elevated levels of free l-tryptophan (l-Trp) promote translational arrest of the TnaC peptide by inhibiting its termination. However, the mechanism by which translation-termination by the UGA-specific decoding release factor 2 (RF2) is inhibited at the UGA stop codon of stalled TnaC-ribosome-nascent chain complexes has so far been ambiguous. This study presents cryo-EM structures for ribosomes stalled by TnaC in the absence and presence of RF2 at average resolutions of 2.9 and 3.5 Å, respectively. Stalled TnaC assumes a distinct conformation composed of two small α-helices that act together with residues in the peptide exit tunnel (PET) to coordinate a single L-Trp molecule. In addition, while the peptidyl-transferase center (PTC) is locked in a conformation that allows RF2 to adopt its canonical position in the ribosome, it prevents the conserved and catalytically essential GGQ motif of RF2 from adopting its active conformation in the PTC. This explains how translation of the TnaC peptide effectively allows the ribosome to function as a L-Trp-specific small-molecule sensor that regulates the tnaCAB operon.     

ArfA recruits release factor 2 to rescue stalled ribosomes by peptidyl‐tRNA hydrolysis in Escherichia coli

The ribosomes stalled at the end of non‐stop mRNAs must be rescued for productive cycles of cellular protein synthesis. Escherichia coli possesses at least three independent mechanisms that resolve non‐productive translation complexes (NTCs). While tmRNA (SsrA) mediates trans‐translation to terminate translation, ArfA (YhdL) and ArfB (YaeJ) induce hydrolysis of ribosome‐tethered peptidyl‐tRNAs. ArfB is a paralogue of the release factors (RFs) and directly catalyses the peptidyl‐tRNA hydrolysis within NTCs. In contrast, the mechanism of the ArfA action had remained obscure beyond its ability to bind to the ribosome. Here, we characterized the ArfA pathway of NTC resolution in vitro and identified RF2 as a factor that cooperates with ArfA to hydrolyse peptidyl‐tRNAs located in the P‐site of the stalled ribosome. This reaction required the GGQ (Gly–Gly–Gln) hydrolysis motif, but not the SPF (Ser–Pro–Phe) codon–recognition sequence, of RF2 and was stimulated by tRNAs. From these results we suggest that ArfA binds to the vacant A‐site of the stalled ribosome with possible aid from association with a tRNA, and then recruits RF2, which hydrolyses peptidyl‐tRNA in a GGQ motif‐dependent but codon‐independent manner. In support of this model, the ArfA‐RF2 pathway did not act on the SecM‐arrested ribosome, which contains an aminoacyl‐tRNA in the A‐site.     

Emerging views on tmRNA-mediated protein tagging and ribosome rescue

Transfer-messenger RNA (tmRNA), also known as SsrA or 10Sa RNA, is a bacterial ribonucleic acid that recycles 70S ribosomes stalled on problematic messenger RNAs (mRNAs) and also contributes to the degradation of incompletely synthesized peptides. tmRNA acts initially as transfer RNA (tRNA), being aminoacylated at its 3'-end by alanyl-tRNA synthetase, to add alanine to the stalled polypeptide chain. Resumption of translation ensues not on the mRNA on which the ribosomes were stalled but at an internal position in tmRNA. Termination soon occurs, tmRNA recruiting the appropriate termination factors allowing the release of the tagged protein that is subsequently recognized and degraded by specific cytoplasmic and periplasmic proteases, and permits ribosome recycling. Recent data suggest that tmRNA tags bacterial proteins in three other instances; when ribosomes stall at internal sites; during 'readthrough' of canonical termination codons; and when ribosomes are at the termination codon of intact messages. The importance of bacterial tmRNAs for survival, growth under stress, and pathogenesis is also discussed. Recent in vivo and in vitro studies have identified novel ligands of tmRNA. Based on the available experimental evidences, an updated model of tmRNA mediated protein tagging and ribosome rescue in bacteria is presented.     

Quantitative analysis of in vivo ribosomal events at UGA and UAG stop codons.

An in vivo translation assay system has been designed to measure, in one and the same assay, the three alternatives for a ribosome poised at a stop codon (termination, read-through and frameshift). A quantitative analysis of the competition has been done in the presence and absence of release factor (RF) mutants, nonsense suppressors and an upstream Shine-Dalgarno-like sequence. The ribosomal +1 frameshift product is measurable when the stop codon is decoded by wild-type or mutant RF (prf A1 or prf B2) and also in the presence of competing suppressor tRNAs. Frameshift frequency appears to be influenced by RF activity. The amount of frameshift product decreases in the presence of competing suppressor tRNAs, however, this decrease is not in proportion to the corresponding increase in the suppression product. Instead, there is an increase in the total amount of protein expressed from the gene, perhaps due to the purging of queued ribosomes. Mutated RFs reduce the total output of the reporter gene by reducing the amount of all three protein products. The nascent peptide has earlier been shown to influence the translation termination process by interacting with the RFs. At 42 degrees C in a temperature-sensitive RF mutant strain, protein measurements indicate that the nascent peptide seems to influence the binding efficiencies of the RFs.     

Inhibition of peptide chain termination by antibodies specific for ribosomal proteins

The effects of antibodies specific for the Escherichia coli 30 S and 50 S ribosomal proteins have been determined for in vitro peptide chain termination and two partial reactions, the codon-directed binding of E. coli release factor to the ribosome and peptidyl-tRNA hydrolysis with RF². Antibodies to ribosomal proteins L7 and L12 inhibit the initial binding of RF to the ribosome, and as a result, the subsequent peptidyl-tRNA hydrolysis. The kinetics of ribosomal inactivation for in vitro termination by anti-L7/L12 indicate that Fab fragments bind to three ribosome sites, and suggest that each of three copies of L7/L12 is involved in the binding of RF to the ribosome. When 70 S ribosome substrates are pretreated with anti-L11 and anti-L16 RF-dependent peptidyl-tRNA, hydrolysis is partially inhibited but the interaction of RF with the ribosome is not affected. The inactivation of in vitro termination by a mixture of anti-L11 and anti-L16 is not co-operative. Pretreatment of the 30 S ribosomal subunit (but not 70 S ribosomal substrate) with antibodies to the 30 S proteins, S9 and S11, results in strong inhibition of codon-directed hydrolysis of peptidyl-tRNA. While these antibodies inhibit ribosome subunit association, a requirement for peptide chain termination, and thereby may inhibit the in vitro termination reactions indirectly, the codon-directed binding of RF is markedly more affected than peptidyl-tRNA hydrolysis by anti-S9 and anti-S11. Antibody to S2 and anti-S3 exhibit a similar but less marked differential effect on the partial reactions of in vitro termination under the same conditions. When dissociated ribosomes are pretreated with anti-L11, in vitro termination is completely inhibited and both codon-directed binding of RF and peptidyl-tRNA hydrolysis are affected. L11 may, therefore, be at or near the interface between the ribosome subunits and like S9 and S11 not completely accessible to antibody in 70 S ribosomes. Pretreatment of dissociated ribosomes with antibodies to a number of other ribosomal proteins (L2, L4, L6, L14, L15, L17, L18, L20, L23, L26, L27) results in partial inhibition of all termination reactions although these antibodies have no effect on termination when incubated with 70 S ribosome substrates. The antibodies probably affect in vitro termination indirectly as a result of either preventing correct ribosome subunit association, or preventing correct positioning of the fMet-tRNA at the ribosome P site.     

A physiological connection between tmRNA and peptidyl-tRNA hydrolase functions in Escherichia coli

The bacterial ssrA gene codes for a dual function RNA, tmRNA, which possesses tRNA-like and mRNA-like regions. The tmRNA appends an oligopeptide tag to the polypeptide on the P-site tRNA by a trans-translation process that rescues ribosomes stalled on the mRNAs and targets the aberrant protein for degradation. In cells, processing of the stalled ribosomes is also pioneered by drop-off of peptidyl-tRNAs. The ester bond linking the peptide to tRNA is hydrolyzed by peptidyl-tRNA hydrolase (Pth), an essential enzyme, which releases the tRNA and the aberrant peptide. As the trans-translation mechanism utilizes the peptidyl-transferase activity of the stalled ribosomes to free the tRNA (as opposed to peptidyl-tRNA drop-off), the need for Pth to recycle such tRNAs is bypassed. Thus, we hypothesized that tmRNA may rescue a defect in Pth. Here, we show that overexpression of tmRNA rescues the temperature-sensitive phenotype of Escherichia coli (pth^ts). Conversely, a null mutation in ssrA enhances the temperature-sensitive phenotype of the pth^ts strain. Consistent with our hypothesis, overexpression of tmRNA results in decreased accumulation of peptidyl-tRNA in E.coli. Furthermore, overproduction of tmRNA in E.coli strains deficient in ribosome recycling factor and/or lacking the release factor 3 enhances the rescue of pth^ts strains. We discuss the physiological relevance of these observations to highlight a major role of tmRNA in decreasing cellular peptidyl-tRNA load.     

Alternative fates of paused ribosomes during translation termination

The bacterial tmRNA·SmpB system facilitates recycling of stalled translational complexes in a process termed "ribosome rescue." During ribosome rescue, the nascent chain is tagged with the tmRNA-encoded ssrA peptide, which targets the tagged polypeptide for degradation. Translational pausing also induces a variety of recoding events such as frameshifts, ribosome hops, and stop codon readthrough. To examine the interplay between recoding and ribosome rescue, we determined the various fates of ribosomes that pause during translation termination. We expressed a model protein containing the C-terminal Asp-Pro nascent peptide motif (which interferes with translation termination) and quantified the protein chains produced by recoding and ssrA-peptide tagging. The nature and extent of translational recoding depended upon the codon for the C-terminal Pro residue, with CCU and CCC promoting efficient +1 frameshifting. In contrast, ssrA-peptide tagging was unaffected by C-terminal Pro coding. Moreover, +1 frameshifting was not suppressed by tmRNA·SmpB activity, suggesting that recoding and ribosome rescue are not competing events. However, cells lacking ribosomal protein L9 (ΔL9) exhibited a significant increase in recoding and a concomitant decrease in ssrA-peptide tagging. Pulse-chase analysis revealed that pre-termination ribosomes turn over more rapidly in ΔL9 cells, suggesting that increased recoding alleviates the translational arrest. Together, these results indicate that tmRNA·SmpB does not suppress transient ribosome pauses, but responds to prolonged translational arrest.