Stepping transfer messenger RNA through the ribosome

tmRNA (transfer messenger RNA) is a unique molecule used by all bacteria to rescue stalled ribosomes and to mark unfinished peptides with a specific degradation signal. tmRNA is recruited by arrested ribosomes in which it facilitates the translational switch from cellular mRNA to the mRNA part of tmRNA. Small protein B (SmpB) is a key partner for the trans-translation activity of tmRNA both in vivo and in vitro. It was shown that SmpB acts at the initiation step of the trans-translation process by facilitating tmRNA aminoacylation and binding to the ribosome. Little is known about the subsequent steps of trans-translation. Here we demonstrated the first example of an investigation of tmRNA.ribosome complexes at different stages of trans-translation. Our results show that the structural element at the position of tmRNA pseudoknot 3 remains intact during the translation of the mRNA module of tmRNA and that it is localized on the surface of the ribosome. At least one SmpB molecule remains bound to a ribosome.tmRNA complex isolated from the cell when translation is blocked at different positions within the mRNA part of tmRNA.     

Protein tagging at rare codons is caused by tmRNA action at the 3' end of nonstop mRNA generated in response to ribosome stalling

It has been believed that protein tagging caused by consecutive rare codons involves tmRNA action at the internal mRNA site. We demonstrated previously that ribosome stalling either at sense or stop codons caused by certain arrest sequences could induce mRNA cleavage near the arrest site, resulting in nonstop mRNAs that are recognized by tmRNA. These findings prompted us to re-examine the mechanism of tmRNA tagging at a run of rare codons. We report here that either AGG or CGA but not AGA arginine rare-codon clusters inserted into a model crp mRNA encoding cAMP receptor protein (CRP) could cause an efficient protein tagging. We demonstrate that more than three consecutive AGG codons are needed to induce an efficient ribosome stalling therefore tmRNA tagging in our system. The tmRNA tagging was eliminated by overproduction of tRNAs corresponding to rare codons, indicating that a scarcity of the corresponding tRNA caused by the rare-codon cluster is an important factor for tmRNA tagging. Mass spectrometry analyses of proteins generated in cells lacking or possessing tmRNA encoding a protease-resistant tag sequence indicated that the truncation and tmRNA tagging occur within the cluster of rare codons. Northern and S1 analyses demonstrated that nonstop mRNAs truncated within the rare-codon clusters are detected in cells lacking tmRNA but not in cells expressing tmRNA. We conclude that a ribosome stalled by the rare codon induces mRNA cleavage, resulting in nonstop mRNAs that are recognized by tmRNA.     

Novel factor rescues ribosomes trapped on non-stop mRNAs

Ribosomes are trapped at the 3′ ends of mRNAs that lack a natural stop codon. In bacteria, a reaction called trans-translation recycles ribosomes entrapped at such ‘non-stop’ mRNAs. The main player in trans-translation is tmRNA (SsrA-RNA), a bi-functional RNA that acts as both a tRNA and an mRNA. In the trans-translation reaction, alanine-charged tmRNA loads at the ribosomal A-site and translation shifts to the resume codon in tmRNA. Translation of tmRNA stops at a natural stop codon at the end of the small reading frame of tmRNA. In this way, the reaction simultaneously adds a peptide tag to the end of the nascent, incomplete polypeptide and recycles the stalled ribosomes. The peptide tag is recognized by cellular proteases that rapidly degrade the incomplete, potentially harmful polypeptides. The trans-translation reaction is not essential in most bacteria, raising the possibility that ribosomes stalled at non-stop mRNAs can be rescued by alternative routes. In this issue of Molecular Microbiology, Chadani et al. show that a novel translation factor, ArfA, can recycle a ribosome trapped at the 3′ end of a non-stop mRNA in the absence of trans-translation. AfrA is essential in the absence of tmRNA, showing that the two systems work in parallel to resolve stalled ribosomes.     

Functional SmpB-ribosome interactions require tmRNA

Small protein B (SmpB) is a requisite component of the transfer messenger RNA (tmRNA)-mediated bacterial translational quality control system known as trans-translation. The initial binding of tmRNA and its subsequent accommodation into the ribosomal A-site are activities intimately linked to SmpB protein function. From a mechanistic perspective, two key unanswered questions that require further investigation are: 1) what constitutes a stalled ribosome recognition complex and 2) does SmpB pre-bind ribosomes to recruit tmRNA. We have assessed, both in vivo and in vitro, the nature and stability of free SmpB interactions with stalled ribosomes and examined whether these interactions are functionally relevant. We present evidence to demonstrate that interaction of free SmpB with ribosomes is salt sensitive and significantly more labile than interaction of the SmpB.tmRNA complex with ribosomes. Upon dissociation of 70 S ribosomes SmpB partitions primarily with tmRNA rather than ribosomal subunits. This finding is consistent with biochemical and structural data demonstrating that tmRNA is the high-affinity binding partner of SmpB. Moreover, we show that under normal physiological conditions roughly similar numbers of SmpB and tmRNA molecules are present in cells. Our investigations also reveal that upon induction of a nonstop mRNA, SmpB is enriched in stalled ribosome fractions only in the presence of tmRNA. Based on these findings, we conclude that SmpB does not pre-bind stalled ribosome and that functional SmpB-stalled ribosome interactions require tmRNA. We propose that a 1:1:1 complex of SmpB.tmRNA.EF-Tu(GTP) recognizes and binds a stalled ribosome to initiate trans-translation.     

tmRNA·SmpB complex mimics native aminoacyl-tRNAs in the A site of stalled ribosomes

Bacterial ribosomes stalled on faulty, often truncated, mRNAs lacking stop codons are rescued by trans-translation. It relies on an RNA molecule (tmRNA) capable of replacing the faulty mRNA with its own open reading frame (ORF). Translation of tmRNA ORF results in the tagging of faulty protein for degradation and its release from the ribosome. We used single-particle cryo-electron microscopy to visualize tmRNA together with its helper protein SmpB on the 70S Escherichia coli ribosome in states subsequent to GTP hydrolysis on elongation factor Tu (EF-Tu). Three-dimensional reconstruction and heterogeneity analysis resulted in a 15 Å resolution structure of the tmRNA·SmpB complex accommodated in the A site of the ribosome, which shows that SmpB mimics the anticodon- and D-stem of native tRNAs missing in the tRNA-like domain of tmRNA. We conclude that the tmRNA·SmpB complex accommodates in the ribosomal A site very much like an aminoacyl-tRNA during protein elongation.     

Resuming translation on tmRNA: a unique mode of determining a reading frame.

The bacterial ribosome switches from an mRNA lacking an in-frame stop codon and resumes translation on a specialized RNA known as tmRNA, SsrA or 10Sa RNA. We find that the ribosome can reach and use the extreme 3' terminal codon of the defective mRNA prior to switching. The first triplet to be translated in tmRNA (the resume codon) is determined at two levels: distant elements in tmRNA restrict resume codon choice to a narrow window and local upstream elements provide precision. Insights from a randomization-selection experiment secure the alignment of tmRNA sequences from diverse species. The triplet UA(A/G) (normally recognized as a stop codon by release factor-1) is strongly conserved two nucleotides upstream of the resume codon. The central adenosine of this triplet is essential for tmRNA activity. The reading frame of tmRNA is determined differently from all other known reading frames in that the first translated codon is not specified by a particular tRNA anticodon.     

Ribosomal protein S1 influences trans-translation in vitro and in vivo

When the bacterial ribosome stalls on a truncated mRNA, transfer–messenger RNA (tmRNA) acts initially as a transfer RNA (tRNA) and then as a messenger RNA (mRNA) to rescue the ribosome and add a peptide tag to the nascent polypeptide that targets it for degradation. Ribosomal protein S1 binds tmRNA but its functional role in this process has remained elusive. In this report, we demonstrate that, in vitro, S1 is dispensable for the tRNA-like role of tmRNA but is essential for its mRNA function. Increasing or decreasing the amount of protein S1 in vivo reduces the overall amount of trans-translated proteins. Also, a truncated S1 protein impaired for ribosome binding can still trigger protein tagging, suggesting that S1 interacts with tmRNA outside the ribosome to keep it in an active state. Overall, these results demonstrate that S1 has a role in tmRNA-mediated tagging that is distinct from its role during canonical translation.     

SmpB triggers GTP hydrolysis of elongation factor Tu on ribosomes by compensating for the lack of codon-anticodon interaction during trans-translation initiation

Bacterial tmRNA rescues ribosomes that stall because of defective mRNAs via the trans-translation process. Although entry of the charged transfer messenger RNA (tmRNA) into the ribosome proceeded in the absence of elongation factor (EF-Tu) and in the presence of EF-Tu and the antibiotic kirromycin, evidence was found for the involvement of EF-Tu in trans-translation initiation. The polyalanine synthesis system attained by using a tmRNA variant consisting of only the tRNA-like domain revealed that it was completely dependent on the presence of SmpB and greatly enhanced by EF-Tu and EF-G. Actually, ribosome-dependent GTPase activity of EF-Tu was stimulated by the addition of SmpB and tmRNA but independently of template mRNA, demonstrating that SmpB compensates for the lack of codon-anticodon interaction during the first step of the trans-translation initiation. Based on these results, we suggest that SmpB structurally mimics the anticodon arm of tRNA and elicits GTP hydrolysis of EF-Tu upon tmRNA accommodation in the A site of the ribosome.     

Ribosome stalling during translation elongation induces cleavage of mRNA being translated in Escherichia coli

Recently, it has been found that ribosome pausing at stop codons caused by certain nascent peptides induces cleavage of mRNA in Escherichia coli cells (1, 2). The question we addressed in the present study is whether mRNA cleavage occurs when translation elongation is prevented. We focused on a specific peptide sequence (AS17), derived from SecM, that is known to cause elongation arrest. When the crp-crr fusion gene encoding CRP-AS17-IIA(Glc) was expressed, cAMP receptor protein (CRP) proteins truncated around the arrest sequence were efficiently produced, and they were tagged by the transfer-messenger RNA (tmRNA) system. Northern blot analysis revealed that both truncated upstream crp and downstream crr mRNAs were generated along with reduced amounts of the full-length crp-crr mRNA. The truncated crp mRNA dramatically decreased in the presence of tmRNA due to rapid degradation. The 3' ends of truncated crp mRNA correspond well to the C termini of the truncated CRP proteins. We conclude that ribosome stalling by the arrest sequence induces mRNA cleavage near the arrest point, resulting in nonstop mRNAs that are recognized by tmRNA. We propose that the mRNA cleavage induced by ribosome stalling acts in concert with the tmRNA system as a way to ensure quality control of protein synthesis and possibly to regulate the expression of certain genes.     

In vitro trans-translation of Thermus thermophilus: ribosomal protein S1 is not required for the early stage of trans-translation

Transfer-messenger RNA (tmRNA) plays a dual role as a tRNA and an mRNA in trans-translation, during which the ribosome replaces mRNA with tmRNA encoding the tag-peptide. These processes have been suggested to involve several tmRNA-binding proteins, including SmpB and ribosomal protein S1. To investigate the molecular mechanism of trans-translation, we developed in vitro systems using purified ribosome, elongation factors, tmRNA and SmpB from Thermus thermophilus. A stalled ribosome in complex with polyphenylalanyl-tRNA(Phe) was prepared as a target of tmRNA. A peptidyl transfer reaction from polyphenylalanyl-tRNA(Phe) to alanyl-tmRNA was observed in an SmpB-dependent manner. The next peptidyl transfer to aminoacyl-tRNA occurred specifically to the putative resume codon for the tag-peptide, which was confirmed by introducing a mutation in the codon. Thus, the in vitro systems developed in this study are useful to investigate the early steps of trans-translation. Using these in vitro systems, we investigated the function of ribosomal protein S1, which has been believed to play a role in trans-translation. Although T. thermophilus S1 tightly bound to tmRNA, as in the case of Escherichia coli S1, it had little or no effect on the early steps of trans-translation.     

Structure probing of tmRNA in distinct stages of trans-translation

Ribosomes stalled on problematic mRNAs in bacterial cells can be rescued by transfer-messenger RNA (tmRNA), its helper protein (small protein B, SmpB), and elongation factor Tu (EF-Tu) through a mechanism called trans-translation. In this work we used lead(II) footprinting to probe the interactions of tmRNA with SmpB and other components of the translation machinery at different steps of the trans-translation cycle. Ribosomes with a short nascent peptide stalled on a truncated mRNA were reacted with Ala-tmRNA*EF-Tu*GTP, SmpB, and other translation components to initiate and execute trans-translation. Free tmRNA was probed with lead(II) acetate with and without SmpB, and ribosome bound tmRNA was probed in one of four different trans-translation states stabilized by antibiotic addition or selective exclusion of translation components. For comparison, we also analyzed lead(II) cleavage patterns of tmRNA in vivo in a wild-type as well as in an SmpB-deficient Escherichia coli strain. We observed some specific cleavages/protections in tmRNA for the individual steps of trans-translation, but the overall tmRNA conformation appeared to be similar in the stages analyzed. Our findings suggest that, in vivo, a dominant fraction of tmRNA is in complex with SmpB and that, in vitro, SmpB remains tmRNA bound at the initial steps of trans-translation.     

tmRNA-induced release of messenger RNA from stalled ribosomes

A ribosome stalled on a truncated mRNA in the eubacterial cell can be rescued by tmRNA via a process called trans-translation. We demonstrate here that release of truncated mRNAs from stalled ribosomes accelerates significantly already after trans-peptidation following tmRNA binding to the ribosome. However, rapid release of truncated mRNA requires EF-G-dependent translocation of peptidyl-tmRNA from the A to the P site of the ribosome. We show also that the rate of mRNA release before and after peptidyl-tmRNA translocation correlates well with the rate of dissociation of deacylated tRNA, indicating that mRNA is retained on the ribosome mainly through codon:anticodon interaction with tRNA. The rate of mRNA release is reduced for mRNAs with strong Shine-Dalgarno (SD)-like sequences in the vicinity of the truncation site as well as for mRNAs with long 3' extensions downstream from the P-site codon. The reduced rate of release in the former case was due to a persisting SD-anti SD interaction between mRNA and the ribosome.     

tRNA slippage at the tmRNA resume codon

The bacterial ribosome does not initiate translation on the mRNA portion of tmRNA; instead translation that had begun on a separate mRNA molecule resumes at a particular triplet on tmRNA (the resume codon). For at least two tRNAs that could pair with both the resume and -2 triplets on mutant tmRNAs, UAA (stop) as the second codon induced high-frequency -2 slippage on the resume codon in the P site. The frameshift product was not detected when the -2 base was altered. Deficiency for ribosomal L9 protein, which affects other cases of frameshifting, had no significant effect. A special feature of this frameshifting is its dependence on a particular context, that of the tmRNA resume codon; it failed on the same sequence in a regular mRNA, and, more strikingly, at the second tmRNA codon. This focuses attention on the peculiar features expected of the slippage-prone state, such as unusual E-site filling, that might make the P-site resume codon:anticodon interaction especially unstable. Keywords: tmRNA; ribosome; frameshift; E site; translation     

Prolyl-tRNA(Pro) in the A-site of SecM-arrested ribosomes inhibits the recruitment of transfer-messenger RNA

Translational pausing can lead to cleavage of the A-site codon and facilitate recruitment of the transfer-messenger RNA (tmRNA) (SsrA) quality control system to distressed ribosomes. We asked whether aminoacyl-tRNA binding site (A-site) mRNA cleavage occurs during regulatory translational pausing using the Escherichia coli SecM-mediated ribosome arrest as a model. We find that SecM ribosome arrest does not elicit efficient A-site cleavage, but instead allows degradation of downstream mRNA to the 3'-edge of the arrested ribosome. Characterization of SecM-arrested ribosomes shows the nascent peptide is covalently linked via glycine 165 to tRNA(3Gly) in the peptidyl-tRNA binding site, and prolyl-tRNA(2Pro) is bound to the A-site. Although A-site-cleaved mRNAs were not detected, tmRNA-mediated ssrA tagging after SecM glycine 165 was observed. This tmRNA activity results from sequestration of prolyl-tRNA(2Pro) on overexpressed SecM-arrested ribosomes, which produces a second population of stalled ribosomes with unoccupied A-sites. Indeed, compensatory overexpression of tRNA(2Pro) readily inhibits ssrA tagging after glycine 165, but has no effect on the duration of SecM ribosome arrest. We conclude that, under physiological conditions, the architecture of SecM-arrested ribosomes allows regulated translational pausing without interference from A-site cleavage or tmRNA activities. Moreover, it seems likely that A-site mRNA cleavage is generally avoided or inhibited during regulated ribosome pauses.     

Ribosome rescue: tmRNA tagging activity and capacity in Escherichia coli

When protein synthesis stalls in bacteria, tmRNA acts first as a surrogate tRNA and then as an mRNA in a series of reactions that append a peptide tag to the nascent polypeptide and 'rescue' the ribosome. The peptide tag encoded by wild-type tmRNA promotes rapid degradation of rescued proteins. Using a mutant tmRNA that encodes a tag that does not lead to degradation, we demonstrate that the synthesis of approximately 0.4% of all proteins terminates with tagging and ribosome rescue during normal exponential growth of Escherichia coli. The frequency of tagging was not significantly increased in cells expressing very high levels of tmRNA and its binding protein SmpB, suggesting that recognition of 'stalled' ribosomes does not involve competition between tmRNA and other translation factors for A-sites that are unoccupied transiently during protein synthesis. When the demand for ribosome rescue was increased artificially by overproduction of a non-stop mRNA, tmRNA levels did not increase but tmRNA-mediated tagging increased substantially. Thus, the ribosome-rescue system usually operates well below capacity.     

Reduced action of polypeptide release factors induces mRNA cleavage and tmRNA tagging at stop codons in Escherichia coli

Certain C-terminal sequences of nascent peptide cause an efficient protein tagging by tmRNA system at stop codons in Escherichia coli. Here, we demonstrate that both mRNA cleavage and tmRNA tagging occur at UAG stop codon recognized specifically by polypeptide release factor 1 (RF-1) when the activity of RF-1 is reduced by a mutation in the prfA gene without requirement of particular C-terminal sequences of nascent peptide. The tmRNA tagging and mRNA cleavage in the prfA mutant were eliminated when the wild-type RF-1 but not RF-2 was supplied from plasmid. In addition, depletion of either RF-1 or RF-2 induces endonucleolytic cleavage and tmRNA tagging at UAG or UGA stop codons respectively. We conclude that ribosome stalling at the cognate stop codon caused by reduced activity or expression of RF-1 or RF-2 is responsible for mRNA cleavage. The present data along with our previous studies strongly suggest that ribosome stalling leads to endonucleolytic cleavage of mRNA in general resulting in non-stop mRNA and that the 3' end of non-stop mRNA is probably only target for the tmRNA system.     

Accommodation of tmRNA–SmpB into stalled ribosomes: A cryo-EM study

In eubacteria, translation of defective messenger RNAs (mRNAs) produces truncated polypeptides that stall on the ribosome. A quality control mechanism referred to as trans-translation is performed by transfer-messenger RNA (tmRNA), a specialized RNA acting as both a tRNA and an mRNA, associated with small protein B (SmpB). So far, a clear view of the structural movements of both the protein and RNA necessary to perform accommodation is still lacking. By using a construct containing the tRNA-like domain as well as the extended helix H2 of tmRNA, we present a cryo-electron microscopy study of the process of accommodation. The structure suggests how tmRNA and SmpB move into the ribosome decoding site after the release of EF-Tu·GDP. While two SmpB molecules are bound per ribosome in a preaccommodated state, our results show that during accommodation the SmpB protein interacting with the small subunit decoding site stays in place while the one interacting with the large subunit moves away. Relative to canonical translation, an additional movement is observed due to the rotation of H2. This suggests that the larger movement required to resume translation on a tmRNA internal open reading frame starts during accommodation.     

One SmpB molecule accompanies tmRNA during its passage through the ribosomes

tmRNA and SmpB are the main participants of trans-translation, a process which rescues the ribosome blocked during translation of non-stop mRNA. While a one-to-one stoichiometry of tmRNA to the ribosome is generally accepted, the number of SmpB molecules in the complex is still under question. We have isolated tmRNA-ribosome complexes blocked at different steps of the tmRNA path through the ribosome and analyzed the stoichiometry of the complexes. Ribosome, tmRNA and SmpB were found in equimolar amount in the tmRNA-ribosome complexes stopped at the position of the 2nd, 4th, 5th or the 11th codons of the coding part of the tmRNA.     

SmpB functions in various steps of trans-translation

tmRNA has a dual function as a tRNA and an mRNA to facilitate trans-translation, in which a ribosome can switch between translation of a truncated mRNA and the tmRNA’s tag sequence. SmpB is a tmRNA binding protein that has been identified to be essential for trans-translation in vivo. To further study the function of SmpB, an S30 fraction from an Escherichia coli strain, in which the set of genes for SmpB and tmRNA has been deleted from the genome, and His-tagged SmpB active in trans-translation were prepared. The SmpB-depleted S30 fraction had an ability to facilitate poly(U)-dependent tag-peptide synthesis in vitro when purified His-tagged SmpB was exogenously added together with tmRNA, although SmpB was not required for in vitro poly(U)-dependent poly(Phe) synthesis. It was also found that depletion of SmpB leads to a decrease in the level of tmRNA in the cell. In addition, SmpB considerably enhanced the aminoacylation of tmRNA by alanyl-tRNA synthetase in vitro. The aminoacylation enhancement by SmpB, the binding of SmpB to tmRNA and the effect of depletion of SmpB on the expression level of tmRNA in the cell were all affected by some mutations in the tRNA-like domain which cause a defect in ribosome binding leading to a trans-translation deficiency. These results demonstrate that, via binding to the tRNA-like domain of tmRNA, SmpB plays various roles: rescuing the tmRNA molecule from degradation in the cell, enhancing the aminoacylation of tmRNA and mediating the binding of tmRNA to ribosome.