A functional interaction of SmpB with tmRNA for determination of the resuming point of trans-translation

In trans-translation, transfer-messenger RNA (tmRNA), possessing a dual function as a tRNA and an mRNA, relieves a stalled translation on the ribosome with the help of SmpB. Here, we established an in vitro system using Escherichia coli translation and trans-translation factors to evaluate two steps of trans-translation, peptidyl transfer from peptidyl-tRNA to alanyl-tmRNA and translation of the resume codon on tmRNA. Using this system, the effects of several mutations upstream of the tag-encoding region on tmRNA were examined. These mutations affected translation of the resume codon rather than peptidyl transfer, and one of them, A84U/U85G, caused a shift of the resume codon by -1. We also found that U(85) is protected from chemical modification by SmpB. In the A84U/U85G mutant, the base of protection was shifted from 85 to 84. Another mutation, A86U, which caused a shift of the resume codon by +1, shifted the base of protection from 85 to 86. The protection at 85 was suppressed by a mutation in the tRNA-like domain critical to SmpB binding. These results suggest that SmpB serves to bridge two separate domains of tmRNA to determine the initial codon for tag-translation. A mutant SmpB with a truncation of the unstructured C-terminal tail failed to promote peptidyl transfer, although it still protected U(85) from chemical modification.     

反式翻译模型

反式翻译是细菌体内一种修复翻译水平上受阻的遗传信息表达过程的机制。tmRNA是反式翻译的核心分子,它兼具tRNA和mRNA的特点,在SmpB蛋白的帮助下特异性识别携带mRNA缺失体的核糖体,在核糖体蛋白S1的传递作用下结合在A位点上,一方面延续被中断的mRNA上的遗传信息,一方面终止蛋白质的合成,释放被束缚的核糖体和tRNA进入新的翻译过程。本文对近年来关于反式翻译模型的研究进行综述。     

The role of SmpB protein in trans-translation

The function of SmpB protein in the trans-translation system was evaluated using the well-defined cell-free translation system consisting of purified ribosome, alanyl-tRNA synthetase and elongation factors. The analysis showed that SmpB protein enhances alanine-accepting activity of tmRNA and that SmpB protein and tmRNA are sufficient to complete the trans-translation process in the presence of translational components. Moreover, SmpB is indispensable in the addition of tag-peptide onto ribosomes by tmRNA. In particular, the A-site binding of tmRNA is inhibited in the absence of SmpB.     

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.     

Pre-binding of small protein B to a stalled ribosome triggers trans-translation

To rescue stalled ribosomes, eubacteria employ a molecule, transfer messenger RNA (tmRNA), which functions both as a tRNA and as an mRNA. With the help of small protein B (SmpB), tmRNA restarts protein synthesis and adds by the trans-translation mechanism a peptide tag to the stalled protein to target it for destruction by cellular proteases. Here, the cellular location and expression of endogenous SmpB were monitored in vivo. We report that SmpB is associated with 70S ribosomes and not in the soluble fraction, independently of the presence of tmRNA. In vitro, SmpB that is pre-bound to a stalled ribosome can trigger initiation of trans-translation. Our results demonstrate the existence of a novel pathway for the entry of tmRNA to the ribosome and for the trans-transfer of a nascent peptide chain from peptidyl-tRNA to charged tmRNA.     

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.     

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.     

Various effects of paromomycin on tmRNA-directed trans-translation

trans-Translation is an unusual translation in which tmRNA plays a dual function as a tRNA and an mRNA to relieve the stalled translation on the ribosome. In this study, we examined the effects of an aminoglycoside antibiotic, paromomycin, on several tmRNA-related events in vitro. The results of a chemical footprinting study indicated that paromomycin molecules bind tmRNA at G332/G333 in the tRNA domain and A316 in the middle of the long helix between tRNA and mRNA domains. Paromomycin bound at G332/G333 inhibited aminoacylation, and the inhibition was suppressed by the addition of SmpB, a tmRNA-binding protein. It was also found that paromomycin causes a shift of the translation resuming point on tmRNA by -1. The effect on initiation shift was canceled by a mutation at the paromomycin-binding site in 16 S rRNA but not by mutations in tmRNA. A high concentration of paromomycin inhibited trans-translation, whereas it enhanced the initiation-shifted trans-translation when SmpB was exogenously added or a mutation was introduced at 333. The effect of paromomycin on trans-translation differs substantially from that on canonical translation, in which it induces miscoding by modulating the A site of the decoding helix of the small subunit RNA of the ribosome.     

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.     

Trans-translation mediated by Bacillus subtilis tmRNA

Trans-translation, in which a ribosome switches between translation of an mRNA and a tmRNA, produces a chimera polypeptide of an N-terminal truncated polypeptide and a C-terminal tag-peptide encoded by tmRNA. One of the tmRNA binding proteins, a ribosomal protein S1, has not been found in a group of Gram-positive bacteria. In this study, the trans-translation reaction with tmRNA from Bacillus subtilis belonging to this group was examined. When a truncated gene lacking a termination codon was expressed in B. subtilis, a 15-amino acid tag-peptide derived from tmRNA was identified in the C-termini of the trans-translation products. An identical tag-peptide was also found at the C-termini of the products from a truncated gene, when it was coexpressed with B. subtilis tmRNA in Escherichia coli. B. subtilis tmRNA was functional, although much less efficiently, in the in vitro poly(U)-dependent tag-peptide synthesis system of E. coli. A comparison of two bacterial tmRNAs suggests that the rule for determining the tag-initiation point on tmRNA may be the same in Gram-positive and Gram-negative bacteria.     

Simultaneous and functional binding of SmpB and EF-Tu-TP to the alanyl acceptor arm of tmRNA.

Transfer-messenger RNA (tmRNA) mimics functions of aminoacyl-tRNA and mRNA, subsequently, when rescuing stalled ribosomes on a 3' truncated mRNA without stop codon in bacteria. In addition, this mechanism marks prematurely terminated proteins by a C-terminal peptide tag as a signal for degradation by specific cellular proteases. For Escherichia coli, previous studies on initial steps of this "trans-translation" mechanism revealed that tmRNA alanylation by Ala-tRNA synthetase and binding of Ala-tmRNA by EF-Tu-GTP for subsequent delivery to stalled ribosomes are inefficient when compared to analogous reactions with canonical tRNA(Ala). In other studies, protein SmpB and ribosomal protein S1 appeared to bind directly to tmRNA and to be indispensable for trans-translation. Here, we have searched for additional and synergistic effects of the latter two on tmRNA alanylation and its subsequent binding to EF-Tu-GTP. Kinetic analysis of functioning combined with band-shift experiments and structural probing demonstrate, that tmRNA may indeed form a multimeric complex with SmpB, S1 and EF-Tu-GTP, which leads to a considerably enhanced efficiency of the initial steps of trans-translation. Whereas S1 binds to the mRNA region of tmRNA, we have found that SmpB and EF-Tu both interact with its acceptor arm region. Interaction with SmpB and EF-Tu was also observed at the acceptor arm of Ala-tRNA(Ala), but there the alanylation efficiency was inhibited rather than stimulated by SmpB. Therefore, SmpB may function as an essential modulator of the tRNA-like acceptor arm of tmRNA during its successive steps in trans-translation.     

Contributions of pseudoknots and protein SmpB to the structure and function of tmRNA in trans-translation

Bacteria contain transfer-messenger RNA (tmRNA), a molecule that during trans-translation tags incompletely translated proteins with a small peptide to signal the proteolytic destruction of defective polypeptides. TmRNA is composed of tRNA- and mRNA-like domains connected by several pseudoknots. Using truncated ribosomal protein L27 as a reporter for tagging in vitro and in vivo, we have developed exceptionally sensitive assays to study the role of Escherichia coli tmRNA in trans-translation. Site-directed mutagenesis experiments showed that pseudoknot 2 and the abutting helix 5 were particularly important for the binding of ribosomal protein S1 to tmRNA. Pseudoknot 4 not only facilitated tmRNA maturation but also promoted tagging. In addition, the three pseudoknots (pk2 to pk4) were shown to play a significant role in the proper folding of the tRNA-like domain. Protein SmpB enhanced tmRNA processing, suggesting a new role for SmpB in trans-translation. Taken together, these results provide unanticipated insights into the functions of the pseudoknots and protein SmpB during tmRNA folding, maturation, and protein synthesis.     

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.     

The role of SmpB and the ribosomal decoding center in licensing tmRNA entry into stalled ribosomes

In bacteria, stalled ribosomes are recycled by a hybrid transfer-messenger RNA (tmRNA). Like tRNA, tmRNA is aminoacylated with alanine and is delivered to the ribosome by EF-Tu, where it reacts with the growing polypeptide chain. tmRNA entry into stalled ribosomes poses a challenge to our understanding of ribosome function because it occurs in the absence of a codon-anticodon interaction. Instead, tmRNA entry is licensed by the binding of its protein partner, SmpB, to the ribosomal decoding center. We analyzed a series of SmpB mutants and found that its C-terminal tail is essential for tmRNA accommodation but not for EF-Tu activation. We obtained evidence that the tail likely functions as a helix on the ribosome to promote accommodation and identified key residues in the tail essential for this step. In addition, our mutational analysis points to a role for the conserved K(131)GKK tail residues in trans-translation after peptidyl transfer to tmRNA, presumably EF-G-mediated translocation or translation of the tmRNA template. Surprisingly, analysis of A1492, A1493, and G530 mutants reveals that while these ribosomal nucleotides are essential for normal tRNA selection, they play little to no role in peptidyl transfer to tmRNA. These studies clarify how SmpB interacts with the ribosomal decoding center to license tmRNA entry into stalled ribosomes.     

Single molecule imaging of the trans-translation entry process via anchoring of the tagged ribosome

Trans-translation is an eubacterial quality control system to rescue the stalled ribosome, in which multiple components such as transfer messenger RNA (tmRNA) and Small protein B (SmpB) are involved. However, how these molecules interact with ribosome remains elusive. Here, we report the single molecule analysis of the trans-translation process. We developed a new method to label the functional ribosome, in which a tag protein (the HaloTag protein of 297 amino acids) was fused to the 30S ribosomal protein S2 and covalently labelled with specific ligand (HaloTag ligand), resulting in the stable and specific labelling of ribosome. Ribosomes were anchored onto the glass surface using biotinylated derivative of the Cy3 HaloTag ligand (i.e. biotin-Cy3-ligand), and real-time interactions of Cy5-tmRNA/SmpB/EF-Tu ternary complexes with anchored ribosomes are observed as a model of the trans-translation entry. Statistical analysis revealed that Cy5-tmRNA/SmpB/EF-Tu ternary complexes bind to the anchored ribosome with the second-order rate constant of 2.6 × 10(6) (1/M/s) and tmRNAs undergo multi-modal pathway before release from ribosome. The methods presented here are also applicable to the analysis for general translation processes.     

Mapping the interaction of SmpB with ribosomes by footprinting of ribosomal RNA

In trans-translation transfer messenger RNA (tmRNA) and small protein B (SmpB) rescue ribosomes stalled on truncated or in other ways problematic mRNAs. SmpB promotes the binding of tmRNA to the ribosome but there is uncertainty about the number of participating SmpB molecules as well as their ribosomal location. Here, the interaction of SmpB with ribosomal subunits and ribosomes was studied by isolation of SmpB containing complexes followed by chemical modification of ribosomal RNA with dimethyl sulfate, kethoxal and hydroxyl radicals. The results show that SmpB binds 30S and 50S subunits with 1:1 molar ratios and the 70S ribosome with 2:1 molar ratio. SmpB-footprints are similar on subunits and the ribosome. In the 30S subunit, SmpB footprints nucleotides that are in the vicinity of the P-site facing the E-site, and in the 50S subunit SmpB footprints nucleotides that are located below the L7/L12 stalk in the 3D structure of the ribosome. Based on these results, we suggest a mechanism where two molecules of SmpB interact with tmRNA and the ribosome during trans-translation. The first SmpB molecule binds near the factor-binding site on the 50S subunit helping tmRNA accommodation on the ribosome, whereas the second SmpB molecule may functionally substitute for a missing anticodon stem–loop in tmRNA during later steps of trans-translation.     

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.     

An unusual mechanism for EF-Tu activation during tmRNA-mediated ribosome rescue

In bacteria, ribosomes stalled on truncated mRNAs are rescued by transfer-messenger RNA (tmRNA) and its protein partner SmpB. Acting like tRNA, the aminoacyl-tmRNA/SmpB complex is delivered to the ribosomal A site by EF-Tu and accepts the transfer of the nascent polypeptide. Although SmpB binding within the decoding center is clearly critical for licensing tmRNA entry into the ribosome, it is not known how activation of EF-Tu occurs in the absence of a codon–anticodon interaction. A recent crystal structure revealed that SmpB residue His136 stacks on 16S rRNA nucleotide G530, a critical player in the canonical decoding mechanism. Here we use pre-steady-state kinetic methods to probe the role of this interaction in ribosome rescue. We find that although mutation of His136 does not reduce SmpB''s affinity for the ribosomal A-site, it dramatically reduces the rate of GTP hydrolysis by EF-Tu. Surprisingly, the same mutation has little effect on the apparent rate of peptide-bond formation, suggesting that release of EF-Tu from the tmRNA/SmpB complex on the ribosome may occur prior to GTP hydrolysis. Consistent with this idea, we find that peptidyl transfer to tmRNA is relatively insensitive to the antibiotic kirromycin. Taken together, our studies provide a model for the initial stages of ribosomal rescue by tmRNA.     

Binding and cross-linking of tmRNA to ribosomal protein S1, on and off the Escherichia coli ribosome

UV irradiation of an in vitro translation mixture induced cross-linking of 4-thioU-substituted tmRNA to Escherichia coli ribosomes by forming covalent complexes with ribosomal protein S1 and 16S rRNA. In the absence of S1, tmRNA was unable to bind and label ribosomal components. Mobility assays on native gels demonstrated that protein S1 bound to tmRNA with an apparent binding constant of 1 x 10(8) M(-1). A mutant tmRNA, lacking the tag coding region and pseudoknots pk2, pk3 and pk4, did not compete with full-length tmRNA, indicating that this region is required for S1 binding. This was confirmed by identification of eight cross-linked nucleotides: U85, located before the resume codon of tmRNA; U105, in the mRNA portion of tmRNA; U172 in pK2; U198, U212, U230 and U240 in pk3; and U246, in the junction between pk3 and pk4. We concluded that ribosomal protein S1, in concert with the previously identified elongation factor EF-Tu and protein SmpB, plays an important role in tmRNA-mediated trans-translation by facilitating the binding of tmRNA to ribosomes and forming complexes with free tmRNA.     

Ribosomal protein S1 is not essential for the trans-translation machinery

In eubacteria, ribosome stalling during protein synthesis is rescued by a tmRNA-derived trans-translation system. Because ribosomal protein S1 specifically binds to tmRNA with high affinity, it is considered to be involved in the trans-translation system. However, the role of S1 in trans-translation is still unclear. To study the function of S1 in the trans-translation system, we constructed an S1-free cell-free translation system. We found that trans-translation proceeded even in the absence of S1. Addition of S1 into the S1-free system did not affect trans-translation efficiency. These results suggest that S1 does not play a role in the trans-translation machinery.