Control of SecA and SecM translation by protein secretion

SecA, the protein translocation ATPase of E. coli is subject to secretion-defect-response control. SecM (secretion monitor) encoded by the 5' region of the secM-secA mRNA is involved in this regulation. SecM translation is subject to transient elongation arrest at Pro166, which is prolonged when export of the nascent SecM is blocked. An "arrest sequence", FXXXXWIXXXXGIRAGP, was identified at a carboxy-terminal region of SecM that interacts with the ribosomal exit tunnel. Presumably, the stalled ribosome disrupts the secondary structure of the secM-secA mRNA such that the Shine-Dalgarno sequence for translation of secA is exposed. Mutation studies established that the SecM elongation arrest is required for the viability of E. coli as well as for constitutive (in secretion-proficient cells) and upregulated (in secretion compromised cells) expression of SecA. Furthermore, evidence suggests that elongation-arresting SecM has a role of upregulating the functionality of newly synthesized SecA molecules, presumably by bringing the mRNA to the vicinity of the membrane/Sec translocation apparatus. These results are discussed in relation to the versatile nature of SecA in its localization and structure.     

The translational regulatory function of SecM requires the precise timing of membrane targeting

In Escherichia coli, secA expression is regulated at the translational level by an upstream gene (secM) that encodes a presecretory protein. SecM contains a C-terminal sequence motif that induces a transient translation arrest. Inhibition of SecM membrane targeting prolongs the translation arrest and increases SecA synthesis by concomitantly altering the structure of the secM-secA mRNA. Here we show that the SecM signal peptide plays an essential role in this regulatory process by acting as a molecular timer that co-ordinates membrane targeting with the synthesis of the arrest motif. We found that signal peptide mutations that alter targeting kinetics and insertions or deletions that change the distance between the SecM signal peptide and the arrest motif perturb the balance between the onset and release of arrest that is required to regulate SecA synthesis. Furthermore, we found that the strength of the interaction between the ribosome and the SecM arrest motif is calibrated to ensure the release of arrest upon membrane targeting. Our results strongly suggest that several distinctive features of the SecM protein evolved as a consequence of constraints imposed by the ribosome and the Sec machinery.     

Secretion monitor, SecM, undergoes self-translation arrest in the cytosol

The product of the Escherichia coli secM gene (secretion monitor, formerly gene X), upstream of secA, is involved in secretion-responsive control of SecA translation. In wild-type cells, SecM is rapidly degraded by the periplasmic tail-specific protease. It is also subject to a transient translation pause at a position close to the C terminus. The elongation arrest was strikingly prolonged when translocation of SecM was impaired. SRP was not required for this arrest. Instead, the nascent SecM product itself may participate, as the arrest was diminished when it incorporated a proline analog, azetidine. We propose that cytosolically localized nascent SecM undergoes self-translation arrest, thereby enhancing translation of secA through an altered secondary structure of the secM-secA messenger RNA.     

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.     

Genetically encoded but nonpolypeptide prolyl-tRNA functions in the A site for SecM-mediated ribosomal stall

The arrest sequence, FXXXXWIXXXXGIRAGP, of E. coli SecM interacts with the ribosomal exit tunnel, thereby interfering with translation elongation. Here, we studied this elongation arrest in vitro using purified translation components. While a simplest scenario would be that elongation is arrested beyond Pro166, the last arrest-essential amino acid, and that the Pro166 codon is positioned at the P site of the ribosomal peptidyl transferase center (PTC), our toeprint analyses revealed that the ribosome actually stalls when the Pro166 codon is positioned at the A site. Northern hybridization identification of the polypeptide bound tRNA and mass determination showed that the last amino acid of the arrested peptidyl-tRNA is Gly165, which is only inefficiently transferred to Pro166. Also, puromycin does not effectively release the arrested peptidyl-tRNA under the conditions of A site occupancy by Pro166-tRNA. These results reveal that secM-encoded Pro166-tRNA functions as a nonpolypeptide element in fulfilling SecM's role as a secretion monitor.     

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.     

Nascent SecM Chain Outside the Ribosome Reinforces Translation Arrest

SecM, a bacterial secretion monitor protein, contains a specific amino acid sequence at its C-terminus, called arrest sequence, which interacts with the ribosomal tunnel and arrests its own translation. The arrest sequence is sufficient and necessary for stable translation arrest. However, some previous studies have suggested that the nascent chain outside the ribosome affects the stability of translation arrest. To clarify this issue, we performed in vitro translation assays with HaloTag proteins fused to the C-terminal fragment of E. coli SecM containing the arrest sequence or the full-length SecM. We showed that the translation of HaloTag proteins, which are fused to the fragment, is not effectively arrested, whereas the translation of HaloTag protein fused to full-length SecM is arrested efficiently. In addition, we observed that the nascent SecM chain outside the ribosome markedly stabilizes the translation arrest. These results indicate that changes in the nascent polypeptide chain outside the ribosome can affect the stability of translation arrest; the nascent SecM chain outside the ribosome stabilizes the translation arrest.     

Translocon "pulling" of nascent SecM controls the duration of its translational pause and secretion-responsive secA regulation

SecA is an ATPase and motor protein that drives protein translocation across the bacterial plasma membrane. In Escherichia coli SecA levels are regulated by the secretion needs of the cell utilizing secM, which encodes a secreted protein. Previous studies demonstrated that this regulation requires a translational pause within secM, whose duration regulates the accessibility of the secA Shine-Dalgarno sequence on secM secA mRNA. Here we provide evidence that translocon "pulling" of nascent SecM is what regulates the duration of the secM translational pause, and thus secA expression levels, thereby providing direct support for this model.     

Critical regions of secM that control its translation and secretion and promote secretion-specific secA regulation

SecA is an essential ATP-driven motor protein that binds to presecretory or membrane proteins and the translocon and promotes the translocation or membrane integration of these proteins. secA is subject to a protein secretion-specific form of regulation, whereby its translation is elevated during secretion-limiting conditions. A novel mechanism that promotes this regulation involves translational pausing within the gene upstream of secA, secM. The secM translational pause prevents formation of an RNA helix that normally blocks secA translational initiation. The duration of this pause is controlled by the rate of secretion of nascent SecM, which in turn depends on its signal peptide and a functional translocon. We characterized the atypical secM signal peptide and found that mutations within the amino-terminal region specifically affect the secM translational pause and secA regulation, while mutations in the hydrophobic core region affect SecM secretion as well as translational pausing and secA regulation. In addition, mutational analysis of the 3' end of secM allowed us to identify a conserved region that is required to promote the translational pause that appears to be operative at the peptide level. Together, our results provide direct support for the secM translational pause model of secA regulation, and they pinpoint key sequences within secM that promote this important regulatory system.     

Translation arrest requires two-way communication between a nascent polypeptide and the ribosome

When the export of E. coli SecM is blocked, a 17 amino acid motif near the C terminus of the protein induces a translation arrest from within the ribosome tunnel. Here we used a recently described application of fluorescence resonance energy transfer (FRET) to gain insight into the mechanism of translation arrest. We found that the SecM C terminus adopted a compact conformation upon synthesis of the arrest motif. This conformational change did not occur spontaneously, but rather was induced by the ribosome. Translation arrest required both compaction of the SecM C terminus and the presence of key residues in the arrest motif. Further analysis showed that the arrested peptidyl-tRNA was resistant to puromycin treatment and revealed additional changes in the ribosome-nascent SecM complex. Based on these observations, we propose that translation arrest results from a series of reciprocal interactions between the ribosome and the C terminus of the nascent SecM polypeptide.     

Proline residues at the C terminus of nascent chains induce SsrA tagging during translation termination

The SsrA or tmRNA quality control system relieves ribosome stalling and directs the addition of a degradation tag to the C terminus of the nascent chain. In some instances, SsrA tagging of otherwise full-length proteins occurs when the ribosome pauses at stop codons during normal translation termination. Here, the identities of the C-terminal residues of the nascent chain are shown to play an important role in full-length protein tagging. Specifically, a subset of C-terminal Xaa-Pro sequences caused SsrA tagging of the full-length YbeL protein from Escherichia coli. This tagging increased when a less efficient stop codon was used, increased in cells lacking protein release factor-3, and decreased when protein release factor-1 was overexpressed. Incorporation of the analog azetidine-2-carboxylic acid in place of proline suppressed tagging, whereas incorporation of 3,4-dehydroproline increased SsrA tagging of full-length YbeL. These results suggest that the detailed chemical or conformational properties of the C-terminal residues of the nascent polypeptide can affect the rate of translation termination, thereby influencing ribosome pausing and SsrA tagging at stop codons.     

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.     

Revised translation start site for secM defines an atypical signal peptide that regulates Escherichia coli secA expression

The secretion-responsive regulation of Escherichia coli secA occurs by coupling its translation to the translation and secretion of an upstream regulator, secM (formerly geneX). We revise the translational start site for secM, defining a new signal peptide sequence with an extended amino-terminal region. Mutational studies indicate that certain atypical amino acyl residues within this extended region are critical for proper secA regulation.     

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.