Ribosomal Protein S12 and Aminoglycoside Antibiotics Modulate A-site mRNA Cleavage and Transfer-Messenger RNA Activity in Escherichia coli

Translational pausing in Escherichia coli can lead to mRNA cleavage within the ribosomal A-site. A-site mRNA cleavage is thought to facilitate transfer-messenger RNA (tmRNA)·SmpB- mediated recycling of stalled ribosome complexes. Here, we demonstrate that the aminoglycosides paromomycin and streptomycin inhibit A-site cleavage of stop codons during inefficient translation termination. Aminoglycosides also induced stop codon read-through, suggesting that these antibiotics alleviate ribosome pausing during termination. Streptomycin did not inhibit A-site cleavage in rpsL mutants, which express streptomycin-resistant variants of ribosomal protein S12. However, rpsL strains exhibited reduced A-site mRNA cleavage compared with rpsL⁺ cells. Additionally, tmRNA·SmpB-mediated SsrA peptide tagging was significantly reduced in several rpsL strains but could be fully restored in a subset of mutants when treated with streptomycin. The streptomycin-dependent rpsL(P90K) mutant also showed significantly lower levels of A-site cleavage and tmRNA·SmpB activity. Mutations in rpsD (encoding ribosomal protein S4), which suppressed streptomycin dependence, were able to partially restore A-site cleavage to rpsL(P90K) cells but failed to increase tmRNA·SmpB activity. Taken together, these results show that perturbations to A-site structure and function modulate A-site mRNA cleavage and tmRNA·SmpB activity. We propose that tmRNA·SmpB binds to streptomycin-resistant rpsL ribosomes less efficiently, leading to a partial loss of ribosome rescue function in these mutants.     

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.     

RelE toxins from bacteria and Archaea cleave mRNAs on translating ribosomes,which are rescued by tmRNA

RelE of Escherichia coli is a global inhibitor of translation that is activated by nutritional stress. Activation of RelE depends on Lon-mediated degradation of RelB, the antagonist that neutralizes RelE. In vitro, RelE cleaves synthetic mRNAs positioned at the ribosomal A-site. We show here that in vivo overexpression of RelE confers cleavage of mRNA and tmRNA in their coding regions. RelE-mediated cleavage depended on translation of the RNAs and occurred at both sense and stop codons. RelE cleavage of mRNA and tmRNA was also induced by amino acid starvation. An ssrA deletion strain was hypersensitive to RelE, whereas overproduction of tmRNA counteracted RelE toxicity. After neutralization of RelE by RelB, rapid recovery of translation required tmRNA, indicating that tmRNA alleviated RelE toxicity by rescuing ribosomes stalled on damaged mRNAs. RelE proteins from Gram-positive Bacteria and Archaea cleaved tmRNA with a pattern similar to that of E. coli RelE, suggesting that the function and target of RelE may be conserved across the prokaryotic domains.     

RNA cleavage linked with ribosomal action

Ribonuclease LS in Escherichia coli is a potential antagonist of bacteriophage T4. When T4 dmd is mutated, this RNase efficiently cleaves T4 mRNAs and leads to the silencing of late genes, thus blocking T4 growth. We previously found that, when two consecutive ochre codons were placed in the open reading frame of T4 soc, RNase LS cleaved soc mRNA at a specific site downstream of the ochre codons. Here, we demonstrate that RNase LS cleaves soc RNA at the same site even when only a single ochre codon is present or is replaced with either an amber or an opal codon. On the other hand, disruption of the Shine-Dalgarno sequence, a ribosome-binding site required for the initiation of translation, eliminates the cleavage. These results strongly suggest that RNase LS cleaves in a manner dependent on translation termination. Consistent with this suggestion, the cleavage dependency on an amber codon was considerably reduced in the presence of amber-codon-suppressing tRNA. Instead, two other cleavages that depend on translation of the region containing the target sites occurred farther downstream. Additional analysis suggests that an interaction of the ribosome with a stop codon might affect the site of cleavage by RNase LS in an mRNA molecule. This effect of the ribosome could reflect remodeling of the high-order structure of the mRNA molecule.     

Rae1/YacP,a new endoribonuclease involved in ribosome-dependent mRNA decay in Bacillus subtilis

The PIN domain plays a central role in cellular RNA biology and is involved in processes as diverse as rRNA maturation, mRNA decay and telomerase function. Here, we solve the crystal structure of the Rae1 (YacP) protein of Bacillus subtilis, a founding member of the NYN (Nedd4-BP1/YacP nuclease) subfamily of PIN domain proteins, and identify potential substrates in vivo. Unexpectedly, degradation of a characterised target mRNA was completely dependent on both its translation and reading frame. We provide evidence that Rae1 associates with the B. subtilis ribosome and cleaves between specific codons of this mRNA in vivo. Critically, we also demonstrate translation-dependent Rae1 cleavage of this substrate in a purified translation assay in vitro. Multiple lines of evidence converge to suggest that Rae1 is an A-site endoribonuclease. We present a docking model of Rae1 bound to the B. subtilis ribosomal A-site that is consistent with this hypothesis and show that Rae1 cleaves optimally immediately upstream of a lysine codon (AAA or AAG) in vivo.     

The bacterial toxin RelE induces specific mRNA cleavage in the A site of the eukaryote ribosome

RelE/RelB is a well-characterized toxin-anti-toxin pair involved in nutritional stress responses in Bacteria and Archae. RelE lacks any eukaryote homolog, but we demonstrate here that it efficiently and specifically cleaves mRNA in the A site of the eukaryote ribosome. The cleavage mechanism is similar to that in bacteria, showing the feasibility of A-site cleavage of mRNA for regulatory purposes also in eukaryotes. RelE cleavage in the A-site codon of a stalled eukaryote ribosome is precise and easily monitored, making "RelE printing" a useful complement to toeprinting to determine the exact mRNA location on the eukaryote ribosome and to probe the occupancy of its A site.     

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.     

New insights into the incorporation of natural suppressor tRNAs at stop codons in Saccharomyces cerevisiae

Stop codon readthrough may be promoted by the nucleotide environment or drugs. In such cases, ribosomes incorporate a natural suppressor tRNA at the stop codon, leading to the continuation of translation in the same reading frame until the next stop codon and resulting in the expression of a protein with a new potential function. However, the identity of the natural suppressor tRNAs involved in stop codon readthrough remains unclear, precluding identification of the amino acids incorporated at the stop position. We established an in vivo reporter system for identifying the amino acids incorporated at the stop codon, by mass spectrometry in the yeast Saccharomyces cerevisiae. We found that glutamine, tyrosine and lysine were inserted at UAA and UAG codons, whereas tryptophan, cysteine and arginine were inserted at UGA codon. The 5′ nucleotide context of the stop codon had no impact on the identity or proportion of amino acids incorporated by readthrough. We also found that two different glutamine tRNA^Gln were used to insert glutamine at UAA and UAG codons. This work constitutes the first systematic analysis of the amino acids incorporated at stop codons, providing important new insights into the decoding rules used by the ribosome to read the genetic code.     

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.     

Cleavage of mRNAs and role of tmRNA system under amino acid starvation in Escherichia coli

We have shown previously that ribosome stalling during translation caused by various reasons leads to mRNA cleavage, resulting in non-stop mRNAs that are eliminated in a tmRNA-dependent manner. Amino acid starvation is a physiological condition in which ribosome stalling is expected to occur more frequently. Here we demonstrate that mRNA cleavage is induced by amino acid starvation, resulting in accumulation of truncated mRNAs in cells lacking tmRNA. The truncated mRNAs are eliminated in wild-type cells, indicating that the tmRNA system rapidly degrade the truncated mRNAs. The cleavage pattern of model mRNAs in which serine codons were replaced with threonine codons indicated that mRNA cleavage occurs near serine codons in response to serine starvation. Cells lacking all of the five known toxin loci were proficient in mRNA cleavage, showing that toxin–antitoxin systems are not responsible for the cleavage. A mild serine starvation caused a significant growth inhibition in cells lacking tmRNA but not in wild-type cells. The ribosome-mediated mRNA cleavage along with the tmRNA system is an important mechanism that enables cells to adapt to amino acid starvation conditions.     

Ribosome pausing and stacking during translation of a eukaryotic mRNA.

We have devised a sensitive assay to determine the distribution of translating ribosomes on a mRNA. Using this assay to monitor ribosome transit on bovine preprolactin mRNA, we have detected four major positions of ribosome pausing in both wheat-germ and rabbit reticulocyte extracts. Two of these rate-limiting steps represent initiation and termination. One pause occurs after approximately 75 amino acids have been polymerized; signal recognition particle arrests preprolactin synthesis at this position. The other internal pause occurs at 160 amino acids. In these latter two cases ribosomes stop at a GGC glycine codon; however, two other GGC codons are translated without apparent pausing. Surprisingly, we find that up to nine ribosomes are tightly stacked behind each pausing ribosome, such that the ribosome centers are only 27-29 nucleotides apart. The assay should prove useful for probing mechanisms of translational regulation.     

Structure of a human translation termination complex

In contrast to bacteria that have two release factors, RF1 and RF2, eukaryotes only possess one unrelated release factor eRF1, which recognizes all three stop codons of the mRNA and hydrolyses the peptidyl-tRNA bond. While the molecular basis for bacterial termination has been elucidated, high-resolution structures of eukaryotic termination complexes have been lacking. Here we present a 3.8 Å structure of a human translation termination complex with eRF1 decoding a UAA(A) stop codon. The complex was formed using the human cytomegalovirus (hCMV) stalling peptide, which perturbs the peptidyltransferase center (PTC) to silence the hydrolysis activity of eRF1. Moreover, unlike sense codons or bacterial stop codons, the UAA stop codon adopts a U-turn-like conformation within a pocket formed by eRF1 and the ribosome. Inducing the U-turn conformation for stop codon recognition rationalizes how decoding by eRF1 includes monitoring geometry in order to discriminate against sense codons.     

Thermodynamic and Kinetic Insights into Stop Codon Recognition by Release Factor 1

Stop codon recognition is a crucial event during translation termination and is performed by class I release factors (RF1 and RF2 in bacterial cells). Recent crystal structures showed that stop codon recognition is achieved mainly through a network of hydrogen bonds and stacking interactions between the stop codon and conserved residues in domain II of RF1/RF2. Additionally, previous studies suggested that recognition of stop codons is coupled to proper positioning of RF1 on the ribosome, which is essential for triggering peptide release. In this study we mutated four conserved residues in Escherichia coli RF1 (Gln185, Arg186, Thr190, and Thr198) that are proposed to be critical for discriminating stop codons from sense codons. Our thermodynamic and kinetic analysis of these RF1 mutants showed that the mutations inhibited the binding of RF1 to the ribosome. However, the mutations in RF1 did not affect the rate of peptide release, showing that imperfect recognition of the stop codon does not affect the proper positioning of RF1 on the ribosome.     

Codon-specific and general inhibition of protein synthesis by the tRNA-sequestering minigenes

The expression of minigenes in bacteria inhibits protein synthesis and cell growth. Presumably, the translating ribosomes, harboring the peptides as peptidyl-tRNAs, pause at the last sense codon of the minigene directed mRNAs. Eventually, the peptidyl-tRNAs drop off and, under limiting activity of peptidyl-tRNA hydrolase, accumulate in the cells reducing the concentration of specific aminoacylable tRNA. Therefore, the extent of inhibition is associated with the rate of starvation for a specific tRNA. Here, we used minigenes harboring various last sense codons that sequester specific tRNAs with different efficiency, to inhibit the translation of reporter genes containing, or not, these codons. A prompt inhibition of the protein synthesis directed by genes containing the codons starved for their cognate tRNA (hungry codons) was observed. However, a non-specific in vitro inhibition of protein synthesis, irrespective of the codon composition of the gene, was also evident. The degree of inhibition correlated directly with the number of hungry codons in the gene. Furthermore, a tRNA(Arg4)-sequestering minigene promoted the production of an incomplete beta-galactosidase polypeptide interrupted, during bacterial polypeptide chain elongation at sites where AGA codons were inserted in the lacZ gene suggesting ribosome pausing at the hungry codons.     

Cleavage of the A site mRNA codon during ribosome pausing provides a mechanism for translational quality control

Cells employ many mechanisms to ensure quality control during protein biosynthesis. Here, we show that, during the pausing of a bacterial ribosome, the mRNA being translated is cleaved at a site within or immediately adjacent to the A site codon. The extent of this A site mRNA cleavage is correlated with the extent of ribosome pausing as assayed by tmRNA-mediated tagging of the nascent polypeptide. Cleavage does not require tmRNA, the ribosomal alarmone (p)ppGpp, or bacterial toxins such as RelE which have been shown to stimulate a similar activity. Translation is required for cleavage, suggesting that the ribosome participates in the reaction in some fashion. When normal protein synthesis is compromised, A site mRNA cleavage and the tmRNA system provide a mechanism for reducing translational errors and the production of aberrant and potentially harmful polypeptides.     

Regulation of c-myc mRNA decay by translational pausing in a coding region instability determinant

A 249-nucleotide coding region instability determinant (CRD) destabilizes c-myc mRNA. Previous experiments identified a CRD-binding protein (CRD-BP) that appears to protect the CRD from endonuclease cleavage. However, it was unclear why a CRD-BP is required to protect a well-translated mRNA whose coding region is covered with ribosomes. We hypothesized that translational pausing in the CRD generates a ribosome-deficient region downstream of the pause site, and this region is exposed to endonuclease attack unless it is shielded by the CRD-BP. Transfection and cell-free translation experiments reported here support this hypothesis. Ribosome pausing occurs within the c-myc CRD in tRNA-depleted reticulocyte translation reactions. The pause sites map to a rare arginine (CGA) codon and to an adjacent threonine (ACA) codon. Changing these codons to more common codons increases translational efficiency in vitro and increases mRNA abundance in transfected cells. These data suggest that c-myc mRNA is rapidly degraded unless it is (i) translated without pausing or (ii) protected by the CRD-BP when pausing occurs. Additional mapping experiments suggest that the CRD is bipartite, with several upstream translation pause sites and a downstream endonuclease cleavage site.