Cysteinyl-tRNA deacylation can be uncoupled from protein synthesis

Aminoacyl-tRNA synthetases (ARSs) are critical components of protein translation, providing ribosomes with aminoacyl-tRNAs. In return, ribosomes release uncharged tRNAs as ARS substrates. Here, we show that tRNA deacylation can be uncoupled from protein synthesis in an amino acid specific manner. While tRNAs coupled to radiolabeled Met, Leu Lys, or Ser are stable in cells following translation inhibition with arsenite, radiolabeled Cys is released from tRNA at a high rate. We discuss possible translation independent functions for tRNA(Cys).     

Ribosomes are stalled during in vitro translation of alfalfa mosaic virus RNA 1

In the presence of plant tRNAs the full-length translation product of alfalfa mosaic virus RNA 1 is produced in rabbit reticulocytes only at low mRNA concentration. At higher mRNA concentration translation is restricted to the 5' half of RNA 1. At high mRNA concentration the full-length product can be formed when additional plant tRNA and glutamine are supplied to the translation mixture. In contrast, in the presence of yeast or calf liver tRNA the translation pattern of alfalfa mosaic virus RNA 1 always results in the synthesis of the full-length product. Pulse-chase experiments in the presence of plant tRNAs show that the ribosomes pause at several positions in the 5' half of RNA 1. The pausing time is different at the different 'halting places'. Protein synthesis is resumed upon addition of glutamine, even when the addition is delayed for more than 3 h after the start of protein synthesis. Only one tRNA species, purified from wheat germ or tobacco, could promote full-length translation of RNA 1. This tRNA can be charged with glutamine. Analysis of the position of glutamine codons on RNA 1 shows a correlation between the positions of the CAA codons and the halting places of the ribosomes. The CAA codon (for any other codon) on its own cannot be responsible for the pausing of the ribosomes, since a variety of RNAs, known to contain all sense codons, are translated efficiently in rabbit reticulocyte lysates in the presence of plant tRNAs. Apparently other elements can restrict decoding of normal codons during protein chain elongation.     

Structural analysis of 5S rRNA, 5S rRNA-protein complexes and ribosomes employing RNase H and d(GTTCGG)

The hybridization of d(GTTCGG) to eubacterial 5S rRNAs, 5S rRNA-protein complexes, 70S ribosomes and 50S and 30S ribosomal subunits was investigated. This oligonucleotide, which may be considered to be an analogue of the T psi CG loop of tRNAs, was chosen in order to investigate a possible interaction between tRNAs with ribosomal components during protein synthesis. The hybridization was analysed by RNase H hydrolysis studies and, in the case of the ribosomes and ribosomal subunits, in addition with the radioactively labelled oligodeoxyribonucleotide in binding studies. The results obtained lead to the conclusion that nucleotides in loop c, i.e. positions 42-47, are available for oligonucleotide interaction in free Escherichia coli and Bacillus stearothermophilus 5S rRNAs and not available in the corresponding 5S rRNA-protein complexes. The 70S ribosomes and ribosomal subunits did not interact with the oligonucleotide. Under the assumption that d(GTTCGG) is an analogue of the T psi CG loop of tRNAs and in view of the results obtained, we conclude that in the unprogrammed ribosomes the T psi CG loop of tRNAs does not interact via standard Watson-Crick base pairs with the ribosomal 5S, 16S or 23S RNAs.     

Protein synthesis inhibitors and catalytic RNA. Effect of puromycin on tRNA precursor processing by the RNA component of Escherichia coli RNase P

RNase P and ribosomes must interact with similar substrate molecules, tRNA precursors in the case of RNase P and aminoacyl-, peptidyl- or free tRNAs in the case of ribosomes. In order to compare the substrate recognition mechanisms between ribosomes and RNase P, protein synthesis inhibitors have been assayed for their effect on the catalytic activity of the RNA component of Escherichia coli RNase P (M1 RNA). Puromycin has an inhibitory effect that could be related to similar substrate recognition mechanisms by rRNA in the ribosome and by M1 RNA in RNase P.     

Molecular localization of a ribosome-dependent ATPase on Escherichia coli ribosomes

We have previously isolated and described an Escherichia coli ribosome-bound ATPase, RbbA, that is required for protein synthesis in the presence of ATP, GTP and the elongation factors, EF-Tu and EF-G. The gene encoding RbbA, yhih, has been cloned and the deduced protein sequence harbors two ATP-motifs and one RNA-binding motif and is homologous to the fungal EF-3. Here, we describe the isolation and assay of a truncated form of the RbbA protein that is stable to overproduction and purification. Chemical protection results show that the truncated RbbA specifically protects nucleotide A937 on the 30S subunit of ribosomes, and the protected site occurs at the E-site where the tRNA is ejected upon A-site occupation. Other weakly protected bases in the region occur at or near the mRNA binding site. Using radiolabeled tRNAs, we study the stimulating effect of this truncated RbbA on the binding and release of different tRNAs bound to the (aminoacyl) A-, (peptidyl) P- and (exit) E-sites of 70S ribosomes. The combined data suggest plausible mechanisms for the function of RbbA in translation.     

Association of a multi-synthetase complex with translating ribosomes in the archaeon Thermococcus kodakarensis

In archaea and eukaryotes aminoacyl-tRNA synthetases (aaRSs) associate in multi-synthetase complexes (MSCs), however the role of such MSCs in translation is unknown. MSC function was investigated in vivo in the archaeon Thermococcus kodakarensis, wherein six aaRSs were affinity co-purified together with several other factors involved in protein synthesis, suggesting that MSCs may interact directly with translating ribosomes. In support of this hypothesis, the aminoacyl-tRNA synthetase (aaRS) activities of the MSC were enriched in isolated T. kodakarensis polysome fractions. These data indicate that components of the archaeal protein synthesis machinery associate into macromolecular assemblies in vivo and provide the potential to increase translation efficiency by limiting substrate diffusion away from the ribosome, thus facilitating rapid recycling of tRNAs.     

Isolation and characterization of an estrogen-regulated ribosome-associated inactivator of tRNA aminoacylation in the uterus

Estradiol (E2) induces an increase in the peptide elongation rate of isolated uterine ribosomes assayed in a cell-free protein synthesis system. An inhibitory factor, extracted from ribosomes of E2-deprived rats, was found to inhibit the peptide elongation reaction by acting on certain tRNAs to render them incapable of binding to aminoacyl-tRNA synthetases, thus reducing the availability of specific aminoacylated tRNAs required for the sequential translation of the codons in mRNA. The uterine ribosome-associated tRNA inactivator (RATI) has been partially purified and monoclonal antibodies (MABs) to RATI have been prepared. Specificity of the MABs for RATI was indicated by the inactivation of RATI in vitro by the anti-RATI MABs. RATI selectively inactivates deacylated, but not acylated, tRNAs and the inactivation does not appear to involve nuclease cleavage of the tRNA. Within 1 h after E2 treatment 50% of both RATI activity and immunoreactivity were lost from the uterine ribosome extracts, suggesting that E2 regulation of tRNA reutilization may occur through dissociation of RATI from the ribosomal site of tRNA deacylation or alteration in the structure of RATI resulting in inactivation both biologically and immunologically. We propose that RATI may function as an E2-regulatable 'switch' mechanism which inactivates, delays or defers the aminoacylation of certain tRNAs in the absence of E2 and which participates in the regulation of protein synthesis at the translational level by creating rate-limiting levels of certain tRNAs in the E2-deprived uterus.     

血管生成素与tRNA片段化

tRNA主要功能是转运氨基酸参与蛋白质合成,在蛋白质生物合成过程中起着关键性的作用．近年来发现,tRNA是细胞内小RNA分子的重要来源,具有其它重要的生物学功能．来源于成熟tRNA分子的tRNA片段根据切割位置及生成机制的不同,主要分为两类：一类是tRNA半分子（tRNA halves）;另一类是较小的tRNA片段,称为tRFs( tRNA fragments)．在哺乳动物细胞中,tRNA半分子由血管生成素在tRNA分子反密码环处切割生成．本文主要针对tRNA半分子的加工机制、功能及在临床上的潜在应用进行综述．     

The role of tRNA and ribosome competition in coupling the expression of different mRNAs in Saccharomyces cerevisiae

Protein synthesis translates information from messenger RNAs into functional proteomes. Because of the finite nature of the resources required by the translational machinery, both the overall protein synthesis activity of a cell and activity on individual mRNAs are controlled by the allocation of limiting resources. Upon introduction of heterologous sequences into an organism-for example for the purposes of bioprocessing or synthetic biology-limiting resources may also become overstretched, thus negatively affecting both endogenous and heterologous gene expression. In this study, we present a mean-field model of translation in Saccharomyces cerevisiae for the investigation of two particular translational resources, namely ribosomes and aminoacylated tRNAs. We firstly use comparisons of experiments with heterologous sequences and simulations of the same conditions to calibrate our model, and then analyse the behaviour of the translational system in yeast upon introduction of different types of heterologous sequences. Our main findings are that: competition for ribosomes, rather than tRNAs, limits global translation in this organism; that tRNA aminoacylation levels exert, at most, weak control over translational activity; and that decoding speeds and codon adaptation exert strong control over local (mRNA specific) translation rates.     

Single-molecule structural dynamics of EF-G--ribosome interaction during translocation

EF-G catalyzes translocation of mRNA and tRNAs within the ribosome during protein synthesis. Detection of structural states in the reaction sequence that are not highly populated can be facilitated by studying the process one molecule at a time. Here we present single-molecule studies of translocation showing that, for ribosomes engaged in poly(Phe) synthesis, fluorescence resonance energy transfer (FRET) between the G' domain of EF-G and the N-terminal domain of ribosomal protein L11 occurs within two rapidly interconverting states, having FRET efficiencies of 0.3 and 0.6. The antibiotic fusidic acid increases the population of the 0.6 state, indicating that it traps the ribosome.EF-G complex in a preexisting conformation formed during translation. Only the 0.3 state is observed when poly(Phe) synthesis is prevented by omission of EF-Tu, or in studies on vacant ribosomes. These results suggest that the 0.6 state results from the conformational lability of unlocked ribosomes formed during translocation. An idling state, possibly pertinent to regulation of protein synthesis, is detected in some ribosomes in the poly(Phe) system.     

The architecture of eukaryotic translation

Translation in baker’s yeast involves the coordinated interaction of 200 000 ribosomes, 3 000 000 tRNAs and between 15 000 and 60 000 mRNAs. It is currently unknown whether this specific constellation of components has particular relevance for the requirements of the yeast proteome, or whether this is simply a frozen accident. Our study uses a computational simulation model of the genome-wide translational apparatus of yeast to explore quantitatively which combinations of mRNAs, ribosomes and tRNAs can produce viable proteomes. Surprisingly, we find that if we only consider total translational activity over time without regard to composition of the proteome, then there are many and widely differing combinations that can generate equivalent synthesis yields. In contrast, translational activity required for generating specific proteomes can only be achieved within a much more constrained parameter space. Furthermore, we find that strongly ribosome limited regimes are optimal for cells in that they are resource efficient and simplify the dynamics of the system.     

Reconstitution of translation from Thermus thermophilus reveals a minimal set of components sufficient for protein synthesis at high temperatures and functional conservation of modern and ancient translation components

Thermus thermophilus is a thermophilic model organism distantly related to the mesophilic model organism E. coli. We reconstituted protein translation of Thermus thermophilus in vitro from purified ribosomes, transfer ribonucleic acids (tRNAs) and 33 recombinant proteins. This reconstituted system was fully functional, capable of translating natural messenger RNA (mRNA) into active full-length proteins at temperatures up to 65°C and with yields up to 60 μg/ml. Surprisingly, the synthesis of active proteins also occurred at 37°C, a temperature well below the minimal growth temperature for T. thermophilus. A polyamine was required, with tetraamine being most effective, for translation at both high and low temperatures. Using such a defined in vitro system, we demonstrated a minimal set of components that are sufficient for synthesizing active proteins at high temperatures, the functional compatibility of key translation components between T. thermophilus and E. coli, and the functional conservation of a number of resurrected ancient elongation factors. This work sets the stage for future experiments that apply abundant structural information to biochemical characterization of protein translation and folding in T. thermophilus. Because it contains significantly reduced nucleases and proteases, this reconstituted thermostable cell-free protein synthesis system may enable in vitro engineering of proteins with improved thermostability.     

Regulation of ex-translational activities is the primary function of the multi-tRNA synthetase complex

During mRNA translation, tRNAs are charged by aminoacyl-tRNA synthetases and subsequently used by ribosomes. A multi-enzyme aminoacyl-tRNA synthetase complex (MSC) has been proposed to increase protein synthesis efficiency by passing charged tRNAs to ribosomes. An alternative function is that the MSC repurposes specific synthetases that are released from the MSC upon cues for functions independent of translation. To explore this, we generated mammalian cells in which arginyl-tRNA synthetase and/or glutaminyl-tRNA synthetase were absent from the MSC. Protein synthesis, under a variety of stress conditions, was unchanged. Most strikingly, levels of charged tRNA^Arg and tRNA^Gln remained unchanged and no ribosome pausing was observed at codons for arginine and glutamine. Thus, increasing or regulating protein synthesis efficiency is not dependent on arginyl-tRNA synthetase and glutaminyl-tRNA synthetase in the MSC. Alternatively, and consistent with previously reported ex-translational roles requiring changes in synthetase cellular localizations, our manipulations of the MSC visibly changed localization.     

Inhibition of the aminoacylation of selected tRNA molecules by an estrogen-regulated factor on uterine ribosomes. Regulation of aminoacylation of tRNA by estrogens

Administration of estradiol to ovariectomized mature rats for 1 h induces a transient increase in the peptide elongation rate on uterine ribosomes. An inhibitor of the peptide elongation rate, which appears to be regulated by estrogen treatment in vivo, can be extracted from ribosomes of estrogen-deprived rats. The extracted inhibitor or a native inhibitor-ribosome complex affects the rate of the peptide elongation reaction in a uterine cell-free protein synthesis system by inhibiting the ability of selected tRNAs in the assay to be charged with amino acids by their respective aminoacyl-tRNA synthetases. The degree of inhibition of charging of the affected tRNAs ranges from 22% to 78%, the order of inhibition being Pro greater than Val greater than Arg greater than Try greater than Leu greater than Glu greater than Ile greater than Gly greater than His greater than Ser greater than Lys. Inhibition results from a specific dose-dependent, and presumably reversible, effect of the inhibitor on tRNA, but not on the aminoacyl-tRNA synthetase. The effect does not result from removal of A-C-C terminal nucleotides from the 3' end of tRNA, but does inhibit the ability of selected tRNAs to bind to the aminoacyl-tRNA synthetases. We propose that regulation of the peptide elongation rate on uterine ribosomes by estradiol occurs through the estradiol-induced inactivation of a ribosome-associated inhibitor, which causes a reversible alteration to selected tRNAs. The modified tRNAs are unable to bind to their respective aminoacyl-tRNA synthetase to become charged with an amino acid thus causing the availability of selected aminoacyl-tRNAs to become rate-limiting in the sequential elongation of peptides.     

A single-step method for purification of active His-tagged ribosomes from a genetically engineered Escherichia coli

With the rapid development of the ribosome field in recent years a quick, simple and high-throughput method for purification of the bacterial ribosome is in demand. We have designed a new strain of Escherichia coli (JE28) by an in-frame fusion of a nucleotide sequence encoding a hexa-histidine affinity tag at the 3′-end of the single copy rplL gene (encoding the ribosomal protein L12) at the chromosomal site of the wild-type strain MG1655. As a result, JE28 produces a homogeneous population of ribosomes (His)₆-tagged at the C-termini of all four L12 proteins. Furthermore, we have developed a single-step, high-throughput method for purification of tetra-(His)₆-tagged 70S ribosomes from this strain using affinity chromatography. These ribosomes, when compared with the conventionally purified ones in sucrose gradient centrifugation, 2D-gel, dipeptide formation and a full-length protein synthesis assay showed higher yield and activity. We further describe how this method can be adapted for purification of ribosomal subunits and mutant ribosomes. These methodologies could, in principle, also be used to purify any functional multimeric complex from the bacterial cell.     

Protease activity associated with HeLa cell ribosomes

HeLa cells contain endoprotease activity, detected by a sensitive, solid phase assay. The endoprotease has the ability to cleave a variety of protein substrates and is trypsin-like in its sensitivity to inhibitors. The activity is in part associated with cellular ribosomes and polysomes. A variety of biological and physical-chemical treatments which alter ribosomes or protein synthesis also directly affect the ribosomal protease activity.     

Specialized Yeast Ribosomes: A Customized Tool for Selective mRNA Translation

Evidence is now accumulating that sub-populations of ribosomes - so-called specialized ribosomes - can favour the translation of subsets of mRNAs. Here we use a large collection of diploid yeast strains, each deficient in one or other copy of the set of ribosomal protein (RP) genes, to generate eukaryotic cells carrying distinct populations of altered ‘specialized’ ribosomes. We show by comparative protein synthesis assays that different heterologous mRNA reporters based on luciferase are preferentially translated by distinct populations of specialized ribosomes. These mRNAs include reporters carrying premature termination codons (PTC) thus allowing us to identify specialized ribosomes that alter the efficiency of translation termination leading to enhanced synthesis of the wild-type protein. This finding suggests that these strains can be used to identify novel therapeutic targets in the ribosome. To explore this further we examined the translation of the mRNA encoding the extracellular matrix protein laminin β3 (LAMB3) since a LAMB3-PTC mutant is implicated in the blistering skin disease Epidermolysis bullosa (EB). This screen identified specialized ribosomes with reduced levels of RP L35B as showing enhanced synthesis of full-length LAMB3 in cells expressing the LAMB3-PTC mutant. Importantly, the RP L35B sub-population of specialized ribosomes leave both translation of a reporter luciferase carrying a different PTC and bulk mRNA translation largely unaltered.     

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.     

The structures of antibiotics bound to the E site region of the 50 S ribosomal subunit of Haloarcula marismortui: 13-deoxytedanolide and girodazole

Crystal structures of the 50 S ribosomal subunit from Haloarcula marismortui complexed with two antibiotics have identified new sites at which antibiotics interact with the ribosome and inhibit protein synthesis. 13-Deoxytedanolide binds to the E site of the 50 S subunit at the same location as the CCA of tRNA, and thus appears to inhibit protein synthesis by competing with deacylated tRNAs for E site binding. Girodazole binds near the E site region, but is somewhat buried and may inhibit tRNA binding by interfering with conformational changes that occur at the E site. The specificity of 13-deoxytedanolide for eukaryotic ribosomes is explained by its extensive interactions with protein L44e, which is an E site component of archaeal and eukaryotic ribosomes, but not of eubacterial ribosomes. In addition, protein L28, which is unique to the eubacterial E site, overlaps the site occupied by 13-deoxytedanolide, precluding its binding to eubacterial ribosomes. Girodazole is specific for eukarytes and archaea because it makes interactions with L15 that are not possible in eubacteria.