Ribosomes inhibit an RNase E cleavage which induces the decay of the rpsO mRNA of Escherichia coli.

The hypothesis generally proposed to explain the stabilizing effect of translation on many bacterial mRNAs is that ribosomes mask endoribonuclease sites which control the mRNA decay rate. We present the first demonstration that ribosomes interfere with a particular RNase E processing event responsible for mRNA decay. These experiments used an rpsO mRNA deleted of the translational operator where ribosomal protein S15 autoregulates its synthesis. We demonstrate that ribosomes inhibit the RNase E cleavage, 10 nucleotides downstream of the rpsO coding sequence, responsible for triggering the exonucleolytic decay of the message mediated by polynucleotide phosphorylase. Early termination codons and insertions which increase the length of ribosome-free mRNA between the UAA termination codon and this RNase E site destabilize the translated mRNA and facilitate RNase E cleavage, suggesting that ribosomes sterically inhibit RNase E access to the processing site. Accordingly, a mutation which reduces the distance between these two sites stabilizes the mRNA. Moreover, an experiment showing that a 10 nucleotide insertion which destabilizes the untranslated mRNA does not affect mRNA stability when it is inserted in the coding sequence of a translated mRNA demonstrates that ribosomes can mask an RNA feature, 10-20 nucleotides upstream of the processing site, which contributes to the RNase E cleavage efficiency.     

Translational control in sea urchin eggs and embryos: Initiation is rate limiting in blastula stage embryos

To determine whether initiation is rate-limiting in protein synthesis during the embryogenesis of sea urchins, polyribosome profiles of unfertilized eggs and cleavage, blastula and prism stage embryos were examined after incubation of the eggs and embryos in the presence and absence of low amounts of emetine, an inhibitor of polypeptide elongation. The ribosomes were radioactively labeled with [³H]uridine by injection of the adults during oogenesis so that we could monitor emetine-dependent shifts of monoribosomes to polyribosomes. Although initiation is not rate limiting in unfertilized eggs or 2- to 16-cell embryos of Strongylocentrotus purpuratus, it is rate limiting in blastula and prism embryos. We suggest that initiation becomes rate limiting to allow the selective translation of certain classes of mRNA during later development.     

Analysis of an mRNA exhibiting anomalous translational specificity.

Gene 6 mRNA of Bacillus subtilis phage phi 29 is inefficiently translated under standard in vitro conditions by Escherichia coli, while it is efficiently translated by the in vitro system derived from B. subtilis. This is a rare example of the inability of E. coli to translate mRNA translated by B. subtilis. The ionic condition in the translation systems was the key component in the differential recognition of the gene 6 message by E. coli and B. subtilis ribosomes. Its translation by E. coli ribosomes was preferentially inhibited by moderate levels of KCl, while its translation by B. subtilis ribosomes was unaffected by these concentrations of salt. This preferential inhibition with E. coli ribosomes was observed in vitro as well as in vivo. While not influencing the general phenomenon of preferential inhibition, anion-specific effects were observed in overall protein synthesis. Glutamate and acetate promoted efficient synthesis over a broad range of concentrations, whereas chloride was inhibitory at all concentrations tested.     

Relief of polarity in E. coli depleted of 30S ribosomal subunits.

Summary Escherichia coli was depleted of ribosomes by a thermal shock at 47° C which quantitatively destroyed the 30S ribosomal subunits. During recovery in minimal medium at 30° C RNA is synthesized while protein synthesis resumes only after about 90 min. It is shown that lac mRNA is synthesized in the complete absence of ribosomal activity and hence RNA synthesis is not coupled to protein synthesis. Lac mRNA from a series of lac nonsense mutants was examined in both heated and untreated cells. It was found that the polar effect of nonsense mutation is relieved in the absence of ribosomes and that this relief is due to the synthesis of larger mRNA molecules. Since Rho remained active in thermally treated cells, premature termination at secondary signals within the lac operon must also depend on the presence of active ribosomes.Abbreviations used SSC 0.15 M Nacl, 0.015 M sodium citrate (pH 7.0) - mRNA messenger ribonucleic acid - IPTG isopropyl--D-thiogalactopyranoside - cAMP adenosine 3: 5-cyclic monophosphoric acid - LDS lithium dodecyl sulfate - TCA trichloroacetic acid The paper forms part of the first author's M.Sc. thesis     

Inhibition of Cell-Free Protein Synthesis by Hydrostatic Pressure

Pressure inhibition of cell-free polypeptide synthesis is manifested in the same manner as that observed in the intact cell: (i) starting at approximately 200 atm, there is a progressive inhibition with increasing pressures; (ii) there is complete inhibition at 680 atm; (iii) incorporation into polypeptide is instantaneously reversible after pressure release and proceeds at a rate parallel to an atmospheric control; and (iv) the volume change of activation (DeltaV*) is 100 cm(3)/mole. Peptide bond formation per se can occur at a pressure level which is totally inhibitory to polypeptide synthesis. The one investigated step in translation that is inhibited in an identical manner is the binding of aminoacyl-transfer ribonucleic acid (AA-tRNA) to the ribosome-messenger RNA (mRNA) complex. The volume change of activation (DeltaV*) calculated for the binding reaction is also 100 cm(3)/mole. Thus, the inability of AA-tRNA to bind to ribosomes and mRNA under pressure, possibly in conjunction with translocation, appears to be responsible for the observed inhibition of the translational mechanism.     

Regulation of protein synthesis in mammalian cells. V. Further studies on the effect of actinomycin D on translation control in HeLa cells

The rate of protein synthesis in HeLa cells appears to be regulated, in part, by a factor which promotes the association of ribosomes with messenger RNA and whose production is inhibited by actinomycin. The decline in protein synthesis after the administration of actinomycin is not primarily due to a decay of available messenger RNA but, rather, is a result of a decrease in the rate of ribosomal association with message.The decay of protein synthesis in actinomycin can be varied over a wide range by altering the temperature of cell incubation. Thus the half-life of protein synthesis decay ranges from eight hours at 34 °C to two hours at 41°C. The rapid decline of protein synthesis at 41 °C is not accompanied by a corresponding decay of the messenger RNA. Polyribosomes decrease in size, but they can be restored to normal sedimentation distributions by low levels of cycloheximide, suggesting that messenger RNA remains functional. The translation rate at 41 °C is unaltered. The dose-response of protein synthesis inhibition by actinomycin was measured and a half-maximum inhibition was found to be effected by 0·1 μg of the drug/ml.Another important aspect of the regulation of translation in HeLa cells is the response of cells to depressed rates of protein synthesis. At 42 °C, protein synthesis is severely inhibited, due to a failure in the association of ribosomes with messenger RNA. Prolonged incubation at the elevated temperature results in a significant repair of the lesion. This repair is inhibited by actinomycin. The half-maximum inhibition is achieved at levels of from 0·05 to 0·1 μg of the drug/ml.The cell response to depressed rates of protein synthesis can also be demonstrated using the drug cycloheximide. Prolonged incubation in the drug results in a response which then can promote protein synthesis at 42 °C. Here again, the half-maximum inhibition of the response to cyclohemixide is achieved by 0·1 μg of actinomycin/ml. These experiments suggest, but do not prove, that the cellular response may be mediated through the synthesis of RNA that promotes the initiation of translation and does not involve the subsequent production of protein.     

Models for decay of Escherichia coli lac messenger RNA and evidence for inactivating cleavages between its messages.

The size distributions of decaying polycistronic Escherichia coli lac messenger RNA have been followed on polyacrylamide gels. At the same time, equations have been derived that generate the theoretical size distributions of decaying macromolecules for different mechanisms of degradation. Using observed values of lac mRNA metabolism, it was possible to reproduce the in vivo patterns with a model in which cleavage occurs at the start of each of the three messages² and is followed by a net 5′ to 3′ wave of mass loss. Other models of degradation could not generate the observed in vivo patterns. These alternative mechanisms include: (1) the same number of primary cleavage sites (three) but at different positions on the full-length molecule; (2) an exclusive 5′ to 3′ directional degradation from the start of the lac mRNA (no cleavages); or (3) the presence of many internal targets. Further support for primary cleavage at the start of messages came from the observed accumulation of the intact z mRNA released by cleavage at the $\text{z}\text{y}$ boundary and from the predictable effects of specific deletions on the resultant size distributions.The significance of these cleavages has been assessed; they could be necessary “processing” events or, conversely, inactivate the message for translation. Full-length molecules as well as cleavage fragments have been fractionated by successive sucrose gradient centrifugation and tested for their capacity to form translation initiation complexes in vitro. Full-length lac RNA could form such complexes at one or more of its three ribosome-loading sites, whereas the y or a message fragments were inactive. These results suggest that a cleavage at or near the start of a message inactivates it.     

Translational fidelity and specificity of ribosomes cleaved by cloacin DF13.

The effect of cloacin DF13 cleavage on several functional properties of the ribosome has been studied in a translational system in vitro. Cleaved ribosomes synthesize relatively shorter polypeptide chains on synthetic and natural templates. Their translational specificity is, however, unchanged as judged by the read-out of MS2 RNA. Here, cleaved as well as control ribosomes start translation only on the coat cistron of the phage RNA. Cloacin cleavage of ribosomes increases their fidelity of translation. Differential inhibition of translation of synthetic and natural template was not observed.     

An investigation of the stability of messenger RNAs in cell-free,translational systems from uninfected and mengovirus-infected Ehrlich ascites tumor cells

The stabilities and translation of Ehrlich ascites tumor cell poly(A)-containing mRNA and mengovirus RNA in fractionated cell-free protein synthesizing systems from uninfected and mengovirus-infected Ehrlich ascites tumor cells were studied. During incubation of the systems about 20% of the input RNA is reduced in size and associated with ribosomes engaged in polypeptide synthesis; the remainder is rapidly degraded by RNases. At the end of active translation, both mRNA and nascent proteins are bound to polysomes which are of the same size as those formed during active protein synthesis. The kinetics of protein synthesis closely follow those of RNA hydrolysis. The stabilities of mengovirus RNA and poly(A)-containing mRNA from Ehrlich ascites tumor cells are the same in both systems.     

Altered translatability of messenger RNA from suspended anchorage-dependent fibroblasts: Reversal upon cell attachment to a surface

Anchorage-dependent cells, when forced into suspension culture, display a repertoire of dramatic, coordinated regulatory phenomena. Message production promptly decreases 5 fold but the cells maintain a constant amount of poly(A)⁺ by means of a concomitant stabilization of mRNA against decay. Protein synthesis shuts down much later and the mRNA is stored in a nonfunctioning state. In this study, the inactive mRNA is extracted from suspended cells and shown to have aberrant translation properties. Well defined polypeptides are apparently no longer synthesized when this mRNA directs protein formation in either reticulocyte or wheat germ-derived heterologous translation systems. Rather, shortened peptides are formed by this mRNA and these become smaller as mRNA is used from cells suspended for longer periods of time. Very few focused spots are formed when the aberrant polypeptides are analyzed in two-dimensional electrophoresis.The sedimentation properties of suspended cell mRNA and the size of poly(A) are unchanged from control monolayer cells. Cross-hybridization of cDNA transcribed from a control cell message population with suspended cell mRNA shows that all sequences are present in normal concentrations. While most identifiable spots disappear from the two-dimensional gel electropherograms of the protein products produced by suspended cell mRNA, a few polypeptides are still synthesized in relatively normal amounts. Conserved polypeptides are found in products of both the reticulocyte and wheat germ systems, but they are different products in each case. The lesion in the suspended cell mRNA does not seem to be at the 5′ termini, since synthesis of the shortened peptides is fully sensitive to inhibition by pm⁷G.Cells that contain extensively modified message can resume protein synthesis when allowed to reattach to a solid substrate. There is an apparent remodification of mRNA to normal translatability within a few hours of cell reattachment, since mRNA from recovering cells quickly resumes directing relatively normal patterns of polypeptide synthesis in vitro. The restoration of normal message function occurs even when new message formation is blocked with actinomycin.Cells recovering after reattachment synthesize supranormal amounts of a few major proteins involved with cell structure, as shown in these studies by an increased amount of translatable sequences which encode these proteins. The most apparent enhanced message is that coding for actin. mRNA from recovering cells produces in vitro several times more actin relative to other proteins than does control cell mRNA. The enhancement of actin mRNA is not seen in the message population of cells that reattach in the presence of actinomycin. The results suggest a morphologically related induction of gene expression.     

Translation of aberrant mRNAs lacking a termination codon or with a shortened 3'-UTR is repressed after initiation in yeast

A novel mRNA surveillance for mRNA lacking a termination codon (nonstop mRNA) has been proposed in which Ski7p is thought to recognize stalled ribosomes at the 3' end of mRNA. Here we report our analysis of translation and decay of nonstop mRNAs in Saccharomyces cerevisiae. Although the reduction of nonstop mRNAs was only 4.5-fold, a level that is sufficient for residual protein synthesis, translation products of nonstop mRNAs were hardly detectable. We show that nonstop mRNAs were associated with polysomes, but not with Pab1p. We also show that ribosomes translating nonstop mRNA formed stable and heavy polysome complexes with mRNA. These data suggest that ribosome stalling at the 3' end of nonstop mRNA may block further rounds of translation, hence repressing protein synthesis. Furthermore, it was found that the 5' --> 3' decay pathway was accelerated for nonstop mRNA decay in the absence of Ski7p. We also found that translation of aberrant mRNAs with a shortened 3'-UTR was repressed, suggesting that an improper spatial distance between the termination codon and the 3' end of mRNA results in translation repression.     

Decay of messenger ribonucleic acid from the lactose operon of Escherichia coli as a function of growth temperature

The inactivation rates of the first, β-galactosidase, and last, transacetylase, messages of the lactose operon of Escherichia coli were measured at different growth temperatures. The inactivation rate of each message appears to increase exponentially with temperature. The rate constant for this increase is almost twice as high for transacetylase message as it is for β-galactosidase message. The inactivation rate is more a direct function of growth temperature than of growth rate. At 15 °C transacetylase message is inactivated about 2.5 times more slowly than is β-galactosidase message. This difference is not paralleled by a different rate of chemical loss of the β-galactosidase message compared to the distal lac mRNA; all parts of the molecule appear to be lost at the same rate. This same pattern is observed in decay of the total mRNA; loss of capacity to direct peptide synthesis (functional inactivation) occurs at variable rates whereas loss of mRNA mass (chemical degradation) seems to occur at a uniform rate.We conclude that each message has a unique target for inactivation with a specifie temperature coefficient of sensitivity, and the inactivation of a message need not be associated with chemical destruction of the molecule.     

<Emphasis Type="Italic">Trans</Emphasis>-translation: Findings and hypotheses

Trans-translation is a unique process that switches the synthesis of a polypeptide hain encoded by a nonstop mRNA to the mRNA-like domain of tmRNA. The process is used in bacterial cells for rescuing the ribosomes arrested during translation of nonstop mRNA and directing this mRNA and the polypeptide product for degradation. Activity of tmRNA is essential for bacterial survival under adverse conditions, the quality control of translation, and the regulation of certain physiological pathways. The review focuses on recent advances in trans-translation studies. Details of the tmRNA-SmpB interaction and the structures of early ribosomal complexes are characterized, the causes of the appearance of an empty A site in the translating ribosome and possible mechanisms of the stalled ribosome recognition and resume codon determination are discussed, and the proteins degrading nonstop mRNAs and tagged peptides are considered.     

Recessive nonsense-suppression in yeast Saccharomyces cerevisiae

Summary The shift of recessive suppressor mutant of yeast Saccharomyces cerevisiae from permissive to restrictive conditions is accompanied by polysome decay and accumulation of 80 S ribosomes (Smirnov et al., 1976). In this paper some properties of 80 S ribosomes are studied. It is demonstrated that polysome decay under non-permissive conditions is not the consequence of the impairement of RNA synthesis. More than 70% of 80 S ribosomes accumulated under non-permissive conditions contain bound peptidyl-tRNAs localized in P-ribosomal site. tRNA moiety of bound peptidyl-tRNA is able to accept all 20 natural amino acids after chemical deacylation. Therefore it is not a specific isoacceptor species but rather total tRNA that is bound to ribosomes. The polypeptide residues of these peptidyl-tRNAs are heterogeneous in size. Their molecular weights are comparable with the molecular weights of the completed polypeptides. Some of the 80 S ribosomes accumulated under non-permissive conditions contain poly-A RNA. In conclusion, possible mechanism of the impairement of translation under non-permissive conditions in recessive suppressor strain is discussed.     

Two ribosome binding sites from the gene 0.3 messenger RNA of bacteriophage T7

Ribosome-protected regions have been isolated and analyzed from the bacteriophage T7 gene 0.3 mRNA labeled in vivo. Two discrete sites which are nearly equally protected by ribosomes are obtained from what was previously assumed to be a monocistronic message. Use of appropriate T7 deletion mutant RNAs has allowed mapping of both ribosome-recognized regions. Site a is positioned very close to the 5′ terminus of the mRNA and is apparently the initiator region for the major gene 0.3 protein, which acts to overcome the host DNA restriction system. Site b is located within several hundred nucleotides of the 3′ end of the RNA and probably initiates synthesis of a small polypeptide of unknown function. Both ribosome binding sites exhibit features common to other initiator regions from Escherichia coli and bacteriophage mRNAs. The proximity of site a to the RNase III cleavage site at the left end of gene 0.3 may explain why processing by RNase III is required for efficient translation of the major gene 0.3 protein.