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.     

RelE-mediated dormancy is enhanced at high cell density in Escherichia coli

Bacteria show remarkable adaptability under several stressful conditions by shifting themselves into a dormant state. Less is known, however, about the mechanism underlying the cell transition to dormancy. Here, we report that the transition to dormant states is mediated by one of the major toxin-antitoxin systems, RelEB, in a cell density-dependent manner in Escherichia coli K-12 MG1655. We constructed a strain, IKA121, which expresses the toxin RelE in the presence of rhamnose and lacks chromosomal relBE and rhaBAD. With this strain, we demonstrated that RelE-mediated dormancy is enhanced at high cell densities compared to that at low cell densities. The initiation of expression of the antitoxin RelB from a plasmid, pCA24N, reversed RelE-mediated dormancy in bacterial cultures. The activation of RelE increased the appearance of persister cells against β-lactams, quinolones, and aminoglycosides, and more persister cells appeared at high cell densities than at low cell densities. Further analysis indicated that amino acid starvation and an uncharacterized extracellular heat-labile substance promote RelE-mediated dormancy. This is a first report on the induction of RelE-mediated dormancy by high cell density. This work establishes a population-based dormancy mechanism to help explain E. coli survival in stressful environments.     

The suppression of defective translation by ppGpp and its role in the stringent response.

Amino acid starvation is shown to decrease the fidelity of translation in E. coli. When proteins are analyzed by two-dimensional gel electrophoresis, missense errors are detected as an unusual heterogeneity in their isoelectric points, while premature termination of protein synthesis can be recognized by a decreased relative rate of synthesis of higher molecular weight proteins and by the the accumulation of a complex group of new small polypeptides. The types of translational errors observed are amino acid-specific. For example, starvation of a rel- strain for histidine produces severe isoelectric point heterogeneity with little evidence of premature termination, while starvation for leucine has little effect on the isoelectric points, but produces a drastic decrease in the average molecular weight of the newly synthesized protein. These differences suggest codon-specific errors in reading the genetic code. In these rel- cells, the effect of amino acid starvation on the rates of synthesis of complete individual proteins is both protein- and amino acid-specific. For example, ribosomal protein L7/12, which lacks histidine, is made at a higher level during histidine starvation than during isoleucine or leucine starvation. This suggests that in rel- cells, the modulation of gene expression caused by the lack of a particular amino acid is, at least in part, a function of the abundance of that amino acid in particular proteins-that is, the response of rel- cells to starvation is consistent with the theory that the inhibition of protein synthesis and the accompanying increase in error frequency both result from low levels of the correct substrate. In marked contrast, virtually no starvation-induced translational errors are detected in a rel+ strain, and the response is not amino acid-specific. Varoius data strongly imply that in this rel+ strain, essentially all the changes caused by starvation are due to the accumulation of ppGpp, which independently reduces protein synthesis, thereby suppressing all the direct effects of amino acid limitation seen in rel- strains (where ppGpp does not accumulate upon starvation). A model is presented which describes how ppGpp might suppress the direct effects of starvation and avoid the loss of translational fidelity. In addition, the direct and specific effects of ppGpp on gene expression are examined independently of amino acid starvation.     

Purification of the RelB and RelE proteins of Escherichia coli: RelE binds to RelB and to ribosomes

The direct interaction of the Escherichia coli cytotoxin RelE with its specific antidote, RelB, was demonstrated in two ways: (i) copurification of the two proteins and (ii) a positive yeast two-hybrid assay involving the relB and relE genes. In addition, the purified RelE protein exhibited ribosome-binding activity in an in vitro assay, supporting previous observations suggesting that it is an inhibitor of translation.     

Characterization of the stringent and relaxed responses of Streptococcus equisimilis.

The 739-codon rel(Seq) gene of Streptococcus equisimilis H46A is bifunctional, encoding a strong guanosine 3',5'-bis(diphosphate) 3'-pyrophosphohydrolase (ppGppase) and a weaker ribosome-independent ATP:GTP 3'-pyrophosphoryltransferase [(p)ppGpp synthetase]. To analyze the function of this gene, (p)ppGpp accumulation patterns as well as protein and RNA synthesis were compared during amino acid deprivation and glucose exhaustion between the wild type and an insertion mutant carrying a rel(Seq) gene disrupted at codon 216. We found that under normal conditions, both strains contained basal levels of (p)ppGpp. Amino acid deprivation imposed by pseudomonic acid or isoleucine hydroxamate triggered a rel(Seq)-dependent stringent response characterized by rapid (p)ppGpp accumulation at the expense of GTP and abrupt cessation of net RNA accumulation in the wild type but not in the mutant. Tetracycline added to block (p)ppGpp synthesis caused the accumulated (p)ppGpp to degrade rapidly, with a concomitant increase of the GTP pool (decay constant of ppGpp, approximately 0.7 min(-1)). Simultaneous addition of pseudomonic acid and tetracycline to mimic a relaxed response caused wild-type RNA synthesis to proceed at rates approximating those seen under either condition in the mutant. Glucose exhaustion provoked the (p)ppGpp accumulation response in both the wild type and the rel(Seq) insertion mutant, consistent with the block of net RNA accumulation in both strains. Although the source of (p)ppGpp synthesis during glucose exhaustion remains to be determined, these findings reinforce the idea entertained previously that rel(Seq) fulfils functions that reside separately in the paralogous reL4 and spoT genes of Escherichia coli. Analysis of (p)ppGpp accumulation patterns was complicated by finding an unknown phosphorylated compound that comigrated with ppGpp under two standard thin-layer chromatography conditions. Unlike ppGpp, this compound did not adsorb to charcoal and did not accumulate appreciably during isoleucine deprivation. Like ppGpp, the unknown compound did accumulate during energy source starvation.     

Correlation between RNA synthesis and basal level guanosine 5'-diphosphate 3'-diphosphate in relaxed mutants of Escherichia coli

Through the use of a new nucleotide extraction procedure, we had previously shown that relaxed mutants of Escherichia coli exhibit a unique response to amino acid starvation (Lagosky, P. A., and Chang, F. N. (1980) J. Bacteriol. 144, 499-508). The basal level amounts of guanosine 5'-diphosphate 3'-diphosphate (ppGpp) in both relA and phenotypically relaxed relA+ rplK (relC) strains were shown to decrease at the onset of amino acid limitation and to remain severely depressed throughout the course of the starvation. Upon resupplementation of amino acid-starved relaxed mutants, the production of ppGpp resumes and results in the temporary overaccumulation of this nucleotide beyond its original basal level amount. We now show that the basal level ppGpp content of relaxed bacteria, as well as its subsequent fluctuations in response to amino acid starvation, is inversely correlated with the initial rates of RNA synthesis in these strains. The ability of ppGpp to control the rate of protein synthesis in relA mutants was also examined. It was observed that ppGpp had no apparent direct effect on the initial rates of protein synthesis in relA mutants. The constant inverse correlation which exists between ppGpp content in relA mutants, and their rates of RNa synthesis provide evidence which indicates that basal level ppGpp synthesis has definite physiological significance. It also suggests that the synthesis of basal level ppGpp might be an absolute requirement needed for normal bacterial growth.     

Influence of amino acid starvation on guanosine 5''-diphosphate 3''-diphosphate basal-level synthesis in Escherichia coli.

We observed that the synthesis of basal-level guanosine 5'-diphosphate 3'-diphosphate (ppGpp) in both relA mutants and relA+ relC strains of Escherichia coli decreased in response to amino acid limitation and that this was accompanied by an increase in ribonucleic acid (RNA) synthesis. Addition of the required amino acid to starved cultures of relaxed bacteria resulted in the resumption of ppGpp synthesis and a concomitant decrease in RNA production. Our results indicate that relA mutants retain a stringent factor-independent ribosomal mechanism for basal-level ppGpp synthesis. They also suggest that in relA+ bacteria, stringent factor-mediated ppGpp synthesis and the production of basal-level ppGpp are mutually exclusive. These findings substantiate the hypothesis that there are two functionally discrete mechanisms for ppGpp synthesis in E. coli. Through these studies we have also obtained new evidence which indicates that ppGpp serves as a modulator of RNA synthesis during balanced growth as well as under conditions of nutritional downshift and starvation.     

Lowering GTP Level Increases Survival of Amino Acid Starvation but Slows Growth Rate for Bacillus subtilis Cells Lacking (p)ppGpp

Bacterial cells sense external nutrient availability to regulate macromolecular synthesis and consequently their growth. In the Gram-positive bacterium Bacillus subtilis, the starvation-inducible nucleotide (p)ppGpp negatively regulates GTP levels, both to resist nutritional stress and to maintain GTP homeostasis during growth. Here, we quantitatively investigated the relationship between GTP level, survival of amino acid starvation, and growth rate when GTP synthesis is uncoupled from its major homeostatic regulator, (p)ppGpp. We analyzed growth and nucleotide levels in cells that lack (p)ppGpp and found that their survival of treatment with a nonfunctional amino acid analog negatively correlates with both growth rate and GTP level. Manipulation of GTP levels modulates the exponential growth rate of these cells in a positive dose-dependent manner, such that increasing the GTP level increases growth rate. However, accumulation of GTP levels above a threshold inhibits growth, suggesting a toxic effect. Strikingly, adenine counteracts GTP stress by preventing GTP accumulation in cells lacking (p)ppGpp. Our results emphasize the importance of maintaining appropriate levels of GTP to maximize growth: cells can survive amino acid starvation by decreasing GTP level, which comes at a cost to growth, while (p)ppGpp enables rapid adjustment to nutritional stress by adjusting GTP level, thus maximizing fitness.     

Continued Expression of the Ribonucleic Acid Control Gene During Inhibition of Escherichia coli Ribonucleic Acid and Protein Synthesis

The effect of the ribonucleic acid (RNA) control (RC) gene on the biosynthesis of viral RNA has been examined in an RC(str) and an RC(rel) host infected with R17 RNA bacteriophage under conditions in which host RNA and protein synthesis were inhibited by the addition of rifampicin. Methionine and isoleucine starvation depressed viral RNA biosynthesis in an RC(str) host but not in an RC(rel) host. However, histidine starvation had little effect on viral RNA and protein synthesis in both RC(str) and RC(rel) cells, although it had a marked effect on host protein and RNA synthesis in an RC(str) host. Chloramphenicol relieved the effect of amino acid starvation on viral RNA synthesis in an RC(str) host. It is concluded that stringent control of viral RNA biosynthesis does not require the continued biosynthesis of the RC gene product (RNA or protein) and that a preformed RC gene product can regulate the biosynthesis of the exogenous RNA. It is suggested that the amino acid dependence of viral RNA biosynthesis is due to its obligatory coupling with the translation of the viral coat protein which lacks histidine. It may be inferred that the amino acid requirement of bacterial RNA is due to its coupling with the translation of a host-specific protein (other than the RC gene product) which requires a full complement of amino acids. Since chloramphenicol is known to permit ribosome movement in the absence of protein synthesis, it is suggested that ribosome movement along the nascent RNA chain is a sufficient condition for the continuation of RNA synthesis.     

Toxic effects of high levels of ppGpp in Escherichia coli are relieved by rpoB mutations.

A controversy has surrounded the questions of whether or not guanosine tetraphosphate (ppGpp) is a specific inhibitor of bacterial rRNA and tRNA synthesis, especially during normal exponential growth, and whether the RNA polymerase is the target of ppGpp action. To answer these questions, a pBR322-derived plasmid, pKT28, was constructed that carries the Escherichia coli relA gene encoding a ppGpp synthetase under control of the lacUV5 promoter. The plasmid was used to transform the ppGpp reporter strain VH271 in which expression of beta-galactosidase from an rrnB P1 promoter is inhibited by ppGpp. In the presence of high concentrations of lac inducer, bacteria of the transformed strain accumulate ppGpp with the result that synthesis of rRNA and beta-galactosidase is inhibited and growth ceases. At low concentrations of inducer, growth is only reduced and cells form small white colonies on X-gal indicator plates. After continued incubation, these colonies form blue sectors of faster growing mutant cells. Phage P1 transduction experiments showed that these mutants have mutations cotransducing with rpoB, the gene encoding the beta-subunit of RNA polymerase. One particular mutant strain, KT13, had acquired partial resistance to ppGpp inhibition of rRNA synthesis. The mutation in this strain was cloned by in vivo recombination into an rpoB plasmid. The presence of this plasmid conferred increased resistance to overproduction of ppGpp. These results suggest that ppGpp is a specific inhibitor of rRNA synthesis, even in the absence of amino acid starvation, and that RNA polymerase is involved as the target of ppGpp action.     

Guanosine polyphosphate concentration and stable RNA synthesis in Bacillus subtilis following suppression of protein synthesis

Amount of guanosine-5'-triphosphate, 3'-diphosphate (pppGpp) and guanosine-5'-diphosphate, 3'-diphosphate (ppGpp) in the cells of b. subtilis increased several times during starvation for lysine or after treatment with serine hydroxamate (analog of serine) or norvaline (analog of leucine), or in the presence of trimethoprim, which induced deficiency of methionine and leucine. In exponentially growing cells the concentration of pppGpp was found to be 10-20 pmol/A600. When serine hydroxamate or trimethoprim were added, concentration of pppGpp increased to 500-800 pmol/A600 and then slowly diminished. Elimination of lysine or addition to the culture medium of norvaline caused slight transitory accumulation of pppGpp (150 pmol/A600). The amount of another nucleotide ppGpp was always 2-3 times lower than one of pppGpp. Accumulation of (p)ppGpp in rel+ cells was accompanied by cessation of stable RNA synthesis. Under conditions described above rel- cells continued RNA synthesis and did not accumulate (p)ppGpp. In the rel+ cells treated with serine hydroxamate synthesis of stable RNA resumed and the amount of (p)ppGpp decreased after addition of serine or tetracycline and chloramphenicol. The half-life period for pppGpp in the presence of chloramphenicol was determined to be 30-40 seconds. Thus, during aminoacyl-tRNA deficiency rel+ cells of B. subtilis accumulate (p)ppGpp, which are believed to participate in negative regulation of RNA synthesis. Slight accumulation of pppGpp without concomitant inhibition of stable RNA synthesis was observed after treatment of growing cells with chloramphenicol.     

Effect of Serine Hydroxamate on Phospholipid Synthesis in Escherichia coli

Serine hydroxamate, which inhibits the charging of seryl-transfer ribonucleic acid, reduced the synthesis of phospholipid and nucleic acids in Escherichia coli. This effect was analogous to depriving amino acid auxotrophs of their nutritional requirement and appears to be a manifestation of the stringent response shown by rel(+) strains of E. coli. Amino acid starvation (serine or methionine) alone or serine hydroxamate treatment alone results in 60 to 80% inhibition of lipid accumulation, 90% inhibition of ribonucleic acid accumulation, and an increase in guanosine tetraphosphate (ppGpp). These three effects were reversed by addition of chloramphenicol (CM). A combination of serine starvation and serine hydroxamate treatment resulted in inhibition of lipid and RNA accumulation as well as an increase in ppGpp, but the consequences of the double block were not reversed by CM. We conclude that a strong interrelationship exists among these processes and that CM acts to relax a stringent response by mechanisms other than interference with ppGpp formation. All species of phospholipid were affected by a stringent response evoked by amino acid starvation or addition of serine hydroxamate, but in all cases the synthesis of phosphatidylethanolamine was most severely inhibited. Serine hydroxamate was not incorporated into lipid but specifically caused phosphatidylserine accumulation. Serine starvation produced a dramatic alteration of the distribution of isotope incorporated into phospholipid, which resulted from the stringent response compounded with the limitation of a substrate for phosphatidylserine synthesis.     

Role of peptide chain elongation factor G in guanosine 5'-diphosphate 3'-diphosphate synthesis.

In a wild-type strain (relA+) of Escherichia coli, starvation of amino acid led to an immediate cessation of the synthesis of stable ribonucleic acids, together with the accumulation of an unusual nucleotide, guanosine 5'-diphosphate 3'-diphosphate, commonly known as ppGpp. This compound also accumulated during heat shock. When temperature-sensitive protein synthesis elongation factor G (EF-G) was introduced into E. coli NF859, a relA+ strain, the synthesis of ppGpp was reduced to approximately one-half that of wild-type EF-G+ cells at a nonpermissive temperature of 40 degrees C. Furthermore, fusidic acid, an inhibitor of protein synthesis which specifically inactivates EF-G, prevented any accumulation of ppGpp during the heat shock. We suggest that a functional EF-G protein is necessary for ppGpp accumulation under temperature shift conditions, possibly by mediating changes in the function of another protein, the relA gene product. However, EF-G is probably not required for the synthesis of ppGpp during the stringent response, since its inactivation did not prevent ppGpp accumulation during amino acid starvation.     

Control of rRNA and tRNA syntheses in Escherichia coli by guanosine tetraphosphate

The expression of stable RNA (rRNA and tRNA) genes and the concentration of guanosine tetraphosphate (ppGpp) were measured in an isogenic pair of relA+ and relA derivatives of Escherichia coli B/r. The cells were either growing exponentially at different rates or subject to amino acid starvation when they were measured. The specific stable RNA gene activity (rs/rt, the rate of rRNA and tRNA synthesis relative to the total instantaneous rate of RNA synthesis) was found to decrease from 1.0 at a ppGpp concentration of 0 (extrapolated value) to 0.24 at saturating concentrations of ppGpp (above 100 pmoles per optical density at 460 nm unit of cell mass). The same relationship between the rs/rt ratio and ppGpp concentration was obtained independent of the physiological state of the bacteria (i.e., independent of the growth rate or of amino acid starvation) and independent of the relA allele. It can be concluded that ppGpp is an effector for stable RNA gene control and that stable RNA genes are not controlled by factors other than the ppGpp-mediated system. The results were shown to be qualitatively and quantitatively consistent with data on in vitro rRNA gene control by ppGpp, and they were interpreted in the light of reported ideas derived from those in vitro experiments.     

Effect of the “Ribonucleic Acid Control” Locus in Escherichia coli on T4 Bacteriophage-Specific Ribonucleic Acid Synthesis

Amino acid control of ribonucleic acid (RNA) synthesis in bacteria is known to be governed genetically by the rel locus. We investigated whether the rel gene of the host would also exert its effect on the regulation of phage-specific RNA synthesis in T4 phage-infected Escherichia coli cells. Since T-even phage infection completely shuts off host macromolecular synthesis, phage RNA synthesis could be followed specifically by the cumulative incorporation of radioactivity from labeled precursors into RNA of infected cells. Labeled uracil was shown to accumulate in phage-specific RNA for 30 to 35 min after infection, a phenomenon which probably reflects an expansion of the labile phage-RNA pool. Amino acid starvation was effected by the use of auxotrophic bacterial strains or thienylalanine. The latter substance is an amino acid analogue which induces a chemical auxotrophy by inhibiting the biosynthesis of phenylalanine, tyrosine, and tryptophan. Phage RNA synthesis was strictly dependent on the presence of amino acids, whereas phage deoxyribonucleic acid synthesis was not. By the use of several pairs of bacterial strains which were isogenic except for the rel gene, it was demonstrated that amino acid dependence was related to the allelic state of this gene. If the rel gene was mutated, amino acid starvation did not restrict phage RNA synthesis.     

The bacterial toxin RelE displays codon-specific cleavage of mRNAs in the ribosomal A site

The Escherichia coli relBE operon encodes a toxin-antitoxin pair, RelE-RelB. RelB can reverse inhibition of protein synthesis by RelE in vivo. We have found that although RelE does not degrade free RNA, it cleaves mRNA in the ribosomal A site with high codon specificity. Among stop codons UAG is cleaved with fast, UAA intermediate and UGA slow rate, while UCG and CAG are cleaved most rapidly among sense codons. We suggest that inhibition of protein synthesis by RelE is reversed with the help of tmRNA, and that RelE plays a regulatory role in bacteria during adaptation to poor growth conditions.