Hybrid protein between ribosomal protein S16 and RimM of Escherichia coli retains the ribosome maturation function of both proteins

The RimM protein in Escherichia coli is associated with free 30S ribosomal subunits but not with 70S ribosomes and is important for efficient maturation of the 30S subunits. A mutant lacking RimM shows a sevenfold-reduced growth rate and a reduced translational efficiency. Here we show that a double alanine-for-tyrosine substitution in RimM prevents it from associating with the 30S subunits and reduces the growth rate of E. coli approximately threefold. Several faster-growing derivatives of the rimM amino acid substitution mutant were found that contain suppressor mutations which increased the amount of the RimM protein by two different mechanisms. Most of the suppressor mutations destabilized a secondary structure in the rimM mRNA, which previously was shown to decrease the synthesis of RimM by preventing the access of the ribosomes to the translation initiation region on the rimM mRNA. Three other independently isolated suppressor mutations created a fusion between rpsP, encoding the ribosomal protein S16, and rimM on the chromosome as a result of mutations in the rpsP stop codon preceding rimM. A severalfold-higher amount of the produced hybrid S16-RimM protein in the suppressor strains than of the native-sized RimM in the original substitution mutant seems to explain the suppression. The S16-RimM protein but not any native-size ribosomal protein S16 was found both in free 30S ribosomal subunits and in translationally active 70S ribosomes of the suppressor strains. This suggests that the hybrid protein can substitute for S16, which is an essential protein probably because of its role in ribosome assembly. Thus, the S16-RimM hybrid protein seems capable of carrying out the important functions that native S16 and RimM have in ribosome biogenesis.     

Functional interactions in vivo between suppressor tRNA and mutationally altered ribosomal protein S4

Summary Ribosomal mutants (rpsD) which are associated with a generally increased translational ambiguity were investigated for their effects in vivo on individual tRNA species using suppressor tRNAs as models. It was found that nonsense suppression is either increased, unaffected or decreased depending on the codon context and the rpsD allele involved as well as the nature of the suppressor tRNA. Missense suppression of AGA and AGG by glyT(SuAGA/G) tRNA as well as UGG by glyT(SuUGG-8) tRNA is unaffected whereas suppression of UGG by glyT(SuUGA/G) or glyV(SuUGA/G) tRNA is decreased in the presence of an rpsD mutation. The effects on suppressor tRNA are thus not correlated with the ribosomal ambiguity (Ram) phenotype of the rpsD mutants used in this study. It is suggested that the mutationally altered ribosomes are changed in functional interactions with the suppressor tRNA itself rather than with the competing translational release factor(s) or cognate aminoacyl tRNA. The structure of suppressor tRNA, particularly the anticodon loop, and the suppressed codon as well as the codon context determine the allele specific functional interactions with these ribosomal mutations.     

Genetic analysis of an alteration of ribosomal protein S20 in revertants of an alanyl-tRNA-synthetase mutant of Escherichia coli

Summary The genetic location has been determined of two mutations which suppress the temperature-sensitive phenotype of an alanyl-tRNA-synthetase mutant of Escherichia coli and which are correlated with alterations of the ribosomal protein S20. Both mutations map at the same chromosomal site; the gene order relative to other markers of the Escherichia coli map is thr-sup-pyrA-araC-leu.Replacement of the suppressor allele by the wild-type allele via P1 transduction results in the appearance of the wild-type S20 protein; concomitantly suppression of temperature-sensitivity is released.Strains of Escherichia coli were contructed which are partially diploid for the region of the chromosome containing the suppressor allele. Investigation of these strains revealed that the wild-type suppressor is dominant as judged by the activity to suppress the alaS mutation since the partial diploids are no longer able to suppress the alaS-3 mutation. Investigation of the ribosomal protein pattern of these partial diploids by means of two-dimensional polyacrylamide gel electrophoresis did not reveal two distinct spots characteristic for the normal and the altered forms of S20; rather, an elongated spot was observed trailing from the wild-type S20 position towards the anode.     

Base 2661 in Escherichia coli 23S rRNA influences the binding of elongation factor Tu during protein synthesis in vivo.

The binding of the EF-Tu.GTP.aminoacyl-tRNA ternary complex (EF, elongation factor) to the ribosome is known to be strengthened by a 2661G-to-C mutation in 23S ribosomal RNA, whereas the binding to normal ribosomes is weakened if the factor is in an appropriate mutant form (Aa). In this report we describe the mutual effects by the 2661C alteration in 23S rRNA and EF-Tu(Aa) on bacterial viability and translation efficiency in strains with normal or mutationally altered ribosomes. The rrnB(2661C) allele on a multicopy plasmid was introduced by transformation into Escherichia coli K-12 strains, harbouring either the wild-type or the mutant gene (tufA) for EF-Tu as well as normal or mutant ribosomal protein S12 (rpsL). Together with wild-type EF-Tu, the 2661C mutant ribosomes decreased the translation elongation rate in a rpsL+ strain or a non-restrictive rpsL224 strain. This reduction was not seen in strains which harbored EF-Tu(Aa) instead of EF-Tu(As) (As, wild-type form). Nonsense codon suppression by tyrT(Su3) suppressor tRNA was reduced by 2661C in a rpsL224 strain in the presence of EF-Tu(As) but not in the presence of EF-Tu(Aa). The lethal effect obtained by the combination of 2661C and a restrictive ribosomal protein S12 mutation (rpsL282) disappeared if EF-Tu(As) was replaced by EF-Tu(Aa) in the strain. In such a viable strain, 2661C had no effect on either the translation elongation rate or nonsense codon suppression. Our data suggest that the G base at position 2661 in 23S rRNA is important for binding of EF-Tu during protein synthesis in vivo. The interaction between this base and EF-Tu is strongly influenced by the structure of ribosomal protein S12.     

Yeast suppressors of UAA and UAG nonsense codons work efficiently in vitro via tRNA

A cell-free protein-synthesizing system, containing an S-100 fraction from yeast, ribosomal subunits from Krebs ascites cells, and ribosome initiation factors from rabbit reticulocytes, translates yeast, adenovirus, and rabbit globin messenger RNAs and the RNA from bacteriophage Qβ. An amber mutation in the Qβ synthetase gene is suppressed in vitro if the S-100 fraction is from yeast strains carrying amber suppressor mutations. Suppressor SUP6-2 gives 16% suppression, and the recessive lethal suppressor RL-1 gives 50% suppression. Extracts from strain FM6, which has the ochre suppressor SUP4-1, give a longer protein product from the normal synthetase gene of Qβ with an efficiency of 63%. This implies that UAA is the terminator for the synthetase gene, and that synthesis of this read through protein can be used as an assay for ochre suppression. Suppression in each of these cases is mediated by tRNA, since purified tRNA is the only fraction from suppressing strains that is required in an otherwise nonsuppressing cell-free system.     

Suppression of a defective alanyl-tRNA synthetase in Escherichia coli: a compensatory mutation to high alanine affinity.

Summary Among temperature resistant revertants of a temperature sensitive E. coli alanyl-tRNA synthetase mutant a strain was found which contains an alanyl-tRNA synthetase with an additional mutation in the structural gene of the enzyme. This mutant enzyme has a 9 or 38 fold decreased K _m value for alanine compared to that of the thermolabile parental enzyme or to wild-type enzyme, respectively. The alaS gene maps just counterclockwise from recA on the E. coli map (94% cotransduction frequency). It appears that the enzyme's increased affinity for alanine is the mechanism of suppressing the temperature sensitive character of the cell. In addition, some coldsensitive temperature resistant revertants were found, where the cold-sensitive character mapped near strA, Presumably they are due to changes in ribosomal proteins as characterized by Ruffler et al. (1974).     

A suppressor of temperature-sensitive rna mutations that affect mRNA metabolism in Saccharomyces cerevisiae.

We have isolated a dominant suppressor of rna mutation (SRN1) that relieves the temperature-sensitive inhibition of mRNA synthesis of ribosomal protein genes in the yeast Saccharomyces cerevisiae. The suppressor was selected for its ability to alleviate simultaneously the temperature-sensitive growth phenotypes of rna2 and rna6. Several independently isolated suppressors appeared to be recessive lethal mutations. One suppressor, SRN1, was recovered as viable in haploid strains. SRN1 can suppress rna2, rna3, rna4, rna5, rna6, and rna8 singly or in pairs, although some combinations of rna mutations are less well suppressed than others. The suppressor allows strains with rna mutations to grow at 34 degrees C but is unable to suppress at 37 degrees C; however, SRN1 does not, by itself, prevent growth at 37 degrees C. In addition, SRN1 suppresses the rna1 mutation which affects general mRNA levels and also leads to the accumulation of precursor tRNA for those tRNAs that have intervening sequences. SRN1 can suppress the rna1 mutation as well as the rna1 rna2 double mutation at 34 degrees C. The suppressor does not affect the temperature-sensitive growth of two unrelated temperature-sensitive mutations, cdc4 and cdc7.     

30S subunit mutations relieving restriction of ribosomal misreading caused by L6 mutations

Summary Mutants were analyzed biochemically and genetically in which restriction of translational misreading by ribosomes containing an altered L6 protein is relieved. Amongst 100 such strains eight possessed an altered S4 and two a mutant S5 protein. The protein-chemical type of L6 mutation seems to influence the kind of S4 mutant form selected. Also, only a few types of S4 ram mutations are obtained and they are different from those usually found amongst suppressors of streptomycin-dependent (Sm^D) strains. The S4 mutations selected are able to reduce the level of streptomycin-resistance of strA1 or strA40 strains and they confer extreme hypersensitivity to aminoglycosides when present alone. On the other hand, S4 mutations from Sm^D suppressor strains only weakly reverse L6 restriction. The results imply that control of translational fidelity is an intersubunit function and that protein L6 (an interface protein) cooperates with 30S proteins by directly or indirectly determining parameters involved in aminoacyl-tRNA recognition.     

Characterization of Mutants of Escherichia coli Temperature-Sensitive for Ribonucleic Acid Regulation: an Unusual Phenotype Associated with a Phenylalanyl Transfer Ribonucleic Acid Synthetase Mutant

A mutant strain AA-522, temperature-sensitive for protein synthesis, was isolated from a stringent strain (CP-78) of Escherichia coli K-12. The mutant strain has a relaxed phenotype at the nonpermissive growth temperature. Protein synthesis stops completely at 42 C, whereas the rate of ribonucleic acid (RNA) synthesis is maintained at 20% of the 30 C rate. Sucrose-gradient centrifugation analysis of RNA-containing particles formed at 42 C indicated the presence of “relaxed particles.” These particles possess 16S and 23S RNA and are precursors to normal 50S and 30S ribosomal subunits. A search for the temperature-sensitive protein responsible for the halt in protein synthesis implicated phenylalanyl transfer RNA (tRNA) synthetase. Essentially no enzyme activity is detected in vitro at 30 or 40 C. Analysis of phenylalanyl tRNA synthetase activity in revertants of strain AA-522 indicated the presence of intragenic suppressor mutations. Revertants of strain AA-522 analyzed for the relaxed response at 42 C were all stringent; strain AA-522 was stringent at 30 C. These data indicate that a single mutation in phenylalanyl tRNA synthetase is responsible for both a block in protein synthesis and the relaxed phenotype at 42 C.     

Antagonistic effects of mutant elongation factor Tu and ribosomal protein S12 on control of translational accuracy, suppression and cellular growth

Kirromycin-resistant mutant forms of elongation factor Tu, which are coded by tufA (Ar) or tufB (Bo) and are associated with an increased rate of translational error formation, have been analysed. In vivo, Ar was found to increase misreading as well as suppression of non-sense codons irrespective of Bo in a strain with wild type ribosomes. It is therefore not necessary to evoke both tufA (Ar) and tufB (Bo) mutations together in order to increase translational error as suggested earlier [1]. When combined with a hyperaccurate ribosomal rpsL (S12) mutation, Ar counteracts the restrictive effects on translational error formation caused by the altered protein S12, thus restoring the levels of missense error in vitro and non-sense error and suppression in vivo to near wild type values. As judged from in vitro experiments this results principally from a lowered selectivity of the Ar ternary complex at the initial discrimination step on the ribosome during translation. In vivo, this compensatory effect on the rpsL mutation on non-sense error formation and suppression is seen irrespective of the nature of tRNA or codon context. Furthermore, the tufA mutation enhances the cellular growth rate of the rpsL mutant, whereas it decreases growth of strains with normal ribosomes. Inactivation of one of the two genes coding for EF-Tu (tufB), while leaving the other gene (tufA) intact, can by itself, increase non-sense error formation and suppression.     

Charcot–Marie–Tooth mutation in glycyl-tRNA synthetase stalls ribosomes in a pre-accommodation state and activates integrated stress response

Toxic gain-of-function mutations in aminoacyl-tRNA synthetases cause a degeneration of peripheral motor and sensory axons, known as Charcot–Marie–Tooth (CMT) disease. While these mutations do not disrupt overall aminoacylation activity, they interfere with translation via an unknown mechanism. Here, we dissect the mechanism of function of CMT mutant glycyl-tRNA synthetase (CMT-GARS), using high-resolution ribosome profiling and reporter assays. We find that CMT-GARS mutants deplete the pool of glycyl-tRNA^Gly available for translation and inhibit the first stage of elongation, the accommodation of glycyl-tRNA into the ribosomal A-site, which causes ribosomes to pause at glycine codons. Moreover, ribosome pausing activates a secondary repression mechanism at the level of translation initiation, by inducing the phosphorylation of the alpha subunit of eIF2 and the integrated stress response. Thus, CMT-GARS mutant triggers translational repression via two interconnected mechanisms, affecting both elongation and initiation of translation.     

Function of the ribosomal E-site: a mutagenesis study

Ribosomes synthesize proteins according to the information encoded in mRNA. During this process, both the incoming amino acid and the nascent peptide are bound to tRNA molecules. Three binding sites for tRNA in the ribosome are known: the A-site for aminoacyl-tRNA, the P-site for peptidyl-tRNA and the E-site for the deacylated tRNA leaving the ribosome. Here, we present a study of Escherichia coli ribosomes with the E-site binding destabilized by mutation C2394G of the 23S rRNA. Expression of the mutant 23S rRNA in vivo caused increased frameshifting and stop codon readthrough. The progression of these ribosomes through the ribosomal elongation cycle in vitro reveals ejection of deacylated tRNA during the translocation step or shortly after. E-site compromised ribosomes can undergo translocation, although in some cases it is less efficient and results in a frameshift. The mutation affects formation of the P/E hybrid site and leads to a loss of stimulation of the multiple turnover GTPase activity of EF-G by deacylated tRNA bound to the ribosome.     

Mutation affecting the charging reaction of alanyl-tRNA synthetase from Escherichia coli K 10

Summary A temperature-sensitive mutant of Escherichia coli was identified as having an altered alanyl-tRNA synthetase. Specific activity of wild type and mutant cell-free extracts showed no difference in the hydroxamate assay; the charging activity, however, was more than 10 fold lower for mutant extract protein. Wild type alanyl-tRNA synthetase has been purified 344 fold, the mutant enzyme was enriched 45 fold. With these preparations the following results were obtained:Sedimentation analysis in sucrose gradients indicates a molecular weight of the mutant enzyme of half the size of the wild type enzyme. Analytical gel filtration yields an approximate size for the native enzyme of 165000 and for the mutant enzyme material of 95,000. The mutant alanyl-tRNA synthetase differs from the wild type enzyme by a 10 fold increase in the k _mfor tRNA; no true difference in the k _m-values for the other substrates was detected. Temperature studies indicate an unusual low temperature-optimum for the charging reaction of both enzymes, whereas hydroxamate fromation capacity increases linearly up to almost 50°C. High temperature treatment of the native enzyme selectively affects the aminoacylation reaction but not the activation step; no effect of such treatment of the mutant enzyme was detected. It is proposed that the mutation causes the enzyme to dissociate and that the resulting subunits possess and altered tRNA binding site.     

RimM and RbfA Are Essential for Efficient Processing of 16S rRNA in Escherichia coli

The trmD operon is located at 56.7 min on the genetic map of the Escherichia coli chromosome and contains the genes for ribosomal protein (r-protein) S16, a 21-kDa protein (RimM, formerly called 21K), the tRNA (m¹G37)methyltransferase (TrmD), and r-protein L19, in that order. Previously, we have shown that strains from which the rimM gene has been deleted have a sevenfold-reduced growth rate and a reduced translational efficiency. The slow growth and translational deficiency were found to be partly suppressed by mutations in rpsM, which encodes r-protein S13. Further, the RimM protein was shown to have affinity for free ribosomal 30S subunits but not for 30S subunits in the 70S ribosomes. Here we have isolated several new suppressor mutations, most of which seem to be located close to or within the nusA operon at 68.9 min on the chromosome. For at least one of these mutations, increased expression of the ribosome binding factor RbfA is responsible for the suppression of the slow growth and translational deficiency of a ΔrimM mutant. Further, the RimM and RbfA proteins were found to be essential for efficient processing of 16S rRNA.     

Localization of the structural gene for ribosomal protein L19 (rplS) in Escherichia coli

Summary A temperature-sensitive mutant derived from an E. coli K12 strain, PA3092, was found to have an alteration in the ribosomal protein L19 (Isono et al., 1977). This mutant is a double mutant with a temperature-sensitivity mutation and a mutation leading to the structural alteration of L19 protein. Crosses with various Hfr strains and transductions with P1kc have revealed that the latter mutation maps at 56.4 min, between pheA and alaS. From the fact that two other mutations causing different types of alterations in L19 protein also map at this locus, the gene affected by these mutations was concluded to be the structural gene for the ribosomal protein L19 (rplS).     

Role of Isoleucyl-Transfer Ribonucleic Acid Synthetase in Ribonucleic Acid Synthesis and Enzyme Repression in Yeast

Temperature-sensitive mutations in the isoleucyl-transfer ribonucleic acid (tRNA) synthetase of yeast, ilS(-)1-1 and ilS(-)1-2, were used to examine the role of aminoacyl-tRNA synthetase enzymes in the regulation of ribonucleic acid (RNA) synthesis and enzyme synthesis in a eucaryotic organism. At the permissive temperature, 70 to 100% of the intracellular isoleucyl-tRNA was charged in mutants carrying these mutations; at growth-limiting temperatures, less than 10% was charged with isoleucine. Other aminoacyl-tRNA molecules remained essentially fully charged under both conditions. Net protein and RNA syntheses were rapidly inhibited when the mutant was shifted from the permissive to the restrictive temperature. Most of the ribosomes remained in polyribosome structures at the restrictive temperature even though protein synthesis was strongly inhibited. Two of the enzymes of isoleucine biosynthesis, threonine deaminase and acetohydroxyacid synthetase, were derepressed about twofold during slow growth of the mutants at a growth-limiting temperature. This is about the same degree of derepression that is achieved by growth of an auxotroph on limiting isoleucine. We conclude that charged aminoacyl-tRNA is essential for RNA synthesis and for the multivalent repression of the isoleucine biosynthetic enzymes. Aminoacyl tRNA synthetase enzymes appear to play important regulatory roles in the cell physiology of eucaryotic organisms.     

Dissociation of peptidyl-tRNA from ribosomes is perturbed by streptomycin and by strA mutations

Summary Peptidyl-tRNA may dissociate preferentially from ribosomes during protein synthesis when it is inappropriate to, does not correctly complement, the messenger RNA. To test this idea, growing cultures of Escherichia coli were treated with streptomycin to increase the frequency of errors during protein synthesis. Since the treated cells had a temperature-sensitive peptidyl-tRNA hydrolase and could not destroy dissociated peptidyl-tRNA, it was possible to measure the rate of its accumulation after raising the temperature to non-permissive conditions. Both low and high doses of streptomycin enhanced the rate of dissociation and accumulation of peptidyl-tRNA. The rank order of rates of dissociation/accumulation of various isoaccepting tRNA families was not significantly altered by the drug treatment. We concluded that streptomycin stimulated a normal pathway for dissociation of peptidyl-tRNA. Two streptomycin-resistent strains of E. coli had higher rates of dissociation of peptidyl-tRNA than did their sensitive parent strain. When treated with high doses of the drug, the resistant strains showed slightly reduced rates of dissociation of peptidyl-tRNA. These results were interpreted in terms of a two state, two site model for protein synthesis: streptomycin enhances the binding of aminoacyl-tRNA to a tight state of the ribosome A site; the strA mutation enhances translocation to a loose state of the ribosome P site.     

Anticodon loop mutations perturb reading frame maintenance by the E site tRNA

The ribosomal E site helps hold the reading frame. Certain tRNA mutations affect translation, and anticodon loop mutations can be especially detrimental. We studied the effects of mutations saturating the anticodon loop of the amber suppressor tRNA, Su7, on the ability to help hold the reading frame when in the E site. We also tested three mutations in the anticodon stem, as well as a mutation in the D stem (the “Hirsh” mutation). We used the Escherichia coli RF2 programmed frameshift site to monitor frame maintenance. Most anticodon loop mutations increase frameshifting, possibly by decreasing codon:anticodon stability. However, it is likely that the A site is more sensitive to anticodon loop structure than is the E site. Unexpectedly, the Hirsh mutation also increases frameshifting from the E site. Other work shows that mutation may increase the ability of tRNA to react in the A site, possibly by facilitating conformational changes required for aminoacyl-tRNA selection. We suggest that this property may decrease its ability to bind to the E site. Finally, the absence of the ms²io⁶A nucleoside modifications at A37 does not decrease the ability of tRNA to help hold the reading frame from the E site. This was also unexpected because the absence of these modifications affects translational properties of tRNA in A and P sites. The absence of a negative effect in the E site further highlights the differences among the substrate requirements of the ribosomal coding sites.     

A hamster temperature-sensitive alanyl-tRNA synthetase mutant causes degradation of cell-cycle related proteins and apoptosis

We have isolated a temperature-sensitive alanyl-tRNA synthetase mutant from hamster BHK21 cells, designated as ts ET12. It has a single nucleotide mutation, converting the 321st amino acid residue, 321Gly, to Arg. The mutation was localized between two RNA-binding domains of alanyl-tRNA synthetase. Thus far, we have isolated two temperature-sensitive aminoacyl-tRNA synthetase mutants from the BHK21 cell line: ts BN250 and ts BN269. They are defective in histidyl- and lysyl-tRNA synthetase respectively. Both mutants rapidly undergo apoptosis at the nonpermissive temperature, 39.5 degrees C. ts ET12 cells, however, did not undergo apoptosis until 48 h after a temperature-shift to 39.5 degrees C, while mutated alanyl-tRNA synthetase of ts ET12 cells was lost within 4 h. Loss of the mutated alanyl-tRNA synthetase was inhibited by a ubiquitin-dependent proteasome inhibitor, MG132, and by a protein-synthesis inhibitor, cycloheximide. Cell-cycle related proteins were also lost in ts ET12 cells at 39.5 degrees C, as shown in ts BN250. In contrast, the mutated aminoacyl-tRNA synthetases of ts BN250 and ts BN269 were stable at 39.5 degrees C. However, the defects of these mutants released EMAPII, an inducer of apoptosis at 39.5 degrees C. No release of EMAPII occurred in ts ET12 cells at 39.5 degrees C, consistent with the delay of apoptosis in these cells.