Improvement of α-Amylase Production by Modulation of Ribosomal Component Protein S12 in Bacillus subtilis 168

The capacity of ribosomal modification to improve antibiotic production by Streptomyces spp. has already been demonstrated. Here we show that introduction of mutations that produce streptomycin resistance (str) also enhances α-amylase (and protease) production by a strain of Bacillus subtilis as estimated by measuring the enzyme activity. The str mutations are point mutations within rpsL, the gene encoding the ribosomal protein S12. In vivo as well as in vitro poly(U)-directed cell-free translation systems showed that among the various rpsL mutations K56R (which corresponds to position 42 in E. coli) was particularly effective at enhancing α-amylase production. Cells harboring the K56R mutant ribosome exhibited enhanced translational activity during the stationary phase of cell growth. In addition, the K56R mutant ribosome exhibited increased 70S complex stability in the presence of low Mg²⁺ concentrations. We therefore conclude that the observed increase in protein synthesis activity by the K56R mutant ribosome reflects increased stability of the 70S complex and is responsible for the increase in α-amylase production seen in the affected strain.     

Mutations in rsmG, encoding a 16S rRNA methyltransferase, result in low-level streptomycin resistance and antibiotic overproduction in Streptomyces coelicolor A3(2)

Certain str mutations that confer high- or low-level streptomycin resistance result in the overproduction of antibiotics by Streptomyces spp. The str mutations that confer the high-level resistance occur within rpsL, which encodes the ribosomal protein S12, while those that cause low-level resistance are not as well known. We have used comparative genome sequencing to determine that low-level resistance is caused by mutations of rsmG, which encodes an S-adenosylmethionine (SAM)-dependent 16S rRNA methyltransferase containing a SAM binding motif. Deletion of rsmG from wild-type Streptomyces coelicolor resulted in the acquisition of streptomycin resistance and the overproduction of the antibiotic actinorhodin. Introduction of wild-type rsmG into the deletion mutant completely abrogated the effects of the rsmG deletion, confirming that rsmG mutation underlies the observed phenotype. Consistent with earlier work using a spontaneous rsmG mutant, the strain carrying DeltarsmG exhibited increased SAM synthetase activity, which mediated the overproduction of antibiotic. Moreover, high-performance liquid chromatography analysis showed that the DeltarsmG mutant lacked a 7-methylguanosine modification in the 16S rRNA (possibly at position G518, which corresponds to G527 of Escherichia coli). Like certain rpsL mutants, the DeltarsmG mutant exhibited enhanced protein synthetic activity during the late growth phase. Unlike rpsL mutants, however, the DeltarsmG mutant showed neither greater stability of the 70S ribosomal complex nor increased expression of ribosome recycling factor, suggesting that the mechanism underlying increased protein synthesis differs in the rsmG and the rpsL mutants. Finally, spontaneous rsmG mutations arose at a 1,000-fold-higher frequency than rpsL mutations. These findings provide new insight into the role of rRNA modification in activating secondary metabolism in Streptomyces.     

Innovative approach for improvement of an antibiotic-overproducing industrial strain of Streptomyces albus

Working with a Streptomyces albus strain that had previously been bred to produce industrial amounts (10 mg/ml) of salinomycin, we demonstrated the efficacy of introducing drug resistance-producing mutations for further strain improvement. Mutants with enhanced salinomycin production were detected at a high incidence (7 to 12%) among spontaneous isolates resistant to streptomycin (Str(r)), gentamicin, or rifampin (Rif(r)). Finally, we successfully demonstrated improvement of the salinomycin productivity of the industrial strain by 2.3-fold by introducing a triple mutation. The Str(r) mutant was shown to have a point mutation within the rpsL gene (encoding ribosomal protein S12). Likewise, the Rif(r) mutant possessed a mutation in the rpoB gene (encoding the RNA polymerase beta subunit). Increased productivity of salinomycin in the Str(r) mutant (containing the K88R mutation in the S12 protein) may be a result of an aberrant protein synthesis mechanism. This aberration may manifest itself as enhanced translation activity in stationary-phase cells, as we have observed with the poly(U)-directed cell-free translation system. The K88R mutant ribosome was characterized by increased 70S complex stability in low Mg(2+) concentrations. We conclude that this aberrant protein synthesis ability in the Str(r) mutant, which is a result of increased stability of the 70S complex, is responsible for the remarkable salinomycin production enhancement obtained.     

Development of antibiotic-overproducing strains by site-directed mutagenesis of the rpsL gene in Streptomyces lividans

Certain rpsL (which encodes the ribosomal protein S12) mutations that confer resistance to streptomycin markedly activate the production of antibiotics in Streptomyces spp. These rpsL mutations are known to be located in the two conserved regions within the S12 protein. To understand the roles of these two regions in the activation of silent genes, we used site-directed mutagenesis to generate eight novel mutations in addition to an already known (K88E) mutation that is capable of activating antibiotic production in Streptomyces lividans. Of these mutants, two (L90K and R94G) activated antibiotic production much more than the K88E mutant. Neither the L90K nor the R94G mutation conferred an increase in the level of resistance to streptomycin and paromomycin. Our results demonstrate the efficacy of the site-directed mutagenesis technique for strain improvement.     

Use of a dominant rpsL allele conferring streptomycin dependence for positive and negative selection in Thermus thermophilus

A spontaneous rpsL mutant of Thermus thermophilus was isolated in a search for new selection markers for this organism. This new allele, named rpsL1, encodes a K47R/K57E double mutant S12 ribosomal protein that confers a streptomycin-dependent (SD) phenotype to T. thermophilus. Models built on the available three-dimensional structures of the 30S ribosomal subunit revealed that the K47R mutation directly affects the streptomycin binding site on S12, whereas the K57E does not apparently affect this binding site. Either of the two mutations conferred the SD phenotype individually. The presence of the rpsL1 allele, either as a single copy inserted into the chromosome as part of suicide plasmids or in multicopy as replicative plasmids, produced a dominant SD phenotype despite the presence of a wild-type rpsL gene in a host strain. This dominant character allowed us to use the rpsL1 allele not only for positive selection of plasmids to complement a kanamycin-resistant mutant strain, but also more specifically for the isolation of deletion mutants through a single step of negative selection on streptomycin-free growth medium.     

Innovative Approach for Improvement of an Antibiotic-Overproducing Industrial Strain of Streptomyces albus

Working with a Streptomyces albus strain that had previously been bred to produce industrial amounts (10 mg/ml) of salinomycin, we demonstrated the efficacy of introducing drug resistance-producing mutations for further strain improvement. Mutants with enhanced salinomycin production were detected at a high incidence (7 to 12%) among spontaneous isolates resistant to streptomycin (Str^r), gentamicin, or rifampin (Rif^r). Finally, we successfully demonstrated improvement of the salinomycin productivity of the industrial strain by 2.3-fold by introducing a triple mutation. The Str^r mutant was shown to have a point mutation within the rpsL gene (encoding ribosomal protein S12). Likewise, the Rif^r mutant possessed a mutation in the rpoB gene (encoding the RNA polymerase β subunit). Increased productivity of salinomycin in the Str^r mutant (containing the K88R mutation in the S12 protein) may be a result of an aberrant protein synthesis mechanism. This aberration may manifest itself as enhanced translation activity in stationary-phase cells, as we have observed with the poly(U)-directed cell-free translation system. The K88R mutant ribosome was characterized by increased 70S complex stability in low Mg²⁺ concentrations. We conclude that this aberrant protein synthesis ability in the Str^r mutant, which is a result of increased stability of the 70S complex, is responsible for the remarkable salinomycin production enhancement obtained.     

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.     

The novel mutation K87E in ribosomal protein S12 enhances protein synthesis activity during the late growth phase in<Emphasis Type="Italic"> Escherichia coli</Emphasis>

Resistance to streptomycin in bacterial cells often results from a mutation in the rpsL gene that encodes the ribosomal protein S12. We found that a particular rpsL mutation (K87E), newly identified in Escherichia coli, causes aberrant protein synthesis activity late in the growth phase. While protein synthesis decreased with age in cells in the wild-type strain, it was sustained at a high level in the mutant, as determined using living cells. This was confirmed using an in vitro protein synthesis system with poly(U) and natural mRNAs (GFP mRNA and CAT mRNA). Other classical rpsL mutations (K42N and K42T) tested did not show such an effect, indicating that this novel characteristic is typical of ribosomes bearing the K87E mutant form of S12, although the K87E mutation conferred the streptomycin resistance and error-restrictive phenotypes also seen with the K42N and K42T mutations. The K87E (but not K42N or K42T) mutant ribosomes exhibited increased stability of the 70S complex in the presence of low concentrations of magnesium. We propose that the aberrant activation of protein synthesis at the late growth phase is caused by the increased stability of the ribosome.Communicated by W. Goebel     

Use of a Dominant rpsL Allele Conferring Streptomycin Dependence for Positive and Negative Selection in Thermus thermophilus

A spontaneous rpsL mutant of Thermus thermophilus was isolated in a search for new selection markers for this organism. This new allele, named rpsL1, encodes a K47R/K57E double mutant S12 ribosomal protein that confers a streptomycin-dependent (SD) phenotype to T. thermophilus. Models built on the available three-dimensional structures of the 30S ribosomal subunit revealed that the K47R mutation directly affects the streptomycin binding site on S12, whereas the K57E does not apparently affect this binding site. Either of the two mutations conferred the SD phenotype individually. The presence of the rpsL1 allele, either as a single copy inserted into the chromosome as part of suicide plasmids or in multicopy as replicative plasmids, produced a dominant SD phenotype despite the presence of a wild-type rpsL gene in a host strain. This dominant character allowed us to use the rpsL1 allele not only for positive selection of plasmids to complement a kanamycin-resistant mutant strain, but also more specifically for the isolation of deletion mutants through a single step of negative selection on streptomycin-free growth medium.     

Era and RbfA have overlapping function in ribosome biogenesis in Escherichia coli

A cold-shock protein, RbfA (ribosome-binding factor A), is essential for cell growth at low temperature. In an rbfA-deletion strain, 30S and 50S ribosomal subunits increase relative to 70S monosomes with concomitant accumulation of a precursor 16S rRNA (17S rRNA). Recently, we have reported that overexpression of Era, an essential GTP-binding protein, suppresses not only the cold-sensitive cell growth but also defective ribosome biogenesis in the rbfA-deletion strain. Here, in order to elucidate how RbfA and Era functionally overlap, we characterized a cold-sensitive Era mutant (a point mutation at the Glu-200 to Lys; E200K) which shows a similar phenotype as the rbfA-deletion strain; accumulation of free ribosome subunits and 17S rRNA. To examine the effect of E200K in the rbfA-deletion strain, we constructed an E200K-inducible expression system. Interestingly, unlike wild-type Era, overexpression of Era(E200K) protein in the rbfA-deletion strain severely inhibited cell growth even at permissive temperature with further concomitant reduction of 16S rRNA. Purified Era(E200K) protein binds to 30S ribosomal subunits in a nucleotide-dependent manner like wild-type Era and retains both GTPase and autophosphorylation activities. Furthermore, we isolated spontaneous revertants of the E200K mutant. These revertants partially suppressed the accumulation of 17S rRNA. All the spontaneous mutations were found to result in higher Era(E200K) expression. These results suggest that the Era(E200K) protein has an impaired function in ribosome biogenesis without losing its ribosome binding activity. The severe growth defect caused by E200K in the rbfA-deletion strain may be due to competition between intrinsic wild-type Era and overexpressed Era(E200K) for binding to 30S ribosomal subunits. We propose that Era and RbfA have an overlapping function that is essential for ribosome biogenesis, and that RbfA becomes dispensable only at high temperatures because Era can complement its function only at higher temperatures.     

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

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

Induction of actinorhodin production by rpsL (encoding ribosomal protein S12) mutations that confer streptomycin resistance in Streptomyces lividans and Streptomyces coelicolor A3(2).

A strain of Streptomyces lividans, TK24, was found to produce a pigmented antibiotic, actinorhodin, although S. lividans normally does not produce this antibiotic. Genetic analyses revealed that a streptomycin-resistant mutation str-6 in strain TK24 is responsible for induction of antibiotic synthesis. DNA sequencing showed that str-6 is a point mutation in the rpsL gene encoding ribosomal protein S12, changing Lys-88 to Glu. Gene replacement experiments with the Lys88-->Glu str allele demonstrated unambiguously that the str mutation is alone responsible for the activation of actinorhodin production observed. In contrast, the strA1 mutation, a genetic marker frequently used for crosses, did not restore actinorhodin production and was found to result in an amino acid alteration of Lys-43 to Asn. Induction of actinorhodin production was also detected in strain TK21, which does not harbor the str-6 mutation, when cells were incubated with sufficient streptomycin or tetracycline to reduce the cell's growth rate, and 40 and 3% of streptomycin- or tetracycline-resistant mutants, respectively, derived from strain TK21 produced actinorhodin. Streptomycin-resistant mutations also blocked the inhibitory effects of relA and brgA mutations on antibiotic production, aerial mycelium formation or both. These str mutations changed Lys-88 to Glu or Arg and Arg-86 to His in ribosomal protein S12. The decrease in streptomycin production in relC mutants in Streptomyces griseus could also be abolished completely by introducing streptomycin-resistant mutations, although the impairment in antibiotic production due to bldA (in Streptomyces coelicolor) or afs mutations (in S. griseus) was not eliminated. These results indicate that the onset and extent of secondary metabolism in Streptomyces spp. is significantly controlled by the translational machinery.     

Novel approach for improving the productivity of antibiotic-producing strains by inducing combined resistant mutations

We developed a novel approach for improving the production of antibiotic from Streptomyces coelicolor A3(2) by inducing combined drug-resistant mutations. Mutants with enhanced (1.6- to 3-fold-higher) actinorhodin production were detected at a high frequency (5 to 10%) among isolates resistant to streptomycin (Str(r)), gentamicin (Gen(r)), or rifampin (Rif(r)), which developed spontaneously on agar plates which contained one of the three drugs. Construction of double mutants (str gen and str rif) by introducing gentamicin or rifampin resistance into an str mutant resulted in further increased (1.7- to 2.5-fold-higher) actinorhodin productivity. Likewise, triple mutants (str gen rif) thus constructed were found to have an even greater ability for producing the antibiotic, eventually generating a mutant able to produce 48 times more actinorhodin than the wild-type strain. Analysis of str mutants revealed that a point mutation occurred within the rpsL gene, which encodes the ribosomal protein S12. rif mutants were found to have a point mutation in the rpoB gene, which encodes the beta-subunit of RNA polymerase. Mutation points in gen mutants still remain unknown. These single, double, and triple mutants displayed in hierarchical order a remarkable increase in the production of ActII-ORF4, a pathway-specific regulatory protein, as determined by Western blotting analysis. This reflects the same hierarchical order observed for the increase in actinorhodin production. The superior ability of the triple mutants was demonstrated by physiological analyses under various cultural conditions. We conclude that by inducing combined drug-resistant mutations we can continuously increase the production of antibiotic in a stepwise manner. This new breeding approach could be especially effective for initially improving the production of antibiotics from wild-type strains.     

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.     

Construction of an in vivo nonsense readthrough assay system and functional analysis of ribosomal proteins S12, S4, and S5 in Bacillus subtilis

To investigate the function of ribosomal proteins and translational factors in Bacillus subtilis, we developed an in vivo assay system to measure the level of nonsense readthrough by utilizing the LacZ-LacI system. Using the in vivo nonsense readthrough assay system which we developed, together with an in vitro poly(U)-directed cell-free translation assay system, we compared the processibility and translational accuracy of mutant ribosomes with those of the wild-type ribosome. Like Escherichia coli mutants, most S12 mutants exhibited lower frequencies of both UGA readthrough and missense error; the only exception was a mutant (in which Lys-56 was changed to Arg) which exhibited a threefold-higher frequency of readthrough than the wild-type strain. We also isolated several ribosomal ambiguity (ram) mutants from an S12 mutant. These ram mutants and the S12 mutant mentioned above (in which Lys-56 was changed to Arg) exhibited higher UGA readthrough levels. Thus, the mutation which altered Lys-56 to Arg resulted in a ram phenotype in B. subtilis. The efficacy of our in vivo nonsense readthrough assay system was demonstrated in our investigation of the function of ribosomal proteins and translational factors.     

Conditional lethal mutants of bacteriophage T4 unable to grow on a streptomycin resistant mutant of Escherichia coli.

Sixteen conditional lethal mutants of bacteriophage T4D have been isolated which grow on Escherichia coli CR63 (a su+ streptomycin-sensitive K12 strain) but are restricted by CR/s (a streptomycin-resistant derivative of CR63). These mutants have been given the prefix str. Four of these mutants are amber and 12 appear to be missense. Eleven of the 12 missense mutants appear to be "pseudo-amber" (i.e. they are restricted by a su- E. coli B strain but not by a su- K12 strain); the other missense mutant was not restricted by either B or K12. The str mutations mapped in 12 different genes. Most were clustered in a region of early genes (gene 56 to gene 47). Fifty-eight amber and 10 "pseudo-amber" mutants isolated previously for their inability to grow on E. coli B were tested for restriction by CR/s. All the amber mutants grew normally on CR/s, whereas all 10 "pseudo-amber" mutants were restricted by CR/s. This implies that the phenotype of the "pseudo-amber" mutants is the result of a ribosomal difference between the permissive host CR63 and the restrictive hosts B and CR/s. These str mutants should prove to be useful alternatives to amber mutants for genetic and biochemical studies of bacteriophage T4 and for studies of the E. coli ribosome. It should be possible ot isolate similar mutants in other bacteriophages provided that streptomycin resistant hosts are available.     

Peptidyltransferase activity of ribosomes and a ribosome precursor from a mutant of Escherichia coli.

Escherichia coli strain 15-28 is a mutant with a defect in ribosome synthesis that caused the accumulation of ribonucleoprotein ('47S') particles during exponential growth. These particles are precursors to 50S ribosomes that lack three ribosomal proteins. Peptidyltransferase activity and binding at the peptidyl site of the peptidyltransferase centre are greatly decreased in 47S particles. Both these activities are lower in the 50S and 70S ribosomes of strain 15-28 than in its parent. Unusual assembly of the larger ribosomal subunit in strain 15-28 may produce completed ribosomes with diminished biological activity.     

Streptomycin-resistant and streptomycin-dependent mutants of the extreme thermophile Thermus thermophilus

We have isolated spontaneous streptomycin-resistant, streptomycin-dependent and streptomycin-pseudo-dependent mutants of the thermophilic bacterium Thermus thermophilus IB-21. All mutant phenotypes were found to result from single amino acid substitutions located in the rpsL gene encoding ribosomal protein S12. Spontaneous suppressors of streptomycin dependence were also readily isolated. Thermus rpsL mutations were found to be very similar to rpsL mutations identified in mesophilic organisms. This similarity affords greater confidence in the utility of the crystal structures of Thermus ribosomes to interpret biochemical and genetic data obtained with Escherichia coli ribosomes. In the X-ray crystal structure of the T. thermophilus HB8 30 S subunit, the mutated residues are located in close proximity to one another and to helices 18, 27 and 44 of 16 S rRNA. X-ray crystallographic analysis of ribosomes from streptomycin-resistant, streptomycin-pseudo-dependent and streptomycin-dependent mutants described here is expected to reveal fundamental insights into the mechanism of tRNA selection, translocation, and conformational dynamics of the ribosome.     

A novel single amino acid change in small subunit ribosomal protein S5 has profound effects on translational fidelity

S5 is a small subunit ribosomal protein (r-protein) linked to the functional center of the 30S ribosomal subunit. In this study we have identified a unique amino acid mutation in Escherichia coli S5 that produces spectinomycin-resistance and cold sensitivity. This mutation significantly alters cell growth, folding of 16S ribosomal RNA, and translational fidelity. While translation initiation is not affected, both +1 and -1 frameshifting and nonsense suppression are greatly enhanced in the mutant strain. Interestingly, this S5 ribosome ambiguity-like mutation is spatially remote from previously identified S5 ribosome ambiguity (ram) mutations. This suggests that the mechanism responsible for ram phenotypes in the novel mutant strain is possibly distinct from those proposed for other known S5 (and S4) ram mutants. This study highlights the importance of S5 in ribosome function and cell physiology, and suggests that translational fidelity can be regulated in multiple ways.     

UGA suppressor that maps within a cluster of ribosomal protein genes.

A suppressor of UGA mutations (supU) maps near or within a cluster of ribosomal protein genes at 72 min on the Salmonella typhimurium genetic map. The suppressor is relatively inefficient, and its activity is abolished by rpsL (formerly strA) mutations. The suppressor is dominant to a wild-type supU allele. The map position of this suppressor suggests that it may owe its activity to an alteration of ribosome structure.