Alteration of ribosomal protein S17 by mutation linked to neamine resistance in Escherichia coli. I. General properties of neaA mutants

Correcting direct effects of ethanol on translation and transcription machinery confers ethanol tolerance in bacteria

The molecular mechanisms of ethanol toxicity and tolerance in bacteria, although important for biotechnology and bioenergy applications, remain incompletely understood. Genetic studies have identified potential cellular targets for ethanol and have revealed multiple mechanisms of tolerance, but it remains difficult to separate the direct and indirect effects of ethanol. We used adaptive evolution to generate spontaneous ethanol-tolerant strains of Escherichia coli, and then characterized mechanisms of toxicity and resistance using genome-scale DNAseq, RNAseq, and ribosome profiling coupled with specific assays of ribosome and RNA polymerase function. Evolved alleles of metJ, rho, and rpsQ recapitulated most of the observed ethanol tolerance, implicating translation and transcription as key processes affected by ethanol. Ethanol induced miscoding errors during protein synthesis, from which the evolved rpsQ allele protected cells by increasing ribosome accuracy. Ribosome profiling and RNAseq analyses established that ethanol negatively affects transcriptional and translational processivity. Ethanol-stressed cells exhibited ribosomal stalling at internal AUG codons, which may be ameliorated by the adaptive inactivation of the MetJ repressor of methionine biosynthesis genes. Ethanol also caused aberrant intragenic transcription termination for mRNAs with low ribosome density, which was reduced in a strain with the adaptive rho mutation. Furthermore, ethanol inhibited transcript elongation by RNA polymerase in vitro. We propose that ethanol-induced inhibition and uncoupling of mRNA and protein synthesis through direct effects on ribosomes and RNA polymerase conformations are major contributors to ethanol toxicity in E. coli, and that adaptive mutations in metJ, rho, and rpsQ help protect these central dogma processes in the presence of ethanol.

Bactobolin resistance is conferred by mutations in the L2 ribosomal protein

Burkholderia thailandensis produces a family of polyketide-peptide molecules called bactobolins, some of which are potent antibiotics. We found that growth of B. thailandensis at 30°C versus that at 37°C resulted in increased production of bactobolins. We purified the three most abundant bactobolins and determined their activities against a battery of bacteria and mouse fibroblasts. Two of the three compounds showed strong activities against both bacteria and fibroblasts. The third analog was much less potent in both assays. These results suggested that the target of bactobolins might be conserved across bacteria and mammalian cells. To learn about the mechanism of bactobolin activity, we isolated four spontaneous bactobolin-resistant Bacillus subtilis mutants. We used genomic sequencing technology to show that each of the four resistant variants had mutations in rplB, which codes for the 50S ribosome-associated L2 protein. Ectopic expression of a mutant rplB gene in wild-type B. subtilis conferred bactobolin resistance. Finally, the L2 mutations did not confer resistance to other antibiotics known to interfere with ribosome function. Our data indicate that bactobolins target the L2 protein or a nearby site and that this is not the target of other antibiotics. We presume that the mammalian target of bactobolins involves the eukaryotic homolog of L2 (L8e).

Currently available antibiotics target surprisingly few cellular functions, and there is a need to identify novel antibiotic targets. We have been interested in the Burkholderia thailandensis bactobolins, and we sought to learn about the target of bactobolin activity by mapping spontaneous resistance mutations in the bactobolin-sensitive Bacillus subtilis. Our results indicate that the bactobolin target is the 50S ribosome-associated L2 protein or a region of the ribosome affected by L2. Bactobolin-resistant mutants are not resistant to other known ribosome inhibitors. Our evidence indicates that bactobolins interact with a novel antibiotic target.

Missense suppressor mutations in 16S rRNA reveal the importance of helices h8 and h14 in aminoacyl-tRNA selection

The molecular basis of the induced-fit mechanism that determines the fidelity of protein synthesis remains unclear. Here, we isolated mutations in 16S rRNA that increase the rate of miscoding and stop codon read-through. Many of the mutations clustered along interfaces between the 30S shoulder domain and other parts of the ribosome, strongly implicating shoulder movement in the induced-fit mechanism of decoding. The largest subset of mutations mapped to helices h8 and h14. These helices interact with each other and with the 50S subunit to form bridge B8. Previous cryo-EM studies revealed a contact between h14 and the switch 1 motif of EF-Tu, raising the possibility that h14 plays a direct role in GTPase activation. To investigate this possibility, we constructed both deletions and insertions in h14. While ribosomes harboring a 2-base-pair (bp) insertion in h14 were completely inactive in vivo, those containing a 2-bp deletion retained activity but were error prone. In vitro, the truncation of h14 accelerated GTP hydrolysis for EF-Tu bearing near-cognate aminoacyl-tRNA, an effect that can largely account for the observed miscoding in vivo. These data show that h14 does not help activate EF-Tu but instead negatively controls GTP hydrolysis by the factor. We propose that bridge B8 normally acts to counter inward rotation of the shoulder domain; hence, mutations in h8 and h14 that compromise this bridge decrease the stringency of aminoacyl-tRNA selection.

Mutations in the nucleolar proteins Tma23 and Nop6 suppress the malfunction of the Nep1 protein

The nucleolar Saccharomyces cerevisiae protein Nep1 was previously shown to bind to a specific site of the 18S rRNA and to be involved in assembly of Rps19p into pre-40S ribosome subunits. Here we report on the identification of tma23 and nop6 mutations as recessive suppressors of a nep1(ts) mutant allele and the nep1 deletion as well. Green fluorescent protein fusions localized Tma23p and Nop6p within the nucleolus, indicating their function in ribosome biogenesis. The high lysine content of both proteins and an RNA binding motif in the Nop6p amino acid sequence suggest RNA-binding functions for both factors. Surprisingly, in contrast to Nep1p, Tma23p and Nop6p seem to be specific for fungi as no homologues could be found in higher eukaryotes. In contrast to most other ribosome biogenesis factors, Tma23p and Nop6p are nonessential in S. cerevisiae. Interestingly, the tma23 mutants showed a considerably increased resistance against the aminoglycoside G418, probably due to a structural change in the 40S ribosomal subunit, which could be the result of incorrectly folded 18S rRNA gene, missing rRNA modifications or the lack of a ribosomal protein.

Compensatory evolution reveals functional interactions between ribosomal proteins S12, L14 and L19

Certain mutations in S12, a ribosomal protein involved in translation elongation rate and translation accuracy, confer resistance to the aminoglycoside streptomycin. Previously we showed in Salmonella typhimurium that the fitness cost, i.e. reduced growth rate, due to the amino acid substitution K42N in S12 could be compensated by at least 35 different mutations located in the ribosomal proteins S4, S5 and L19. Here, we have characterized in vivo the fitness, translation speed and translation accuracy of four different L19 mutants. When separated from the resistance mutation located in S12, the three different compensatory amino acid substitutions in L19 at position 40 (Q40H, Q40L and Q40R) caused a decrease in fitness while the G104A change had no effect on bacterial growth. The rate of protein synthesis was unaffected or increased by the mutations at position 40 and the level of read-through of a UGA nonsense codon was increased in vivo, indicating a loss of translational accuracy. The mutations in L19 increased sensitivity to aminoglycosides active at the A-site, further indicating a perturbation of the decoding step. These phenotypes are similar to those of the classical S4 and S5 ram (ribosomal ambiguity) mutants. By evolving low-fitness L19 mutants by serial passage, we showed that the fitness cost conferred by the L19 mutations could be compensated by additional mutations in the ribosomal protein L19 itself, in S12 and in L14, a protein located close to L19. Our results reveal a novel functional role for the 50 S ribosomal protein L19 during protein synthesis, supporting published structural data suggesting that the interaction of L14 and L19 with 16 S rRNA could influence function of the 30 S subunit. Moreover, our study demonstrates how compensatory fitness-evolution can be used to discover new molecular functions of ribosomal proteins.

Determination of the amino acids in yeast ribosomal protein YS11 essential for the recognition of nucleotides in 18 S ribosomal RNA

The nucleotides in domain I of 18 S rRNA that are important for the binding of the essential yeast ribosomal protein YS11 are mainly in a kink-turn motif and the terminal loop of helix 11 (H11). In the atomic structure of the Thermus thermophilus 30 S subunit, 16 amino acids in S17, the homolog of YS11, are within hydrogen bonding distance of nucleotides in 16 S rRNA. The homologous or analogous 16 amino acids in YS11 were replaced with alanine; nine of the substitutions slowed the growth of yeast cells. The most severe effects were caused by mutations R103A, N106A, K133A, T134A, and K151A. The T. thermophilus analogs of Arg103, Asn106, Thr134, and Lys151 contact nucleotides in the kink-turn motif of 16 S rRNA, whereas Lys133 contacts nucleotides in the terminal loop of H11. These contacts are predominantly with backbone phosphate and sugar oxygens in regions that deviate from A-form geometry, suggesting that YS11 recognizes the shape of its rRNA-binding site rather than reading the sequence of nucleotides. The effect of the mutations on the binding of YS11 to a domain I fragment of 18 S rRNA accorded, in general, with their effect on growth. Mutations of seven YS11 amino acids (Ser77, Met80, Arg88, Tyr97, Pro130, Ser132, and Arg136) whose homologs or analogs in S17 are within hydrogen bonding distance of nucleotides in 16 S rRNA did not affect binding. Apparently, proximities alone do not define either the amino acids or the nucleotides that are important for recognition.

A determination of the identity elements in yeast 18 S ribosomal RNA for the recognition of ribosomal protein YS11: the role of the kink-turn motif in helix 11

A description of the site of interaction of YS11, the yeast homolog of eubacterial S17, with 18 S rRNA was obtained by assessing the binding of the ribosomal protein, in a filter retention assay, to oligoribonucleotides that reproduce regions of 18 S rRNA. YS11 binds predominantly to domain I; the Kd value is 113 nM. The dimensions of the YS11 binding site were refined, guided by chemical protection data and by the atomic structure of the Thermus thermophilus 30 S subunit, which has the S17 recognition site in 16 S rRNA. An oligoribonucleotide that mimics helix 11, a phylogenetically conserved region in domain I, binds YS11 with a Kd value of 230 nM; a second oligoribonucleotide that contains only the kink-turn motif in helix 11 binds YS11 with a Kd value of 528 nM. Thus, helix 11 has most of the nucleotides required for the recognition of YS11. To identify those nucleotides a set of 27 transversion mutations in H11 was constructed and their contribution to the binding of YS11 determined. Mutations of nine nucleotides (U313, C314, A316, G337, C338, G347, U348, U350, and C351) increased the Kd value for YS11 binding by at least eightfold; G325U and U349A mutations increased the Kd value fivefold. Eight of the 11 mutations are in the kink-turn in H11, confirming the critical importance of the motif for YS11 recognition. The other three nucleotides are in the lower stem and the terminal loop of H11, which makes a lesser, but still important, contribution to YS11 binding. The identity elements for YS11 recognition are: A316, G325, G337, G347, U348, U349, U350, and C351. The effect of the other nucleotides that decrease binding is probably indirect, presumably they affect the conformation of the binding site but do not have contacts to YS11 amino acid residues. The eight identity element nucleotides are in regions of H11 that deviate from A-form geometry and the contacts are predominantly, if not exclusively, to backbone phosphate and sugar oxygen atoms, indicating that YS11 recognizes the shape of the rRNA binding site rather than reading the sequence of nucleotides.

Crystal structure of the 30 S ribosomal subunit from Thermus thermophilus: structure of the proteins and their interactions with 16 S RNA

We present a detailed analysis of the protein structures in the 30 S ribosomal subunit from Thermus thermophilus, and their interactions with 16 S RNA based on a crystal structure at 3.05 A resolution. With 20 different polypeptide chains, the 30 S subunit adds significantly to our data base of RNA structure and protein-RNA interactions. In addition to globular domains, many of the proteins have long, extended regions, either in the termini or in internal loops, which make extensive contact to the RNA component and are involved in stabilizing RNA tertiary structure. Many ribosomal proteins share similar alpha+beta sandwich folds, but we show that the topology of this domain varies considerably, as do the ways in which the proteins interact with RNA. Analysis of the protein-RNA interactions in the context of ribosomal assembly shows that the primary binders are globular proteins that bind at RNA multihelix junctions, whereas proteins with long extensions assemble later. We attempt to correlate the structure with a large body of biochemical and genetic data on the 30 S subunit.

A genetic study of apramycin-resistant mutants of Escherichia coli

The apramycin-resistant mutants of E. coli were isolated spontaneously. Mutations, aprA and aprB, conferring resistance to apramycin were located at 72 min on the E. coli genetic map where most of ribosomal genes were mapped. One of the mutants, carrying the aprB mutation, has an altered translational fidelity expressed as severe restriction of amber suppressor activity in vivo. The chromosome location and altered translational fidelity indicate that the apramycin-resistant phenotype could be a consequence of an alteration of the ribosomal structure.

The yeast omnipotent suppressor SUP46 encodes a ribosomal protein which is a functional and structural homolog of the Escherichia coli S4 ram protein

The accurate synthesis of proteins is crucial to the existence of a cell. In yeast, several genes that affect the fidelity of translation have been identified (e.g., omnipotent suppressors, antisuppressors and allosuppressors). We have found that the dominant omnipotent suppressor SUP46 encodes the yeast ribosomal protein S13. S13 is encoded by two similar genes, but only the sup46 copy of the gene is able to fully complement the recessive phenotypes of SUP46 mutations. Both copies of the S13 genes contain introns. Unlike the introns of other duplicated ribosomal protein genes which are highly diverged, the duplicated S13 genes have two nearly identical DNA sequences of 25 and 31 bp in length within their introns. The SUP46 protein has significant homology to the S4 ribosomal protein in prokaryotic-type ribosomes. S4 is encoded by one of the ram (ribosomal ambiguity) genes in Escherichia coli which are the functional equivalent of omnipotent suppressors in yeast. Thus, SUP46 and S4 demonstrate functional as well as sequence conservation between prokaryotic and eukaryotic ribosomal proteins. SUP46 and S4 are most similar in their central amino acid sequences. Interestingly, the alterations resulting from the SUP46 mutations and the segment of the S4 protein involved in binding to the 16S rRNA are within this most conserved region.

Hygromycin- and paromomycin-resistant mutants of Aspergillus nidulans alter translational fidelity

Mutants of Aspergillus nidulans resistant to the aminoglycoside antibiotics paromomycin and hygromycin B have been isolated and their growth characteristics are described here. Most paromomycin mutants were cross-resistant to hygromycin and geneticin. All the hygromycin-resistant mutants were slightly cross-resistant to geneticin. Out of the 15 mutants tested 14 had drug-resistant ribosomes in vitro and all 12 of those investigated further had reduced levels of translational misreading. Five new loci have been found--parA on linkage group I, hygA on III, hygB on IV, hygC on V, hygD on VI and parB on VIII. This increases, to at least 12, the number of translational fidelity loci in A. nidulans.

Antisuppressor mutations reduce misreading of the genetic code in Aspergillus nidulans

Antisuppressor mutations were isolated in a strain containing the omnipotent suppressor suaC109. The antisuppressors reduce the activity of translational suppressors in vivo and counteract most aspects of the pleiotropic phenotype associated with the suaC and the suaA suppressor mutations. Using an homologous system for cell-free translation, we have measured translational accuracy in two antisuppressor strains with the genotype suaC109 and either the asuB11 or the asuD14 antisuppressor mutation. Ribosomes from antisuppressor mutants have higher levels of translation accuracy than those from the suppressor strain (suaC109, asu+). Mistranslation levels depended solely on the source of the sucrose-cleaned ribosomes. However, the increased accuracy associated with sucrose-cleaned ribosomes from antisuppressor strains can be nullified by salt-washing, suggesting that the component responsible can be washed off.

Sequence and functional similarity between a yeast ribosomal protein and the Escherichia coli S5 ram protein

The accurate and efficient translation of proteins is of fundamental importance to both bacteria and higher organisms. Most of our knowledge about the control of translational fidelity comes from studies of Escherichia coli. In particular, ram (ribosomal ambiguity) mutations in structural genes of E. coli ribosomal proteins S4 and S5 have been shown to increase translational error frequencies. We describe the first sequence of a ribosomal protein gene that affects translational ambiguity in a eucaryote. We show that the yeast omnipotent suppressor SUP44 encodes the yeast ribosomal protein S4. The gene exists as a single copy without an intron. The SUP44 protein is 26% identical (54% similar) to the well-characterized E. coli S5 ram protein. SUP44 is also 59% identical (78% similar) to mouse protein LLrep3, whose function was previously unknown (D.L. Heller, K.M. Gianda, and L. Leinwand, Mol. Cell. Biol. 8:2797-2803, 1988). The SUP44 suppressor mutation occurs near a region of the protein that corresponds to the known positions of alterations in E. coli S5 ram mutations. This is the first ribosomal protein whose function and sequence have been shown to be conserved between procaryotes and eucaryotes.

Sequence and functional similarity between a yeast ribosomal protein and the Escherichia coli S5 ram protein

The accurate and efficient translation of proteins is of fundamental importance to both bacteria and higher organisms. Most of our knowledge about the control of translational fidelity comes from studies of Escherichia coli. In particular, ram (ribosomal ambiguity) mutations in structural genes of E. coli ribosomal proteins S4 and S5 have been shown to increase translational error frequencies. We describe the first sequence of a ribosomal protein gene that affects translational ambiguity in a eucaryote. We show that the yeast omnipotent suppressor SUP44 encodes the yeast ribosomal protein S4. The gene exists as a single copy without an intron. The SUP44 protein is 26% identical (54% similar) to the well-characterized E. coli S5 ram protein. SUP44 is also 59% identical (78% similar) to mouse protein LLrep3, whose function was previously unknown (D.L. Heller, K.M. Gianda, and L. Leinwand, Mol. Cell. Biol. 8:2797-2803, 1988). The SUP44 suppressor mutation occurs near a region of the protein that corresponds to the known positions of alterations in E. coli S5 ram mutations. This is the first ribosomal protein whose function and sequence have been shown to be conserved between procaryotes and eucaryotes.

Correlation between poly(U) misreading and poly(dT) translation efficiency in E coli cell-free systems

A positive correlation between poly(U) misreading and efficiency of poly(dT) translation has been revealed in cell-free systems from wild-type E coli and streptomycin--resistant mutants with altered ribosomal protein S12. Different factors promoting misreading of poly(U) such as aminoglycoside antibiotics and Mg2+ ions also stimulate poly(dT) translation. The effect of the antibiotics on poly(U) translation efficiency and misreading as well as on poly(dT) decoding is characterised by the same order: neomycin greater than kanamycin greater than streptomycin. S12 mutants ribosomes are less erroneous in poly(U) translation and less efficient in poly(dT) decoding. The data obtained are in good agreement with the hypothesis of stereospecific stabilization of codon-anticodon complexes by the ribosome decoding centre.

Suppressors suaC109 and suaA101 of Aspergillus nidulans alter the ribosomal phenotype in vitro

A new homologous, cell-free system for protein synthesis has been devised for use with ribosomes and elongation factors from Aspergillus nidulans. Ribosome preparations from strains with either the suaA101 or suaC109 mutations have a higher misreading ratio (non-cognate:cognate amino acid incorporation) in the presence of hygromycin than controls. They can be classed as fidelity mutants. These results also prove that the mutations must be in genes coding for ribosomal proteins or enzymes which modify ribosomal proteins post-translationally. Alternatively, the genes could code for translation factors.

Antisuppressor mutations in Aspergillus nidulans: cold-resistant revertants of suppressor suaC109

Cold-resistant revertants of the cold-sensitive, ribosomal suppressorsuaC109have been isolated, with a view to obtaining mutations in new ribosomal protein genes. Many revertants had reduced suppressor activity and were classified as antisuppressor mutants. Both intragenic and extragenic reversions were found. In seven strains the extragenic reversion to cold resistance segregated with the antisuppressor phenotype, and these were designatedasumutations. Three of the fiveasugenes, C, B and D were mapped to linkage groups, I, II and V respectively. The antisuppressors are not gene-specific, although they mainly antagonize the activity of ribosomal suppressors. The antisuppressors altered all aspects of the phenotype of suppressorsuaC109including sensitivity to aminoglycoside antibiotics, and are therefore thought to be mutations in ribosomal protein genes.

Primary structures of mutationally altered ribosomal protein L7/L12 and their effects on cellular growth and translational accuracy

The amino acid sequences of mutationally altered ribosomal protein L7/L12 from four different rplL mutants of Escherichia coli were determined and correlated with some features of the mutant ribosomes. Two of the rplL mutations are deletions around position 40, which give rise to a shortened hinge region between the two domains of L7/L12. The other two mutants harbor point mutations at position 74 (Gly----Asp) or at position 82 (Glu----Lys), which are in or close to an evolutionarily conserved sequence in the C-terminal domain. The two latter mutations are associated with decreased rates of growth and translational elongation. All four mutants show increased nonsense codon read-through in vivo. Ribosomes from one of the deletion mutants show clearly increased missense error rates in vitro.

Isolation of the SUP45 omnipotent suppressor gene of Saccharomyces cerevisiae and characterization of its gene product

The Saccharomyces cerevisiae SUP45+ gene has been isolated from a genomic clone library by genetic complementation of paromomycin sensitivity, which is a property of a mutant strain carrying the sup45-2 allele. This plasmid complements all phenotypes associated with the sup45-2 mutation, including nonsense suppression, temperature sensitivity, osmotic sensitivity, and paromomycin sensitivity. Genetic mapping with a URA3+-marked derivative of the complementing plasmid that was integrated into the chromosome by homologous recombination demonstrated that the complementing fragment contained the SUP45+ gene and not an unlinked suppressor. The SUP45+ gene is present as a single copy in the haploid genome and is essential for viability. In vitro translation of the hybrid-selected SUP45+ transcript yielded a protein of Mr = 54,000, which is larger than any known ribosomal protein. RNA blot hybridization analysis showed that the steady-state level of the SUP45+ transcript is less than 10% of that for ribosomal protein L3 or rp59 transcripts. When yeast cells are subjected to a mild heat shock, the synthesis rate of the SUP45+ transcript was transiently reduced, approximately in parallel with ribosomal protein transcripts. Our data suggest that the SUP45+ gene does not encode a ribosomal protein. We speculate that it codes for a translation-related function whose precise nature is not yet known.

Isolation of the SUP45 omnipotent suppressor gene of Saccharomyces cerevisiae and characterization of its gene product

The Saccharomyces cerevisiae SUP45+ gene has been isolated from a genomic clone library by genetic complementation of paromomycin sensitivity, which is a property of a mutant strain carrying the sup45-2 allele. This plasmid complements all phenotypes associated with the sup45-2 mutation, including nonsense suppression, temperature sensitivity, osmotic sensitivity, and paromomycin sensitivity. Genetic mapping with a URA3+-marked derivative of the complementing plasmid that was integrated into the chromosome by homologous recombination demonstrated that the complementing fragment contained the SUP45+ gene and not an unlinked suppressor. The SUP45+ gene is present as a single copy in the haploid genome and is essential for viability. In vitro translation of the hybrid-selected SUP45+ transcript yielded a protein of Mr = 54,000, which is larger than any known ribosomal protein. RNA blot hybridization analysis showed that the steady-state level of the SUP45+ transcript is less than 10% of that for ribosomal protein L3 or rp59 transcripts. When yeast cells are subjected to a mild heat shock, the synthesis rate of the SUP45+ transcript was transiently reduced, approximately in parallel with ribosomal protein transcripts. Our data suggest that the SUP45+ gene does not encode a ribosomal protein. We speculate that it codes for a translation-related function whose precise nature is not yet known.

Involvement of ribosomal protein L7/L12 in control of translational accuracy

The effects of two mutations, which map at the rplL locus and both give a changed 50S ribosomal protein L7/L12, were studied. Both mutations are associated with an increased misreading of all three nonsense codons in vivo and ribosomes from the mutants give an increased misreading of the phenylalanine codon UUU by tRNALeu in vitro. The rplL-associated misreading in vitro is not limited to a particular type of mRNA or tRNA. Results from a translational proofreading assay, using mutant ribosomes, suggest that protein L7/L12 is involved in the control of translational accuracy by contributing to the efficiency of a translational proofreading step(s).

Revertants of a streptomycin-resistant, oligosporogenous mutant of Bacillus subtilis

Revertants of a streptomycin-resistant (Strr), oligosporogenous (Spo-) mutant of Bacillus subtilis were selected form the ability to sporulate. The revertants obtained fell into two phenotypic classes: Strs Spo+ (streptomycin-sensitive, sporeforming), which arose by reversion of the streptomycin resistance mutations of the parent strain; and Strr Spo+, which arose by the acquisition of additional mutations, some of which were shown to affect ribosomal proteins. Alterations of ribosomal proteins S4 and S16 in the 30S subunit and L18 inthe 50S subunit were detected in Strr Spo+ revertants by polyacrylamide gel electrophoresis. Streptomycin resistance of the parental strain and the Strr revertants was demonstrated to reside in the 30S ribosomal subunit. The second site mutations of the revertants depressed the level of streptomycin resistance in vivo and in the in vitro translation of phage SP01 messenger ribonucleic acid (mRNA) relative to the resistance exhibited by the Strr parental strain. The Strr parent grew slowly and sporulated at approximately 1% of the wild type level. The Strr revertants closely resembled the wild type strain with regard to growth and sporulation. The Strr revertants grew at rates intermediate between those of the Strr patent and wild type, and sporulated at wild type levels.

Speed-accuracy relationships during in vitro and in vivo protein biosynthesis

Poly U-directed incorporation of phenylalanine and leucine into polypeptide has been described in at least 50 papers since 1961. In general, high translation activities are associated with high accuracies, and vice-versa. Moreover, a vast body of independent experimental data (effect of ethanol, temperature, urea, aminoglycosides, etc... on protein synthesis) put together here suggests that, in many circumstances, speed and accuracy of elongation are correlated. This result is to be contrasted with the view that the speed and the fidelity of protein synthesis are two opposing parameters. In this report, recent experimental data on the nature and effect of ribosomal ambiguity (ram) and streptomycin resistance (Strr) mutations are reexamined. Models on the action of streptomycin and other misreading-inducing antibiotics, as well as long-standing ideas on the control of misreading in mammalian systems are critically evaluated. An explanation is provided for the long-befuddling data on the action of gentamicin.

Translational fidelity in Escherichia coli: antagonistic effects of neaA and ramC gene products on the ribosome function

A double mutant carrying the ramC and neaA mutations has been constructed by Plvir transductions. This mutant, which carries alterations in ribosomal proteins S5 and S17, behaves like to wild-type bacteria in the following respects: it no longer exhibits the restriction of informational suppressors normally associated with the neaA mutation (altered protein S17); ribosomes from the double mutant show increased intrinsic and neamine-induced misreading in vitro in contrast to ribosomes from the neaA strain, although still less than the misreading level of ribosomes from the ramC (altered protein S5) strain. These properties suggest that ribosomal proteins S5 and S17 act cooperatively to balance translational fidelity.

Biogenesis of mitochondria 51: biochemical characterization of a mitochondrial mutation in Saccharomyces cerevisiae affecting the mitochondrial ribosome by conferring resistance to aminoglycoside antibiotics

An examination of the effect of the aminoglycoside antibiotics paromomycin and neomycin on mitochondrial ribosome function in yeast has been made. Both antibiotics are potent inhibitors of protein synthesis in isolated mitochondria. With isolated mitochondrial ribosomes programmed with polyuridylic acid (poly U), the drugs are shown to inhibit polyphenylalanine synthesis at moderately high concentrations (above 100 microgram/ml). At lower concentrations (about 10 microgram/ml), paromomycin and neomycin cause a 2-3 fold stimulation in the extent of misreading of the UUU codons in poly U, over and above the significant level of misreading catalyzed by the ribosomes in the absence of drugs. Comparative studies have been made between a paromomycin sensitive strain D585-11C and a mutant strain 4810P carrying the par l-r mutation in mtDNA, which leads to high resistance to both paromomycin and neomycin in vivo. A high level of resistance to these antibiotics is observed in strain 4810P at the level of mitochondrial protein synthesis in vitro. Whilst the degree of resistance of isolated mitochondrial ribosomes from strain 4810P judged by the inhibition of polyphenylalanine synthesis by paromomycin and neomycin is not extensive, studies on misreading of the poly U message promoted by these drugs demonstrate convincingly the altered properties of mitochondrial ribosomes from the mutant strain 4810P. These ribosomes show resistance to the stimulation of misreading of the codon UUU brought about by paromomycin and neomycin in wild-type mitochondrial ribosomes. Although strain 4810P was originally isolated as being resistant to paromomycin, in all the in vitro amino acid incorporation systems tested here, the 4810P mitochondrial ribosomes show a higher degree of resistance to neomycin than to paromomycin. It is concluded that the parl-r mutation in strain 4810P affects a component of the mitochondrial ribosome, possibly by altering the 15S rRNA or a protein of the small ribosomal subunit. The further elucidation of the functions in the ribosomes that are modified by the parl-r mutation was hampered by the inability of current preparations of yeast mitochondrial ribosomes to translate efficiently natural messenger RNAs from the several sources tested.

A missense mutation in the gene coding for ribosomal protein S17 (rpsQ) leading to ribosomal assembly defectivity in Escherichia coli

The conditionally lethal mutation, 2861 mis, has been mapped inside the ribosomal protein gene cluster at 72 minutes on the Escherichia coli chromosome and was found to cotransduce at 97% with rpsE (S5). The 2861 mis mutation leads to thermosensitivity and impaired assembly in vivo of 30S ribosomal particles at 42 degrees C. The strain carrying the mutation has an altered S 17 ribosomal protein; the mutational alteration involves a replacement of serine by phenylalanine in protein S 17. Spontaneous reversion to temperature independence can restore the normal assembly in vivo of 30 S ribosomal subunits at 42 degrees C and the normal chromatographical behaviour of the S 17 ribosomal protein in vitro. We conclude therefore that the 2861 mis mutation affects the structural gene for protein S 17 (rpsQ).

Bacterial ribosomes with two ambiguity mutations: effects of translational fidelity, on the response to aminoglycosides and on the rate of protein synthesis

A set of mutants affected in translational fidelity was constructed by transduction within an otherwise isogenic Escherichia coli B argF40 argR11 background. Alterations in ribosomal proteins S4, S5, S12 and L6 either as single mutations or in various combinations were compared for their effects on aminoglycoside phenotypes, on in vivo and in vitro misreading and on the rate of peptide bond formation. Results may be summarized as follows: (i) Strains carrying two ambiguity mutations on the ribosome without any restrictive mutation are viable. When together, they only weakly increase the level of mistranslation as judged by several in vivo and in vitro test systems. (ii) The combination of two ram mutations causes a very strong cooperative increase of streptomycin sensitivity, irrespective of whether the strains have a wild-type S12 or mutationally altered S12 proteins (of the drug-resistant or -dependent types) on their ribosomes; (iii) The S4 and S5 ram mutations do not alter the response of the ribosome to aminoglycosides of the 2-desoxystreptamine group which are structurally unrelated to streptomycin. This is interpreted in terms of an effect of these ram mutations on the streptomycin binding site but not on the site(s) of binding of the other aminoglycosides. (iv) The rate of polypeptide bond formation which was determined from the kinetics of beta-galactosidase induction is not significantly changed in strains bearing the ram and the strA (streptomycin-resistant) alleles. In contrast, the L6 and the strA (streptomycin-dependent) alleles strongly reduce the rate of polypeptide elongation which mechanistically might be connected with restriction of ambiguity (Nino, 1974) in these cases.

Mutations determining generalized resistance to aminoglycoside antibiotics in Escherichia coli

Mutations conferring resistance to low levels of kanamycin in Escherichia coli have been mapped at 3 locations: the unc locus (min. 83), a locus we have designated kanA (MIN. 72), close to strA (rpsL), and a locus at min. 86.5 previously discovered by Plate (1976) that we have designated ecfB. The unc and ecfB mutations are associated with defects in energy metabolism, while mutations at kanA may be in the gene coding for ribosomal protein S12 (rpsL). The three types of mutations cause cross resistance to a number of different aminoglycoside antibiotics and the effects of the mutations are cumulative in combination.

Ribosomal proteins of yeast strains carrying mutations which affect the efficiency of nonsense suppression

We have examined the ribosomal proteins of strains of Saccharomyces cerevisiae which differ in the efficiency with which ochre nonsense mutations are suppressed. The strains in which ochre suppression is poor were [psi]- or carried antisuppressor mutations; those in which suppression was highly efficient were [psi]+ or carried allosuppressor mutations. The ribosomal proteins of these strains, as judged by two-dimensional polyacrylamide gel electrophoresis, were indistinguishable from those of wild-type.

Amber mutations in Escherichia coli essential genes: isolation of mutants affected in the ribosomes

A method to obtain amber mutations in ribosomal protein genes is described. tit relies on the P1-mediated localized mutagenesis (Hong and Ames, 1971) and on the fact that the recipient strain contains (a) an efficient but genetically unstable suppressor, (b) a particular thermoinducible lambda prophage which kills suppressor hosts at 42 degrees C. Exposure of these bacteria to the high temperature yields frequent suppressor-free derivatives while none will be found if the strain carries an amber mutation in an essential gene. Eleven mutants have been isolated by this method, of which at least six appear to carry amber mutations. All of them map close to, and to the right of spcA, in a region which codes mostly for ribosomal proteins. Three mutants were studied biochemically; all three show defective ribosomal assembly in vivo upon loss of suppression.

Ribosome editing and the error catastrophe hypothesis of cellular aging

Ribosome editing involves the dissociation during protein synthesis of inappropriate peptidyl-tRNA's, ones whose structure does not correctly complement the codon of the mRNA. This process is one of three stages in protein biosynthesis in which the frequency of errors in cellular proteins is controlled. These stages are reviewed and the implications of ribosome editing are described. A model for stability of the translation apparatus is criticized. Calculations using a revision of the model and experimentally reasonable values for the various parameters show varying time courses for error catastrophes.

Translational fidelity in Escherichia coli: contrasting role of neaA and ramA gene products in the ribosome functioning

Strains carrying both the ramA1 and the neaA301 mutations do not exhibit the restriction of informational suppressors normally associated with resistance to neamine. Furthermore, ribosomes from such strains exhibit increased misreading in vitro with respect to particles from the neaA strain. These properties suggest that translational fidelity may be cooperatively controlled by ribosomal proteins S4 and S17, coded by ramA (rpsd) and neaA (rpsq) genes respectively.