Accuracy modulating mutations of the ribosomal protein S4-S5 interface do not necessarily destabilize the rps4-rps5 protein–protein interaction

During the process of translation, an aminoacyl tRNA is selected in the A site of the decoding center of the small subunit based on the correct codon–anticodon base pairing. Though selection is usually accurate, mutations in the ribosomal RNA and proteins and the presence of some antibiotics like streptomycin alter translational accuracy. Recent crystallographic structures of the ribosome suggest that cognate tRNAs induce a “closed conformation” of the small subunit that stabilizes the codon–anticodon interactions at the A site. During formation of the closed conformation, the protein interface between rpS4 and rpS5 is broken while new contacts form with rpS12. Mutations in rpS12 confer streptomycin resistance or dependence and show a hyperaccurate phenotype. Mutations reversing streptomycin dependence affect rpS4 and rpS5. The canonical rpS4 and rpS5 streptomycin independent mutations increase translational errors and were called ribosomal ambiguity mutations (ram). The mutations in these proteins are proposed to affect formation of the closed complex by breaking the rpS4-rpS5 interface, which reduces the cost of domain closure and thus increases translational errors. We used a yeast two-hybrid system to study the interactions between the small subunit ribosomal proteins rpS4 and rpS5 and to test the effect of ram mutations on the stability of the interface. We found no correlation between ram phenotype and disruption of the interface.     

Cooperative control of translational fidelity by ribosomal proteins in Escherichia coli

Summary The effect on translational fidelity of a particular mutation in the gene coding for protein S5 (rpxE) has been investigated. This mutation has the opposite effect of a restrictive strA mutation; in vivo, it relieves the restriction imposed by strA on the suppression of T4 nonsense mutants and results in hypersensitivity to streptomycin; in vitro, the presence of the altered S5 protein in 30S ribosomes results in increased intrinsic misreading. It is concluded that this mutation, ramC₃₁₉, acts as a ribosomal ambiguity mutation similar to certain mutations of protein S4 (ramA).     

Correlation between a novel phenotype towards streptomycin and the binding of an additional protein to the ribosome in mutants of Escherichia coli B.]

Summary Mutants of Escherichia coli have been isolated containing streptomycin suppressors that exhibit novel phenotypes with respect to strA alleles. In one class of these mutants, the suppressor effect parallels a strong binding to the ribosome of an additional protein in at least stoichiometric amounts. Transduction experiments confirmed that the level of suppression and the degree of binding of this protein were correlated.     

Coevolution of antibiotic production and counter‐resistance in soil bacteria

We present evidence for the coexistence and coevolution of antibiotic resistance and biosynthesis genes in soil bacteria. The distribution of the streptomycin (strA) and viomycin (vph) resistance genes was examined in Streptomyces isolates. strA and vph were found either within a biosynthetic gene cluster or independently. Streptomyces griseus strains possessing the streptomycin cluster formed part of a clonal complex. All S. griseus strains possessing solely strA belonged to two clades; both were closely related to the streptomycin producers. Other more distantly related S. griseus strains did not contain strA. S. griseus strains with only vph also formed two clades, but they were more distantly related to the producers and to one another. The expression of the strA gene was constitutive in a resistance‐only strain whereas streptomycin producers showed peak strA expression in late log phase that correlates with the switch on of streptomycin biosynthesis. While there is evidence that antibiotics have diverse roles in nature, our data clearly support the coevolution of resistance in the presence of antibiotic biosynthetic capability within closely related soil dwelling bacteria. This reinforces the view that, for some antibiotics at least, the primary role is one of antibiosis during competition in soil for resources.     

A slow-growing, ribosomal mutant of Salmonella typhimurium

Summary The mechanisms of S. typhimurium reversion from histidine dependence (his ^–) to histidine independence (his ⁺) were studied. Genetic and phenotypic characteristics of revertants induced by nitrosoguanidine were analyzed. Among them a class of slow-growing revertants was selected. It is found that all of these slow-growing revertants carry the original UGA nonsense mutation within the histidine operon. They are streptomycin sensitive and no specific suppressor(s) for UGA nonsense codon are demonstrable. The suppression takes place in the absence of conventional nonsense UGA suppressor(s). It is seemingly due to a ribosomal mutation which in turn is likely to produce ambiguity in the process of translation and which suppresses the UGA nonsense codon. The rate of both in vivo and in vitro protein synthesis is significantly reduced. The fact that streptomycin, at sublethal doses, reduced the growth rate of these mutants, probably because of the simultaneous burden of two ambiguity factors, suggests that the mutants described may be regarded as a kind of ram (ribosomal ambiguity) mutants with a his ^– sup ^–genotype. Their capacity to translate poly-U is reduced and in that respect they differ from ram mutants of Escherichia coli.     

An in vitro polypeptide synthesizing system from methanogenic bacteria: Sensitivity to antibiotics

Summary An in vitro polypeptide synthesis system was set up for three methanogenic bacteria, Methanococcus vannielii, Methanobacterium formicicum and Methanosarcina barkeri, and the effect of classical 70S and 80S protein synthesis inhibitors studied. The following results were obtained: (i) The activity of ribosomes from all three methanogens was unaffected by a number of 70S inhibitors such as tetracycline, chloramphenicol, streptomycin, tiamulin and, probably, erythromycin as well; (ii) However, the ribosomes were sensitive to thiostrepton, virginiamycin and, to varying degrees, to those aminoglycosides containing a 2-deoxystreptamine moiety. Among the aminoglycosides examined, streptomycin induced no translational misreading. The compounds containing 2-deoxystreptamine stimulated misreading, albeit only at high concentrations (neomycin being an exception); (iii) Ribosomes from all three organisms were insensitive to the 80S inhibitors cycloheximide and ricin, but those from Methanobacterium formicicum were highly sensitive to anisomycin and moderately sensitive to verrucarin. The results support those of in vivo studies and provide conclusive evidence that archaebacterial ribosomes despite being 70S ribosomes lack binding sites for many classical eubacterial ribosome inhibitors. At the same time they possess sites for others, as well as for some inhibitors of 80S ribosomes.     

Electrophoretic and immunological studies on ribosomal proteins of 100 Escherichia coli revertants from streptomycin dependence

Summary Revertants from streptomycin dependence to independence were isolated as single step mutants from six different streptomycin dependent strains. The ribosomal proteins from 100 such mutants were analyzed by two-dimensional polyacrylamide gel electrophoresis and some of them were also examined by immunological techniques. Altered proteins were found in 40 mutants, 24 in protein S4 and 16 in protein S5. No change in any other protein was detected.Altered S5 proteins migrated into five different positions on the polyacrylamide plate and it can be concluded that the mutant proteins differ from the wild type probably by single amino acid replacements. The altered S4 proteins migrated into 17 different positions on the plate. Extensive changes of length, both shorter and longer than wild type S4 protein, are postulated for many of the mutant S4 proteins.Analysis of the ribosomal proteins of four ram mutants revealed altered S4 protein in two of them. The alterations in these mutant proteins are probably very similar to those found in streptomycin independent mutants.Among the revertants there was no apparent correlation between the protein alteration and the particular response to streptomycin.These studies suggest a strong interaction between protein S12, which confers streptomycin dependence, and protein S4 or S5, which can suppress this dependence.Paper No. 60 on Ribosomal Proteins. Preceding paper is by B. Wittmann-Liebold, Hoppe-Seyler's Z. physiol. Chemie, in press.     

The chloroplast gene encoding ribosomal protein S4 in Chlamydomonas reinhardtii spans an inverted repeat — unique sequence junction and can be mutated to suppress a streptomycin dependence mutation in ribosomal protein S12

The ribosomal protein gene rps4 was cloned and sequenced from the chloroplast genome of Chlamydomonas reinhardtii. The N-terminal 213 amino acid residues of the S4 protein are encoded in the single-copy region (SCR) of the genome, while the C-terminal 44 amino acid residues are encoded in the inverted repeat (IR). The deduced 257 amino acid sequence of C. reinhardtii S4 is considerably longer (by 51–59 residues) than S4 proteins of other photosynthetic species and Escherichia coli, due to the presence of two internal insertions and a C-terminal extension. A short conserved C-terminal motif found in all other S4 proteins examined is missing from the C. reinhardtii protein. In E. coli, mutations in the S4 protein suppress the streptomycin-dependent (sd) phenotype of mutations in the S12 protein. Because we have been unable to identify similar S4 mutations among suppressors of an sd mutation in C. reinhardtii S12 obtained using UV mutagenesis, we made site-directed mutations [Arg₆₈ (CGT) to Len (CTG and CTT)] in the wild-type rps4 gene equivalent to an E. coli Gln₅₃ to Len ribosomal ambiguity mutation (ram), which suppresses the sd phenotype and decreases translational accuracy. These mutants were tested for their ability to transform the sd S 12 mutation of C. reinhardtii to streptomycin independence. The streptomycin-independent isolates obtained by biolistic transformation all possessed the original sd mutation in rps12, but none had the expected donor Leu₆₈ mutations in rps4. Instead, six of 15 contained a Gln₇₃ (CAA) to Pro (CCA) mutation five amino acids downstream from the predicted mutant codon, irrespective of rps4 donor DNA. Two others contained six- and ten-amino acid, in-frame insertions at S4 positions 90 and 92 that appear to have been induced by the biolistic process itself. Eight streptomycin-independent isolates analyzed had wild-type rps4 genes and may possess mutations identical to previously isolated suppressors of sd that define at least two additional chloroplast loci. Cloned rps4 genes from streptomycin-independent isolates containing the Gln₇₃ to Pro mutation and the 6-amino acid insertion in r-protein S4 transform the sd strain to streptomycin independence.     

Status of Streptomycin Resistance Development in Xanthomonas oryzae pv. oryzae and Xanthomonas oryzae pv. oryzicola in China and their Resistance Characters

Rice leaves with bacterial blight or bacterial leaf streak symptoms were collected in southern China in 2007 and 2008. Five hundred and thirty‐four single‐colony isolates of Xanthomonas oryzae pv. oryzae and 827 single‐colony isolates of Xanthomonas oryzae pv. oryzicola were obtained and tested on plates for sensitivity to streptomycin. Four strains (0.75%) of X. oryzae pv. oryzae isolated from the same county of Province Yunnan were resistant to streptomycin, and the resistance factor (the ratio of the mean median effective concentration inhibiting growth of resistant isolates to that of sensitive isolates) was approximately 226. The resistant isolate also showed streptomycin resistance in vivo. In addition to resistant isolates, isolates of less sensitivity were also present in the population of X. oryzae pv. oryzae from Province Yunnan. However, no isolates with decreased streptomycin‐sensitivity were obtained from the population of X. oryzae pv. oryzicola. Mutations in the rpsL (encoding S12 protein) and rrs genes (encoding 16S rRNA) and the presence of the strA gene accounting for streptomycin resistance in other phytopathogens or animal and human pathogenic bacteria were examined on sensitive and resistant strains of X. oryzae pv. oryzae by polymerase chain reaction amplification and sequencing. Neither the presence of the strA gene nor mutations in the rpsL or rrs were found, suggesting that different resistance mechanisms are involved in the resistant isolates of X. oryzae pv. oryzae.     

Studies on ribosomal mutants of Salmonella typhimurium LT-2

Summary Mutations conferring resistance to spectinomycin, resistance to neomycinkanamycin and cold-sensitivity of ribosome biosynthesis were located on the Salmonella typhimurium chromosome in relation to the genes cysG, strA, and aroC. The effect of temperature and growth medium on the expression of these mutations, and the interactions between the mutations was determined as a prerequisite to the mapping. On the basis of chromosomal location and dominance, it is concluded that cold-sensitivity of ribosome synthesis can result from mutations in several distinct genes.This work was supported by Public Health Service research grant AI-05526.     

The dependence of UV-induced reversions to prototrophy on the streptomycin resistance allele in Escherichia coli

UV-induced mutability to prototrophy depended on the alleles of the strA locus. The yield of UV-induced suppressor mutations was decreased ten-fold in a Str^r strain compared with an isogenic Str^s strain. This decrease was due to the inability of the majority of suppressors to be expressed phenotypically in the Str^r strain in the course of selection. The addition of streptomycin to the selective media raised the number of selected suppressor revertants, by making such expression possible. The probable relation of streptomycin resistance and UV-induced suppressors is discussed.     

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.     

Mutations conferring lincomycin, spectinomycin, and streptomycin resistance in Solanum nigrum are located in three different chloroplast genes

A number of Solanum nigrum mutants resistant to the antibiotics spectinomycin, streptomycin and lincomycin have been isolated from regenerating leaf strips after mutagenesis with nitroso-methylurea. Selection of streptomycin- and spectinomycin-resistant mutants has been described earlier. Lincomycin-resistant mutants show resistance to higher levels of the antibiotic than used in the initial selection, and in the most resistant mutant (Ll7A1) maternal inheritance of the trait was demonstrated. The lincomycin-resistant mutant L17A1 and a streptomycin plus spectinomycin resistant double mutant (StSpl) were chosen for detailed molecular characterisation. Regions of the plastid DNA, within the genes encoding 16S and 23S rRNA and rps12 (3) were sequenced. For spectinomycin and lincomycin resistance, base changes identical to those in similar Nicotiana mutants were identified. Streptomycin resistance is associated with an A C change at codon 87 of rps 12 (converting a lysine into a glutamine), three codons upstream from a mutation earlier reported for Nicotiana. This site has not previously been implicated in streptomycin resistance mutations of higher plants, but has been found in Escherichia coli. The value of these mutants for studies on plastid genetics is discussed.     

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

Summary 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.     

Multiple effects of kanamycin on translational accuracy

Summary We have studied the effects of kanamycin on the accuracy of translation in vitro by wild-type and mutant ribosomes from Escherichia coli. Kanamycin stimulates the leucine missense error of poly(U) translation by wild-type, Ram, and streptomycin-resistant ribosomes in characteristic ways; in particular, the streptomycin-resistant ribosomes are significantly less error-prone than wild-type or Ram ribosomes at all concentrations of the antibiotic. Kinetic analysis of the effects of kanamycin on the translational accuracy of wild-type ribosomes reveals a different concentration dependence for the perturbation of the initial selectivity and for the proofreading. Furthermore, the initial selectivity of streptomycin-resistant ribosomes is not affected by kanamycin; the drug enhances only the error of proofreading by this mutant ribosome. We suggest that the multiple effects of kanamycin on the errors of translation are due to separate effects at different ribosomal sites.Abbreviations N-AcPhe N-acetylphenylalanine - Km Kanamycin (used in the Figures and Tables only) - Str streptomycin (-'-) - EF elongation factor - TCA trichloroacetic acid - Ram ribosome ambiguity mutant     

Distinct functional classes of ram mutations in 16S rRNA

During decoding, the ribosome selects the correct (cognate) aminoacyl-tRNA (aa-tRNA) from a large pool of incorrect aa-tRNAs through a two-stage mechanism. In the initial selection stage, aa-tRNA is delivered to the ribosome as part of a ternary complex with elongation factor EF-Tu and GTP. Interactions between codon and anticodon lead to activation of the GTPase domain of EF-Tu and GTP hydrolysis. Then, in the proofreading stage, aa-tRNA is released from EF-Tu and either moves fully into the A/A site (a step termed “accommodation”) or dissociates from the ribosome. Cognate codon-anticodon pairing not only stabilizes aa-tRNA at both stages of decoding but also stimulates GTP hydrolysis and accommodation, allowing the process to be both accurate and fast. In previous work, we isolated a number of ribosomal ambiguity (ram) mutations in 16S rRNA, implicating particular regions of the ribosome in the mechanism of decoding. Here, we analyze a representative subset of these mutations with respect to initial selection, proofreading, RF2-dependent termination, and overall miscoding in various contexts. We find that mutations that disrupt inter-subunit bridge B8 increase miscoding in a general way, causing defects in both initial selection and proofreading. Mutations in or near the A site behave differently, increasing miscoding in a codon-anticodon-dependent manner. These latter mutations may create spurious favorable interactions in the A site for certain near-cognate aa-tRNAs, providing an explanation for their context-dependent phenotypes in the cell.     

The chloroplast gene encoding ribosomal protein S4 in Chlamydomonas reinhardtii spans an inverted repeat — unique sequence junction and can be mutated to suppress a streptomycin dependence mutation in ribosomal protein S12

The ribosomal protein gene rps4 was cloned and sequenced from the chloroplast genome of Chlamydomonas reinhardtii. The N-terminal 213 amino acid residues of the S4 protein are encoded in the single-copy region (SCR) of the genome, while the C-terminal 44 amino acid residues are encoded in the inverted repeat (IR). The deduced 257 amino acid sequence of C. reinhardtii S4 is considerably longer (by 51–59 residues) than S4 proteins of other photosynthetic species and Escherichia coli, due to the presence of two internal insertions and a C-terminal extension. A short conserved C-terminal motif found in all other S4 proteins examined is missing from the C. reinhardtii protein. In E. coli, mutations in the S4 protein suppress the streptomycin-dependent (sd) phenotype of mutations in the S12 protein. Because we have been unable to identify similar S4 mutations among suppressors of an sd mutation in C. reinhardtii S12 obtained using UV mutagenesis, we made site-directed mutations [Arg₆₈ (CGT) to Len (CTG and CTT)] in the wild-type rps4 gene equivalent to an E. coli Gln₅₃ to Len ribosomal ambiguity mutation (ram), which suppresses the sd phenotype and decreases translational accuracy. These mutants were tested for their ability to transform the sd S 12 mutation of C. reinhardtii to streptomycin independence. The streptomycin-independent isolates obtained by biolistic transformation all possessed the original sd mutation in rps12, but none had the expected donor Leu₆₈ mutations in rps4. Instead, six of 15 contained a Gln₇₃ (CAA) to Pro (CCA) mutation five amino acids downstream from the predicted mutant codon, irrespective of rps4 donor DNA. Two others contained six- and ten-amino acid, in-frame insertions at S4 positions 90 and 92 that appear to have been induced by the biolistic process itself. Eight streptomycin-independent isolates analyzed had wild-type rps4 genes and may possess mutations identical to previously isolated suppressors of sd that define at least two additional chloroplast loci. Cloned rps4 genes from streptomycin-independent isolates containing the Gln₇₃ to Pro mutation and the 6-amino acid insertion in r-protein S4 transform the sd strain to streptomycin independence.     

Aminoglycoside sensitivity of ribosomes from the archaebacterium Methanococcus vannielii: Structure-activity relationship

Abstract The effect of about 20 aminoglycoside antibiotics comprising compounds with specific 70S or with 70S plus 80S activity on polypeptide synthesis and translational misreading by ribosomes from the archaebacterium Methanococcus vannielii was investigated. A clear structure-activity relationship was found: sensitivity was observed only to the class of 4,5-disubstituted deoxystreptamine compounds, with neomycin and paromomycin as the most active ones. The streptomycin class aminoglycosides were completely inactive whereas the gentamicin group compounds solely affected misreading and only at high concentrations. Viomycin, a specific inhibitor of the translocation reaction at the eubacterial ribosome which competes with binding of 2-deoxystreptamine aminoglycosides was inactive as well.     

Novel ribosomal mutations affecting translational accuracy, antibiotic resistance and virulence of Salmonella typhimurium

Many mutations in rpsL cause resistance to, or dependence on, streptomycin and are restrictive (hyperaccurate) in translation. Dependence on streptomycin and hyperaccuracy can each be reversed phenotypically by mutations in either rpsD or rpsE . Such compensatory mutations have been shown to have a ram phenotype (ribosomal ambiguity), increasing the level of translational errors. We have shown recently that restrictive rpsL alleles are also associated with a loss of virulence in Salmonella typhimurium . To test whether ram mutants could reverse this loss of virulence, we have isolated a set of rpsD alleles in Salmonella typhimurium . We found that the rpsD alleles restore the virulence of strains carrying restrictive rpsL alleles to a level close to that of the wild type. Unexpectedly, three out of seven mutant rpsD alleles tested have phenotypes typical of restrictive alleles of rpsL , being resistant to streptomycin and restrictive (hyperaccurate) in translation. These phenotypes have not been previously associated with the ribosomal protein S4. Furthermore, all seven rpsD alleles (four ram and three restrictive) can phenotypically reverse the hyperaccuracy associated with restrictive alleles of rpsL . This is the first demonstration that such compensations do not require that the compensating rpsD allele has a ribosomal ambiguity ( ram ) phenotype.     

Effect of Streptomycin on Ribosome Interconversion,a Possible Basis for the Action of the Antibiotic

STREPTOMYCIN affects bacterial protein synthesis in vitro by interfering with ribosomal functions^1,2. For example, it inhibits polypeptide synthesis directed by natural mRNA^3–5 or by synthetic polynucleotides^4,6–10, and, in the latter case, causes extensive misreading of the genetic code^10–15. The drug also induces breakdown of polysomes^5,14,15 and the release of fMet-tRNA from its complex with the 70S ribosome^16–18. It has been proposed that streptomycin causes these effects by distorting the ribosomal binding sites for tRNA derivatives^14–18. The nature of the primary effect of streptomycin on the ribosome is, however, still not fully understood. We present evidence that might provide an insight into the basic mechanism underlying the mode of action of the antibiotic.