An examination of the inhibitory effects of three antibiotics in combination on ribosome biosynthesis in Staphylococcus aureus

Although a number of different antibiotics are used to combat staphylococcal infections, resistance has continued to develop. The use of rifampicin and ciprofloxacin in combination with azithromycin, known for its inhibitory effects on the bacterial ribosome, can create potential synergistic effects on ribosomal subunit synthesis rates. In this work, combination antibiotic treatments gave a significant decrease in cell numbers following growth in the presence of ciprofloxacin or rifampicin with azithromycin compared to those grown with azithromycin or rifampicin alone. DNA, RNA and protein synthesis rates were reduced with single antibiotic treatments and showed further decreases when drug combinations were used. 70S ribosome levels were reduced with every antibiotic treatment. DNA gyrase subunits A and B showed significant decreases for double and triple antibiotic-treated samples. Ribosomal subunit synthesis rates were diminished for each different antibiotic combination. Turnover of 16S and 23S rRNA was also observed in each case and was stimulated by antibiotic combinations. The frequency of spontaneous resistance was reduced in all double selections, and no triply resistant mutants were found.     

A noncanonical binding site of chloramphenicol revealed via molecular dynamics simulations

Chloramphenicol, an antibiotic belonging to the family of amphenicols, is an inhibitor of translation. On the basis of X–ray structural analysis of the binding of chloramphenicol to free bacterial ribosomes, the chloramphenicol action mechanism that consists in preventing the binding of aminoacyl-tRNA to the A–site of the large subunit of the ribosome was adopted. However, the known structures of chloramphenicol complexes with bacterial ribosomes poorly explain the results of the experiments on the chemical modification of 23S rRNA, the resistance to chloramphenicol caused by mutations in 23S rRNA and, which is particularly important, the selectivity of chloramphenicol in suppression of translation, depending on the amino acid sequence of the nascent peptide. In the present study the putative structure of the chloramphenicol complex with a bacterial ribosome in the A,A/P,P–state has been obtained by molecular dynamics simulations methods. The proposed structure of the complex allows us to explain the results of biochemical studies of the interaction of chloramphenicol with the bacterial ribosome.     

NMR structure of bacterial ribosomal protein l20: implications for ribosome assembly and translational control

L20 is a specific protein of the bacterial ribosome, which is involved in the early assembly steps of the 50S subunit and in the feedback control of the expression of its own gene. This dual function involves specific interactions with either the 23S rRNA or its messenger RNA. The solution structure of the free Aquifex aeolicus L20 has been solved. It is composed of an unstructured N-terminal domain comprising residues 1-58 and a C-terminal alpha-helical domain. This is in contrast with what is observed in the bacterial 50S subunit, where the N-terminal region folds as an elongated alpha-helical region. The solution structure of the C-terminal domain shows that several solvent-accessible, conserved residues are clustered on the surface of the molecule and are probably involved in RNA recognition. In vivo studies show that this domain is sufficient to repress the expression of the cistrons encoding L35 and L20 in the IF3 operon. The ability of L20 C-terminal domain to specifically recognise RNA suggests an assembly mechanism for L20 into the ribosome. The pre-folded C-terminal domain would make a primary interaction with a specific site on the 23S rRNA. The N-terminal domain would then fold within the ribosome, participating in its correct 3D assembly.     

Cross-linking of streptomycin to the 50S subunit of Escherichia coli with phenyldiglyoxal

[3H]Dihydrostreptomycin was covalently linked to the 50S subunit of Escherichia coli K12A19 with the bifunctional cross-linking reagent phenyldiglyoxal. The cross-linking was abolished under conditions that prevent the specific interaction of streptomycin with the ribosome. The binding primarily involved the ribosomal RNA and also a limited number of proteins, namely, L2, L6, and L17. This suggests that the binding domain for streptomycin is close to the peptidyl transferase center, in the valley between the central protuberance and the wider lateral protuberance of the 50S subunit. This domain faces the binding domain for streptomycin which we have previously characterized on the 30S subunit [Melan?on, P., Boileau, G., & Brakier-Gingras, L. (1984) Biochemistry 23, 6697-6703]. Our results indicate that the 50S subunit is involved in the binding of streptomycin to the bacterial ribosome, in addition to the 30S subunit which is generally considered as the specific target of the antibiotic. They are consistent with the occurrence of a single binding site for streptomycin on the ribosome, comprised of regions of both subunits.     

Structural analysis of kasugamycin inhibition of translation

The prokaryotic ribosome is an important target of antibiotic action. We determined the X-ray structure of the aminoglycoside kasugamycin (Ksg) in complex with the Escherichia coli 70S ribosome at 3.5-A resolution. The structure reveals that the drug binds within the messenger RNA channel of the 30S subunit between the universally conserved G926 and A794 nucleotides in 16S ribosomal RNA, which are sites of Ksg resistance. To our surprise, Ksg resistance mutations do not inhibit binding of the drug to the ribosome. The present structural and biochemical results indicate that inhibition by Ksg and Ksg resistance are closely linked to the structure of the mRNA at the junction of the peptidyl-tRNA and exit-tRNA sites (P and E sites).     

Impairment of ribosomal subunit synthesis in aminoglycoside-treated ribonuclease mutants of Escherichia coli

The bacterial ribosome is an important target for many antimicrobial agents. Aminoglycoside antibiotics bind to both 30S and 50S ribosomal subunits, inhibiting translation and subunit formation. During ribosomal subunit biogenesis, ribonucleases (RNases) play an important role in rRNA processing. E. coli cells deficient for specific processing RNases are predicted to have an increased sensitivity to neomycin and paromomycin. Four RNase mutant strains showed an increased growth sensitivity to both aminoglycoside antibiotics. E. coli strains deficient for the rRNA processing enzymes RNase III, RNase E, RNase G or RNase PH showed significantly reduced subunit amounts after antibiotic treatment. A substantial increase in a 16S RNA precursor molecule was observed as well. Ribosomal RNA turnover was stimulated, and an enhancement of 16S and 23S rRNA fragmentation was detected in E. coli cells deficient for these enzymes. This work indicates that bacterial RNases may be novel antimicrobial targets.     

Structural basis for aminoglycoside inhibition of bacterial ribosome recycling

Aminoglycosides are widely used antibiotics that cause messenger RNA decoding errors, block mRNA and transfer RNA translocation, and inhibit ribosome recycling. Ribosome recycling follows the termination of protein synthesis and is aided by ribosome recycling factor (RRF) in bacteria. The molecular mechanism by which aminoglycosides inhibit ribosome recycling is unknown. Here we show in X-ray crystal structures of the Escherichia coli 70S ribosome that RRF binding causes RNA helix H69 of the large ribosomal subunit, which is crucial for subunit association, to swing away from the subunit interface. Aminoglycosides bind to H69 and completely restore the contacts between ribosomal subunits that are disrupted by RRF. These results provide a structural explanation for aminoglycoside inhibition of ribosome recycling.     

Inhibition by Thiopeptin of Bacterial Protein Synthesis

Thiopeptin, a sulfur-containing antibiotic, was found to inhibit protein synthesis in a bacterial ribosomal system. The pretreatment of ribosomal subunits with the antibiotic revealed that thiopeptin may act on the 50 S ribosomal subunit. The elongation of peptide chain on the ribosome is more profoundly blocked by the antibiotic than the initiation of protein synthesis. It was demonstrated that thiopeptin inhibits elongation factor (EF)-Tu-dependent GTP hydrolysis and binding of aminoacyl-tRNA to the ribosome. The peptidyl transferase-catalyzed puromycin reaction is not significantly affected by the antibiotic. Thiopeptin inhibits EF-G-associated GTPase reaction, and translocation of peptidyl-tRNA and mRNA from the acceptor site to the donor site. Protein synthesis in ribosomal systems, obtained from rat liver and rabbit reticulocytes are insensitive to the antibiotic.     

How initiation factors maximize the accuracy of tRNA selection in initiation of bacterial protein synthesis

During initiation of bacterial protein synthesis, messenger RNA and fMet-tRNAfMet bind to the 30S ribosomal subunit together with initiation factors IF1, IF2, and IF3. Docking of the 30S preinitiation complex to the 50S ribosomal subunit results in a peptidyl-transfer competent 70S ribosome. Initiation with an elongator tRNA may lead to frameshift and an aberrant N-terminal sequence in the nascent protein. We show how the occurrence of initiation errors is minimized by (1) recognition of the formyl group by the synergistic action of IF2 and IF1, (2) uniform destabilization of the binding of all tRNAs to the 30S subunit by IF3, and (3) an optimal distance between the Shine-Dalgarno sequence and the initiator codon. We suggest why IF1 is essential for E. coli, discuss the role of the G-C base pairs in the anticodon stem of some tRNAs, and clarify gene expression changes with varying IF3 concentration in the living cell.     

Growth of the Stress-Bearing and Shape-Maintaining Murein Sacculus of Escherichia coli

To withstand the high intracellular pressure, the cell wall of most bacteria is stabilized by a unique cross-linked biopolymer called murein or peptidoglycan. It is made of glycan strands [poly-(GlcNAc-MurNAc)], which are linked by short peptides to form a covalently closed net. Completely surrounding the cell, the murein represents a kind of bacterial exoskeleton known as the murein sacculus. Not only does the sacculus endow bacteria with mechanical stability, but in addition it maintains the specific shape of the cell. Enlargement and division of the murein sacculus is a prerequisite for growth of the bacterium. Two groups of enzymes, hydrolases and synthases, have to cooperate to allow the insertion of new subunits into the murein net. The action of these enzymes must be well coordinated to guarantee growth of the stress-bearing sacculus without risking bacteriolysis. Protein-protein interaction studies suggest that this is accomplished by the formation of a multienzyme complex, a murein-synthesizing machinery combining murein hydrolases and synthases. Enlargement of both the multilayered murein of gram-positive and the thin, single-layered murein of gram-negative bacteria seems to follow an inside-to-outside growth strategy. New material is hooked in a relaxed state underneath the stress-bearing sacculus before it becomes inserted upon cleavage of covalent bonds in the layer(s) under tension. A model is presented that postulates that maintenance of bacterial shape is achieved by the enzyme complex copying the preexisting murein sacculus that plays the role of a template.     

Removal of a ribosome small subunit-dependent GTPase confers salt resistance on Escherichia coli cells

RsgA is a unique GTP hydrolytic protein in which GTPase activity is significantly enhanced by the small ribosomal subunit. Deletion of RsgA causes slow cell growth as well as defects in subunit assembly of the ribosome and 16S rRNA processing, suggesting its involvement in maturation of the small subunit. In this study, we found that removal of RsgA or inactivation of its ribosome small subunit-dependent GTPase activity provides Escherichia coli cells with resistance to high salt stress. Salt stress suppressed the defects in subunit assembly of the ribosome and processing of 16S rRNA as well as truncation of the 3′ end of 16S rRNA in RsgA-deletion cells. In contrast, salt stress transiently impaired subunit assembly of the ribosome and processing of 16S rRNA and induced 3′ truncation of 16S rRNA in wild-type cells. These results suggest that the action of RsgA on the ribosome, which usually facilitates maturation of the small subunit, disturbs it under a salt stress condition. Consistently, there was a drastic but transient decrease in the intracellular amount of RsgA after salt shock. Salt shock would make the pathway of maturation of the ribosome small subunit RsgA independent.     

A novel GTPase activated by the small subunit of ribosome

The GTPase activity of Escherichia coli YjeQ, here named RsgA (ribosome small subunit-dependent GTPase A), has been shown to be significantly enhanced by ribosome or its small subunit. The enhancement of GTPase activity was inhibited by several aminoglycosides bound at the A site of the small subunit, but not by a P site-specific antibiotic. RsgA stably bound the small subunit in the presence of GDPNP, but not in the presence of GTP or GDP, to dissociate ribosome into subunits. Disruption of the gene for RsgA from the genome affected the growth of the cells, which predominantly contained the dissociated subunits having only a weak activation activity of RsgA. We also found that 17S RNA, a putative precursor of 16S rRNA, was contained in the small subunit of the ribosome from the RsgA-deletion strain. RsgA is a novel GTPase that might provide a new insight into the function of ribosome.     

Ribosomal history reveals origins of modern protein synthesis

The origin and evolution of the ribosome is central to our understanding of the cellular world. Most hypotheses posit that the ribosome originated in the peptidyl transferase center of the large ribosomal subunit. However, these proposals do not link protein synthesis to RNA recognition and do not use a phylogenetic comparative framework to study ribosomal evolution. Here we infer evolution of the structural components of the ribosome. Phylogenetic methods widely used in morphometrics are applied directly to RNA structures of thousands of molecules and to a census of protein structures in hundreds of genomes. We find that components of the small subunit involved in ribosomal processivity evolved earlier than the catalytic peptidyl transferase center responsible for protein synthesis. Remarkably, subunit RNA and proteins coevolved, starting with interactions between the oldest proteins (S12 and S17) and the oldest substructure (the ribosomal ratchet) in the small subunit and ending with the rise of a modern multi-subunit ribosome. Ancestral ribonucleoprotein components show similarities to in vitro evolved RNA replicase ribozymes and protein structures in extant replication machinery. Our study therefore provides important clues about the chicken-or-egg dilemma associated with the central dogma of molecular biology by showing that ribosomal history is driven by the gradual structural accretion of protein and RNA structures. Most importantly, results suggest that functionally important and conserved regions of the ribosome were recruited and could be relics of an ancient ribonucleoprotein world.     

Ribosome assembly in Escherichia coli strains lacking the RNA helicase DeaD/CsdA or DbpA

Ribosome subunit assembly in bacteria is a fast and efficient process. Among the nonribosomal proteins involved in ribosome biogenesis are RNA helicases. We describe ribosome biogenesis in Escherichia coli strains lacking RNA helicase DeaD (CsdA) or DbpA. Ribosome large subunit assembly intermediate particles (40S) accumulate at 25 degrees C and at 37 degrees C in the absence of DeaD but not without DbpA. 23S rRNA is incompletely processed in the 40S and 50S particles of the DeaD(-) strain. Pulse labeling showed that the 40S particles are converted nearly completely into functional ribosomes. The rate of large ribosomal subunit assembly was reduced about four times in DeaD-deficient cells. Functional activity tests of the ribosomal particles demonstrated that the final step of 50S assembly, the activation step, was affected when DeaD was not present. The results are compatible with the model that predicts multiple DeaD-catalyzed structural transitions of the ribosome large subunit assembly.     

Fluorescence studies on a streptomycin-induced conformational change in ribosomes which correlates with misreading

The fluorescent reagent N-(iodoacetylaminoethyl)-5-naphthylamine-1-sulfonic acid (I-AEDANS) was employed to detect and study the previously reported conformational change in the Escherichia coli ribosome induced by streptomycin. Labeling of ribosomes with this probe, which results in the derivatization of proteins S18 and L31', described earlier, inhibits neither their ribosomal protein synthesizing nor misreading ability. To calculate the amount of streptomycin bound to the ribosome, we determined the K'D for streptomycin, which is 0.24 micron, indicating that under our conditions, bound streptomycin/ribosome molar ratios are low, not in excess of 1. Under these conditions, streptomycin addition induces fluorescence quenching by 15% but does not affect streptomycin-resistant ribosomes. Maximal misreading occurs at these same ratios. Removal of AEDANS-L31' from the ribosomes drastically reduces streptomycin-induced quenching indicating the involvement of the environment of this protein in streptomycin action. The finding that streptomycin decreases AEDANS-L31' affinity for the ribosome supports this view. Streptomycin has been shown to bind to the 30 S subunit protein S4 while the 50 S protein L31' has been shown to be localized at the subunit interface. Thus, the observation that streptomycin influences this 50 S subunit protein L31', combined with the tight correlation between the effects of streptomycin on quenching and on misreading, strongly suggests that this antibiotic induces a conformational change at the subunit interface of the ribosome, and that this results in misreading. Polyuridylic acid also induces a conformational change in the ribosome but the polynucleotide and streptomycin seem to act independently. Streptomycin-resistant ribosomes, which undergo neither streptomycin-induced fluorescence nor streptomycin-induced misreading, are resistant to misreading induced by high Mg2+ as well.     

Escherichia coli Ribosomal Protein S1 Unfolds Structured mRNAs Onto the Ribosome for Active Translation Initiation

Regulation of translation initiation is well appropriate to adapt cell growth in response to stress and environmental changes. Many bacterial mRNAs adopt structures in their 5′ untranslated regions that modulate the accessibility of the 30S ribosomal subunit. Structured mRNAs interact with the 30S in a two-step process where the docking of a folded mRNA precedes an accommodation step. Here, we used a combination of experimental approaches in vitro (kinetic of mRNA unfolding and binding experiments to analyze mRNA–protein or mRNA–ribosome complexes, toeprinting assays to follow the formation of ribosomal initiation complexes) and in vivo (genetic) to monitor the action of ribosomal protein S1 on the initiation of structured and regulated mRNAs. We demonstrate that r-protein S1 endows the 30S with an RNA chaperone activity that is essential for the docking and the unfolding of structured mRNAs, and for the correct positioning of the initiation codon inside the decoding channel. The first three OB-fold domains of S1 retain all its activities (mRNA and 30S binding, RNA melting activity) on the 30S subunit. S1 is not required for all mRNAs and acts differently on mRNAs according to the signals present at their 5′ ends. This work shows that S1 confers to the ribosome dynamic properties to initiate translation of a large set of mRNAs with diverse structural features.