Novel mutants of 23S RNA: characterization of functional properties

Mapping the in vivo fitness landscape of a tethered ribosome

Fitness landscapes are models of the sequence space of a genetic element that map how each sequence corresponds to its activity and can be used to guide laboratory evolution. The ribosome is a macromolecular machine that is essential for protein synthesis in all organisms. Because of the prevalence of dominant lethal mutations, a comprehensive fitness landscape of the ribosomal peptidyl transfer center (PTC) has not yet been attained. Here, we develop a method to functionally map an orthogonal tethered ribosome (oRiboT), which permits complete mutagenesis of nucleotides located in the PTC and the resulting epistatic interactions. We found that most nucleotides studied showed flexibility to mutation, and identified epistatic interactions between them, which compensate for deleterious mutations. This work provides a basis for a deeper understanding of ribosome function and malleability and could be used to inform design of engineered ribosomes with applications to synthesize next-generation biomaterials and therapeutics.

The A-Z of bacterial translation inhibitors

Protein synthesis is one of the major targets in the cell for antibiotics. This review endeavors to provide a comprehensive "post-ribosome structure" A-Z of the huge diversity of antibiotics that target the bacterial translation apparatus, with an emphasis on correlating the vast wealth of biochemical data with more recently available ribosome structures, in order to understand function. The binding site, mechanism of action, and modes of resistance for 26 different classes of protein synthesis inhibitors are presented, ranging from ABT-773 to Zyvox. In addition to improving our understanding of the process of translation, insight into the mechanism of action of antibiotics is essential to the development of novel and more effective antimicrobial agents to combat emerging bacterial resistance to many clinically-relevant drugs.

Unraveling New Features of Clindamycin Interaction with Functional Ribosomes and Dependence of the Drug Potency on Polyamines

The effect of spermine on the inhibition of peptide-bond formation by clindamycin, an antibiotic of the Macrolide-Lincosamide-StreptograminsB family, was investigated in a cell-free system derived from Escherichia coli. In this system peptide bond is formed between puromycin, a pseudo-substrate of the A-site, and acetylphenylalanyl-tRNA, bound at the P-site of poly(U)-programmed 70 S ribosomes. Biphasic kinetics revealed that one molecule of clindamycin, after a transient interference with the A-site of ribosomes, is slowly accommodated near the P-site and perturbs the 70 S/acetylphenylalanyl-tRNA complex so that a peptide bond is still formed but with a lower velocity compared with that observed in the absence of the drug. The above mechanism requires a high temperature (25 degrees C as opposed to 5 degrees C). If this is not met, the inhibition is simple competitive. It was found that at 25 degrees C spermine favors the clindamycin binding to ribosomes; the affinity of clindamycin for the A-site becomes 5 times higher, whereas the overall inhibition constant undergoes a 3-fold decrease. Similar results were obtained when ribosomes labeled with N1-azidobenzamidinospermine, a photo-reactive analogue of spermine, were used or when a mixture of spermine and spermidine was added in the reaction mixture instead of spermine alone. Polyamines cannot compensate for the loss of biphasic kinetics at 5 degrees C nor can they stimulate the clindamycin binding to ribosomes. Our kinetic results correlate well with photoaffinity labeling data, suggesting that at 25 degrees C polyamines bound at the vicinity of the drug binding pocket affect the tertiary structure of ribosomes and influence their interaction with clindamycin.

Simulating movement of tRNA into the ribosome during decoding

Decoding is the key step during protein synthesis that enables information transfer from RNA to protein, a process critical for the survival of all organisms. We have used large-scale (2.64 x 10(6) atoms) all-atom simulations of the entire ribosome to understand a critical step of decoding. Although the decoding problem has been studied for more than four decades, the rate-limiting step of cognate tRNA selection has only recently been identified. This step, known as accommodation, involves the movement inside the ribosome of the aminoacyl-tRNA from the partially bound "A/T" state to the fully bound "A/A" state. Here, we show that a corridor of 20 universally conserved ribosomal RNA bases interacts with the tRNA during the accommodation movement. Surprisingly, the tRNA is impeded by the A-loop (23S helix 92), instead of enjoying a smooth transition to the A/A state. In particular, universally conserved 23S ribosomal RNA bases U2492, C2556, and C2573 act as a 3D gate, causing the acceptor stem to pause before allowing entrance into the peptidyl transferase center. Our simulations demonstrate that the flexibility of the acceptor stem of the tRNA, in addition to flexibility of the anticodon arm, is essential for tRNA selection. This study serves as a template for simulating conformational changes in large (>10(6) atoms) biological and artificial molecular machines.

Analysis of the function of E. coli 23S rRNA helix-loop 69 by mutagenesis

BACKGROUND

The ribosome is a two-subunit enzyme known to exhibit structural dynamism during protein synthesis. The intersubunit bridges have been proposed to play important roles in decoding, translocation, and the peptidyl transferase reaction; yet the physical nature of their contributions is ill understood. An intriguing intersubunit bridge, B2a, which contains 23S rRNA helix 69 as a major component, has been implicated by proximity in a number of catalytically important regions. In addition to contacting the small ribosomal subunit, helix 69 contacts both the A and P site tRNAs and several translation factors.

RESULTS

We scanned the loop of helix 69 by mutagenesis and analyzed the mutant ribosomes using a plasmid-borne IPTG-inducible expression system. We assayed the effects of 23S rRNA mutations on cell growth, contribution of mutant ribosomes to cellular polysome pools and the ability of mutant ribosomes to function in cell-free translation. Mutations A1912G, and A1919G have very strong growth phenotypes, are inactive during in vitro protein synthesis, and under-represented in the polysomes. Mutation Psi1917C has a very strong growth phenotype and leads to a general depletion of the cellular polysome pool. Mutation A1916G, having a modest growth phenotype, is apparently defective in the assembly of the 70S ribosome.

CONCLUSION

Mutations A1912G, A1919G, and Psi1917C of 23S rRNA strongly inhibit translation. Mutation A1916G causes a defect in the 50S subunit or 70S formation. Mutations Psi1911C, A1913G, C1914A, Psi1915C, and A1918G lack clear phenotypes.

U2552 methylation at the ribosomal A-site is a negative modulator of translational accuracy

We have recently identified RrmJ, the first encoded protein of the rrmJ-ftsH heat shock operon, as being the Um(2552) methyltransferase of 23S rRNA, and reported that rrmJ-deficient strains exhibit growth defects, reduced translation rates and reduced stability of 70S ribosomes. U2552 is an ubiquitously methylated residue. It belongs to the A loop of 23S RNA which is an essential component of the ribosome peptidyltransferase centre and interacts directly with aminoacyl(A)-site tRNA. In the present study, we show that a lack of U2552 methylation, obtained in rrmJ-deficient mutants, results in a decrease in programmed +1 and -1 translational frameshifing and a decrease in readthrough of UAA and UGA stop codons. The increased translational accuracy of rrmJ-deficient strains suggests that the interaction between aminoacyl-tRNA and U2552 is important for selection of the correct tRNA at the ribosomal A site, and supports the idea that translational accuracy in vivo is optimal rather than maximal, thus pointing to the participation of recoding events in the normal cell physiology.

Protected nucleotide G2608 in 23S rRNA confers resistance to oxazolidinones in E. coli

The oxazolidinones are a new class of potent antibiotics that are active against a broad spectrum of Gram-positive bacterial pathogens including those resistant to other antibiotics. These drugs specifically inhibit protein biosynthesis whereas DNA and RNA synthesis are not affected. Although biochemical and genetic studies indicate that oxazolidinones target the ribosomal peptidyltransferase center, other investigations suggest that they interact with different regions of ribosomes. Thus, the exact binding site and mechanism of action have remained elusive. Here, we study, by use of base-specific reagents, the effect of the oxazolidinones on the chemical protection footprinting patterns of the 23S rRNA. We report: (i) reproducible protection of G2607 and G2608 of 23S rRNA by a potent oxazolidinone on a ribosome.tRNA.mRNA complex; (ii) no protections were observed on 70S ribosomes devoid of tRNA and mRNA; (iii) EF-G also weakly protected G2607 and G2608; (iv) mutations at G2608 conferred resistance to the oxazolidinones in Escherichia coli cells; and (v) G2607 and G2608 occur near the exit to the peptide tunnel on the 50S subunit. A mechanism for the pleiotropic action of the oxazolidinones is discussed.

Importance of transient structures during post-transcriptional refolding of the pre-23S rRNA and ribosomal large subunit assembly

An important step of ribosome assembly is the folding of the rRNA into a functional structure. Despite knowledge of the folded state of rRNA in the ribosomal subunits, there is very little information on the rRNA folding pathway. We are interested in understanding how the functional structure of rRNA is formed and whether the rRNA folding intermediates have a role in ribosome assembly. To this end, transient secondary structures around both ends of pre-23S rRNA were analyzed by a chemical probing approach, using pre-23S rRNA transcripts. Metastable hairpin loop structures were found at both ends of 23S rRNA. The functional importance of the transient structures around the ends of 23S rRNA was tested by mutations that alter only the transient structure. The effect of mutations on 23S rRNA folding was tested in vitro and in vivo. It was found that both stabilization and destabilization of the transient structure around the 5' end of 23S rRNA inhibits post-transcriptional refolding in vitro and ribosome formation in vivo. The data suggest that the transient structure of rRNA has a function during 23S rRNA folding and thereby in ribosome assembly.

Effect of polyamines on the inhibition of peptidyltransferase by antibiotics: revisiting the mechanism of chloramphenicol action

Chloramphenicol is thought to interfere competitively with the binding of the aminoacyl-tRNA 3'-terminus to ribosomal A-site. However, noncompetitive or mixed-noncompetitive inhibition, often observed to be dependent on chloramphenicol concentration and ionic conditions, leaves some doubt about the precise mode of action. Here, we examine further the inhibition effect of chloramphenicol, using a model system derived from Escherichia coli in which a peptide bond is formed between puromycin and AcPhe-tRNA bound at the P-site of poly(U)-programmed ribosomes, under ionic conditions (6 mM Mg2+, 100 mM NH4+, 100 microM spermine) more closely resembling the physiological status. Kinetics reveal that chloramphenicol (I) reacts rapidly with AcPhe-tRNA.poly(U).70S ribosomal complex (C) to form the encounter complex CI which is then isomerized slowly to a more tight complex, C*I. A similar inhibition pattern is observed, if complex C modified by a photoreactive analogue of spermine, reacts in buffer free of spermine. Spermine, either reversibly interacting with or covalently attached to ribosomes, enhances the peptidyltransferase activity and increases the chloramphenicol potency, without affecting the isomerization step. As indicated by photoaffinity labeling, the peptidyltransferase center at which chloramphenicol binds, is one of the preferred cross-linking sites for polyamines. This fact may explain the effect of spermine on chloramphenicol binding to ribosomes.

Slow sequential conformational changes in Escherichia coli ribosomes induced by lincomycin: kinetic evidence

In a cell-free system derived from Escherichia coli, lincomycin produces biphasic logarithmic time plots for inhibition of peptide-bond formation when puromycin is used as an acceptor substrate and AcPhe-tRNA as a donor substrate. In a previous study, initial slope analysis of the logarithmic time plots revealed that the encounter complex CI between the initiator ribosomal complex (C) and lincomycin (I) undergoes a slow isomerization to C*I. During this change, the bound AcPhe-tRNA and lincomycin are rearranged to also accommodate puromycin, and this may account for the mixed noncompetitive inhibition (K(i)* = 70 microM) established at higher concentrations of the drug. The above-mentioned effect was further investigated by analyzing the late phase of the logarithmic time plots. It was found that C*I complex reacts with a second molecule of I, giving C*I(2) complex. However, the logarithmic time plots remain biphasic even at high concentrations of lincomycin, making possible the identification of another inhibition constant K(i)*', which is equal to 18 microM. The simplest explanation of this finding is to assume the existence of a second isomerization step C*I(2) <--> C*I(2'), slowly equilibrated. The determination of K(i)*' enables us to calculate the isomerization constant (K(isom) = 2.9) with the formula K(i)*' = K(i)*/(1 + K(isom)). Our results suggest that whenever a fast and reversible interaction of lincomycin with the elongating ribosomal complex C occurs, the latter undergoes a slow isomerization, which may be the result of conformational changes induced by the drug.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Multiple functions of the transcribed spacers in ribosomal RNA operons

rRNA operons contain about 25% transcribed spacer sequences in addition to the 16S, 23S, 5S and tRNA genes. The spacer sequences are removed from the primary rRNA transcript by a series of co-ordinated nucleolytic events. Besides the role in rRNA processing, the spacer sequences are also involved in transcription and the ribosome assembly. In this study we analyze the spacer between tRNA and 23S rRNA genes. Based on computer modeling and chemical probing data, a model for the transient secondary structure of the intergenic spacer is proposed. Mutational analysis has shown that the transient secondary structure around the 5' end of 23S rRNA is involved in ribosome assembly. We propose that the transient structure at the 5' end of 23S rRNA directs 23S rRNA folding into the mature structure and facilitates ribosomal large subunit assembly.

Base-pairing of 23 S rRNA ends is essential for ribosomal large subunit assembly

In ribosomal RNA precursors the spacer sequences bracketing mature 16 S and 23 S rRNA are base-paired to form long helices (processing stems). In pre-23 S rRNA, the processing stem is continued by eight base-pairs of mature 23 S rRNA known as helix 1. Recently, we have found that any part of 23 S rRNA between positions 40 and 2773 could be deleted without the loss of ribosome-like particle formation, while both end regions were indispensable. In this paper we have analyzed the role of the 5' and 3' end regions of 23 S rRNA during ribosomal 50 S assembly in vivo by using mutants of the 23 S rRNA gene. Deletions and substitutions in both strands of the helix 1 lead to the loss of plasmid derived 50 S formation. Compensatory mutations restoring helix 1 were assembled into functional 50 S subunits. We conclude that the helix 1 of 23 S rRNA is the main RNA determinant for ribosomal large-subunit assembly. Deletions in both the 5' and 3' strand of the processing stem reduced the ability of the 23 S rRNA to form ribosomal 50 S subunits. However, even the complete removal of either the 5' or the 3' strand of the processing stem did not abolish the 50 S assembly completely. Thus, processing stem facilitates, but is not essential for assembly.

Mutational analysis of the donor substrate binding site of the ribosomal peptidyltransferase center

Previous experiments have shown that the top of helix 90 of 23S rRNA is highly important for the ribosomal peptidyltransferase activity and might be part of the donor (P) site. Developing on these studies, mutations in the 23S rRNA at the highly conserved positions G2505, G2582, and G2583 were investigated. None of the mutations affected assembly, subunit association, or the capacity of tRNA binding to A and P sites. A "selective transpeptidation assay" revealed that the mutations specifically impaired peptide bond formation. Results with a modified "fragment" assay using the minimal donor substrate pA-fMet are consistent with a model where the nucleotides psiGG2582 form a binding pocket for C75 of the tRNA.

Mutational analysis of two highly conserved UGG sequences of 23 S rRNA from Escherichia coli

The 23 S-type rRNA contains two phylogenetically conserved UGG sequences, which have the potential to bind the universal CCA-3'-ends of tRNAs at the ribosomal peptidyltransferase center by base pairing. The first two positions, UG, of these sequences at the helix-loop 80 (U2249G2250) and helix-loop 90 (Psi2580G2581) and some related nucleotides were tested by site-directed mutagenesis for their involvement in ribosomal function, i.e. peptidyltransferase. The plasmid-derived mutated 23 S rRNA comprised about 50% of the total 23 S rRNA. None of the single mutations caused an assembly defect, and all 50 S subunits carrying an altered 23 S rRNA could freely exchange with the pools of 70S ribosomes and polysomes. The mutations at the helix-loop 80 region hardly affected bacterial growth. However, mutations at the helix 90 caused severe growth effects and severely impaired the in vitro protein synthesis, showing that this 23 S rRNA region is of high importance for ribosomal function.

Throwing a spanner in the works: antibiotics and the translation apparatus

The protein synthetic machinery is essential to all living cells and is one of the major targets for antibiotics. Knowledge of the structure and function of the ribosome and its associated factors is key to understanding the mechanism of drug action. Conversely, drugs have been used as tools to probe the translation cycle, thus providing a means to further our understanding of the steps that lead to protein synthesis. Our current understanding as to how antibiotics disrupt this process is reviewed here, with particular emphasis on the prokaryotic elongation cycle and those drugs that interact with ribosomal RNAs.

A functional peptide encoded in the Escherichia coli 23S rRNA

A pentapeptide open reading frame equipped with a canonical ribosome-binding site is present in the Escherichia coli 23S rRNA. Overexpression of 23S rRNA fragments containing the mini-gene renders cells resistant to the ribosome-inhibiting antibiotic erythromycin. Mutations that change either the initiator or stop codons of the peptide mini-gene result in the loss of erythromycin resistance. Nonsense mutations in the mini-gene also abolish erythromycin resistance, which can be restored in the presence of the suppressor tRNA, thus proving that expression of the rRNA-encoded peptide is essential for the resistance phenotype. The ribosome appears to be the likely target of action of the rRNA-encoded pentapeptide, because in vitro translation of the peptide mini-gene decreases the inhibitory action of erythromycin on cell-free protein synthesis. Thus, the new mechanism of drug resistance reveals that in addition to the structural and functional role of rRNA in the ribosome, it may also have a peptide-coding function.

Mutation of a highly conserved base in the yeast mitochondrial 21S rRNA restricts ribosomal frameshifting

A mutation shown to cause resistance to chloramphenicol in Saccharomyces cerevisiae was mapped to the central loop in domain V of the yeast mitochondrial 21S rRNA. The mutant 21S rRNA has a base pair exchange from U2677 (corresponding to U2504 in Escherichia coli) to C2677, which significantly reduces rightward frameshifting at a UU UUU UCC A site in a +1 U mutant. There is evidence to suggest that this reduction also applies to leftward frameshifting at the same site in a -1 U mutant. The mutation did not increase the rate of misreading of a number of mitochondrial missense, nonsense or frameshift (of both signs) mutations, and did not adversely affect the synthesis of wild-type mitochondrial gene products. It is suggested here that ribosomes bearing either the C2677 mutation or its wild-type allele may behave identically during normal decoding and only differ at sites where a ribosomal stall, by permitting non-standard decoding, differentially affects the normal interaction of tRNAs with the chloramphenicol resistant domain V. Chloramphenicol-resistant mutations mapping at two other sites in domain V are described. These mutations had no effect on frameshifting.

Clustering of pseudouridine residues around the peptidyltransferase center of yeast cytoplasmic and mitochondrial ribosomes

Analysis of the high molecular weight RNAs of the larger ribosomal subunit of Saccharomyces cerevisiae cytoplasm and mitochondria by a new method [Bakin, A., & Ofengand, J. (1993) Biochemistry 32, 9754-9762] has for the first time located all of the pseudouridine residues present in these two RNAs. Thirty pseudouridines were found in the cytoplasmic RNA, and one was found in the mitochondrial RNA. The 30 cytoplasmic RNA pseudouridines were clustered in three regions of the RNA known to be at or near the peptidyltransferase center. The single pseudouridine in yeast mitochondrial rRNA at position 2819 was also located at the peptidyltransferase center. The localization of pseudouridines at or near the peptidyltransferase center in both cytoplasmic and mitochondrial ribosomes implies a functional role for pseudouridine in peptide bond formation. A correlation was shown to exist between the locations of the pseudouridines determined in this work and the positions of the methylated nucleotides (both 2'-OCH3 and base-methylated) determined previously by others. In addition, this work has tentatively identified the locations of two previously unknown ribothymidine residues, at positions 955 and 2920 in the cytoplasmic rRNA.

Mutations in the peptidyl transferase region of E. coli 23S rRNA affecting translational accuracy

We have produced mutations in a cloned Escherichia coli 23S rRNA gene at positions G2252 and G2253. These sites are protected in chemical footprinting studies by the 3' terminal CCA of P site-bound tRNA. Three possible base changes were introduced at each position and the mutations produced a range of effects on growth rate and translational accuracy. Growth of cells bearing mutations at 2252 was severely compromised while the only mutation at 2253 causing a marked reduction in growth rate was a G to C transversion. Most of the mutations affected translational accuracy, causing increased readthrough of UGA, UAG and UAA nonsense mutations as well as +1 and -1 frameshifting in a lacZ reporter gene in vivo. C2253 was shown to act as a suppressor of a UGA nonsense mutation at codon 243 of the trpA gene. The C2253 mutation was also found not to interact with alleles of rpsL coding for restrictive forms of ribosomal protein S12. These results provide further evidence that nucleotides localized to the P site in the 50S ribosomal subunit influence the accuracy of decoding in the ribosomal A site.

Mutations at U2555, a tRNA-protected base in 23S rRNA, affect translational fidelity

A plasmid carrying a mutation in the highly conserved base U2555 in Escherichia coli 23S rRNA was isolated by selecting for suppression of the -1 frameshift mutation trpE91. U2555 is normally protected in chemical footprinting experiments by the aminoacyl residue of A-site-bound tRNA. Substitution of U2555 by adenine or guanine (but not by cytosine) increased readthrough of all three stop codons and +1 and -1 frameshifting. These effects on translational fidelity demonstrate the importance of U2555 for selection of the correct tRNA at the ribosomal A site.