The importance of conserved nucleotides of 23 S ribosomal RNA and transfer RNA in ribosome catalyzed peptide bond formation

Mutational characterization and mapping of the 70S ribosome active site

The synthetic capability of the Escherichia coli ribosome has attracted efforts to repurpose it for novel functions, such as the synthesis of polymers containing non-natural building blocks. However, efforts to repurpose ribosomes are limited by the lack of complete peptidyl transferase center (PTC) active site mutational analyses to inform design. To address this limitation, we leverage an in vitro ribosome synthesis platform to build and test every possible single nucleotide mutation within the PTC-ring, A-loop and P-loop, 180 total point mutations. These mutant ribosomes were characterized by assessing bulk protein synthesis kinetics, readthrough, assembly, and structure mapping. Despite the highly-conserved nature of the PTC, we found that >85% of the PTC nucleotides possess mutational flexibility. Our work represents a comprehensive single-point mutant characterization and mapping of the 70S ribosome's active site. We anticipate that it will facilitate structure-function relationships within the ribosome and make possible new synthetic biology applications.

The presence of highly disruptive 16S rRNA mutations in clinical samples indicates a wider role for mutations of the mitochondrial ribosome in human disease

Mitochondrial DNA mutations are well recognized as an important cause of disease, with over two hundred variants in the protein encoding and mt-tRNA genes associated with human disorders. In contrast, the two genes encoding the mitochondrial rRNAs (mt-rRNAs) have been studied in far less detail. This is because establishing the pathogenicity of mt-rRNA mutations is a major diagnostic challenge. Only two disease causing mutations have been identified at these loci, both mapping to the small subunit (SSU). On the large subunit (LSU), however, the evidence for the presence of pathogenic LSU mt-rRNA changes is particularly sparse. We have previously expanded the list of deleterious SSU mt-rRNA mutations by identifying highly disruptive base changes capable of blocking the activity of the mitoribosomal SSU. To do this, we used a new methodology named heterologous inferential analysis (HIA). The recent arrival of near-atomic-resolution structures of the human mitoribosomal LSU, has enhanced the power of our approach by permitting the analysis of the corresponding sites of mutation within their natural structural context. Here, we have used these tools to determine whether LSU mt-rRNA mutations found in the context of human disease and/or ageing could disrupt the function of the mitoribosomal LSU. Our results clearly show that, much like the for SSU mt-rRNA, LSU mt-rRNAs mutations capable of compromising the function of the mitoribosomal LSU are indeed present in clinical samples. Thus, our work constitutes an important contribution to an emerging view of the mitoribosome as an important element in human health.

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Identification of pathogenic mutations of mitochondrial rRNAs is problematic.

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We analysed 64 rare 16S rRNA mutations obtained from clinical samples.

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The mutations underwent heterologous inferential analysis (HIA).

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We show that highly disruptive 16S rRNA mutations are present in clinical samples.

Insights into the molecular determinants of EF-G catalyzed translocation

Translocation, the directional movement of transfer RNA (tRNA) and messenger RNA (mRNA) substrates on the ribosome during protein synthesis, is regulated by dynamic processes intrinsic to the translating particle. Using single-molecule fluorescence resonance energy transfer (smFRET) imaging, in combination with site-directed mutagenesis of the ribosome and tRNA substrates, we show that peptidyl-tRNA within the aminoacyl site of the bacterial pretranslocation complex can adopt distinct hybrid tRNA configurations resulting from uncoupled motions of the 3'-CCA terminus and the tRNA body. As expected for an on-path translocation intermediate, the hybrid configuration where both the 3'-CCA end and body of peptidyl-tRNA have moved in the direction of translocation exhibits dramatically enhanced puromycin reactivity, an increase in the rate at which EF-G engages the ribosome, and accelerated rates of translocation. These findings provide compelling evidence that the substrate for EF-G catalyzed translocation is an intermediate wherein the bodies of both tRNA substrates adopt hybrid positions within the translating ribosome.

Potential New Antibiotic Sites in the Ribosome Revealed by Deleterious Mutations in RNA of the Large Ribosomal Subunit

The ribosome is the main target for antibiotics that inhibit protein biosynthesis. Despite the chemical diversity of the known antibiotics that affect functions of the large ribosomal subunit, these drugs act on only a few sites corresponding to some of the known functional centers. We have used a genetic approach for identifying structurally and functionally critical sites in the ribosome that can be used as new antibiotic targets. By using randomly mutagenized rRNA genes, we mapped rRNA sites where nucleotide alterations impair the ribosome function or assembly and lead to a deleterious phenotype. A total of 77 single-point deleterious mutations were mapped in 23 S rRNA and ranked according to the severity of their deleterious phenotypes. Many of the mutations mapped to familiar functional sites that are targeted by known antibiotics. However, a number of mutations were located in previously unexplored regions. The distribution of the mutations in the spatial structure of the ribosome showed a strong bias, with the strongly deleterious mutations being mainly localized at the interface of the large subunit and the mild ones on the solvent side. Five sites where deleterious mutations tend to cluster within discrete rRNA elements were identified as potential new antibiotic targets. One of the sites, the conserved segment of helix 38, was studied in more detail. Although the ability of the mutant 50 S subunits to associate with 30 S subunits was impaired, the lethal effect of mutations in this rRNA element was unrelated to its function as an intersubunit bridge. Instead, mutations in this region had a profound deleterious effect on the ribosome assembly.

A conserved base-pair between tRNA and 23 S rRNA in the peptidyl transferase center is important for peptide release

The 3' terminus of tRNAs has the universally conserved bases C74C75A76 that interact with the ribosomal large subunit. In the ribosomal P site, bases C74 and C75 of tRNA, form Watson-Crick base-pairs with G2252 and G2251, respectively, present in the conserved P-loop of 23 S rRNA. Previous studies have suggested that the G2252-C74 base-pair is important for peptide bond formation. Using a pure population of mutant ribosomes, we analyzed the precise role of this base-pair in peptide bond formation, elongation factor G-dependent translocation, and peptide release by release factor 1. Surprisingly, our results show that the G2252-C74 base-pair is not essential for peptide bond formation with intact aminoacyl tRNAs as substrates and for EF-G catalyzed translocation. Interestingly, however, peptide release was reduced substantially when base-pair formation between G2252 and C74 of P site tRNA was disrupted, indicating that this conserved base-pair plays an important role in ester bond hydrolysis during translation termination.

The ribosomal peptidyl transferase center: structure, function, evolution, inhibition

The ribosomal peptidyl transferase center (PTC) resides in the large ribosomal subunit and catalyzes the two principal chemical reactions of protein synthesis: peptide bond formation and peptide release. The catalytic mechanisms employed and their inhibition by antibiotics have been in the focus of molecular and structural biologists for decades. With the elucidation of atomic structures of the large ribosomal subunit at the dawn of the new millennium, these questions gained a new level of molecular significance. The crystallographic structures compellingly confirmed that peptidyl transferase is an RNA enzyme. This places the ribosome on the list of naturally occurring ribozymes that outlived the transition from the pre-biotic RNA World to contemporary biology. Biochemical, genetic and structural evidence highlight the role of the ribosome as an entropic catalyst that accelerates peptide bond formation primarily by substrate positioning. At the same time, peptide release should more strongly depend on chemical catalysis likely involving an rRNA group of the PTC. The PTC is characterized by the most pronounced accumulation of universally conserved rRNA nucleotides in the entire ribosome. Thus, it came as a surprise that recent findings revealed an unexpected high level of variation in the mode of antibiotic binding to the PTC of ribosomes from different organisms.

Ribosome-DnaK interactions in relation to protein folding

Bacterial ribosomes or their 50S subunit can refold many unfolded proteins. The folding activity resides in domain V of 23S RNA of the 50S subunit. Here we show that ribosomes can also refold a denatured chaperone, DnaK, in vitro, and the activity may apply in the folding of nascent DnaK polypeptides in vivo. The chaperone was unusual as the native protein associated with the 50S subunit stably with a 1:1 stoichiometry in vitro. The binding site of the native protein appears to be different from the domain V of 23S RNA, the region with which denatured proteins interact. The DnaK binding influenced the protein folding activity of domain V modestly. Conversely, denatured protein binding to domain V led to dissociation of the native chaperone from the 50S subunit. DnaK thus appears to depend on ribosomes for its own folding, and upon folding, can rebind to ribosome to modulate its general protein folding activity.

Transit of tRNA through the Escherichia coli ribosome: cross-linking of the 3' end of tRNA to ribosomal proteins at the P and E sites

Photoreactive derivatives of yeast tRNA(Phe) containing 2-azidoadenosine at their 3' termini were used to trace the movement of tRNA across the 50S subunit during its transit from the P site to the E site of the 70S ribosome. When bound to the P site of poly(U)-programmed ribosomes, deacylated tRNA(Phe), Phe-tRNA(Phe) and N-acetyl-Phe-tRNA(Phe) probes labeled protein L27 and two main sites within domain V of the 23S RNA. In contrast, deacylated tRNA(Phe) bound to the E site in the presence of poly(U) labeled protein L33 and a single site within domain V of the 23S rRNA. In the absence of poly(U), the deacylated tRNA(Phe) probe also labeled protein L1. Cross-linking experiments with vacant 70S ribosomes revealed that deacylated tRNA enters the P site through the E site, progressively labeling proteins L1, L33 and, finally, L27. In the course of this process, tRNA passes through the intermediate P/E binding state. These findings suggest that the transit of tRNA from the P site to the E site involves the same interactions, but in reverse order. Moreover, our results indicate that the final release of deacylated tRNA from the ribosome is mediated by the F site, for which protein L1 serves as a marker. The results also show that the precise placement of the acceptor end of tRNA on the 50S subunit at the P and E sites is influenced in subtle ways both by the presence of aminoacyl or peptidyl moieties and, more surprisingly, by the environment of the anticodon on the 30S subunit.

Possible interaction sites of mRNA, tRNA, translation factors and the nascent peptide in 5S, 5.8S and 28S rRNA in in vivo assembled eukaryotic ribosomal complexes

We have investigated possible interaction sites for mRNA, tRNA, translation factors and the nascent peptide on 5S, 5.8S and 28S rRNA in in vivo assembled translational active mouse ribosomes by comparing the chemical footprinting patterns derived from native polysomes, salt-washed polysomes (mainly lacking translational factors) and salt-washed runoff ribosomes (lacking mRNA, tRNA and translational factors). Several ligand-induced footprints were observed in 28S rRNA while no reactivity changes were seen in 5S and 5.8S rRNA. Footprints derived from mRNA, tRNA and/or the nascent peptide chain were observed in domain I of 28S rRNA (hairpin 23), in domain II (helix 37/38 and helices 42 and 43 and in the eukaryotic expansion segment 15), in domain IV (helices 67 and 74) and in domain V (helices 94 and 96 and in the peptidyl transferase ring). Some of the protected sites were homologous to sites previously suggested to be involved in mRNA, tRNA and/or peptide binding in in vitro assembled prokaryotic complexes. Additional footprints were located in regions that have not previously been found involved in ligand binding. Part of these sites could derive from the nascent peptide in the exit channel of the ribosome.

A method for differentiating proteins from nucleic acids in intermediate-resolution density maps: cryo-electron microscopy defines the quaternary structure of the Escherichia coli 70S ribosome

BACKGROUND

This study addresses the general problem of dividing a density map of a nucleic-acid-protein complex obtained by cryo-electron microscopy (cryo-EM) or X-ray crystallography into its two components. When the resolution of the density map approaches approximately 3 A it is generally possible to interpret its shape (i. e., the envelope obtained for a standard choice of threshold) in terms of molecular structure, and assign protein and nucleic acid elements on the basis of their known sequences. The interpretation of low-resolution maps in terms of proteins and nucleic acid elements of known structure is of increasing importance in the study of large macromolecular complexes, but such analyses are difficult.

RESULTS

Here we show that it is possible to separate proteins from nucleic acids in a cryo-EM density map, even at 11.5 A resolution. This is achieved by analysing the (continuous-valued) densities using the difference in scattering density between protein and nucleic acids, the contiguity constraints that the image of any nucleic acid molecule must obey, and the knowledge of the molecular volumes of all proteins.

CONCLUSIONS

The new method, when applied to an 11.5 A cryo-EM map of the Escherichia coli 70S ribosome, reproduces boundary assignments between rRNA and proteins made from higher-resolution X-ray maps of the ribosomal subunits with a high degree of accuracy. Plausible predictions for the positions of as yet unassigned proteins and RNA components are also possible. One of the conclusions derived from this separation is that 23S rRNA is solely responsible for the catalysis of peptide bond formation. Application of the separation method to any nucleoprotein complex appears feasible.

Base-pairing between 23S rRNA and tRNA in the ribosomal A site

The aminoacyl (A site) tRNA analog 4-thio-dT-p-C-p-puromycin (s4TCPm) photochemically cross-links with high efficiency and specificity to G2553 of 23S rRNA and is peptidyl transferase reactive in its cross-linked state, establishing proximity between the highly conserved 2555 loop in domain V of 23S rRNA and the universally conserved CCA end of tRNA. To test for base-pairing interactions between 23S rRNA and aminoacyl tRNA, site-directed mutations were made at the universally conserved nucleotides U2552 and G2553 of 23S rRNA in both E. coli and B. stearothermophilus ribosomal RNA and incorporated into ribosomes. Mutations at G2553 resulted in dominant growth defects in E. coli and in decreased levels of peptidyl transferase activity in vitro. Genetic analysis in vitro of U2552 and G2553 mutant ribosomes and CCA end mutant tRNA substrates identified a base-pairing interaction between C75 of aminoacyl tRNA and G2553 of 23S rRNA.

Mutations in the conserved P loop perturb the conformation of two structural elements in the peptidyl transferase center of 23 S ribosomal RNA

Evidence is presented for the participation of the P loop (nucleotides G2250-C2254) of 23 S rRNA in establishing the tertiary structure of the peptidyl transferase center. Single base substitutions were introduced into the P loop, which participates in peptide bond formation through direct interaction with the CCA end of P site-bound tRNA. These mutations altered the pattern of reactivity of RNA to chemical probes in a structural subdomain encompassing the P loop and extending roughly from G2238 to A2433. Most of the effects on chemical modification in the P loop subdomain occurred near sites of tertiary interactions inferred from comparative sequence analysis, indicating that these mutations perturb the tertiary structure of this region of RNA. Changes in chemical modification were also seen in a subdomain composed of the 2530 loop (nucleotides G2529-A2534) and the A loop (nucleotides U2552-C2556), the latter a site of interaction with the CCA end of A site-bound tRNA. Mutations in the P loop induced effects on chemical modification that were commensurate with the severity of their characterized functional defects in peptide bond formation, tRNA binding and translational fidelity. These results indicate that, in addition to its direct role in peptide bond formation, the P loop contributes to the tertiary structure of the peptidyl transferase center and influences the conformation of both the acceptor and peptidyl tRNA binding sites.

Models of the elongation cycle: an evaluation

The central process for the transfer of the genetic information from the nucleic acid world into the structure of proteins is the ribosomal elongation cycle, where the sequence of codons is translated into the sequence of amino acids. The nascent polypeptide chain is elongated by one amino acid during the reactions of one cycle. Essentially, three models for the elongation cycle have been proposed. The allosteric three-site model and the hybrid-site model describe different aspects of tRNA binding and do not necessarily contradict each other. However, the alpha-epsilon model is not compatible with both models. The three models are evaluated in the light of recent results on the tRNA localization within the ribosome: the tRNAs of the elongating ribosome could be localized by two different techniques, viz. an advanced method of small-angle neutron scattering and cryo-electron microscopy. The best fit with the biochemical and structural data is obtained with the alpha-epsilon model.

23S rRNA positions essential for tRNA binding in ribosomal functional sites

rRNA plays an important role in function of peptidyl transferase, the catalytic center of the ribosome responsible for the peptide bond formation. Proper placement of the peptidyl transferase substrates, peptidyl-tRNA and aminoacyl-tRNA, is essential for catalysis of the transpeptidation reaction and protein synthesis. In this report, we define a small set of rRNA nucleotides that are most likely directly involved in binding of tRNA in the functional sites of the large ribosomal subunit. By binding biotinylated tRNA substrates to randomly modified large ribosomal subunits from Escherichia coli and capturing resulting complexes on the avidin resin, we identified four nucleotides in the large ribosomal subunit rRNA (positions G2252, A2451, U2506, and U2585) whose modifications prevent binding of a peptidyl-tRNA analog in the P site and one residue (U2555) whose modification interferes with transfer of peptidyl moiety to puromycin. These nucleotides represent a subset of positions protected by tRNA analogs from chemical modification and significantly narrow the number of 23S rRNA nucleotides that may be directly involved in tRNA binding in the ribosomal functional sites.

Structure of a conserved RNA component of the peptidyl transferase centre

The structure of a conserved hairpin loop involved in peptidyl-tRNA recognition by 50S ribosomal subunits has been solved by NMR. The loop is closed by a novel G-C base pair and presents guanine residues for RNA recognition.

Conserved nucleotides of 23 S rRNA located at the ribosomal peptidyltransferase center

Two nucleotides of the 23 S rRNA gene were mutated; the nucleotides correspond to the first two positions of the universally conserved sequence PsiGG2582 at the peptidyltransferase ring of 23 S rRNA. The ribosomes containing the altered 23 S rRNA were analyzed. Previously, it was shown that ribosomal assembly was indistinguishable from that in wild-type cells, that the flow of the corresponding 50 S subunit into the polysome fraction was not restricted, but that the ribosomes were strongly impaired in poly(Phe) synthesis (C. M. T. Spahn, J. Remme, M. A. Schäfer, and K. H. Nierhaus (1996) J. Biol. Chem. 271, 32849-32856). Here we apply assay systems exclusively testing the puromycin reaction of ribosomes carrying plasmid-born rRNA, a dipeptide assay using the minimal P site donor pA(fMet) and a translocation system not depending on the puromycin reaction. The mutations in helix 90 exclusively abolish or severely impair the ribosome capability to catalyze AcPhe-puromycin formation. A possible explanation of these observations is that G2581 and Psi2580 (and possibly also G2582) are part of the binding site of C75 of peptidyl-tRNA in the P site. The results suggest that in this case, however, such an interaction would disobey canonical base pairing.

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.

Genetic probes of ribosomal RNA function

We have used a genetic approach to uncover the functional roles of rRNA in protein synthesis. Mutations were constructed in a cloned rrn operon by site-directed mutagenesis or isolated by genetic selections following random mutagenesis. We have identified mutations that affect each step in the process of translation. The data are consistent with the results of biochemical and phylogenetic analyses but, in addition, have provided novel information on regions of rRNA not previously investigated.

A base pair between tRNA and 23S rRNA in the peptidyl transferase centre of the ribosome

Interaction of the conserved CCA terminus of tRNA with rRNA in the peptidyl transferase P site has been studied by in vitro genetics. A watson-Crick G-C pair between G2252 in a conserved hairpin loop of 23S rRNA and C74 at the acceptor end of tRNA is required for proper functional interaction of the CCA end of tRNA with the ribosomal P site. These findings establish a direct role for 23S rRNA in protein synthesis.