Mapping the path of the nascent peptide chain through the 23S RNA in the 50S ribosomal subunit.

Peptides of different lengths encoded by suitable mRNA fragments were biosynthesized in situ on Escherichia coli ribosomes. The peptides carried a diazirine derivative bound to their N-terminal methionine residue, which was photoactivated whilst the peptides were still attached to the ribosome. Subsequently, the sites of photo-cross-linking to 23S RNA were analyzed by our standard procedures. The N-termini of peptides of increasing length became progressively cross-linked to nucleotide 750 (peptides of 6, 9 or 13-15 amino acids), to nucleotide 1614 and concomitantly to a second site between nucleotides 1305 and 1350 (a peptide of 25-26 amino acids), and to nucleotide 91 (a peptide of 29-33 amino acids). Previously we had shown that peptides of 1 or 2 amino acids were cross-linked to nucleotides 2062, 2506 and 2585 within the peptidyl transferase ring, whereas tri-and tetrapeptides were additionally cross-linked to nucleotides 2609 and 1781. Taken together, the data demonstrate that the path of the nascent peptide chain moves from the peptidyl transferase ring in domain V of the 23S RNA to domain IV, then to domain II, then to domain III, and finally to domain I. These cross-linking results are correlated with other types of topographical data relating to the 50S subunit.     

Ribosome origins: The relative age of 23S rRNA Domains

The modern ribosome and its component RNAs are quite large and it is likely that at an earlier time they were much smaller. Hence, not all regions of the modern ribosomal RNAs (rRNA) are likely to be equally old. In the work described here, it is hypothesized that the oldest regions of the RNAs will usually be highly integrated into the machinery. When this is the case, an examination of the interconnectivity between local RNA regions can provide insight to the relative age of the various regions. Herein, we describe an analysis of all known long-range RNA/RNA interactions within the 23S rRNA and between the 23S rRNA and the 16S rRNA in order to assess the interconnectivity between the usual Domains as defined by secondary structure. Domain V, which contains the peptidyl transferase center is centrally located, extensively connected, and therefore likely to be the oldest region. Domain IV and Domain II are extensively interconnected with both themselves and Domain V. A portion of Domain IV is also extensively connected with the 30S subunit and hence Domain IV may be older than Domain II. These results are consistent with other evidence relating to the relative age of RNA regions. Although the relative time of addition of the GTPase center can not be reliably deduced it is pointed out that the development of this may have dramatically affected the progenotes that preceded the last common ancestor.     

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.     

Trial for peptide bond formation using model molecules based on the interactions between the CCA sequence of tRNA and 23S rRNA.

The peptidyl transfer reaction catalyzed by the ribosome is a sophisticated product of evolution. The molecular mechanism of peptide bond formation has not been fully elucidated although the essential involvement of 23S rRNA has been established. The universal CCA sequence at the 3'-end of tRNA plays an important role in this process, by interacting with specific nucleotides in 23S rRNA. However, reconstitution of peptidyl transferase activity by a naked 23S rRNA (without the help of any of the ribosomal proteins) has not been reported. To investigate the possible evolutionary development of the peptidyl transfer reaction, we tried to obtain peptide bond formation using a piece of tRNA--an aminoacyl-minihelix--mixed with sequence-specific oligonucleotides that contained puromycin. This system reproduced conceptually the equivalent interactions between the CCA trinucleotide of tRNA and 23S rRNA. Peptide bond formation was detected by gel electrophoresis, TLC and mass spectrometry. These results have implications for the evolution of the peptidyl transfer reaction in biological system.     

Peptidyl transferase antibiotics perturb the relative positioning of the 3'-terminal adenosine of P/P'-site-bound tRNA and 23S rRNA in the ribosome.

A range of antibiotic inhibitors that act within the peptidyl transferase center of the ribosome were examined for their capacity to perturb the relative positioning of the 3' end of P/P'-site-bound tRNA and the Escherichia coli ribosome. The 3'-terminal adenosines of deacylated tRNA and N-Ac-Phe-tRNA were derivatized at the 2 position with an azido group and the tRNAs were cross-linked to the ribosome on irradiation with ultraviolet light at 365 nm. The cross-links were localized on the rRNA within extended versions of three previously characterized 23S rRNA fragments F1', F2', and F4' at nucleotides C2601/A2602, U2584/U2585 (F1'), U2506 (F2'), and A2062/C2063 (F4'). Each of these nucleotides lies within the peptidyl transferase loop region of the 23S rRNA. Cross-links were also formed with ribosomal proteins L27 (strong) and L33 (weak), as shown earlier. The antibiotics sparsomycin, chloramphenicol, the streptogramins pristinamycin IA and IIA, gougerotin, lincomycin, and spiramycin were tested for their capacity to alter the identities or yields of each of the cross-links. Although no new cross-links were detected, each of the drugs produced major changes in cross-linking yields, mainly decreases, at one or more rRNA sites but, with the exception of chloramphenicol, did not affect cross-linking to the ribosomal proteins. Moreover, the effects were closely similar for both deacylated and N-Ac-Phe-tRNAs, indicating that the drugs selectively perturb the 3' terminus of the tRNA. The strongest decreases in the rRNA cross-links were observed with pristinamycin IIA and chloramphenicol, which correlates with their both producing complex chemical footprints on 23S rRNA within E. coli ribosomes. Furthermore, gougerotin and pristinamycin IA strongly increased the yields of fragments F2' (U2506) and F4' (U2062/C2063), respectively. The results obtained with an RNAse H approach correlate well with primer extension data implying that cross-linking occurs primarily to the bases. Both sets of data are also consistent with the results of earlier rRNA footprinting experiments on antibiotic-ribosome complexes. It is concluded that the antibiotics perturb the relative positioning of the 3' end of the P/P'-site-bound tRNA and the peptidyl transferase loop region of 23S rRNA.     

Contacts between the growing peptide chain and the 23S RNA in the 50S ribosomal subunit.

Peptides of defined length carrying a diazirine photoaffinity label attached either to the alpha-NH2 group of the N-terminal methionine residue, or to the epsilon-NH2 group of an immediately adjacent lysine residue, were prepared in situ on Escherichia coli ribosomes in the presence of a synthetic mRNA analogue. Peptide growth was stopped simply by withholding the aminoacyl-tRNA cognate to an appropriate downstream codon. After photo-activation at 350 nm the sites of cross-linking to ribosomal RNA were determined by our standard procedures; the C-terminal amino acid of each peptide was labelled with tritium, in order to confirm whether the individual cross-linked complexes contained the expected 'full-length' peptide, as opposed to shorter products. The shortest peptides became cross-linked to sites within the 'peptidyl transferase ring' of the 23S RNA, namely to positions 2062, 2506, 2585 and 2609. However, already when the peptide was three or four residues long, a new cross-link was observed several hundred nucleotides away in another secondary structural domain; this site, at position 1781, lies within one of several RNA regions which have been implicated in other studies as being located close to the peptidyl transferase ring. Further application of this approach, combined with model-building studies, should enable the path of the nascent peptide through the large ribosomal subunit to be definitively mapped.     

Leader peptides of inducible chloramphenicol resistance genes from gram-positive and gram-negative bacteria bind to yeast and Archaea large subunit rRNA.

catA86 is the second gene in a constitutively transcribed, two-gene operon cloned from Bacillus pumilus . The region that intervenes between the upstream gene, termed the leader, and the catA86 coding sequence contains a pair of inverted repeat sequences which cause sequestration of the catA86 ribosome binding site in mRNA secondary structure. As a consequence, the catA86 coding sequence is untranslatable in the absence of inducer. Translation of the catA86 coding sequence is induced by chloramphenicol in Gram-positives and induction requires a function of the leader coding sequence. The leader-encoded peptide has been proposed to instruct its translating ribosome to pause at leader codon 6, enabling chloramphenicol to stall the ribosome at that site. Ribosome stalling causes destabilization of the RNA secondary structure, exposing the catA86 ribosome binding site, allowing activation of its translation. A comparable mechanism of induction by chloramphenicol has been proposed for the regulated cmlA gene from Gram-negative bacteria. The catA86 and cmlA leader-encoded peptides are in vitro inhibitors of peptidyl transferase, which is thought to be the basis for selection of the site of ribosome stalling. Both leader-encoded peptides have been shown to alter the secondary structure of Escherichia coli 23S rRNA in vitro. All peptide-induced changes in rRNA conformation are within domains IV and V, which contains the peptidyl transferase center. Here we demonstrate that the leader peptides alter the conformation of domains IV and V of large subunit rRNA from yeast and a representative of the Archaea. The rRNA target for binding the leader peptides is therefore conserved across kingdoms.     

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.     

Importance of tRNA interactions with 23S rRNA for peptide bond formation on the ribosome: studies with substrate analogs

The major enzymatic activity of the ribosome is the catalysis of peptide bond formation. The active site -- the peptidyl transferase center -- is composed of ribosomal RNA (rRNA), and interactions between rRNA and the reactants, peptidyl-tRNA and aminoacyl-tRNA, are crucial for the reaction to proceed rapidly and efficiently. Here, we describe the influence of rRNA interactions with cytidine residues in A-site substrate analogs (C-puromycin or CC-puromycin), mimicking C74 and C75 of tRNA on the reaction. Base-pairing of C75 with G2553 of 23S rRNA accelerates peptide bond formation, presumably by stabilizing the peptidyl transferase center in its productive conformation. When C74 is also present in the substrate analog, the reaction is slowed down considerably, indicating a slow step in substrate binding to the active site, which limits the reaction rate. The tRNA-rRNA interactions lead to a robust reaction that is insensitive to pH changes or base substitutions in 23S rRNA at the active site of the ribosome.     

Inhibition of the ribosomal peptidyl transferase reaction by the mycarose moiety of the antibiotics carbomycin, spiramycin and tylosin

Many antibiotics, including the macrolides, inhibit protein synthesis by binding to ribosomes. Only some of the macrolides affect the peptidyl transferase reaction. The 16-member ring macrolide antibiotics carbomycin, spiramycin, and tylosin inhibit peptidyl transferase. All these have a disaccharide at position 5 in the lactone ring with a mycarose moiety. We have investigated the functional role of this mycarose moiety. The 14-member ring macrolide erythromycin and the 16-member ring macrolides desmycosin and chalcomycin do not inhibit the peptidyl transferase reaction. These drugs have a monosaccharide at position 5 in the lactone ring. The presence of mycarose was correlated with inhibition of peptidyl transferase, footprints on 23 S rRNA and whether the macrolide can compete with binding of hygromycin A to the ribosome. The binding sites of the macrolides to Escherichia coli ribosomes were investigated by chemical probing of domains II and V of 23 S rRNA. The common binding site is around position A2058, while effects on U2506 depend on the presence of the mycarose sugar. Also, protection at position A752 indicates that a mycinose moiety at position 14 in 16-member ring macrolides interact with hairpin 35 in domain II. Competitive footprinting of ribosomal binding of hygromycin A and macrolides showed that tylosin and spiramycin reduce the hygromycin A protections of nucleotides in 23 S rRNA and that carbomycin abolishes its binding. In contrast, the macrolides that do not inhibit the peptidyl transferase reaction bind to the ribosomes concurrently with hygromycin A. Data are presented to argue that a disaccharide at position 5 in the lactone ring of macrolides is essential for inhibition of peptide bond formation and that the mycarose moiety is placed near the conserved U2506 in the central loop region of domain V 23 S rRNA.     

The pleuromutilin drugs tiamulin and valnemulin bind to the RNA at the peptidyl transferase centre on the ribosome

The pleuromutilin antibiotic derivatives, tiamulin and valnemulin, inhibit protein synthesis by binding to the 50S ribosomal subunit of bacteria. The action and binding site of tiamulin and valnemulin was further characterized on Escherichia coli ribosomes. It was revealed that these drugs are strong inhibitors of peptidyl transferase and interact with domain V of 23S RNA, giving clear chemical footprints at nucleotides A2058-9, U2506 and U2584-5. Most of these nucleotides are highly conserved phylogenetically and functionally important, and all of them are at or near the peptidyl transferase centre and have been associated with binding of several antibiotics. Competitive footprinting shows that tiamulin and valnemulin can bind concurrently with the macrolide erythromycin but compete with the macrolide carbomycin, which is a peptidyl transferase inhibitor. We infer from these and previous results that tiamulin and valnemulin interact with the rRNA in the peptidyl transferase slot on the ribosomes in which they prevent the correct positioning of the CCA-ends of tRNAs for peptide transfer.     

Rapid peptide bond formation on isolated 50S ribosomal subunits

The catalytic site of the ribosome, the peptidyl transferase centre, is located on the large (50S in bacteria) ribosomal subunit. On the basis of results obtained with small substrate analogues, isolated 50S subunits seem to be less active in peptide bond formation than 70S ribosomes by several orders of magnitude, suggesting that the reaction mechanisms on 50S subunits and 70S ribosomes may be different. Here we show that with full-size fMet-tRNA(fMet) and puromycin or C-puromycin as peptide donor and acceptor substrates, respectively, the reaction proceeds as rapidly on 50S subunits as on 70S ribosomes, indicating that the intrinsic activity of 50S subunits is not different from that of 70S ribosomes. The faster reaction on 50S subunits with fMet-tRNA(fMet), compared with oligonucleotide substrate analogues, suggests that full-size transfer RNA in the P site is important for maintaining the active conformation of the peptidyl transferase centre.     

Effect of antibiotics on large ribosomal subunit assembly reveals possible function of 5 S rRNA.

Functional large ribosomal subunits of Thermus aquaticus can be reconstituted from ribosomal proteins and either natural or in vitro transcribed 23 S and 5 S rRNA. Omission of 5 S rRNA during subunit reconstitution results in dramatic decrease of the peptidyl transferase activity of the assembled subunits. However, the presence of some ribosome-targeted antibiotics of the macrolide, ketolide or streptogramin B groups during 50 S subunit reconstitution can partly restore the activity of ribosomal subunits assembled without 5 S rRNA. Among tested antibiotics, macrolide RU69874 was the most active: activity of the subunits assembled in the absence of 5 S rRNA was increased more than 30-fold if antibiotic was present during reconstitution procedure. Activity of the subunits assembled with 5 S rRNA was also slightly stimulated by RU69874, but to a much lesser extent, approximately 1.5-fold. Activity of the native T. aquaticus 50 S subunits incubated in the reconstitution conditions in the presence of RU69874 was, in contrast, slightly decreased. The presence of antibiotics was essential during the last incubation step of the in vitro assembly, indicating that drugs affect one of the last assembly steps. The 5 S rRNA was previously shown to form contacts with segments of domains II and V of 23 S rRNA. All the antibiotics which can functionally compensate for the lack of 5 S rRNA during subunit reconstitution interact simultaneously with the central loop in domain V (which is known to be a component of peptidyl transferase center) and a loop of the helix 35 in domain II of 23 S rRNA. It is proposed that simultaneous interaction of 5 S rRNA or of antibiotics with the two domains of 23 S rRNA is essential for the successful assembly of ribosomal peptidyl transferase center. Consequently, one of the functions of 5 S rRNA in the ribosome can be that of assisting the assembly of ribosomal peptidyl transferase by correctly positioning functionally important segments of domains II and V of 23 S rRNA.     

MRM2 encodes a novel yeast mitochondrial 21S rRNA methyltransferase

Mitochondria of the yeast Saccharomyces cerevisiae assemble their ribosomes from ribosomal proteins, encoded by the nuclear genome (with one exception), and rRNAs of 15S and 21S, encoded by the mitochondrial genome. Unlike cytoplasmic rRNA, which is highly modified, mitochondrial rRNA contains only three modified nucleotides: a pseudouridine (Psi(2918)) and two 2'-O-methylated riboses (Gm(2270) and Um(2791)) located at the peptidyl transferase centre of 21S rRNA. We demonstrate here that the yeast nuclear genome encodes a mitochondrial protein, named Mrm2, which is required for methylating U(2791) of 21S rRNA, both in vivo and in vitro. Deletion of the MRM2 gene causes thermosensitive respiration and leads to rapid loss of mitochondrial DNA. We propose that Mrm2p belongs to a new class of three eukaryotic RNA-modifying enzymes and is the orthologue of FtsJ/RrmJ, which methylates a nucleotide of the peptidyl transferase centre of Escherichia coli 23S rRNA that is homologous to U(2791) of 21S rRNA. Our data suggest that this universally conserved modified nucleotide plays an important function in vivo, possibly by inducing conformational rearrangement of the peptidyl transferase centre.     

The critical role of the universally conserved A2602 of 23S ribosomal RNA in the release of the nascent peptide during translation termination

The ribosomal peptidyl transferase center is responsible for two fundamental reactions, peptide bond formation and nascent peptide release, during the elongation and termination phases of protein synthesis, respectively. We used in vitro genetics to investigate the functional importance of conserved 23S rRNA nucleotides located in the peptidyl transferase active site for transpeptidation and peptidyl-tRNA hydrolysis. While mutations at A2451, U2585, and C2063 (E. coli numbering) did not significantly affect either of the reactions, substitution of A2602 with C or its deletion abolished the ribosome ability to promote peptide release but had little effect on transpeptidation. This indicates that the mechanism of peptide release is distinct from that of peptide bond formation, with A2602 playing a critical role in peptide release during translation termination.     

Changes in the conformation of 5S rRNA cause alterations in principal functions of the ribosomal nanomachine

5S rRNA is an integral component of the large ribosomal subunit in virtually all living organisms. Polyamine binding to 5S rRNA was investigated by cross-linking of N¹-azidobenzamidino (ABA)-spermine to naked 5S rRNA or 50S ribosomal subunits and whole ribosomes from Escherichia coli cells. ABA-spermine cross-linking sites were kinetically measured and their positions in 5S rRNA were localized by primer extension analysis. Helices III and V, and loops A, C, D and E in naked 5S rRNA were found to be preferred polyamine binding sites. When 50S ribosomal subunits or poly(U)-programmed 70S ribosomes bearing tRNA^Phe at the E-site and AcPhe-tRNA at the P-site were targeted, the susceptibility of 5S rRNA to ABA-spermine was greatly reduced. Regardless of 5S rRNA assembly status, binding of spermine induced significant changes in the 5S rRNA conformation; loop A adopted an apparent ‘loosening’ of its structure, while loops C, D, E and helices III and V achieved a more compact folding. Poly(U)-programmed 70S ribosomes possessing 5S rRNA cross-linked with spermine were more efficient than control ribosomes in tRNA binding, peptidyl transferase activity and translocation. Our results support the notion that 5S rRNA serves as a signal transducer between regions of 23S rRNA responsible for principal ribosomal functions.     

Toward Ribosomal RNA Catalytic Activity in the Absence of Protein

The ribosome is the ribonucleoprotein particle responsible for translation of genetic information into proteins. The RNA component of the ribosome has been implicated as the catalytic entity for peptide bond formation based on protease resistance and structural data indicating an all-RNA active site. Nevertheless, peptidyl transfer by ribosomal RNA (rRNA) alone has not been demonstrated. In an attempt to show such activity we generated a minimal construct that comprises much of the 23S rRNA peptidyl transferase center, including the central loop and the A- and P-loops. This minimal rRNA domain was inactive in peptide bond formation under all conditions tested. The RNA was subsequently subjected to six rounds of in vitro selection designed to enrich for this activity. The result was a mutated rRNA sequence that could catalyze the covalent linkage of an A-site and P-site substrate; however, the product did not contain a peptide bond. The current study is an example of an in vitro derived alternate function of rRNA mutants and illustrates the evolutionary possibility that the protoribosome may have used amino acids as substrates before it gained the ability to join them into peptides. Though peptidyl transferase activity in the absence of protein remains elusive, the ease with which alternate catalytic activity was selected from rRNA with a small number of mutations suggests that rRNA may have inherent activity. This study represents a step on the path toward isolating that native activity. Electronic Supplementary Material The online version of this article (doi:) contains supplementary material, which is available to authorized users. [Reviewing Editor: Dr. Niles Lehman]