Monoclonal antibodies to epitopes in both C-terminal and N-terminal domains of Escherichia coli ribosomal protein L7/L12 inhibit elongation factor binding but not peptidyl transferase activity

Two monoclonal antibodies against different epitopes in Escherichia coli ribosomal protein L7/L12, one within residues 74-120 and the other within residues 1-73, shown before to inhibit the binding of EF-G, have been tested for their effects on the binding to E. coli ribosomes of EF-Tu-aminoacyl-tRNA-GTP ternary complex and on peptidyl transferase activity. Both antibodies inhibit the binding of ternary complex and EF-Tu-dependent GTPase but have no inhibitory effect on peptidyl transferase activity. The inhibition of binding of both elongation factors is indicative of overlapping binding sites for EF-G and EF-Tu. The inhibition by both antibodies implies the contribution of both domains of L7/L12 to this binding site. This implies the location of one or more of the C-terminal domains of L7/L12 on the body of the 50S subunit. The absence of any inhibition of peptidyl transferase activity shows distinct separation of this site from the factor binding site.     

Differential localization of two epitopes of Escherichia coli ribosomal protein L2 on the large ribosomal subunit by immune electron microscopy using monoclonal antibodies.

Two monoclonal antibodies (mAb), directed toward different epitopes of Escherichia coli ribosomal protein L2, have been used as probes in immune electron microscopy. mAb 5-186 recognizes an epitope within residues 5-186 of protein L2; it is seen to bind to 50 S subunits at or near the peptidyl transferase center, beside the subunit head on the L1 shoulder. mAb 187-272 recognizes an epitope within residues 187-272. This antibody binds to the face of the 50 S subunit, below the head and slightly toward the side with the stalk; this site is near the translocation domain. Both antibodies can bind simultaneously to single subunits. This indicates that protein L2 is elongated, reaching from the peptidyl transferase center to below the subunit head and approaching the translocational domain. The different locations of the two epitopes are consistent with previous biochemical results with the two antibodies (Nag, B., Tewari, D. S., Etchison, J. R., Sommer, A., and Traut, R. R. (1986) J. Biol. Chem. 261, 13892-13897).     

The binding site for ribosomal protein L2 within 23S ribosomal RNA of Escherichia coli.

Ribosomal protein L2 from Escherichia coli binds to and protects from nuclease digestion a substantial portion of 'domain IV' of 23S rRNA. In particular, oligonucleotides derived from the sequence 1757-1935 were isolated and shown to rebind specifically to protein L2 in vitro. Other L2-protected oligonucleotides, also derived from domain IV (i.e. from residues 1955-2010) did not rebind to protein L2 in vitro nor did others derived from domain I. Given that protein L2 is widely believed to be located in the peptidyl transferase centre of the 50S ribosomal subunit, these data suggest that domain IV of 23S rRNA is also present in that active site of the ribosomal enzyme.     

Modification of histidine residues on proteins from the 50S subunit of the Escherichia coli ribosome. Effects on subunit assembly and peptidyl transferase centre activity.

L2, L3, L4, L16 and L20 are proteins of the 50S ribosomal subunit of Escherichia coli which are essential for the assembly and activity of the peptidyl transferase centre. These proteins have been modified with the histidine-specific reagent, diethylpyrocarbonate, while L17 and L18 were treated as controls. Each modified protein tested was able to participate in the reconstitution of a 50S particle when replacing its normal counterpart, although the particles assembled with modified L2 were heterogeneous. However, although they could support assembly, modified L16 and L20 were not themselves reconstituted stably, and modified L2 and L3 were found in less than stoichiometric amounts. Particles assembled in the presence of modified L16 retained significant peptidyl transferase activity (60-70% at 10 mM diethylpyrocarbonate) whereas those reconstituted with modified L2, L3, L4 or L20 had low activity (10-30% at 10 mM diethylpyrocarbonate). The particles assembled with the modified control protein, L17, retained 80% of their peptidyl transferase activity under the same conditions. The histidine residues within the essential proteins therefore contribute to ribosome structure and function in three significant ways; in the correct assembly of the ribosomal subunit (L2), for the stable assembly of the proteins within the ribosomal particle (L20 and L16 in particular), and directly or indirectly for the subsequent activity of the peptidyl transferase centre (L2, L3, L4 and L20). The essential nature of the unmodified histidines for assembly events precludes the use of the chemical-modification strategy to test the proposal that a histidine on one of the proteins might participate in the catalytic activity of the centre.     

Phosphorylation of ribosomal proteins influences subunit association and translation of poly (U) in Streptomyces coelicolor

The occurrence of phosphorylated proteins in ribosomes of Streptomyces coelicolor was investigated. Little is known about which biological functions these posttranslational modifications might fulfil. A protein kinase associated with ribosomes phosphorylated six ribosomal proteins of the small subunit (S3, S4, S12, S13, S14 and S18) and seven ribosomal proteins of the large subunit (L2, L3, L7/L12, L16, L17, L23 and L27). The ribosomal proteins were phosphorylated mainly on the Ser/Thr residues. Phosphorylation of the ribosomal proteins influences ribosomal subunits association. Ribosomes with phosphorylated proteins were used to examine poly (U) translation activity. Phosphorylation induced about 50% decrease in polyphenylalanine synthesis. After preincubation of ribosomes with alkaline phosphatase the activity of ribosomes was greatly restored. Small differences were observed between phosphorylated and unphosphorylated ribosomes in the kinetic parameters of the binding of Phe-tRNA to the A-site of poly (U) programmed ribosomes, suggesting that the initial binding of Phe-tRNA is not significantly affected by phosphorylation. On contrary, the rate of peptidyl transferase was about two-fold lower than that in unphosphorylated ribosomes. The data presented demonstrate that phosphorylation of ribosomal proteins affects critical steps of protein synthesis.     

The interaction of ribosomal protein L16 and its fragments with tRNA

Two large proteolytic fragments of Escherichia coli 50 S ribosomal subunit protein L16 were generated by limited hydrolysis with chymotrypsin (missing 9 N-terminal amino acids) and trypsin (missing 16 N-terminal amino acids). It was found that while intact L16 and its chymotryptic fragment both interact with tRNA (Kd = 5.4 x 10(-7) M), the tryptic fragment does not. These results are interpreted in terms of possible significance of the residues 10-16 in the peptidyl transferase activity.     

Identification of 50S components neighboring 23S rRNA nucleotides A2448 and U2604 within the peptidyl transferase center of Escherichia coli ribosomes

The 23S rRNA nucleotides 2604-12 and 2448-58 fall within the central loop of domain V, which forms a major part of the peptidyl transferase center of the ribosome. We report the synthesis of radioactive, photolabile 2'-O-methyloligoRNAs, PHONTs 1 and 2, complementary to these nucleotides and their exploitation in identifying 50S ribosomal subunit components neighboring their target sites. Photolysis of the 50S complex with PHONT 1, complementary to nts 2604-12, leads to target site-specific photoincorporation into protein L2 and 23S rRNA nucleotides A886, Alpha1918, A1919, G1922-C1924, U2563, U2586, and C2601. Photolysis of the 50S complex with PHONT 2, complementary to nts 2448-58, leads to target site-specific probe photoincorporation into proteins L2, L3, one or more of proteins L17, L18, L21, and of proteins L9, L15, L16, and 23S rRNA nucleotides C2456 and psi2457. Chemical footprinting studies show that 2'-O-methyloligoRNA binding causes little distortion of the peptidyl transferase center but do provide suggestive evidence for the location of flexible regions within 23S rRNA. The significance of these results for the structure of the peptidyl transferase center is considered.     

Placement of the alpha-sarcin loop within the 50S subunit: evidence derived using a photolabile oligodeoxynucleotide probe.

We report the synthesis of a radioactive, photolabile oligodeoxyribonucleotide probe and its exploitation in identifying 50S ribosomal subunit components neighboring the alpha-sarcin loop. The probe is complementary to 23S rRNA nt 2653-2674. Photolysis of the complex formed between the probe and 50S subunits leads to site-specific probe photoincorporation into proteins L2, the most highly labeled protein, L1, L15, L16 and L27, labeled to intermediate extents, and L5, L9, L17 and L24, each labeled to a minor extent. Portions of each of these proteins thus lie within 23 A of nt U2653. These results lead us to conclude that the alpha-sarcin loop is located at the base of the L1 projection within the 50S subunit. Such placement, near the peptidyl transferase center, provides a rationale for the extreme sensitivity of ribosomal function to cleavage of the alpha-sarcin loop.     

Mutations in ribosomal protein L3 and 23S ribosomal RNA at the peptidyl transferase centre are associated with reduced susceptibility to tiamulin in Brachyspira spp. isolates

The pleuromutilin antibiotic tiamulin binds to the ribosomal peptidyl transferase centre. Three groups of Brachyspira spp. isolates with reduced tiamulin susceptibility were analysed to define resistance mechanisms to the drug. Mutations were identified in genes encoding ribosomal protein L3 and 23S rRNA at positions proximal to the peptidyl transferase centre. In two groups of laboratory-selected mutants, mutations were found at nucleotide positions 2032, 2055, 2447, 2499, 2504 and 2572 of 23S rRNA (Escherichia coli numbering) and at amino acid positions 148 and 149 of ribosomal protein L3 (Brachyspira pilosicoli numbering). In a third group of clinical B. hyodysenteriae isolates, only a single mutation at amino acid 148 of ribosomal protein L3 was detected. Chemical footprinting experiments show a reduced binding of tiamulin to ribosomal subunits from mutants with decreased susceptibility to the drug. This reduction in drug binding is likely the resistance mechanism for these strains. Hence, the identified mutations located near the tiamulin binding site are predicted to be responsible for the resistance phenotype. The positions of the mutated residues relative to the bound drug advocate a model where the mutations affect tiamulin binding indirectly through perturbation of nucleotide U2504.     

Reconstitution of Escherichia coli 50S ribosomal subunits containing puromycin-modified L23: functional consequences

In previous work we have shown that both puromycin [Weitzmann, C. J., & Cooperman, B. S. (1985) Biochemistry 24, 2268-2274] and p-azidopuromycin [Nicholson, A. W., Hall, C. C., Strycharz, W. A., & Coooperman, B. S. (1982) Biochemistry 21, 3809-3817] site specifically photoaffinity label protein L23 to the highest extent of any Escherichia coli ribosomal protein. In this work we demonstrate that L23 that has been photoaffinity labeled within a 70S ribosome by puromycin (puromycin-L23) can be separated from unmodified L23 by reverse-phase high-performance liquid chromatography (RP-HPLC) and further that puromycin-L23 can reconstitute into 50S subunits when added in place of unmodified L23 to a reconstitution mixture containing the other 50S components in unmodified form. We have achieved a maximum incorporation of 0.5 puromycin-L23 per reconstituted 50S subunit. As compared with reconstituted 50S subunits either containing unmodified L23 or lacking L23, reconstituted 50S subunits containing 0.4-0.5 puromycin-L23 retain virtually all (albeit low) peptidyl transferase activity but only 50-60% of mRNA-dependent tRNA binding stimulation activity. We conclude that although L23 is not directly at the peptidyl transferase center, it is sufficiently close that puromycin-L23 can interfere with tRNA binding. This conclusion is consistent with a number of other experiments placing L23 close to the peptidyl transferase center but is difficult to reconcile with immunoelectron microscopy results placing L23 near the base of the 50S subunit on the side facing away from the 30S subunit [Hackl, W., & St?ffler-Meilicke, M. (1988) Eur. J. Biochem. 174, 431-435].     

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.     

High resolution structure of the large ribosomal subunit from a mesophilic eubacterium.

We describe the high resolution structure of the large ribosomal subunit from Deinococcus radiodurans (D50S), a gram-positive mesophile suitable for binding of antibiotics and functionally relevant ligands. The over-all structure of D50S is similar to that from the archae bacterium Haloarcula marismortui (H50S); however, a detailed comparison revealed significant differences, for example, in the orientation of nucleotides in peptidyl transferase center and in the structures of many ribosomal proteins. Analysis of ribosomal features involved in dynamic aspects of protein biosynthesis that are partially or fully disordered in H50S revealed the conformations of intersubunit bridges in unbound subunits, suggesting how they may change upon subunit association and how movements of the L1-stalk may facilitate the exit of tRNA.     

Involvement of mitochondrial ribosomal proteins in ribosomal RNA-mediated protein folding

The peptidyl transferase center of the domain V of large ribosomal RNA in the prokaryotic and eukaryotic cytosolic ribosomes acts as general protein folding modulator. We showed earlier that one part of the domain V (RNA1 containing the peptidyl transferase loop) binds unfolded protein and directs it to a folding competent state (FCS) that is released by the other part (RNA2) to attain the folded native state by itself. Here we show that the peptidyl transferase loop of the mitochondrial ribosome releases unfolded proteins in FCS extremely slowly despite its lack of the rRNA segment analogous to RNA2. The release of FCS can be hastened by the equivalent activity of RNA2 or the large subunit proteins of the mitochondrial ribosome. The RNA2 or large subunit proteins probably introduce some allosteric change in the peptidyl transferase loop to enable it to release proteins in FCS.     

Termination of protein synthesis

One of three mRNA codons — UAA, UAG and UGA — is used to signal to the elongating ribosome that translation should be terminated at this point. Upon the arrival of the stop codon at the ribosomal acceptor(A)-site, a protein release factor (RF) binds to the ribosome resulting in the peptidyl transferase centre of the ribosome switching to a hydrolytic function to remove the completed polypeptide chain from the peptidyl-tRNA bound at the adjacent ribosomal peptidyl(P)-site. In this review recent advances in our understanding of the mechanism of termination in the bacteriumEscherichia coli will be summarised, paying particular attention to the roles of 16S ribosomal RNA and the release factors RF-1, RF-2 and RF-3 in stop codon recognition. Our understanding of the translation termination process in eukaryotes is much more rudimentary with the identity of the single eukaryotic release factor (eRF) still remaining elusive. Finally, several examples of how the termination mechanism can be subverted either to expand the genetic code (e.g. selenocysteine insertion at UGA codons) or to regulate the expression of mammalian retroviral or plant viral genomes will be discussed.     

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.     

On the structural basis of peptide-bond formation and antibiotic resistance from atomic structures of the large ribosomal subunit

The atomic structures of the large ribosomal subunit from Haloarcula marismortui and its complexes with substrates and antibiotics have provided insights into the way the 3000 nucleotide 23S rRNA folds into a compact, specific structure and interacts with 27 ribosomal proteins as well as the structural basis of the peptidyl transferase reaction and its inhibition by antibiotics. The structure shows that the ribosome is indeed a ribozyme.