A structural view on the mechanism of the ribosome-catalyzed peptide bond formation

The ribosome is a large ribonucleoprotein particle that translates genetic information encoded in mRNA into specific proteins. Its highly conserved active site, the peptidyl-transferase center (PTC), is located on the large (50S) ribosomal subunit and is comprised solely of rRNA, which makes the ribosome the only natural ribozyme with polymerase activity. The last decade witnessed a rapid accumulation of atomic-resolution structural data on both ribosomal subunits as well as on the entire ribosome. This has allowed studies on the mechanism of peptide bond formation at a level of detail that surpasses that for the classical protein enzymes. A current understanding of the mechanism of the ribosome-catalyzed peptide bond formation is the focus of this review. Implications on the mechanism of peptide release are discussed as well.     

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.     

Localization of the protein L2 in the 50 S subunit and the 70 S E. coli ribosome

The protein L2 is found in all ribosomes and is one of the best conserved proteins of this mega-dalton complex. The protein was localized within both the isolated 50 S subunit and the 70 S ribosome of the Escherichia coli bacteria with the neutron-scattering technique of spin-contrast variation. L2 is elongated, exposing one end of the protein to the surface of the intersubunit interface of the 50 S subunit. The protein changes its conformation slightly when the 50 S subunit reassociates with the 30 S subunit to form a 70 S ribosome, becoming more elongated and moving approximately 30 A into the 50 S matrix. The results support a recent observation that L2 is essential for the association of the ribosomal subunits and might participate in the binding and translocation of the tRNAs.     

The peptidyltransferase centre of the Escherichia coli ribosome. The histidine of protein L16 affects the reconstitution and control of the active centre but is not essential for release-factor-mediated peptidyl-tRNA hydrolysis and peptide bond formation

Modification of the Escherichia coli 50S ribosomal subunit with histidine-specific diethyl pyrocarbonate affects peptide bond formation and release-factor-dependent peptidyl-tRNA hydrolysis. Unmodified L16 can restore activity to a split protein fraction from the altered subunit but other proteins of the core also contain histidine residues important for the activity of the peptidyltransferase centre. When isolated and purified by centrifugation, particles reconstituted with unmodified proteins and modified L16 do not retain the altered L16. The modified protein does mediate the partial restoration of peptide bond formation and release-factor-2 activities to these particles. It must be exerting its effect during the assembly of the peptidyltransferase centre in the reconstituted particle. A particle could be reconstituted which lacks L16 and has significant activity in peptide bond formation and peptidyl-tRNA hydrolysis. L16 stimulates these activities. A tighter ribosomal binding of the release factor 2, dependent upon the absence of protein L11, can in part compensate for the loss of activity of the peptidyltransferase centre when it is assembled with either modified L16 or in the absence of L16. The protein and its histidine residue seem important, therefore, for the peptidyltransferase centre to be formed in the correct conformation but not essential for activity once the centre is assembled.     

Deletion of a conserved, central ribosomal intersubunit RNA bridge

Elucidation of the structure of the ribosome has stimulated numerous proposals for the roles of specific rRNA elements, including the universally conserved helix 69 (H69) of 23S rRNA, which forms intersubunit bridge B2a and contacts the D stems of A- and P-site tRNAs. H69 has been proposed to be involved not only in subunit association and tRNA binding but also in initiation, translocation, translational accuracy, the peptidyl transferase reaction, and ribosome recycling. Consistent with such proposals, deletion of H69 confers a dominant lethal phenotype. Remarkably, in vitro assays show that affinity-purified Deltah69 ribosomes have normal translational accuracy, synthesize a full-length protein from a natural mRNA template, and support EF-G-dependent translocation at wild-type rates. However, Deltah69 50S subunits are unable to associate with 30S subunits in the absence of tRNA, are defective in RF1-catalyzed peptide release, and can be recycled in the absence of RRF.     

Puromycin-rRNA interaction sites at the peptidyl transferase center

The binding site of puromycin was probed chemically in the peptidyl-transferase center of ribosomes from Escherichia coli and of puromycin-hypersensitive ribosomes from the archaeon Haloferax gibbonsii. Several nucleotides of the 23S rRNAs showed altered chemical reactivities in the presence of puromycin. They include A2439, G2505, and G2553 for E. coli, and G2058, A2503, G2505, and G2553 for Hf. gibbonsii (using the E. coli numbering system). Reproducible enhanced reactivities were also observed at A508 and A1579 within domains I and III, respectively, of E. coli 23S rRNA. In further experiments, puromycin was shown to produce a major reduction in the UV-induced crosslinking of deacylated-(2N3A76)tRNA to U2506 within the P' site of E. coli ribosomes. Moreover, it strongly stimulated the putative UV-induced crosslink between a streptogramin B drug and m2A2503/psi2504 at an adjacent site in E. coli 23S rRNA. These data strongly support the concept that puromycin, along with other peptidyl-transferase antibiotics, in particular the streptogramin B drugs, bind to an RNA structural motif that contains several conserved and accessible base moieties of the peptidyl transferase loop region. This streptogramin motif is also likely to provide binding sites for the 3' termini of the acceptor and donor tRNAs. In contrast, the effects at A508 and A1579, which are located at the exit site of the peptide channel, are likely to be caused by a structural effect transmitted along the peptide channel.     

A peptide from the eel pancreas with structural similarity to human pancreatic secretory trypsin inhibitor

The primary structure of a 61-amino-acid residue peptide from the pancreas of the European eel (Anguilla anguilla) has been established as E E K S G(5)L Y R K P(10)S C G E M(15)S A M H A(20)C P M N F(25)A P V C G(30)T D G N T(35)Y P N E C(40)S L C F Q(45)R Q N T K(50)T D I L I(55)T K D D R(60)C. There was no indication of microheterogeneity. This peptide shows structural similarity to pancreatic secretory trypsin inhibitors from several mammalian species and to a cholecystokinin-releasing peptide isolated from rat pancreatic juice. A comparison of the amino acid sequences of the peptides has identified a domain in the central region of the molecules that has been strongly conserved during evolution. In contrast, the amino acid sequence in the region corresponding to the reactive centre of the mammalian trypsin inhibitors is very poorly conserved in the eel peptide. The P1-P1' reactive site lysine-isoleucine (or arginine-isoleucine) bond in the mammalian trypsin inhibitors is replaced by a methionine-asparagine bond. This region does, however, show limited homology to the reactive centre of human alpha 1-protease inhibitor suggesting that the eel peptide may function as an inhibitor of other proteolytic enzymes in the pancreas.     

Locking and unlocking of ribosomal motions

During the ribosomal translocation, the binding of elongation factor G (EF-G) to the pretranslocational ribosome leads to a ratchet-like rotation of the 30S subunit relative to the 50S subunit in the direction of the mRNA movement. By means of cryo-electron microscopy we observe that this rotation is accompanied by a 20 A movement of the L1 stalk of the 50S subunit, implying that this region is involved in the translocation of deacylated tRNAs from the P to the E site. These ribosomal motions can occur only when the P-site tRNA is deacylated. Prior to peptidyl-transfer to the A-site tRNA or peptide removal, the presence of the charged P-site tRNA locks the ribosome and prohibits both of these motions.     

Role of conserved residues within helices IV and VIII of the oxaloacetate decarboxylase beta subunit in the energy coupling mechanism of the Na+ pump.

The membrane-bound beta subunit of the oxaloacetate decarboxylase Na+ pump of Klebsiella pneumoniae catalyzes the decarboxylation of enzyme-bound biotin. This event is coupled to the transport of 2 Na+ ions into the periplasm and consumes a periplasmically derived proton. The connecting fragment IIIa and transmembrane helices IV and VIII of the beta subunit are highly conserved, harboring residues D203, Y229, N373, G377, S382, and R389 that play a profound role in catalysis. We report here detailed kinetic analyses of the wild-type enzyme and the beta subunit mutants N373D, N373L, S382A, S382D, S382T, R389A, and R389D. In these studies, pH profiles, Na+ binding affinities, Hill coefficients, Vmax values and inhibition by Na+ was determined. A prominent result is the complete lack of oxaloacetate decarboxylase activity of the S382A mutant at Na+ concentrations up to 20 mm and recovery of significant activities at elevated Na+ concentrations (KNa approximately 400 mm at pH 6.0), where the wild-type enzyme is almost completely inhibited. These results indicate impaired Na+ binding to the S382 including site in the S382A mutant. Oxaloacetate decarboxylation by the S382A mutant at high Na+ concentrations is uncoupled from the vectorial events of Na+ or H+ translocation across the membrane. Based on all data with the mutant enzymes we propose a coupling mechanism, which includes Na+ binding to center I contributed by D203 (region IIIa) and N373 (helix VIII) and center II contributed by Y229 (helix IV) and S382 (helix VIII). These centers are exposed to the cytoplasmic surface in the carboxybiotin-bound state of the beta subunit and become exposed to the periplasmic surface after decarboxylation of this compound. During the countertransport of 2 Na+ and 1 H+ Y229 of center II switches between the protonated and deprotonated Na+-bound state.     

Mutational analysis of the C-domain in nonribosomal peptide synthesis.

The initial condensation event in the nonribosomal biosynthesis of the peptide antibiotics gramicidin S and tyrocidine A takes place between a phenylalanine activating racemase GrsA/TycA and the first proline-activating module of GrsB/TycB. Recently we established a minimal in vitro model system for NRPS with recombinant His6-tagged GrsA (GrsAPhe-ATE; 127 kDa) and TycB1 (TycB1Pro-CAT; 120 kDa) and demonstrated the catalytic function of the C-domain in TycB1Pro-CAT to form a peptide bond between phenylalanine and proline during diketopiperazine formation (DKP). In this work we took advantage of this system to identify catalytically important residues in the C-domain of TycB1Pro-CAT using site-directed mutagenesis and peptide mapping. Mutations in TycB1Pro-CAT of 10 strictly conserved residues among 80 other C-domains with potential catalytic function, revealed that only R62A, H147R and D151N are impaired in peptide-bond formation. All other mutations led to either unaffected (Q19A, C154A/S, Y166F/W and R284A) or insoluble proteins (H146A, R67A and W202L). Although 100 nm of the serine protease inhibitors N-alpha-tosyl-l-phenylalanylchloromethane or phenylmethanesulfonyl fluoride completely abolished DKP synthesis, no covalently bound inhibitor derivatives in the C-domain could be identified by peptide mapping using HPLC-MS. Though the results do not reveal a particular mechanism for the C-domain, they exhibit a possible way of catalysis analogous to the functionally related enzymes chloramphenicol acetyltransferase and dihydrolipoyl transacetylase. Based on this, we propose a mechanism in which one catalytic residue (H147) and two other structural residues (R62 and D151) are involved in amino-acid condensation.     

Structures of deacylated tRNA mimics bound to the E site of the large ribosomal subunit

During translation, tRNAs cycle through three binding sites on the ribosome: the A, the P, and the E sites. We have determined the structures of complexes between the Haloarcula marismortui large ribosomal subunit and two different E site substrates: a deacylated tRNA acceptor stem minihelix and a CCA-acceptor end. Both of these tRNA mimics contain analogs of adenosine 76, the component responsible for a large proportion of E site binding affinity. They bind in the center of the loop-extension of protein L44e, and make specific contacts with both L44e and 23S rRNA including bases that are conserved in all three kingdoms of life. These contacts are consistent with the footprinting, protection, and cross-linking data that have identified the E site biochemically. These structures explain the specificity of the E site for deacylated tRNAs, as it is too small to accommodate any relevant aminoacyl-tRNA. The orientation of the minihelix suggests that it may mimic the P/E hybrid state. It appears that the E site on the 50S subunit was formed by only RNA in the last common ancestor of the three kingdoms, since the proteins at the E sites of H. marismortui and Deinucoccus radiodurans large subunits are not homologous.     

Visualization of the hybrid state of tRNA binding promoted by spontaneous ratcheting of the ribosome

A crucial step in translation is the translocation of tRNAs through the ribosome. In the transition from one canonical site to the other, the tRNAs acquire intermediate configurations, so-called hybrid states. At this stage, the small subunit is rotated with respect to the large subunit, and the anticodon stem loops reside in the A and P sites of the small subunit, while the acceptor ends interact with the P and E sites of the large subunit. In this work, by means of cryo-EM and particle classification procedures, we visualize the hybrid state of both A/P and P/E tRNAs in an authentic factor-free ribosome complex during translocation. In addition, we show how the repositioning of the tRNAs goes hand in hand with the change in the interplay between S13, L1 stalk, L5, H68, H69, and H38 that is caused by the ratcheting of the small subunit.     

Properties of ribosomes and RNA synthesized by Escherichia coli grown in the presence of ethionine. V. Methylation dependence on the assembly of E. coli 50 S ribosomal subunits.

An ethionine-containing submethylated particle related to the 50 S ribosomal subunit has been isolated from Escherichia coli grown in the presence of ethionine. This particle (E-50S) lacks L16, contains reduced amounts of L6, L27, L28 and L30 and possesses a more labile and flexible structure than the normal 50 S subunit. The E-50S particle has defective association properties and is incapable of peptide bond formation. It can be converted to an active 50 S ribosomal subunit when ethionine-treated bacteria are incubated under conditions which permit methylation of submethylated cellular components (presence of methionine) in the absence of de novo protein and RNA synthesis (presence of rifampicin).Total reconstitution of 50 S ribosomal subunits in vitro using normal 23 S and 5 S ribosomal RNA and proteins prepared from E-50S particles yields active subunits only if L16 is also added. The hypothesis that E-50S particles accumulate in ethionine-treated bacteria because the absence of methylation of one or more of their components blocks a late stage (L16 integration) in the normal 50 S assembly process is discussed.     

Mutations at position A960 of E. coli 23 S ribosomal RNA influence the structure of 5 S ribosomal RNA and the peptidyltransferase region of 23 S ribosomal RNA

The proximity of loop D of 5 S rRNA to two regions of 23 S rRNA, domain II involved in translocation and domain V involved in peptide bond formation, is known from previous cross-linking experiments. Here, we have used site-directed mutagenesis and chemical probing to further define these contacts and possible sites of communication between 5 S and 23 S rRNA. Three different mutants were constructed at position A960, a highly conserved nucleotide in domain II previously crosslinked to 5 S rRNA, and the mutant rRNAs were expressed from plasmids as homogeneous populations of ribosomes in Escherichia coli deficient in all seven chromosomal copies of the rRNA operon. Mutations A960U, A960G and, particularly, A960C caused structural rearrangements in the loop D of 5 S rRNA and in the peptidyltransferase region of domain V, as well as in the 960 loop itself. These observations support the proposal that loop D of 5 S rRNA participates in signal transmission between the ribosome centers responsible for peptide bond formation and translocation.     

Coupling mechanism of the oxaloacetate decarboxylase Na(+) pump

The oxaloacetate decarboxylase Na(+) pump consists of subunits alpha, beta and gamma, and contains biotin as the prosthetic group. The peripheral alpha subunit catalyzes the carboxyltransfer from oxaloacetate to the prosthetic biotin group to yield the carboxybiotin enzyme. Subsequently, this is decarboxylated in a Na(+)-dependent reaction by the membrane-bound beta subunit. The decarboxylation is coupled to Na(+) translocation from the cytoplasm into the periplasm, and consumes a periplasmically derived proton. The gamma subunit contains a Zn(2+) metal ion which may be involved in the carboxyltransfer reaction. It is proposed to insert with its N-terminal alpha-helix into the membrane and to form a complex with the alpha subunit with its water-soluble C-terminal domain. The beta subunit consists of nine transmembrane alpha-helices, a segment (IIIa) which inserts from the periplasm into the membrane but does not penetrate it, and connecting hydrophilic loops. The most highly conserved regions of the molecule are segment IIIa and transmembrane helix VIII. Functionally important residues are D203 (segment IIIa), Y229 (helix IV) and N373, G377, S382 and R389 (helix VIII). The polar of these amino acids may constitute a network of ionizable groups which promotes the translocation of Na(+) and the oppositely oriented translocation of H(+) across the membrane. Evidence indicates that two Na(+) ions are bound simultaneously to subunit beta with D203 and S382 acting as binding sites. Sodium ion binding from the cytoplasm to both sites elicits decarboxylation of carboxybiotin possibly with the consumption of the proton extracted from S382 and delivered via Y229 to the carboxylated prosthetic group. A conformational change exposes the bound Na(+) ions toward the periplasm. With H(+) entering from the periplasm, the hydroxyl group of S382 is regenerated, and as a consequence, the Na(+) ions are released into this compartment. After switching back to the original conformation, Na(+) pumping continues.     

An alternative mechanism for the catalysis of peptide bond formation by L/F transferase: substrate binding and orientation

Eubacterial leucyl/phenylalanyl tRNA protein transferase (L/F transferase) catalyzes the transfer of a leucine or a phenylalanine from an aminoacyl-tRNA to the N-terminus of a protein substrate. This N-terminal addition of an amino acid is analogous to that of peptide synthesis by ribosomes. A previously proposed catalytic mechanism for Escherichia coli L/F transferase identified the conserved aspartate 186 (D186) and glutamine 188 (Q188) as key catalytic residues. We have reassessed the role of D186 and Q188 by investigating the enzymatic reactions and kinetics of enzymes possessing mutations to these active-site residues. Additionally three other amino acids proposed to be involved in aminoacyl-tRNA substrate binding are investigated for comparison. By quantitatively measuring product formation using a quantitative matrix-assisted laser desorption/ionization time-of-flight mass spectrometry-based assay, our results clearly demonstrate that, despite significant reduction in enzymatic activity as a result of different point mutations introduced into the active site of L/F transferase, the formation of product is still observed upon extended incubations. Our kinetic data and existing X-ray crystal structures result in a proposal that the critical roles of D186 and Q188, like the other amino acids in the active site, are for substrate binding and orientation and do not directly participate in the chemistry of peptide bond formation. Overall, we propose that L/F transferase does not directly participate in the chemistry of peptide bond formation but catalyzes the reaction by binding and orientating the substrates for reaction in an analogous mechanism that has been described for ribosomes.     

Mutation of asparagine 229 to aspartate in thymidylate synthase converts the enzyme to a deoxycytidylate methylase.

The conserved Asn 229 of thymidylate synthase (TS) forms a cyclic hydrogen bond network with the 3-NH and 4-O of the nucleotide substrate dUMP. The Asn 229 to Asp mutant of Lactobacillus casei thymidylate synthase (TS N229D) has been prepared, purified, and investigated. Steady-state kinetic parameters of TS N229D show 3.5- and 10-fold increases in the Km values of CH2H4folate and dUMP, respectively, and a 1000-fold decrease in kcat. Most important, the Asp 229 mutation changes the substrate specificity of TS to an enzyme which recognizes and methylates dCMP in preference to dUMP. With TS N229D the Km for dCMP is bout 3-fold higher than for dUMP, and the Km for CH2H4folate is increased about 5-fold; however, the kcat for dCMP methylation is 120-fold higher than that for dUMP methylation. Specificity for dCMP versus dUMP, as measured by kcat/Km, changes from negligible with wild-type TS to about a 40-fold increase with TS N229D. TS N229D reacts with CH2H4folate and FdUMP or FdCMP to form ternary complexes which are analogous to the TS-FdUMP-CH2H4folate complex. From what is known of the mechanism and structure of TS, the dramatic change in substrate specificity of TS N229D is proposed to involve a hydrogen bond network between Asp 229 and the 3-N and 4-NH2 of the cytosine heterocycle, causing protonation of the 3-N and stabilization of a reactive imino tautomer. A similar mechanism is proposed for related enzymes which catalyze one-carbon transfers to cytosine heterocycles.     

Multiple defects in translation associated with altered ribosomal protein L4

The ribosomal proteins L4 and L22 form part of the peptide exit tunnel in the large ribosomal subunit. In Escherichia coli, alterations in either of these proteins can confer resistance to the macrolide antibiotic, erythromycin. The structures of the 30S as well as the 50S subunits from each antibiotic resistant mutant differ from wild type in distinct ways and L4 mutant ribosomes have decreased peptide bond-forming activity. Our analyses of the decoding properties of both mutants show that ribosomes carrying the altered L4 protein support increased levels of frameshifting, missense decoding and readthrough of stop codons during the elongation phase of protein synthesis and stimulate utilization of non-AUG codons and mutant initiator tRNAs at initiation. L4 mutant ribosomes are also altered in their interactions with a range of 30S-targeted antibiotics. In contrast, the L22 mutant is relatively unaffected in both decoding activities and antibiotic interactions. These results suggest that mutations in the large subunit protein L4 not only alter the structure of the 50S subunit, but upon subunit association, also affect the structure and function of the 30S subunit.     

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.