The interaction between C75 of tRNA and the A loop of the ribosome stimulates peptidyl transferase activity

Ribosomal variants carrying mutations in active site nucleotides are severely compromised in their ability to catalyze peptide bond formation (PT) with minimal aminoacyl tRNA substrates such as puromycin. However, catalysis of PT by these same ribosomes with intact aminoacyl tRNA substrates is uncompromised. These data suggest that these active site nucleotides play an important role in the positioning of minimal aminoacyl tRNA substrates but are not essential for catalysis per se when aminoacyl tRNAs are positioned by more remote interactions with the ribosome. Previously reported biochemical studies and atomic resolution X-ray structures identified a direct Watson-Crick interaction between C75 of the A-site substrate and G2553 of the 23S rRNA. Here we show that the addition of this single cytidine residue (the C75 equivalent) to puromycin is sufficient to suppress the deficiencies of active site ribosomal variants, thus restoring "tRNA-like" behavior to this minimal substrate. Studies of the binding parameters and the pH-dependence of catalysis with this minimal substrate indicate that the interaction between C75 and the ribosomal A loop is an essential feature for robust catalysis and further suggest that the observed effects of C75 on peptidyl transfer activity reflect previously reported conformational rearrangements in this active site.     

Polynucleotide-protein interactions in the translation system. Identification of proteins interacting with tRNA in the A- and P-sites of E. coli ribosomes.

Ultraviolet irradiation (lambda = 254 nm) of ternary complexes of E. coli 70 S ribosomes with poly(U) and either Phe-tRNAPhe (in the A-site) or NAcPhe-tRNAPhe (in the P-site) effectively induces covalent linking of tRNA with a limited number of ribosomal proteins. The data obtained indicate that in both sites tRNA is in contact with proteins of both 30 S and 50 S subunits (S5, S7, S9, S10, L2, L6 and L16 proteins in the A-site and S7, S9, S11, L2, L4, L7/L12 and L27 proteins in the P-site). Similar sets of proteins are in contact with total aminoacyl-tRNA and N-acetylaminoacyl-tRNA. However, here no contacts of tRNA in the P-site with the S7 and L25/S17 proteins were revealed, whereas in the A-site total aminoacyl-tRNA contacts L7/L12. Proteins S9, L2 and, probably, S7 and L7/L12 are common to both sites.     

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.     

Binding of misacylated tRNAs to the ribosomal A site

To test whether the ribosome displays specificity for the esterified amino acid and the tRNA body of an aminoacyl-tRNA (aa-tRNA), the stabilities of 4 correctly acylated and 12 misacylated tRNAs in the ribosomal A site were determined. By introducing the GAC (valine) anticodon into each tRNA, a constant anticodon.codon interaction was maintained, thus removing concern that different anticodon.codon strengths might affect the binding of the different aa-tRNAs to the A site. Surprisingly, all 16 aa-tRNAs displayed similar dissociation rate constants from the A site. These results suggest that either the ribosome is not specific for different amino acids and tRNA bodies when intact aa-tRNAs are used or the specificity for the amino acid side chain and tRNA body is masked by a conformational change upon aa-tRNA release.     

Peptide bond formation does not involve acid-base catalysis by ribosomal residues

Ribosomes catalyze the formation of peptide bonds between aminoacyl esters of transfer RNAs within a catalytic center composed of ribosomal RNA only. Here we show that the reaction of P-site formylmethionine (fMet)-tRNA(fMet) with a modified A-site tRNA substrate, Phelac-tRNA(Phe), in which the nucleophilic amino group is replaced with a hydroxyl group, does not show the pH dependence observed with small substrate analogs such as puromycin and hydroxypuromycin. This indicates that acid-base catalysis by ribosomal residues is not important in the reaction with the full-size substrate. Rather, the ribosome catalyzes peptide bond formation by positioning the tRNAs, or their 3' termini, through interactions with rRNA that induce and/or stabilize a pH-insensitive conformation of the active site and provide a preorganized environment facilitating the reaction. The rate of peptide bond formation with unmodified Phe-tRNA(Phe) is estimated to be >300 s(-1).     

Binding of ribosome recycling factor to ribosomes,comparison with tRNA

The prokaryotic post-termination ribosomal complex is disassembled by ribosome recycling factor (RRF) and elongation factor G. Because of the structural similarity of RRF and tRNA, we compared the biochemical characteristics of RRF binding to ribosomes with that of tRNA. Unesterified tRNA inhibited the disassembly of the post-termination complex in a competitive manner with RRF, suggesting that RRF binds to the A-site. Approximately one molecule of ribosome-bound RRF was detected after isolation of the RRF-ribosome complex. RRF and unesterified tRNA similarly inhibited the binding of N-acetylphenylalanyl-tRNA to the P-site of non-programmed but not programmed ribosomes. Under the conditions in which unesterified tRNA binds to both the P- and E-sites of non-programmed ribosomes, RRF inhibited 50% of the tRNA binding, suggesting that RRF does not bind to the E-site. The results are consistent with the notion that a single RRF binds to the A- and P-sites in a somewhat analogous manner to the A/P-site bound peptidyl tRNA. The binding of RRF and tRNA to ribosomes was influenced by Mg(2+) and NH(4)(+) ions in a similar manner.     

Maintenance of the correct open reading frame by the ribosome

During translation, a string of non-overlapping triplet codons in messenger RNA is decoded into protein. The ability of a ribosome to decode mRNA without shifting between reading frames is a strict requirement for accurate protein biosynthesis. Despite enormous progress in understanding the mechanism of transfer RNA selection, the mechanism by which the correct reading frame is maintained remains unclear. In this report, evidence is presented that supports the idea that the translational frame is controlled mainly by the stability of codon–anticodon interactions at the P site. The relative instability of such interactions may lead to dissociation of the P-site tRNA from its codon, and formation of a complex with an overlapping codon, the process known as P-site tRNA slippage. We propose that this process is central to all known cases of +1 ribosomal frameshifting, including that required for the decoding of the yeast transposable element Ty3. An earlier model for the decoding of this element proposed 'out-of-frame' binding of A-site tRNA without preceding P-site tRNA slippage.     

Study of the photoaffinity modification of Escherichia coli ribosomes near the donor tRNA-binding center

Affinity labelling of E. coli ribosomes near the donor tRNA-binding (P) site was studied with the use of photoreactive derivatives of tRNAPhe bearing arylazidogroups on N7 atoms of guanine residues (azido-tRNA). UV-irradiation of complexes 70S ribosome.poly(U).azido- tRNA(P-site) and 70S ribosome.poly(U).azido-tRNA(P-site).Phe- tRNAPhe(A-site) resulted in covalent attachment of azido-tRNA to ribosomes, both subunits being labelled. In both cases modification extent of 30S subunit was two-fold than that of the 50S one. It was shown that when the A-site was free the azido-tRNA located in P-site labelled proteins S9, S11, S12, S13, S21 and L14, L27, L31. Azido-tRNA located in P-site when the A-site was occupied with Phe-tRNAPhe labelled proteins S11, S12, S13, S14, S19, L32/L33 and possibly L23, L25. From the comparison of the sets of proteins labelled when A-site was free or occupied a conclusion was drawn that aminoacyl-tRNA located in ribosomal A-site affects the arrangement of deacylated tRNA in P-site. Data obtained allow to propose that proteins S5, S19, S20 and L24, L33 interact with guanine residues important for the tRNA tertiary structure formation.     

Physiologically Dependent Appearance of a Low Density Region That Corresponds to the Tunnel through the 50S Part of the 70S Ribosome

Ribosomes have different conformations in cells that are starved for a required amino acid (giving aminoacyl.tRNA starvation), or treated with kirromycin (blocking EF-Tu.GDP release), or are in exponential growth. A tunnel spans the 50S ribosome from a location facing the 70S ribosomal intersubunit space to the back side of the subunit inEscherichia colicells. Here we have analyzed the internal low density region that corresponds to this tunnel in ribosomesin vivo.The data suggest that the tunnel is opened in connection with spatial separation of the subunits in ribosomes that have an empty A-site due to starvation for aminoacyl.tRNA. A region that corresponds to this tunnel can be found in the more compact structure of ribosomes in kirromycin-treated cells only after a substantial removal of low density material. This region is even less prominent in ribosomes in undefined working modes in growing bacteria. The data suggest that appearance of the tunnel through the 50S ribosomal subunit is working-mode dependent and it is not a characteristic feature of the major fraction of the ribosomal population in growing cells.     

Peptidyl-CCA deacylation on the ribosome promoted by induced fit and the O3'-hydroxyl group of A76 of the unacylated A-site tRNA

The last step in ribosome-catalyzed protein synthesis is the hydrolytic release of the newly formed polypeptide from the P-site bound tRNA. Hydrolysis of the ester link of the peptidyl-tRNA is stimulated normally by the binding of release factors (RFs). However, an unacylated tRNA or just CCA binding to the ribosomal A site can also stimulate deacylation under some nonphysiological conditions. Although the sequence of events is well described by biochemical studies, the structural basis of the mechanism underlying this process is not well understood. Two new structures of the large ribosomal subunit of Haloarcula marismortui complexed with a peptidyl-tRNA analog in the P site and two oligonucleotide mimics of unacylated tRNA, CCA and CA, in the A site show that the binding of either CA or CCA induces a very similar conformational change in the peptidyl-transferase center as induced by aminoacyl-CCA. However, only CCA positions a water molecule appropriately to attack the carbonyl carbon of the peptidyl-tRNA and stabilizes the proper orientation of the ester link for hydrolysis. We, thus, conclude that both the ability of the O3′-hydroxyl group of the A-site A76 to position the water and the A-site CCA induced conformational change of the PTC are critical for the catalysis of the deacylation of the peptidyl-tRNA by CCA, and perhaps, an analogous mechanism is used by RFs.     

P-site tRNA is a crucial initiator of ribosomal frameshifting

The expression of some genes requires a high proportion of ribosomes to shift at a specific site into one of the two alternative frames. This utilized frameshifting provides a unique tool for studying reading frame control. Peptidyl-tRNA slippage has been invoked to explain many cases of programmed frameshifting. The present work extends this to other cases. When the A-site is unoccupied, the P-site tRNA can be repositioned forward with respect to mRNA (although repositioning in the minus direction is also possible). A kinetic model is presented for the influence of both, the cognate tRNAs competing for overlapping codons in A-site, and the stabilities of P-site tRNA:mRNA complexes in the initial and new frames. When the A-site is occupied, the P-site tRNA can be repositioned backward. Whether frameshifting will happen depends on the ability of the A-site tRNA to subsequently be repositioned to maintain physical proximity of the tRNAs. This model offers an alternative explanation to previously published mechanisms of programmed frameshifting, such as out-of-frame tRNA binding, and a different perspective on simultaneous tandem tRNA slippage.     

Solid phase synthesis and binding affinity of peptidyl transferase transition state mimics containing 2'-OH at P-site position A76

All living cells are dependent on ribosomes to catalyze the peptidyl transfer reaction, by which amino acids are assembled into proteins. The previously studied peptidyl transferase transition state analog CC-dA-phosphate-puromycin (CCdApPmn) has important differences from the transition state, yet current models of the ribosomal active site have been heavily influenced by the properties of this molecule. One significant difference is the substitution of deoxyadenosine for riboadenosine at A76, which mimics the 3′ end of a P-site tRNA. We have developed a solid phase synthetic approach to produce inhibitors that more closely match the transition state, including the critical P-site 2′-OH. Inclusion of the 2′-OH or an even bulkier OCH₃ group causes significant changes in binding affinity. We also investigated the effects of changing the A-site amino acid side chain from phenylalanine to alanine. These results indicate that the absence of the 2′-OH is likely to play a significant role in the binding and conformation of CCdApPmn in the ribosomal active site by eliminating steric clash between the 2′-OH and the tetrahedral phosphate oxygen. The conformation of the actual transition state must allow for the presence of the 2′-OH, and transition state mimics that include this critical hydroxyl group must bind in a different conformation from that seen in prior analog structures. These new inhibitors will provide valuable insights into the geometry and mechanism of the ribosomal active site.     

Function of the ribosomal E-site: a mutagenesis study

Ribosomes synthesize proteins according to the information encoded in mRNA. During this process, both the incoming amino acid and the nascent peptide are bound to tRNA molecules. Three binding sites for tRNA in the ribosome are known: the A-site for aminoacyl-tRNA, the P-site for peptidyl-tRNA and the E-site for the deacylated tRNA leaving the ribosome. Here, we present a study of Escherichia coli ribosomes with the E-site binding destabilized by mutation C2394G of the 23S rRNA. Expression of the mutant 23S rRNA in vivo caused increased frameshifting and stop codon readthrough. The progression of these ribosomes through the ribosomal elongation cycle in vitro reveals ejection of deacylated tRNA during the translocation step or shortly after. E-site compromised ribosomes can undergo translocation, although in some cases it is less efficient and results in a frameshift. The mutation affects formation of the P/E hybrid site and leads to a loss of stimulation of the multiple turnover GTPase activity of EF-G by deacylated tRNA bound to the ribosome.     

Interaction between non-formylated initiator Met-tRNA(fMet) and the ribosomal A-site from Escherichia coli

We report studies in vitro of the interaction between non-formylated initiator Met-tRNA(fMet) and 70S ribosomes. The binding of Met-tRNA(fMet) to ribosomes carrying fMet-tRNA(fMet) in the P-site is strongly stimulated by elongation factor EF-Tu:GTP in the presence of (AUG)3. The enzymatically bound Met-tRNA(fMet) does not react with puromycin. The bound Met-tRNA(fMet) can accept formylmethionine from P-site-bound fMet-tRNA(fMet). These results demonstrate a functionally active binding at the ribosomal A-site. Partial ribonuclease digestion (footprinting) was used to study the sites in Met-tRNA(fMet) which are involved in the interaction with the ribosomal A-site. The results show that a large part of the tRNA molecule is protected by the ribosome against ribonuclease digestion. In addition to the protection found in the amino acid region and the anticodon arm, protection is seen in the D-loop and in the extra arm. No region within the bound tRNA is found to be more accessible for RNases than in the free Met-tRNA(fMet). The reported enhancement of ribonuclease cuts in the D- and T-arms of A-site-bound Phe-tRNAPhe is thus not found in A-site bound Met-tRNA(fMet).     

Comparison of Escherichia coli tRNAPhe in the free state, in the ternary complex and in the ribosomal A and P sites by chemical probing

tRNAPheE.coli was modified at accessible guanosine, cytidine, and adenosine residues using the chemical modification method described by Peattie and Gilbert [Proc. Natl Acad. Sci. USA, 77, 4679-4689 (1980)]. Modification characteristics of the tRNA in the free state, in the ternary complex with elongation factor EF-Tu and GTP and in the ribosomal A and P sites were compared. A special procedure was devised to monitor, exclusively, tRNA molecules in the aminoacylated state. In the free tRNA, the most reactive bases are confined to the A73-C-C-A sequence of the aminoacyl stem, the anticodon loop, the D-loop and the extra loop and the results correlate well with the three-dimensional structure of tRNAPheyeast determined by X-ray studies. The pattern of reactivity was not affected either by charging the tRNA with phenylalanine or by labelling the 3' terminus with pCp. In the ternary complex, with elongation factor EF-Tu and GTP, changes in modification were observed at two sites, A73-C-C-A at the 3' terminus and C-13 and C-17 in the D-loop region, which are about 6 nm apart; no difference was observed in the anticodon loop. tRNAPhe bound at the ribosomal A or P sites exhibited similar, but not identical, modification patterns. Whereas nucleotides C-74 and C-75 were strongly protected at both sites, the adjacent A-73 showed an enhanced reactivity in the A site. The anticodon region G34-A-A-ms2.6(1)A was also strongly protected at both sites. In addition, nucleotide A-21 was protected during A-site, but not P-site, binding.     

Movement of the decoding region of the 16 S ribosomal RNA accompanies tRNA translocation

The ribosome undergoes pronounced periodic conformational changes during protein synthesis. Of particular importance are those occurring around the decoding site, the region of the 16 S rRNA interacting with the mRNA-(tRNA)(2) complex. We have incorporated structural information from X-ray crystallography and nuclear magnetic resonance into cryo-electron microscopic maps of ribosomal complexes designed to capture structural changes at the translocation step of the polypeptide elongation cycle. The A-site region of the decoding site actively participates in the translocation of the tRNA from the A to the P-site upon GTP hydrolysis by elongation factor G, shifting approximately 8 A toward the P-site. This implies that elongation factor G actively pushes both the decoding site and the mRNA/tRNA complex during translocation.     

EF-G-independent reactivity of a pre-translocation-state ribosome complex with the aminoacyl tRNA substrate puromycin supports an intermediate (hybrid) state of tRNA binding

Following peptide-bond formation, the mRNA:tRNA complex must be translocated within the ribosomal cavity before the next aminoacyl tRNA can be accommodated in the A site. Previous studies suggested that following peptide-bond formation and prior to EF-G recognition, the tRNAs occupy an intermediate (hybrid) state of binding where the acceptor ends of the tRNAs are shifted to their next sites of occupancy (the E and P sites) on the large ribosomal subunit, but where their anticodon ends (and associated mRNA) remain fixed in their prepeptidyl transferase binding states (the P and A sites) on the small subunit. Here we show that pre-translocation-state ribosomes carrying a dipeptidyl-tRNA substrate efficiently react with the minimal A-site substrate puromycin and that following this reaction, the pre-translocation-state bound deacylated tRNA:mRNA complex remains untranslocated. These data establish that pre-translocation-state ribosomes must sample or reside in an intermediate state of tRNA binding independent of the action of EF-G.     

Functional Interaction Between Release Factor One and P-site Peptidyl-tRNA on the Ribosome

Translation termination at UAG is influenced by the nature of the 5′ flanking codon inEscherichia coli. Readthrough of the stop codon is always higher in a strain with mutant (prfA1) as compared to wild-type (prfA⁺) release factor one (RF1). Isocodons, which differ in the last base and are decoded by the same tRNA species, affect termination at UAG differently in strains with mutant or wild-type RF1. No general preference of the last codon base to favour readthrough or termination can be found. The data suggest that RF1 is sensitive to the nature of the wobble base anticodon-codon interaction at the ribosomal peptidyl-tRNA binding site (P-site). For some isoaccepting P-site tRNAs (tRNA₃^ProversustRNA₂^Pro, tRNA₄^ThrversustRNA_1,3^Thr) the effect is different on mutant and wild-type RF1, suggesting an interaction between RF1 at the aminoacyl-tRNA acceptor site (A-site) and the P-site tRNA itself. The glycine codons GGA (tRNA₂^Gly) and GGG (tRNA_2,3^Gly) at the ribosomal P-site are associated with an almost threefold higher readthrough of UAG than any of the other 42 codons tested, including the glycine codons GGU/C, in a strain with wild-type RF1. This differential response to the glycine codons is lost in the strain with the mutant form of RF1 since readthrough is increased to a similar high level for all four glycine codons. High α-helix propensity of the last amino acid residue at the C-terminal end of the nascent peptide is correlated with an increased termination at UAG. The effect is stronger on mutant compared to wild-type RF1. The data suggest that RF1-mediated termination at UAG is sensitive to the nature of the codon-anticodon interaction of the wobble base, the last amino acid residue of the nascent peptide chain, and the tRNA at the ribosomal P-site.     

Catalytic properties of mutant 23 S ribosomes resistant to oxazolidinones

Kinetic analysis of ribosomal peptidyltransferase activity in a methanolic puromycin reaction with wild type and drug-resistant 23 S RNA mutants was used to probe the structural basis of catalysis and mechanism of resistance to antibiotics. 23 S RNA mutants G2032A and G2447A are resistant to oxazolidinones both in vitro and in vivo with the latter displaying a 5-fold increase in the value of Km for initiator tRNA and a 100-fold decrease in Vmax in puromycin reaction. Comparison of the Ki values for oxazolidinones, chloramphenicol, and sparsomycin revealed partial cross-resistance between oxazolidinones and chloramphenicol; no cross-resistance was observed with sparsomycin, a known inhibitor of the peptidyltransferase A-site. Inhibition of the mutants using a truncated CCA-Phe-X-Biotin fragment as a P-site substrate is similar to that observed with the intact initiator tRNA, indicating that the inhibition is substrate-independent and that the peptidyltransferase itself is the oxazolidinone target. Mapping of all known mutations that confer resistance to these drugs onto the spatial structure of the 50 S ribosomal subunit allows for docking of an oxazolidinone into a proposed binding pocket. The model suggests that oxazolidinones bind between the P- and A-loops, partially overlapping with the peptidyltransferase P-site. Thus, kinetic, mutagenesis, and structural data suggest that oxazolidinones interfere with initiator fMet-tRNA binding to the P-site of the ribosomal peptidyltransferase center.