Peculiarities in Activation of Hydrolytic Activity of Elongation Factors.

Translational GTPases (trGTPases) belong to the family of G proteins and play key roles at all stages of protein biosynthesis on the ribosome. Unidirectional and cyclic functioning of G proteins is ensured by their ability to switch between the active and inactive states due to GTP hydrolysis accelerated by the auxiliary GTPase-activating proteins. Although trGTPases interact with the ribosomes in different conformational states, they bind to the same conserved region, which, unlike in classical GTPase-activating proteins, is represented by ribosomal RNA. The resulting catalytic sites have almost identical structure in all elongation factors suggesting a common mechanism of GTP hydrolysis. However, fine details of the activated state formation and significantly different rates of GTP hydrolysis indicate the existence of distinctive features upon GTP hydrolysis catalyzed by the different factors. Here, we present a contemporary view on the mechanism of GTPase activation and GTP hydrolysis by the elongation factors EF-Tu, EF-G, and SelB based on the analysis of structural, biochemical, and bioinformatics data.

Transit of tRNA through the Escherichia coli ribosome. Cross-linking of the 3' end of tRNA to specific nucleotides of the 23 S ribosomal RNA at the A, P, and E sites.

When bound to Escherichia coli ribosomes and irradiated with near-UV light, various derivatives of yeast tRNA(Phe) containing 2-azidoadenosine at the 3' terminus form cross-links to 23 S rRNA and 50 S subunit proteins in a site-dependent manner. A and P site-bound tRNAs, whose 3' termini reside in the peptidyl transferase center, label primarily nucleotides U2506 and U2585 and protein L27. In contrast, E site-bound tRNA labels nucleotide C2422 and protein L33. The cross-linking patterns confirm the topographical separation of the peptidyl transferase center from the E site domain. The relative amounts of label incorporated into the universally conserved residues U2506 and U2585 depend on the occupancy of the A and P sites by different tRNA ligands and indicates that these nucleotides play a pivotal role in peptide transfer. In particular, the 3'-adenosine of the peptidyl-tRNA analogue, AcPhe-tRNA(Phe), remains in close contact with U2506 regardless of whether its anticodon is located in the A site or P site. Our findings, therefore, modify and extend the hybrid state model of tRNA-ribosome interaction. We show that the 3'-end of the deacylated tRNA that is formed after transpeptidation does not immediately progress to the E site but remains temporarily in the peptidyl transferase center. In addition, we demonstrate that the E site, defined by the labeling of nucleotide C2422 and protein L33, represents an intermediate state of binding that precedes the entry of deacylated tRNA into the F (final) site from which it dissociates into the cytoplasm.

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.

Direct crosslinking of the antitumor antibiotic sparsomycin, and its derivatives, to A2602 in the peptidyl transferase center of 23S-like rRNA within ribosome-tRNA complexes.

The antitumor antibiotic sparsomycin is a universal and potent inhibitor of peptide bond formation and selectively acts on several human tumors. It binds to the ribosome strongly, at an unknown site, in the presence of an N-blocked donor tRNA substrate, which it stabilizes on the ribosome. Its site of action was investigated by inducing a crosslink between sparsomycin and bacterial, archaeal, and eukaryotic ribosomes complexed with P-site-bound tRNA, on irradiating with low energy ultraviolet light (at 365 nm). The crosslink was localized exclusively to the universally conserved nucleotide A2602 within the peptidyl transferase loop region of 23S-like rRNA by using a combination of a primer extension approach, RNase H fragment analysis, and crosslinking with radioactive [(125)I]phenol-alanine-sparsomycin. Crosslinking of several sparsomycin derivatives, modified near the sulfoxy group, implicated the modified uracil residue in the rRNA crosslink. The yield of the antibiotic crosslink was weak in the presence of deacylated tRNA and strong in the presence of an N-blocked P-site-bound tRNA, which, as was shown earlier, increases the accessibility of A2602 on the ribosome. We infer that both A2602 and its induced conformational switch are critically important both for the peptidyl transfer reaction and for antibiotic inhibition. This supposition is reinforced by the observation that other antibiotics that can prevent peptide bond formation in vitro inhibit, to different degrees, formation of the crosslink.

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.

UV-induced modifications in the peptidyl transferase loop of 23S rRNA dependent on binding of the streptogramin B antibiotic, pristinamycin IA.

The naturally occurring streptogramin B antibiotic, pristinamycin IA, which inhibits peptide elongation, can produce two modifications in 23S rRNA when bound to the Escherichia coli 70S ribosome and irradiated at 365 nm. Both drug-induced effects map to highly conserved nucleotides within the functionally important peptidyl transferase loop of 23S rRNA at positions m2A2503/psi2504 and G2061/A2062. The modification yields are influenced strongly, and differentially, by P-site-bound tRNA and strongly by some of the peptidyl transferase antibiotics tested, with chloramphenicol producing a shift in the latter modification to A2062/C2063. Pristinamycin IA can also produce a modification on binding to deproteinized, mature 23S rRNA, at position U2500/C2501. The same modification occurs on an approximately 37-nt fragment, encompassing positions approximately 2496-2532 of the peptidyl transferase loop that was excised from the mature rRNA using RNAse H. In contrast, no antibiotic-induced effects were observed on in vitro T7 transcripts of full-length 23S rRNA, domain V, or on a fragment extending from positions approximately 2496-2566, which indicates that one or more posttranscriptional modifications within the sequence Cm-C-U-C-G-m2A-psi-G2505 are important for pristinamycin IA binding and/or the antibiotic-dependent modification of 23S rRNA.

Peptidyl transferase and beyond.

The peptidyl transferase center of the Escherichia coli ribosome encompasses a number of 50S-subunit proteins as well as several specific segments of the 23S rRNA. Although our knowledge of the role that both ribosomal proteins and 23S rRNA play in peptide bond formation has steadily increased, the location, organization, and molecular structure of the peptidyl transferase center remain poorly defined. Over the past 10 years, we have developed a variety of photoaffinity reagents and strategies for investigating the topography of tRNA binding sites on the ribosome. In particular, we have used the photoreactive tRNA probes to delineate ribosomal components in proximity to the 3' end of tRNA at the A, P, and E sites. In this article, we describe recent experiments from our laboratory which focus on the identification of segments of the 23S rRNA at or near the peptidyl transferase center and on the functional role of L27, the 50S-subunit protein most frequently labeled from the acceptor end of A- and P-site tRNAs. In addition, we discuss how these results contribute to a better understanding of the structure, organization, and function of the peptidyl transferase center.

Structural elements of rps0 mRNA involved in the modulation of translational initiation and regulation of E. coli ribosomal protein S15.

Previous experiments showed that S15 inhibits its own translation by binding to its mRNA in a region overlapping the ribosome loading site. This binding was postulated to stabilize a pseudoknot structure that exists in equilibrium with two stem-loops and to trap the ribosome on its mRNA loading site in a transitory state. In this study, we investigated the effect of mutations in the translational operator on: the binding of protein S15, the formation of the 30S/mRNA/tRNA(fMet) ternary initiation complex, the ability of S15 to inhibit the formation of this ternary complex. The results were compared to in vivo expression and repression rates. The results show that (1) the pseudoknot is required for S15 recognition and translational control; (2) mRNA and 16S rRNA efficiently compete for S15 binding and 16S rRNA suppresses the ability of S15 to inhibit the formation of the active ternary complex; (3) the ribosome binds more efficiently to the pseudoknot than to the stem-loop; (4) sequences located between nucleotides 12 to 47 of the S15 coding phase enhances the efficiency of ribosome binding in vitro; this is correlated with enhanced in vivo expression and regulation rates.

[Interaction of deacylated phenylalanyl tRNA from yeasts with Escherichia coli ribosomes. The role of the modified nucleotide in codon-anticodon interaction]. / Vzaimodeistvie deatsilirovannoi fenilalaninovoi tRNK iz drozhzhei s ribosomami Escherichia coli. Rol' modifitsirovannogo nukleotida v kodon-antikodonovom vazimodeistvii.

The method of anticodon loop replacement has been used to make derivatives of yeast tRNA(Phe)GmAAY with the substitution at the 37 position (tRNA(Phe)GAAA), and at both the anticodon (tRNA(Phe)GCAG) and the 37 position. A quantitative study of the interaction of various types of yeast deacylated tRNA: tRNA(Phe)GmAAY, tRNA(Phe)GAAA, tRNA(Phe)GCAG, and tRNA(Phe)-Y with the P site of the 70S ribosome.poly(U) complex was carried out at different Mg2+ concentrations and temperatures. The replacement of the Y base on the nonmodified adenosine decreases the interaction enthalpy from 39 to 24 kcal/mole, whereas the complete removal of the Y base reduces the interaction enthalpy to 16 kcal/mole. The replacement of the second letter of the anticodon (A) with cytosine leads to a drop in the enthalpy to 6 kcal/mole, which is typical of tRNA interaction with the P site in the absence of poly(U). In the absence of poly(U) the affinity of tRNA(Phe)-Y for the P site of the 70S ribosome is 5 times lower than the affinity of tRNA(Phe)GmAAY and tRNA(Phe)GCAG. Thus, in the ribosome the modified nucleotide not only stabilizes the codon-anticodon interaction owing to the stacking interaction with the stack of codon-anticodon bases, but also lowers the free energy of binding as a result of the interaction of the modified nucleotide itself with the hydrophobic center of the P site on the ribosome.

Puromycin reaction of the A-site bound peptidyl-tRNA.

AcPhe2-tRNA(Phe) which appears in ribosomes after consecutive binding of AcPhe-tRNA(Phe) at the P sites and EF-Tu-directed binding of Phe-tRNA(Phe) at the A sites is able to react quantitatively with puromycin in the absence of EF-G. One could readily explain this fact to be the consequence of spontaneous translocation. However, a detailed study of kinetics of puromycin reaction carried out with the use of viomycin (inhibitor of translocation) and the P-site test revealed that, apart from spontaneous translocation, this peptidyl-tRNA could react with puromycin being located at the A site. This leads to the conclusion that the transpeptidation reaction triggers conformational changes in the A-site ribosomal complex bringing the 3'-end of a newly synthesized peptidyl-tRNA nearer to the peptidyl site of peptidyltransferase center. This is detected functionally as a highly pronounced ability of such a peptidyl-tRNA to react with puromycin.

Interaction of tRNA with the A and P sites of rabbit-liver 80S ribosomes and their 40S subunits.

The interaction between tRNA and rabbit liver 80S ribosomes and 40S subunits was studied using a nitrocellulose membrane filtration technique. Binding of the different tRNA forms (aminoacyl-, peptidyl- or deacylated) to poly(U)-programmed 40S subunits and 80S ribosomes was found to be a cooperative process. The association constants of AcPhe-TRNA(Phe) for the A and P sites of 80S ribosomes and the cooperativity constant were measured at different temperature and Mg2+ concentration. The AcPhe-tRNA(Phe) association constant for the P site was shown to be between 2 x 10(7) M-1 and 2 x 10(8) M-1 at 25-37 degrees C and 5-20 mM Mg2+, while the affinity for the A site was 10-100-fold lower. The cooperativity constant was shown to decrease with the increase of incubation temperature and the decrease of Mg2+ concentration. The affinity of AcPhe-tRNA(Phe) for the A site of 80S ribosomes was shown to depend upon the codon specificity of tRNA at the P site. The cooperativity of the tRNA interaction with 80S ribosomes was suggested to be mostly contributed by the association with the 40S subunit and result from the correct codon-anticodon pairing at the P site. The data presented imply a codon-anticodon interaction at the P site of eukaryotic 80S ribosomes.

[A modified method of isolation of "tight" 70S ribosomes from Escherichia coli highly active at different stages of the elongation cycle]. / Modifitsirovannyi sposob polucheniia "tight" 70S ribosom iz Escherichia coli, vysokoaktivnykh v otdel'nykh stadiiakh tsikla élongatsii.

The functional activity of the wide-spread "tight" 70S ribosomes is usually equal to 55-80%. We show here that the inactive fraction of this type of ribosomes is virtually blocked by residual endogenous RNA's. These RNA's are shown to be removable by introducing an additional stage in the isolation procedure including: 1. short heating (15 min, 37 degrees C) of "tight" 70S under dissociation conditions, i. e. in a buffer containing 3 mM MgCl2 and 200 mM NH4Cl; 2. washing off endogenous RNA's on a sucrose density gradient in the same buffer; 3. final selection of purified "tight" 70S on the sucrose gradient containing 5 mM MgCl2 and 50 mM NH4Cl. "Tight" 70S ribosomes isolated by such a procedure are 90-100% active with respect to tRNA binding (including the factor-dependent one), peptide bond synthesis and translocation.

Number of tRNA binding sites on 80 S ribosomes and their subunits.

The ability of rabbit liver ribosomes and their subunits to form complexes with different forms of tRNAPhe (aminoacyl-, peptidyl- and deacylated) was studied using the nitrocellulose membrane filtration technique. The 80 S ribosomes were shown to have two binding sites for aminoacyl- or peptidyl-tRNA and three binding sites for deacylated tRNA. The number of tRNA binding sites on 80 S ribosomes or 40 S subunits is constant at different Mg2+ concentrations (5-20 mM). Double reciprocal or Scatchard plot analysis indicates that the binding of Ac-Phe-tRNAPhe to the ribosomal sites is a cooperative process. The third site on the 80 S ribosome is formed by its 60 S subunit, which was shown to have one codon-independent binding site specific for deacylated tRNA.

[Effect of the concentration ratio of bi- and monovalent ions on the functional activity of 30S ribosome subunits of Escherichia coli]. / Vliianie sootnosheniia kontsentratsii dvukh- i odnovalentnykh kationov na funktsional'nuiu aktivnost' 30S subchastits ribosom Escherichia coli.

Experiments on poly(U)-dependent binding of Phe-tRNAPhe to 30S subunits revealed the existence of a critical [Mg2+]/[NH4+] ratio in a medium (approximately 0.05-0.1) with respect to the binding capacity of subunits. If the ratio is greater than the critical one, 30S subunits undergo reversible inactivation even at the highest Mg2+ concentrations (up to 20 mM). The stronger is the deviation from the [Mg2+]/[NH4+] value = 0.05-0.1, the greater are both the rate and extent of such an inactivation. Two sites for tRNA in initially active 30S subunits have been shown to be inactivated in an interdependent way. On the other hand, a progressive decrease of [Mg2+]/[NH4+] ratio in a medium (from the value of 0.05 and lower) does not produce inactivation, but rather results in reduced affinity constants of Phe-tRNAPhe for active sites of 30S subunits.

Extension of Watson's model for the elongation cycle of protein biosynthesis.

The scheme for the elongation cycle of protein biosynthesis is proposed based on modern quantitative data on the interactions of mRNA and different functional forms of tRNA with 70S ribosomes and their 30S and 50S subunits. This scheme takes into account recently discovered third ribosomal (E) site with presumable exit function. The E site is introduced into 70S ribosome by its 50S subunit, the codon-anticodon interaction does not take place at the E site, and the affinity of tRNA for the E site is considerably lower than that for the P site. On the other hand, the P and A sites are located mainly on a 30S subunit, the codon-anticodon interactions being realized on both these sites. An mRNA molecule is placed exclusively on a 30S subunit where it makes U-turn. The proposed scheme does not contradict to any data but includes all main postulates of the initial Watson's model (J. D. Watson, Bull. Soc. Chim. Biol. 46, 1399 (1964), and is considered as a natural extension of the later according to modern experimental data.

40 S subunits from rat liver ribosomes contain two codon-dependent sites for transfer RNA.

40 S subunits from rat liver ribosomes are able to bind, after heat activation, two molecules of either Phe-tRNAPhe, Ac-Phe-tRNAPhe or deacylated tRNAPhe. Addition of 60 S subunits to the quaternary complex 40 S.poly(U).(Phe-tRNAPhe)2 results in quantitative formation of (Phe)2-tRNAPhe. This indicates that the two binding sites for tRNA on 40 S subunits should be considered as the constituent of P and A sites of 80 S ribosomes.

The effect of GTP hydrolysis and transpeptidation on the arrangement of aminoacyl-tRNA at the A-site of Escherichia coli 70 S ribosomes.

From the affinity labelling of 70 S ribosomes with a photoreactive derivative of Phe-tRNAPhe bearing an arylazido group on guanine residues, it has been found that different sets of ribosomal proteins are labelled in the course of three successive steps of EF-Tu-dependent binding of aminoacyl-tRNA derivative at the A-site. Proteins S5, S7, S8, S16, S17, L9, L14, L15 and L24 were labelled before GTP hydrolysis; proteins S5, S7, S9, S11, S14, S18, S19, S21, L9, L21 and L29--after GTP hydrolysis; proteins S2, S5, S7, S21, L11 and L23--after GTP hydrolysis and transpeptidation.

[Binding of the yeast phenylalanine tRNA with Escherichia coli ribosomes. Effect of the removal of a modified base from the 3'-end of the anticodon on codon-anticodon interaction]. / Sviazyvanie fenilalaninovoi tRNK iz drozhzhei s ribosomami Escherichia coli. Vliianie udaleniia modifitsirovannogo osnovaniia s 3'-storony antikodona na kodon-antikodonovoe vzaimodeistvie.

Phe-tRNAPhe+Y and N-acetyl-Phe-tRNAPhe+Y from yeast interact with prokaryotic 30S subunits and 70S ribosomes with slightly lower affinity than respective tRNA's of E. coli (decrease of standard free energy change of interaction less than 10%). The removal of Y-base from Phe-tRNAPhe+Y results in two orders of magnitude decrease of association constant of Phe-tRNAPh-Ye with P site of the 30S X poly(U) complex and one ordef of magnitude or more of that with A site. The same modification decreases the association constants of Phe-tRNAPhe-Y and N-acetyl-Phe-tRNAPhe-Y 60 and 15 times respectively with P site of the 70S X poly(U) complex. In the absence of poly(U) the affinity of N-acetyl-Phe-tRNAPhe-Y to P-site of 70S ribosome was 20-fold lower than that of native N-acetyl-Phe-tRNAPhe+Y. The sign of interaction enthalpy of N-acetyl-Phe-tRNAPhe+/-Y and Phe-tRNAPhe-Y changes below 6-7 degrees C exposing the hydrophobic part of P-site interactions. Similar removal of Y-base does not change both the enthalpy of interaction with P-site and magnesium concentration dependence.