The E-site story: the importance of maintaining two tRNAs on the ribosome during protein synthesis

In the sixties James Watson suggested a twosite model for the ribosome comprising the P site for the peptidyl transfer RNA (tRNA) before peptide-bond formation and the A site, where decoding takes place according to the codon exposed there. In the eighties a third tRNA binding site was detected, the E site, which was specific for deacylated tRNA and turned out to be a universal feature of ribosomes. However, despite having three tRNA binding sites, only two tRNAs occupy the ribosome at a time during protein synthesis: at the A and P sites before translocation (PRE state) and at the P and E sites after translocation (POST state). The importance of having two tRNAs in the POST state has been revealed during the last 25 years, showing that the E site contributes two fundamental features: (i) the fact that incorporation of a wrong amino acid is not harmful for the cell (only 1 in about 400 misincorporations destroys the function of a protein) stems from the presence of an E-tRNA; (ii) maintenance of the reading frame is one of the most remarkable achievements of the ribosome, essential for faithful translation of the genetic information. The presence of the POST state E-tRNA prevents loss of the reading frame.

Functions and interplay of the tRNA-binding sites of the ribosome

The ribosome translates the genetic information of an mRNA molecule into a sequence of amino acids. The ribosome utilizes tRNAs to connect elements of the RNA and protein worlds during protein synthesis, i.e. an anticodon as a unit of genetic information with the corresponding amino acid as a building unit of proteins. Three tRNA-binding sites are located on the ribosome, termed the A, P and E sites. In recent years the tRNA-binding sites have been localized on the ribosome by three different techniques, small-angle neutron scattering, cryo-electron microscopy and X-ray analyses of 70 S crystals. These high-resolution glimpses into various ribosomal states together with a large body of biochemical data reveal an intricate interplay between the tRNAs and the three ribosomal binding sites, providing an explanation for the remarkable features of the ribosome, such as the ability to select the correct ternary complex aminoacyl-tRNA.EF-Tu.GTP out of more than 40 extremely similar tRNA complexes, the precise movement of the tRNA(2).mRNA complex during translocation and the maintenance of the reading frame.

Complex of transfer-messenger RNA and elongation factor Tu. Unexpected modes of interaction

Transfer-messenger RNA (tmRNA) is a stable RNA in bacteria of 360 +/- 40 nucleotides that can be charged with alanine and can function as both tRNA and mRNA. Ribosomes that are stalled either in a coding region of mRNA or at the 3' end of an mRNA fragment lacking a stop codon are rescued by replacing their mRNA for tmRNA. Here we demonstrate that the interaction of tmRNA with the elongation factor Tu shows unexpected features. Deacylated tmRNA can form a complex with either EF-Tu.GDP or EF-Tu.GTP, the association constants are about one order of magnitude smaller than that of an Ala-tRNA.EF-Tu.GTP complex. tmRNA as well as Ala-tmRNA can be efficiently cross-linked with EF-Tu.GDP using a zero-length cross-link. The efficiency of cross-linking in the case of deacylated tmRNA does not depend on an intact CCA-3' end and is about the same, regardless whether protein mixtures such as the post-ribosomal supernatant (S100 enzymes) or purified EF-Tu are present. Two cross-linking sites with EF-Tu.GDP have been identified that are located outside the tRNA part of tmRNA, indicating an unusual interaction of tmRNA with EF-Tu.GDP.

SERF: in vitro election of random RNA fragments to identify protein binding sites within large RNAs

In vitro selection experiments have various goals depending on the composition of the initial pool and the selection method applied. We developed an in vitro selection variant (SERF, selection of random RNA fragments) that is useful for the identification of short RNA fragments originating from large RNAs that bind specifically to a protein. A pool of randomly fragmented RNA is constructed from a large RNA, which is the natural binding partner for a protein. Such a pool contains all the potential binding sites and is therefore used as starting material for affinity selection with the purified protein to find its natural target. Here we provide a detailed experimental protocol of the method. SERF has been developed for ribosomal systems and is a general approach providing a basis for functional and structural characterization of RNA-protein interactions in large ribonucleoprotein particles.

Localization of L11 protein on the ribosome and elucidation of its involvement in EF-G-dependent translocation

L11 protein is located at the base of the L7/L12 stalk of the 50 S subunit of the Escherichia coli ribosome. Because of the flexible nature of the region, recent X-ray crystallographic studies of the 50 S subunit failed to locate the N-terminal domain of the protein. We have determined the position of the complete L11 protein by comparing a three-dimensional cryo-EM reconstruction of the 70 S ribosome, isolated from a mutant lacking ribosomal protein L11, with the three-dimensional map of the wild-type ribosome. Fitting of the X-ray coordinates of L11-23 S RNA complex and EF-G into the cryo-EM maps combined with molecular modeling, reveals that, following EF-G-dependent GTP hydrolysis, domain V of EF-G intrudes into the cleft between the 23 S ribosomal RNA and the N-terminal domain of L11 (where the antibiotic thiostrepton binds), causing the N-terminal domain to move and thereby inducing the formation of the arc-like connection with the G' domain of EF-G. The results provide a new insight into the mechanism of EF-G-dependent translocation.

Mapping proteins of the 50S subunit from Escherichia coli ribosomes

Mapping of protein positions in the ribosomal subunits was first achieved for the 30S subunit by means of neutron scattering about 15 years ago. Since the 50S subunit is almost twice as large as the 30S subunit and consists of more proteins, it was difficult to apply classical contrast variation techniques for the localisation of the proteins. Polarisation dependent neutron scattering (spin-contrast variation) helped to overcome this restriction. Here a map of 14 proteins within the 50S subunit from Escherichia coli ribosomes is presented including the proteins L17 and L20 that are not present in archeal ribosomes. The results are compared with the recent crystallographic map of the 50S subunit from the archea Haloarcula marismortui.

Localization of the ribosomal protection protein Tet(O) on the ribosome and the mechanism of tetracycline resistance

Tet(O) belongs to a class of ribosomal protection proteins that mediate tetracycline resistance. It is a G protein that shows significant sequence similarity to elongation factor EF-G. Here we present a cryo-electron microscopic reconstruction, at 16 A resolution, of its complex with the E. coli 70S ribosome. Tet(O) was bound in the presence of a noncleavable GTP analog to programmed ribosomal complexes carrying fMet-tRNA in the P site. Tet(O) is directly visible as a mass close to the A-site region, similar in shape and binding position to EF-G. However, there are important differences. One of them is the different location of the tip of domain IV, which in the Tet(O) case, does not overlap with the ribosomal A site but is directly adjacent to the primary tetracycline binding site. Our findings give insights into the mechanism of tetracycline resistance.

A short fragment of 23S rRNA containing the binding sites for two ribosomal proteins, L24 and L4, is a key element for rRNA folding during early assembly

Previously we described an in vitro selection variant abbreviated SERF (in vitro selection from random rRNA fragments) that identifies protein binding sites within large RNAs. With this method, a small rRNA fragment derived from the 23S rRNA was isolated that binds simultaneously and independently the ribosomal proteins L4 and L24 from Escherichia coli. Until now the rRNA structure within the ternary complex L24-rRNA-L4 could not be studied due to the lack of an appropriate experimental strategy. Here we tackle the issue by separating the various complexes via native gel-electrophoresis and analyzing the rRNA structure by in-gel iodine cleavage of phosphorothioated RNA. The results demonstrate that during the transition from either the L4 or L24 binary complex to the ternary complex the structure of the rRNA fragment changes significantly. The identified protein binding sites are in excellent agreement with the recently reported crystal structure of the 50S subunit. Because both proteins play a prominent role in early assembly of the large subunit, the results suggest that the identified rRNA fragment is a key element for the folding of the 23S RNA during early assembly. The introduced in-gel cleavage method should be useful when an RNA structure within mixed populations of different but related complexes should be studied.

Intrinsic structural differences between "tight couples" and Kaltschmidt-Wittmann ribosomes evidenced by dielectric spectroscopy and scanning microcalorimetry

Measurements of dielectric spectroscopy (DS) and microcalorimetry (differential scanning calorimetry (DSC)) of Escherichia coli 70S, 50S and 30S were performed on particles prepared according either to the "classical" twice NH(4)Cl-washed ribosomes, also known as loose couples (LC), or to the "tight couples" preparative protocol (TC). Results show that 70S particles prepared according to the two different protocols exhibit different structural properties. Two subsequent relaxation processes occur in both samples as measured by DS. However, in LC ribosomes the first one is shifted towards a lower frequency with a higher dielectric increment. This is suggestive of a more extensive exposure of RNA to the solvent and of an overall more relaxed structure. The smaller LC subunit exhibits only one relaxation while the TC 30S shows two dielectric dispersions as well as 70S. No substantial differences were evidenced in either 50S species. Two typical melting peaks were observed by DSC both in LC and TC 70S as well as in 50S. Thermograms obtained from the TC 30S show a single well structured peak while LC particles produce a large unstructured curve. On the basis of these results we conclude that TC 70S particles are more compact than LC ribosomes and that in the former ones the rRNA is less exposed to the solvent phase. Furthermore 30S particles obtained from TC show a more stable structure with respect to LC 30S. We conclude that the 30S subunit gives a major contribution to the compact character of the whole TC 70S. These differences might be related to the intrinsic and well documented functional difference between the two ribosome species.

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.

Ribosomal protein L2 is involved in the association of the ribosomal subunits, tRNA binding to A and P sites and peptidyl transfer

Ribosomal proteins L2, L3 and L4, together with the 23S RNA, are the main candidates for catalyzing peptide bond formation on the 50S subunit. That L2 is evolutionarily highly conserved led us to perform a thorough functional analysis with reconstituted 50S particles either lacking L2 or harboring a mutated L2. L2 does not play a dominant role in the assembly of the 50S subunit or in the fixation of the 3'-ends of the tRNAs at the peptidyl-transferase center. However, it is absolutely required for the association of 30S and 50S subunits and is strongly involved in tRNA binding to both A and P sites, possibly at the elbow region of the tRNAs. Furthermore, while the conserved histidyl residue 229 is extremely important for peptidyl-transferase activity, it is apparently not involved in other measured functions. None of the other mutagenized amino acids (H14, D83, S177, D228, H231) showed this strong and exclusive participation in peptide bond formation. These results are used to examine critically the proposed direct involvement of His229 in catalysis of peptide synthesis.

Periodic conformational changes in rRNA: monitoring the dynamics of translating ribosomes

In protein synthesis, a tRNA transits the ribosome via consecutive binding to the A (acceptor), P (peptidyl), and E (exit) site; these tRNA movements are catalyzed by elongation factor G (EF-G) and GTP. Site-specific Pb2+ cleavage was applied to trace tertiary alterations in tRNA and all rRNAs on pre- and posttranslocational ribosomes. The cleavage pattern of deacylated tRNA and AcPhe-tRNA changed individually upon binding to the ribosome; however, these different conformations were unaffected by translocation. On the other hand, translocation affects 23S rRNA structure. Significantly, the Pb2+ cleavage pattern near the peptidyl transferase center was different before and after translocation. This structural rearrangement emerged periodically during elongation, thus providing evidence for a dynamic and mobile role of 23S rRNA in translocation.

A map of protein-rRNA distribution in the 70 S Escherichia coli ribosome

Neutron scattering exploits the enormous scattering difference between protons and deuterons. A set of 42 x-ray and neutron solution scattering curves from hybrid Escherichia coli ribosomes was obtained, where the proteins and rRNA moieties in the subunits were either protonated or deuterated in all possible combinations. This extensive data set is analyzed using a novel method. The volume defined by the cryoelectron microscopic model of Frank and co-workers (Frank, J., Zhu, J., Penczek, P., Li, Y. H., Srivastava, S., Verschoor, A., Radermacher, M., Grassucci, R., Lata, R. K., and Agrawal, R. K. (1995) Nature 376, 441-444) is divided into 7890 densely packed spheres of radius 0.5 nm. Simulated annealing is employed to assign each sphere to solvent, protein, or rRNA moieties to simultaneously fit all scattering curves. Twelve independent reconstructions starting from random approximations yielded reproducible results. The resulting model at a resolution of 3 nm represents the volumes occupied by rRNA and protein moieties at 95% probability threshold and displays 15 and 20 protein subvolumes in the 30 S and 50 S, respectively, connected by rRNA. 17 proteins with known atomic structure can be tentatively positioned into the protein subvolumes within the ribosome in agreement with the results from other methods. The protein-rRNA map enlarges the basis for the models of the rRNA folding and can further help to localize proteins in high-resolution crystallographic density maps.

Detection and selective dissociation of intact ribosomes in a mass spectrometer

Intact Escherichia coli ribosomes have been projected into the gas phase of a mass spectrometer by means of nanoflow electrospray techniques. Species with mass/charge ratios in excess of 20,000 were detected at the level of individual ions by using time-of-flight analysis. Once in the gas phase the stability of intact ribosomes was investigated and found to increase as a result of cross-linking ribosomal proteins to the rRNA. By lowering the Mg(2+) concentration in solutions containing ribosomes the particles were found to dissociate into 30S and 50S subunits. The resolution of the charge states in the spectrum of the 30S subunit enabled its mass to be determined as 852,187 +/- 3,918 Da, a value within 0.6% of that calculated from the individual proteins and the 16S RNA. Further dissociation into smaller macromolecular complexes and then individual proteins could be induced by subjecting the particles to increasingly energetic gas phase collisions. The ease with which proteins dissociated from the intact species was found to be related to their known interactions in the ribosome particle. The results show that emerging mass spectrometric techniques can be used to characterize a fully functional biological assembly as well as its isolated components.

Selecting rRNA binding sites for the ribosomal proteins L4 and L6 from randomly fragmented rRNA: application of a method called SERF

Two-thirds of the 54 proteins of the Escherichia coli ribosome interact directly with the rRNAs, but the rRNA binding sites of only a very few proteins are known. We present a method (selection of random RNA fragments; SERF) that can identify the minimal binding region for proteins within ribonucleo-protein complexes such as the ribosome. The power of the method is exemplified with the ribosomal proteins L4 and L6. Binding sequences are identified for both proteins and characterized by phosphorothioate footprinting. Surprisingly, the binding region of L4, a 53-nt rRNA fragment of domain I of 23S rRNA, can simultaneously and independently bind L24, one of the two assembly initiator proteins of the large subunit.

Hsp15: a ribosome-associated heat shock protein

We are analyzing highly conserved heat shock genes of unknown or unclear function with the aim of determining their cellular role. Hsp15 has previously been shown to be an abundant nucleic acid-binding protein whose synthesis is induced massively at the RNA level upon temperature upshift. We have now identified that the in vivo target of Hsp15 action is the free 50S ribosomal subunit. Hsp15 binds with very high affinity (K(D) <5 nM) to this subunit, but only when 50S is free, not when it is part of the 70S ribosome. In addition, the binding of Hsp15 appears to correlate with a specific state of the mature, free 50S subunit, which contains bound nascent chain. This provides the first evidence for a so far unrecognized abortive event in translation. Hsp15 is suggested to be involved in the recycling of free 50S subunits that still carry a nascent chain. This gives Hsp15 a very different functional role from all other heat shock proteins and points to a new aspect of translation.

Protein expression in liposomes

Compartmentalization is one of the key steps in the evolution of cellular structures and, so far, only few attempts have been made to model this kind of "compartmentalized chemistry" using liposomes. The present work shows that even such complex reactions as the ribosomal synthesis of polypeptides can be carried out in liposomes. A method is described for incorporating into 1-palmitoyl-2-oleoyl-sn-3-phosphocholine (POPC) liposomes the ribosomal complex together with the other components necessary for protein expression. Synthesis of poly(Phe) in the liposomes is monitored by trichloroacetic acid of the (14)C-labelled products. Control experiments carried out in the absence of one of the ribosomal subunits show by contrast no significant polypeptide expression. This methodology opens up the possibility of using liposomes as minimal cell bioreactors with growing degree of synthetic complexity, which may be relevant for the field of origin of life as well as for biotechnological applications.

Effect of buffer conditions on the position of tRNA on the 70 S ribosome as visualized by cryoelectron microscopy

The effect of buffer conditions on the binding position of tRNA on the Escherichia coli 70 S ribosome have been studied by means of three-dimensional (3D) cryoelectron microscopy. Either deacylated tRNAfMet or fMet-tRNAfMet were bound to the 70 S ribosomes, which were programmed with a 46-nucleotide mRNA having AUG codon in the middle, under two different buffer conditions (conventional buffer: containing Tris and higher Mg2+ concentration [10-15 mM]; and polyamine buffer: containing Hepes, lower Mg2+ concentration [6 mM], and polyamines). Difference maps, obtained by subtracting 3D maps of naked control ribosome in the corresponding buffer from the 3D maps of tRNA.ribosome complexes, reveal the distinct locations of tRNA on the ribosome. The position of deacylated tRNAfMet depends on the buffer condition used, whereas that of fMet-tRNAfMet remains the same in both buffer conditions. The acylated tRNA binds in the classical P site, whereas deacylated tRNA binds mostly in an intermediate P/E position under the conventional buffer condition and mostly in the position corresponding to the classical P site, i. e. in the P/P state, under the polyamine buffer conditions.

Protection patterns of tRNAs do not change during ribosomal translocation

The translocation reaction of two tRNAs on the ribosome during elongation of the nascent peptide chain is one of the most puzzling reactions of protein biosynthesis. We show here that the ribosomal contact patterns of the two tRNAs at A and P sites, although strikingly different from each other, hardly change during the translocation reaction to the P and E sites, respectively. The results imply that the ribosomal micro-environment of the tRNAs remains the same before and after translocation and thus suggest that a movable ribosomal domain exists that tightly binds two tRNAs and carries them together with the mRNA during the translocation reaction from the A-P region to the P-E region. These findings lead to a new explanation for the translocation reaction.

Structure of 5S rRNA within the Escherichia coli ribosome: iodine-induced cleavage patterns of phosphorothioate derivatives

The protection patterns of 5S rRNA in solution, within the ribosomal 50S subunit, 70S ribosomes, and functional complexes, were assessed with the phosphorothioate method. About 20% of the analyzed positions (G9-G107) showed strong assembly defects: A phosphorothioate at one of these positions significantly impaired the incorporation of 5S rRNA into 50S particles. The reverse has also been observed: A phosphorothioate is preferred over a phosphate residue in the assembly process at a few positions. The results further demonstrate that 5S rRNA undergoes conformational changes during the assembly in the central protuberance of the 50S subunit and upon association with the small ribosomal subunit forming a 70S ribosome. In striking contrast, when the 70S ribosomes are once formed, the contact pattern of the 5S rRNA is the same in various functional states such as initiation-like complexes and pre- and posttranslocational states.

Natural defenses and autoprotection: naturotherapy, an old concept of healing in a new perspective

Recent molecular-biological and molecular-genetic research has shown that important cellular-based autoprotective mechanisms are mediated by heat-shock proteins (HSPs) or stress-response proteins, also called 'chaperones'. This can happen because cells react to extracellular stimuli by activating signal transduction pathways which result in activating the genetic program. Molecular biologists and cardiologists are tempted to evaluate these phenomena in respect to their potential meaning for a better understanding of the complex notions of health and disease. When molecular geneticists or cardiologists talk about autoprotective or natural defense mechanisms, and physicians talk about salutogenesis, they all mean something very specific. The phenomenon seen here belongs to the body's own defense mechanisms which make it capable of reacting to harmful influences and allow it to stabilize a structure and/or function of the body for a certain period. Here we see a connecting link to the historically grounded term self-healing forces, which has challenged medical doctors in the different historical periods of medical science. They tried to explain these effects based on the current model of the organism. Their understanding of this phenomenon played a role in defining the concept of health and disease. Thus, it seems very fitting to look back into history, since the phenomena discussed here as well as the insights into autoprotective mechanisms will continue to influence medical understanding of health and disease.

Mechanisms of autoprotection and the role of stress-proteins in natural defenses, autoprotection, and salutogenesis

We hypothesize that in all physiotherapeutically oriented procedures of naturotherapy -- such as helio-, climate-, thalasso- or hydrotherapy or certain forms of physical exercise -- the transient expression of stress-proteins (heat-shock proteins, HSPs) is an important element of salutogenesis. These therapeutical procedures all cause a transitory 'disturbance' by an unspecific stressor that leads to functional responses. These functional responses can be trained and thus increase the forces and the capacity for resistance of the organism. The autoprotective mechanisms which we want to deal with in more detail are based on the functions of the heat-shock proteins (HSPs, stress-response proteins, 'chaperones') and represent archaic autoprotective responses. In addition, more complex mechanisms of autoprotection seem to have evolved that may play a role in the natural defenses against disease and which show a hierarchy of various genomically conserved strategies with different time-constants and time windows. This becomes apparent by studying autoprotective responses of the cardiovascular system of warm-blooded animals under ischemic stress. Recent extensive experimental protocols and clinical observations in elucidating the molecular basis of cardiac ischemia show that powerful autoprotective mechanisms are involved in the phenomena of 'hibernation', 'stunning', and 'ischemic preconditioning'. The system of the heat-shock proteins may therefore be regarded as a basic model for the principle of autoprotection and salutogenesis.

Escherichia coli 70 S ribosome at 15 A resolution by cryo-electron microscopy: localization of fMet-tRNAfMet and fitting of L1 protein

Cryo-electron microscopy of the ribosome in different binding states with mRNA and tRNA helps unravel the different steps of protein synthesis. Using over 29,000 projections of a ribosome complex in single-particle form, a three-dimensional map of the Escherichia coli 70 S ribosome was obtained in which a single site, the P site, is occupied by fMet-tRNAfMet as directed by an AUG codon containing mRNA. The superior resolution of this three-dimensional map, 14.9 A, has made it possible to fit the tRNA X-ray crystal structure directly and unambiguously into the electron density, thus determining the locations of anticodon-codon interaction and peptidyltransferase center of the ribosome. Furthermore, at this resolution, one of the distinctly visible domains corresponding to a ribosomal protein, L1, closely matches with its X-ray structure.

Models of the elongation cycle: an evaluation

The central process for the transfer of the genetic information from the nucleic acid world into the structure of proteins is the ribosomal elongation cycle, where the sequence of codons is translated into the sequence of amino acids. The nascent polypeptide chain is elongated by one amino acid during the reactions of one cycle. Essentially, three models for the elongation cycle have been proposed. The allosteric three-site model and the hybrid-site model describe different aspects of tRNA binding and do not necessarily contradict each other. However, the alpha-epsilon model is not compatible with both models. The three models are evaluated in the light of recent results on the tRNA localization within the ribosome: the tRNAs of the elongating ribosome could be localized by two different techniques, viz. an advanced method of small-angle neutron scattering and cryo-electron microscopy. The best fit with the biochemical and structural data is obtained with the alpha-epsilon model.

A novel cell-free system for peptide synthesis driven by pyridine

Previously we demonstrated that ribosomes can synthesize polypeptides in the presence of high concentrations (40-60%) of pyridine without any protein factors. Here we analyze additional ribosomal parameters in 60% pyridine using Escherichia coli ribosomes. Ribosomal subunits once exposed to pyridine failed to re-associate to 70S ribosomes in aqueous buffer systems even in the presence of 20 mM Mg2+, whereas they formed 70S complexes in the presence of 60% pyridine. Two-dimensional gel electrophoresis of ribosomal proteins revealed that some proteins located at the protuberances of the large subunit, e. g. L7/L12 and L11 forming the elongation factor-binding domain, were released in the pyridine system. The aminoglycoside neomycin, a strong inhibitor of the ribosomal (factor-independent) translocation reaction, completely blocked poly(Phe) synthesis and translocation activities in the pyridine system, whereas these activities were not affected at all by gypsophilin, a ribotoxin that inhibits factor-dependent translocation. Another inhibitor of the ribosomal translocation, thiostrepton, had no effect concerning the two activities, which is consistent with the fact that this antibiotic requires L11 for its binding to the ribosome. These results suggest that the ribosomes can perform a translocation reaction in the pyridine system, but in a factor-independent (spontaneous) manner.

Ribosomal protection from tetracycline mediated by Tet(O): Tet(O) interaction with ribosomes is GTP-dependent

Tet(O) mediates tetracycline resistance by protecting the ribosome from inhibition. A recombinant Tet(O) protein with a histidine tag was purified and its activity in protein synthesis characterized. Tetracycline inhibited the rate of poly(Phe) synthesis, producing short peptide chains. Tet(O)-His was able to restore the elongation rate and processivity. 70S ribosomes bound tetracycline with high affinity. Tet(O)-His in the presence of GTP, but not GDP or GMP, reduced the affinity of the ribosomes for tetracycline. Non-hydrolyzable GTP analogs in the presence of the factor were also able to interfere with tetracycline binding. Ribosomes increased the affinity of Tet(O)-His for GTPgammaS. Tet(O), 70S ribosomes and GTPgammaS formed a complex that could be isolated by gel filtration. The GTP conformer is the active form of Tet(O) that interacts with the ribosome. GTP binding is necessary for Tet(O) activity.

Small angle scattering in ribosomal structure research: localization of the messenger RNA within ribosomal elongation states

Besides EM and biochemical studies small angle scattering (SAS) examinations have contributed significantly to our current knowledge about the ribosomal structure. SAS does not only allow the validation of competing models but permits independent model building. However, the major contribution of SAS to ribosomal structure research derived from its ability to reveal the spatial distribution of the individual ribosomal components (57 in the E. coli ribosome) within the ribosomal structure. More recently, an improved scattering method (proton-spin contrast variation) made it possible also to address the question of mapping functional ligands in defined ribosomal elongation states. Here, we review the contributions of SAS to the current understanding of the ribosome. Furthermore we present the direct localization of a small mRNA fragment within 70S elongation complexes and describe its movement upon the translocation reaction. The successful mapping of this fragment comprising only about 0.6% of the total mass of the complex proves that proton-spin contrast-variation is a powerful tool in modern ribosome research.

Ribosomal tRNA binding sites: three-site models of translation

The first models of translation described protein synthesis in terms of two operationally defined tRNA binding sites, the P-site for the donor substrate, the peptidyl-tRNA, and the A-site for the acceptor substrates, the aminoacyl-tRNAs. The discovery and analysis of the third tRNA binding site, the E-site specific for deacylated tRNAs, resulted in the allosteric three-site model, the two major features of which are (1) the reciprocal relationship of A-site and E-site occupation, and (2) simultaneous codon-anticodon interactions of both tRNAs present at the elongating ribosome. However, structural studies do not support the three operationally defined sites in a simple fashion as three topographically fixed entities, thus leading to new concepts of tRNA binding and movement: (1) the hybrid-site model describes the tRNAs' movement through the ribosome in terms of changing binding sites on the 30S and 50S subunits in an alternating fashion. The tRNAs thereby pass through hybrid binding states. (2) The alpha-epsilon model introduces the concept of a movable tRNA-binding domain comprising two binding sites, termed alpha and epsilon. The translocation movement is seen as a result of a conformational change of the ribosome rather than as a diffusion process between fixed binding sites. The alpha-epsilon model reconciles most of the experimental data currently available.

Structure of the elongating ribosome: arrangement of the two tRNAs before and after translocation

The ribosome uses tRNAs to translate the genetic information into the amino acid sequence of proteins. The mass ratio of a tRNA to the ribosome is in the order of 1:100; because of this unfavorable value it was not possible until now to determine the location of tRNAs within the ribosome by neutron-scattering techniques. However, the new technique of proton-spin contrast-variation improves the signal-to-noise ratio by more than one order of magnitude, thus enabling the direct determination of protonated tRNAs within a deuterated ribosome for the first time. Here we analyze a pair of ribosomal complexes being either in the pre- or post-translocational states that represent the main states of the elongating ribosome. Both complexes were derived from one preparation. The orientation of both tRNAs within the ribosome and their mutual arrangement are determined by using an electron microscopy model for the Escherichia coli ribosome and the tRNA structure. The mass center of gravity of the (tRNA)2mRNA complex moves within the ribosome by 12 +/- 4 A in the course of translocation as previously reported. The main results of the present analysis are that the mutual arrangement of the two tRNAs does not change on translocation and that the angle between them is, depending on the model used, 110 degrees +/- 10 degrees before and after translocation. The translocational movement of the constant tRNA complex within the ribosome can be described as a displacement toward the head of the 30S subunit combined with a rotational movement by about 18 degrees.

Mutational analysis of the donor substrate binding site of the ribosomal peptidyltransferase center

Previous experiments have shown that the top of helix 90 of 23S rRNA is highly important for the ribosomal peptidyltransferase activity and might be part of the donor (P) site. Developing on these studies, mutations in the 23S rRNA at the highly conserved positions G2505, G2582, and G2583 were investigated. None of the mutations affected assembly, subunit association, or the capacity of tRNA binding to A and P sites. A "selective transpeptidation assay" revealed that the mutations specifically impaired peptide bond formation. Results with a modified "fragment" assay using the minimal donor substrate pA-fMet are consistent with a model where the nucleotides psiGG2582 form a binding pocket for C75 of the tRNA.

Effect of point mutations at position 89 of the E. coli 5S rRNA on the assembly and activity of the large ribosomal subunit

Nucleotide residue U89 in the D loop of Escherichia coli 5S rRNA is adjacent to two domains of 23S rRNA in the large ribosomal subunit [Dokudovskaya et al., RNA 2 (1996) 146-152]. 50S ribosomal subunits were reconstituted containing U89(C, G or A) mutants of 5S rRNAs and the activities of the corresponding 70S ribosomes were studied. The U89C mutant behaves similarly to the wild-type 5S rRNA. Replacement of the pyrimidine base at position U89 by more bulky purine bases impairs the incorporation of 5S rRNA into 50S subunits, whereas the particles formed showed full activities in poly(U)-dependent poly(Phe) synthesis in the presence of either U89G or U89A 5S rRNA mutants. The activity of the reconstituted particles depends on the incorporation of 5S rRNA in agreement with early observations.

The ribosomal elongation cycle and the movement of tRNAs across the ribosome

Ribosome research has reached an exciting state, where two lines of experimental research have considerably improved our understanding of the ribosomal functions. On one hand, functional analysis has elucidated principles of both the decoding process and the tRNA movement on the ribosome during translocation. Experimental data leading to current competing models of the ribosomal elongation cycle can be reconciled by a new model, the alpha-epsilon model, according to which both tRNAs are tightly bound to a movable ribosomal domain. This alpha-epsilon domain carries the tRNA2.mRNA complex from the A and P sites to the P and E sites in the course of translocation maintaining the binding of both tRNAs. On the other hand, the location of tRNAs within the elongating ribosome can be directly determined for the first time by neutron scattering and electron microscopy. Both lines of evidence complement each other and define a frame for the first experimentally sound functional model of the elongating ribosome.

Solution scattering structural analysis of the 70 S Escherichia coli ribosome by contrast variation. II. A model of the ribosome and its RNA at 3.5 nm resolution

Selectively deuterated 70 S E. coli ribosomes and isolated 30 S and 50 S subunits were analyzed by X-ray and neutron solution scattering. The resulting contrast variation data set (42 curves in total) was proven to be consistent in describing the ribosome as a four-phase system composed of the protein and rRNA moieties of both subunits. This data set thus provides ten times more information than a single scattering curve. A solid body four-phase model of the 70 S ribosome at low resolution was built from the envelope functions of the 30 S and 50 S subunits and of those of the corresponding RNA moieties. The four envelopes were parameterized at a resolution of 3.5 nm using spherical harmonics and taking into account interface layers between the phases. The initial approximation for the envelopes of the subunits was taken from electron microscopic data presented recently by J. Frank and co-workers (Albany); the rRNA envelopes were initially approximated by spheres. The optimization and the refinement of the model proceeded by non-linear least squares minimization fitting the available experimental data. The refined envelopes of the subunits differ by about 10% from the starting approximation and the shape of the final 70 S model lies between the outer envelopes of the models by Frank and by M. von Heel & R. Brimacombe (Berlin). The rRNA moiety in the 30 S subunit is more anisometric than the subunit itself, whereas the rRNA of the 50 S subunit forms a compact core. The rRNAs protrude to the surfaces of the subunits and occupy approximately 30 to 40% of the corresponding surface areas. X-ray scattering curves of the two main functional elongation 70 S complexes (pre- and post-translocational) differ only marginally from those of the non-programmed ribosomes, suggesting that the low resolution four-phase model is also valid for the elongating 70 S ribosome.

Solution scattering structural analysis of the 70 S Escherichia coli ribosome by contrast variation. I. Invariants and validation of electron microscopy models

Solutions of selectively deuterated 70 S Escherichia coli ribosomes and of free 30 S and 50 S subunits were studied by neutron scattering using contrast variation. The integrity of the partially deuterated particles was controlled by parallel X-ray measurements. Integral parameters of the entire ribosome, of its subunits and of the protein and rRNA moieties were evaluated. The data allow an experimental validation of the two most recent electron microscopy reconstructions of the 70 S ribosome presented by the groups of J. Frank (Albany) and of M. van Heel & R. Brimacombe (Berlin). For each reconstruction, integral parameters and theoretical scattering curves from the 70 S and its subunits were calculated and compared with the experimental data. Although neither of the two models yields a comprehensive agreement with the experimental data, Frank's model provides a better fit. For the 50 S subunit of van Heel & Brimacombe's model the fit with the experimental data improves significantly when the internal channels and tunnels are filled up. The poorer fit of the latter model is thus caused by its "sponge"-like structure which may partly be due to an enhancement of high frequency contributions in some of the steps of the three-dimensional image reconstruction. It seems therefore unlikely that the ribosome has a "sponge"-like structure with a pronounced network of channels.

Three tRNA binding sites in rabbit liver ribosomes and role of the intrinsic ATPase in 80S ribosomes from higher eukaryotes

Three tRNA binding sites have been found in organisms of all domains (former kingdoms) with only one exception: Four binding sites have been reported for cytoplasmic 80S ribosomes from rabbit liver. Therefore, the issue was reconsidered, and the data revealed that rabbit liver ribosomes contain three tRNA binding sites, underlining the universal character of this ribosomal feature. Furthermore, a first analysis of the role of the ribosome intrinsic ATPase was performed. This ATPase is found in ribosomes of higher eukarya but not in lower eukarya such as yeast or ribosomes of the domains archea and bacteria. The results suggest that the intrinsic ATPase fulfills the same function as the essential third elongation factor EF-3, an ATPase in higher fungi (yeast etc.), that facilitates the release of the deacylated tRNA from the E site.

Large-scale isolation of proteins of the large subunit from Escherichia coli ribosomes

A strategy has been developed and optimized that allows the isolation of proteins of the large subunit from Escherichia coli ribosomes and combines the following advantages: speed, applicability for the isolation of milligram amounts of a single protein, and preservation of the biological activity of the proteins. The method consists of the following steps: ion-exchange chromatography on MonoS and MonoQ, gel filtration on Sephadex 75, and salt washes. Eleven proteins can be purified by a single chromatographic step, and a combination of two steps enables the isolation of the other proteins.

Direct localization of the tRNAs within the elongating ribosome by means of neutron scattering (proton-spin contrast-variation)

A new technique for neutron scattering, the proton-spin contrast-variation, improves the signal-to-noise ratio more than one order of magnitude as compared to conventional techniques. The improved signal enables small RNA ligands within a large deuterated ribonucleic acid-protein complex to be measured. We used this technique to determine the positions of the two tRNAs within the elongating ribosome before and after translocation. Using a four-sphere model for each of the L-shaped tRNAs, unequivocal solutions were found for the localization of the mass centre of both tRNAs. The centre of gravity is located in the interface cavity separating the ribosomal subunits near the neck of the 30 S subunit. It moves during translocation by 12(+/-4) A towards the head of the 30 S subunit and slightly towards the L1 protuberance of the 50 S subunit.

Conserved nucleotides of 23 S rRNA located at the ribosomal peptidyltransferase center

Two nucleotides of the 23 S rRNA gene were mutated; the nucleotides correspond to the first two positions of the universally conserved sequence PsiGG2582 at the peptidyltransferase ring of 23 S rRNA. The ribosomes containing the altered 23 S rRNA were analyzed. Previously, it was shown that ribosomal assembly was indistinguishable from that in wild-type cells, that the flow of the corresponding 50 S subunit into the polysome fraction was not restricted, but that the ribosomes were strongly impaired in poly(Phe) synthesis (C. M. T. Spahn, J. Remme, M. A. Schäfer, and K. H. Nierhaus (1996) J. Biol. Chem. 271, 32849-32856). Here we apply assay systems exclusively testing the puromycin reaction of ribosomes carrying plasmid-born rRNA, a dipeptide assay using the minimal P site donor pA(fMet) and a translocation system not depending on the puromycin reaction. The mutations in helix 90 exclusively abolish or severely impair the ribosome capability to catalyze AcPhe-puromycin formation. A possible explanation of these observations is that G2581 and Psi2580 (and possibly also G2582) are part of the binding site of C75 of peptidyl-tRNA in the P site. The results suggest that in this case, however, such an interaction would disobey canonical base pairing.

Mutational analysis of two highly conserved UGG sequences of 23 S rRNA from Escherichia coli

The 23 S-type rRNA contains two phylogenetically conserved UGG sequences, which have the potential to bind the universal CCA-3'-ends of tRNAs at the ribosomal peptidyltransferase center by base pairing. The first two positions, UG, of these sequences at the helix-loop 80 (U2249G2250) and helix-loop 90 (Psi2580G2581) and some related nucleotides were tested by site-directed mutagenesis for their involvement in ribosomal function, i.e. peptidyltransferase. The plasmid-derived mutated 23 S rRNA comprised about 50% of the total 23 S rRNA. None of the single mutations caused an assembly defect, and all 50 S subunits carrying an altered 23 S rRNA could freely exchange with the pools of 70S ribosomes and polysomes. The mutations at the helix-loop 80 region hardly affected bacterial growth. However, mutations at the helix 90 caused severe growth effects and severely impaired the in vitro protein synthesis, showing that this 23 S rRNA region is of high importance for ribosomal function.

[Phosphate sites of RNA-ligands interacting with ribosome at different stages of translation. Thiophosphate method of analysis]

A novel footprinting method was recently developed which identifies phosphate groups of RNA involved in strong RNA-RNA and RNA-protein interactions. The method is based on iodine-dependent RNA cleavage at phosphothioate groups as long as these groups are not protected from iodine. Our recent studies of mRNA and tRNA regions protected in active ribosomes are summarized; initiation state of ribosomes as well as two elongation states in pre- and post-translocational states were analyzed. Only one phosphate group of mRNA, which was two positions upstream of the decoding codons, was weakly protected in longation complexes, whereas this group and the phosphate groups in the Shine-Dalgarno sequence were protected in the initiation complex. No protection was observed downstream of the decoding codons. On the contrary, numerous phosphate residues of tRNA were protected by the ribosome. The tRNA protection patterns significantly varied between two tRNAs simultaneously bound to the ribosome. The protection pattern of an individual tRNA was not significantly affected by translocation. The data indicate that both tRNA molecules are tightly bound to the ribosome, whereas mRNA is fixed predominantly by two tRNAs via codon-anticodon interaction. A possible translocation mechanism is suggested.

Effects of antisense DNA against the alpha-sarcin stem-loop structure of the ribosomal 23S rRNA

Antisense DNAs complementary against various sequences of the alpha-sarcin domain (C2646-G2674) of 23S rRNA from Escherichia coli were hybridized to naked 23S rRNA as well as to 70S ribosomes. Saturation levels of up to 0.4 per 70S ribosome were found, the identical fraction was susceptible to the attack of the RNase alpha-sarcin. The hybridization was specific as demonstrated with RNase H digestion, sequencing the resulting fragments and blockage of the action of alpha-sarcin. The RNase alpha-sarcin seems to approach its cleavage site from the 3' half of the loop of the alpha-sarcin domain. Hybridization is efficiently achieved at 37 degrees C and can extend at least into the 3' strand of the stem of the alpha-sarcin domain. However, the inhibition of alpha-sarcin activity is observed at 30 degrees C but not at 37 degrees C. For a significant inhibition of poly(Phe) synthesis the temperature had to be lowered to 25 degrees C. The results imply that the alpha-sarcin domain changes its conformation during protein synthesis and that the conformational changes may include a melting of the stem of the alpha-sarcin domain.

5S rRNA sugar-phosphate backbone protection in complexes with specific ribosomal proteins

5S ribosomal RNA forms stable specific complexes with ribosomal proteins L18, L25 and L5. In this work, interaction of phosphate residues of E. coli 5S rRNA within 5S rRNA-protein complexes has been studied. For this purpose 5S rRNA with statistically distributed phosphorothioate residues has been used for complex formation and the accessibility of phosphorothioates to iodine cleavage in the complex and in the free state has been studied. In free 5S rRNA, the phosphate residue at A73 was partially protected, probably due to being involved in the organization of the spatial structure of 5S rRNA. This protection is stronger in the complex with three proteins when the 5S rRNA structure is stabilized. In the 5S rRNA-L18 complex only two phosphate groups, G7 and A34, were protected. L25 in a complex with 5S rRNA protects large numbers of phosphorothioate groups concentrating in two clusters, indicating the possibility of two binding sites for this protein on 5S rRNA. The protection pattern differs from that for individual proteins because of the possible rearrangement of the structure.