Isolation of tRNA isoacceptors by affinity chromatography on immobilized bacterial elongation factor Tu

Aminoacyl RNA domain of turnip yellow mosaic virus Val-RNA interacting with elongation factor Tu

Turnip yellow mosaic virus (TYMV) Val-RNA forms a complex with the peptide elongation factor Tu (EF-Tu) in the presence of GTP: the Val-RNA is protected by EF-Tu.GTP from non-enzymatic deacylation and nuclease digestion. The determination of the length of the shortest TYMV Val-RNA fragment that binds EF-Tu.GTP leads us to conclude that the valylated aminoacyl RNA domain equivalent in tRNAs to the continuous helix formed by the acceptor stem and the T arm is sufficient for complex formation. Since the aminoacyl RNA domain is also sufficient for adenylation by the ATP(CTP):tRNA nucleotidyltransferase, an analogy can be drawn between these two tRNA-specific proteins.

Fluorophore labeling to monitor tRNA dynamics

Transfer RNA (tRNA) molecules mediate translation of the nucleic acid genetic code into the amino acid building blocks of proteins, thus ensuring the survivability of cells. The dynamic properties of tRNA molecules are crucial to their functions in both activity and specificity. This chapter summarizes two methods that have been recently developed or improved upon previous protocols to introduce fluorophores to site-specific positions in tRNA. One method enables incorporation of fluorophores carrying a primary amine (such as proflavin or rhodamine) to dihydrouridine (D) residues in the tRNA tertiary core, and a second method enables incorporation of pyrroloC and 2-aminopurine to positions 75 and 76, respectively, of the CCA sequence at the 3' end. These site-specific fluorophore labeling methods utilize tRNA transcripts as the substrates to provide the versatility with both wild-type and mutant sequences for examining their motions in space and time during the process of decoding genetic information.

Exp5 exports eEF1A via tRNA from nuclei and synergizes with other transport pathways to confine translation to the cytoplasm

Importin beta-type transport receptors mediate the vast majority of transport pathways between cell nucleus and cytoplasm. We identify here the translation elongation factor 1A (eEF1A) as the predominant nuclear export substrate of RanBP21/exportin 5 (Exp5). This cargo-exportin interaction is rather un usual in that eEF1A binds the exportin not directly, but instead via aminoacylated tRNAs. Exp5 thus represents the second directly RNA-binding exportin and mediates tRNA export in parallel with exportin-t. It was suggested recently that 10-15% of the cellular translation would occur in the nucleus. Our data rule out such a scenario and instead suggest that nuclear translation is actively suppressed by the nuclear export machinery. We found that the vast majority of translation initiation factors (eIF2, eIF2B, eIF3, eIF4A1, eIF5 and eIF5B), all three elongation factors (eEF1A, eEF1B and eEF2) and the termination factor eRF1 are strictly excluded from nuclei. Besides Exp5 and importin 13, CRM1 and as yet unidentified exportins also contribute to the depletion of translation factors from nuclei.

Isolation of tRNA isoacceptors by affinity chromatography with immobilized elongation factor Tu from Escherichia coli

Elongation factor Tu (EF-Tu) from E. coli was coupled to activated CH Sepharose 4B. The immobilized EF-Tu maintained most of the guanosine nucleotide binding activity, but its ability to bind aminoacyl-tRNA depended on the type of complex used in the coupling reaction. The EF-Tu.GTP.aminoacyl-tRNA.kirromycin complex yielded an immobilized factor that was much more active in binding aminoacyl-tRNA than that obtained by coupling EF-Tu.GDP or EF-Tu.GDP.kirromycin to CH Sepharose 4B. Like the free factor, the immobilized EF-Tu.GTP did bind aminoacyl-tRNAs, but not unacylated tRNAs or N-acylated-aminoacyl-tRNAs. The antibiotic kirromycin was used to obtain the rapid conversion of EF-Tu.GDP to EF-Tu.GTP and the release of aminoacyl-tRNA from the matrix-bound EF-Tu by GDP. When total tRNA was aminoacylated by one amino acid only, a column of immobilized EF-Tu-GTP.kirromycin allowed the isolation of the aminoacylated tRNA from bulk tRNA. A rapid and nearly quantitative recovery of highly purified tRNA isoacceptors for various amino acids was obtained in one chromatographic step.

Discrimination against misacylated tRNA by chloroplast elongation factor Tu

Chloroplast elongation factor Tu was purified from Pisum sativum and the binding properties of glutamylated chloroplast tRNAs were studied by gel-permeation chromatography. Whereas chloroplast Glu-tRNA(Glu) is efficiently bound by this factor, the misacylated Glu-tRNA(Gln) does not interact with chloroplast elongation factor Tu.GTP and is thus efficiently excluded from protein synthesis. Comparison with the behaviour of Escherichia coli elongation factor Tu.GTP shows that this factor, which is not confronted with the in vivo misacylation phenomenon of organelles, binds both Glu-tRNA(Glu) and Glu-tRNA(Gln) from chloroplasts with approximately equal efficiency.

Partial release of AcPhe-Phe-tRNA from ribosomes during poly(U)-dependent poly(Phe) synthesis and the effects of chloramphenicol

Poly(U)-programmed 70S ribosomes can be shown to be 80% to 100% active in binding the peptidyl-tRNA analogue AcPhe-tRNA to their A or P sites, respectively. Despite this fact, only a fraction of such ribosomes primed with AcPhe-tRNA participate in poly(U)-directed poly(Phe) synthesis (up to 65%) at 14 mM Mg2+ and 160 mM NH4+. Here it is demonstrated that the apparently 'inactive' ribosomes (greater than or equal to 35%) are able to participate in peptide-bond formation, but lose their nascent peptidyl-tRNA at the stage of Ac(Phe)n-tRNA, with n greater than or equal to 2. The relative loss of early peptidyl-tRNAs is largely independent of the degree of initial saturation with AcPhe-tRNA and is observed in a poly(A) system as well. This observation resolves a current controversy concerning the active fraction of ribosomes. The loss of Ac(Phe)n-tRNA is reduced but still significant if more physiological conditions for Ac(Phe)n synthesis are applied (3 mM Mg2+, 150 mM NH4+, 2 mM spermidine, 0.05 mM spermine). Chloramphenicol (0.1 mM) blocks the puromycin reaction with AcPhe-tRNA as expected but, surprisingly, does not affect the puromycin reaction with Ac(Phe)2-tRNA nor peptide bond formation between AcPhe-tRNA and Phe-tRNA. The drug facilitates the release of Ac(Phe)2-4-tRNA from ribosomes at 14 mM Mg2+ while it hardly affects the overall synthesis of poly(Phe) or poly(Lys).

Interaction of a selenocysteine-incorporating tRNA with elongation factor Tu from E.coli

Selenocysteine-incorporating tRNA(Sec)(UCA), the product of selC, was isolated from E.coli and aminoacylated with serine. The equilibrium dissociation constant for the interaction of Ser-tRNA(Sec)(UCA) with elongation factor Tu.GTP was determined to be 5.0 +/- 2.5 x 10(-8) M. Compared with the dissociation constants of the two elongator Ser-tRNA(Ser) species (Kd = 7 x 10(-10) M), the selenocysteine-incorporating UGA suppressor tRNA has an almost hundred fold weaker affinity for EF-Tu.GTP. This suggests a mechanism by which the Ser-tRNA(Sec) is prevented in recognition of UGA codons. This tRNA is not bound to EF-Tu.GTP and is converted to selenocysteinyl-tRNA(Sec). We also demonstrate the lack of an efficient interaction of Sec-tRNA(Sec)(UCA) with EF-Tu.GTP. The results of this work are in support of a mechanism by which the selenocysteine incorporation at UGA nonsense codons is mediated by an elongation factor other than EF-Tu.GTP.

Is the three-site model for the ribosomal elongation cycle sound?

The release of deacylated tRNA from the ribosome as a result of translocation has been studied. Translating ribosomes prepared with poly(U)-S-S-Sepharose columns have been used. It has been shown that deacylated tRNA released from the ribosomal P site as a result of translocation rebinds with the vacated A site. Consistent with the known properties of the A site of the ribosome, this interaction is reversible, Mg2+-dependent, codon-specific and is inhibited by the antibiotic tetracycline. It has been concluded that the proposed three-site model of the ribosomal elongation cycle (Rheinberger and Nierhaus (1983) Proc. Natl. Acad. Sci. USA 80, 4213-4217) is not sound: the experimentally observed 'retention' of the deacylated tRNA on the ribosome after translocation can be explained by a codon-dependent rebinding to the A site, rather than by its transition to the 'E site', i.e., in terms of the classical two-site model.

Sequence and identification of the nucleotide binding site for the elongation factor Tu from Thermus thermophilus HB8

Two structural genes for the Thermus thermophilus elongation factor Tu (tuf) were identified by cross-hybridization with the tufA gene from E. coli. The sequence of one of these tuf genes, localized on a 6.6 kb Bam HI fragment, was determined and confirmed by partial protein sequencing of an authentic elongation factor Tu from T. thermophilus HB8. Expression of this tuf gene in E. coli minicells provided a low amount of immuno-precipitable thermophilic EF-Tu. Affinity labeling of the T. thermophilus EF-Tu and sequence comparison with homologous proteins from other organisms were used to identify the guanosine-nucleotide binding domain.

Resolution of RNA using high-performance liquid chromatography

High-performance liquid chromatographic techniques can be very effective for the resolution and isolation of nucleic acids. The characteristic ionic (phosphodiesters) and hydrophobic (nucleobases) properties of RNAs can be exploited for their separation. In this respect anion-exchange and reversed-phase chromatography have been successfully employed in the analysis and/or isolation of RNAs. In some cases, particularly tRNAs, chromatographic separations which rely upon multiple interactions between the solute and mobile and/or stationary phases have been highly effective. Mixed-mode chromatography involving simultaneous ionic and hydrophobic interactions, has been employed to resolve complex mixtures of tRNAs. Hydrophobic-interaction chromatography using gradients of decreasing salt concentration and weakly hydrophobic stationary phases has allowed the resolution of some tRNA mixtures as well as the analysis of modified materials.

Purification of individual tRNAs using a monoclonal anti-AMP antibody affinity column

A murine monoclonal anti-AMP antibody affinity matrix was used for isolation of individual species of amino acid transfer nucleic acids (tRNAs). The antibodies had been prepared using 5'-AMP covalently attached to bovine serum albumin as antigen and exhibited high affinity for 5'-AMP but greatly reduced affinity for 3'-AMP. Native uncharged tRNAs that terminate in a 5'-AMP group on the amino acid acceptor arm of the molecule bind tightly to the anti-AMP affinity matrix, whereas aminoacylated tRNAs are not retained. This allows separation of a particular tRNA species as its aminoacyl derivative from a complex mixture of uncharged tRNAs under very mild conditions.

Transfer ribonucleic acid populations in concanavalin-A-stimulated bovine lymphocytes

Transfer RNA isolated from lymphocytes stimulated by concanavalin A and that from resting cells were compared with respect to amino-acid acceptance, integrity of the CCA-terminus, extent of modification and isoacceptor distribution. Following growth stimulation the overall amino-acid acceptance of the tRNA is elevated, in particular the relative acceptor activities for threonine and arginine are increased. The reduced acceptor activity of the tRNA from the quiescent cells is not due to a preferential degradation of the CCA-end, since it persists even in the presence of ATP(CTP):tRNA nucleotidyltransferase. We therefore conclude that this reduced activity is caused by structural differences of the tRNAs. The content of modified nucleotides in newly synthesized tRNA from lymphocytes cultured in the presence and absence of concanavalin A was determined. tRNA from resting cells was found to be undermodified with respect to pseudouridine and dihydrouridine. Upon monitoring the tRNA isoacceptor distribution by affinity chromatography on immobilized elongation factor Tu and subsequent two-dimensional gel electrophoresis, a preferential synthesis of particular lysine- and threonine-accepting tRNAs was observed upon mitogenic stimulation. Evidently, a specific tRNA population is needed by the proliferating cells. These results are discussed in view of the hypothesis that the commitment of lymphocytes to proliferation is at least in part under translational control.

Ser-tRNAs from bovine mitochondrion form ternary complexes with bacterial elongation factor Tu and GTP

Transfer ribonucleic acids were isolated from mitochondria of bovine heart and aminoacylated in vitro by a crude mitochondrial enzyme. Ser-tRNASerUCN and Ser-tRNASerAGY were isolated and characterized by partial sequencing. Although these tRNAs possess unique structural features not found in any bacterial tRNA, they form a ternary complex with elongation factor from the extreme thermophilic bacterium Thermus thermophilus and GTP.

Interaction of methionine-specific tRNAs from Escherichia coli with immobilized elongation factor Tu

The interaction of three different Met-tRNAsMet from E. coli with bacterial elongation factor (EF) Tu X GTP was investigated by affinity chromatography. Met-tRNAfMet which lacks the base pair at the end of the acceptor stem binds only weakly to EF-Tu X GTP, while Met-tRNAmMet has a high affinity for the elongation factor. A modified Met-tRNAfMet which has a C1-G72 base pair binds much more strongly to immobilized EF-Tu X GTP than the native aminoacyl(aa)-tRNA with non-base-paired C1A72 at this position, demonstrating that the base pair including the first nucleotide in the tRNA is one of the essential structural requirements for the aa-tRNA X EF-Tu X GTP ternary complex formation.

Analysis of modification-dependent structural alterations in the anticodon loop of Escherichia coli tRNAArg and their effects on the translation of MS2 RNA

The conformation of the anticodon loop of Escherichia coli tRNAArg was investigated. It is shown that the structure of the anticodon loop is influenced by the base composition of the anticodon stem, and the natural modification of the nucleoside residue 32 in the anticodon loop. The structural effects detected by analysis of the accessibility of the anticodon loop to nuclease S1 could be correlated with the ability of different Arg-tRNAArg species to suppress frame-shifting during translation of MS2 RNA.