Mechanism of codon-anticodon interaction in ribosomes: comparative study of interaction of Phe-tRNAPhe and N-acetyl-Phe-tRNAPhe with the donor site of Escherichia coli ribosomes

Movement of the 3'-end of tRNA through the peptidyl transferase centre and its inhibition by antibiotics

Determining how antibiotics inhibit ribosomal activity requires a detailed understanding of the interactions and relative movement of tRNA, mRNA and the ribosome. Recent models for the formation of hybrid tRNA binding sites during the elongation cycle have provided a basis for re-evaluating earlier experimental data and, especially, those relevant to substrate movements through the peptidyl transferase centre. With the exception of deacylated tRNA, which binds at the E-site, ribosomal interactions of the 3'-ends of the tRNA substrates generate only a small part of the total free energy of tRNA-ribosome binding. Nevertheless, these relatively weak interactions determine the unidirectional movement of tRNAs through the ribosome and, moreover, they appear to be particularly susceptible to perturbation by antibiotics. Here we summarise current ideas relating particularly to the movement of the 3'-ends of tRNA through the ribosome and consider possible inhibitory mechanisms of the peptidyl transferase antibiotics.

tRNA regions which contact with the ribosomal poly(U)-programmed P-site

Equilibrium binding affinity of yeast tRNA(Phe) for Escherichia coli poly(U)-programmed 70S ribosomal P-site was compared with corresponding affinities of several tRNA(Phe) 3'- and 5'-end-truncated derivatives, all containing the anticodon arm. Our findings strongly suggest that besides three 3'-terminal-CCA nucleotides (C74, C75 and A76), only the tRNA(Phe) anticodon arm (N28-N42) contains ribosomal P-site contact centers and that there are no such centers in the intermediate regions N1-N27 and N43-N73.

Effect of the nucleotide-37 on the interaction of tRNA(Phe) with the P site of Escherichia coli ribosomes

The method of anticodon loop replacement has been used to make derivatives of yeast tRNA(Phe) with the substitution at position 37 (tRNA(Phe)GAAA) and at the anticodon(tRNA(Phe)GCAG). A quantitative study of the interaction of various types of deacylated yeast tRNA(Phe) (tRNA(Phe)+Y, tRNA(Phe)GAAA, tRNA(Phe)-Y) with the P site of the [70S ribosome*poly(U)]-complex was carried out at different Mg2+ concentrations and temperatures. The presence and nature of the nucleotide situated at the 3'-end of the anticodon are essential for such interaction in E coli ribosomes. Replacement of the Y base with the unmodified adenosine decreases the interaction enthalpy from 39 kcal/mol to 24 kcal/mol, whereas its removal reduces the interaction enthalpy to 16 kcal/mol. Replacement of the second anticodon nucleotide, adenosine, with cytosine further reduces the enthalpy to 6 kcal/mol, which is typical of tRNA-P site interaction in the absence of poly(U). In the absence of poly(U) the affinity of tRNA(PheY) for the P site of the 70S ribosome is five times lower than the affinity of tRNA(Phe+Y) or tRNA(Phe)GCAG. Thus, in the ribosome the modified nucleotide stabilizes the codon-anticodon interaction through its stacking interaction with the codon-anticodon base stack. In addition, this decreases the free energy of binding as a result of the interaction of the modified nucleotide itself with the hydrophobic center of the P site.

Interaction of human and Escherichia coli tRNA(Phe) with human 80S ribosomes in the presence of oligo- and polyuridylate templates

Human placenta and Escherichia coli Phe-tRNA(Phe) and N-AcPhe-tRNA(Phe) binding to human placenta 80S ribosomes was studied at 13 mM Mg2+ and 20 degrees C in the presence of poly(U), (pU)6 or without a template. Binding properties of both tRNA species were studied. Poly(U)-programmed 80S ribosomes were able to bind charged tRNA at A and P sites simultaneously under saturating conditions resulting in effective dipeptide formation in the case of Phe-tRNA(Phe). Affinities of both forms of tRNA(Phe) to the P site were similar (about 1 x 10(7) M-1) and exceeded those to the A site. Affinity of the deacylated tRNA(Phe) to the P site was much higher (association constant > 10(10) M-1). Binding at the E site (introduced into the 80S ribosome by its 60S subunit) was specific for deacylated tRNA(Phe). The association constant of this tRNA to the E site when A and P sites were preoccupied with N-AcPhe-tRNA(Phe) was estimated as (1.7 +/- 0.1) x 10(6) M-1. In the presence of (pU)6, charged tRNA(Phe) bound loosely at the A and P sites, and the transpeptidation level exceeded the binding level due to the exchange with free tRNA from solution. Affinities of aminoacyl-tRNA to the A and P sites in the presence of (pU)6 seem to be the same and much lower than those in the case of poly(U). Without a messenger, binding of the charged tRNA(Phe) to 80S ribosomes was undetectable, although an effective transpeptidation was observed suggesting a very labile binding of the tRNA simultaneously at the A and P sites.

Alkaloid homoharringtonine inhibits polypeptide chain elongation on human ribosomes on the step of peptide bond formation

The aim of the present study was to investigate homoharringtonine alkaloid effect on: (i) the nonenzymatic and eEF-1-dependent Phe-tRNAPhe binding to poly(U)-programmed human placenta 80 S ribosomes; (ii) diphenylalanine synthesis accompanying nonenzymatic Phe-tRNAPhe binding; and (iii) acetylphenylalanyl-puromycin formation. Neither nonenzymatic nor eEF-1-dependent Phe-tRNAPhe binding were noticeably affected by the alkaloid, whereas diphenylalanine synthesis and puromycin reaction were strongly inhibited by homoharringtonine. It has been proposed that the site of homoharringtonine binding on 80 S ribosomes should overlap or coincide with the acceptor site of the ribosome.

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.

Intersubunit RNA-protein contacts in pre- and post-translocated E. coli ribosome

Ribosomal proteins participating in intersubunit RNA-protein contacts (directly interacting with RNA of the opposite subunit) were determined by means of ultraviolet-induced cross-links in pre- and post-translocated ribosomal complexes, as well as in the free 70 S ribosome (tight couple) of E. coli. In these 3 complexes at least L1 and L9 proteins interact with 16 S RNA, while S6, S9/11 and S15 react with 23 S RNA. All these proteins ('hinge-joint' proteins) are clustered on the small protuberance of the 50 S subunit and on the platform of the 30 S subunit. Reduction in the number of other (variable) intersubunit RNA-protein contacts in the course of transition from the tight couple to the pre- and, finally, to the post-translocated state, demonstrates gradual loosening of intersubunit interactions in 70 S ribosome. Such a loosening ('opening') of the 70 S ribosome is determined by conformational changes in ribosomal subunits and/or in their relative arrangement, conjugated with alteration of the functional state of the ribosomal complex.

Quantitative study of interaction of deacylated tRNA with Escherichia coli ribosomes. Role of 50 S subunits in formation of the E site

The 30 S subunit contains 2 sites for tRNA binding (Phe-tRNA, AcPhe-tRNA, tRNAPheOH) with the functional properties of D and A sites of the 70 S ribosome after attachment of 50 S subunit. The third (E) site specific for deacylated tRNA is introduced into 70 S ribosome by its 50 S subunit. The E-site binding of tRNAPheOH is not sensitive to either tetracycline and edeine, and practically codon-independent. The affinity constant of tRNAPheOH for the E site is 2-3 orders of magnitude lower than that for the D site.

Binding of tRNA to Escherichia coli ribosomes as measured by velocity sedimentation

We followed the binding of initiator and elongator tRNA to 70-S ribosomes and its subunits by velocity sedimentation in the analytical ultracentrifuge. This technique shows the advantage over the previously used methods (adsorption of the complexes to nitrocellulose filters or fluorescence titrations) in that no kinetic effects obscure the equilibrium data and that none of the components has to be chemically modified. The concentrations of the macromolecular compounds are kept constant and the binding equilibria are shifted by varying the Mg2+ concentration in a range which is accessible to experimental analysis. Free 30-S ribosomes bind no tRNA, whereas one tRNA molecule is bound to 50-S ribosomal subunits. In the presence of the cognate codon one tRNA can be associated with the small subunit. Free, programmed, or misprogrammed 70-S ribosomes bind exactly two elongator tRNAs. Only the initiator tRNA does discriminate significantly between the two ribosomal sites when bound to a ribosome . A-U-G complex.