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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.

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Sparsomycin, a broad-spectrum antibiotic, acts at the peptidyl transferase centre of the ribosome, stabilizing peptidyl-tRNA binding at the P-site and weakening ternary complex binding. A sparsomycin-resistant mutant was isolated for the archaeon Halobacterium salinarium and shown to lack a post-transcriptional modification of U2603 (Escherichia coli numbering U2584), which is a universally conserved uridine base located within the peptidyl transferase loop of 23 S rRNA. This mutant also exhibited altered sensitivities to the peptidyl transferase antibiotics anisomycin, chloramphenicol and puromycin. Several lines of evidence indicate that the unmodified uridine base lies within the P-substrate site of the peptidyl transferase centre.

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The present review attempts to deal with movement of tRNA substrates through the peptidyl transferase centre on the large ribosomal subunit and to explain how this movement is interrupted by antibiotics. It builds on the concept of hybrid tRNA states forming on ribosomes and on the observed movement of the 5' end of P-site-bound tRNA relative to the ribosome that occurs on peptide bond formation. The 3' ends of the tRNAs enter, and move through, a catalytic cavity where antibiotics are considered to act by at least three primary mechanisms: (i) they interfere with the entry of the aminoacyl moiety into the catalytic cavity before peptide bond formation; (ii) they inhibit movement of the nascent peptide along the peptide channel, a process that may generally involve destabilization of the peptidyl tRNA, and (iii) they prevent movement of the newly deacylated tRNA between the P/P and hybrid P/E sites on peptide bond formation.

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Ribosomal binding sites were investigated for the diverse group of antibiotics: anisomycin, anthelmycin, blasticidin S, bruceantin, carbomycin, chloramphenicol, griseoviridin, narciclasine, T2 toxin, tylosin and virginiamycin M1 all of which are considered to inhibit the peptidyl transferase reaction by different mechanisms. The drugs also exhibit differing degrees of specificity for bacterial, archaeal and eukaryotic ribosomes despite a high level of conservation of sequence and secondary structure at the peptidyl transferase centre of the 23 S-like rRNAs. The drug binding sites were characterized by incubating each antibiotic with ribosomes from a bacterium, an archaeon and a eukaryote and chemically probing the 23 S-like rRNA. The complexity of the changes in reactivity ranged from one or two nucleotides (anthelmycin, narciclasine) to eight or nine (virginiamycin M1) and it was inferred, at least for those drugs producing complex changes, that they induce, and stabilize, a particular functional conformer in the peptidyl transferase centre. The results were correlated with literature data on both ribosomal ligand binding and the putative inhibitory mechanisms of the drugs, and the following inferences are made concerning the fine structure of the peptidyl transferase centre. (1) An irregular secondary structural motif, which includes unpaired A2439 (Escherichia coli numbering), lies close to the catalytic centre; (2) nucleotides A2451 and C2452 contribute to a site for the binding of the side chains of aromatic amino acids; (3) the P-substrate site encompasses U2585, U2506 and, possibly, a site in domain IV (A1787), and (4) the sequence A2058 to A2062 and nucleotide U2609 contribute to, or modulate, the start of the peptide channel. No drug effects were found that could be directly attributed to an A-site and the possibility is raised that, if it exists, it consists mainly of ribosomal proteins. However, two drugs T2 toxin and virginiamycin M1 protected the only nucleotide in the peptidyl transferase loop region (C2394) associated with the E-site. Finally, it is proposed that the putative sub-sites are physically separated, that some drugs bind to more than one of them, and that they are conformationally interdependent.

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The binding site and probable site of action have been determined for the universal antibiotic amicetin which inhibits peptide bond formation. Evidence from in vivo mutants, site-directed mutations and chemical footprinting all implicate a highly conserved motif in the secondary structure of the 23S-like rRNA close to the central circle of domain V. We infer that this motif lies at, or close to, the catalytic site in the peptidyl transfer centre. The binding site of amicetin is the first of a group of functionally related hexose-cytosine inhibitors to be localized on the ribosome.

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