The ribosomal peptidyl transferase

Peptide bond formation on the ribosome takes place in an active site composed of RNA. Recent progress of structural, biochemical, and computational approaches has provided a fairly detailed picture of the catalytic mechanism of the reaction. The ribosome accelerates peptide bond formation by lowering the activation entropy of the reaction due to positioning the two substrates, ordering water in the active site, and providing an electrostatic network that stabilizes the reaction intermediates. Proton transfer during the reaction appears to be promoted by a concerted proton shuttle mechanism that involves ribose hydroxyl groups on the tRNA substrate.     

Structural analysis of ribosomal DNA homologues in nucleolus-less mutant of Xenopus laevis

Sequences homologous to the ribosomal DNA (rDNA) in a Xenopus anucleolate (nucleolus-less) mutant were analyzed by Southern blot analysis. The mutant was found to possess a variety of sequences homologous to non-transcribed spacer (NTS) and/or coding region of rDNA. 65 rDNA-homologous clones were isolated from a genomic DNA library of the mutant. All the clones showed only partial homology to the normal rDNA unit and their restriction maps differed from that of the normal rDNA unit. Based on the hybridization patterns, the rDNA-homologous clones were divided into four groups (I-IV). Structure of group IV, which most strongly hybridized to normal rDNA probe, was analyzed by nucleotide sequencing. The group IV sequence was found to contain a part of the rDNA, including Bam island, enhancer element, promoter region, external transcribed spacer, and a portion of 18S rRNA gene. The blotting analysis suggested that the group IV sequence is specific for a particular strain of Xenopus.     

Kinetic isotope effect analysis of the ribosomal peptidyl transferase reaction

The ribosome is the macromolecular machine responsible for protein synthesis in all cells. Here, we establish a kinetic framework for the 50S modified fragment reaction that makes it possible to measure the kinetic effects that result from isotopic substitution in either the A or P site of the ribosome. This simplified peptidyl transferase assay follows a rapid equilibrium random mechanism in which the reverse reaction is nonexistent and the forward commitment is negligible. A normal effect (1.009) is observed for (15)N substitution of the incoming nucleophile at both low and high pH. This suggests that the first irreversible step is the formation of the tetrahedral intermediate. The observation of a normal isotope effect that does not change as a function of pH suggests that the ribosome promotes peptide bond formation by a mechanism that differs in its details from an uncatalyzed aminolysis reaction in solution. This implies that the ribosome contributes chemically to catalysis of peptide bond formation.     

Structural proteins associated with ribosomal cistrons in Xenopus laevis chromosomes

The N banding technique to define the location of nucleolus organiser in mammalian and marsupial chromosomes was applied to the Xenopus laevis chromosomes. Results obtained are: 1. The N bands coincide with the location of all the clustered ribosomal cistrons including the 18S + 28S RNA genes as well as the 5S RNA genes. 2. The N bands are consistently detected in both metabolically active (interphase) and metabolically inactive (metaphase) nuclei. 3. Cytochemical and chemical extraction tests indicate that the N bands show typical biochemical properties requested for non-histone (residual) chromosomal proteins. 4. Proteins associated with the 5S RNA genes differ, in their acid-solubility, from those for the 18S+28S RNA genes. 5. The N banding proteins comprise a small portion of a total nuclear protein. These findings strongly suggest the existence of ribosomal gene-specific non-histone proteins which probably represent the structural chromatin element rather than the primary gene product. The possible role of N banding proteins in eukaryotes is discussed.     

Affinity labelling of yeast ribosomal peptidyl transferase

Summary Using p-nitrophenylcarbamyl-phenylananyl-tRNA (PNPC-Phe-tRNA) and N-Iodoacetyl-phenylalanyl-tRNA as affinity labels we have attempted to identify the components of the aminoacyl-tRNA binding sites located in the vicinity of the peptidyl transferase centre of the yeast ribosome. Both Phe-tRNA derivatives bind to the ribosomal A-site in the presence of 20 mM Mg⁺⁺ ion concentration and can be translocated to the ribosomal P-site in the presence of elongation factor. After the labels have been allowed to react covalently with ribosomes they were found associated with the large ribosomal subunit. Proteins L36, L43, L42, L29, L2, L17/18, L19/20 and proteins L26, L38, L22/23, L7/9, L4/6, L36, L11, L43, L39 were labelled in samples treated with PNPC-Phe-tRNA and N-Iodoacetyl-Phe-tRNA respectively. In contrast, when only the components of the ribosomal P-site were analysed by reacting the treated particles with puromycin fewer spots were labelled, corresponding to proteins L36 and L19/20 using PNPC-Phe-tRNA and proteins L4/6, L36, and L43 using N-Iodoacetyl-Phe-tRNA.     

Location of the genes for 5S ribosomal RNA in Xenopus laevis

In situ hybridization of 5S RNA and cRNA transcribed in vitro from Xenopus laevis 5S DNA shows that 5S DNA is localized at or near the telomere region of the long arm of many, if not all, of the X. laevis chromosomes. No 5S DNA is detected near the nucleolus organizer in the normal X. laevis chromosome complement, but in a X. laevis kidney cell line, 5S DNA is found at the distal end of the secondary constriction. The arrangement of 5S DNA in several types of interphase nuclei is described. — During the pairing stages of meiosis the telomeres of most or perhaps all of the chromosomes become closely associated so that the regions containing 5S DNA form a single cluster. This close association might be either a cause or a result of the presence of the similar sequences of 5S DNA on many telomeres. It suggests that the uniformity of 5S sequences on non-homologous chromosomes might be maintained by crossing-over between the chromosomes.     

Transcriptional organization of the 5.8S ribosomal RNA cistron in Xenopus laevis ribosomal DNA.

Hybridization of purified, 32p-labeled 5.8S ribosomal RNA from Xenopus laevis to fragments generated from X. laevis rDNA by the restriction endonuclease, EcoRI, demonstrates that the 5.8S rRNA cistron lies within the transcribed region that links the 18S and 28S rRNA cistrons.     

Structural studies on site-directed mutants of domain 3 of Xenopus laevis oocyte 5 S ribosomal RNA

Base substitutions have been introduced into the highly conserved sequences of loops D and E within domain 3 of Xenopus laevis oocyte 5 S rRNA. The effects of these mutations on the solution structure of this 5 S rRNA have been studied by means of probing with nucleases, and with chemical reagents under native and semi-denaturing conditions. The data obtained with these mutants support the graphic model of Xenopus oocyte 5 S rRNA proposed by Westhof et al. In particular, our results rule out the existence of long-range base-pairing interactions between loop C and either loop D or loop E. The data also confirm that loops D and E in the wild-type 5 S RNA adopt unusual secondary structures and illustrate the importance of nucleotide sequence in the formation of intrinsic local loop conformations via non-canonical base-pairs and specific base-phosphate contacts. Consistent with this conclusion is our observation that the domain 3 fragment of Xenopus oocyte 5 S rRNA adopts the same conformation as the corresponding region in the full-length 5 S rRNA.     

Chloramphenicol, erythromycin, carbomycin and vernamycin B protect overlapping sites in the peptidyl transferase region of 23S ribosomal RNA

Using dimethyl sulfate and kethoxal, we have probed antibiotic-ribosome complexes, and identified sites of interaction of chloramphenicol, erythromycin, carbomycin, vernamycin B and viomycin with 23S rRNA. Chloramphenicol, erythromycin, carbomycin and vernamycin B protect overlapping nonequivalent sites in the central loop of domain V. From the known functional effects of these drugs and their protection patterns, we infer that peptidyl transferase is inhibited as a result of binding antibiotics proximal to A-2451, whereas antibiotics bound proximal to A-2058 interfere with growth of the nascent polypeptide chain. Vernamycin B also strongly protects A-752, implying that this region of domain II is proximal to the central loop of domain V. Viomycin, which affects translocation and subunit dissociation, protects U-913 and G-914.     

The nucleotide sequences of 5.8-S ribosomal RNA from Xenopus laevis and Xenopus borealis

1. The nucleotide sequence of 5.8-S rRNA from Xenopus laevis is given; it differs by a C in equilibrium U transition at position 140 from the 5.8-S rRNA of Xenopus borealis. 2. The sequence contains two completely modified and two partially modified residues. 3. Three different 5' nucleotides are found: pU-C-G (0.4) pC-G (0.2) and pG (0.4). 4. The 3' terminus is C not U as in all other 5.8-S sequences so far determined. 5. The X. laevis sequence differs from the mammalian and turtle sequences by five and six residue changes respectively. 6. A ribonuclease-resistant hairpin loop is a principle feature of secondary structure models proposed for this molecule. 7. Sequence heterogeneity may occur at one position at a very low level (approximately 0.01) in X. laevis 5.8-S rRNA, while none was detected in X. borealis or HeLa cell 5.8-S rRNA.     

Interaction of arginine with the ribosomal peptidyl transferase centre.

Arginine inhibits the formation of acetylleucyl-puromycin from C(U)-A-C-C-A-LeuAc and puromycin ('fragment reaction'), catalized by Escherichia coli and yeast ribosomes. From 18 different L-amino acids assayed, arginine was the most effective in producing inhibition (50% inhibition at 20 mM, with 1 mM puromycin). L-Argininamide and D-arginine gave about the same inhibition as L-arginine. The inhibition by L-arginine is competitive with respect to puromycin. The plot of the slopes obtained in a Lineweaver and Burk representation versus [Arg]2, and the plot of 1/v versus [Arg]2 at a fixed concentration of puromycin, are linear, which seems to indicate that two arginine molecules must interact at the puromycin binding site to produce inhibition. In addition to the 'fragment reaction', arginine inhibits the non-enzymatic binding of AcPhe-tRNA, C(U)-A-C-C-A-Leu and C(U)-A-C-C-A-LeuAc to ribosomes. However, it does not inhibit poly(U)-directed polyphenylalanine synthesis or the reaction of puromycin with AcPhe-tRNA previously bound to the peptidyl site. The results agree with arginine binding to the acceptor site, and with a sequential mechanism for the 'fragment reaction', puromycin binding first.     

An analysis of ribosomal protein during the development of Xenopus laevis

Summary Conditions for the isolation and purification of ribosome proteins from developing Xenopus embryos have been established. The procedure involves the preparation of ribosome gradients, and from the monosomes and polysomes their protein. These proteins are purified by an ammonium chloride wash and are separated by electrophoresis. Results indicate that differences do not exist between monosome ribosome proteins from different developmental stages, but do exist between these monosomes and ribosomal protein from postgastrula polysomes. The possible role of the ribosome in translation-level control is discussed.     

pH-dependent conformational flexibility within the ribosomal peptidyl transferase center.

A universally conserved adenosine, A2451, within the ribosomal peptidyl transferase center has been proposed to act as a general acid-base catalyst during peptide bond formation. Evidence in support of this proposal came from pH-dependent dimethylsulfate (DMS) modification within Escherichia coli ribosomes. A2451 displayed reactivity consistent with an apparent acidity constant (pKa) near neutrality, though pH-dependent structural flexibility could not be rigorously excluded as an explanation for the enhanced reactivity at high pH. Here we present three independent lines of evidence in support of the alternative interpretation. First, A2451 in ribosomes from the archaebacteria Haloarcula marismortui displays an inverted pH profile that is inconsistent with proton-mediated base protection. Second, in ribosomes from the yeast Saccharomyces cerevisiae, C2452 rather than A2451 is modified in a pH-dependent manner. Third, within E. coli ribosomes, the position of A2451 modification (N1 or N3 imino group) was analyzed by testing for a Dimroth rearrangement of the N1-methylated base. The data are more consistent with DMS modification of the A2451 N1, a functional group that, according to the 50S ribosomal crystal structure, is solvent inaccessible without structural rearrangement. It therefore appears that pH-dependent DMS modification of A2451 does not provide evidence either for or against a general acid-base mechanism of protein synthesis. Instead the data suggest that there is pH-dependent conformational flexibility within the peptidyl transferase center, the exact nature and physiological relevance of which is not known.