Structure and function of ribosomal RNA
- 1 December 1995
- journal article
- review article
- Published by Canadian Science Publishing in Biochemistry and Cell Biology
- Vol. 73 (11-12), 997-1009
- https://doi.org/10.1139/o95-107
Abstract
A refined model has been developed for the folding of 16S rRNA in the 30S subunit, based on additional constraints obtained from new experimental approaches. One set of constraints comes from hydroxyl radical footprinting of each of the individual 30S ribosomal proteins, using free Fe2+–EDTA complex. A second approach uses localized hydroxyl radical cleavage from a single Fe2+tethered to unique positions on the surface of single proteins in the 30S subunit. This has been carried out for one position on the surface of protein S4, two on S17, and three on S5. Nucleotides in 16S rRNA that are essential for P-site tRNA binding were identified by a modification interference strategy. Ribosomal subunits were partially inactivated by chemical modification at a low level. Active, partially modified subunits were separated from inactive ones by binding 3′-biotin-derivatized tRNA to the 30S subunits and captured with streptavidin beads. Essential bases are those that are unmodified in the active population but modified in the total population. The four essential bases, G926, 2mG966, G1338, and G1401 are a subset of those that are protected from modification by P-site tRNA. They are all located in the cleft of our 30S subunit model. The rRNA neighborhood of the acceptor end of tRNA was probed by hydroxyl radical probing from Fe2+tethered to the 5′ end of tRNA via an EDTA linker. Cleavage was detected in domains IV, V, and VI of 23S rRNA, but not in 5S or 16S rRNA. The sites were all found to be near bases that were protected from modification by the CCA end of tRNA in earlier experiments, except for a set of E-site cleavages in domain IV and a set of A-site cleavages in the α-sarcin loop of domain VI. In vitro genetics was used to demonstrate a base-pairing interaction between tRNA and 23S rRNA. Mutations were introduced at positions C74 and C75 of tRNA and positions 2252 and 2253 of 23S rRNA. Interaction of the CCA end of tRNA with mutant ribosomes was tested using chemical probing in conjunction with allele-specific primer extension. The interaction occurred only when there was a Watson–Crick pairing relationship between positions 74 of tRNA and 2252 of 23S rRNA. Using a novel chimeric in vitro reconstitution method, it was shown that the peptidyl transferase reaction depends on this same Watson–Crick base pair.Key words: rRNA, ribosome, tRNA, hydroxyl radical, ribosomal protein.Keywords
This publication has 27 references indexed in Scilit:
- Directed hydroxyl radical probing of 16S rRNA using Fe(II) tethered to ribosomal protein S4.Proceedings of the National Academy of Sciences, 1995
- A Quantitative Model of the Escherichia coli 16 S RNA in the 30 S Ribosomal SubunitJournal of Molecular Biology, 1994
- Hydroxyl radical cleavage of tRNA in the ribosomal P site.Proceedings of the National Academy of Sciences, 1992
- Identification of intermolecular RNA cross-links at the subunit interface of the Escherichia coli ribosomeBiochemistry, 1992
- Specific structural probing of plasmid-coded ribosomal RNAs from Escherichia coliBiochimie, 1991
- Three-dimensional reconstruction of the 70S Escherichia coli ribosome in ice: the distribution of ribosomal RNA.The Journal of cell biology, 1991
- A detailed model of the three-dimensional structure of Escherichia coli 16 S ribosomal RNA in situ in the 30 S subunitJournal of Molecular Biology, 1988
- Transfer RNA shields specific nucleotides in 16S ribosomal RNA from attack by chemical probesCell, 1986
- Identification of a site on 23S ribosomal RNA located at the peptidyl transferase center.Proceedings of the National Academy of Sciences, 1984
- Ribosome-catalysed peptidyl transfer: the polyphenylalanine systemJournal of Molecular Biology, 1968