Maturation of the 3' end of 5-S ribosomal RNA from Escherichia coli

The 3' ends of 5-S rRNA isolated from Escherichia coli cells were analyzed and identified after different durations of labeling with 32Pi, with and without blocking of protein synthesis. These experiments suggest that the 5-S rRNA starts as a species containing 126 nucleotides, three at each end, and that the extra nucleotides are removed from the 5' and 3' ends in parallel at comparable but different rates. Inhibition of protein synthesis with chloramphenicol blocks, in addition to the 5'-end maturation, the trimming of the extra nucleotides from the 3' end. The trimming of extra nucleotides from both ends of the 5-S rRNA is also affected by the structure of the molecular stalk of 5-S rRNA. A number of observations suggest that the trimmings from both ends are independent processes, which are carried out probably by different enzymes.     

The composition and properties of the Escherichia coli 5-S RNA-protein complex

At a high concentration of MgCl2 (30 mM) and a low concentration of proteins from the 50-S subunit (0.2 mg/ml), only three proteins, L15, L18 and L25, bind to 5-S RNA in significant amounts. On the other hand, in a buffer containing only 1 mM Mg Cl2, but otherwise at the same ionic strength (0.2 M), or at a protein concentration about 1.5 mg/ml, a large, stable complex can form between immobilized 5-S RNA and 50-S ribosomal proteins. This complex contains proteins L2, L3, L5, L15, L16, L17, L18, L21, L22, L25, L33 and L34, and it possess properties relevant to the function of the 50-S subunit; it has a binding site for deacylated tRNA, with a dissociation constant of 4.5 x 10(-7) M. The complex formed with 5-S RNA immobilized on an affinity column interacts also with 30-S subunits. The 5-S RNA-protein complex is interpreted as a sub-ribosomal domain which includes a considerable fraction of the peptidyl transferase center of the Escherichia coli ribosome.     

Small-angle X-ray titration study on the complex formation between 5-S RNA and the L18 protein of the Escherichia coli 50-S ribosome particle.

The 5-S RNA (A) and the L18 protein (B) from Escherichia coli ribosomes form one single AB complex in the concentration ranges supposed to prevail in vivo; at concentrations of L18 higher than 40 mM there is some indication for a minor species, most probably an AB2 species. This is indicated from the X-ray scattering titration data of the 5-S RNA/L18 system recorded at 21 degrees C in ribosomal reconstitution buffer. As a result of the 1:1 complex formation, there is a relatively small but defined increase in the radius of gyration from 3.61 to 3.85 nm. This result as well as the experimental scattering curve can be explained by models where it is assumed that the elongated L18 model is quite far from the electron density centre and where protein L18 interacts with one or both of the minor arms of the supposed Y-shaped 5-S RNA molecule.     

A characterization of the low temperature structural transition of Escherichia coli 5 S RNA by partial enzymatic digestion

The low temperature structural transition (low leads to high) of 5 S RNA from Escherichia coli is investigated by partial digestion with ribonuclease T1. In addition to a general masking of guanines from the nuclease, differential changes of accessibility are observed when Mg2+ and salt concentrations are increased to bring about the low leads to high transition. Residue G13 becomes more exposed in the high form while residues G54, G56, G61, G72, and G83-86 become less exposed. The observed cutting rate at other sites is unchanged. A possible conformational change is discussed which could explain the observed changes in RNase T1 digestion patterns as well as the physical chemical observations.     

The effect of tRNA binding on the structure of 5 S RNA in Escherichia coli. A chemical modification study

The structure of 5 S RNA within the 70 S ribosome from Escherichia coli was studied using the chemical reagent kethoxal (alpha-keto-beta-ethoxybutyraldehyde) to modify accessible guanosines. The modification pattern of 5 S RNA from free 70 S ribosomes was compared with that of poly(U) programmed ribosomes where tRNA had been bound to both the A- and P-sites. Binding to the ribosomal A-site was achieved enzymatically using the elongation factor Tu and GTP in the presence of deacylated tRNA which blocks the ribosomal P-site. Modified guanosines were identified after partial RNase T1 hydrolysis and separation of the hydrolysis products on sequencing gels. Binding of tRNA to the ribosome leads to a strong protection of 5 S RNA guanosine G-41 and to some degree G-44 from kethoxal modification. The limited RNase T1 hydrolysis pattern provides evidence for the existence of a 5 S RNA conformation different from the known 5 S RNA A- and B-forms which are characterized by their gel electrophoretic mobility. The importance of 5 S RNA for the binding of tRNA to the ribosome is discussed.     

The effect of modification of cytosines in Escherichia coli 16-S rRNA on reconstitution and function of 30-S ribosomes.

O-Methylhydroxylamine (methoxyamine) was used for selective modification of cytosine residues in Escherichia coli 16-S rRNA. It was shown that cytosines accessible for methoxyamination are randomly distributed along the 16-S rRNA chain. Preparations of methoxyaminated 16-S rRNA, containing 2--130 modified cytosines/chain, still retained the ability to bind 30-S proteins, but the physical assembly of reconstituted particles was incorrect. The protein compositions of the reconstituted and native particles did not differ qualitatively from each other. However, the amount of protein in reconstituted particles decreased with an increasing number of methoxyaminated cytosines in 16-S rRNA. The particles obtained sedimented slower than native 30-S subunits, lost their ability to associate with 50-S ribosomes and to bind native phage f2 RNA. In contrast, modification of 16-S rRNA did not affect binding of poly(U) by reconstituted particles.     

Fluorine-19 nuclear magnetic resonance studies of the structure of 5-fluorouracil-substituted Escherichia coli transfer RNA

19F nuclear magnetic resonance has been used to study fully active Escherichia coli tRNA1Val in which 5-fluorouracil has replaced more than 90% of all uracil and uracil-derived modified bases. The 19F spectrum of the native tRNA contains resolved resonances for all 14 incorporated 5-fluorouracils. These are spread over a 6 ppm range, from 1.8 to 7.7 ppm downfield of the standard free 5-fluorouracil. The 19F resonances serve as sensitive monitors of tRNA conformation. Removal of magnesium or addition of NaCl produces major, reversible changes in the 19F spectrum. Most affected is the lowest field resonance (peak A) in the spectrum of the native tRNA. This shifts 2-3 ppm upfield as the Mg2+ concentration is lowered or the NaCl concentration is raised. Thermal denaturation of the tRNA results in a collapse of the spectrum to a single broad peak centered at 4.7 ppm. Study of the pH dependence of the 19F spectrum shows that five incorporated fluorouracils with 19F signals in the central, 4-5.5 ppm, region of the spectrum, peaks C, D, E, F, and H, are accessible to titration in the pH 4.5-9 range. All have pKa's close to that of free 5-fluorouridine (ca. 7.5). Evidence for a conformation change in the tRNA at mildly acidic pHs, ca. 5.5, is also presented. Four of the titratable 5-fluorouracil residues, those corresponding to peaks D, E/F, and H in the 19F spectrum of fluorine-labeled tRNAVal1, are essentially completely exposed to solvent as determined by the solvent isotope shift (SIS) on transfer of the tRNA from H2O to 2H2O. These are also the 5-fluorouracils that readily form adducts with bisulfite, a reagent that reacts preferentially with pyrimidines in single-stranded regions. On the basis of these results, resonances D, E, F, and H in the middle of the 19F spectrum are attributed to 5-fluorouracils in non-base-paired (loop) regions of the tRNA. Evidence from the ionic strength dependence of the 19F spectrum and arguments based on other recent studies with fluorinated tRNAs support earlier suggestions [Horowitz, J., Ofengand, J., Daniel, W. E., & Cohn, M. (1977) J. Biol. Chem. 252, 4418-4420] that the resonances at lowest field correspond to tertiary hydrogen-bonded 5-fluorouracils. Consideration of ring-current effects and the preferential perturbation of upfield 19F resonances by the cyclophotoaddition of 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen, which is known to react most readily with pyrimidines in double-stranded regions, permits initial assignment of upfield resonances to 5-fluorouracils in helical stems.(ABSTRACT TRUNCATED AT 400 WORDS)