The circular dichroism of ribosomal ribonucleic acids

A method for estimating the nearest neighbor base-pair content of RNAs using CD and absorption spectroscopy

CD and absorption spectra are sensitive to the secondary structure of RNAs. By fitting the spectra contained in our basis set to the CD and absorption spectra of an RNA of known sequence, we could determine the fractions of base pairs, the fractions of each of the nearest neighbor base pairs, and the fractions of the single-stranded nucleotides in that RNA. The basis set included 58 CD and 58 absorption spectra. The fitting was done with a guided selection routine. The estimated error was about 0.05 for predicting the fractions of the nearest neighbor base pairs, 0.06 for predicting the fractions of A.U, G.C, and G.U base pairs, and 0.04 for predicting the fractions of the single-stranded nucleotides.

A.U and G.C base pairs in synthetic RNAS have characteristic vacuum UV CD bands

The vacuum UV CD spectra of GpC, CpG, GpG, poly[r(A)], poly[r(C)], poly[r(U)], poly[r(A-U)], poly[r(G).r(C)], poly[r(A).r(U)], and poly[r(A-U).r(A-U)] were measured down to at least 174 nm. These spectra, together with the published spectra of poly[r(G-C).r(G-C)], CMP, and GMP, were sufficient to estimate the CD changes upon base pairing for four double-stranded RNAs. The vacuum UV CD bands of poly[r(A)], poly[r(C)], and the dinucleotides GpC and CpG were temperature dependent, suggesting that they were due to intrastrand base stacking. The dinucleotide sequence isomers GpC and CpG had very different vacuum UV CD bands, indicating that the sequence can play a role in the vacuum UV CD of single-stranded RNA. The vacuum UV CD bands of the double-stranded (G.C)-containing RNAs, poly[r(G).r(C)] and poly[r(G-C).r(G-C)], were larger than the measured or estimated vacuum UV CD bands of their constituent single-stranded RNAs and were similar in having an exceptionally large positive band at about 185 nm and negative bands near 176 and 209 nm. These similarities were enhanced in difference-CD spectra, obtained by subtracting the CD spectra of the single strands from the CD spectra of the corresponding double strands. The (A.U)-containing double-stranded RNAs poly[r(A).r(U)] and poly[r(A-U).r(A-U)] were similar only in that their vacuum UV CD spectra had a large positive band at 177 nm. The spectrum of poly[r(A).r(U)] had a shoulder at 188 nm and a negative band at 206 nm, whereas the spectrum of poly[r(A-U).r(A-U)] had a positive band at 201 nm. On the other hand, difference spectra of both of the (A.U)-containing polymers had positive bands at about 177 and 201 nm. Thus, the difference-CD spectra revealed CD bands characteristic of A.U and G.C base pairing. (ABSTRACT TRUNCATED AT 250 WORDS)

The role of magnesium and potassium ions in the molecular mechanism of ribosome assembly: hydrodynamic, conformational, and thermal stability studies of 16 S RNA from Escherichia coli ribosomes

In an attempt to understand the role of magnesium ion in ribosome assembly in vitro, the hydrodynamic shape, conformation, and thermal stability of ribosomal 16 S RNA were studied systematically as a function of Mg2+ concentration by sedimentation velocity, intrinsic viscosity, circular dichroism, and difference ultraviolet absorption spectroscopy. These results were then compared with the corresponding parameters obtained for 16 S RNA under the optimal conditions of reconstitution, i.e., at 37 degrees C, 20 mM Mg2+, an ionic strength equal to 0.37, and pH 7.8 [S. H. Allen, and K.-P. Wong (1978) J. Biol. Chem. 253, 8759-8766]. When the 360 mM KCl required for reconstitution of 30 S ribosomes is added to the medium, only subtle conformational changes are observed, consistent with the destabilization of the conformation, thus making the RNA molecule more "open" and accessible to protein binding. However, when the concentration of Mg2+ is lowered from 20 to 1 mM, the hydrodynamic parameters indicate that the 16 S RNA is partially unfolded, while thermal denaturation studies suggest that the amount of base-stacking and base-pairing is not concomitantly altered. Further removal of the Mg2+ by dialysis against a pH 7.8 buffer containing no Mg2+ results in a drastic decrease of secondary structure and indicates that the Mg2+ is required for maintenance of the pairing, stacking, and stability of the nucleotide bases, in addition to the long range interactions which result in a compact structure. The results suggest that the 20 mM Mg2+ is required for the 16 S RNA molecules to assume the proper secondary and tertiary structure containing the protein-binding sites, while the high K+ concentration (360 mM KCl) is needed for "loosening up" the RNA, making the protein binding sites more accessible to the ribosomal proteins for molecular recognition and binding as well as for the conformational changes that occur during ribosome assembly.

A circular dichroism study of the Turnip yellow mosaic virus-RNA

We examined the circular dichroism spectra of intact Turnip yellow mosaic virus, freezed/thawed virus, empty capsid particles, and phenol extracted RNA. The circular dichroism signal of the empty capsid was found to contribute for less than 1% to the circular dichroism of the virus. Differences in the circular dichroism spectra indicate that TYMV-RNA exhibits different conformations when it is in situ in the virus, when it has been ejected by freezing/thawing and when it has been phenol extracted. Increase of the ionic strength up to 0.1 M NaCl led to conformational change of the RNA either freezed/thawed ejected or phenol extracted but not in situ in the capsid. Addition of spermidine (3 mM) induced a conformational change only for the phenol extracted RNA. These results are discussed with respect to the origin of the various conformational states of viral RNA.

Mg2+-induced proton release from Escherichia coli ribosome and ribosomal RNA

Escherichia coli ribosome released protons upon addition of Mg2+. The Mg2+-induced proton release was studied by means of the pH-stat technique. The number of protons released from a 70 S ribosome in the Mg2+ concentration range 1-20 mM was about 30 at pH 7 and 7.6, and increased to about 40 at pH 6.5. The rRNA mixture extracted from 70 S ribosome showed proton release of amount and of pH dependence similar to those of the 70 S ribosome but the ribosomal protein mixture released few. This indicates that rRNA is the main source of the protons released from ribosome. The pH titration of rRNA showed that the pKa values of nucleotide bases were downward shifted upon Mg2+ binding. This pKa shift can account for the proton release. The Scatchard plots of proton release from rRNA and ribosome were concave upward, showing that the Mg2+-binding sites leading to proton release were either heterogeneous or had a negative cooperativity. A model assuming heterogeneous Mg2+-binding sites is shown to be unable to explain the proton release. Electrostatic field effect models are proposed in which Mg2+ modulates the electrostatic field of phosphate groups and the potential change induces a shift of the pKa values of bases that leads to the proton release. These models can explain the main features of the proton release.

Secondary structure features of ribosomal RNA species within intact ribosomal subunits and efficiency of RNA-protein interactions in thermoacidophilic (Caldariella acidophila, Bacillus acidocaldarius) and mesophilic (Escherichia coli) bacteria

Ribosomal subunits of Caldariella acidophila (max.growth temp., 90 degrees C) have been compared to subunits of Bacillus acidocaldarius (max. growth temp., 70 degrees C) and Escherichia coli (max. growth temp., 47 degrees C) with respect to (a) bihelical content of rRNA; (b) G . C content of bihelical domains and (c) tightness of rRNA-protein interactions. The principal results are as follows. Subunits of C. acidophilia ribosomes (Tm = 90-93 degrees C) exhibit considerable thermal tolerance over their B. acidocaldarius (Tm = 77 degrees C) and E. coli counterparts (Tm = 72 degrees C). Based on the "melting' hyperchromicities of the intact ribosomal subunits a 51-55% fraction of the nucleotides appears to participate in hydrogen-bonded base pairing regardless of ribosome source, whereas a larger fraction, 67-70%, appears to be involved in hydrogen bonding in the naked rRNA species. The G . C content of bihelical domains of both free and ribosome-bound rRNA increases with increasing thermophily; based on hyperchromicity dispersion spectra of intact subunits and free rRNA, the bihelical parts of C. acidophila rRNA are estimated to contain 63-64% G . C, compared to 58.5% G . C for B. acidocaldarius and 55% G . C for E. coli. The increment of ribosome Tm values with increasing thermophily is greater than the increase in Tm for the free rRNA, indicating that within ribosomes bihelical domains of the thermophile rRNA species are stabilized more efficiently than their mesophile counterparts by proteins or/ and other component(s). The efficiency of the rRNA-protein interactions in the mesophile and thermophile ribosomes has been probed by comparing the releases, with LiCl-urea, of the rRNA species from the corresponding ribosomal subunits stuck to a Celite column through their protein moiety; it has been established that the release of C. acidophila rRNA from the Celite-bound ribosomes occurs at salt-urea concentrations about 4-fold higher than those required to release rRNA from Celite-bound E. coli ribosomes. Compared to E. coli the C. acidophila 50 and 30 S ribosomal subunits are considerably less susceptible to treatment designed to promote ribosome unfolding through depletion of magnesium ions.

Characterization of the secondary structure features of Escherichia coli, Caldariella acidophila and mammalian ribosomal RNA species by chemical modification of sterically exposed bases

The helix content of rRNA species (Escherichia coli, Caldariella acidophila, rat liver) and the G . C content of their bihelical domains have been investigated by chemical modification of uracil and cytosine residues with probes specific for sterically exposed bases. By using radioactively labelled rRNA, G . C base pairs and the sum of A . U plus G . U base pairs have been quantified assuming that they are numerically identical with the unreactive cytosine and uracil rings, respectively. Exposed uracil bases were probed by their conversion to alkali-labile, nonultraviolet-absorbing sulphonated adducts, with 1.33 M bisulfite pH 7, at 20 degrees C; the adducts can be separated from unreacted uracil, and quantified, by cation-exchange chromatography of RNase T2 plus pancreatic RNase digests of bisulfite-modified rRNA. Exposed cytosines were probed by their conversion to methoxyaminated, alkali-stable, derivatives with 1 M methoxyamine, pH 5.5, at 37 degrees C, and quantified by monitoring the CMP/AMP radioactivity ratio after alkaline hydrolysis of modified rRNA. Exposed uracil rings can also be estimated spectrophotometrically by the alkali-catalyzed reversal of the non-ultraviolet-absorbing sulphonated adducts after separation of the latter from unreacted uracil. The cytosine deamination reaction, catalyzed by bisulfite at pH 6, has also been investigated and found to exhibit little specificity for sterically exposed bases of rRNA, the (G + C)-richer rRNA species of C. acidophila being considerably less susceptible to non-specific deamination than the (G + C)-poorer rRNA of E. coli. A high degree of congruence is shown to exist between results obtained by chemical modification and melting hyperchromicity experiments.

Secondary structures of influenza and Sendai Virus RNAs

The secondary structures of influenza and Sendai virus RNAs were investigated by thermal denaturation, circular dichroism and proflavine binding methods. In 0.1 M NaCl about 60% of the bases of both RNAs were involved in secondary structure. The melting temperatures (Tm) of both viral RNAs were linear functions of the logarithm of the sodium ion concentration in solution, but under all ionic conditions the melting temperatures of Sendai virus RNA were higher than those of influenza virus RNA. At all ionic strengths the melting range of Sendai virus RNA was less than influenza virus RNA, indicating that the helical regions in Sendai virus RNA were longer than those in influenza virus RNA. Although Sendai virus RNA had a higher thermal stability than influenza virus RNA, hyperchromicity and circular dichroism data showed that Sendai virus RNA had less G+C content (34%) within the double stranded regions than influenza virus RNA (48%). The binding isotherms of Sendai and influenza virus RNA-proflavine complexes were studied at different ionic strengths. The number of binding sites of proflavine with influenza virus RNA were significantly lower than those with Sendai virus RNA. These results demonstrate the essential difference between the secondary and tertiary structures of the RNAs under study.

Studies on the negative circular dichroic bands around 297 nm of ribosomes from bacterial cells

The small negative CD bands around 297 nm of isolated 30-S and 50-S ribosomal subunits were precisely measured for three bacteria, Bacillus stearothermophilus, Bacillus subtilis and Escherichia coli Q 13. The intensities of the negative CD bands of 30-S subunits were always much greater than those of 50-S subunits irrespective of the bacterial strains, which may be related to the difference in comformations of rRNAs and proteins in the complexes between these subribosomal particles. The dissociation of 70-S ribosomes into two subunits by lowering Mg2+ concentration caused evident enhancement of intensity of the 297 nm CD band, which was completely reversed by the association of the two subunits into 70-S particles. The melting profiles of CD spectra 3 B. stearothermophilus and E. coli were compared and both subunits of the former were found to be more heat stable than those of the latter. It was found that 5 M urea and 0.5% sodium dodecyl sulfate (SDS) treatment caused considerable reduction of the negative CD intensity around 297 nm of 30-S subunits but no significant change of 50-S subunits, while no significant change was observed for the CD spectra of isolated 16-S and 23-S rRNAs by the same treatment. Effects of EDTA treatment and then addition of Mg2+ on the CD spectra and fluorescence emission spectra of the subunits were also observed and the contribution by the interaction between rRNA s and proteins in ribosomes to the small negative band around 297 nm was discussed.

Alteration of 5S RNA conformation by ribosomal proteins L18 and L25

The effects of ribosomal proteins L18, L25 and L5 on the conformation of 5S RNA have been studied by circular dichroism and temperature dependent ultraviolet absorbance. The circular dichroism spectrum of native 5S RNA is characterized in the near ultraviolet by a large positive band at 267 nm and a small negative band at 298 nm. The greatest perturbation in the spectrum was produced by protein L18 which induced a 20% increase in the 267 nm band and no change in the 298 nm band. By contrast, protein L25 caused a small decrease in both bands. No effect was observed with protein L5. Simultaneous binding of proteins L18 and L25 resulted in CD changes equivalent to the sum of their independent effects. The UV absorbance thermal denaturation profile of the 5S RNA L18 complex lacked the pre-melting behavior characteristic of 5S RNA. Protein L25 had no effect on the 5S RNA melting profile. We concluded that protein L18 increases the secondary, and possible the tertiary structure of 5S RNA, and exerts a minor stabilizing effect on its conformation while protein L25 causes a small decrease in 5S RNA secondary structure. The implications of these findings for ribosome assembly and function are discussed.

Re-activation of the peptidyltransferase centre of rabbit reticulocyte ribosomes after inactivation by exposure to low concentrations of magnesium ion

1. The larger subrivosomal particles of rabbit reticulocytes retained full activity in the puromycin reaction and in poly(U)-directed polyphenylalanine synthesis after 4h at 0 degrees C when buffered 0.5M-NH4Cl/10-30mM-MgCl2 was the solvent. 2. Activity in the puromycin reaction was diminished to approx 10% after 15-30 min at 0 degrees C when the concentration of MgCl2 was lowered to 2mM. 3. Activity was not restored when the concentration of MgCl2 was raised from 2mM to 10-30 mM at 0 degrees C. However, activity was recovered as measured by both assay systems when the ribosome fraction was heated to 37 degrees C at the higher concentrations of MgCl2. 4. Recovery of activity was noted during the course of the polyphenylalanine synthesis in 50 mM-KCl/5mM-MgCl2/25mM-Tris/HCl, pH 7.6, at 37 degrees C. Re-activation was slow at 20 degrees C and below. 5. No more than about 5% of the protein moiety of the subparticle was lost in 0.5M-NH4Cl on decreasing MgCl2 concentration from 10mM to 2mM. No proteins were detected in the supernatant fractions by gel electrophoresis after ribosomes were separated by differential centrifugation. The supernatant fraction was not essential for the recovery of activity. However, at higher (e.g. 1M) concentrations of NH4Cl, proteins were split from the subparticle. 6. The loss and regain of activity found on lowering and restoring the concentration of MgCl2 at 0.5M-NH4Cl appears to arise from a conformational change that does not seem to be associated with a loss and regain of particular proteins. 7. A 2% decrease in E260 was noticed when the concentration of Mg2+ was restored, and the change in the spectrum indicated a net increase of approx. 100A-U base-pairs per subribosomal particle. 8. When the concentration of Mg2+ was restored, S20,W of the subparticle remained at 52+/- 1S until the sample was incubated at 37 degrees C when S20,W increased to 56 +/- 1S compared with the value of 58 +/- 1S for the subparticle as originally isolated.

A study of the influence of magnesium ions on the conformation of ribosomal ribonucleic acid and on the stability of the larger subribosomal particle of rabbit reticulocytes

Mg2+ was shown to affect the conformation of rRNA over the range of 0.03-1.2M-KCl. The species studies were Escherichia coli S-rRNA and L-rRNA (the RNA moieties of the smaller and larger subribosomal particles respectively) and rabbits S-rRNA and L-rRNA. 2. The addition of Mg2+ to rRNA in reconstitution buffer (0.35M-KCl0.01M-Tris/HCl, pH7.2) at 20 degrees C let to an increase in bihelical secondary structure through the formation of additional (mainly A-U) base-pairs (e.g. an additional approx. 58 A-U base-pairs per molecule of E. coli S-rRNA as judged by u.v. difference spectrophotometry...

Spectroscopic evidence for the uneven distribution of adenine and uracil residues in ribosomal ribonucleic acid of Drosophila melanogaster and of Plasmodium knowlesi and its possible evolutionary significance

RNA was isolated from subribosomal particles of the malaria parasite Plasmodium knowlesi. The nucleotide composition (mole fraction) of the principal species was obtained (S-rRNA, 0.295A, 0.36U, 0.25G, 0.105C: L-rRNA, 0.326A, 0.31U, 0.228G, 0.144C). Ribosomal RNA was also isolated from Drosophila melanogaster. Optical properties of these A + U-rich species were measured. In all four cases analysis of the hypochromic effect revealed that adenine and uracil residues tended to form clusters along the polynucleotide chain. A substantial fraction of residues was located in bihelical regions of approx. 50% G-C base pairs or in regions of approx. 30-35% G-C base pairs. The possible evolutionary significance of these results was considered on the basis of comparison with properties of rRNA from bacteria (Escherichia coli) and a mammal (rabbit reticulocyte).