The binding of ribosomal protein S1 to S1-depleted 30S and 70S ribosomes. A fluorescence anisotropy study of the effects of Mg2+

We have determined the equilibrium constants for the binding of AEDANS-labelled S1 to S1-depleted 30S and 70S ribosomes. For "tight" ribosomes, the association of S1 increases with the sixth power of Mg2+ concentration, but for 30S subunits and "loose" ribosomes, there is virtually no dependence of the association on Mg2+ over the same concentration range, 2-10 mM in Mg2+. The binding of S1 to 70S ribosomes at 10 mM Mg2+ is stabilized by 2 kcal/mol compared to the binding to 30S subunits. When intact S1 binds to tight ribosomes, the fluorescence anisotrophy is that for virtually complete rotational immobilization. The anisotropies vary considerably with the preparation and treatment of both S1 and ribosomes and these variations are detailed here. The results suggest the linkage of Mg2+-dependent conformational changes in the intact ribosomes, perhaps including rRNA, and the binding of S1.     

Binding of magnesium ions and ethidium bromide: comparison of ribosomes and free ribosomal RNA.

Comparative studies of free ribosomal RNA and ribosomes were made with two probes, Mg++ ions and ethidium bromide, which interact with RNA in different ways. Mg++. E. coli 16 S rRNA and 30 S ribosomes were equilibrated with four different buffers. Equilibration required several days at 4 degrees and several hours at 37 degrees. In all buffers ribosomes bound more Mg than free rRNA, the difference sometimes reaching 20--30%. Ribosomes were more resistant than free rRNA to heat denaturation and their denaturation was more highly cooperative. Ribosomes that bound more Mg++ had higher denaturation temperatures. Ethidium bromide. Fluorescence enhancement studies of ethidium intercalation showed the free 16 S rRNA to have 50--80 binding sites per molecule. A large fraction of these sites were present and accessible in the ribosome, but their ethidium-binding constants were reduced by an order of magnitude. In addition, free rRNA contained a small number of very strong binding sites that were virtually absent in the ribosomes.     

Nuclease S1 mapping of 16S ribosomal RNA in ribosomes

Escherichia coli 16S rRNA and 16S-like rRNAs from other species have several universally conserved sequences which are believed to be single-stranded in ribosomes. The quantitative disposition of these sequences within ribosomes is not known. Here we describe experiments designed to explore the availability of universal 16S rRNA sequences for hybridization with DNA probes in 30S particles and 70S ribosomes. Unlike previous investigations, quantitative data on the accessibility of DNA probes to the conserved portions of 16S rRNA within ribosomes was acquired. Uniquely, the experimental design also permitted investigation of cooperative interactions involving portions of conserved 16S rRNA. The basic strategy employed ribosomes, 30S subunits, and 16S rRNAs, which were quantitatively analyzed for hybridization efficiency with synthetic DNA in combination with nuclease S1. In deproteinated E. coli 16S rRNA and 30S subunits, the regions 520-530, 1396-1404, 1493-1504, and 1533-1542 are all single-stranded and unrestricted for hybridization to short synthetic DNAs. However, the quantitative disposition of the sequences in 70S ribosomes varies with each position. In 30S subunits there appear to be no cooperative interactions between the 16S rRNA universal sequences investigated.     

rRNA topography in ribosome. IV. The accessibility of the 5'-end region of 16S rRNA

The accessibility of the 5'-end region of 16S rRNA (A₈GAGUUUG₁₅) inEscherichia coli ribosomes for complementary binding with the synthetic octanucleotide d(CAAACTCT) has been studied. Nonequilibrium gel-filtration was used to evaluate parameters of the binding of this oligonucleotide with free 16S rRNA, ribosomal subunits, and 70S ribosomes. A simple approach is presented to calculate the apparent association constants and the number of binding sites based upon the data obtained under those conditions. Free 16S rRNA, 30S subunits, and 70S ribosomes were found to form rather stable complexes with the octanucleotide, the association constants being similar in all three cases. These data strongly suggest the surface location of the 16S rRNA 5'-end inE. coli ribosomes.     

Nonbridging phosphate oxygens in 16S rRNA important for 30S subunit assembly and association with the 50S ribosomal subunit

Ribosomes are composed of RNA and protein molecules that associate together to form a supramolecular machine responsible for protein biosynthesis. Detailed information about the structure of the ribosome has come from the recent X-ray crystal structures of the ribosome and the ribosomal subunits. However, the molecular interactions between the rRNAs and the r-proteins that occur during the intermediate steps of ribosome assembly are poorly understood. Here we describe a modification-interference approach to identify nonbridging phosphate oxygens within 16S rRNA that are important for the in vitro assembly of the Escherichia coli 30S small ribosomal subunit and for its association with the 50S large ribosomal subunit. The 30S small subunit was reconstituted from phosphorothioate-substituted 16S rRNA and small subunit proteins. Active 30S subunits were selected by their ability to bind to the 50S large subunit and form 70S ribosomes. Analysis of the selected population shows that phosphate oxygens at specific positions in the 16S rRNA are important for either subunit assembly or for binding to the 50S subunit. The X-ray crystallographic structures of the 30S subunit suggest that some of these phosphate oxygens participate in r-protein binding, coordination of metal ions, or for the formation of intersubunit bridges in the mature 30S subunit. Interestingly, however, several of the phosphate oxygens identified in this study do not participate in any interaction in the mature 30S subunit, suggesting that they play a role in the early steps of the 30S subunit assembly.     

Magnesium ion induced proton release as a probe for the polyelectrolytic structure of ribosomal RNAs and subunits

E coli ribosomes and rRNA's released 20 to 50 protons upon jump of magnesium ion concentration from 1 mM to 20 mM. The Mg2+-induced proton release was measured separately for 16S rRNA, 23S rRNA, 30S subunit, and 50S subunit by a new spectrophotometric method that had a much better sensitivity than the pH-stat method. The proton release from the subunits and rRNA's were similar in the number of protons, the pH dependence that had a minimum at neutral pH, and the upward concaveness of the Scatchard plot. From these results, the main source of protons in ribosomal subunits was assigned to nucleotide bases of rRNA's that showed a downward pKa shift upon Mg2+-ion binding. The subunits and rRNA's, however, differed in the proton release. 16S rRNA released protons somewhat more effectively than 23S rRNA, while 30S subunit released protons 2 to 5 times more effectively than 50S subunit. The marked difference between the two subunits suggest that ionizable bases in 16S and 23S rRNA's are covered and their pKa values are shifted by ribosomal proteins to different extents. The association of 30S and 50S subunits induced little proton release, showing that few ionizable groups with pKa near neutral pH are involved in the association. E. coli tRNA and poly U also showed Mg2+-induced proton release. The amounts of protons released from rRNA's, tRNA, and poly U were roughly proportional to the amount of bases not hydrogen bonded. The Mg2+-induced proton release from the natural and synthetic RNA's can be explained by the electrostatic field effect of polyphosphate backbones on bases not hydrogen bonded, as proposed in a previous paper. It also reflects the conformational structure of each RNA molecule.     

Number of tRNA binding sites on 80 S ribosomes and their subunits

The ability of rabbit liver ribosomes and their subunits to form complexes with different forms of tRNAPhe (aminoacyl-, peptidyl- and deacylated) was studied using the nitrocellulose membrane filtration technique. The 80 S ribosomes were shown to have two binding sites for aminoacyl- or peptidyl-tRNA and three binding sites for deacylated tRNA. The number of tRNA binding sites on 80 S ribosomes or 40 S subunits is constant at different Mg2+ concentrations (5-20 mM). Double reciprocal or Scatchard plot analysis indicates that the binding of Ac-Phe-tRNAPhe to the ribosomal sites is a cooperative process. The third site on the 80 S ribosome is formed by its 60 S subunit, which was shown to have one codon-independent binding site specific for deacylated tRNA.     

The aminoglycoside resistance methyltransferases from the ArmA/Rmt family operate late in the 30S ribosomal biogenesis pathway

Bacterial resistance to 4,6-type aminoglycoside antibiotics, which target the ribosome, has been traced to the ArmA/RmtA family of rRNA methyltransferases. These plasmid-encoded enzymes transfer a methyl group from S-adenosyl-L-methionine to N7 of the buried G1405 in the aminoglycoside binding site of 16S rRNA of the 30S ribosomal subunit. ArmA methylates mature 30S subunits but not 16S rRNA, 50S, or 70S ribosomal subunits or isolated Helix 44 of the 30S subunit. To more fully characterize this family of enzymes, we have investigated the substrate requirements of ArmA and to a lesser extent its ortholog RmtA. We determined the Mg+2 dependence of ArmA activity toward the 30S ribosomal subunits and found that the enzyme recognizes both low Mg+2 (translationally inactive) and high Mg+2 (translationally active) forms of this substrate. We tested the effects of LiCl pretreatment of the 30S subunits, initiation factor 3 (IF3), and gentamicin/kasugamycin resistance methyltransferase (KsgA) on ArmA activity and determined whether in vivo derived pre-30S ribosomal subunits are ArmA methylation substrates. ArmA failed to methylate the 30S subunits generated from LiCl washes above 0.75 M, despite the apparent retention of ribosomal proteins and a fully mature 16S rRNA. From our experiments, we conclude that ArmA is most active toward the 30S ribosomal subunits that are at or very near full maturity, but that it can also recognize more than one form of the 30S subunit.     

Mechanism of ribosomal subunit association: oligodeoxynucleotides as probes.

From the kethoxal treatment data [Herr, W.; Chapman, N.M.; Noller, H.F. (1979) J. Mol. Biol. 130, 433-439] some regions of ribosomal RNAs are thought to be responsible for the association of 30S and 50S ribosomes of E. coli to form 70S ribosomes. In order to test this possibility about a dozen oligodeoxynucleotides complementary to the suspected regions of rRNAs were synthesised. Their association with ribosomes and naked rRNAs was tested by the gel filtration technique. In order to check the effects on the ribosomal subunit association or rRNA association either intact 30S and 50S ribosomes or naked 16S and 23S rRNAs were preincubated with the individual oligodeoxynucleotide and its effect was checked by density gradient centrifugation followed by UV absorbance monitoring. Some oligodeoxynucleotides interfered with either subunit association or 16S RNA and 23S RNA association, some with both. These data clearly indicate that RNA-RNA interaction plays the major role in ribosomal subunit association.     

Organization of the 16S rRNA around its 5' terminus determined by photochemical crosslinking in the 30S ribosomal subunit

The organization of the 5' terminus region in the 16S rRNA was investigated using a series of RNA constructs in which the 5' terminus was extended by 5 nt or was shortened to give RNA molecules that started at positions -5, +1, +5, +8, +14, or +21. The structural and functional effects of the 5' extension/truncations were determined after the RNAs were reconstituted. 30S subunits containing 16S rRNA with 5' termini at -5, +1, +5, +8 and +14 had similar structures (judged by UV-induced crosslinking) and exhibited a gradual reduction in tRNA binding activity compared to that seen with 30S subunits reconstituted with native 16S rRNA. To create the 5' terminal site-specific photocrosslinking agent, the reagent azidophenacylbromide (APAB) was attached to the 5' terminus of 16S rRNA through a guanosine monophosphorothioate and the APA-16S rRNAs were reconstituted. Crosslinking carried out with the APA revealed sites in six regions around positions 300-340, 560, 900, 1080, the 16S rRNA decoding region, and at 1330. Differences in the pattern and efficiency of crosslinking for the different constructs allow distance estimates for the crosslinked sites from nucleotide G9. These measurements provide constraints for the arrangement of the RNA elements in the 30S subunit. Similar experiments carried out in the 70S ribosome resulted in a five- to tenfold lower frequency of crosslinking. This is most likely due to a repositioning of the 5' terminus upon subunit association.     

Probing the conformational changes in 5.8S, 18S and 28S rRNA upon association of derived subunits into complete 80S ribosomes.

The participation of 18S, 5.8S and 28S ribosomal RNA in subunit association was investigated by chemical modification and primer extension. Derived 40S and 60S ribosomal subunits isolated from mouse Ehrlich ascites cells were reassociated into 80S particles. These ribosomes were treated with dimethyl sulphate and 1-cyclohexyl-3-(morpholinoethyl) carbodiimide metho-p-toluene sulfonate to allow specific modification of single strand bases in the rRNAs. The modification pattern in the 80S ribosome was compared to that of the derived ribosomal subunits. Formation of complete 80S ribosomes altered the extent of modification of a limited number of bases in the rRNAs. The majority of these nucleotides were located to phylogenetically conserved regions in the rRNA but the reactivity of some bases in eukaryote specific sequences was also changed. The nucleotides affected by subunit association were clustered in the central and 3'-minor domains of 18S rRNA as well as in domains I, II, IV and V of 5.8/28S rRNA. Most of the bases became less accessible to modification in the 80S ribosome, suggesting that these bases were involved in subunit interaction. Three regions of the rRNAs, the central domain of 18S rRNA, 5.8S rRNA and domain V in 28S rRNA, contained bases that showed increased accessibility for modification after subunit association. The increased reactivity indicates that these regions undergo structural changes upon subunit association.     

In vitro incorporation of eubacterial, archaebacterial and eukaryotic 5S rRNAs into large ribosomal subunits of Bacillus stearothermophilus.

Bacillus stearothermophilus large ribosomal subunits were reconstituted in the presence of 5S rRNAs from different origins and tested for their biological activities. The results obtained have shown that eubacterial and archaebacterial 5S rRNAs can easily substitute for B. stearothermophilus 5S rRNA in the reconstitution, while eukaryotic 5S rRNAs yield ribosomal subunits with reduced biological activities. From our results we propose an interaction between nucleotides 42-47 of 5S rRNA and nucleotides 2603-2608 of 23S rRNA during the assembly of the 50S ribosomal subunit. Other experiments with eukaryotic 5.8S rRNAs reveal, if at all, a very low incorporation of these RNA species into the reconstituted ribosomes.     

Structural dynamics of bacterial ribosomes: II. Preparation and characterization of ribosomes and subunits active in the translation of natural messenger RNA

Ribosomes from Escherichia coli were tested for activity in initiation with R17 RNA as messenger. All vacant 70 S ribosomes but not all subunits were found to be active. The ability of 30 S and 50 S subunits to form a 70 S couple at Mg²⁺ concentrations above 4 mm is a stringent test for activity.Fresh extracts, prepared at 10 mm-Mg²⁺ from cells harvested after slow cooling contain up to 80% of the ribosomes in the form of vacant 70 S couples and 20% of free subunits. The proportion of subunits increases with standing as a result of the preferential inactivation of the 50 S particles. “Native” subunits are heterogeneous and consist mostly of active 30 S and inactive 50 S particles.In contrast to 50 S subunits, 30 S subunits prepared by exposure of 70 S ribosomes to low Mg²⁺ concentrations, are largely inactive and unable to reassociate with their active 50 S counterparts. However, both initiation and association activity can be restored by heating.The results imply that the structures necessary for subunit association are most critical for the biological activity of ribosomes, presumably because they are topologically closely related to the binding sites for messenger RNA, transfer RNA, and the protein factors for initiation, translocation and termination.     

Structural analysis of the peptidyl transferase region in ribosomal RNA of the eukaryote Xenopus laevis

Accessible single-strand bases in Xenopus laevis 28 S ribosomal RNA (rRNA) Domain V, the peptidyl transferase region, were determined by chemical modification with dimethylsulfate, 1-cyclohexyl-3-(2-morpholinoethyl-carbodiimide metho-p-toluene sulfonate and kethoxal, followed by primer extension. The relative accessibilities of three rRNA substrates were compared: deproteinized 28 S rRNA under non-denaturing conditions (free 28 S rRNA), 60 S subunits and 80 S ribosomes. Overall, our experimental results support the theoretical secondary structure model of Domain V derived by comparative sequence analysis and compensatory base-pair changes, and support some theoretical tertiary interactions previously suggested by covariation. The 60 S subunits and 80 S ribosomes generally show increasing resistance to chemical modification. Bases which are sensitive in free 28 S rRNA but protected in 60 S subunits may be sites for ribosomal protein binding or induced structural rearrangements. Another class of nucleotides is distinguished by its sensitivity in 60 S subunits but protection in 80 S ribosomes; these nucleotides may be involved in subunit-subunit interactions or located at the interface of the ribosome. We found a third class of bases, which is protected in free 28 S rRNA but sensitive in 60 S subunits and/or 80 S ribosomes, suggesting that structural changes occur in Domain V as a result of subunit assembly and ribosome formation. One such region is uniquely hypersensitive in eukaryotic ribosomes but is absent in Escherichia coli ribosomes. Sites that we determined to be accessible on empty 80 S ribosomes could serve as recognition sites for translation components.     

Reconstitution of active 30-S ribosomal subunits in vitro using heat-denatured 16-S rRNA.

30-S ribosomal subunits which have been reconstituted using heat-denatured 16-S rRNA can participate in the synthesis of lysosyme in vitro. Therefore all the information contributed by 16-S rRNA to the reconstitution process is carried in the primary sequence of this RNA. The specific protein-synthesizing activity of 30-S subunits reconstituted from 30-S subunit proteins and heat-denatured 16-S rRNA is about one third of that observed if unheated 16-S rRNA is used and is comparable to the activity of 30-S particles isolated after dissociation of 70-S ribosomes in the presence of 0.1 mM Mg2+.     

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.     

The identification of spermine binding sites in 16S rRNA allows interpretation of the spermine effect on ribosomal 30S subunit functions

A photoreactive analogue of spermine, N¹-azidobenzamidino (ABA)-spermine, was covalently attached after irradiation to Escherichia coli 30S ribosomal subunits or naked 16S rRNA. By means of RNase H digestion and primer extension, the cross-linking sites of ABA-spermine in naked 16S rRNA were characterised and compared with those identified in 30S subunits. The 5′ domain, the internal and terminal loops of helix H24, as well as the upper part of helix H44 in naked 16S rRNA, were found to be preferable binding sites for polyamines. Association of 16S rRNA with ribosomal proteins facilitated its interaction with photoprobe, except for 530 stem–loop nt, whose modification by ABA-spermine was abolished. Association of 30S with 50S subunits, poly(U) and AcPhe-tRNA (complex C) further altered the susceptibility of ABA-spermine cross-linking to 16S rRNA. Complex C, modified in its 30S subunit by ABA-spermine, reacted with puromycin similarly to non-photolabelled complex. On the contrary, poly(U)-programmed 70S ribosomes reconstituted from photolabelled 30S subunits and untreated 50S subunits bound AcPhe-tRNA more efficiently than untreated ribosomes, but were less able to recognise and reject near cognate aminoacyl-tRNA. The above can be interpreted in terms of conformational changes in 16S rRNA, induced by the incorporation of ABA-spermine.     

The RimP Protein Is Important for Maturation of the 30S Ribosomal Subunit

The in vivo assembly of ribosomal subunits requires assistance by auxiliary proteins that are not part of mature ribosomes. More such assembly proteins have been identified for the assembly of the 50S than for the 30S ribosomal subunit. Here, we show that the RimP protein (formerly YhbC or P15a) is important for the maturation of the 30S subunit. A rimP deletion (ΔrimP135) mutant in Escherichia coli showed a temperature-sensitive growth phenotype as demonstrated by a 1.2-, 1.5-, and 2.5-fold lower growth rate at 30, 37, and 44 °C, respectively, compared to a wild-type strain. The mutant had a reduced amount of 70S ribosomes engaged in translation and showed a corresponding increase in the amount of free ribosomal subunits. In addition, the mutant showed a lower ratio of free 30S to 50S subunits as well as an accumulation of immature 16S rRNA compared to a wild-type strain, indicating a deficiency in the maturation of the 30S subunit. All of these effects were more pronounced at higher temperatures. RimP was found to be associated with free 30S subunits but not with free 50S subunits or with 70S ribosomes. The slow growth of the rimP deletion mutant was not suppressed by increased expression of any other known 30S maturation factor.