Probing the function of conserved RNA structures in the 30S subunit of Escherichia coli ribosomes.

Ribosomes play an active role in protein biosynthesis. Ribosomal RNA conformation in ribosomal subunits, intramolecular interactions between different rRNA sequences within the confinement of the particles, and intermolecular interactions are presumed necessary to support efficient and accurate protein synthesis. Here we report an analysis of the disposition of 16S rRNA conserved zones centered about positions 525, 1400, and 1500 in 30S subunits. Complementary oligodeoxyribonucleotides in conjunction with nuclease S1 digestion were used to do this. All of the sequences examined in 30S subunits are accessible to DNA probes of 9 to 12 nucleotide residues in length. However, the kinetic characteristics of the respective DNA interactions with 30S particles vary significantly. In addition to the investigation of normal 30S particles, a four base deletion within the 1400 region of 16S rRNA was analyzed. The deletion was made by using synthetic DNAs to target the deletion site for RNase H digestion. The direct in vitro procedure for manipulating rRNA conserves nucleotide modifications. The alteration causes a significant change in the disposition of 16S rRNA in 30S subunits, suggesting a reduction in the freedom of movement of the altered zone in the particle. In a factor-dependent in vitro protein synthesis system primed with MS2 mRNA and altered 30S subunits, there was a 50% decrease in phage coat protein synthesis. The reduction could be due to a decrease in the rate of translation or premature termination of translation. We present evidence here, based on isotopic studies, which supports the latter possibility.     

Studies on the structure and function of 16S ribosomal RNA using structure-specific chemical probes

Recent technological developments permit us to examine the accessibility of specific atoms on any nucleotide in any large RNA molecule to certain chemical probes. This can provide detailed information about the higher order structure of large RNA molecules, including secondary and tertiary structure, protein-RNA contacts, binding sites for functional ligands and possible biologically significant conformational changes. Here, we summarize recent studies on (i) the conformation of naked 16S rRNA under a variety of ionic conditions, and (ii) the behaviour of 16S rRNA in active and inactive 30S subunits, as defined by Zamir, Elson and their colleagues. The latter study reveals a reciprocal conformational change in the vicinity of the decoding region of 16S rRNA in 30S ribosomal subunits. This conformational change appears to be a rearrangement of tertiary and/or quaternary structure involving several universally conserved nucleotides. No reproducible effects are seen elsewhere in the molecule, suggesting that the active-inactive transition is a result of the observed conformational change.     

Basepairing potential of the 3' terminus of 16S RNA: dependence on the functional state of the 30S subunit and the presence of protein S21.

The deoxyoctanucleotide 5'd (AAGGAGGT) which is complementary to the 3' terminus of 16S RNA has been used as a probe to measure the potential of this rRNA region to engage in intermolecular basepairing. The site specific binding of the octanucleotide is shown by labeling 16S RNA in situ at its 3' end with [32P]pCp and T4 RNA ligase (EC 6.5.1.3.). The label can be released as pA[32P]pCp by the simultaneous action of RNAse H (EC 3.1.4.34) and 5'd(AAGGAGGT). WE show that (1) 30S subunits prepared according to standard procedures, bind less than one copy of 5'd(AAGGAGGT); (2) isolated 16S RNA and 30S subunits inactivated by transcient exposure to 0.5 mM Mg2+ do not bind the octanucleotide; (3) binding to inactive subunits can be restored by a brief heat treatment; (4) 30S subunits lacking protein S21 do not bind 5'd(AAGGAGGT) even when submitted to heat treatment; (5) addition of protein S21 to subunits lacking S21 restores octamer binding; (6) the apparent exposure of the 16S RNA 3' terminus brought about by protein S21 is accompanied by the potential of the subunits to accept MS2 RNA as messenger; (7) the presence or absence of S1 on 30S subunits has no effect on their octanucleotide binding property.     

Crosslinking studies on the organization of the 16 S ribosomal RNA within the 30 S Escherichia coli ribosomal subunit.

The location and frequency of RNA crosslinks induced by photoreaction of hydroxymethyltrimethylpsoralen with 30 S Escherichia coli ribosomal subunits have been determined by electron microscopy. At least seven distinct crosslinks between regions distant in the 16 S rRNA primary structure are seen in the inactive conformation of the 30 S particle. All correspond to crosslinked features seen when the free 16 S rRNA is treated with hydroxymethyltrimethylpsoralen. The most frequently observed crosslink occurs between residues near one end of the molecule and residues about 600 nucleotides away to generate a loop of 570 bases. The size and orientation of this feature indicate it corresponds to the crosslinked feature located at the 3′ end of free 16 S rRNA.When active 30 S particles are crosslinked in 5 mm-Mg²⁺, six of the seven features seen in the inactive 30 S particle can still be detected. However, the frequency of several of the features, and particularly the 570-base loop feature, is dramatically decreased. This suggests that the long-range contacts that lead to these crosslinks are either absent or inaccessible in the active conformation. Crosslinking results in some loss of functional activities of the 30 S particle. This is consistent with the notion that the presence of the crosslink that generates the 570-base loop traps the subunit in an inactive form, which cannot associate with 50 S particles.The arrangement of the interacting regions crosslinked by hydroxymethyltrimethylpsoralen suggests that the RNA may be organized into three general domains. A striking feature of the Crosslinking pattern is that three of the seven products involve regions near the 3′ end of the 16 S rRNA. These serve to tie together large sections of rRNA. Thus structural changes at the 3′ end could, in principle, be felt through the entire 30 S particle.     

30S ribosomal subunits with fragmented 16S RNA: a new approach for structure and function study of ribosomes.

A new approach for function and structure study of ribosomes based on oligodeoxyribonucleotide-directed cleavage of rRNA with RNase H and subsequent reconstitution of ribosomal subunits from fragmented RNA has been developed. The E coli 16S rRNA was cleaved at 9 regions belonging to different RNA domains. The deletion of 2 large regions was also produced by cleaving 16S rRNA in the presence of 2 or 3 oligonucleotides complementary to different RNA sites. Fragmented and deleted RNA were shown to be efficiently assembled with total ribosomal protein into 30S-like particles. The capacity to form 70S ribosomes and translate both synthetic and natural mRNA of 30S subunits reconstituted from intact and fragmented 16S mRNA was compared. All 30S subunits assembled with fragmented 16S rRNA revealed very different activity: the fragmentation of RNA at the 781-800 and 1392-1408 regions led to the complete inactivation of ribosomes, whereas the RNA fragmentation at the regions 296-305, 913-925, 990-998, 1043-1049, 1207-1215, 1499-1506, 1530-1539 did not significantly influence the ribosome protein synthesis activity, although it was also reduced. These findings are mainly in accordance with the data on the functional activity of some 16S rRNA sites obtained by other methods. The relations between different 16S RNA functional sites are discussed.     

Ribosomes with unique breaks in 16S RNA: isolation and biological activity

A set of Escherichia coli 16S rRNA having unique breaks were prepared using the method of oligodeoxyribonucleotide-directed fragmentation with RNAse H. 16S RNA remained compact or dissociated to separate fragments, depending on the cleavage site location in the RNA structure. 16S rRNAs which have been split at different sites or their isolated fragments were used for a reconstitution of the 30S ribosomal subunits. These reconstituted 30S subunits carrying unique breaks at positions 301, 772, 1047 have the same sedimentation coefficients and electron microscopy images as the native subunit. They were active in the poly(U)-directed cell-free system of synthesis of polyphenylalanine.     

Substrate specificity and properties of the Escherichia coli 16S rRNA methyltransferase, RsmE

The small ribosome subunit of Escherichia coli contains 10 base-methylated sites distributed in important functional regions. At present, seven enzymes responsible for methylation of eight bases are known, but most of them have not been well characterized. One of these enzymes, RsmE, was recently identified and shown to specifically methylate U1498. Here we describe the enzymatic properties and substrate specificity of RsmE. The enzyme forms dimers in solution and is most active in the presence of 10-15 mM Mg(2+) and 100 mM NH(4)Cl at pH 7-9; however, in the presence of spermidine, Mg(2+) is not required for activity. While small ribosome subunits obtained from an RsmE deletion strain can be methylated by purified RsmE, neither 70S ribosomes nor 50S subunits are active. Likewise, 16S rRNA obtained from the mutant strain, synthetic 16S rRNA, and 3' minor domain RNA are all very poor or inactive as substrates. 30S particles partially depleted of proteins by treatment with high concentrations of LiCl or in vitro reconstituted intermediate particles also show little or no methyl acceptor activity. Based on these data, we conclude that RsmE requires a highly structured ribonucleoprotein particle as a substrate for methylation, and that methylation events in the 3' minor domain of 16S rRNA probably occur late during 30S ribosome assembly.     

YebU is a m5C methyltransferase specific for 16 S rRNA nucleotide 1407

The rRNAs in Escherichia coli contain methylations at 24 nucleotides, which collectively are important for ribosome function. Three of these methylations are m5C modifications located at nucleotides C967 and C1407 in 16S rRNA and at nucleotide C1962 in 23S rRNA. Bacterial rRNA modifications generally require specific enzymes, and only one m5C rRNA methyltransferase, RsmB (formerly Fmu) that methylates nucleotide C967, has previously been identified. BLAST searches of the E.coli genome revealed a single gene, yebU, with sufficient similarity to rsmB to encode a putative m5C RNA methyltransferase. This suggested that the yebU gene product modifies C1407 and/or C1962. Here, we analysed the E.coli rRNAs by matrix assisted laser desorption/ionization mass spectrometry and show that inactivation of the yebU gene leads to loss of methylation at C1407 in 16 S rRNA, but does not interfere with methylation at C1962 in 23 S rRNA. Purified recombinant YebU protein retains its specificity for C1407 in vitro, and methylates 30 S subunits (but not naked 16 S rRNA or 70 S ribosomes) isolated from yebU knockout strains. Nucleotide C1407 is located at a functionally active region of the 30 S subunit interface close to the P site, and YebU-directed methylation of this nucleotide seems to be conserved in bacteria. The yebU knockout strains display slower growth and reduced fitness in competition with wild-type cells. We suggest that a more appropriate designation for yebU would be the rRNA small subunit methyltransferase gene rsmF, and that the nomenclature system be extended to include the rRNA methyltransferases that still await identification.     

A paradigm for local conformational control of function in the ribosome: binding of ribosomal protein S19 to Escherichia coli 16S rRNA in the presence of S7 is required for methylation of m2G966 and blocks methylation of m5C967 by their respective methyltransferases.

We have partially purified two 16S rRNA-specific methyltransferases, one of which forms m2G966 (m2G MT), while the other one makes m5C967 (m5C MT). The m2G MT uses unmethylated 30S subunits as a substrate, but not free unmethylated 16S rRNA, while the m5C MT functions reciprocally, using free rRNA but not 30S subunits (Nègre, D., Weitzmann, C. and Ofengand, J. (1990) UCLA Symposium: Nucleic Acid Methylation (Alan Liss, New York), pp. 1-17). We have now determined the basis for this unusual inverse specificity at adjacent nucleotides. Binding of ribosomal proteins S7, S9, and S19 to unmodified 16S rRNA individually and in all possible combinations showed that S7 plus S19 were sufficient to block methylation by the m5C MT, while simultaneously inducing methylation by the m2G MT. A purified complex containing stoichiometric amounts of proteins S7, S9, and S19 bound to 16S rRNA was isolated and shown to possess the same methylation properties as 30S subunits, that is, the ability to be methylated by the m2G MT but not by the m5C MT. Since binding of S19 requires prior binding of S7, which had no effect on methylation when bound alone, we attribute the switch in methylase specificity solely to the presence of RNA-bound S19. Single-omission reconstitution of 30S subunits deficient in S19 resulted in particles that could not be efficiently methylated by either enzyme. Thus while binding of S19 is both necessary and sufficient to convert 16S rRNA into a substrate of the m2G MT, binding of either S19 alone or some other protein or combination of proteins to the 16S rRNA can abolish activity of the m5C MT. Binding of S19 to 16S rRNA is known to cause local conformational changes in the 960-975 stem-loop structure surrounding the two methylated nucleotides (Powers, T., Changchien, L.-M., Craven, G. and Noller, H.F. (1988) J. Mol. Biol. 200, 309-319). Our results show that the two ribosomal RNA MTs studied in this work are exquisitely sensitive to this small but nevertheless functionally important structural change.     

Purification of 30S ribosomal subunit by streptavidin affinity chromatography

Preparation of pure ribosomal subunits carrying lethal mutations is necessary for studying every essential functional region of ribosomal RNA. Affinity purification via a tag, inserted into rRNA proved to be procedure of choice for purification of such ribosomal subunits. Here we describe fast and simple purification method for the 30S ribosomal subunits using affinity chromatography. Streptavidin-binding tag was inserted into functionally neutral helix 33a of the 16 S rRNA from Escherichia coli. Tagged ribosomal subunits were shown to be expressed in E. coli and could be purified. Purified subunits with affinity tag behave similarly to the wild type subunits in association with the 50S subunits, toe-printing and tRNA binding assays. Tagged 30S subunits could support cell growth in the strain lacking wild type 30S subunits and only marginally change the growth rate of bacteria. The presented purification method is thus suitable for further use in purification of 30S subunits carrying any lethal mutations.