Major rearrangements in the 70S ribosomal 3D structure caused by a conformational switch in 16S ribosomal RNA

Dynamic changes in secondary structure of the 16S rRNA during the decoding of mRNA are visualized by three-dimensional cryo-electron microscopy of the 70S ribosome. Thermodynamically unstable base pairing of the 912-910 (CUC) nucleotides of the 16S RNA with two adjacent complementary regions at nucleotides 885-887 (GGG) and 888-890 (GAG) was stabilized in either of the two states by point mutations at positions 912 (C912G) and 885 (G885U). A wave of rearrangements can be traced arising from the switch in the three base pairs and involving functionally important regions in both subunits of the ribosome. This significantly affects the topography of the A-site tRNA-binding region on the 30S subunit and thereby explains changes in tRNA affinity for the ribosome and fidelity of decoding mRNA.     

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.     

Use of lead(II) to probe the structure of large RNA's. Conformation of the 3' terminal domain of E. coli 16S rRNA and its involvement in building the tRNA binding sites

The present work shows that lead(II) can be used as a convenient structure probe to map the conformation of large RNA's and to follow discrete conformational changes at different functional states. We have investigated the conformation of the 3' domain of the E. coli 16S rRNA (nucleotides 1295-1542) in its naked form, in the 30S subunit and in the 70S ribosome. Our study clearly shows a preferential affinity of Pb(II) for interhelical and loop regions and suggests a high sensitivity for dynamic and flexible regions. Within 30S subunits, some cleavages are strongly decreased as the result of protein-induced protection, while others are enhanced suggesting local conformational adjustments. These rearrangements occur at functionally strategic regions of the RNA centered around nucleotides 1337, 1400, 1500 and near the 3' end of the RNA. The association of 30S and 50S subunits causes further protections at several nucleotides and some enhanced reactivities that can be interpreted in terms of subunits interface and allosteric transitions. The binding of E. coli tRNA-Phe to the 70S ribosome results in message-independent (positions 1337 and 1397) and message-dependent (1399-1400, 1491-1492 and 1505) protections. A third class of protection (1344-1345, 1393-1395, 1403-1409, 1412-1414, 1504, 1506-1507 and 1517-1519) is observed in message-directed 30S subunits, which are induced by both tRNA binding and 50S subunit association. This extensive reduction of reactivity most probably reflects an allosteric transition rather than a direct shielding.     

Differential assembly of 16S rRNA domains during 30S subunit formation

Rapid and accurate assembly of the ribosomal subunits, which are responsible for protein synthesis, is required to sustain cell growth. Our best understanding of the interaction of 30S ribosomal subunit components (16S ribosomal RNA [rRNA] and 20 ribosomal proteins [r-proteins]) comes from in vitro work using Escherichia coli ribosomal components. However, detailed information regarding the essential elements involved in the assembly of 30S subunits still remains elusive. Here, we defined a set of rRNA nucleotides that are critical for the assembly of the small ribosomal subunit in E. coli. Using an RNA modification interference approach, we identified 54 nucleotides in 16S rRNA whose modification prevents the formation of a functional small ribosomal subunit. The majority of these nucleotides are located in the head and interdomain junction of the 30S subunit, suggesting that these regions are critical for small subunit assembly. In vivo analysis of specific identified sites, using engineered mutations in 16S rRNA, revealed defective protein synthesis capability, aberrant polysome profiles, and abnormal 16S rRNA processing, indicating the importance of these residues in vivo. These studies reveal that specific segments of 16S rRNA are more critical for small subunit assembly than others, and suggest a hierarchy of importance.     

Following the dynamics of changes in solvent accessibility of 16 S and 23 S rRNA during ribosomal subunit association using synchrotron-generated hydroxyl radicals

We have probed the structure and dynamics of ribosomal RNA in the Escherichia coli ribosome using equilibrium and time-resolved hydroxyl radical (OH) RNA footprinting to explore changes in the solvent-accessible surface of the rRNA with single-nucleotide resolution. The goal of these studies is to better understand the structural transitions that accompany association of the 30 S and 50 S subunits and to build a foundation for the quantitative analysis of ribosome structural dynamics during translation. Clear portraits of the subunit interface surfaces for 16 S and 23 S rRNA were obtained by constructing difference maps between the OH protection maps of the free subunits and that of the associated ribosome. In addition to inter-subunit contacts consistent with the crystal structure, additional OH protections are evident in regions at or near the subunit interface that reflect association-induced conformational changes. Comparison of these data with the comparable difference maps of the solvent-accessible surface of the rRNA calculated for the Thermus thermophilus X-ray crystal structures shows extensive agreement but also distinct differences. As a prelude to time-resolved OH footprinting studies, the reactivity profiles obtained using Fe(II)EDTA and X-ray generated OH were comprehensively compared. The reactivity patterns are similar except for a small number of nucleotides that have decreased reactivity to OH generated from Fe(II)EDTA compared to X-rays. These nucleotides are generally close to ribosomal proteins, which can quench diffusing radicals by virtue of side-chain oxidation. Synchrotron X-ray OH footprinting was used to monitor the kinetics of association of the 30 S and 50 S subunits. The rates individually measured for the inter-subunit contacts are comparable within experimental error. The application of this approach to the study of ribosome dynamics during the translation cycle is discussed.     

Topography of 16 S RNA in 30 S subunits and 70 S ribosomes accessibility to cobra venom ribonuclease

A ribonuclease extracted from the venom of the cobra Naja oxiana, which shows an unusual specificity for double-stranded RNA regions, was used to obtain new insight on the topography of Escherichia coli ribosomal 16 S RNA in the 30 S subunit and in the 70 S couple. ³²P-labeled 30 S subunits or reconstituted 70 S tight couples containing ³²P-labeled 16 S RNA have been digested under progressively stronger conditions. The cleavage sites have been precisely localized and the chronology of the hydrolysis process studied.The enzyme cleaves the 16 S RNA within 30 S subunits at 21 different sites, which are not uniformly distributed along the molecule. These results provide valuable information on the 16 S RNA topography and evidence for secondary structure features.The binding of the 50 S subunit markedly reduces the rate of the 16 S RNA hydrolysis and provides protection for several cleavage sites. Four of them are clustered in the 3′-terminal 200 nucleotides of the molecule, one in the middle (at position 772) and one in the 5′ domain (at position 336). Our results provide further evidence that the 3′-terminal and central regions of the RNA chain are close to each other in the ribosome structure and lie at the interface of the two subunits. They also suggest that the 5′ domain is probably not involved exclusively in structure and assembly.     

Use of Lead(II) to Probe the Structure of Large RNA's. Conformation of the 3′ Terminal Domain of E. coli 16S rRNA and its Involvement in Building the tRNA Binding Sites

Abstract

The present work shows that lead(II) can be used as a convenient structure probe to map the conformation of large RNA's and to follow discrete conformational changes at different functional states. We have investigated the conformation of the 3′ domain of the E. coli 16S rRNA (nucleotides 1295–1542) in its naked form, in the 30S subunit and in the 70S ribosome. Our study clearly shows a preferential affinity of Pb(II) for interhelical and loop regions and suggests a high sensitivity for dynamic and flexible regions. Within 30S subunits, some cleavages are strongly decreased as the result of protein-induced protection, while others are enhanced suggesting local conformational ajustments. These rearrangements occur at functionally strategic regions of the RNA centered around nucleotides 1337,1400,1500 and near the 3′ end of the RNA The association of 30S and 50S subunits causes further protections at several nucleotides and some enhanced reactivities that can be interpreted in terms of subunits interface and allosteric transitions. The binding of E. coli tRNA-Phe to the 70S ribosome results in message-independent (positions 1337 and 1397) and message-dependent (1399–1400, 1491–1492 and 1505) protections. Athird class ofprotection(1344–1345,1393–1395,1403–1409,1412–1414, 1504, 1506–1507 and 1517–1519) is observed in message-directed 30S subunits, which are induced by both tRNA binding and 50S subunit association. This extensive reduction of reactivity most probably reflects an allosteric transition rather than a direct shielding.     

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.     

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.     

Probing the structure of 16 S ribosomal RNA from Bacillus brevis

A majority (approximately 89%) of the nucleotide sequence of Bacillus brevis 16 S rRNA has been determined by a combination of RNA sequencing methods. Several experimental approaches have been used to probe its structure, including (a) partial RNase digestion of 30 S ribosomal subunits, followed by two-dimensional native/denatured gel electrophoresis, in which base-paired fragments were directly identified; (b) identification of positions susceptible to cleavage by RNase A and RNase T1 in 30 S subunits; (c) sites of attack by cobra venom RNase on naked 16 S rRNA; and (d) nucleotides susceptible to attack by bisulfite in 16 S rRNA. These data are discussed with respect to a secondary structure model for B. brevis 16 S rRNA derived by comparative sequence analysis.     

Secondary structure model for bacterial 16S ribosomal RNA: phylogenetic, enzymatic and chemical evidence.

We have derived a secondary structure model for 16S ribosomal RNA on the basis of comparative sequence analysis, chemical modification studies and nuclease susceptibility data. Nucleotide sequences of the E. coli and B. brevis 16S rRNA chains, and of RNAse T1 oligomer catalogs from 16S rRNAs of over 100 species of eubacteria were used for phylogenetic comparison. Chemical modification of G by glyoxal, A by m-chloroperbenzoic acid and C by bisulfite in naked 16S rRNA, and G by kethoxal in active and inactive 30S ribosomal subunits was taken as an indication of single stranded structure. Further support for the structure was obtained from susceptibility to RNases A and T1. These three approaches are in excellent agreement. The structure contains fifty helical elements organized into four major domains, in which 46 percent of the nucleotides of 16S rRNA are involved in base pairing. Phylogenetic comparison shows that highly conserved sequences are found principally in unpaired regions of the molecule. No knots are created by the structure.     

Conformational change in the 16S rRNA in the Escherichia coli 70S ribosome induced by P/P- and P/E-site tRNAPhe binding

The effects of P/P- and P/E-site tRNA(Phe) binding on the 16S rRNA structure in the Escherichia coli 70S ribosome were investigated using UV cross-linking. The identity and frequency of 16S rRNA intramolecular cross-links were determined in the presence of deacyl-tRNA(Phe) or N-acetyl-Phe-tRNA(Phe) using poly(U) or an mRNA analogue containing a single Phe codon. For N-acetyl-Phe-tRNA(Phe) with either poly(U) or the mRNA analogue, the frequency of an intramolecular cross-link C967 x C1400 in the 16S rRNA was decreased in proportion to the binding stoichiometry of the tRNA. A proportional effect was true also for deacyl-tRNA(Phe) with poly(U), but the decrease in the C967 x C1400 frequency was less than the tRNA binding stoichiometry with the mRNA analogue. The inhibition of the C967 x C1400 cross-link was similar in buffers with, or without, polyamines. The exclusive participation of C967 with C1400 in the cross-link was confirmed by RNA sequencing. One intermolecular cross-link, 16S rRNA (C1400) to tRNA(Phe)(U33), was made with either poly(U) or the mRNA analogue. These results indicate a limited structural change in the small subunit around C967 and C1400 during tRNA P-site binding sensitive to the type of mRNA that is used. The absence of the C967 x C1400 cross-link in 70S ribosome complexes with tRNA is consistent with the 30S and 70S crystal structures, which contain tRNA or tRNA analogues; the occurrence of the cross-link indicates an alternative arrangement in this region in empty ribosomes.     

Probing the phosphates of the Escherichia coli ribosomal 16S RNA in its naked form, in the 30S subunit, and in the 70S ribosome

Ethylnitrosourea is an alkylating reagent which preferentially modifies phosphates in nucleic acids. It was used to map phosphates in naked Escherichia coli 16S rRNA engaged in tertiary interactions through hydrogen bonds or ion coordination. Of the phosphates, 7% are found involved in such interactions, and 57% of them are located in loops or interhelical regions, where they are involved in maintaining local intrinsic structures or long-distance tertiary interactions. The other phosphates (43%) are found in helical regions. These phosphates often occur at the proximity of bulged nucleotides or in irregular helices containing noncanonical base pairs (and bulges) and are assumed to bind cations in order to neutralize negative charges and to stabilize unusual phosphate backbone folding. In the 30S subunit, ENU allowed mapping of phosphates in contact with proteins. The RNA is not uniformly engaged in RNA/protein interactions. Regions 1-51, 250-310, 567-612, 650-670, and 1307-1382 are particularly buried whereas the 3'-terminal domain and the 5'-proximal region (nucleotides 53-218) are exposed. The conformation of 16S rRNA is not drastically affected by protein binding, but conformational adjustments are detected in several defined regions. They are found in the 5' domain (region 147-172), in the central domain (region 827-872), in the 3' major domain (nucleotides 955-956, 994, 1054, 1181, 1257, and 1262-1263), and in the 3'-terminal domain (around 1400). The 50S subunit shields clusters of phosphates located at the subunit interface. The most extensive protections are observed in the 3'-terminal domain (1490-1542), in the central region of the molecule (770-930), and in the upper 3' major domain.(ABSTRACT TRUNCATED AT 250 WORDS)     

The Shine and Dalgarno hypothesis for termination: the 3' terminus of the 16S rRNA of the Escherichia coli ribosome can be modified or base-paired with a complementary oligonucleotide without affecting termination in vitro

The occurrence of the nucleotides "...CCUUAOH" at the 3' terminus of the 16S rRNA of the small subunit of the Escherichia coli ribosome led to the suggestion that they may have a direct base pairing with the termination codon in the termination event of protein biosynthesis (Shine and Dalgarno 1974). We have examined this concept with two approaches, firstly using a 30S subunit whose 16S rRNA has been modified with a fluorescein moiety on the terminal adenosine together with the antibody against the moiety, and secondly with an oligonucleotide, UAAGG, complementary to the terminal pentanucleotide sequence of the rRNA. Collectively the data suggest that the nucleotides at the 3' terminus of 16S rRNA are not critically involved in base pairing during termination codon recognition.     

A functional relationship between helix 1 and the 900 tetraloop of 16S ribosomal RNA within the bacterial ribosome

The conserved 900 tetraloop that caps helix 27 of 16S ribosomal RNA (rRNA) interacts with helix 24 of 16S rRNA and also with helix 67 of 23S rRNA, forming the intersubunit bridge B2c, proximal to the decoding center. In previous studies, we investigated how the interaction between the 900 tetraloop and helix 24 participates in subunit association and translational fidelity. In the present study, we investigated whether the 900 tetraloop is involved in other undetected interactions with different regions of the Escherichia coli 16S rRNA. Using a genetic complementation approach, we selected mutations in 16S rRNA that compensate for a 900 tetraloop mutation, A900G, which severely impairs subunit association and translational fidelity. Mutations were randomly introduced in 16S rRNA, using either a mutagenic XL1-Red E. coli strain or an error-prone PCR strategy. Gain-offunction mutations were selected in vivo with a specialized ribosome system. Two mutations, the deletion of U12 and the U12C substitution, were thus independently selected in helix 1 of 16S rRNA. This helix is located in the vicinity of helix 27, but does not directly contact the 900 tetraloop in the crystal structures of the ribosome. Both mutations correct the subunit association and translational fidelity defects caused by the A900G mutation, revealing an unanticipated functional interaction between these two regions of 16S rRNA.