From stand-by to decoding site. Adjustment of the mRNA on the 30S ribosomal subunit under the influence of the initiation factors.

The hypothesis of an adjustment of the mRNA in its ribosomal channel under the influence of the initiation factors has been tested by site-directed crosslinking experiments. Complexes containing 30S subunits with bound mRNA having 4-thio-uracil at specific positions were prepared in the presence or absence of initiation factors and/or fMet-tRNA and subjected to UV irradiation to obtain specific crosslinks of the radioactively labeled mRNA with bases of the 16S rRNA and with ribosomal proteins. The subsequent identification of the specific sites of both mRNA and rRNA and individual ribosomal proteins involved in the crosslinking, obtained under different conditions of complex formation, provide direct evidence for the occurrence of a partial relocation of the mRNA on the 30S ribosomal subunits under the influence of the factors. The nature of this mRNA relocation is compatible with our previous proposal of a shift of the template from an initial ribosomal "stand-by site" to a second site closer to that occupied when the initiation triplet of the mRNA is decoded in the P-site.     

Mapping the three-dimensional locations of ribosomal RNA and proteins.

Seven regions of 16S rRNA have been located on the surface of the 30S ribosomal subunit by DNA hybridization electron microscopy in our laboratory. In addition, we have recently mapped the three-dimensional locations of an additional seven small ribosomal proteins by immunoelectron microscopy. The information from the direct mapping of the sites on rRNA has been incorporated into a model for the tertiary structure of 16S rRNA, accounting for approximately 40% of the total 16S rRNA. A novel structure, the platform ring, is proposed for a region of rRNA within the central domain. This structure rings the edges of the platform and includes regions 655-751 and 769-810. Another region, the recognition complex, consists of nucleotides 500-545, and occupies a region on the exterior surface of the subunit, near the EF-Tu binding site. In addition, 19 of the 21 small subunit ribosomal proteins have been mapped by immunoelectron microscopy in our laboratory. In order to evaluate the reliability of our model for the three-dimensional distribution of 16S rRNA, we have predicted which sites of rRNA are adjacent to ribosomal proteins and compared these predictions with r-protein protection studies of others. Good correlation between the model, the locations of rRNA sites, the locations of ribosomal proteins, and regions of rRNA protected by ribosomal proteins, provides independent support for this model.     

DNA-hybridization electron microscopy tertiary structure of 16 S rRNA

Seven regions of 16 S rRNA have been located on the surface of the 30 S ribosomal subunit by DNA-hybridization electron microscopy. This information has been incorporated into a model for the tertiary structure of 16 S rRNA, accounting for approximately 40% of the total 16 S rRNA. A structure labeled the platform ring is proposed for a region of rRNA within the central domain. This structure rings the edges of the platform and includes regions 655-751 and 769-810. Another region, the recognition complex, consists of nucleotides 500 to 545, and occupies a region on the exterior surface of the subunit near the elongation factor Tu binding site. Ribosomal proteins that have been mapped by immunoelectron microscopy are superimposed onto the model in order to examine possible regions of interaction. Good correlation between the model locations of ribosomal proteins, and regions of rRNA protected by ribosomal proteins provide independent support for this model.     

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.     

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.     

Directed hydroxyl radical probing of 16S ribosomal RNA in ribosomes containing Fe(II) tethered to ribosomal protein S20.

The 16S ribosomal RNA neighborhood of ribosomal protein S20 has been mapped, in both 30S subunits and 70S ribosomes, using directed hydroxyl radical probing. Cysteine residues were introduced at amino acid positions 14, 23, 49, and 57 of S20, and used for tethering 1-(p-bromoacetamidobenzyl)-Fe(II)-EDTA. In vitro reconstitution using Fe(II)-derivatized S20, together with the remaining small subunit ribosomal proteins and 16S ribosomal RNA (rRNA), yielded functional 30S subunits. Both 30S subunits and 70S ribosomes containing Fe(II)-S20 were purified and hydroxyl radicals were generated from the tethered Fe(II). Hydroxyl radical cleavage of the 16S rRNA backbone was monitored by primer extension. Different cleavage patterns in 16S rRNA were observed from Fe(II) tethered to each of the four positions, and these patterns were not significantly different in 30S and 70S ribosomes. Cleavage sites were mapped to positions 160-200, 320, and 340-350 in the 5' domain, and to positions 1427-1430 and 1439-1458 in the distal end of the penultimate stem of 16S rRNA, placing these regions near each other in three dimensions. These results are consistent with previous footprinting data that localized S20 near these 16S rRNA elements, providing evidence that S20, like S17, is located near the bottom of the 30S subunit.     

Structural-functional topography of human ribosomes based on the data from crosslinking with mRNA analogs--oligoribonucleotide derivatives

Reviewed are data on the position of template codons with respect to 18S rRNA and certain proteins on human ribosome obtained using a set of mRNA analogs, oligoribonucleotide derivatives carrying alkylating or photoactivatable group at different positions. A comparison of data on template position on the human and Escherichia coli ribosomes has revealed both the similarity in the structure of the mRNA-binding site of bacterial and mammalian ribosomes and the peculiarities of the functioning of mammalian (in particular, human) ribosomes. The similarity manifests itself in that the template codons at the A, P, and E sites of bacterial and human ribosomes are surrounded by similar nucleotides (occupying similar positions in the conserved regions of secondary structure) of small subunit rRNA. The template forms a loop whose foot is in proximity to the 530 stem-loop conserved region of rRNA. The specific features of mammalian ribosomes appear to be associated with their lower conformational mobility as compared with bacterial ribosomes, owing to which their interaction with the template involves a lesser number of molecular contacts.     

Mapping the ribosomal RNA neighborhood of protein L11 by directed hydroxyl radical probing.

Ribosomal protein L11 is a highly conserved protein that has been implicated in binding of elongation factors to ribosomes and associated GTP hydrolysis. Here, we have analyzed the ribosomal RNA neighborhood of Escherichia coli L11 in 50 S subunits by directed hydroxyl radical probing from Fe(II) tethered to five engineered cysteine residues at positions 19, 84, 85, 92 and 116 via the linker 1-(p -bromoacetamidobenzyl)-EDTA. Correct assembly of the L11 derivatives was analyzed by incorporating the modified proteins into 50 S subunits isolated from an E. coli strain that lacks L11 and testing for previously characterized L11-dependent footprints in domain II of 23 S rRNA. Hydroxyl radicals were generated from Fe(II) tethered to L11 and sites of cleavage in the ribosomal RNA were detected by primer extension. Strong cleavages were detected within the previously described binding site of L11, in the 1100 region of 23 S rRNA. Moreover, Fe(II) tethered to position 19 in L11 targeted the backbone of the sarcin loop in domain VI while probing from position 92 cleaved the backbone around bases 900 and 2470 in domains II and V, respectively. Fe(II) tethered to positions 84, 85 and 92 also generated cleavages in 5 S rRNA around helix II. These data provide new information about the positions of specific features of 23 S rRNA and 5 S rRNA relative to protein L11 in the 50 S subunit and show that L11 is near highly conserved elements of the rRNA that have been implicated in binding of tRNA and elongation factors to the ribosome.     

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.     

HCV IRES interacts with the 18S rRNA to activate the 40S ribosome for subsequent steps of translation initiation

Previous analyses of complexes of 40S ribosomal subunits with the hepatitis C virus (HCV) internal ribosome entry site (IRES) have revealed contacts made by the IRES with ribosomal proteins. Here, using chemical probing, we show that the HCV IRES also contacts the backbone and bases of the CCC triplet in the 18S ribosomal RNA (rRNA) expansion segment 7. These contacts presumably provide interplay between IRES domain II and the AUG codon close to ribosomal protein S5, which causes a rearrangement of 18S rRNA structure in the vicinity of the universally conserved nucleotide G1639. As a result, G1639 becomes exposed and the corresponding site of the 40S subunit implicated in transfer RNA discrimination can select . These data are the first demonstration at nucleotide resolution of direct IRES–rRNA interactions and how they induce conformational transition in the 40S subunit allowing the HCV IRES to function without AUG recognition initiation factors.     

Structure of the ribosome-associated 5.8 S ribosomal RNA

The structure of the 5.8 S ribosomal RNA in rat liver ribosomes was probed by comparing dimethyl sulfate-reactive sites in whole ribosomes, 60 S subunits, the 5.8 S-28 S rRNA complex and the free 5.8 S rRNA under conditions of salt and temperature that permit protein synthesis in vitro. Differences in reactive sites between the free and both the 28 S rRNA and 60 S subunit-associated 5.8 S rRNA show that significant conformational changes occur when the molecule interacts with its cognate 28 S rRNA and as the complex is further integrated into the ribosomal structure. These results indicate that, as previously suggested by phylogenetic comparisons of the secondary structure, only the "G + C-rich" stem may remain unaltered and a universal structure is probably present only in the whole ribosome or 60 S subunit. Further comparisons with the ribosome-associated molecule indicate that while the 5.8 S rRNA may be partly localized in the ribosomal interface, four cytidylic acid residues, C56, C100, C127 and C128, remain reactive even in whole ribosomes. In contrast, the cytidylic acid residues in the 5 S rRNA are not accessible in either the 60 S subunit or the intact ribosome. The nature of the structural rearrangements and potential sites of interaction with the 28 S rRNA and ribosomal proteins are discussed.     

Structural and Functional Topography of Human Ribosomes Deduced from Crosslinking with mRNA Analogs,Oligoribonucleotide Derivatives

Reviewed are data on the position of template codons with respect to 18S rRNA and certain proteins on human ribosome obtained using a set of mRNA analogs, oligoribonucleotide derivatives carrying alkylating or photoactivatable groups at different positions. A comparison of data on the template position on the human and Escherichia coliribosomes has revealed both the similarity in the structure of the mRNA-binding site of bacterial and mammalian ribosomes and the peculiarities of the functioning of mammalian (in particular, human) ribosomes. The similarity manifests itself in that the template codons at the A-, P-, and E-sites of bacterial and human ribosomes are surrounded by similar nucleotides (occupying similar positions in the conserved regions of secondary structure) of small subunit rRNA. The template forms a loop whose foot is in proximity to the 530 stem–loop conserved region of rRNA. The specific features of mammalian ribosomes appear to be associated with their lower conformational mobility as compared with bacterial ribosomes, owing to which their interaction with the template involves a lesser number of molecular contacts.     

Biochemical characterization of the ribosomal decoding site

Prior to the emergence of crystal structures of the ribosome, different ribosomal functions were identified with specific regions of ribosomal RNA by biochemical and genetic approaches. In particular, three universally conserved bases of 16S rRNA, G530, A1492 and A1493, were implicated in the interaction of the incoming aminoacyl-tRNA with the 30S subunit and mRNA. The conserved region surrounding A1492 and A1493 was called the "decoding site", based on the results of chemical probing experiments and antibiotic resistance mutations. Crystallographic studies from the Ramakrishnan laboratory have now shown that G530 loop, A1492 and A1493 undergo localized conformational changes to form an RNA structure that positions these three bases to inspect the accuracy of the codon-anticodon match with high stereochemical precision, using A-minor interactions. Some results from the pre-X-ray era may provide clues to further aspects of the decoding process.     

Structure of 5S rRNA within the Escherichia coli ribosome: iodine-induced cleavage patterns of phosphorothioate derivatives.

The protection patterns of 5S rRNA in solution, within the ribosomal 50S subunit, 70S ribosomes, and functional complexes, were assessed with the phosphorothioate method. About 20% of the analyzed positions (G9-G107) showed strong assembly defects: A phosphorothioate at one of these positions significantly impaired the incorporation of 5S rRNA into 50S particles. The reverse has also been observed: A phosphorothioate is preferred over a phosphate residue in the assembly process at a few positions. The results further demonstrate that 5S rRNA undergoes conformational changes during the assembly in the central protuberance of the 50S subunit and upon association with the small ribosomal subunit forming a 70S ribosome. In striking contrast, when the 70S ribosomes are once formed, the contact pattern of the 5S rRNA is the same in various functional states such as initiation-like complexes and pre- and posttranslocational states.     

Structural organization of the 16S ribosomal RNA from E. coli. Topography and secondary structure.

Extensive studies in our laboratory using different ribonucleases resulted in valuable data on the topography of the E.coli 16S ribosomal RNA within the native 30S subunit, within partially unfolded 30S subunits, in the free state, and in association with individual ribosomal proteins. Such studies have precise details on the accessibility of certain residues and delineated highly accessible RNA regions. Furthermore, they provided evidence that the 16S rRNA is organized in its subunit into four distinct domains. A secondary structure model of the E.coli 16S rRNA has been derived from these topographical data. Additional information from comparative sequence analyses of the small ribosomal subunit RNAs from other species sequenced so far has been used.     

A detailed model of the three-dimensional structure of Escherichia coli 16 S ribosomal RNA in situ in the 30 S subunit

A large body of intra-RNA and RNA-protein crosslinking data, obtained in this laboratory, was used to fold the phylogenetically and experimentally established secondary structure of Escherichia coli 16 S RNA into a three-dimensional model. All the crosslinks were induced in intact 30 S subunits (or in some cases in growing E. coli cells), and the sites of crosslinking were precisely localized on the RNA by oligonucleotide analysis. The RNA-protein crosslinking data (including 28 sites, and involving 13 of the 21 30S ribosomal were used to relate the RNA structure to the distribution of the proteins as determined by neutron scattering. The three-dimensional model of the 16 S RNA has overall dimensions of 220 A x 140 A x 90 A, in good agreement with electron microscopic estimates for the 30 S subunit. The shape of the model is also recognizably the same as that seen in electron micrographs, and the positions in the model of bases localized on the 30 S subunit by immunoelectron microscopy (the 5' and 3' termini, the m7G and m6(2)A residues, and C-1400) correspond closely to their experimentally observed positions. The distances between the RNA-protein crosslink sites in the model correlate well with the distances between protein centres of mass obtained by neutron scattering, only two out of 66 distances falling outside the expected tolerance limits. These two distances both involve protein S13, a protein noted for its anomalous behaviour. A comparison with other experimental information not specifically used in deriving the model shows that it fits well with published data on RNA-protein binding sites, mutation sites on the RNA causing resistance to antibiotics, tertiary interactions in the RNA, and a potential secondary structural "switch". Of the sites on 16 S RNA that have been found to be accessible to chemical modification in the 30 S subunit, 87% are at obviously exposed positions in the model. In contrast, 70% of the sites corresponding to positions that have ribose 2'-O-methylations in the eukaryotic 18 S RNA from Xenopus laevis are at non-exposed (i.e. internal) positions in the model. All nine of the modified bases in the E. coli 16 S RNA itself show a remarkable distribution, in that they form a "necklace" in one plane around the "throat" of the subunit. Insertions in eukaryotic 18 S RNA, and corresponding deletions in chloroplast or mammalian mitochondrial ribosomal RNA relative to E. coli 16 S RNA represent distinct sub-domains in the structure.(ABSTRACT TRUNCATED AT 400 WORDS)     

Sequence and structural conservation in RNA ribose zippers

The "ribose zipper", an important element of RNA tertiary structure, is characterized by consecutive hydrogen-bonding interactions between ribose 2'-hydroxyls from different regions of an RNA chain or between RNA chains. These tertiary contacts have previously been observed to also involve base-backbone and base-base interactions (A-minor type). We searched for ribose zipper tertiary interactions in the crystal structures of the large ribosomal subunit RNAs of Haloarcula marismortui and Deinococcus radiodurans, and the small ribosomal subunit RNA of Thermus thermophilus and identified a total of 97 ribose zippers. Of these, 20 were found in T. thermophilus 16 S rRNA, 44 in H. marismortui 23 S rRNA (plus 2 bridging 5 S and 23 S rRNAs) and 30 in D. radiodurans 23 S rRNA (plus 1 bridging 5 S and 23 S rRNAs). These were analyzed in terms of sequence conservation, structural conservation and stability, location in secondary structure, and phylogenetic conservation. Eleven types of ribose zippers were defined based on ribose-base interactions. Of these 11, seven were observed in the ribosomal RNAs. The most common of these is the canonical ribose zipper, originally observed in the P4-P6 group I intron fragment. All ribose zippers were formed by antiparallel chain interactions and only a single example extended beyond two residues, forming an overlapping ribose zipper of three consecutive residues near the small subunit A-site. Almost all ribose zippers link stem (Watson-Crick duplex) or stem-like (base-paired), with loop (external, internal, or junction) chain segments. About two-thirds of the observed ribose zippers interact with ribosomal proteins. Most of these ribosomal proteins bridge the ribose zipper chain segments with basic amino acid residues hydrogen bonding to the RNA backbone. Proteins involved in crucial ribosome function and in early stages of ribosomal assembly also stabilize ribose zipper interactions. All ribose zippers show strong sequence conservation both within these three ribosomal RNA structures and in a large database of aligned prokaryotic sequences. The physical basis of the sequence conservation is stacked base triples formed between consecutive base-pairs on the stem or stem-like segment with bases (often adenines) from the loop-side segment. These triples have previously been characterized as Type I and Type II A-minor motifs and are stabilized by base-base and base-ribose hydrogen bonds. The sequence and structure conservation of ribose zippers can be directly used in tertiary structure prediction and may have applications in molecular modeling and design.