Structure and accessibility of domain I of Escherichia coli 23 S RNA in free RNA, in the L24-RNA complex and in 50 S subunits. Implications for ribosomal assembly

Force measurements show that uL4 and uL24 mechanically stabilize a fragment of 23S rRNA essential for ribosome assembly

In vitro reconstitution studies have shown that ribosome assembly is highly cooperative and starts with the binding of a few ribosomal (r-) proteins to rRNA. It is unknown how these early binders act. Focusing on the initial stage of the assembly of the large subunit of the Escherichia coli ribosome, we prepared a 79-nucleotide-long region of 23S rRNA encompassing the binding sites of the early binders uL4 and uL24. Force signals were measured in a DNA/RNA dumbbell configuration with a double optical tweezers setup. The rRNA fragment was stretched until unfolded, in the absence or in the presence of the r-proteins (either uL4, uL24, or both). We show that the r-proteins uL4 and uL24 individually stabilize the rRNA fragment, both acting as molecular clamps. Interestingly, this mechanical stabilization is enhanced when both proteins are bound simultaneously. Independently, we observe a cooperative binding of uL4 and uL24 to the rRNA fragment. These two aspects of r-proteins binding both contribute to the efficient stabilization of the 3D structure of the rRNA fragment under investigation. We finally consider implications of our results for large ribosomal subunit assembly.

Saccharomyces cerevisiae ribosomal protein L26 is not essential for ribosome assembly and function

Ribosomal proteins play important roles in ribosome biogenesis and function. Here, we study the evolutionarily conserved L26 in Saccharomyces cerevisiae, which assembles into pre-60S ribosomal particles in the nucle(ol)us. Yeast L26 is one of the many ribosomal proteins encoded by two functional genes. We have disrupted both genes; surprisingly, the growth of the resulting rpl26 null mutant is apparently identical to that of the isogenic wild-type strain. The absence of L26 minimally alters 60S ribosomal subunit biogenesis. Polysome analysis revealed the appearance of half-mers. Analysis of pre-rRNA processing indicated that L26 is mainly required to optimize 27S pre-rRNA maturation, without which the release of pre-60S particles from the nucle(ol)us is partially impaired. Ribosomes lacking L26 exhibit differential reactivity to dimethylsulfate in domain I of 25S/5.8S rRNAs but apparently are able to support translation in vivo with wild-type accuracy. The bacterial homologue of yeast L26, L24, is a primary rRNA binding protein required for 50S ribosomal subunit assembly in vitro and in vivo. Our results underscore potential differences between prokaryotic and eukaryotic ribosome assembly. We discuss the reasons why yeast L26 plays such an apparently nonessential role in the cell.

Domain III of the T. thermophilus 23S rRNA folds independently to a near-native state

The three-dimensional structure of the ribosomal large subunit (LSU) reveals a single morphological element, although the 23S rRNA is contained in six secondary structure domains. Based upon maps of inter- and intra-domain interactions and proposed evolutionary pathways of development, we hypothesize that Domain III is a truly independent structural domain of the LSU. Domain III is primarily stabilized by intra-domain interactions, negligibly perturbed by inter-domain interactions, and is not penetrated by ribosomal proteins or other rRNA. We have probed the structure of Domain III rRNA alone and when contained within the intact 23S rRNA using SHAPE (selective 2'-hydroxyl acylation analyzed by primer extension), in the absence and presence of magnesium. The combined results support the hypothesis that Domain III alone folds to a near-native state with secondary structure, intra-domain tertiary interactions, and inter-domain interactions that are independent of whether or not it is embedded in the intact 23S rRNA or within the LSU. The data presented support previous suggestions that Domain III was added relatively late in ribosomal evolution.

The function of RH22, a DEAD RNA helicase, in the biogenesis of the 50S ribosomal subunits of Arabidopsis chloroplasts

The chloroplast ribosome is a large and dynamic ribonucleoprotein machine that is composed of the 30S and 50S subunits. Although the components of the chloroplast ribosome have been identified in the last decade, the molecular mechanisms driving chloroplast ribosome biogenesis remain largely elusive. Here, we show that RNA helicase 22 (RH22), a putative DEAD RNA helicase, is involved in chloroplast ribosome assembly in Arabidopsis (Arabidopsis thaliana). A loss of RH22 was lethal, whereas a knockdown of RH22 expression resulted in virescent seedlings with clear defects in chloroplast ribosomal RNA (rRNA) accumulation. The precursors of 23S and 4.5S, but not 16S, rRNA accumulated in rh22 mutants. Further analysis showed that RH22 was associated with the precursors of 50S ribosomal subunits. These results suggest that RH22 may function in the assembly of 50S ribosomal subunits in chloroplasts. In addition, RH22 interacted with the 50S ribosomal protein RPL24 through yeast two-hybrid and pull-down assays, and it was also bound to a small 23S rRNA fragment encompassing RPL24-binding sites. This action of RH22 may be similar to, but distinct from, that of SrmB, a DEAD RNA helicase that is involved in the ribosomal assembly in Escherichia coli, which suggests that DEAD RNA helicases and rRNA structures may have coevolved with respect to ribosomal assembly and function.

Effects of a short-term exposure to the fungicide prochloraz on endocrine function and gene expression in female fathead minnows (Pimephales promelas)

Prochloraz is a fungicide known to cause endocrine disruption through effects on the hypothalamic-pituitary-gonadal (HPG) axis. To determine the short-term impacts of prochloraz on gene expression and steroid production, adult female fathead minnows (Pimephales promelas) were exposed to the chemical (0 or 300 μg/L) for a time-course of 6, 12 and 24 h. Consistent with inhibition of cytochrome P450 17α-hydroxylase/17,20-lyase (CYP17) and aromatase (CYP19), known molecular targets of prochloraz, plasma 17β-estradiol (E2) was reduced within 6 h. Ex vivo E2 production was significantly reduced at all time-points, while ex vivo testosterone (T) production remained unchanged. Consistent with the decrease in E2 levels, plasma concentrations of the estrogen-responsive protein vitellogenin were significantly reduced at 24 h. Genes coding for CYP19, CYP17, and steroidogenic acute regulatory protein were up-regulated in a compensatory manner in ovaries of the prochloraz-treated fish. In addition to targeted quantitative real-time polymerase chain reaction analyses, a 15k feature fathead minnow microarray was used to determine gene expression profiles in ovaries. From time-point to time-point, the microarray results showed a relatively rapid change in the differentially expressed gene (DEG) profiles associated with the chemical exposure. Functional analysis of the DEGs indicated changes in expression of genes associated with cofactor and coenzyme binding (GO:0048037 and 0050662), fatty acid binding (GO:0005504) and organelle organization and biogenesis (GO:0006996). Overall, the results from this study are consistent with compensation of the fish HPG axis to inhibition of steroidogenesis by prochloraz, and provide further insights into relatively rapid, system-wide, effects of a model chemical stressor on fish.

DMS footprinting of structured RNAs and RNA-protein complexes

We describe a protocol in which dimethyl sulfate (DMS) modification of the base-pairing faces of unpaired adenosine and cytidine nucleotides is used for structural analysis of RNAs and RNA-protein complexes (RNPs). The protocol is optimized for RNAs of small to moderate size (< or = 500 nt). The RNA or RNP is first exposed to DMS under conditions that promote formation of the folded structure or complex, as well as 'control' conditions that do not allow folding or complex formation. The positions and extents of modification are then determined by primer extension, polyacrylamide gel electrophoresis and quantitative analysis. From changes in the extent of modification upon folding or protein binding (appearance of a 'footprint'), it is possible to detect local changes in the secondary and tertiary structure of RNA, as well as the formation of RNA-protein contacts. This protocol takes 1.5-3 d to complete, depending on the type of analysis used.

Size, shape, and flexibility of RNA structures

Determination of sizes and flexibilities of RNA molecules is important in understanding the nature of packing in folded structures and in elucidating interactions between RNA and DNA or proteins. Using the coordinates of the structures of RNA in the Protein Data Bank we find that the size of the folded RNA structures, measured using the radius of gyration R(G), follows the Flory scaling law, namely, R(G)=5.5N(1/3) A, where N is the number of nucleotides. The shape of RNA molecules is characterized by the asphericity Delta and the shape S parameters that are computed using the eigenvalues of the moment of inertia tensor. From the distribution of Delta, we find that a large fraction of folded RNA structures are aspherical and the distribution of S values shows that RNA molecules are prolate (S>0). The flexibility of folded structures is characterized by the persistence length l(p). By fitting the distance distribution function P(r), that is computed using the coordinates of the folded RNA, to the wormlike chain model we extracted the persistence length l(p). We find that l(p) approximately 1.5N(0.33) A which might reflect the large separation between the free energies that stabilize secondary and tertiary structures. The dependence of l(p) on N implies that the average length of helices should increase as the size of RNA grows. We also analyze packing in the structures of ribosomes (30S, 50S, and 70S) in terms of R(G), Delta, S, and l(p). The 70S and the 50S subunits are more spherical compared to most RNA molecules. The globularity in 50S is due to the presence of an unusually large number (compared to 30S subunit) of small helices that are stitched together by bulges and loops. Comparison of the shapes of the intact 70S ribosome and the constituent particles suggests that folding of the individual molecules might occur prior to assembly.

Importance of transient structures during post-transcriptional refolding of the pre-23S rRNA and ribosomal large subunit assembly

An important step of ribosome assembly is the folding of the rRNA into a functional structure. Despite knowledge of the folded state of rRNA in the ribosomal subunits, there is very little information on the rRNA folding pathway. We are interested in understanding how the functional structure of rRNA is formed and whether the rRNA folding intermediates have a role in ribosome assembly. To this end, transient secondary structures around both ends of pre-23S rRNA were analyzed by a chemical probing approach, using pre-23S rRNA transcripts. Metastable hairpin loop structures were found at both ends of 23S rRNA. The functional importance of the transient structures around the ends of 23S rRNA was tested by mutations that alter only the transient structure. The effect of mutations on 23S rRNA folding was tested in vitro and in vivo. It was found that both stabilization and destabilization of the transient structure around the 5' end of 23S rRNA inhibits post-transcriptional refolding in vitro and ribosome formation in vivo. The data suggest that the transient structure of rRNA has a function during 23S rRNA folding and thereby in ribosome assembly.

Using an RNA secondary structure partition function to determine confidence in base pairs predicted by free energy minimization

A partition function calculation for RNA secondary structure is presented that uses a current set of nearest neighbor parameters for conformational free energy at 37 degrees C, including coaxial stacking. For a diverse database of RNA sequences, base pairs in the predicted minimum free energy structure that are predicted by the partition function to have high base pairing probability have a significantly higher positive predictive value for known base pairs. For example, the average positive predictive value, 65.8%, is increased to 91.0% when only base pairs with probability of 0.99 or above are considered. The quality of base pair predictions can also be increased by the addition of experimentally determined constraints, including enzymatic cleavage, flavin mono-nucleotide cleavage, and chemical modification. Predicted secondary structures can be color annotated to demonstrate pairs with high probability that are therefore well determined as compared to base pairs with lower probability of pairing.

The roles of ribosomal proteins in the structure assembly, and evolution of the large ribosomal subunit

The structures of ribosomal proteins and their interactions with RNA have been examined in the refined crystal structure of the Haloarcula marismortui large ribosomal subunit. The protein structures fall into six groups based on their topology. The 50S subunit proteins function primarily to stabilize inter-domain interactions that are necessary to maintain the subunit's structural integrity. An extraordinary variety of protein-RNA interactions is observed. Electrostatic interactions between numerous arginine and lysine residues, particularly those in tail extensions, and the phosphate groups of the RNA backbone mediate many protein-RNA contacts. Base recognition occurs via both the minor groove and widened major groove of RNA helices, as well as through hydrophobic binding pockets that capture bulged nucleotides and through insertion of amino acid residues into hydrophobic crevices in the RNA. Primary binding sites on contiguous RNA are identified for 20 of the 50S ribosomal proteins, which along with few large protein-protein interfaces, suggest the order of assembly for some proteins and that the protein extensions fold cooperatively with RNA. The structure supports the hypothesis of co-transcriptional assembly, centered around L24 in domain I. Finally, comparing the structures and locations of the 50S ribosomal proteins from H.marismortui and D.radiodurans revealed striking examples of molecular mimicry. These comparisons illustrate that identical RNA structures can be stabilized by unrelated proteins.

Incorporating chemical modification constraints into a dynamic programming algorithm for prediction of RNA secondary structure

A dynamic programming algorithm for prediction of RNA secondary structure has been revised to accommodate folding constraints determined by chemical modification and to include free energy increments for coaxial stacking of helices when they are either adjacent or separated by a single mismatch. Furthermore, free energy parameters are revised to account for recent experimental results for terminal mismatches and hairpin, bulge, internal, and multibranch loops. To demonstrate the applicability of this method, in vivo modification was performed on 5S rRNA in both Escherichia coli and Candida albicans with 1-cyclohexyl-3-(2-morpholinoethyl) carbodiimide metho-p-toluene sulfonate, dimethyl sulfate, and kethoxal. The percentage of known base pairs in the predicted structure increased from 26.3% to 86.8% for the E. coli sequence by using modification constraints. For C. albicans, the accuracy remained 87.5% both with and without modification data. On average, for these sequences and a set of 14 sequences with known secondary structure and chemical modification data taken from the literature, accuracy improves from 67% to 76%. This enhancement primarily reflects improvement for three sequences that are predicted with <40% accuracy on the basis of energetics alone. For these sequences, inclusion of chemical modification constraints improves the average accuracy from 28% to 78%. For the 11 sequences with <6% pseudoknotted base pairs, structures predicted with constraints from chemical modification contain on average 84% of known canonical base pairs.

The structural basis of large ribosomal subunit function

The ribosome crystal structures published in the past two years have revolutionized our understanding of ribonucleoprotein structure, and more specifically, the structural basis of the peptide bonding forming activity of the ribosome. This review concentrates on the crystallographic developments that made it possible to solve these structures. It also discusses the information obtained from these structures about the three-dimensional architecture of the large ribosomal subunit, the mechanism by which it facilitates peptide bond formation, and the way antibiotics inhibit large subunit function. The work reviewed, taken as a whole, proves beyond doubt that the ribosome is an RNA enzyme, as had long been surmised on the basis of less conclusive evidence.

All three functional domains of the large ribosomal subunit protein L25 are required for both early and late pre-rRNA processing steps in Saccharomyces cerevisiae

Mutational analysis has shown that the integrity of the region in domain III of 25S rRNA that is involved in binding of ribosomal protein L25 is essential for the production of mature 25S rRNA in the yeast Saccharomyces cerevisiae. However, even structural alterations that do not noticeably affect recognition by L25, as measured by an in vitro assay, strongly reduced 25S rRNA formation by inhibiting the removal of ITS2 from the 27S(B) precursor. In order to analyze the role of L25 in yeast pre-rRNA processing further we studied the effect of genetic depletion of the protein or mutation of each of its three previously identified functional domains, involved in nuclear import (N-terminal), RNA binding (central) and 60S subunit assembly (C-terminal), respectively. Depletion of L25 or mutating its (pre-)rRNA-binding domain blocked conversion of the 27S(B) precursor to 5.8S/25S rRNA, confirming that assembly of L25 is essential for ITS2 processing. However, mutations in either the N- or the C-terminal domain of L25, which only marginally affect its ability to bind to (pre-)rRNA, also resulted in defective ITS2 processing. Furthermore, in all cases there was a notable reduction in the efficiency of processing at the early cleavage sites A0, A1 and A2. We conclude that the assembly of L25 is necessary but not sufficient for removal of ITS2, as well as for fully efficient cleavage at the early sites. Additional elements located in the N- as well as C-terminal domains of L25 are required for both aspects of pre-rRNA processing.

Selecting rRNA binding sites for the ribosomal proteins L4 and L6 from randomly fragmented rRNA: application of a method called SERF

Two-thirds of the 54 proteins of the Escherichia coli ribosome interact directly with the rRNAs, but the rRNA binding sites of only a very few proteins are known. We present a method (selection of random RNA fragments; SERF) that can identify the minimal binding region for proteins within ribonucleo-protein complexes such as the ribosome. The power of the method is exemplified with the ribosomal proteins L4 and L6. Binding sequences are identified for both proteins and characterized by phosphorothioate footprinting. Surprisingly, the binding region of L4, a 53-nt rRNA fragment of domain I of 23S rRNA, can simultaneously and independently bind L24, one of the two assembly initiator proteins of the large subunit.

Domain III of Saccharomyces cerevisiae 25 S ribosomal RNA: its role in binding of ribosomal protein L25 and 60 S subunit formation

Domain III of Saccharomyces cerevisiae 25 S rRNA contains the recognition site for the primary rRNA-binding ribosomal protein L25, which belongs to the functionally conserved EL23/L25 family of ribosomal proteins. The EL23/L25 binding region is very complex, consisting of several irregular helices held together by long-distance secondary and tertiary interactions. Moreover, it contains the eukaryote-specific V9 (D7a) expansion segment. Functional characterisation of the structural elements of this site by a detailed in vitro and in vivo mutational analysis indicates the presence of two separate regions that are directly involved in L25 binding. In particular, mutation of either of two conserved nucleotides in the loop of helix 49 significantly reduces in vitro L25 binding, thus strongly supporting their role as attachment sites for the r-protein. Two other helices appear to be primarily required for the correct folding of the binding site. Mutations that abolish in vitro binding of L25 block accumulation of 25 S rRNA in vivo because they stall pre-rRNA processing at the level of its immediate precursor, the 27 S(B) pre-rRNA. Surprisingly, several mutations that do not significantly affect L25 binding in vitro cause the same lethal defect in 27 S(B) pre-rRNA processing. Deletion of the V9 expansion segment also leads to under-accumulation of mature 25 S rRNA and a twofold reduction in growth rate. We conclude that an intact domain III, including the V9 expansion segment, is essential for normal processing and assembly of 25 S rRNA.

Ribosomal protein L15 as a probe of 50 S ribosomal subunit structure

L15, a 15 kDa protein of the large ribosomal subunit, interacts with over ten other proteins during 50 S assembly in vitro. We have probed the interaction L15 with 23 S rRNA in 50 S ribosomal subunits by chemical footprinting, and have used localized hydroxyl radical probing, generated from Fe(II) tethered to unique sites of L15, to characterize the three-dimensional 23 S rRNA environment of L15. Footprinting of L15 was done by reconstituting purified, recombinant L15 with core particles derived from Escherichia coli 50 S subunits by treatment with 2 M LiCl. The cores migrate as compact 50 S-like particles in sucrose gradients, contain 23 S and 5 S rRNA, and lack a subset of the 50 S proteins, including L15. Using both Fe(II).EDTA and dimethyl sulfate, we have identified a strong footprint for L15 in the region spanning nucleotides 572-654 in domain II of 23 S rRNA. This footprint cannot be detected when L15 is incubated with "naked" 23 S rRNA, indicating that formation of the L15 binding site requires a partially assembled particle.Protein-tethered hydroxyl radical probing was done using mutants of L15 containing single cysteine residues at amino acid positions 68, 71 and 115. The mutant proteins were derivatized with 1-[p-(bromo-acetamido)benzyl]-EDTA. Fe(II), bound to core particles, and hydroxyl radical cleavage was initiated. Distinct but overlapping sets of cleavages were obtained in the footprinted region of domain II, and in specific regions of domains I, IV and V of 23 S rRNA. These data locate L15 in proximity to several 23 S rRNA elements that are dispersed in the secondary structure, consistent with its central role in the latter stages of 50 S subunit assembly. Furthermore, these results indicate the proximity of these rRNA regions to one another, providing constraints on the tertiary folding of 23 S rRNA.

Assembly of proteins and 5 S rRNA to transcripts of the major structural domains of 23 S rRNA

The six major structural domains of 23 S rRNA from Escherichia coli, and all combinations thereof, were synthesized as separate T7 transcripts and reconstituted with total 50 S subunit proteins. Analysis by one and two-dimensional gel electrophoresis demonstrated the presence of at least one primary binding protein associated with each RNA domain and additional proteins assembled to domains I, II, V and VI. For all the combinations of two to five domains, enhanced assembly yields and/or new proteins were observed primarily to those transcripts containing either domains I+II or domains V+VI. This indicates that there are two major protein assembly centres located at the ends of the 23 S rRNA, which is consistent with an earlier view that in vitro protein assembly nucleates around proteins L24 and L3. Although similar protein assembly patterns were observed over a range of temperature and magnesium concentrations, protein L2 assembled strongly with domains II and IV at 4-8 mM Mg2+ (the first step of the two-step reconstitution procedure) and with domain IV alone at higher Mg2+ concentrations (the second step). It is proposed that this change in protein-RNA binding provides a basis for the two-step reconstitution in vitro. A chemical footprinting approach was employed on the reconstituted protein-domain complexes to localize a putative L4 binding region within domain I to a region that is partially co-structural with the site on the L4-mRNA where L4 binds and inhibits its own translation. A similar approach was used to map the putative binding regions on domain V of protein L9 and the 5 S RNA-L5-L18 complex.

A common motif organizes the structure of multi-helix loops in 16 S and 23 S ribosomal RNAs

Phylogenetic and chemical probing data indicate that a modular RNA motif, common to loop E of eucaryotic 5 S ribosomal RNA (rRNA) and the alpha-sarcin/ricin loop of 23 S rRNA, organizes the structure of multi-helix loops in 16 S and 23 S ribosomal RNAs. The motif occurs in the 3' domain of 16 S rRNA at positions 1345-1350/1372-1376 (Escherichia coli numbering), within the three-way junction loop, which binds ribosomal protein S7, and which contains nucleotides that help to form the binding site for P-site tRNA in the ribosome. The motif also helps to structure a three-way junction within domain I of 23 S, which contains many universally conserved bases and which lies close in the primary and secondary structure to the binding site of r-protein L24. Several other highly conserved hairpin, internal, and multi-helix loops in 16 S and 23 S rRNA contain the motif, including the core junction loop of 23 S and helix 27 in the core of 16 S rRNA. Sequence conservation and range of variation in bacteria, archaea, and eucaryotes as well as chemical probing and cross-linking data, provide support for the recurrent and autonomous existence of the motif in ribosomal RNAs. Besides its presence in the hairpin ribozyme, the loop E motif is also apparent in helix P10 of bacterial RNase P, in domain P7 of one sub-group of group I introns, and in domain 3 of one subgroup of group II introns.

An rRNA fragment and its antisense can alter decoding of genetic information

rRNA plays a central role in protein synthesis and is intimately involved in the initiation, elongation, and termination stages of translation. However, the mode of its participation in these reactions, particularly as to the decoding of genetic information, remains elusive. In this paper, we describe a new approach that allowed us to identify an rRNA segment whose function is likely to be related to translation termination. By screening an expression library of random rRNA fragments, we identified a fragment of the Escherichia coli 23S rRNA (nucleotides 74 to 136) whose expression caused readthrough of UGA nonsense mutations in certain codon contexts in vivo. The antisense RNA fragment produced a similar effect, but in neither case was readthrough of UAA or UAG observed. Since termination at UGA in E. coli specifically requires release factor 2 (RF2), our data suggest that the fragments interfere with RF2-dependent termination.

Probing the structure of mouse Ehrlich ascites cell 5.8S, 18S and 28S ribosomal RNA in situ

The secondary structure of mouse Ehrlich ascites 18S, 5.8S and 28S ribosomal RNA in situ was investigated by chemical modification using dimethyl sulphate and 1-cyclohexyl-3-(morpholinoethyl) carbodiimide metho-p-toluene sulphonate. These reagents specifically modify unpaired bases in the RNA. The reactive bases were localized by primer extension followed by gel electrophoresis. The three rRNA species were equally accessible for modification i.e. approximately 10% of the nucleotides were reactive. The experimental data support the theoretical secondary structure models proposed for 18S and 5.8/28S rRNA as almost all modified bases were located in putative single-strand regions of the rRNAs or in helical regions that could be expected to undergo dynamic breathing. However, deviations from the suggested models were found in both 18S and 28S rRNA. In 18S rRNA some putative helices in the 5'-domain were extensively modified by the single-strand specific reagents as was one of the suggested helices in domain III of 28S rRNA. Of the four eukaryote specific expansion segments present in mouse Ehrlich ascites cell 28S rRNA, segments I and III were only partly available for modification while segments II and IV showed average to high modification.

Requirement for a conserved, tertiary interaction in the core of 23S ribosomal RNA

A putative base-pairing interaction that determines the folding of the central region of 23S rRNA has been investigated by mutagenesis. Each of the possible base substitutions has been made at the phylogenetically covariant positions adenine-1262 (A1262) and U2017 in Escherichia coli 23S rRNA. Every substitution that disrupts the potential for Watson-Crick base pairing between these positions reduces or abolishes the participation of 23S rRNA in protein synthesis. All mutant 23S rRNAs are assembled into 50S subunits, but the mutant subunits are less able to stably interact with 30S subunits to form translationally active ribosomes. The function of 23S rRNA is largely reestablished by introduction of an alternative G1262.C2017 or U1262.A2017 pair, although neither of these supports polysome formation quite as effectively as the wild-type pair. A 23S rRNA with a C1262.G2017 pair is nonfunctional. In contrast to the considerable effect the mutations have on function, they impart only slight structural changes on the naked rRNA, and these are limited to the immediate vicinity of the mutations. The data show that positions 1262 and 2017 pair in a Watson-Crick manner, but the data also indicate that these nucleotides engage in additional interactions within the ribosome and that these interactions determine what base pairs are acceptable there.

Conformational heterogeneity in the Salmonella typhimurium pyrC and pyrD leader mRNAs produced in vivo

In Salmonella typhimurium, different conformations of the pyrC and pyrD leader transcripts are produced as a result of nucleotide sensitive selection of the transcriptional start site. The CTP-initiated transcripts, synthesized at high intracellular CTP/GTP pool ratios (repressing conditions), have the potential of forming a stable secondary structure at the 5' end, thereby sequestering the site for translational initiation. At low CTP/GTP pool ratios (derepressing conditions), transcription starts 2-3 bp further downstream, resulting in transcripts with limited potential for stem-loop formation and therefore open for translational initiation. The conformation of the leader regions of wild type pyrC and pyrD mRNA has been investigated by chemical and enzymatic probing of RNA isolated from cultures grown in repressing and derepressing conditions. As controls and to obtain further information on the relation between the leader RNA conformation and the regulatory mechanism, the probing experiments also included pyrC and pyrD mRNA from mutants that contain a base substitution at a position that destabilizes the putative hairpin. In accordance with predictions based on the nucleotide sequence, the results showed that the 5' end of pyrC and pyrD leader mRNA isolated from repressed cultures is folded into a secondary structure, whereas it is largely unstructured in mRNA isolated from derepressed cultures.

Domain I of 23S rRNA competes with a paused transcription complex for ribosomal protein L4 of Escherichia coli

Ribosomal protein L4 of Escherichia coli regulates expression of its own eleven gene S10 operon both by inhibiting translation and by stimulating premature termination of transcription. Both regulatory processes presumably involve L4 recognition of the S10 leader RNA. To help define L4's regulatory target, we have investigated the protein's cognate target on 23S rRNA. Binding of L4 to various fragments of the 23S rRNA was monitored by determining their ability to sequester L4 in an in vitro transcription system and thereby eliminate the protein's effect on transcription. Using this approach we identified a region of about 110 bases within domain I of 23S rRNA which binds L4. A two base deletion within this region, close to the base to which L4 has been cross-linked in intact 50S subunits, eliminates L4 binding. These results also confirm the prediction of the autogenous control model, that L4 bound to its target on rRNA is not active in regulating transcription of the S10 operon.

The sequence of 28S ribosomal RNA varies within and between human cell lines

The primary structure of 28S ribosomal RNA constitutes a conserved core which is similar among most 23S-like rRNAs and expansion segments which occur at specific positions in the sequence. The expansion segments account for most of the size difference between prokaryotic (archaeal and eubacterial) and eukaryotic rRNAs and they exhibit a sequence variation which is unique among rRNAs. We have investigated the sequence variation of one of the expansion segments, V8, by sequencing a total of 111 V8 segments from 9 different human cell lines and tissues and have found 35 different variants. The variation occur mainly at two 'hot spots' which are separated by 170 nucleotides in the primary sequence but are neighbours in the secondary structure. The sequence of V8 segments varies both within and between human cell lines and tissues. The implications for the evolution of the eukaryotic 28S rRNA are discussed together with possible functions of the expansion segments. We also present a secondary structure model for the V8 segment based on comparative sequence analysis and chemical and enzymatic foot printing.

Introducing mutations into the single-copy chromosomal 23S rRNA gene of the archaeon Halobacterium halobium by using an rRNA operon-based transformation system

A vector-transformation system is described that permits replacement of a portion of the single rRNA operon of the archaeon Halobacterium halobium with a homologous fragment from a vector-borne gene. The vector construct contains three functional sections: (i) an entire H. halobium rRNA operon with two selective mutations in the 23S rRNA gene, the substitutions of A----G at position 1159 conferring resistance to thiostrepton and C----U at position 2471 conferring resistance to anisomycin; (ii) the complete pHSB1 plasmid from Halobacterium sp. SB3, which interferes with vector maintenance in the transformed halobacterial cells; and (iii) a segment of the pBR322 plasmid that permits vector replication in Escherichia coli. Transformation of H. halobium with the vector plasmid generates cells resistant to both anisomycin and thiostrepton that can be selected for, and discriminated from spontaneous mutants, by a two-step selection procedure. After transformation, the plasmid recombines homologously with the chromosome so that the plasmid-borne rDNA segment with resistance markers substitutes for the corresponding region of the chromosomal rRNA operon, and the transforming plasmid is lost. Eventually, this leads to a homogeneous population of the mutant ribosomes in the cell. Other mutations that are engineered in the vector-borne rRNA sequences can be transferred to the chromosomal rRNA operon concomitantly with the selective markers. The system has considerable potential for ribosomal engineering.

Attachment sites of primary binding proteins L1, L2 and L23 on 23 S ribosomal RNA of Escherichia coli

The attachment sites of the primary binding proteins L1, L2 and L23 on 23 S ribosomal RNA of Escherichia coli were examined by a chemical and ribonuclease footprinting method using several probes with different specificities. The results show that the sites are confined to localized RNA regions within the large ribonuclease-protected ribonucleoprotein fragments that were characterized earlier. They are as follows: (1) L1 recognizes a tertiary structural motif in domain V centred on two interacting internal loops; the main protein interaction sites occur at the internal loop/helix junctions. (2) The L2 site constitutes a single irregular stem/loop structure in the centre of domain IV where non-Watson-Crick pairing is likely to occur. (3) L23 recognizes a tertiary structural motif involving a single terminal loop structure and part of an adjacent internal loop at the centre of domain III. Each of the three primary binding proteins, whose presence is essential for ribosomal assembly, has been associated with important ribosomal functions: L1 lies in the E-site for deacylated tRNA binding while L2 and L23 have been implicated in the P and A substrate sites, respectively, of the peptidyl transferase centre. Moreover, each of the protein sites, but particularly those of L2 and L23, lies at the centre of RNA domains where they can maximally influence both the assembly of secondary binding proteins and the function of the RNA region.

RNA-protein interactions in the Escherichia coli ribosome

Over the last two decades essentially three different approaches have been used to study the topography of RNA-protein interactions in the ribosome. These are: (a) the analysis of binding sites for individual ribosomal proteins or groups of proteins on the RNA; (b) the determination of protein footprint sites on the RNA by the application of higher order structure analytical techniques; and (c) the localisation of RNA-protein cross-link sites on the RNA. This article compares and contrasts the types of data that the three different approaches provide, and gives a brief and highly simplified summary of the results that have been obtained for both the 16S and 23S ribosomal RNA from E coli.

Chloramphenicol resistance mutations in the single 23S rRNA gene of the archaeon Halobacterium halobium

A broad range of antibiotics affecting protein biosynthesis were screened for their ability to inhibit growth of the archaeon Halobacterium halobium. Only a few drugs, including chloramphenicol, produced inhibitory effects. Mutants which showed increased resistance to chloramphenicol were isolated; of the nine tested, eight exhibited a C----U transition at position 2471 and the ninth had an A----C transversion at position 2088 of 23S rRNA. A double mutant containing both C----U (position 2471) and A----C (position 2088) mutations was isolated, but the level of its chloramphenicol resistance did not exceed that of either single-point mutant. Inferences are made concerning the functional significance of the conserved nucleotides in rRNAs.

The assembly of prokaryotic ribosomes

The targets of in vivo studies of the ribosomal assembly process are mainly the events of rRNA processing, whereas in vitro studies (total reconstitution) focus on principles of the assembly process such as assembly-initiation proteins, rate-limiting steps and a detailed sequence of assembly reactions (assembly map). The success of in vitro analyses is particularly remarkable in view of ionic and temperature requirements of the total reconstitution which differ significantly from the in vivo conditions. Features of the in vivo assembly are surveyed, however, the focal point is a description of experimental strategies and results concerning the in vitro assembly of ribosomes.

Structural analysis of the interaction between the human immunodeficiency virus Rev protein and the Rev response element

The specific interaction between a defined structural element of the human immunodeficiency virus mRNA (RRE, the Rev response element) and the virus-encoded protein Rev has been implicated in the regulation of the export of unspliced or singly spliced mRNA from the nucleus to the cytoplasm. Rev protein was expressed and purified from insect cells using the baculovirus expression system. Chemical and RNase probes were used to analyze the structure of the RRE and the regions involved in Rev binding. Increased reactivity to single-strand-specific probes of nucleotides in two helical domains indicates that Rev binding induces conformational changes in the RRE. Binding of Rev to the RRE primarily protects helical segments and adjacent nucleotides in domain II. A Rev unit binding site is proposed that consists of a six-base-pair helical segment and three adjacent nucleotides. The data also suggest that multiple Rev proteins bind to repeated structural elements of the RRE.

Localization of a series of RNA-protein cross-link sites in the 23S and 5S ribosomal RNA from Escherichia coli, induced by treatment of 50S subunits with three different bifunctional reagents

50S ribosomal subunits were reacted with bis-(2-chloroethyl)methylamine, 2-iminothiolane or methyl p-azidophenyl acetimidate, and RNA-protein cross-link sites on the RNA were localised using our published procedures. The degree of precision with which these sites could be determined was variable, depending on the particular protein or RNA region concerned. The following positions in the 23S RNA were identified as encompassing the individual cross-link sites (numbered from the 5'-end, with asterisks denoting sites previously reported): L1, 1864-67, 1876-78, 2119-33, 2163-72*, L2, 1819-20*; L3, 2832-34; L4, 320-25*; 613-17*; L5, 2307; L6, 2473-81*; L9, 1484-91; L11, 1060-62; L13, 547-50; L14, 1993-2002; L17, 1260-95; L18, 2307-20; L19, 1741-58; L21, 544-48*; 1198-1248; L23, 63-65, 137-41*; L24, 99-107*; L27, 2272-83, 2320-23*; 2332-37*; L28, 195-242, 368-424; L29, 101-02*; L30, 931-38; L32, 2878-90; L33, 2422-24. Cross-links to 5S RNA were observed with L5 (positions 34-41), and L18 (precise site not localised).

Sixteen discrete RNA components in the cytoplasmic ribosome of Euglena gracilis

We have isolated cytoplasmic ribosomes from Euglena gracilis and characterized the RNA components of these particles. We show here that instead of the four rRNAs (17-19 S, 25-28 S, 5.8 S and 5 S) found in typical eukaryotic ribosomes, Euglena cytoplasmic ribosomes contain 16 RNA components. Three of these Euglena rRNAs are the structural equivalents of the 17-19 S, 5.8 S and 5 S rRNAs of other eukaryotes. However, the equivalent of 25-28 S rRNA is found in Euglena as 13 separate RNA species. We demonstrate that together with 5 S and 5.8 S rRNA, these 13 RNAs are all components of the large ribosomal subunit, while a 19 S RNA is the sole RNA component of the small ribosomal subunit. Two of the 13 pieces of 25-28 S rRNA are not tightly bound to the large ribosomal subunit and are released at low (0 to 0.1 mM) magnesium ion concentrations. We present here the complete primary sequences of each of the 14 RNA components (including 5.8 S rRNA) of Euglena large subunit rRNA. Sequence comparisons and secondary structure modeling indicate that these 14 RNAs exist as a non-covalent network that together must perform the functions attributed to the covalently continuous, high molecular weight, large subunit rRNA from other systems.

Characterization of the binding sites of protein L11 and the L10.(L12)4 pentameric complex in the GTPase domain of 23 S ribosomal RNA from Escherichia coli

Ribonuclease and chemical probes were used to investigate the binding sites of ribosomal protein L11 and the pentameric complex L10.(L12)4 on Escherichia coli 23 S RNA. Protein complexes were formed with an RNA fragment constituting most of domains I and II or with 23 S RNA and they were investigated by an end-labelling method and a reverse transcriptase procedure, respectively. The results demonstrate that the two protein moieties bind at adjacent sites within a small RNA region. The L11 binding region overlaps with those of the modified peptide antibiotics thiostrepton and micrococcin and is constrained structurally by a three-helix junction while the L10.(L12)4 site is centred on an adjacent internal loop. The secondary structure of the whole region was determined in detail by the phylogenetic sequence comparison method, and the results for the L11 binding region, together with the experimental data, were used in a computer graphics approach to build a partial RNA tertiary structural model. The model provides insight into the topography of the L11 binding site. It also provides a structural rationale for the mutually co-operative binding of protein L11 with the antibiotics thiostrepton and micrococcin, and with the L10.(L12)4 protein complex.

The 23S ribosomal RNA higher-order structure of Pseudomonas cepacia and other prokaryotes

A 23S ribosomal RNA gene of Pseudomonas cepacia has been cloned and sequenced. A general higher-order structure model based on earlier published models has been derived from comparative analysis of 23S-like rRNAs of eubacteria, archaebacteria, organelles and eukaryotes. Differences between the previous models were carefully analyzed and controversial regions evaluated. Moderately large insertions and deletions have been found at new points in the secondary structure. The analysis of 50 published as well as unpublished 23S rRNA sequences provide additional proof for six of the seven previously suggested tertiary interactions within the 23S rRNA. P. cepacia is the first representative of the beta subgroup of the Proteobacteria phylum whose 23S rRNA has been sequenced. A tree reflecting evolutionary relationships of prokaryotes was constructed. The topology of this tree is in good agreement with the 16S rRNA tree.

Protein L18 binds primarily at the junctions of helix II and internal loops A and B in Escherichia coli 5 S RNA. Implications for 5 S RNA structure

Ribonuclease and chemical probes were used to investigate the binding sites of ribosomal protein L18 on Escherichia coli 5 S RNA using both end-labelling and reverse transcriptase procedures. The results, together with earlier data, were superimposed on a cylindrical projection of RNA double helices and most of the protection effects were found to cluster in the major groove at two sites located on one side of the RNA at the junctions of helix II with the adjoining internal loops A and B. The loop A/helix II junction was investigated using 5 S RNA mutants, produced by site-directed mutagenesis, that exhibited altered binding properties to L18. These results, together with those from a circular dichroism study of L18 complexed with the wild-type and different mutant RNAs, enabled us to assign an L18-induced conformational change to loop A. We infer that this change contributes to the co-operative binding of L5 to helix I, which may be reinforced by the binding of the very basic N-terminal peptide of L18 within the minor groove of helix I. A psoralen derivative formed a mono-addition product with U25 within loop B in the free RNA but not in the L18 complex. Moreover, the modified molecules were selected against in L18 binding experiments. Protection effects that occurred within the adjoining helix III and loop C were compatible with a tertiary interaction between loop C and loop B/helix III that could be stabilized by the L18 binding to the junction of helix II and loop B. Further support for a bipartite binding site derived from the finding that ethidium bromide molecules that are displaced from E. coli 5 S RNA by L18 intercalate both at the loop A/helix II junction and in loop B at the binding site of the psoralen derivative.

Domain VI of Escherichia coli 23 S ribosomal RNA. Structure, assembly and function

Domain VI at the 3' end of the 23 S ribosomal RNA from Escherichia coli was prepared using the in vitro T7 RNA polymerase system. Its structure was examined by probing with ribonucleases and chemical reagents, including a psoralen derivative, of various nucleotide specificities, using a reverse transcriptase procedure for analysis. The data provided support for the most recent secondary structure derived from phylogenetic sequence comparisons and for additional structuring that was inferred from earlier experimental data. Moreover, the structure was essentially the same in the free domain, in renatured 23 S RNA and in 50 S subunits. Protein L3 bound to the isolated domain and its binding site was located at a long-range double helix containing a large internal loop. This structure is unusual for a protein-RNA binding site and it may characterize a new (third) class of site. Protein L3 has been implicated, together with L24, in initiating assembly of the 50 S subunit and it shares the exceptional property with L24 that it binds adjacent to the junction of two RNA domains from where it can maximally influence RNA folding. Protein L6 also assembled to domain VI and, in a control experiment, protein L2 bound to isolated domain IV. Domain VI was largely inaccessible in the 50 S subunit and the few accessible RNA sites occurred mainly within conserved sequence regions that constitute potential functional sites. alpha-Sarcin inactivates ribosomes by cutting at one of these sites in 50 S subunits; it also recognized the same site in the free 23 S RNA and in the free domain. Both the EF-Tu ternary complex, and the EF-G ternary complex stabilized by fusidic acid or by a non-hydrolyzable GTP derivative, inhibited alpha-sarcin attack while non-enzymatically bound tRNA did not, thus providing evidence, more direct than before, for the involvement of the RNA region in a common elongation factor binding site.

Nucleotide sequences of cDNAs encoding four complete nuclear-encoded plastid ribosomal proteins

The nucleotide sequences of four pea nuclear-encoded plastid ribosomal protein cDNAs have been determined. These cDNAs were shown to encode the complete precursor proteins. The transit sequences of the encoded proteins are similar to the transit sequences of other imported proteins being rich in serine and/or threonine and lacking aspartic and glutamic acid. The transit sequences do not, however, have any apparent amino acid sequence similarity with one another or with the transit sequences of other imported proteins. The derived amino acid sequences of the plastid ribosomal proteins were compared to the amino acid sequences of other ribosomal proteins. Significant amino acid sequence similarity was found between Escherichia coli ribosomal proteins L9 and L24 and two of the nuclear-encoded pea plastid ribosomal proteins.

The 9S RNA precursor of Escherichia coli 5S RNA has three structural domains: implications for processing

The secondary structure of the 9S RNA precursor to ribosomal 5S RNA in Escherichia coli has been determined using chemical reagents and ribonucleases in combination with a reverse transcription procedure. The 9S RNA precursor was generated in vitro by T7 RNA polymerase, and the rrnB operon terminator, T1, was able to terminate the in vitro transcript. The secondary structure model exhibits three structural domains corresponding to a 5' region, a mature region and a terminator region. The mature domain is structurally identical to 5S RNA, and the ribosomal proteins L18 and L25 are able to bind to the precursor. The processing endoribonuclease RNase E cleaves between the structural domains. Moreover, an intramolecular refolding of the nascent transcript must take place if the current view of RNase III processing stems is correct.

The E. coli 16S rRNA binding site of ribosomal protein S15: higher-order structure in the absence and in the presence of the protein

We have investigated in detail the secondary and tertiary structures of E. coli 16S rRNA binding site of protein S15 using a variety of enzymatic and chemical probes. RNase T1 and nuclease S1 were used to probe unpaired nucleotides and RNase V1 to monitor base-paired or stacked nucleotides. Bases were probed with dimethylsulfate (at A(N-1), C(N-3) and G(N-7)), with 1-cyclohexyl-3 (2-(1-methylmorpholino)-ethyl)-carboiimide-p- toluenesulfonate (at U(N-3) and G(N-1)) and with diethylpyrocarbonate (at A(N-7)). The RNA region corresponding to nucleotides 652 to 753 was tested within: (1) the complete 16S rRNA molecule; (2) a 16S rRNA fragment corresponding to nucleotides 578 to 756 obtained by transcription in vitro; (3) the S15-16S rRNA complex; (4) the S15-fragment complex. Cleavage and modification sites were detected by primer extension with reverse transcriptase. Our results show that: (1) The synthetized fragment folds into the same overall secondary structure as in the complete 16S rRNA, with the exception of the large asymmetrical internal loop (nucleotides 673-676/714-733) which is fully accessible in the fragment while it appears conformationally heterogeneous in the 16S rRNA; (2) the reactivity patterns of the S15-16S rRNA and S15-fragment complexes are identical; (3) the protein protects defined RNA regions, located in the large interior loop and in the 3'-end strand of helix [655-672]-[734-751]; (4) the protein also causes enhanced chemical reactivity and enzyme accessibility interpreted as resulting from a local conformational rearrangement, induced by S15 binding.