Getting closer to an understanding of the three-dimensional structure of ribosomal RNA

A three-dimensional model of RNase P in the hyperthermophilic archaeon Pyrococcus horikoshii OT3

Ribonuclease P (RNase P) is an endoribonuclease involved in maturation of the 5'-end of tRNA. We found previously that RNase P in the hyperthermophilic archaeon Pyrococcus horikoshii OT3 consists of a catalytic RNase P RNA (PhopRNA) and five protein cofactors designated PhoPop5, PhoRpp21, PhoRpp29, PhoRpp30, and PhoRpp38. The crystal structures of the five proteins have been determined, a three-dimensional (3-D) model of PhopRNA has been constructed, and biochemical data, including protein-RNA interaction sites, have become available. Here, this information was combined to orient the crystallographic structures of the proteins relative to their RNA binding sites in the PhopRNA model. Some alterations were made to the PhopRNA model to improve the fit. In the resulting structure, a heterotetramer composed of PhoPop5 and PhoRpp30 bridges helices P3 and P16 in the PhopRNA C-domain, thereby probably stabilizing a double-stranded RNA structure (helix P4) containing catalytic Mg²⁺ ions, while a heterodimer of PhoRpp21 and PhoRpp29 locates on a single-stranded loop connecting helices P11 and P12 in the specificity domain (S-domain) in PhopRNA, probably forming an appropriate conformation of the precursor tRNA (pre-tRNA) binding site. The fifth protein PhoRpp38 binds each kink-turn (K-turn) motif in helices P12.1, P12.2, and P16 in PhopRNA. Comparison of the structure of the resulting 3-D model with that of bacterial RNase P suggests transition from RNA-RNA interactions in bacterial RNase P to protein-RNA interactions in archaeal RNase P. The proposed 3-D model of P. horikoshii RNase P will serve as a framework for further structural and functional studies on archaeal, as well as eukaryotic, RNase Ps.

Progress and Current Challenges in Modeling Large RNAs

Recent breakthroughs in next-generation sequencing technologies have led to the discovery of several classes of non-coding RNAs (ncRNAs). It is now apparent that RNA molecules are not only just carriers of genetic information but also key players in many cellular processes. While there has been a rapid increase in the number of ncRNA sequences deposited in various databases over the past decade, the biological functions of these ncRNAs are largely not well understood. Similar to proteins, RNA molecules carry out a function by forming specific three-dimensional structures. Understanding the function of a particular RNA therefore requires a detailed knowledge of its structure. However, determining experimental structures of RNA is extremely challenging. In fact, RNA-only structures represent just 1% of the total structures deposited in the PDB. Thus, computational methods that predict three-dimensional RNA structures are in high demand. Computational models can provide valuable insights into structure-function relationships in ncRNAs and can aid in the development of functional hypotheses and experimental designs. In recent years, a set of diverse RNA structure prediction tools have become available, which differ in computational time, input data and accuracy. This review discusses the recent progress and challenges in RNA structure prediction methods.

Structural modeling of RNase P RNA of the hyperthermophilic archaeon Pyrococcus horikoshii OT3

Ribonuclease P (RNase P) is a ubiquitous trans-acting ribozyme that processes the 5' leader sequence of precursor tRNA (pre-tRNA). The RNase P RNA (PhopRNA) of the hyperthermophilic archaeon Pyrococcus horikoshii OT3 is central to the catalytic process and binds five proteins (PhoPop5, PhoRpp21, PhoRpp29, PhoRpp30, and PhoRpp38) which contribute to the enzymatic activity of the holoenzyme. Despite significant progress in determining the crystal structure of the proteins, the structure of PhopRNA remains elusive. Comparative analysis of the RNase P RNA sequences and existing crystallographic structural information of the bacterial RNase P RNAs were combined to generate a phylogenetically supported three-dimensional (3-D) model of the PhopRNA. The model structure shows an essentially flat disk with 16 tightly packed helices and a conserved face suitable for the binding of pre-tRNA. Moreover, the structure in solution was investigated by enzymatic probing and small-angle X-ray scattering (SAXS) analysis. The low resolution model derived from SAXS and the comparative 3-D model have similar overall shapes. The 3-D model provides a framework for a better understanding of structure-function relationships of this multifaceted primordial ribozyme.

In silico analysis of IRES RNAs of foot-and-mouth disease virus and related picornaviruses

Foot-and-mouth disease virus (FMDV) uses an internal ribosome entry site (IRES), a highly structured segment of its genomic RNA, to hijack the translational apparatus of an infected host. Computational analysis of 162 type II picornavirus IRES RNA sequences yielded secondary structures that included only base pairs supported by comparative or experimental evidence. The deduced helical sections provided the foundation for a hypothetical three-dimensional model of FMDV IRES RNA. The model was further constrained by incorporation of data derived from chemical modification and enzymatic probing of IRES RNAs as well as high-resolution information about IRES RNA-bound proteins.

Structure of eEF3 and the mechanism of transfer RNA release from the E-site

Elongation factor eEF3 is an ATPase that, in addition to the two canonical factors eEF1A and eEF2, serves an essential function in the translation cycle of fungi. eEF3 is required for the binding of the aminoacyl-tRNA-eEF1A-GTP ternary complex to the ribosomal A-site and has been suggested to facilitate the clearance of deacyl-tRNA from the E-site. Here we present the crystal structure of Saccharomyces cerevisiae eEF3, showing that it consists of an amino-terminal HEAT repeat domain, followed by a four-helix bundle and two ABC-type ATPase domains, with a chromodomain inserted in ABC2. Moreover, we present the cryo-electron microscopy structure of the ATP-bound form of eEF3 in complex with the post-translocational-state 80S ribosome from yeast. eEF3 uses an entirely new factor binding site near the ribosomal E-site, with the chromodomain likely to stabilize the ribosomal L1 stalk in an open conformation, thus allowing tRNA release.

Comparative 3-D modeling of tmRNA

BACKGROUND

Trans-translation releases stalled ribosomes from truncated mRNAs and tags defective proteins for proteolytic degradation using transfer-messenger RNA (tmRNA). This small stable RNA represents a hybrid of tRNA- and mRNA-like domains connected by a variable number of pseudoknots. Comparative sequence analysis of tmRNAs found in bacteria, plastids, and mitochondria provides considerable insights into their secondary structures. Progress toward understanding the molecular mechanism of template switching, which constitutes an essential step in trans-translation, is hampered by our limited knowledge about the three-dimensional folding of tmRNA.

RESULTS

To facilitate experimental testing of the molecular intricacies of trans-translation, which often require appropriately modified tmRNA derivatives, we developed a procedure for building three-dimensional models of tmRNA. Using comparative sequence analysis, phylogenetically-supported 2-D structures were obtained to serve as input for the program ERNA-3D. Motifs containing loops and turns were extracted from the known structures of other RNAs and used to improve the tmRNA models. Biologically feasible 3-D models for the entire tmRNA molecule could be obtained. The models were characterized by a functionally significant close proximity between the tRNA-like domain and the resume codon. Potential conformational changes which might lead to a more open structure of tmRNA upon binding to the ribosome are discussed. The method, described in detail for the tmRNAs of Escherichia coli, Bacillus anthracis, and Caulobacter crescentus, is applicable to every tmRNA.

CONCLUSION

Improved molecular models of biological significance were obtained. These models will guide in the design of experiments and provide a better understanding of trans-translation. The comparative procedure described here for tmRNA is easily adopted for the modeling the members of other RNA families.

Getting on target: the archaeal signal recognition particle

Protein translocation begins with the efficient targeting of secreted and membrane proteins to complexes embedded within the membrane. In Eukarya and Bacteria, this is achieved through the interaction of the signal recognition particle (SRP) with the nascent polypeptide chain. In Archaea, homologs of eukaryal and bacterial SRP-mediated translocation pathway components have been identified. Biochemical analysis has revealed that although the archaeal system incorporates various facets of the eukaryal and bacterial targeting systems, numerous aspects of the archaeal system are unique to this domain of life. Moreover, it is becoming increasingly clear that elucidation of the archaeal SRP pathway will provide answers to basic questions about protein targeting that cannot be obtained from examination of eukaryal or bacterial models. In this review, recent data regarding the molecular composition, functional behavior and evolutionary significance of the archaeal signal recognition particle pathway are discussed.

Oxazolidinones: activity, mode of action, and mechanism of resistance

Oxazolidinones are a new group of antibiotics. These synthetic drugs are active against a large spectrum of Gram-positive bacteria, including methicillin- and vancomycin-resistant staphylococci, vancomycin-resistant enterococci, penicillin-resistant pneumococci and anaerobes. Oxazolidinones inhibit protein synthesis by binding at the P site at the ribosomal 50S subunit. Resistance to other protein synthesis inhibitors does not affect oxazolidinone activity, however rare development of oxazolidinone resistance cases, associated with 23S rRNA alterations during treatment have been reported. Linezolid, the first oxazolidinone available, has already taken its place in the clinic for treatment of Gram-positive infections. Pharmacokinetic properties as well as its good penetration and accumulation in the tissue including bone, lung, vegetations, haematoma and cerebrospinal fluid, allow its use for surgical infections.

Secondary structure of two regions in expansion segments ES3 and ES6 with the potential of forming a tertiary interaction in eukaryotic 40S ribosomal subunits

The 18S rRNA of the small eukaryotic ribosomal subunit contains several expansion segments. Electron microscopy data indicate that two of the largest expansion segments are juxtaposed in intact 40S subunits, and data from phylogenetic sequence comparisons indicate that these two expansion segments contain complementary sequences that could form a direct tertiary interaction on the ribosome. We have investigated the secondary structure of the two expansion segments in the region around the putative tertiary interaction. Ribosomes from yeast, wheat, and mouse-three organisms representing separate eukaryotic kingdoms-were isolated, and the structure of ES3 and part of the ES6 region were analyzed using the single-strand-specific chemical reagents CMCT and DMS and the double-strand-specific ribonuclease V1. The modification patterns were analyzed by primer extension and gel electrophoresis on an ABI 377 automated DNA sequencer. The investigated sequences were relatively exposed to chemical and enzymatic modification. This is in line with their indicated location on the surface at the solvent side of the subunit. The complementary ES3 and ES6 sequences were clearly inaccessible to single-strand modification, but available for cleavage by double-strand-specific RNase V1. The results are compatible with a direct helical interaction between bases in ES3 and ES6. Almost identical results were obtained with ribosomes from the three organisms investigated.

Is the in situ accessibility of the 16S rRNA of Escherichia coli for Cy3-labeled oligonucleotide probes predicted by a three-dimensional structure model of the 30S ribosomal subunit?

Systematic studies on the hybridization of fluorescently labeled, rRNA-targeted oligonucleotides have shown strong variations in in situ accessibility. Reliable predictions of target site accessibility would contribute to more-rational design of probes for the identification of individual microbial cells in their natural environments. During the past 3 years, numerous studies of the higher-order structure of the ribosome have advanced our understanding of its spatial conformation. These studies range from the identification of rRNA-rRNA interactions based on covariation analyses to physical imaging of the ribosome for the identification of protein-rRNA interactions. Here we reevaluate our Escherichia coli 16S rRNA in situ accessibility data with regard to a tertiary-structure model of the small subunit of the ribosome. We localized target sequences of 176 oligonucleotides on a 3.0-A-resolution three-dimensional (3D) model of the 30S ribosomal subunit. Little correlation was found between probe hybridization efficiency and the proximity of the probe target region to the surface of the 30S ribosomal subunit model. We attribute this to the fact that fluorescence in situ hybridization is performed on fixed cells containing denatured ribosomes, whereas 3D models of the ribosome are based on its native conformation. The effects of different fixation and hybridization protocols on the fluorescence signals conferred by a set of 10 representative probes were tested. The presence or absence of the strongly denaturing detergent sodium dodecyl sulfate had a much more pronounced effect than a change of fixative from paraformaldehyde to ethanol.

tmRDB (tmRNA database)

Maintained at the University of Texas Health Science Center at Tyler, Texas, the tmRNA database (tmRDB) is accessible at the URL http://psyche.uthct.edu/dbs/tmRDB/tmRDB.html with mirror sites located at Auburn University, Auburn, Alabama (http://www.ag.auburn.edu/mirror/tmRDB/) and the Bioinformatics Research Center, Aarhus, Denmark (http://www.bioinf.au.dk/tmRDB/). The tmRDB collects and distributes information relevant to the study of tmRNA. In trans-translation, this molecule combines properties of tRNA and mRNA and binds several proteins to form the tmRNP. Related RNPs are likely to be functional in all bacteria. In this release of tmRDB, 186 new entries from 10 bacterial groups for a total of 274 tmRNA sequences have been added. Lists of the tmRNAs and the corresponding tmRNA-encoded tag-peptides are presented in alphabetical and phylogenetic order. The tmRNA sequences are aligned manually, assisted by computational tools, to determine base pairs supported by comparative sequence analysis. The tmRNA alignment, available in a variety of formats, provides the basis for the secondary and tertiary structure of each tmRNA molecule. Three-dimensional models of the tmRNAs and their associated proteins in PDB format give evidence for the recent progress that has been made in the understanding of tmRNP structure and function.

SRPDB: Signal Recognition Particle Database

The Signal Recognition Particle Database (SRPDB) at http://psyche.uthct.edu/dbs/SRPDB/SRPDB.html and http://bio.lundberg.gu.se/dbs/SRPDB/SRPDB.html assists in the better understanding of the structure and function of the signal recognition particle (SRP), a ribonucleoprotein complex that recognizes signal sequences as they emerge from the ribosome. SRPDB provides alphabetically and phylogenetically ordered lists of SRP RNA and SRP protein sequences. The SRP RNA alignment emphasizes base pairs supported by comparative sequence analysis to derive accurate SRP RNA secondary structures for each species. This release includes a total of 181 SRP RNA sequences, 7 protein SRP9, 11 SRP14, 31 SRP19, 113 SRP54 (Ffh), 9 SRP68 and 12 SRP72 sequences. There are 44 new sequences of the SRP receptor alpha subunit and its FtsY homolog (a total of 99 entries). Additional data are provided for polypeptides with established or potential roles in SRP-mediated protein targeting, such as the beta subunit of SRP receptor, Flhf, Hbsu and cpSRP43. Also available are motifs for the identification of new SRP RNA sequences, 2D representations, three-dimensional models in PDB format, and links to the high-resolution structures of several SRP components. New to this version of SRPDB is the introduction of a relational database system and a SRP RNA prediction server (SRP-Scan) which allows the identification of SRP RNAs within genome sequences and also generates secondary structure diagrams.

SRPDB (Signal Recognition Particle Database)

Signal recognition particle (SRP) is a stable cytoplasmic ribonucleoprotein complex that serves to translocate secretory proteins across membranes during translation. The SRP Database (SRPDB) provides compilations of SRP components, ordered alphabetically and phylogenetically. Alignments emphasize phylogenetically-supported base pairs in SRP RNA and conserved residues in the proteins. Data are provided in various formats including a column arrangement for improved access and simplified computational usability. Included are motifs for identification of new sequences, SRP RNA secondary structure diagrams, 3-D models and links to high-resolution structures. This release includes 11 new SRP RNA sequences (total of 129), two protein SRP9 sequences (total of seven), two protein SRP14 sequences (total of 10), two protein SRP19 sequences (total of 16), 10 new SRP54 (ffh) sequences (total of 66), two protein SRP68 sequences (total of seven) and two protein SRP72 sequences (total of nine). Seven sequences of the SRP receptor alpha-subunit and its FtsY homolog (total of 51) are new. Also considered are ss-subunit of SRP receptor, Flhf, Hbsu, CaM kinase II and cpSRP43. Access to SRPDB is at http://psyche.uthct. edu/dbs/SRPDB/SRPDB.html and the European mirror http://www.medkem. gu.se/dbs/SRPDB/SRPDB.html

tmRDB (tmRNA database)

The tmRNA database (tmRDB) is maintained at the University of Texas Health Science Center at Tyler, Texas, and accessible on the World Wide Web at the URL http://psyche.uthct.edu/dbs/tmRDB/tmRDB.++ +html. Mirror sites are located at Auburn University, Auburn, Alabama (http://www.ag.auburn.edu/mirror/tmRDB/) and the Institute of Biological Sciences, Aarhus, Denmark (http://www.bioinf.au. dk/tmRDB/). The tmRDB provides information and citation links about tmRNA, a molecule that combines functions of tRNA and mRNA in trans-translation. tmRNA is likely to be present in all bacteria and has been found in algae chloroplasts, the cyanelle of Cyanophora paradoxa and the mitochondrion of the flagellate Reclinomonas americana. This release adds 26 new sequences and corresponding predicted tmRNA-encoded tag peptides for a total of 86 tmRNAs, ordered alphabetically and phylogenetically. Secondary structures and three-dimensional models in PDB format for representative molecules are being made available. tmRNA alignments prove individual base pairs and are generated manually assisted by computational tools. The alignments with their corresponding structural annotation can be obtained in various formats, including a new column format designed to improve and simplify computational usability of the data.

An analysis of G-U base pair occurrence in eukaryotic 5S rRNAs

The structure-function relationship in RNA molecules is a key to understanding of the expression of genetic information. Various types of RNA play crucial roles at almost every step of protein biosynthesis. In recent years, it has been shown that one of the most important structural elements in RNA is a wobble pair G-U. In this paper, we present for the first time an analysis of the distribution of G-U pairs in eukaryotic 5S ribosomal RNAs. Interestingly, the G-U pair in 5S rRNA species is predominantly found in two intrahelical regions of the stems I and V and at the junction of helix IV and loop A. The distribution of G-U pairs and the nature of adjacent bases suggests their possible role as a recognition site in interactions with other components of protein biosynthesis machinery.

SRPDB (signal recognition particle database)

The signal recognition particle database (SRPDB) is maintained at the University of Texas Health Science Center at Tyler, Texas, and organizes SRP-related information about SRP RNA, SRP proteins and the SRP receptor. SRPDB is accessible on the WWW at the URL http://psyche.uthct.edu/dbs/SRPDB/SRPDB.++ +html. A mirror site of the SRPDB is located in Europe at the University of Göteborg, Sweden (http://www.medkem. gu.se/dbs/SRPDB/SRPDB.html ). This release of SRPDB adds 10 new SRP RNA sequences (a total of 117 SRP RNAs), four protein SRP19 sequences (a total of 15), seven new SRP54 (ffh) sequences (a total of 52), and eight sequences of the SRP receptor alpha subunit (FtsY) (total of 36). Sequences are arranged in alphabetical and phylogenetic order and alignments are provided which highlight base paired and conserved regions. SPRDB also provides motifs to find new sequences, a brief introduction to SRP function in protein secretion, numerous SRP RNA secondary structure diagrams, 3-D SRP RNA models, and recently obtained crystal structure PDB coordinates of the human SRP54m domain.

tmRDB (tmRNA database)

The tmRNA database (tmRDB) is maintained at the University of Texas Health Science Center at Tyler, Texas, and is accessible on the WWW at URL http://psyche.uthct.edu/dbs/tmRDB/tmRDB.++ +html. A tmRDB mirror site is located on the campus of Auburn University, Auburn, Alabama, reachable at the URL http://www.ag.auburn.edu/mirror/tmRDB/. Since April 1997, the tmRDB has provided sequences of tmRNA (previously called 10Sa RNA), a molecule present in most bacteria and some organelles. This release adds 17 new sequences for a total of 60 tmRNAs. Sequences and corresponding tmRNA-encoded tag peptides are tabulated in alphabetical and phylo-genetic order. The updated tmRNA alignment improves the secondary structures of known tmRNAs on the level of individual basepairs. tmRDB also provides an introduction to tmRNA function in trans-translation (with links to relevant literature), a limited number of tmRNA secondary structure diagrams, and numerous three-dimensional models generated interactively with the program ERNA-3D.

beta-lactam resistance in Streptococcus pneumoniae: penicillin-binding proteins and non-penicillin-binding proteins

The beta-lactams are by far the most widely used and efficacious of all antibiotics. Over the past few decades, however, widespread resistance has evolved among most common pathogens. Streptococcus pneumoniae has become a paradigm for understanding the evolution of resistance mechanisms, the simplest of which, by far, is the production of beta-lactamases. As these enzymes are frequently plasmid encoded, resistance can readily be transmitted between bacteria. Despite the fact that pneumococci are naturally transformable organisms, no beta-lactamase-producing strain has yet been described. A much more complex resistance mechanism has evolved in S. pneumoniae that is mediated by a sophisticated restructuring of the targets of the beta-lactams, the penicillin-binding proteins (PBPs); however, this may not be the whole story. Recently, a third level of resistance mechanisms has been identified in laboratory mutants, wherein non-PBP genes are mutated and resistance development is accompanied by deficiency in genetic transformation. Two such non-PBP genes have been described: a putative glycosyltransferase, CpoA, and a histidine protein kinase, CiaH. We propose that these non-PBP genes are involved in the biosynthesis of cell wall components at a step prior to the biosynthetic functions of PBPs, and that the mutations selected during beta-lactam treatment counteract the effects caused by the inhibition of penicillin-binding proteins.

Comparative sequence analysis of tmRNA

Minimal secondary structures of the bacterial and plastid tmRNAs were derived by comparative analyses of 50 aligned tmRNA sequences. The structures include 12 helices and four pseudoknots and are refinements of earlier versions, but include only those base pairs for which there is comparative evidence. Described are the conserved and variable features of the tmRNAs from a wide phylogenetic spectrum, the structural properties specific to the bacterial subgroups and preliminary 3-dimensional models from the pseudoknotted regions.

Nucleotides in 16S rRNA protected by the association of 30S and 50S ribosomal subunits

We have studied the interaction of 16S rRNA in 30S subunits with 50S subunits using a series of chemical probes that monitor the accessibility of the RNA bases and backbone. The probes include 1-cyclohexyl-3-(2-morpholinoethyl) carbodiimide metho-p-toluene sulfonate (CMCT; to probe U at N-3 and G at N-1), diethylpyrocarbonate (DEPC; to probe A at N-7), dimethyl sulfate (DMS; to probe A at N-1, and C at N-3), kethoxal (to probe G at N-1 and N-2), hydroxyl radicals generated by free Fe(II)-EDTA (to probe the backbone ribose groups) and Pb(II). The sites of reaction were identified by primer extension of the probed RNA. Association of the subunits protects the bases of 11 nucleotides and the ribose groups of over 90 nucleotides of 16S rRNA. The nucleotides protected from the base-specific probes are often adjacent to one another and surrounded by sugar-phosphate backbone protections; thus, the results obtained with the different probes confirmed each other. Most of the protected nucleotides occur in five extended-stem-loop structures around positions 250, 700, 790, 900, and 1408-1495. These regions are located in the platform and bottom of the subunit in the general vicinity of inter-subunit bridges that are visible in reconstructed electron micrographs. Our results provide an extensive map of the nucleotides in 16S rRNA that are likely to be involved in subunit-subunit interactions.

Nucleotides in 23S rRNA protected by the association of 30S and 50S ribosomal subunits

We have studied the effect of subunit association on the accessibility of nucleotides in 23S and 5S rRNA. Escherichia coli 50S subunits and 70S ribosomes were subjected to a combination of chemical probes and the sites of attack identified by primer extension. Since the ribose groups and all of the bases were probed, the present study provides a comprehensive map of the nucleotides that are likely to be involved in subunit-subunit interactions. Upon subunit association, the bases of 22 nucleotides and the ribose groups of more than 60 nucleotides are protected in 23S rRNA; no changes are seen in 5S rRNA. Interestingly, the bases of nucleotides A1866, A1891 and A1896, and G2505 become more reactive to chemical probes, indicating localized rearrangement of the structure of the 50S subunit upon association with the 30S subunit. Most of the protected nucleotides are located in four stem-loop structures around positions 715, 890, 1700, and 1920. In free 50S subunits, virtually all of the ribose groups in these four regions are strongly cleaved by hydroxyl radicals, suggesting that these stems protrude from the 50S subunit. When the 30S subunit is bound, most of the ribose groups in the 715, 890, 1700 and 1920 stem-loops are protected, as are many bases in and around the corresponding apical loops. Intriguingly, three of the protected regions of 23S rRNA are known to be linked via tertiary interactions to features of the peptidyl transferase center. Together with the juxtaposition of the subunit-protected regions of 16S rRNA with the small subunit tRNA binding sites, our findings suggest the existence of a communication pathway between the codon-anticodon binding sites of the 30S subunit with the peptidyl transferase center of the 50S subunit via rRNA-rRNA interactions.

The tmRNA database (tmRDB)

As of September, 1998, a total of 43 sequences are contained within the tmRNA database (tmRDB). The tmRNA sequences are arranged alphabetically and ordered phylogenetically. The alignment of the tmRNAs emphasizes the basepairs that are supported by comparative sequence analysis and establishes minimal secondary structures for the known tmRNAs. A corresponding alignment of the predicted tmRNA-encoded tag peptides is presented. The tmRDB also offers a small number of RNA secondary structure diagrams and PDB-formatted three-dimensional models generated with the program ERNA-3D. The data are available freely at the URL http://psyche.uthct.edu/dbs/tmRDB/tmRDB.++ +html

The Signal Recognition Particle Database (SRPDB)

The signal recognition particle database (SRPDB) is located at the University of Texas Health Science Center at Tyler and includes tabulations of SRP RNA, SRP protein and SRP receptor sequences. The sequences are annotated with links to the primary databases. They are ordered alphabetically or phylogenetically and are available in aligned form. As of September, 1998, there were 108 SRP RNA sequences, 83 SRP protein sequences and 28 sequences of the SRP receptor alpha subunit and its homologues. In addition, the SRPDB provides search motifs consisting of conserved amino acid and nucleotide residues, and a limited number of SRP RNA secondary structure diagrams and 3-D models. The data are available freely at the URL http://psyche.uthct.edu/dbs/SRPDB/SRPDB.++ +html

The three-dimensional structure of the ribosome and its components

Exciting progress has been made in the last decade by those who use physical methods to study the structure of the ribosome and its components. The structures of 10 ribosomal proteins and three isolated ribosomal protein domains are known, and the conformations of a significant number of rRNA sequences have been determined. Electron microscopists have made major advances in the analysis of images of ribosomes, and microscopically derived ribosome models at resolutions approaching 10A are likely quite soon. Furthermore, ribosome crystallographers are on the verge of phasing the diffraction patterns they have had for several years, and near-atomic resolution models for entire ribosomal subunits could emerge from this source at any time. The literature relevant to these developments is reviewed below.

Ribosomal proteins S5 and L6: high-resolution crystal structures and roles in protein synthesis and antibiotic resistance

Antibiotic resistance is rapidly becoming a major medical problem. Many antibiotics are directed against bacterial ribosomes, and mutations within both the RNA and protein components can render them ineffective. It is well known that the majority of these antibiotics act by binding to the ribosomal RNA, and it is of interest to understand how mutations in the ribosomal proteins can produce resistance. Translational accuracy is one important target of antibiotics, and a number of ribosomal protein mutations in Escherichia coli are known to modulate the proofreading mechanism of the ribosome. Here we describe the high-resolution structures of two such ribosomal proteins and characterize these mutations. The S5 protein, from the small ribosomal unit, is associated with two types of mutations: those that reduce translational fidelity and others that produce resistance to the antibiotic spectinomycin. The L6 protein, from the large subunit, has mutations that cause resistance to several aminoglycoside antibiotics, notably gentamicin. In both proteins, the mutations occur within their putative RNA-binding sites. The L6 mutations are particularly drastic because they result in large deletions of an RNA-binding region. These results support the hypothesis that the mutations create local distortions of the catalytic RNA component.When combined with a variety of structural and biochemical data, these mutations also become important probes of the architecture and function of the translational machinery. We propose that the C-terminal half of S5, which contains the accuracy mutations, organizes RNA structures associated with the decoding region, and the N-terminal half, which contains the spectinomycin-resistance mutations, directly interacts with an RNA helix that binds this antibiotic. As regards L6, we suggest that the mutations indirectly affect proofreading by locally distorting the EF-Tu.GTP.aminoacyl tRNA binding site on the large subunit.

The tmRNA database (tmRDB)

This first release of the tmRNA database (tmRDB) contains 19 tmRNA sequences, a tmRNA sequence alignment with emphasis of base pairs that are supported by comparative sequence analysis, and a tabulation of tmRNA-encoded tag peptides. The tmRNADB also offers an RNA secondary structure diagram of the Escherichia coli tmRNA, as well as PDB-formatted coordinates for three-dimensional modeling. The data are available on the World Wide Web at http://www.uthct. edu/tmRDB/tmRDB.html

Ribosomal protein S7: a new RNA-binding motif with structural similarities to a DNA architectural factor

BACKGROUND

The ribosome is a ribonucleoprotein complex which performs the crucial function of protein biosynthesis. Its role is to decode mRNAs within the cell and to synthesize the corresponding proteins. Ribosomal protein S7 is located at the head of the small (30S) subunit of the ribosome and faces into the decoding centre. S7 is one of the primary 16S rRNA-binding proteins responsible for initiating the assembly of the head of the 30S subunit. In addition, S7 has been shown to be the major protein component to cross-link with tRNA molecules bound at both the aminoacyl-tRNA (A) and peptidyl-tRNA (P) sites of the ribosome. The ribosomal protein S7 clearly plays an important role in ribosome function. It was hoped that an atomic-resolution structure of this protein would aid our understanding of ribosomal mechanisms.

RESULTS

The structure of ribosomal protein S7 from Bacillus stearothermophilus has been solved at 2.5 A resolution using multiwavelength anomalous diffraction and selenomethionyl-substituted proteins. The molecule consists of a helical hydrophobic core domain and a beta-ribbon arm extending from the hydrophobic core. The helical core domain is composed of a pair of entangled helix-turn-helix motifs; the fold of the core is similar to that of a DNA architectural factor. Highly conserved basic and aromatic residues are clustered on one face of the S7 molecule and create a 16S rRNA contact surface.

CONCLUSIONS

The molecular structure of S7, together with the results of previous cross-linking experiments, suggest how this ribosomal protein binds to the 3' major domain of 16S rRNA and mediates the folding of 16S rRNA to create the ribosome decoding centre.

A new model for the three-dimensional folding of Escherichia coli 16 S ribosomal RNA. II. The RNA-protein interaction data

The map of the mass centres of the 21 proteins from the Escherichia coli 30 S ribosomal subunit, as determined by neutron scattering, was fitted to a cryoelectron microscopic (cryo-EM) model at a resolution of 20 A of 70 S ribosomes in the pre-translocational state, carrying tRNA molecules at the A and P sites. The fit to the 30 S moiety of the 70 S particles was accomplished with the help of the well-known distribution of the ribosomal proteins in the head, body and side lobe regions of the 30 S subunit, as determined by immuno electron microscopy (IEM). Most of the protein mass centres were found to lie close to the surface (or even outside) of the cryo-EM contour of the 30 S subunit, supporting the idea that the ribosomal proteins are arranged peripherally around the rRNA. The ribosomal protein distribution was then compared with the corresponding model for the 16 S rRNA, fitted to the same EM contour (described in an accompanying paper), in order to analyse the mutual compatibility of the arrangement of proteins and rRNA in terms of the available RNA-protein interaction data. The information taken into account included the hydroxyl radical and base foot-printing data from Noller's laboratory, and our own in situ cross-linking results. Proteins S1 and S14 were not considered, due to the lack of RNA-protein data. Among the 19 proteins analysed, 12 (namely S2, S4, S5, S7, S8, S9, S10, S11, S12, S15, S17 and S21) showed a fit to the rRNA model that varied from being excellent to at least acceptable. Of the remaining 7, S3 and S13 showed a rather poor fit, as did S18 (which is considered in combination with S6 in the foot-printing experiments). S16 was difficult to evaluate, as the foot-print data for this protein cover a large area of the rRNA. S19 and S20 showed a bad fit in terms of the neutron map, but their foot-print and cross-link sites were clustered into compact groups in the rRNA model in those regions of the 30 S subunit where these proteins have respectively been located by IEM studies.

A new model for the three-dimensional folding of Escherichia coli 16 S ribosomal RNA. I. Fitting the RNA to a 3D electron microscopic map at 20 A

Recently published models of the Escherichia coli 70 S ribosome at 20 A resolution, obtained by cryo-electron microscopy (cryo-EM) combined with computerized image processing techniques, exhibit two features that are directly relevant to the in situ three-dimensional folding of the rRNA molecules. First, at this level of resolution many fine structural details are visible, a number of them having dimensions comparable to those of nucleic acid helices. Second, in reconstructions of ribosomes in the pre- and post-translocational states, density can be seen that corresponds directly to the A and P site tRNAs, and to the P and E site tRNAs, respectively, thus enabling the decoding region on the 30 S subunit to be located rather precisely. Accordingly, we have refined our previous model for the 16 S rRNA, based on biochemical evidence, by fitting it to the cryo-EM contour of ribosomes carrying A and P site tRNAs. For this purpose, the most immediately relevant evidence consists of new site-directed cross-linking data in the decoding region, which define sets of contacts between the 16 S rRNA and mRNA, or between 16 S rRNA and tRNA at the A, P and E sites; these contact sites can be correlated directly with the tRNA positions in the EM structure. The model is extended to other parts of the 16 S molecule by fitting individual elements of the well-established secondary structure of the 16 S rRNA into the appropriate fine structural elements of the EM contour, at the same time taking into account other data used in the previous model, such as intra-RNA cross-links within the 16 S rRNA itself. The large body of available RNA-protein cross-linking and foot-printing data is also considered in the model, in order to correlate the rRNA folding with the known distribution of the 30 S ribosomal proteins as determined by neutron scattering and immuno-electron microscopy. The great majority of the biochemical data points involve single-stranded regions of the rRNA, and therefore, in contrast to most previous models, the single-stranded regions are included in our structure, with the help of a specially developed modelling programme, ERNA-3D. This allows the various biochemical data sets to be displayed directly, in this and in the accompanying papers, on diagrams of appropriate parts of the rRNA structure within the cryo-EM contour.

Gene expression evidence indicates that nucleotides 507-513 and 1434-1440 in 16S rRNA are organized in close proximity on the Escherichia coli 30S ribosomal subunit

A non-Shine-Dalgamo translational initiator is identified in Escherichia coli. The nucleotide sequence ACCUACUCGAGUUAG, designated as PL, is capable of initiating translation of pokeweed antiviral protein (PAP) and human calcitonin (hCT) mRNAs in E. coli cells. The yield of recombinant protein was double that obtained with the consensus Shine-Dalgarno-sequence-(SD)-driven translation. The PL sequence is composed of two heptanucleotides (ACCUACU, box I and GAGUUAG, box II) which are complementary to nucleotides 1434-1440 and 507-513, respectively, in 16S rRNA. Mutational analysis shows that the translation initiation efficiency with either box alone is much lower than that obtained with the entire PL sequence, indicating that the boxes interact simultaneously with both complementary regions in 16S rRNA during the translation initiation step. Based on these results, we propose that the two widely separated regions 507-513 (part of helical domain 18) and 1434-1440 (belonging to helical domain 44) are organized in close proximity to each other and to the ribosome decoding center on the surface of the E. coli 30S ribosomal subunit.

The conformation of ribosomes and rRNA

During the past 18 months, electron microscopists have published two reconstructions of the Escherichia coli ribosome, independently derived from images of unstained particles. The resolutions of their images are 20-25 A-much higher than any previously available. During the same time, NMR spectroscopists have provided an atomic-resolution model for the A-site region of 16S rRNA complexed with paromomycin that explains much of what is known about the interaction of aminoglycoside antibiotics with ribosomes.

Incorporation of dinitrophenyl protein L23 into totally reconstituted Escherichia coli 50 S ribosomal subunits and its localization at two sites by immune electron microscopy

Escherichia coli ribosomal protein L23 was derivatized with [3H]2, 4-dinitrofluorobenzene both at the N terminus and at internal lysines. Dinitrophenyl-L23 (DNP-L23) was taken up into 50 S subunits from a reconstitution mixture containing rRNA and total 50 S protein depleted in L23. Unmodified L23 competed with DNP-L23 for uptake, indicating that each protein form bound in an identical or similar position within the subunit. Modified L23, incorporated at a level of 0.7 or 0.4 DNP groups per 50 S, was localized by electron microscopy of subunits complexed with antibodies to dinitrophenol. Antibodies were seen at two major sites with almost equal frequency. One site is beside the central protuberance, in a region previously identified as the peptidyltransferase center. The second location is at the base of the subunit, in the area of the exit site from which the growing peptide leaves the ribosome. Models derived from image reconstruction show hollows or canyons in the subunit and a tunnel that links the transferase and exit sites. Our results indicate that L23 is at the subunit interior, with separate elements of the protein at the subunit surface at or near both ends of this tunnel.

Transfer RNA docking pair model in the ribosomal pre- and post-translocational states

A consensus has been reached that the conformation of the anticodon-codon interactions of two adjacent tRNA molecules on the ribosome is a Sundaralingam-type (S-type). Even if it is kept to the S-type, there are still various possibilities. Various experimental data have been supporting an idea that the conformation of A-site tRNA is different from that of P-site tRNA. Those data as well as the recent result of Brimacombe and co-workers that U20:1 of lupin tRNAmMetbound to the A-site was cross-linked to a region, 875-905, of 23S rRNA in combination with the other recent findings of Nierhaus and co-workers about the spin-contrast method of neutron diffraction of the ribosome and the better accessible nucleotide patterns of phosphorothioated tRNAs on the ribosome have led to a new tRNA docking pair model, in which the highly conserved G18 and G19 of D-loop in A-site tRNA and C56 and C61 of TpsiC-loop in P-site tRNA base pair along with the conventional base pairs of adjacent codon-anticodon interactions. This A-P tRNA pair model can be translocated to the P-E tRNA pair model without changing the conformation except the ACCA termini, keeping the position of the growing nascent polypeptide chain.

Arrangement of tRNAs in pre- and posttranslocational ribosomes revealed by electron cryomicroscopy

The three-dimensional structure of the translating 70S E. coli ribosome is presented in its two main conformations: the pretranslocational and the posttranslocational states. Using electron cryomicroscopy and angular reconstitution, structures at 20 A resolution were obtained, which, when compared with our earlier reconstruction of "empty" ribosomes, showed densities corresponding to tRNA molecules--at the P and E sites for posttranslocational ribosomes and at the A and P sites for pretranslocational ribosomes. The P-site tRNA lies directly above the bridge connecting the two ribosomal subunits, with the A-site tRNA fitted snugly against it at an angle of approximately 50 degrees, toward the L7/L12 side of the ribosome. The E-site tRNA appears to lie between the side lobe of the 30S subunit and the L1 protuberance.

Ribosomes and translation

The ribosome is a large multifunctional complex composed of both RNA and proteins. Biophysical methods are yielding low-resolution structures of the overall architecture of ribosomes, and high-resolution structures of individual proteins and segments of rRNA. Accumulating evidence suggests that the ribosomal RNAs play central roles in the critical ribosomal functions of tRNA selection and binding, translocation, and peptidyl transferase. Biochemical and genetic approaches have identified specific functional interactions involving conserved nucleotides in 16S and 23S rRNA. The results obtained by these quite different approaches have begun to converge and promise to yield an unprecedented view of the mechanism of translation in the coming years.

Comparative analysis of tertiary structure elements in signal recognition particle RNA

BACKGROUND

The signal recognition particle (SRP) is a ribonucleoprotein complex that associates with ribosomes to promote co-translational translocation of proteins across biological membranes. We have used comparative analysis of a large number of bacterial, archaeal, and eukaryotic SRP RNA sequences to derive shared tertiary SRP RNA structure elements.

RESULTS

A representative three-dimensional model of the human SRP RNA is shown that includes single-stranded intrahelical and interhelical RNA loops and incorporates data from enzymatic and chemical modification, electron microscopy, and site-directed mutagenesis. Properties of the SRP RNA model are an overall extended dumbbell-shaped structure (260 A x 70 A) with a pseudoknot in the small SRP domain (a pairing of 12-UGGC-15 with 33-GCUA-36), and a tertiary interaction in the large SRP domain (198-GA-199 with 232-GU-233).

CONCLUSIONS

The RNA 'knuckle' formed in helix 8 of SRP RNA appears to constitute the binding site for protein SRP54 or its bacterial equivalent, protein P48. A dynamic property of this feature may explain the hierarchial assembly of proteins SRP19 and SRP54 in the large SRP domain. Furthermore, the human SRP RNA model serves as a framework to understand details of the structure and function of SRP in all organisms and is presented to stimulate further experimentation in this area.