A 5 S rRNA-like secondary structure in the 7 SL RNA may define a ribosomal binding site of the signal recognition particle

A new secondary structure model for parts of the 7 SL RNA is proposed which indicates for a stretch of at least 40 bases a strong structural homology to the ribosomal protein L5 binding site of eukaryotic 5 S rRNA. It is suggested that the 5 S rRNA-like structural part of 7 SL RNA mediates binding of the signal recognition particle near to the peptidyl transferase center of the ribosome.     

Mutational patterns in RNA secondary structure evolution examined in three RNA families

The goal of this work was to study mutational patterns in the evolution of RNA secondary structure. We analyzed bacterial tmRNA, RNaseP and eukaryotic telomerase RNA secondary structures, mapping structural variability onto phylogenetic trees constructed primarily from rRNA sequences. We found that secondary structures evolve both by whole stem insertion/deletion, and by mutations that create or disrupt stem base pairing. We analyzed the evolution of stem lengths and constructed substitution matrices describing the changes responsible for the variation in the RNA stem length. In addition, we used principal component analysis of the stem length data to determine the most variable stems in different families of RNA. This data provides new insights into the evolution of RNA secondary structures and patterns of variation in the lengths of double helical regions of RNA molecules. Our findings will facilitate design of improved mutational models for RNA structure evolution.     

Mechanism of ribosome assisted protein folding: A new insight into rRNA functions

The peptidyl transferase center (PTC), present in the domain V of 23S rRNA of bacteria can act as a general protein folding modulator. Any general function of a nucleic acid polymer (DNA or RNA) is always related to specific sequence/sequences. The ribosome mediated protein folding also involves a specific interaction between the nucleotides of peptidyl transferase center and the amino acids of an unfolded protein. In this article the mechanism of rRNA assisted protein folding and its significance in the light of high resolution crystal structure of ribosome are discussed.     

Tracing the evolution of RNA structure in ribosomes

The elucidation of ribosomal structure has shown that the function of ribosomes is fundamentally confined to dynamic interactions established between the RNA components of the ribosomal ensemble. These findings now enable a detailed analysis of the evolution of ribosomal RNA (rRNA) structure. The origin and diversification of rRNA was studied here using phylogenetic tools directly at the structural level. A rooted universal tree was reconstructed from the combined secondary structures of large (LSU) and small (SSU) subunit rRNA using cladistic methods and considerations in statistical mechanics. The evolution of the complete repertoire of structural ribosomal characters was formally traced lineage-by-lineage in the tree, showing a tendency towards molecular simplification and a homogeneous reduction of ribosomal structural change with time. Character tracing revealed patterns of evolution in inter-subunit bridge contacts and tRNA-binding sites that were consistent with the proposed coupling of tRNA translocation and subunit movement. These patterns support the concerted evolution of tRNA-binding sites in the two subunits and the ancestral nature and common origin of certain structural ribosomal features, such as the peptidyl (P) site, the functional relay of the penultimate stem helix of SSU rRNA, and other structures participating in ribosomal dynamics. Overall results provide a rare insight into the evolution of ribosomal structure.     

Periodic conformational changes in rRNA: monitoring the dynamics of translating ribosomes

In protein synthesis, a tRNA transits the ribosome via consecutive binding to the A (acceptor), P (peptidyl), and E (exit) site; these tRNA movements are catalyzed by elongation factor G (EF-G) and GTP. Site-specific Pb2+ cleavage was applied to trace tertiary alterations in tRNA and all rRNAs on pre- and posttranslocational ribosomes. The cleavage pattern of deacylated tRNA and AcPhe-tRNA changed individually upon binding to the ribosome; however, these different conformations were unaffected by translocation. On the other hand, translocation affects 23S rRNA structure. Significantly, the Pb2+ cleavage pattern near the peptidyl transferase center was different before and after translocation. This structural rearrangement emerged periodically during elongation, thus providing evidence for a dynamic and mobile role of 23S rRNA in translocation.     

Leader peptides of inducible chloramphenicol resistance genes from gram-positive and gram-negative bacteria bind to yeast and Archaea large subunit rRNA.

catA86 is the second gene in a constitutively transcribed, two-gene operon cloned from Bacillus pumilus . The region that intervenes between the upstream gene, termed the leader, and the catA86 coding sequence contains a pair of inverted repeat sequences which cause sequestration of the catA86 ribosome binding site in mRNA secondary structure. As a consequence, the catA86 coding sequence is untranslatable in the absence of inducer. Translation of the catA86 coding sequence is induced by chloramphenicol in Gram-positives and induction requires a function of the leader coding sequence. The leader-encoded peptide has been proposed to instruct its translating ribosome to pause at leader codon 6, enabling chloramphenicol to stall the ribosome at that site. Ribosome stalling causes destabilization of the RNA secondary structure, exposing the catA86 ribosome binding site, allowing activation of its translation. A comparable mechanism of induction by chloramphenicol has been proposed for the regulated cmlA gene from Gram-negative bacteria. The catA86 and cmlA leader-encoded peptides are in vitro inhibitors of peptidyl transferase, which is thought to be the basis for selection of the site of ribosome stalling. Both leader-encoded peptides have been shown to alter the secondary structure of Escherichia coli 23S rRNA in vitro. All peptide-induced changes in rRNA conformation are within domains IV and V, which contains the peptidyl transferase center. Here we demonstrate that the leader peptides alter the conformation of domains IV and V of large subunit rRNA from yeast and a representative of the Archaea. The rRNA target for binding the leader peptides is therefore conserved across kingdoms.     

Natural selection is not required to explain universal compositional patterns in rRNA secondary structure categories

We have encountered an unexpected property of rRNA secondary structures that may generalize to all RNAs. Analysis of 8892 ribosomal RNA sequences and structures from a wide range of species revealed unexpected universal compositional trends. First, different categories of rRNA secondary structure (stems, loops, bulges, and junctions) have distinct, characteristic base compositions. Second, the observed patterns of variation are similar among sequences from large and small rRNA subunits and all domains of life, despite extensive evolutionary divergence. Surprisingly, these differences do not seem to be related to selection for different compositions in different structural categories, but rather relate to the overall composition of the molecule: Randomized RNAs with no evolutionary history show the same structure-dependent compositional biases as rRNAs. These compositional trends may improve the accuracy of RNA secondary structure prediction, because they allow us to compare predicted structures against known compositional preferences. They also suggest caution in interpreting differences in the rate of change of the GC content in different parts of the molecule as evidence of differential selection.     

An Empirical Analysis of mt 16S rRNA Covarion-Like Evolution in Insects: Site-Specific Rate Variation Is Clustered and Frequently Detected

The structural and functional analysis of rRNA molecules has attracted considerable scientific interest. Empirical studies have demonstrated that sequence variation is not directly translated into modifications of rRNA secondary structure. Obviously, the maintenance of secondary structure and sequence variation are in part governed by different selection regimes. The nature of those selection regimes still remains quite elusive. The analysis of individual bacterial models cannot adequately explore this topic. Therefore, we used primary sequence data and secondary structures of a mitochondrial 16S rRNA fragment of 558 insect species from 15 monophyletic groups to study patterns of sequence variation, and variation of secondary structure. Using simulation studies to establish significance levels of change, we found that despite conservation of secondary structure, the location of sequence variation within the conserved rRNA structure changes significantly between groups of insects. Despite our conservative estimation procedure we found significant site-specific rate changes at 56 sites out of 184. Additionally, site-specific rate variation is somewhat clustered in certain helices. Both results confirm what has been predicted from an application of non-stationary maximum likelihood models to rRNA sequences. Clearly, constraints on sequence variation evolve and leave footprints in the form of evolutionary plasticity in rRNA sequences. Here, we show that a better understanding of the evolution of rRNA sequences can be obtained by integrating both phylogenetic and structural information.     

Deletion of a conserved, central ribosomal intersubunit RNA bridge

Elucidation of the structure of the ribosome has stimulated numerous proposals for the roles of specific rRNA elements, including the universally conserved helix 69 (H69) of 23S rRNA, which forms intersubunit bridge B2a and contacts the D stems of A- and P-site tRNAs. H69 has been proposed to be involved not only in subunit association and tRNA binding but also in initiation, translocation, translational accuracy, the peptidyl transferase reaction, and ribosome recycling. Consistent with such proposals, deletion of H69 confers a dominant lethal phenotype. Remarkably, in vitro assays show that affinity-purified Deltah69 ribosomes have normal translational accuracy, synthesize a full-length protein from a natural mRNA template, and support EF-G-dependent translocation at wild-type rates. However, Deltah69 50S subunits are unable to associate with 30S subunits in the absence of tRNA, are defective in RF1-catalyzed peptide release, and can be recycled in the absence of RRF.     

Trial for peptide bond formation using model molecules based on the interactions between the CCA sequence of tRNA and 23S rRNA.

The peptidyl transfer reaction catalyzed by the ribosome is a sophisticated product of evolution. The molecular mechanism of peptide bond formation has not been fully elucidated although the essential involvement of 23S rRNA has been established. The universal CCA sequence at the 3'-end of tRNA plays an important role in this process, by interacting with specific nucleotides in 23S rRNA. However, reconstitution of peptidyl transferase activity by a naked 23S rRNA (without the help of any of the ribosomal proteins) has not been reported. To investigate the possible evolutionary development of the peptidyl transfer reaction, we tried to obtain peptide bond formation using a piece of tRNA--an aminoacyl-minihelix--mixed with sequence-specific oligonucleotides that contained puromycin. This system reproduced conceptually the equivalent interactions between the CCA trinucleotide of tRNA and 23S rRNA. Peptide bond formation was detected by gel electrophoresis, TLC and mass spectrometry. These results have implications for the evolution of the peptidyl transfer reaction in biological system.     

Ribosome origins: The relative age of 23S rRNA Domains

The modern ribosome and its component RNAs are quite large and it is likely that at an earlier time they were much smaller. Hence, not all regions of the modern ribosomal RNAs (rRNA) are likely to be equally old. In the work described here, it is hypothesized that the oldest regions of the RNAs will usually be highly integrated into the machinery. When this is the case, an examination of the interconnectivity between local RNA regions can provide insight to the relative age of the various regions. Herein, we describe an analysis of all known long-range RNA/RNA interactions within the 23S rRNA and between the 23S rRNA and the 16S rRNA in order to assess the interconnectivity between the usual Domains as defined by secondary structure. Domain V, which contains the peptidyl transferase center is centrally located, extensively connected, and therefore likely to be the oldest region. Domain IV and Domain II are extensively interconnected with both themselves and Domain V. A portion of Domain IV is also extensively connected with the 30S subunit and hence Domain IV may be older than Domain II. These results are consistent with other evidence relating to the relative age of RNA regions. Although the relative time of addition of the GTPase center can not be reliably deduced it is pointed out that the development of this may have dramatically affected the progenotes that preceded the last common ancestor.     

Transit of tRNA through the Escherichia coli ribosome. Cross-linking of the 3' end of tRNA to specific nucleotides of the 23 S ribosomal RNA at the A, P, and E sites

When bound to Escherichia coli ribosomes and irradiated with near-UV light, various derivatives of yeast tRNA(Phe) containing 2-azidoadenosine at the 3' terminus form cross-links to 23 S rRNA and 50 S subunit proteins in a site-dependent manner. A and P site-bound tRNAs, whose 3' termini reside in the peptidyl transferase center, label primarily nucleotides U2506 and U2585 and protein L27. In contrast, E site-bound tRNA labels nucleotide C2422 and protein L33. The cross-linking patterns confirm the topographical separation of the peptidyl transferase center from the E site domain. The relative amounts of label incorporated into the universally conserved residues U2506 and U2585 depend on the occupancy of the A and P sites by different tRNA ligands and indicates that these nucleotides play a pivotal role in peptide transfer. In particular, the 3'-adenosine of the peptidyl-tRNA analogue, AcPhe-tRNA(Phe), remains in close contact with U2506 regardless of whether its anticodon is located in the A site or P site. Our findings, therefore, modify and extend the hybrid state model of tRNA-ribosome interaction. We show that the 3'-end of the deacylated tRNA that is formed after transpeptidation does not immediately progress to the E site but remains temporarily in the peptidyl transferase center. In addition, we demonstrate that the E site, defined by the labeling of nucleotide C2422 and protein L33, represents an intermediate state of binding that precedes the entry of deacylated tRNA into the F (final) site from which it dissociates into the cytoplasm.     

Electron microscopy of the secondary structure in partially denatured rRNAs of Escherichia coli and Bacillus stearothermophilus.

Partially denatured 16S and 23S rRNAs from the thermophile Bacillus stearothermophilus show characteristic loop patterns when observed by electron microscopy. The patterns are very similar to those seen in rRNAs from Escherichia coli. At least 2 of 4 most stable interactions in 16S rRNA and 8 of 12 interactions in 23S rRNA are in common for the two species. These interactions correspond well to features of secondary structure in models inferred for rRNA from phylogenetic sequence comparisons and chemical modification studies. However, two additional large loops, enclosing large portions of the 23S rRNA, have been detected in B. stearothermophilus for the first time, and even though other loops are similar, their relative frequencies vary in the two species. Much of the variation is consistent with relative delta G degree values for putative base-paired stems at the base of different loops; but the 5'-terminal loops in 23S rRNA, for example, are unaccountably far less stable in B. stearothermophilus. Also, in general, structural features are not differentially stabilized in B. stearothermophilus; the relative stability of secondary structure in its ribosomes at elevated growth temperatures must involve interactions with ribosomal proteins or other cellular components.     

On the structural basis of peptide-bond formation and antibiotic resistance from atomic structures of the large ribosomal subunit

The atomic structures of the large ribosomal subunit from Haloarcula marismortui and its complexes with substrates and antibiotics have provided insights into the way the 3000 nucleotide 23S rRNA folds into a compact, specific structure and interacts with 27 ribosomal proteins as well as the structural basis of the peptidyl transferase reaction and its inhibition by antibiotics. The structure shows that the ribosome is indeed a ribozyme.     

Non-stressful death of 23S rRNA mutant G2061C defective in puromycin reaction

Catalysis of peptide bond formation in the peptidyl transferase center is a major enzymatic activity of the ribosome. Mutations limiting peptidyl transferase activity are mostly lethal. However, cellular processes triggered by peptidyl transferase deficiency in the bacterial cell are largely unknown. Here we report a study of the lethal G2061C mutant of Escherichia coli 23S ribosomal RNA (rRNA). The G2061C mutation completely impaired the puromycin reaction and abolished formation of the active firefly luciferase in an in vitro translation system, while poly(U)- and short synthetic mRNA-directed peptidyl transferase reaction with aminoacylated tRNAs in vitro was seemingly unaffected. Study of the cellular proteome upon expression of the 23S rRNA gene carrying the G2061C mutation compared to cells expressing wild-type 23S rRNA gene revealed substantial differences. Most of the observed effects in the mutant were associated with reduced expression of stress response proteins and particularly proteins associated with the ppGpp-mediated stringent response.     

Identification of 50S components neighboring 23S rRNA nucleotides A2448 and U2604 within the peptidyl transferase center of Escherichia coli ribosomes

The 23S rRNA nucleotides 2604-12 and 2448-58 fall within the central loop of domain V, which forms a major part of the peptidyl transferase center of the ribosome. We report the synthesis of radioactive, photolabile 2'-O-methyloligoRNAs, PHONTs 1 and 2, complementary to these nucleotides and their exploitation in identifying 50S ribosomal subunit components neighboring their target sites. Photolysis of the 50S complex with PHONT 1, complementary to nts 2604-12, leads to target site-specific photoincorporation into protein L2 and 23S rRNA nucleotides A886, Alpha1918, A1919, G1922-C1924, U2563, U2586, and C2601. Photolysis of the 50S complex with PHONT 2, complementary to nts 2448-58, leads to target site-specific probe photoincorporation into proteins L2, L3, one or more of proteins L17, L18, L21, and of proteins L9, L15, L16, and 23S rRNA nucleotides C2456 and psi2457. Chemical footprinting studies show that 2'-O-methyloligoRNA binding causes little distortion of the peptidyl transferase center but do provide suggestive evidence for the location of flexible regions within 23S rRNA. The significance of these results for the structure of the peptidyl transferase center is considered.