This study reveals novel insights into how Escherichia coli ribosomal protein S1 functions as an RNA chaperone on the ribosome, unfolding and positioning mRNAs for translation initiation.
Summary E. coli NusA and NusB proteins bind specific sites, such as those in the leader and spacer sequences that flank the 16S region of the ribosomal RNA transcript, forming a complex with RNA polymerase that suppresses Rho-dependent transcription termination. Although antitermination has long been the accepted role for Nus factors in rRNA synthesis, we propose that another major role for the Nus modified transcription complex in rrn operons is as an RNA chaperone insuring coordination of 16S rRNA folding and RNase III processing that results in production of proper 30S ribosome subunits. This contrarian proposal is based on our studies of nusA and nusB cold-sensitive mutations that have altered translation and at low temperature accumulate 30S subunit precursors. Both phenotypes are suppressed by deletion of RNase III. We argue that these results are consistent with the idea that the nus mutations cause altered rRNA folding that leads to abnormal 30S subunits and slow translation. According to this idea, functional Nus proteins stabilize an RNA loop between their binding sites in the 5′ RNA leader and on the transcribing RNA polymerase, providing a topological constraint on the RNA that aids normal rRNA folding and processing.
Assembly of 30S ribosomal subunits from Escherichia coli has been dissected in detail using an in vitro system. Such studies have allowed characterization of the role for ribosomal protein S15 in the hierarchical assembly of 30S subunits; S15 is a primary binding protein that orchestrates the assembly of ribosomal proteins S6, S11, S18, and S21 with the central domain of 16S ribosomal RNA to form the platform of the 30S subunit. In vitro S15 is the sole primary binding protein in this cascade, performing a critical role during assembly of these four proteins. To investigate the role of S15 in vivo, the essential nature of rpsO, the gene encoding S15, was examined. Surprisingly, E. coli with an in-frame deletion of rpsO are viable, although at 37°C this DrpsO strain has an exaggerated doubling time compared to its parental strain. In the absence of S15, the remaining four platform proteins are assembled into ribosomes in vivo, and the overall architecture of the 30S subunits formed in the DrpsO strain at 37°C is not altered. Nonetheless, 30S subunits lacking S15 appear to be somewhat defective in subunit association in vivo and in vitro. In addition, this strain is cold sensitive, displaying a marked ribosome biogenesis defect at low temperature, suggesting that under nonideal conditions S15 is critical for assembly. The viability of this strain indicates that in vivo functional populations of 70S ribosomes must form in the absence of S15 and that 30S subunit assembly has a plasicity that has not previously been revealed or characterized.
SummaryA specific complex of 5 S rRNA and several ribosomal proteins is an integral part of ribosomes in all living organisms. Here we studied the importance of Escherichia coli genes rplE, rplR and rplY, encoding 5 S rRNA-binding ribosomal proteins L5, L18 and L25, respectively, for cell growth, viability and translation. Using recombineering to create gene replacements in the E. coli chromosome, it was shown that rplE and rplR are essential for cell viability, whereas cells deleted for rplY are viable, but grow noticeably slower than the parental strain. The slow growth of these L25-defective cells can be stimulated by a plasmid expressing the rplY gene and also by a plasmid bearing the gene for homologous to L25 general stress protein CTC from Bacillus subtilis. The rplY mutant ribosomes are physically normal and contain all ribosomal proteins except L25. The ribosomes from L25-defective and parental cells translate in vitro at the same rate either poly(U) or natural mRNA. The difference observed was that the mutant ribosomes synthesized less natural polypeptide, compared to wild type ribosomes both in vivo and in vitro. We speculate that the defect is at the ribosome recycling step.
In the present work, ribosomes assembled in bacterial cells in the absence of essential ribosomal protein L5 were obtained. After arresting L5 synthesis, Escherichia coli cells divide a limited number of times. During this time, accumulation of defective large ribosomal subunits occurs. These 45S particles lack most of the central protuberance (CP) components (5S rRNA and proteins L5, L16, L18, L25, L27, L31, L33 and L35) and are not able to associate with the small ribosomal subunit. At the same time, 5S rRNA is found in the cytoplasm in complex with ribosomal proteins L18 and L25 at quantities equal to the amount of ribosomes. Thus, it is the first demonstration that protein L5 plays a key role in formation of the CP during assembly of the large ribosomal subunit in the bacterial cell. A possible model for the CP assembly in vivo is discussed in view of the data obtained.
Analysis of the structures of two complexes of 5 S rRNA with homologous ribosomal proteins, Escherichia coli L25 and Thermus thermophilus TL5, revealed that amino acid residues interacting with RNA can be divided into two different groups. The first group consists of non-conserved residues, which form intermolecular hydrogen bonds accessible to solvent. The second group, comprised of strongly conserved residues, form intermolecular hydrogen bonds that are shielded from solvent. Site-directed mutagenesis was used to introduce mutations into the RNA-binding site of protein TL5. We found that replacement of residues of the first group does not influence the stability of the TL5⅐5 S rRNA complex, whereas replacement of residues of the second group leads to destabilization or disruption of the complex. Stereochemical analysis shows that the replacements of residues of the second group always create complexes with uncompensated losses of intermolecular hydrogen bonds. We suggest that these shielded intermolecular hydrogen bonds are responsible for the recognition between the protein and RNA.Abundant structural information on RNA⅐protein complexes has appeared during last five years (see for review Refs. 1-4). Thorough analysis of this information should contribute fundamentally toward understanding the principles of RNA⅐ protein recognition. In the present work the structures of two complexes of 5 S rRNA with homologous ribosomal proteins, Escherichia coli L25 (5) (PDB code 1DFU) and Thermus thermophilus TL5 (6) (PDB code 1FEU), have been analyzed. L25 and TL5 belong to the so-called CTC family of bacterial proteins. The first protein described under the CTC abbreviation was a general stress protein of Bacillus subtilis (7). Later the genes for homologous proteins were found in most of the sequenced bacterial genomes (8, 9). Among these proteins there are one-domain, two-domain, and even three-domain representatives (5, 6, 10, 11); all of them have a domain homologous to E. coli 5 S rRNA-binding ribosomal protein L25, which consists of only one domain (11). Beside L25, two other proteins of the CTC family were found in bacterial ribosomes, TL5 of T. thermophilus (12) and CTC of Deinococcus radiodurans (10). E. coli L25, T. thermophilus TL5, and D. radiodurans CTC specifically bind 5 S rRNA at the same site, the so-called loop E region (10,13,14). The stress protein CTC of B. subtilis was also shown to bind to the same site on 5 S rRNA (15). It was suggested that all CTC proteins could bind 5 S rRNA through a domain homologous to E. coli L25 (6).T. thermophilus ribosomal protein TL5 was discovered and investigated thoroughly by our group (12,14,16). It is a twodomain protein. Its RNA-binding N-terminal domain is homologous to E. coli L25. The isolated N-terminal fragment of TL5 (NfrTL5) 1 possesses the same 5 S rRNA binding ability as the full-size protein (14). The crystal structures of E. coli L25 and T. thermophilus TL5 complexed with virtually the same fragment of E. coli 5 S rRNA (Fig. 1) have been determined at a...
Ribosome biogenesis is a highly coordinated and complex process that requires numerous assembly factors that ensure prompt and flawless maturation of ribosomal subunits. Despite the increasing amount of data collected, the exact role of most assembly factors and mechanistic details of their operation remain unclear, mainly due to the shortage of high-resolution structural information. Here, using cryo-electron microscopy, we characterized 30S ribosomal particles isolated from an Escherichia coli strain with a deleted gene for the RbfA factor. The cryo-EM maps for pre-30S subunits were divided into six classes corresponding to consecutive assembly intermediates: from the particles with a completely unresolved head domain and unfolded central pseudoknot to almost mature 30S subunits with well-resolved body, platform, and head domains and partially distorted helix 44. The structures of two predominant 30S intermediates belonging to most populated classes obtained at 2.7 Å resolutions indicate that RbfA acts at two distinctive 30S assembly stages: early formation of the central pseudoknot including folding of the head, and positioning of helix 44 in the decoding center at a later stage. Additionally, it was shown that the formation of the central pseudoknot may promote stabilization of the head domain, likely through the RbfA-dependent maturation of the neck helix 28. An update to the model of factor-dependent 30S maturation is proposed, suggesting that RfbA is involved in most of the subunit assembly process.
The presence of CTC family proteins is a unique feature of bacterial cells. In the CTC family, there are true ribosomal proteins (found in ribosomes of exponentially growing cells), and at the same time there are also proteins temporarily associated with the ribosome (they are produced by the cells under stress only and incorporate into the ribosome). One feature is common for these proteins - they specifically bind to 5S rRNA. In this review, the history of investigations of the best known representatives of this family is described briefly. Structural organization of the CTC family proteins and their occurrence among known taxonomic bacterial groups are discussed. Structural features of 5S rRNA and CTC protein are described that predetermine their specific interaction. Taking into account the position of a CTC protein and its intermolecular contacts in the ribosome, a possible role of its complex with 5S rRNA in ribosome functioning is discussed.
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