Requirement for C-terminal extension to the RNA binding domain for efficient RNA binding by ribosomal protein L2

Ribosomal protein L2 is a primary 23S rRNA binding protein in the large ribosomal subunit. We examined the contribution of the N- and C-terminal regions of Bacillus stearothermophilus L2 (BstL2) to the 23S rRNA binding activity. The mutant desN, in which the N-terminal 59 residues of BstL2 were deleted, bound to the 23S rRNA fragment to the same extent as wild type BstL2, but the mutation desC, in which the C-terminal 74 amino acid residues were deleted, abolished the binding activity. These observations indicated that the C-terminal region is involved in 23S rRNA binding. Subsequent deletion analysis of the C-terminal region found that the C-terminal 70 amino acids are required for efficient 23S rRNA binding by BstL2. Furthermore, the surface plasmon resonance analysis indicated that successive truncations of the C-terminal residues increased the dissociation rate constants, while they had little influence on association rate constants. The result indicated that reduced affinities of the C-terminal deletion mutants were due only to higher dissociation rate constants, suggesting that the C-terminal region primarily functions by stabilizing the protein L2-23S rRNA complex.     

Disruption of shape complementarity in the ribosomal protein L1–RNA contact region does not hinder specific recognition of the RNA target site

The formation of a specific and stable complex between two (macro)molecules implies complementary contact surface regions. We used ribosomal protein L1, which specifically binds a target site on 23S rRNA, to study the influence of surface modifications on the protein?RNA affinity. The threonine residue in the universally conserved triad Thr?Met?Gly significant for RNA recognition and binding was substituted by phenylalanine, valine and alanine, respectively. The crystal structure of the mutant Thr217Val of the isolated domain I of L1 from Thermus thermophilus (TthL1) was determined. This structure and that of two other mutants, which had been determined earlier, were analysed and compared with the structure of the wild type L1 proteins. The influence of structural changes in the mutant L1 proteins on their affinity for the specific 23S rRNA fragment was tested by kinetic experiments using surface plasmon resonance (SPR) biosensor analysis. Association rate constants undergo minor changes, whereas dissociation rate constants displayed significantly higher values in comparison with that for the wild type protein. The analysed L1 mutants recognize the specific RNA target site, but the mutant L1?23S rRNA complexes are less stable compared to the wild type complexes. Copyright © 2010 John Wiley & Sons, Ltd.     

Mutual induced fit binding of Xenopus ribosomal protein L5 to 5S rRNA

A library of random mutations in Xenopus ribosomal protein L5 was generated by error-prone PCR and used to delineate the binding domain for 5S rRNA. All but one of the amino acid substitutions that affected binding affinity are clustered in the central region of the protein. Several of the mutations are conservative substitutions of non-polar amino acid residues that are unlikely to form energetically significant contacts to the RNA. Thermal denaturation, monitored by circular dichroism (CD), indicates that L5 is not fully structured and association with 5S rRNA increases the t(m) of the protein by 16 degrees C. L5 induces changes in the CD spectrum of 5S rRNA, establishing that the complex forms by a mutual induced fit mechanism. Deuterium exchange reveals that a considerable amount of L5 is unstructured in the absence of 5S rRNA. The fluorescence emission of W266 provides evidence for structural changes in the C-terminal region of L5 upon binding to 5S rRNA; whereas, protection experiments demonstrate that the N terminus remains highly sensitive to protease digestion in the complex. Analysis of the amino acid sequence of L5 by the program PONDR predicts that the N and C-terminal regions of L5 are intrinsically disordered, but that the central region, which contains three essential tyrosine residues and other residues important for binding to 5S rRNA, is likely to be structured. Initial interaction of the protein with 5S rRNA likely occurs through this region, followed by induced folding of the C-terminal region. The persistent disorder in the N-terminal domain is possibly exploited for interactions between the L5-5S rRNA complex and other proteins.     

The conserved 5 S rRNA complement to tRNA is not required for translation of natural mRNA

We have tested a putative base-paired interaction between the conserved GT psi C sequence of tRNA and the conserved GAAC47 sequence of 5 S ribosomal RNA by in vitro protein synthesis using ribosomes containing deletions in this region of 5 S rRNA. Ribosomes reconstituted with 5 S rRNA possessing a single break between residues 41 and 42, deletion of residues 42-46, or deletion of residues 42-52 were tested for their ability to translate phage MS2 RNA. Initiator tRNA binding, aminoacyl-tRNA binding, ppGpp synthesis, and miscoding were also tested. All of the measured functions could be carried out by ribosomes carrying the deleted 5 S rRNAs. The sizes and relative amounts of the polypeptides synthesized by MS2 RNA-programmed ribosomes were identical whether or not the 5 S RNA contained deletions. Aminoacyl-tRNA binding and miscoding were essentially unaffected. Significant reduction in ApUpG (but not poly(A,U,G) or MS2 RNA)-directed fMet-tRNA binding and ppGpp synthesis were observed, particularly in the case of the larger (residues 42-52) deletion. We conclude that if tRNA and 5 S rRNA interact in this fashion, it is not an obligatory step in protein synthesis.     

The binding site for ribosomal protein complex L8 within 23 s ribosomal RNA of Escherichia coli

The ribosomal protein complex L8 of Escherichia coli consists of two dimers of protein L7/L12 and one monomer of protein L10. This pentameric complex and ribosomal protein L11 bind in mutually cooperative fashion to 23 S rRNA and protect specific fragments of the latter from digestion with ribonuclease T1. Oligonucleotides protected either by the L8 complex alone or by the complex plus protein L11 were isolated from such digests and shown to rebind specifically to these proteins. They were also subjected to nucleotide sequence analysis. The longest oligonucleotide, protected by the L8 complex alone, consisted of residues 1028-1124 of 23 S rRNA and included all the other RNA fragments produced in this study. Previously, protein L11 had been shown to protect residues 1052-1112 of 23 S rRNA. It is concluded that the binding sites for the L8 protein complex and for protein L11 are immediately adjacent within 23 S rRNA of E. coli.     

Evolution of the plastid ribosomal RNA operon in a nongreen parasitic plant: Accelerated sequence evolution,altered promoter structure,and tRNA pseudogenes

The nucleotide sequence of a 7.4 kb region containing the entire plastid ribosomal RNA operon of the nongreen parasitic plant Epifagus virginiana has been determined. Analysis of the sequence indicates that all four rRNA genes are intact and almost certainly functional. In contrast, the split genes for tRNA^Ile and tRNA^Ala present in the 16S-23S rRNA spacer region have become pseudogenes, and deletion upstream of the 16S rRNA gene has removed a tRNA^Val gene and most of the promoter region for the rRNA operon. The rate of nucleotide substitution in 16S and 23S rRNAs is several times higher in Epifagus than in tobacco, a related photosynthetic plant. Possible reasons for this, including relaxed translational constraints, are discussed.     

rRNA binding domain of yeast ribosomal protein L25. Identification of its borders and a key leucine residue

We have delineated the region of yeast ribosomal protein L25 responsible for its specific binding to 26 S rRNA by a novel approach using in vitro synthesized, [35S]methionine-labeled fragments as well as point mutants of the L25 protein. The rRNA binding capacity of these mutant polypeptides was tested by incubation with an in vitro transcribed, biotinylated fragment of yeast 26 S rRNA that contains the complete L25 binding site. Protein-rRNA interaction was assayed by binding of the rRNA-r-protein complex to streptavidin-agarose followed either by analysis of the bound polypeptide by SDS/polyacrylamide gel electrophoresis or by precipitation with trichloroacetic acid. Our results show that the structural elements necessary and sufficient for specific interaction of L25 with 26 S rRNA are contained in the region bordered by amino acids 62 and 126. The remaining parts of the protein, in particular the C-terminal 16 residues, while not essential for binding, do enhance its affinity for 26 S rRNA. To test whether, as suggested by the results of the deletion experiments, the evolutionarily conserved sequence motif K120KAYVRL126 is involved in rRNA binding, we replaced the leucine residue at position 126 by either isoleucine or lysine. The first substitution did not affect binding. The second, however, completely abolished the specific rRNA binding capacity of the protein. Thus, Leu126, and possibly the whole conserved sequence motif, plays a key role in binding of L25 to 26 S rRNA.     

Domain I of ribosomal protein L1 is sufficient for specific RNA binding

Ribosomal protein L1 has a dual function as a ribosomal protein binding 23S rRNA and as a translational repressor binding its mRNA. L1 is a two-domain protein with N- and C-termini located in domain I. Earlier it was shown that L1 interacts with the same targets on both rRNA and mRNA mainly through domain I. We have suggested that domain I is necessary and sufficient for specific RNA-binding by L1. To test this hypothesis, a truncation mutant of L1 from Thermus thermophilus, representing domain I, was constructed by deletion of the central part of the L1 sequence, which corresponds to domain II. It was shown that the isolated domain I forms stable complexes with specific fragments of both rRNA and mRNA. The crystal structure of the isolated domain I was determined and compared with the structure of this domain within the intact protein L1. This comparison revealed a close similarity of both structures. Our results confirm our suggestion that in protein L1 its domain I alone is sufficient for specific RNA binding, whereas domain II stabilizes the L1-rRNA complex.     

Erythromycin and 5S rRNA binding properties of the spinach chloroplast ribosomal protein CL22.

The spinach chloroplast ribosomal protein (r-protein) CL22 contains a central region homologous to the Escherichia coli r-protein L22 plus long N- and C-terminal extensions. We show in this study that the CL22 combines two properties which in E. coli ribosome are split between two separate proteins. The CL22 which binds to the 5S rRNA can also be linked to an erythromycin derivative added to the 50S ribosomal subunit. This latter property is similar to that of the E. coli L22 and suggests a similar localization in the 50S subunit. We have overproduced the r-protein CL22 and deleted forms of this protein in E. coli. We show that the overproduced CL22 binds to the chloroplast 5S rRNA and that the deleted protein containing the N- and C-terminal extensions only has lost the 5S rRNA binding property. We suggest that the central homologous regions of the CL22 contains the RNA binding domain.     

Ribosomal protein S7 from Escherichia coli uses the same determinants to bind 16S ribosomal RNA and its messenger RNA

Ribosomal protein S7 from Escherichia coli binds to the lower half of the 3′ major domain of 16S rRNA and initiates its folding. It also binds to its own mRNA, the str mRNA, and represses its translation. Using filter binding assays, we show in this study that the same mutations that interfere with S7 binding to 16S rRNA also weaken its affinity for its mRNA. This suggests that the same protein regions are responsible for mRNA and rRNA binding affinities, and that S7 recognizes identical sequence elements within the two RNA targets, although they have dissimilar secondary structures. Overexpression of S7 is known to inhibit bacterial growth. This phenotypic growth defect was relieved in cells overexpressing S7 mutants that bind poorly the str mRNA, confirming that growth impairment is controlled by the binding of S7 to its mRNA. Interestingly, a mutant with a short deletion at the C-terminus of S7 was more detrimental to cell growth than wild-type S7. This suggests that the C-terminal portion of S7 plays an important role in ribosome function, which is perturbed by the deletion.     

Fragment of protein L18 from the Escherichia coli ribosome that contains the 5S RNA binding site.

A fragment of ribosomal protein L18 was prepared by limited trypsin digestion of a specific complex of L18 and 5S RNA. It was characterised for sequence and the very basic N-terminal region of the protein was found to be absent. No smaller resistant fragments were produced. 5S RNA binding experiments indicated that the basic N-terminal region, from amino acid residues 1 to 17, was not important for the L18-5S RNA association. Under milder trypsin digestion conditions three resistant fragments were produced from the free protein. The largest corresponded to that isolated from the complex. The smaller ones were trimmed slightly further at both N- and C-terminal ends. These smaller fragments did not reassociate with 5S RNA. It was concluded on the basis of the trypsin protection observations and the 5S RNA binding results that the region extending from residues 18 to 117 approximates to the minimum amount of protein required for a specific and stable protein-RNA interaction. The accessibility of the very basic N-terminal region of L18, in the L18-5S RNA complex, suggests that it may be involved, in some way, in the interaction of 5S RNA with 23S RNA.     

The structure of the RlmB 23S rRNA methyltransferase reveals a new methyltransferase fold with a unique knot

In Escherichia coli, RlmB catalyzes the methylation of guanosine 2251, a modification conserved in the peptidyltransferase domain of 23S rRNA. The crystal structure of this 2'O-methyltransferase has been determined at 2.5 A resolution. RlmB consists of an N-terminal domain connected by a flexible extended linker to a catalytic C-terminal domain and forms a dimer in solution. The C-terminal domain displays a divergent methyltransferase fold with a unique knotted region, and lacks the classic AdoMet binding site features. The N-terminal domain is similar to ribosomal proteins L7 and L30, suggesting a role in 23S rRNA recognition. The conserved residues in this novel family of 2'O-methyltransferases cluster in the knotted region, suggesting the location of the catalytic and AdoMet binding sites.     

L11 domain rearrangement upon binding to RNA and thiostrepton studied by NMR spectroscopy

Ribosomal proteins are assumed to stabilize specific RNA structures and promote compact folding of the large rRNA. The conformational dynamics of the protein between the bound and unbound state play an important role in the binding process. We have studied those dynamical changes in detail for the highly conserved complex between the ribosomal protein L11 and the GTPase region of 23S rRNA. The RNA domain is compactly folded into a well defined tertiary structure, which is further stabilized by the association with the C-terminal domain of the L11 protein (L11_ctd). In addition, the N-terminal domain of L11 (L11_ntd) is implicated in the binding of the natural thiazole antibiotic thiostrepton, which disrupts the elongation factor function. We have studied the conformation of the ribosomal protein and its dynamics by NMR in the unbound state, the RNA bound state and in the ternary complex with the RNA and thiostrepton. Our data reveal a rearrangement of the L11_ntd, placing it closer to the RNA after binding of thiostrepton, which may prevent binding of elongation factors. We propose a model for the ternary L11–RNA–thiostrepton complex that is additionally based on interaction data and conformational information of the L11 protein. The model is consistent with earlier findings and provides an explanation for the role of L11_ntd in elongation factor binding.     

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

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

Mapping of the RNA recognition site of Escherichia coli ribosomal protein S7

Bacterial ribosomal protein S7 initiates the folding of the 3' major domain of 16S ribosomal RNA by binding to its lower half. The X-ray structure of protein S7 from thermophilic bacteria was recently solved and found to be a modular structure, consisting of an alpha-helical domain with a beta-ribbon extension. To gain further insights into its interaction with rRNA, we cloned the S7 gene from Escherichia coli K12 into a pET expression vector and introduced 4 deletions and 12 amino acid substitutions in the protein sequence. The binding of each mutant to the lower half of the 3' major domain of 16S rRNA was assessed by filtration on nitrocellulose membranes. Deletion of the N-terminal 17 residues or deletion of the B hairpins (residues 72-89) severely decreased S7 affinity for the rRNA. Truncation of the C-terminal portion (residues 138-178), which includes part of the terminal alpha-helix, significantly affected S7 binding, whereas a shorter truncation (residues 148-178) only marginally influenced its binding. Severe effects were also observed with several strategic point mutations located throughout the protein, including Q8A and F17G in the N-terminal region, and K35Q, G54S, K113Q, and M115G in loops connecting the alpha-helices. Our results are consistent with the occurrence of several sites of contact between S7 and the 16S rRNA, in line with its role in the folding of the 3' major domain.     

Ribosomal RNA is the target for oxazolidinones, a novel class of translational inhibitors.

Oxazolidinones are antibacterial agents that act primarily against gram-positive bacteria by inhibiting protein synthesis. The binding of oxazolidinones to 70S ribosomes from Escherichia coli was studied by both UV-induced cross-linking using an azido derivative of oxazolidinone and chemical footprinting using dimethyl sulphate. Oxazolidinone binding sites were found on both 30S and 50S subunits, rRNA being the only target. On 16S rRNA, an oxazolidinone footprint was found at A864 in the central domain. 23S rRNA residues involved in oxazolidinone binding were U2113, A2114, U2118, A2119, and C2153, all in domain V. This region is close to the binding site of protein L1 and of the 3' end of tRNA in the E site. The mechanism of action of oxazolidinones in vitro was examined in a purified translation system from E. coli using natural mRNA. The rate of elongation reaction of translation was decreased, most probably because of an inhibition of tRNA translocation, and the length of nascent peptide chains was strongly reduced. Both binding sites and mode of action of oxazolidinones are unique among the antibiotics known to act on the ribosome.