Effects of polyvalent cations on the folding of an rRNA three-way junction and binding of ribosomal protein S15.

The Bacillus stearothermophilus ribosomal protein S15 binds to a phylogenetically conserved three-way junction formed by the intersection of helices 20, 21, and 22 of eubacterial 16S ribosomal RNA, inducing a large conformational change in the RNA. Like many RNA structures, this three-way junction can also be folded by the addition of polyvalent cations such as magnesium, as demonstrated by comparing the mobilities of the wild-type and mutant junctions in the absence and presence of polyvalent cations in nondenaturing polyacrylamide gels. Using a modification interference assay, critical nucleotides for folding have been identified as the phylogenetically conserved nucleotides in the three-way junction. NMR spectroscopy of the junction reveals that the conformations induced by the addition of magnesium or S15 are extremely similar. Thus, the folding of the junction is determined entirely by RNA elements within the phylogenetically conserved junction core, and the role of Mg2+ and S15 is to stabilize this intrinsically unstable structure. The organization of the junction by Mg2+ significantly enhances the bimolecular association rate (k(on)) of S15 binding, suggesting that S15 binds specifically to the folded form of the three-way junction via a tertiary structure capture mechanism.     

A hierarchy of RNA subdomains in assembly of the central domain of the 30 S ribosomal subunit

Beginning with the framework that has been developed for the assembly of the 30 S ribosomal subunit, we have identified a series of RNAs that are minimal binding sites for proteins S15, S6, S18, and S11 in the central domain from Thermus thermophilus. The minimal binding RNA for proteins S15, S6, and S18 consists of helix 22 and three-way junctions at both ends composed of portions of helices 20, 21, and 23. Addition of the remaining portion of helix 23 to this construct results in the minimal site for S11. Surprisingly, almost half of the central domain (helices 24, 25, and 26) is dispensable for binding the central domain proteins. Thus, at least two classes of RNA elements can be identified in ribosomal RNA. A protein-binding core element (such as helices 20, 21, 22, and 23) is required for the association of ribosomal proteins, whereas secondary binding elements (such as helices 24, 25, and 26) associate only with the preformed core RNP complex. Apparently, there may be a hierarchy of ribosomal RNA elements similar to the hierarchy of primary, secondary, and tertiary binding ribosomal proteins.     

The 16S rRNA binding site of Thermus thermophilus ribosomal protein S15: comparison with Escherichia coli S15, minimum site and structure.

Binding of Escherichia coli and Thermus thermophilus ribosomal proteins S15 to a 16S ribosomal RNA fragment from T. thermophilus (nt 559-753) has been investigated in detail by extensive deletion analysis, filter-binding assays, gel mobility shift, structure probing, footprinting with chemical, enzymatic, and hydroxyl radical probes. Both S15 proteins recognize two distinct sites. The first one maps in the bottom of helix 638-655/717-734 (H22) and in the three-way junction between helix 560-570/737-747 (H20), helix 571-600/606-634 (H21), and H22. The second is located in a conserved purine-rich region in the center of H22. The first site provides a higher contribution to the free energy of binding than the second one, and both are required for efficient binding. A short RNA fragment of 56 nt containing these elements binds S15 with high affinity. The structure of the rRNA is constrained by the three-way junction and requires both magnesium and S15 to be stabilized. A 3D model, derived by computer modeling with the use of experimental data, suggests that the bound form adopts a Y-shaped conformation, with a quasi-coaxial stacking of H22 on H20, and H21 forming an acute angle with H22. In this model, S15 binds to the shallow groove of the RNA on the exterior side of the Y-shaped structure, making contact with the two sites, which are separated by one helix turn.     

Protein binding sites on Escherichia coli 16S ribosomal RNA; RNA regions that are protected by proteins S7, S9 and S19, and by proteins S8, S15 and S17.

Selected groups of isolated 14C-labelled proteins from E. coli 30S ribosomal subunits were reconstituted with 32P-labelled 16S RNA, and the reconstituted complexes were partially digested with ribonuclease A. RNA fragments protected by the proteins were separated by gel electrophoresis and subjected to sequence analysis. Complexes containing proteins S7 and S19 protected an RNA region comprising helices 29 to 32, part of helix 41, and helices 42 and 43 of the 16S RNA secondary structure. Addition of protein S9 had no effect. When compared with previous data for proteins S7, S9, S14 and S19, these results suggest that S14 interacts with helix 33, and that S9 and S14 together interact with the loop-end of helix 41. Complexes containing proteins S8, S15 and S17 protected helices 7 to 10 as well as the "S8-S15 binding site" (helices 20, 22 and parts of helices 21 and 23). When protein S15 was omitted, S8 and S18 showed protection of part of helix 44 in addition to the latter regions. The results are discussed in terms of our model for the detailed arrangement of proteins and RNA in the 30S subunit.     

Assembly of the central domain of the 30S ribosomal subunit: roles for the primary binding ribosomal proteins S15 and S8

Assembly of the 30S ribosomal subunit occurs in a highly ordered and sequential manner. The ordered addition of ribosomal proteins to the growing ribonucleoprotein particle is initiated by the association of primary binding proteins. These proteins bind specifically and independently to 16S ribosomal RNA (rRNA). Two primary binding proteins, S8 and S15, interact exclusively with the central domain of 16S rRNA. Binding of S15 to the central domain results in a conformational change in the RNA and is followed by the ordered assembly of the S6/S18 dimer, S11 and finally S21 to form the platform of the 30S subunit. In contrast, S8 is not part of this major platform assembly branch. Of the remaining central domain binding proteins, only S21 association is slightly dependent on S8. Thus, although S8 is a primary binding protein that extensively contacts the central domain, its role in assembly of this domain remains unclear. Here, we used directed hydroxyl radical probing from four unique positions on S15 to assess organization of the central domain of 16S rRNA as a consequence of S8 association. Hydroxyl radical probing of Fe(II)-S15/16S rRNA and Fe(II)-S15/S8/16S rRNA ribonucleoprotein particles reveal changes in the 16S rRNA environment of S15 upon addition of S8. These changes occur predominantly in helices 24 and 26 near previously identified S8 binding sites. These S8-dependent conformational changes are consistent with 16S rRNA folding in complete 30S subunits. Thus, while S8 binding is not absolutely required for assembly of the platform, it appears to affect significantly the 16S rRNA environment of S15 by influencing central domain organization.     

Specific recognition of rpsO mRNA and 16S rRNA by Escherichia coli ribosomal protein S15 relies on both mimicry and site differentiation

The ribosomal protein S15 binds to 16S rRNA, during ribosome assembly, and to its own mRNA (rpsO mRNA), affecting autocontrol of its expression. In both cases, the RNA binding site is bipartite with a common subsite consisting of a G*U/G-C motif. The second subsite is located in a three-way junction in 16S rRNA and in the distal part of a stem forming a pseudoknot in Escherichia coli rpsO mRNA. To determine the extent of mimicry between these two RNA targets, we determined which amino acids interact with rpsO mRNA. A plasmid carrying rpsO (the S15 gene) was mutagenized and introduced into a strain lacking S15 and harbouring an rpsO-lacZ translational fusion. Analysis of deregulated mutants shows that each subsite of rpsO mRNA is recognized by a set of amino acids known to interact with 16S rRNA. In addition to the G*U/G-C motif, which is recognized by the same amino acids in both targets, the other subsite interacts with amino acids also involved in contacts with helix H22 of 16S rRNA, in the region adjacent to the three-way junction. However, specific S15-rpsO mRNA interactions can also be found, probably with A(-46) in loop L1 of the pseudoknot, demonstrating that mimicry between the two targets is limited.     

Crystal structure of the S15-rRNA complex

In bacterial ribosomes, the small (30S) ribosomal subunit is composed of 16S rRNA and 21 distinct proteins. Ribosomal protein S15 is of particular interest because it binds primarily to 16S rRNA and is required for assembly of the small subunit and for intersubunit association, thus representing a key element in the assembly of a whole ribosome. Here we report the 2.8 ? resolution crystal structure of the highly conserved S15-rRNA complex. Protein S15 interacts in the minor groove with a G-U/G-C motif and a three-way junction. The latter is constrained by a conserved base triple and stacking interactions, and locked into place by magnesium ions and protein side chains, mainly through interactions with the unique three-dimensional geometry of the backbone. The present structure gives insights into the dual role of S15 in ribosome assembly and translational regulation.     

Identification of the binding site of Rlp7 on assembling 60S ribosomal subunits in Saccharomyces cerevisiae

Eukaryotic ribosome assembly requires over 200 assembly factors that facilitate rRNA folding, ribosomal protein binding, and pre-rRNA processing. One such factor is Rlp7, an essential RNA binding protein required for consecutive pre-rRNA processing steps for assembly of yeast 60S ribosomal subunits: exonucleolytic processing of 27SA₃ pre-rRNA to generate the 5′ end of 5.8S rRNA and endonucleolytic cleavage of the 27SB pre-rRNA to initiate removal of internal transcribed spacer 2 (ITS2). To better understand the functions of Rlp7 in 27S pre-rRNA processing steps, we identified where it crosslinks to pre-rRNA. We found that Rlp7 binds at the junction of ITS2 and the ITS2-proximal stem, between the 3′ end of 5.8S rRNA and the 5′ end of 25S rRNA. Consistent with Rlp7 binding to this neighborhood during assembly, two-hybrid and affinity copurification assays showed that Rlp7 interacts with other assembly factors that bind to or near ITS2 and the proximal stem. We used in vivo RNA structure probing to demonstrate that the proximal stem forms prior to Rlp7 binding and that Rlp7 binding induces RNA conformational changes in ITS2 that may chaperone rRNA folding and regulate 27S pre-rRNA processing. Our findings contradict the hypothesis that Rlp7 functions as a placeholder for ribosomal protein L7, from which Rlp7 is thought to have evolved in yeast. The binding site of Rlp7 is within eukaryotic-specific RNA elements, which are not found in bacteria. Thus, we propose that Rlp7 coevolved with these RNA elements to facilitate eukaryotic-specific functions in ribosome assembly and pre-rRNA processing.     

Role of conserved nucleotides in building the 16 S rRNA binding site for ribosomal protein S15

Ribosomal protein S15 recognizes a highly conserved target on 16 S rRNA, which consists of two distinct binding regions. Here, we used extensive site-directed mutagenesis on a Escherichia coli 16 S rRNA fragment containing the S15 binding site, to investigate the role of conserved nucleotides in protein recognition and to evaluate the relative contribution of the two sites. The effect of mutations on S15 recognition was studied by measuring the relative binding affinity, RNA probing and footprinting. The crystallographic structure of the Thermus thermophilus complex allowed molecular modelling of the E. coli complex and facilitated interpretation of biochemical data. Binding is essentially driven by site 1, which includes a three-way junction constrained by a conserved base triple and cross-strand stacking. Recognition is based mainly on shape complementarity, and the role of conserved nucleotides is to maintain a unique backbone geometry. The wild-type base triple is absolutely required for protein interaction, while changes in the conserved surrounding nucleotides are partially tolerated. Site 2, which provides functional groups in a conserved G-U/G-C motif, contributes only modestly to the stability of the interaction. Binding to this motif is dependent on binding at site 1 and is allowed only if the two sites are in the correct relative orientation. Non-conserved bulged nucleotides as well as a conserved purine interior loop, although not directly involved in recognition, are used to provide an appropriate flexibility between the two sites. In addition, correct binding at the two sites triggers conformational adjustments in the purine interior loop and in a distal region, which are known to be involved for subsequent binding of proteins S6 and S18. Thus, the role of site 1 is to anchor S15 to the rRNA, while binding at site 2 is aimed to induce a cascade of events required for subunit assembly.     

Global Stabilization of rRNA Structure by Ribosomal Proteins S4, S17, and S20

Ribosomal proteins stabilize the folded structure of the ribosomal RNA and enable the recruitment of further proteins to the complex. Quantitative hydroxyl radical footprinting was used to measure the extent to which three different primary assembly proteins, S4, S17, and S20, stabilize the three-dimensional structure of the Escherichia coli 16S 5′ domain. The stability of the complexes was perturbed by varying the concentration of MgCl₂. Each protein influences the stability of the ribosomal RNA tertiary interactions beyond its immediate binding site. S4 and S17 stabilize the entire 5′ domain, while S20 has a more local effect. Multistage folding of individual helices within the 5′ domain shows that each protein stabilizes a different ensemble of structural intermediates that include nonnative interactions at low Mg²⁺ concentration. We propose that the combined interactions of S4, S17, and S20 with different helical junctions bias the free-energy landscape toward a few RNA conformations that are competent to add the secondary assembly protein S16 in the next step of assembly.     

A three-fluorophore FRET assay for high-throughput screening of small-molecule inhibitors of ribosome assembly

In one of the first steps of prokaryotic ribosome assembly, the ribosomal protein S15 binds to a three-way junction in the central domain of the 16S rRNA. Binding causes a conformational change that is required for subsequent binding events. Using a novel fluorescence resonance energy transfer assay with three fluorophores, two on the RNA and one on the S15 protein, small-molecule libraries can be screened for potential inhibitors of this initial step in ribosome assembly. The employment of three fluorophores allows both the conformational change of the RNA and the binding of S15 to be monitored in a single assay.     

Crystal structure of an RNA tertiary domain essential to HCV IRES-mediated translation initiation

The hepatitis C virus (HCV) internal ribosome entry site (IRES) RNA drives internal initiation of viral protein synthesis during host cell infection. In the tertiary structure of the IRES RNA, two helical junctions create recognition sites for direct binding of the 40S ribosomal subunit and eukaryotic initiation factor 3 (eIF3). The 2.8 A resolution structure of the IIIabc four-way junction, which is critical for binding eIF3, reveals how junction nucleotides interact with an adjacent helix to position regions directly involved in eIF3 recognition. Two of the emergent helices stack to form a nearly continuous A-form duplex, while stacking of the other two helices is interrupted by the insertion of junction residues into the helix minor groove. This distorted stack probably serves as an important recognition surface for the translational machinery.     

Do mRNA and rRNA binding sites of E.coli ribosomal protein S15 share common structural determinants?

Escherichia coli ribosomal protein S15 recognizes two RNA targets: a three-way junction in 16S rRNA and a pseudoknot structure on its own mRNA. Binding to mRNA occurs when S15 is expressed in excess over its rRNA target, resulting in an inhibition of translation start. The sole apparent similarity between the rRNA and mRNA targets is the presence of a G-U/G-C motif that contributes only modestly to rRNA binding but is essential for mRNA. To get more information on the structural determinants used by S15 to bind its mRNA target as compared to its rRNA site, we used site-directed mutagenesis, substitution by nucleotide analogs, footprinting experiments on both RNA and protein, and graphic modeling. The size of the mRNA-binding site could be reduced to 45 nucleotides, without loss of affinity. This short RNA preferentially folds into a pseudoknot, the formation of which depends on magnesium concentration and temperature. The size of the loop L2 that bridges the two stems of the pseudoknot through the minor groove could not be reduced below nine nucleotides. Then we showed that the pseudoknot recognizes the same side of S15 as 16S rRNA, although shielding a smaller surface area. It turned out that the G-U/G-C motif is recognized from the minor groove in both cases, and that the G-C pair is recognized in a very similar manner. However, the wobble G-U pair of the mRNA is not directly contacted by S15, as in rRNA, but is most likely involved in building a precise conformation of the RNA, essential for binding. Otherwise, unique specific features are utilized, such as the three-way junction in the case of 16S rRNA and the looped out A(-46) for the mRNA pseudoknot.     

23S rRNA甲基转移酶RrmJ促进细菌50S亚基后期组装

核糖体是所有细胞中负责蛋白质合成的分子机器。它自身在细胞内的组装成熟过程受到严密调控,需要诸多组装因子的参与。RrmJ是原核生物中一类保守的甲基转移酶,能够甲基化修饰核糖体上肽基转移酶中心（peptidyl transferase center, PTC）内A环的U2552位点。敲除rrmJ基因的大肠杆菌表现出显著的生长缺陷及50S亚基组装前体的累积,因而RrmJ在50S亚基组装中具有重要作用。本研究对细菌生长实验与核糖体图谱分析表明,回补表达RrmJ的质粒对于ΔrrmJ菌株生长缺陷有显著改善,50S前体累积现象也得到有效缓解。通过共沉淀实验证明,RrmJ与ΔrrmJ菌株中提取的50S前体结合能力显著强于缺失型或野生型菌株中纯化的成熟50S;当加入S-腺苷甲硫氨酸时,该酶与50S前体结合能力显著下降。冷冻电镜三维重构数据进一步阐明,缺失型菌株50S前体主要停滞在组装晚期两个PTC区域成熟程度不同的特定时段。综合上述结果表明,U2552位点的修饰发生在50S亚基组装晚期特定阶段,这一事件不仅会加速A环的RNA螺旋折叠,另有可能促进附近PTC区域结构成熟。     

Location and characteristics of ribosomal protein binding sites in the 16S RNA of Escherichia coli.

Specific binding sites for five proteins of the Escherichia coli 30S ribosomal subunit have been located within the 16S RNA. The sites are structurally diverse and range in size from 40 to 500 nucleotides; their functional integrity appears to depend upon both the secondary structure and conformation of the RNA molecule. Evidence is presented which indicates that additional proteins interact with the RNA at later stages of subunit assembly.     

30S ribosomal subunits can be assembled in vivo without primary binding ribosomal protein S15

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 degrees C this DeltarpsO 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 DeltarpsO strain at 37 degrees 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.     

Double molecular mimicry in Escherichia coli: binding of ribosomal protein L20 to its two sites in mRNA is similar to its binding to 23S rRNA

Escherichia coli ribosomal L20 is one of five proteins essential for the first reconstitution step of the 50S ribosomal subunit in vitro. It is purely an assembly protein, because it can be withdrawn from the mature subunit without effect on ribosome activity. In addition, L20 represses the translation of its own gene by binding to two sites in its mRNA. The first site is a pseudoknot formed by a base-pairing interaction between nucleotide sequences separated by more than 280 nucleotides, whereas the second site is an irregular helix formed by base-pairing between neighbouring nucleotide sequences. Despite these differences, the mRNA folds in such a way that both L20 binding sites share secondary structure similarity with the L20 binding site located at the junction between helices H40 and H41 in 23S rRNA. Using a set of genetic, biochemical, biophysical, and structural experiments, we show here that all three sites are recognized similarly by L20.     

Ribosomal protein S15 represses its own translation via adaptation of an rRNA-like fold within its mRNA

The 16S rRNA-binding ribosomal protein S15 is a key component in the assembly of the small ribosomal subunit in bacteria. We have shown that S15 from the extreme thermophile Thermus thermophilus represses the translation of its own mRNA in vitro, by interacting with the leader segment of its mRNA. The S15 mRNA-binding site was characterized by footprinting experiments, deletion analysis and site-directed mutagenesis. S15 binding triggers a conformational rearrangement of its mRNA into a fold that mimics the conserved three-way junction of the S15 rRNA-binding site. This conformational change masks the ribosome entry site, as demonstrated by direct competition between the ribosomal subunit and S15 for mRNA binding. A comparison of the T.thermophilus and Escherichia coli regulation systems reveals that the two regulatory mRNA targets do not share any similarity and that the mechanisms of translational inhibition are different. Our results highlight an astonishing plasticity of mRNA in its ability to adapt to evolutionary constraints, that contrasts with the extreme conservation of the rRNA-binding site.