Conformation of free and ribosome bound rRNAs from E.coli

The effect of protein moiety on the conformation of 16S and 23S RNA of the $\text{E.}\text{coli}$ ribosome has been studied by circular dichroic spectroscopy. Both rRNAs possess a comparable net content of ordered secondary structure which remains unchanged after association with ribosomal proteins into “core” particles or into complete 30S and 50S subunits, respectively. However, differences found in the stability and the cooperativity of melting of free and protein-associated rRNAs imply protein-caused variations in the distribution of the intramolecular hairpin stems and loops and/or changes in long range tertiary interactions which appear to be different for both rRNAs. While 23S RNA is maximally stabilized on the large subunit by the full set of proteins, 16S RNA on the complete small subunit shows lower stability but higher cooperativity in melting.     

Use of lead(II) to probe the structure of large RNA's. Conformation of the 3' terminal domain of E. coli 16S rRNA and its involvement in building the tRNA binding sites

The present work shows that lead(II) can be used as a convenient structure probe to map the conformation of large RNA's and to follow discrete conformational changes at different functional states. We have investigated the conformation of the 3' domain of the E. coli 16S rRNA (nucleotides 1295-1542) in its naked form, in the 30S subunit and in the 70S ribosome. Our study clearly shows a preferential affinity of Pb(II) for interhelical and loop regions and suggests a high sensitivity for dynamic and flexible regions. Within 30S subunits, some cleavages are strongly decreased as the result of protein-induced protection, while others are enhanced suggesting local conformational adjustments. These rearrangements occur at functionally strategic regions of the RNA centered around nucleotides 1337, 1400, 1500 and near the 3' end of the RNA. The association of 30S and 50S subunits causes further protections at several nucleotides and some enhanced reactivities that can be interpreted in terms of subunits interface and allosteric transitions. The binding of E. coli tRNA-Phe to the 70S ribosome results in message-independent (positions 1337 and 1397) and message-dependent (1399-1400, 1491-1492 and 1505) protections. A third class of protection (1344-1345, 1393-1395, 1403-1409, 1412-1414, 1504, 1506-1507 and 1517-1519) is observed in message-directed 30S subunits, which are induced by both tRNA binding and 50S subunit association. This extensive reduction of reactivity most probably reflects an allosteric transition rather than a direct shielding.     

Use of Lead(II) to Probe the Structure of Large RNA's. Conformation of the 3′ Terminal Domain of E. coli 16S rRNA and its Involvement in Building the tRNA Binding Sites

Abstract

The present work shows that lead(II) can be used as a convenient structure probe to map the conformation of large RNA's and to follow discrete conformational changes at different functional states. We have investigated the conformation of the 3′ domain of the E. coli 16S rRNA (nucleotides 1295–1542) in its naked form, in the 30S subunit and in the 70S ribosome. Our study clearly shows a preferential affinity of Pb(II) for interhelical and loop regions and suggests a high sensitivity for dynamic and flexible regions. Within 30S subunits, some cleavages are strongly decreased as the result of protein-induced protection, while others are enhanced suggesting local conformational ajustments. These rearrangements occur at functionally strategic regions of the RNA centered around nucleotides 1337,1400,1500 and near the 3′ end of the RNA The association of 30S and 50S subunits causes further protections at several nucleotides and some enhanced reactivities that can be interpreted in terms of subunits interface and allosteric transitions. The binding of E. coli tRNA-Phe to the 70S ribosome results in message-independent (positions 1337 and 1397) and message-dependent (1399–1400, 1491–1492 and 1505) protections. Athird class ofprotection(1344–1345,1393–1395,1403–1409,1412–1414, 1504, 1506–1507 and 1517–1519) is observed in message-directed 30S subunits, which are induced by both tRNA binding and 50S subunit association. This extensive reduction of reactivity most probably reflects an allosteric transition rather than a direct shielding.     

Lack of complete cooperativity of ribosome assembly in vitro and its possible relevance to in vivo ribosome assembly and the regulation of ribosomal gene expression.

Earlier studies have shown that the reconstitution of Escherichia coli 50S as well as 30S ribosomal subunits from component rRNA and ribosomal protein (r-protein) molecules in vitro is not completely cooperative and binding of more than one r-protein to a single 16S rRNA (or 23S rRNA) molecule is required to initiate a successful 30S (or 50S) ribosome assembly reaction. We first confirmed this conclusion by carrying out 30S subunit reconstitution in the presence of a constant amount of 16S rRNA together with various amounts of total 30S r-proteins (TP30) and by analyzing the physical state of reconstituted particles rather than by assaying protein synthesizing activity of the particles as was done in the earlier studies. As expected, under conditions of excess rRNA, the efficiency of 30S subunit reconstitution per unit amount of TP30 decreased greatly with the decrease in the ratio of TP30 to rRNA, indicating the lack of complete cooperativity in the assembly reaction. We then asked the question whether the cooperativity of ribosome assembly is complete in vivo. We treated exponentially growing E coli cells with low concentrations of chloramphenicol which is known to inhibit protein synthesis without inhibiting rRNA synthesis, creating conditions of excess synthesis of rRNA relative to r-proteins. Several concentrations of chloramphenicol (ranging from 0.4 to 4.0 micrograms/ml) were used so that inhibition of protein synthesis ranged from 40 to 95%. Under these conditions, we examined the synthesis of RNA, ribosomal proteins and 50S ribosomal subunits as well as the synthesis of total protein. We found that the synthesis of 50S subunits was not inhibited as much as the synthesis of total protein at lower concentrations of chloramphenicol, but the degree of inhibition of 50S subunit synthesis increased sharply with increasing concentrations of chloramphenicol and was in fact greater than the degree of inhibition of total protein synthesis at chloramphenicol concentrations of 2 micrograms/ml or higher. The inhibition of 50S subunit synthesis was significantly greater than the inhibition of r-protein synthesis at all chloramphenicol concentrations examined. These data are consistent with the hypothesis that the cooperativity of ribosome assembly in vivo is also not complete as is the case for in vitro ribosome reconstitution, but are difficult, if not impossible, to explain on the basis of the complete cooperativity model.(ABSTRACT TRUNCATED AT 400 WORDS)     

Nonbridging phosphate oxygens in 16S rRNA important for 30S subunit assembly and association with the 50S ribosomal subunit

Ribosomes are composed of RNA and protein molecules that associate together to form a supramolecular machine responsible for protein biosynthesis. Detailed information about the structure of the ribosome has come from the recent X-ray crystal structures of the ribosome and the ribosomal subunits. However, the molecular interactions between the rRNAs and the r-proteins that occur during the intermediate steps of ribosome assembly are poorly understood. Here we describe a modification-interference approach to identify nonbridging phosphate oxygens within 16S rRNA that are important for the in vitro assembly of the Escherichia coli 30S small ribosomal subunit and for its association with the 50S large ribosomal subunit. The 30S small subunit was reconstituted from phosphorothioate-substituted 16S rRNA and small subunit proteins. Active 30S subunits were selected by their ability to bind to the 50S large subunit and form 70S ribosomes. Analysis of the selected population shows that phosphate oxygens at specific positions in the 16S rRNA are important for either subunit assembly or for binding to the 50S subunit. The X-ray crystallographic structures of the 30S subunit suggest that some of these phosphate oxygens participate in r-protein binding, coordination of metal ions, or for the formation of intersubunit bridges in the mature 30S subunit. Interestingly, however, several of the phosphate oxygens identified in this study do not participate in any interaction in the mature 30S subunit, suggesting that they play a role in the early steps of the 30S subunit assembly.     

Protection of specific sites in 23 S and 5 S RNA from chemical modification by association of 30 S and 50 S ribosomes.

The effect of 30S subunit attachment on the accessibility of specific sites in 5 S and 23 S RNA in 50 S ribosomal subunits was studied by means of the guanine-specific reagent kethoxal. Oligonucleotides surrounding the sites of kethoxal substitution were resolved and quantitated by diagonal electrophoresis. In contrast to the extensive protection of sites in 16 S RNA in 70 S ribosomes (Chapman &; Noller, 1977), only two strongly (approx. 90%) protected sites were detected in 23 S RNA. The nucleotide sequences at these sites are

in which the indicated kethoxal-reactive guanines (with K above them) are strongly protected by association of 30 S and 50 S subunits. The latter sequence has the potential to base-pair with nucleotides 816 to 821 of the 16 S RNA, a site which has been shown to be protected from kethoxal by 50 S subunits and essential for subunit association. Six additional sites in 23 S RNA are partially (30 to 50%) protected by 30 S subunits. One of these sequences,

is complementary to nucleotides 787 to 792 of 16 S RNA. a site which is also 50 S-protected and essential for association. Of the two kethoxal-reactive 5 S RNA sites in 50 S subunits, G₁₃ is partially protected in 70 S ribosomes. while G₄₁ remains unaffected by subunit association.The relatively small number of kethoxal-reactive sites in 23 S RNA that is strongly protected in 70 S ribosomes suggests that subunit association may involve contacts between single-stranded sites in 16 S RNA and 50 S subunit proteins or non-Watson-Crick interactions with 23 S RNA. in addition to the two suggested base-paired contacts.     

Surface topography of the Bacillus stearothermophilus ribosome.

Summary The surface topography of the intact 70S ribosome and free 30S and 50S subunits from Bacillus stearothermophilus strain 2184 was investigated by lactoperoxidase-catalyzed iodination. Two-dimensional polyacrylamide gel electrophoresis was employed to separate ribosomal proteins for analysis of their reactivity. Free 50S subunits incorporated about 18% more ¹²⁵I than did 50S subunits derived from 70S ribosomes, whereas free 30S subunits and 30S subunits derived from 70S ribosomes incorporated similar amounts of ¹²⁵I. Iodinated 70S ribosomes and subunits retained 62–78% of the protein synthesis activity of untreated particles and sedimentation profiles showed no gross conformational changes due to iodination. The proteins most reactive to enzymatic iodination were S4, S7, S10 and Sa of the small subunit and L2, L4, L5/9, L6 and L36 of the large subunit. Proteins S2, S3, S7, S13, Sa, L5/9, L10, L11 and L24/25 were labeled substantially more in the free subunits than in the 70S ribosome. Other proteins, including S5, S9, S12, S15/16, S18 and L36 were more extensively iodinated in the 70S ribosome than in the free subunits. The locations of tyrosine residues in some homologus ribosomal proteins from B. stearothermophilus and E. coli are compared.     

Sulfhydryl groups on yeast ribosomal proteins L7 and L26 are significantly more reactive in the 80 S particles than in the 60 S subunits.

The sulfhydryl-directed fluorescent reagent, 5-iodoacetamidofluorescein (IAF), reacts differently with proteins from the 60 S ribosomal subunit of Saccharomyces cerevisiae when this subunit is free as opposed to being contained within the 80 S ribosome. When the 80 S ribosomes and the free 60 S subunits were labeled with IAF, the specific fluorescence intensity (fluorescence intensity unit/A260 60 S subunit) of the subsequently derived 60 S was 16.3 and 5.4, respectively. Gel analysis showed that proteins L7 and L26 were selectively labeled and contained greater than 90% of the total fluorescent label, when 80 S ribosomes were labeled. When free 60 S subunits were labeled, six additional proteins were labeled. Both types of modified 60 S subunits were equally capable to support protein synthesis in vitro. Reassociation of the IAF-labeled derived and free 60 S subunits with unmodified 40 S subunits resulted in a maximum of 5-7% decrease and a 3-fold increase, respectively, in the fluorescence intensity without a shift in the emission maxima. The data suggest that ribosomal proteins L7 and L26 contain SH groups that respond to ribosomal subunit association and become more reactive in the intact ribosome than in the subunit. The environments of some or all of the additionally labeled proteins are also sensitive to subunit reassociation.     

Cross-linking of streptomycin to the 50S subunit of Escherichia coli with phenyldiglyoxal

[3H]Dihydrostreptomycin was covalently linked to the 50S subunit of Escherichia coli K12A19 with the bifunctional cross-linking reagent phenyldiglyoxal. The cross-linking was abolished under conditions that prevent the specific interaction of streptomycin with the ribosome. The binding primarily involved the ribosomal RNA and also a limited number of proteins, namely, L2, L6, and L17. This suggests that the binding domain for streptomycin is close to the peptidyl transferase center, in the valley between the central protuberance and the wider lateral protuberance of the 50S subunit. This domain faces the binding domain for streptomycin which we have previously characterized on the 30S subunit [Melan?on, P., Boileau, G., & Brakier-Gingras, L. (1984) Biochemistry 23, 6697-6703]. Our results indicate that the 50S subunit is involved in the binding of streptomycin to the bacterial ribosome, in addition to the 30S subunit which is generally considered as the specific target of the antibiotic. They are consistent with the occurrence of a single binding site for streptomycin on the ribosome, comprised of regions of both subunits.     

Localization of the protein L2 in the 50 S subunit and the 70 S E. coli ribosome

The protein L2 is found in all ribosomes and is one of the best conserved proteins of this mega-dalton complex. The protein was localized within both the isolated 50 S subunit and the 70 S ribosome of the Escherichia coli bacteria with the neutron-scattering technique of spin-contrast variation. L2 is elongated, exposing one end of the protein to the surface of the intersubunit interface of the 50 S subunit. The protein changes its conformation slightly when the 50 S subunit reassociates with the 30 S subunit to form a 70 S ribosome, becoming more elongated and moving approximately 30 A into the 50 S matrix. The results support a recent observation that L2 is essential for the association of the ribosomal subunits and might participate in the binding and translocation of the tRNAs.     

The effect of ionic and temperature shifts used for in vitro ribosome subunit reconstitution upon the large molecular weight ribosomal ribonucleic acids

The behaviour of purified, intact preparations of 16 S and 23 S rRNAs has been studied in their respective ribosome subunit reconstitution systems by means of sedimentation and electrophoretic analysis. Both species undergo profound conformation changes to more compact species at the temperatures and ionic conditions commonly agreed for their reconstitution into ribosome subunits. The 16 S rRNA undergoes a complete conformation change over the input range of concentration used, whereas the change for 23 S rRNA is incomplete for inputs above 1.5 mg X ml-1. Intact 23 S rRNA is also required and some preparations recommended for r-protein binding studies do not meet this requirement for reconstitution. These observations are discussed in relation to the overall effectiveness of ribosome subunit reconstitution systems.     

Halobacterium cutirubrum ribosomes. Properties of the ribosomal proteins and ribonucleic acid

1. The 30S ribosomal subunit of the extreme halophile Halobacterium cutirubrum is unstable and loses 75% of its ribosomal protein when the 70S ribosome is dissociated into the two subunits. A stable 30S subunit is obtained if the dissociation of the 70S particle is carried out in the presence of the soluble fraction. 2. A fractionation procedure was developed for the selective removal of groups of proteins from the 30S and 50S subunits. When the ribosomes, which are stable in 4m-K(+) and 0.1m-Mg(2+), were extracted with low-ionic-strength buffer 75-80% of the 30S proteins and 60-65% of the 50S proteins as well as the 5S rRNA were released. The proteins in this fraction are the most acidic of the H. cutirubrum ribosomal proteins. Further extraction with Li(+)-EDTA releases additional protein, leaving a core particle containing either 16S rRNA or 23S rRNA and about 5% of the total ribosomal protein. The amino acid composition, mobility on polyacrylamide gels at pH4.5 and 8.7, and the molecular-weight distribution of the various protein fractions were determined. 3. The s values of the rRNA are 5S, 16S and 23S. The C+G contents of the 16S and 23S rRNA were 56.1 and 58.8% respectively and these are higher than C+G contents of the corresponding Escherichia coli rRNA (53.8 and 54.1%).     

Chemical inactivation of Escherichia coli 30-S ribosomes by iodination. Identification of proteins involved in tRNA binding.

30-S ribosomal subunits are inactivated by iodination for both enzymic fMet-tRNA and non-enzymic Phe-tRNA binding activities. This inactivation is due to modification of the protein moiety of the ribosome. Reconstitutions were performed with 16-S RNA and mixtures of total protein isolated from modified subunits and purified proteins isolated from unmodified subunits. This allowed identification of the individual proteins which restore tRNA binding activity. S3, S14 and S19 were identified as proteins involved in fMet-tRNA binding. S1, S2, S3, S14 and S19 were identified as proteins involved in Phe-tRNA binding. Modified particles shown normal sedimentation constants and complete protein compositions both before and after reconstitution. This suggests that the loss of activity is due to modification of one or more of the actual binding sites located on the 30-S subunit and that restoration of activity is due to structural correction at this site rather than to correction of an assembly defect.     

Analysis of the conformation of the 3' major domain of Escherichia coli16S ribosomal RNA using site-directed photoaffinity crosslinking.

The 3' major domain of Escherichia coli 16S rRNA, which occupies the head of the small ribosomal subunit, is involved in several functions of the ribosome. We have used a site-specific crosslinking procedure to gain further insights into the higher-order structure of this domain. Circularly permuted RNAs were used to introduce an azidophenacyl group at specific positions within the 3' major domain. Crosslinks were generated in a high-ionic strength buffer that has been used for ribosome reconstitution studies and so enables the RNA to adopt a structure recognized by ribosomal proteins. The crosslinking sites were identified by primer extension and confirmed by assessing the mobility of the crosslinked RNA lariats in denaturing polyacrylamide gels. Eight crosslinks were characterized. Among them, one crosslink demonstrates that helix 28 is proximal to the top of helix 34, and two others show that the 1337 region, located in an internal loop at the junction of helices 29, 30, 41, and 42, is proximal to the center of helix 30 and to a segment connecting helix 28 to helix 29. These relationships of vicinity have previously been observed in native 30S subunits, which suggests that the free domain adopts a conformation similar to that within the 30S subunit. Furthermore, crosslinks were obtained in helix 34, which suggest that the upper and lower portions of this helix are in close proximity.     

Contacts of ribosomal proteins with tRNAPhe and 16S RNA in analogs of the 30S initiation complex

Direct RNA-protein contacts have been studied by means of ultraviolet-induced (254 nm) cross-links inside complexes of NAcPhe-tRNAPhe, Phe-tRNAPhe and deacylated tRNAPhe with poly(U)-charged 30S subunit of Escherichia coli ribosome. In the first two complexes tRNA directly contacts with the similar sets of proteins (S4, S5, S7, S9/S11; S6 and S8 are found only in the second complex). These sets are similar to that in the fMet-tRNAfMet X 30S X mRNA complex, evidencing similar disposition of tRNAs in these three complexes. 16S RNA contacts in free 30S subunit mainly with proteins S4, S7 and S9/S11. In both complexes, containing NAcPhe-tRNAPhe and Phe-tRNAPhe, 16S RNA contacts with essentially the same proteins (S4, S5, S7, S8, S9/S11, S10, S15, S16 and S17) and in the same ratio, evidencing similar conformation of 30S subunit in these two complexes. In the third complex deacylated tRNAPhe contacts with proteins S4, S5, S6, S8, S9/S11 and S15, 16S RNA-protein interaction differs from those in the first two complexes by a remarkable decrease of cross-linked proteins S8, and S9/S11 and by the appearance of a large amount of cross-linked proteins(s) S13/S14. Hence, this complex differs from the first two by conformation of 30S subunit and, probably, by disposition and/or conformation of tRNA.     

细菌核糖体的结构和功能

二十多年来,国际上几家实验室独立地竞争性地应用高分辨率X-射线衍射技术在原子水平上绘制出了细菌完整核糖体及其亚基精细的三维结构图,为其生物功能的研究提供了清晰的结构基础。由于这项伟大的科学成果,美国科学家文卡特拉曼·拉马克里希南（Venkatraman Ramakrishnan）、托马斯．施泰茨（Thomas A．Steitz）和以色列女科学家阿达．约纳特（Ada E．Yonath）三人荣获2009年度诺贝尔化学奖。细菌核糖体是细胞中合成蛋白质的一种细胞器,包括大小不同的两个亚基,由3种RNA和50多种不同的蛋白质组成。     

Structural dynamics of ribosomal RNA during decoding on the ribosome

Decoding is a multistep process by which the ribosome accurately selects aminoacyl-tRNA (aa-tRNA) that matches the mRNA codon in the A site. The correct geometry of the codon-anticodon complex is monitored by the ribosome, resulting in conformational changes in the decoding center of the small (30S) ribosomal subunit by an induced-fit mechanism. The recognition of aa-tRNA is modulated by changes of the ribosome conformation in regions other than the decoding center that may either affect the architecture of the latter or alter the communication of the 30S subunit with the large (50S) subunit where the GTPase and peptidyl transferase centers are located. Correct codon-anticodon complex formation greatly accelerates the rates of GTP hydrolysis and peptide bond formation, indicating the importance of crosstalk between the subunits and the role of the 50S subunit in aa-tRNA selection. In the present review, recent results of the ribosome crystallography, cryoelectron microscopy (cryo-EM), genetics, rapid kinetics and biochemical approaches are reviewed which show that the dynamics of the structure of ribosomal RNA (rRNA) play a crucial role in decoding.     

Protein involved in the binding of dihydrostreptomycin to ribosomes of Escherichia coli

At increasing ammonium chloride concentrations, 30 S subunits on one hand, and 50 S subunits, 16 S BNA and 23 S RNA on the other hand, show a different behaviour with respect to dihydrostreptomycin binding. Within a wide range (10 to 250 mm) binding to 30 S subunits is not affected by NH₄Cl, whereas binding to 50 S and the RNAs decreases by increasing NH₄Cl concentrations. 30 S subunits lose more than 90% of their binding capacity by washing with 1.15 m-LiCl (SP_1.5³).The split proteins SP_1.15 were analysed by DEAE-cellulose chromatography and Sephadex G100 gel filtration. After reconstitution with the non-binding 2.0 core the proteins S3 and S5 can bind dihydrostreptomycin independently of each other; the S5-dependent binding is stimulated by S9 and S14 (S10). The Scatchard plot revealed 0.8 binding sites per 30 S subunit. We conclude that S3 and S5 are part of one binding site of dihydrostreptomycin.     

Ribosomal protein-dependent orientation of the 16 S rRNA environment of S15

Ribosomal protein S15 binds specifically to the central domain of 16 S ribosomal RNA (16 S rRNA) and directs the assembly of four additional proteins to this domain. The central domain of 16 S rRNA along with these five proteins form the platform of the 30 S subunit. Previously, directed hydroxyl radical probing from Fe(II)-S15 in small ribonucleoprotein complexes was used to study assembly of the central domain of 16 S rRNA. Here, this same approach was used to understand the 16 S rRNA environment of Fe(II)-S15 in 30 S subunits and to determine the ribosomal proteins that are involved in forming the mature S15-16 S rRNA environment. We have identified additional sites of Fe(II)-S15-directed cleavage in 30S subunits compared to the binary complex of Fe(II)-S15/16 S rRNA. Along with novel targets in the central domain, sites within the 5' and 3' minor domains are also cleaved. This suggests that during the course of 30S subunit assembly these elements are positioned in the vicinity of S15. Besides the previously determined role for S8, roles for S5, S6+S18, and S16 in altering the 16 S rRNA environment of S15 were established. These studies reveal that ribosomal proteins can alter the assembly of regions of the 30 S subunit from a considerable distance and influence the overall conformation of this ribonucleoprotein particle.     

Modification of Escherichia coli ribosomes with the fluorescent reagent N-[[(iodoacetyl)amino]ethyl]-5-naphthylamine-1-sulfonic acid. Identification of derivatized L31' and studies on its intraribosomal properties

N-[[(Iodoacetyl)amino]ethyl]-5-naphthylamine-1-sulfonic acid (IAEDANS) is a fluorescent reagent which reacts covalently with the free thiol groups of proteins. When the reagent is reacted with the Escherichia coli ribosome under mild conditions, gel electrophoresis shows modification of predominantly two proteins, S18 and L31', which become labeled to an equal extent. When the native (i.e., untreated) ribosome is dissociated into 30S and 50S subunits, only the 30S ribosomal protein S18 reacts with IAEDANS despite the fact that L31' is still present on the large subunit. Upon heat activation of the subunits, a procedure which alters subunit conformation, S18 plus a number of higher molecular weight proteins is modified, but not L31'; the latter reacts with IAEDANS only in the 70S ribosome or when it is free. In contrast to the relatively stable association of L31' with native or with dissociated ribosomes, dissociation of N-[(acetylamino)ethyl]-5-naphthylaminesulfonic acid (AEDANS)-treated ribosomes weakens the AEDANS-L31'/ribosome interaction, resulting, upon gel filtration analysis, in ribosomes devoid of this derivatized protein.